Comparison Summary

Modelica323 with alias name: Modelica 3.2.3	Modelica322 with alias name: Modelica 3.2.2
Version: 3.2.3	Version: 3.2.2
Version date: 2019-01-23	Version date: 2016-04-03

model Blocks.Examples.PID_Controller

Component	Modelica 3.2.3	Modelica 3.2.2
driveAngle	=1.570796326794897	=1.57

---

model Blocks.Examples.BusUsage_Utilities.Part

Component	Modelica 3.2.3	Modelica 3.2.2
booleanExpression	y=time >= 0.5	y=time > 0.5

---

block Blocks.Continuous.Integrator

Component	Modelica 3.2.3	Modelica 3.2.2
use_reset	Present
use_set	Present
reset	Present
set	Present
local_reset	Present
local_set	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
...
equation if use_reset then	equation der(y) = k*u;
connect(reset, local_reset); if use_set then connect(set, local_set); else local_set = y_start; end if; when local_reset then reinit(y, local_set); end when; else local_reset = false; local_set = 0; end if; der(y) = k*u;

---

block Blocks.Continuous.LimIntegrator

Component	Modelica 3.2.3	Modelica 3.2.2
use_reset	Present
use_set	Present
reset	Present
set	Present
local_reset	Present
local_set	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
...
equation if use_reset then	equation if initial() and not limitsAtInit then
connect(reset, local_reset);	der(y) = k*u;
if use_set then	assert(y >= outMin - 0.001*abs(outMax-outMin) and y <= outMax + 0.001*abs(outMax-outMin), "LimIntegrator: During initialization the limits have been ignored.\n" + "However, the result is that the output y is not within the required limits:\n" + " y = " + String(y) + ", outMin = " + String(outMin) + ", outMax = " + String(outMax));
connect(set, local_set);	elseif strict then
	der(y) = noEvent(if y < outMin and k*u < 0 or y > outMax and k*u > 0 then 0 else k*u);
else
local_set = y_start;	der(y) = if y < outMin and k*u < 0 or y > outMax and k*u > 0 then 0 else k*u;
end if;
when local_reset then reinit(y, if local_set < outMin then outMin elseif local_set > outMax then outMax else local_set); end when; else local_reset = false; local_set = 0; end if; if initial() and not limitsAtInit then der(y) = k*u; assert(y >= outMin - 0.001*abs(outMax-outMin) and y <= outMax + 0.001*abs(outMax-outMin),             "LimIntegrator: During initialization the limits have been ignored.\n"           + "However, the result is that the output y is not within the required limits:\n"           + " y = " + String(y) + ", outMin = " + String(outMin) + ", outMax = " + String(outMax)); elseif strict then der(y) = noEvent(if y < outMin and k*u < 0 or y > outMax and k*u > 0 then 0 else k*u); else der(y) = if y < outMin and k*u < 0 or y > outMax and k*u > 0 then 0 else k*u; end if;

---

block Blocks.Continuous.LimPID

Component	Modelica 3.2.3	Modelica 3.2.2
limiter	homotopyType=homotopyType
withFeedForward	Present
kFF	Present
homotopyType	Present
u_ff	Present
FFzero	Present
addFF	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(I.y, addPID.u3);
	connect(addPID.y, gainPID.u); connect(gainPID.y, addSat.u2); connect(gainPID.y, limiter.u);
connect(limiter.y, addSat.u1); ... connect(Izero.y, addPID.u3);
connect(addPID.y, gainPID.u); connect(addFF.y, limiter.u); connect(gainPID.y, addFF.u1); connect(FFzero.y, addFF.u2); connect(addFF.u2, u_ff); connect(addFF.y, addSat.u2);

---

block Blocks.Continuous.LowpassButterworth

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... for i in 1:m loop
polereal[i] = Modelica323.Math.cos(pi/2 + pi/n*(i - 0.5));	polereal[i] = cos(pi/2 + pi/n*(i - 0.5));
poleimag[i] = Modelica323.Math.sin(pi/2 + pi/n*(i - 0.5));	poleimag[i] = sin(pi/2 + pi/n*(i - 0.5));
w0[i] = (polereal[i]^2 + poleimag[i]^2)*w; ...

---

block Blocks.Interfaces.PartialNoise

Component	Modelica 3.2.3	Modelica 3.2.2
enableNoise	=globalSeed.enableNoise	=true

---

block Blocks.Math.Log

Component	Modelica 3.2.3	Modelica 3.2.2
base	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
y = Modelica323.Math.log(u)/Modelica323.Math.log(base);	y = Modelica322.Math.log(u);

---

block Blocks.Math.RectangularToPolar

Component	Modelica 3.2.3	Modelica 3.2.2
y_arg	unit="rad"

---

block Blocks.Math.PolarToRectangular

Component	Modelica 3.2.3	Modelica 3.2.2
u_arg	unit="rad"

---

block Blocks.Math.ContinuousMean

Component	Modelica 3.2.3	Modelica 3.2.2
t_eps	min=100*Modelica323.Constants.eps	min=0.0

---

block Blocks.Math.Variance

Component	Modelica 3.2.3	Modelica 3.2.2
t_eps	min=100*Modelica323.Constants.eps	min=0.0

---

block Blocks.Math.StandardDeviation

Component	Modelica 3.2.3	Modelica 3.2.2
t_eps	min=100*Modelica323.Constants.eps	min=0.0

---

block Blocks.Math.Harmonic

Component	Modelica 3.2.3	Modelica 3.2.2
sin1	Blocks.Sources.Cosine	Blocks.Sources.Sine
y_arg	unit="rad"
useConjugateComplex	Present
gain	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(rectangularToPolar.y_abs, y_rms);
	connect(rectangularToPolar.y_arg, y_arg);
connect(sin1.y, product1.u[1]); ... connect(sin2.y, product2.u[2]);
connect(rectangularToPolar.y_arg, gain.u); connect(gain.y, y_arg);

---

block Blocks.Nonlinear.Limiter

Component	Modelica 3.2.3	Modelica 3.2.2
homotopyType	Present
simplifiedExpr	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
assert(uMax >= uMin, "Limiter: Limits must be consistent. However, uMax (=" + String(uMax) +                        ") < uMin (=" + String(uMin) + ")");
simplifiedExpr = (if homotopyType == Types.LimiterHomotopy.Linear then u                     else if homotopyType == Types.LimiterHomotopy.UpperLimit then uMax                     else if homotopyType == Types.LimiterHomotopy.LowerLimit then uMin                     else 0);
if strict then
if homotopyType == Types.LimiterHomotopy.NoHomotopy then	y = homotopy(actual = smooth(0, noEvent(if u > uMax then uMax else if u < uMin then uMin else u)), simplified=u);
y = smooth(0, noEvent(if u > uMax then uMax else if u < uMin then uMin else u));
else
y = homotopy(actual = smooth(0, noEvent(if u > uMax then uMax else if u < uMin then uMin else u)), simplified=simplifiedExpr);	y = homotopy(actual = smooth(0,if u > uMax then uMax else if u < uMin then uMin else u), simplified=u);
end if;
else if homotopyType == Types.LimiterHomotopy.NoHomotopy then y = smooth(0,if u > uMax then uMax else if u < uMin then uMin else u); else y = homotopy(actual = smooth(0,if u > uMax then uMax else if u < uMin then uMin else u),                        simplified=simplifiedExpr); end if; end if;

---

block Blocks.Nonlinear.VariableLimiter

Component	Modelica 3.2.3	Modelica 3.2.2
homotopyType	Present
ySimplified	Present
simplifiedExpr	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
assert(limit1 >= limit2, "Input signals are not consistent: limit1 < limit2");
simplifiedExpr = (if homotopyType == Types.VariableLimiterHomotopy.Linear then u                     else if homotopyType == Types.VariableLimiterHomotopy.Fixed then ySimplified                     else 0);
if strict then
if homotopyType == Types.VariableLimiterHomotopy.NoHomotopy then	y = homotopy(actual = smooth(0, noEvent(if u > limit1 then limit1 else if u < limit2 then limit2 else u)), simplified=u);
y = smooth(0, noEvent(if u > limit1 then limit1 else if u < limit2 then limit2 else u));
else
y = homotopy(actual = smooth(0, noEvent(if u > limit1 then limit1 else if u < limit2 then limit2 else u)), simplified=simplifiedExpr);	y = homotopy(actual = smooth(0,if u > limit1 then limit1 else if u < limit2 then limit2 else u), simplified=u);
end if;
else if homotopyType == Types.VariableLimiterHomotopy.NoHomotopy then y = smooth(0,if u > limit1 then limit1 else if u < limit2 then limit2 else u); else y = homotopy(actual = smooth(0,if u > limit1 then limit1 else if u < limit2 then limit2 else u),                        simplified=simplifiedExpr); end if; end if;

---

block Blocks.Nonlinear.SlewRateLimiter

Component	Modelica 3.2.3	Modelica 3.2.2
Rising	Real	SIunits.DampingCoefficient
Falling	Real	SIunits.DampingCoefficient
initType	Present
y_start	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial equation
if initType == Modelica323.Blocks.Types.Init.SteadyState then
y = u;
elseif initType == Modelica323.Blocks.Types.Init.InitialState or initType ==   Modelica323.Blocks.Types.Init.InitialOutput then y = y_start; end if;
equation   if strict then
der(y) = smooth(1, (if noEvent(val<Falling) then Falling else if noEvent(val>Rising) then Rising else val));	der(y) = smooth(1,noEvent(if val<Falling then Falling else if val>Rising then Rising else val));
else ...

---

block Blocks.Nonlinear.VariableDelay

Component	Modelica 3.2.3	Modelica 3.2.2
delayMax	SIunits.Duration	Real

---

block Blocks.Sources.Clock

Component	Modelica 3.2.3	Modelica 3.2.2
offset		Present
startTime		Present

---

block Blocks.Sources.Ramp

Component	Modelica 3.2.3	Modelica 3.2.2
offset		Present
startTime		Present

---

block Blocks.Sources.Sine

Component	Modelica 3.2.3	Modelica 3.2.2
offset		Present
startTime		Present

---

block Blocks.Sources.Cosine

Component	Modelica 3.2.3	Modelica 3.2.2
offset		Present
startTime		Present

---

block Blocks.Sources.ExpSine

Component	Modelica 3.2.3	Modelica 3.2.2
offset		Present
startTime		Present

---

block Blocks.Sources.Pulse

Component	Modelica 3.2.3	Modelica 3.2.2
offset		Present
startTime		Present

---

block Blocks.Sources.SawTooth

Component	Modelica 3.2.3	Modelica 3.2.2
offset		Present
startTime		Present

---

block Blocks.Sources.Trapezoid

Component	Modelica 3.2.3	Modelica 3.2.2
offset		Present
startTime		Present

---

block Blocks.Sources.KinematicPTP2

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... endTime = Tes;
motion_ref = time < endTime;	motion_ref = time <= endTime;
for i in 1:nout loop ...

---

block Blocks.Sources.TimeTable

Component	Modelica 3.2.3	Modelica 3.2.2
shiftTime	Present
offset		Present
startTime		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
if noEvent(size(table, 1) > 1) then	timeScaled := time/timeScale;
assert(not (table[1, 1] > 0.0 or table[1, 1] < 0.0), "The first point in time has to be set to 0, but is table[1,1] = " + String(table[1, 1])); end if;
when {time >= pre(nextEvent),initial()} then
(a,b,nextEventScaled,last) = getInterpolationCoefficients( table, offset, startTime/timeScale, timeScaled, last, 100*Modelica323.Constants.eps, shiftTime/timeScale);	(a,b,nextEventScaled,last) = getInterpolationCoefficients( table, offset, startTime/timeScale, timeScaled, last, 100*Modelica322.Constants.eps);
nextEvent = nextEventScaled*timeScale; ...
equation assert(size(table, 1) > 0, "No table values defined.");	equation y = a*timeScaled + b;
timeScaled = time/timeScale; y = a*timeScaled + b;

---

block Blocks.Sources.CombiTimeTable

Component	Modelica 3.2.3	Modelica 3.2.2
t_min	=t_minScaled*timeScale
		fixed=false
t_max	=t_maxScaled*timeScale
		fixed=false
t_minScaled	=Internal.getTimeTableTmin(tableID)
		fixed=false
t_maxScaled	=Internal.getTimeTableTmax(tableID)
		fixed=false
tableID	parameter
	=Modelica323.Blocks.Types.ExternalCombiTimeTable(if tableOnFile then tableName else "NoName", if tableOnFile and fileName <> "NoName" and not Modelica323.Utilities.Strings.isEmpty(fileName) then fileName else "NoName", table, startTime/timeScale, columns, smoothness, extrapolation, shiftTime/timeScale, if smoothness == Modelica323.Blocks.Types.Smoothness.LinearSegments then timeEvents elseif smoothness == Modelica323.Blocks.Types.Smoothness.ConstantSegments then Modelica323.Blocks.Types.TimeEvents.Always else Modelica323.Blocks.Types.TimeEvents.NoTimeEvents, if tableOnFile then verboseRead else false)	=Modelica322.Blocks.Types.ExternalCombiTimeTable(if tableOnFile then tableName else "NoName", if tableOnFile and fileName <> "NoName" and not Modelica322.Utilities.Strings.isEmpty(fileName) then fileName else "NoName", table, startTime/timeScale, columns, smoothness, extrapolation)
shiftTime	Present
timeEvents	Present
verboseExtrapolation	Present
tableOnFileRead		Present
DBL_MAX		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	initial algorithm
if tableOnFile then
	tableOnFileRead = readTableData(tableID, false, verboseRead); else tableOnFileRead = 1.; end if; t_minScaled = getTableTimeTmin(tableID, tableOnFileRead); t_maxScaled = getTableTimeTmax(tableID, tableOnFileRead); t_min = t_minScaled*timeScale; t_max = t_maxScaled*timeScale; equation   if tableOnFile then
assert(tableName <> "NoName",         "tableOnFile = true and no table name given"); ... end if;
if verboseExtrapolation and (extrapolation == Modelica323.Blocks.Types.Extrapolation.LastTwoPoints    or extrapolation == Modelica323.Blocks.Types.Extrapolation.HoldLastPoint)    then assert(noEvent(time >= t_min), " Extrapolation warning: Time (=" + String(time) + ") must be greater or equal than the minimum abscissa value t_min (=" + String(t_min) + ") defined in the table. ", level=AssertionLevel.warning); assert(noEvent(time <= t_max), " Extrapolation warning: Time (=" + String(time) + ") must be less or equal than the maximum abscissa value t_max (=" + String(t_max) + ") defined in the table. ", level=AssertionLevel.warning); end if;
timeScaled = time/timeScale;
when {time >= pre(nextTimeEvent), initial()} then
nextTimeEventScaled = Internal.getNextTimeEvent(tableID, timeScaled);	nextTimeEventScaled = getNextTimeEvent(tableID, timeScaled, tableOnFileRead);
nextTimeEvent = if nextTimeEventScaled < Modelica323.Constants.inf then nextTimeEventScaled*timeScale else Modelica323.Constants.inf;	if (nextTimeEventScaled < DBL_MAX) then
	nextTimeEvent = nextTimeEventScaled*timeScale; else nextTimeEvent = DBL_MAX; end if;
end when; ... for i in 1:nout loop
y[i] = p_offset[i] + Internal.getTimeTableValueNoDer(tableID, i, timeScaled, nextTimeEventScaled, pre(nextTimeEventScaled));	y[i] = p_offset[i] + getTableValueNoDer(tableID, i, timeScaled, nextTimeEventScaled, pre(nextTimeEventScaled), tableOnFileRead);
end for; ... for i in 1:nout loop
y[i] = p_offset[i] + Internal.getTimeTableValue(tableID, i, timeScaled, nextTimeEventScaled, pre(nextTimeEventScaled));	y[i] = p_offset[i] + getTableValue(tableID, i, timeScaled, nextTimeEventScaled, pre(nextTimeEventScaled), tableOnFileRead);
end for; ...

---

block Blocks.Sources.BooleanPulse

Component	Modelica 3.2.3	Modelica 3.2.2
pulseStart	Present
pulsStart		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial equation
pulseStart = startTime;	pulsStart = startTime;
equation   when sample(startTime, period) then
pulseStart = time;	pulsStart = time;
end when;
y = time >= pulseStart and time < pulseStart + Twidth;	y = time >= pulsStart and time < pulsStart + Twidth;

---

block Blocks.Sources.BooleanTable

Component	Modelica 3.2.3	Modelica 3.2.2
extrapolation	Present
startTime	Present
shiftTime	Present
combiTimeTable	Present
realToBoolean	Present
nextTime		Present
index		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial algorithm
isValidTable(table);	(index,nextTime,y) := getFirstIndex(table,time,startValue);
equation assert(extrapolation <> Modelica323.Blocks.Types.Extrapolation.LastTwoPoints, "Unsuitable extrapolation setting.");	algorithm
connect(combiTimeTable.y[1], realToBoolean.u);	when time >= pre(nextTime) and n > 0 then
connect(realToBoolean.y, y);	if index < n then
	index = index + 1; nextTime = table[index]; y = not y; elseif index == n then index = index + 1; y = not y; end if; end when;

---

block Blocks.Sources.IntegerTable

Component	Modelica 3.2.3	Modelica 3.2.2
extrapolation	Present
startTime	Present
shiftTime	Present
combiTimeTable	Present
realToInteger	Present
nextTime		Present
index		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial algorithm
isValidTable(table);	(index,nextTime,y) := getFirstIndex(table, time);
equation assert(n > 0, "No table values defined.");	equation assert(size(table, 1) > 0, "No table values defined.");
assert(extrapolation <> Modelica323.Blocks.Types.Extrapolation.LastTwoPoints, "Unsuitable extrapolation setting.");	when time >= pre(nextTime) then
connect(combiTimeTable.y[1], realToInteger.u);	y = integer(table[pre(index), 2]);
connect(realToInteger.y, y);	index = pre(index) + 1;
	nextTime = if index <= n then table[index, 1] else pre(nextTime) - 1; end when;

---

block Blocks.Tables.CombiTable1D

Component	Modelica 3.2.3	Modelica 3.2.2
tableID	parameter
	=Modelica323.Blocks.Types.ExternalCombiTable1D(if tableOnFile then tableName else "NoName", if tableOnFile and fileName <> "NoName" and not Modelica323.Utilities.Strings.isEmpty(fileName) then fileName else "NoName", table, columns, smoothness, extrapolation, if tableOnFile then verboseRead else false)	=Modelica322.Blocks.Types.ExternalCombiTable1D(if tableOnFile then tableName else "NoName", if tableOnFile and fileName <> "NoName" and not Modelica322.Utilities.Strings.isEmpty(fileName) then fileName else "NoName", table, columns, smoothness)
extrapolation	Present
verboseExtrapolation	Present
u_min	Present
u_max	Present
tableOnFileRead		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	initial algorithm
if tableOnFile then
	tableOnFileRead = readTableData(tableID, false, verboseRead); else tableOnFileRead = 1.; end if; equation   if tableOnFile then
assert(tableName <> "NoName",         "tableOnFile = true and no table name given"); ... end if;
if verboseExtrapolation and (extrapolation == Modelica323.Blocks.Types.Extrapolation.LastTwoPoints    or extrapolation == Modelica323.Blocks.Types.Extrapolation.HoldLastPoint)    then for i in 1:n loop assert(noEvent(u[i] >= u_min), " Extrapolation warning: The value u[" + String(i) +"] (=" + String(u[i]) + ") must be greater or equal than the minimum abscissa value u_min (=" + String(u_min) + ") defined in the table. ", level=AssertionLevel.warning); assert(noEvent(u[i] <= u_max), " Extrapolation warning: The value u[" + String(i) +"] (=" + String(u[i]) + ") must be less or equal than the maximum abscissa value u_max (=" + String(u_max) + ") defined in the table. ", level=AssertionLevel.warning); end for; end if;
if smoothness == Modelica323.Blocks.Types.Smoothness.ConstantSegments then
for i in 1:n loop
y[i] = Internal.getTable1DValueNoDer(tableID, i, u[i]);	y[i] = getTableValueNoDer(tableID, i, u[i], tableOnFileRead);
end for; ... for i in 1:n loop
y[i] = Internal.getTable1DValue(tableID, i, u[i]);	y[i] = getTableValue(tableID, i, u[i], tableOnFileRead);
end for; ...

---

block Blocks.Tables.CombiTable1Ds

Component	Modelica 3.2.3	Modelica 3.2.2
tableID	parameter
	=Modelica323.Blocks.Types.ExternalCombiTable1D(if tableOnFile then tableName else "NoName", if tableOnFile and fileName <> "NoName" and not Modelica323.Utilities.Strings.isEmpty(fileName) then fileName else "NoName", table, columns, smoothness, extrapolation, if tableOnFile then verboseRead else false)	=Modelica322.Blocks.Types.ExternalCombiTable1D(if tableOnFile then tableName else "NoName", if tableOnFile and fileName <> "NoName" and not Modelica322.Utilities.Strings.isEmpty(fileName) then fileName else "NoName", table, columns, smoothness)
extrapolation	Present
verboseExtrapolation	Present
u_min	Present
u_max	Present
tableOnFileRead		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	initial algorithm
if tableOnFile then
	tableOnFileRead = readTableData(tableID, false, verboseRead); else tableOnFileRead = 1.; end if; equation   if tableOnFile then
assert(tableName <> "NoName",         "tableOnFile = true and no table name given"); ... end if;
if verboseExtrapolation and (extrapolation == Modelica323.Blocks.Types.Extrapolation.LastTwoPoints    or extrapolation == Modelica323.Blocks.Types.Extrapolation.HoldLastPoint)    then assert(noEvent(u >= u_min), " Extrapolation warning: The value u (=" + String(u) + ") must be greater or equal than the minimum abscissa value u_min (=" + String(u_min) + ") defined in the table. ", level=AssertionLevel.warning); assert(noEvent(u <= u_max), " Extrapolation warning: The value u (=" + String(u) + ") must be less or equal than the maximum abscissa value u_max (=" + String(u_max) + ") defined in the table. ", level=AssertionLevel.warning); end if;
if smoothness == Modelica323.Blocks.Types.Smoothness.ConstantSegments then
for i in 1:nout loop
y[i] = Internal.getTable1DValueNoDer(tableID, i, u);	y[i] = getTableValueNoDer(tableID, i, u, tableOnFileRead);
end for; ... for i in 1:nout loop
y[i] = Internal.getTable1DValue(tableID, i, u);	y[i] = getTableValue(tableID, i, u, tableOnFileRead);
end for; ...

---

block Blocks.Tables.CombiTable2D

Component	Modelica 3.2.3	Modelica 3.2.2
tableOnFile		Present
table		Present
tableName		Present
fileName		Present
verboseRead		Present
smoothness		Present
tableID		Present
tableOnFileRead		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
if verboseExtrapolation and (extrapolation == Modelica323.Blocks.Types.Extrapolation.LastTwoPoints or extrapolation == Modelica323.Blocks.Types.Extrapolation.HoldLastPoint) then	initial algorithm
assert(noEvent(u1 >= u_min[1]), " Extrapolation warning: The value u1 (=" + String(u1) + ") must be greater or equal than the minimum abscissa value u_min[1] (=" + String(u_min[1]) + ") defined in the table. ", level=AssertionLevel.warning);	if tableOnFile then
assert(noEvent(u1 <= u_max[1]), " Extrapolation warning: The value u1 (=" + String(u1) + ") must be less or equal than the maximum abscissa value u_max[1] (=" + String(u_max[1]) + ") defined in the table. ", level=AssertionLevel.warning);	tableOnFileRead = readTableData(tableID, false, verboseRead);
assert(noEvent(u2 >= u_min[2]), " Extrapolation warning: The value u2 (=" + String(u2) + ") must be greater or equal than the minimum abscissa value u_min[2] (=" + String(u_min[2]) + ") defined in the table. ", level=AssertionLevel.warning); assert(noEvent(u2 <= u_max[2]), " Extrapolation warning: The value u2 (=" + String(u2) + ") must be less or equal than the maximum abscissa value u_max[2] (=" + String(u_max[2]) + ") defined in the table. ", level=AssertionLevel.warning); end if; if smoothness == Modelica323.Blocks.Types.Smoothness.ConstantSegments then y = Internal.getTable2DValueNoDer(tableID, u1, u2);
else
y = Internal.getTable2DValue(tableID, u1, u2);	tableOnFileRead = 1.;
end if;
	equation   if tableOnFile then assert(tableName <> "NoName",         "tableOnFile = true and no table name given"); else assert(size(table, 1) > 0 and size(table, 2) > 0,         "tableOnFile = false and parameter table is an empty matrix"); end if; if smoothness == Modelica322.Blocks.Types.Smoothness.ConstantSegments then y = getTableValueNoDer(tableID, u1, u2, tableOnFileRead); else y = getTableValue(tableID, u1, u2, tableOnFileRead); end if;

---

block ComplexBlocks.Interfaces.ComplexSI2SO

Component	Modelica 3.2.3	Modelica 3.2.2
u1Internal	=(if useConjugateInput1 then Modelica323.ComplexMath.conj(u1) else u1)	=(if useConjugateInput1 then Modelica322.ComplexMath.conj(u1) else u2)

---

block ComplexBlocks.ComplexMath.Feedback

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
y = (if useConjugateInput1 then Modelica323.ComplexMath.conj(u1) else u1) - ( if useConjugateInput2 then Modelica323.ComplexMath.conj(u2) else u2);	y = (if useConjugateInput1 then Modelica322.ComplexMath.conj(u1) else u1) - ( if useConjugateInput1 then Modelica322.ComplexMath.conj(u2) else u2);

---

block ComplexBlocks.ComplexMath.PolarToComplex

Component	Modelica 3.2.3	Modelica 3.2.2
phi	unit="rad"

---

block ComplexBlocks.ComplexMath.ComplexToPolar

Component	Modelica 3.2.3	Modelica 3.2.2
phi	unit="rad"

---

block ComplexBlocks.Sources.ComplexRotatingPhasor

Component	Modelica 3.2.3	Modelica 3.2.2
phi	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
phi = w*time + phi0;	y = magnitude*Modelica322.ComplexMath.exp(Complex(0, w*time + phi0));
y = magnitude*Modelica323.ComplexMath.exp(Complex(0, phi));

---

block ComplexBlocks.Sources.LogFrequencySweep

Component	Modelica 3.2.3	Modelica 3.2.2
wMin	final min=eps
		min=eps
wMax	final min=eps
		min=(1 + eps)*wMin
startTime	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
y = if time < startTime then wMin else if time < (startTime + max(duration,eps)) then 10^(log10(wMin) + (log10(wMax) - log10(wMin))*min(1, (time-startTime)/max(duration,eps))) else wMax;	y = 10^(log10(wMin) + (log10(wMax) - log10(wMin))*min(1, time/max(duration,eps)));

---

model StateGraph.Examples.ExecutionPaths

Component	Modelica 3.2.3	Modelica 3.2.2
setCondition	y=time >= 7	y=time > 7

---

model StateGraph.Examples.ShowCompositeStep

Component	Modelica 3.2.3	Modelica 3.2.2
setCondition	y=time >= 7	y=time > 7

---

model StateGraph.Examples.Utilities.CompositeStep1

Component	Modelica 3.2.3	Modelica 3.2.2
transition1	condition=time >= 8	condition=time > 8
transition2	condition=time >= 4	condition=time > 4

---

model Electrical.Analog.Examples.CauerLowPassSC

Component	Modelica 3.2.3	Modelica 3.2.2
R4	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rn
R5	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rn
R8	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rn
R9	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rn
R1	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rp
R2	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rp
R3	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rp
Rp1	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rp
R7	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rp
R10	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rp
R11	Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Electrical.Analog.Examples.CauerLowPassSC.Rp

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(V.p, Ground1.p);
connect(R4.n, n5);	connect(R4.n2, n5);
connect(Op1.out, R4.p);	connect(Op1.out, R4.n1);
connect(R5.p, p1);	connect(R5.n1, p1);
connect(R5.n, n5);	connect(R5.n2, n5);
connect(p3, R8.p);	connect(p3, R8.n1);
connect(R8.n, n9);	connect(R8.n2, n9);
connect(Op3.out, R9.p);	connect(Op3.out, R9.n1);
connect(R9.n, n10);	connect(R9.n2, n10);
connect(R1.p, V.n);	connect(R1.n1, V.n);
connect(R1.n, n1);	connect(R1.n2, n1);
connect(R2.n, n2);	connect(R2.n2, n2);
connect(R2.p, n6);	connect(R2.n1, n6);
connect(R3.p, n3);	connect(R3.n1, n3);
connect(R3.n, n4);	connect(R3.n2, n4);
connect(Rp1.n, n8);	connect(Rp1.n2, n8);
connect(Rp1.p, n11);	connect(Rp1.n1, n11);
connect(Op2.out, R7.p);	connect(Op2.out, R7.n1);
connect(R7.n, n7);	connect(R7.n2, n7);
connect(R10.p, Op4.out);	connect(R10.n1, Op4.out);
connect(R10.n, n14);	connect(R10.n2, n14);
connect(R11.n, n12);	connect(R11.n2, n12);
connect(R11.p, p4);	connect(R11.n1, p4);

---

model Electrical.Analog.Examples.CharacteristicIdealDiodes

Component	Modelica 3.2.3	Modelica 3.2.2
R1	R=1e-3	R=1.e-3
R2	R=1e-3	R=1.e-3
R3	R=1e-3	R=1.e-3

---

model Electrical.Analog.Examples.CharacteristicThyristors

Component	Modelica 3.2.3	Modelica 3.2.2
R3	R=1e-3	R=1.e-3
R1	R=1e-3	R=1.e-3
R2	R=1e-3	R=1.e-3
R4	R=1e-3	R=1.e-3

---

model Electrical.Analog.Examples.HeatingMOSInverter

Component	Modelica 3.2.3	Modelica 3.2.2
V	duration=1e-2	duration=1.e-2

---

model Electrical.Analog.Examples.HeatingNPN_OrGate

Component	Modelica 3.2.3	Modelica 3.2.2
T1	Is=1e-14	Is=1.e-14
	Gbc=1e-12	Gbc=1.e-12
	Gbe=1e-12	Gbe=1.e-12
T2	Is=1e-14	Is=1.e-14
	Gbc=1e-12	Gbc=1.e-12
	Gbe=1e-12	Gbe=1.e-12

---

model Electrical.Analog.Examples.NandGate

Component	Modelica 3.2.3	Modelica 3.2.2
VIN1	falling=1e-9	falling=1.e-9
VIN2	falling=1e-9	falling=1.e-9

---

model Electrical.Analog.Examples.OpAmps.InvertingSchmittTrigger

Component	Modelica 3.2.3	Modelica 3.2.2
opAmp	homotopyType=Modelica323.Blocks.Types.LimiterHomotopy.LowerLimit

---

model Electrical.Analog.Examples.OpAmps.SchmittTrigger

Component	Modelica 3.2.3	Modelica 3.2.2
opAmp	homotopyType=Modelica323.Blocks.Types.LimiterHomotopy.UpperLimit

---

model Electrical.Analog.Examples.OpAmps.SignalGenerator

Component	Modelica 3.2.3	Modelica 3.2.2
Vns	=-Vps	=-15
opAmp1	strict=false
	homotopyType=Modelica323.Blocks.Types.LimiterHomotopy.UpperLimit
opAmp2	strict=false

---

model Electrical.Analog.Basic.EMF

Component	Modelica 3.2.3	Modelica 3.2.2
internalSupport	tau=-tau	tau=-flange.tau
tau	Present
tauElectrical	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... k*w = v;
tau = -k*i;	flange.tau = -k*i;
tauElectrical = -tau; tau = flange.tau;
connect(internalSupport.flange, support); ...

---

model Electrical.Analog.Basic.TranslationalEMF

Component	Modelica 3.2.3	Modelica 3.2.2
internalSupport	f=-f	f=-flange.f
f	Present
fElectrical	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... k*vel = v;
f = -k*i;	flange.f = -k*i;
fElectrical = -f; f = flange.f;
connect(internalSupport.flange, support); ...

---

model Electrical.Analog.Basic.OpAmpDetailed

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... i_4 = I2 + v_4/Rcm;
der(q_fr1) = 2.0*pi*fp2*(v_in - q_fr1);	der(q_fr1) = 2.0*Pi*fp2*(v_in - q_fr1);
q_fr2 + (1.0/(2.0*pi*fp3))*der(q_fr2) = q_fr1 + (1.0/(2.0*pi*fz))*der(q_fr1);	q_fr2 + (1.0/(2.0*Pi*fp3))*der(q_fr2) = q_fr1 + (1.0/(2.0*Pi*fz))*der(q_fr1);
der(q_fr3) = 2.0*pi*fp4*(q_fr2 - q_fr3);	der(q_fr3) = 2.0*Pi*fp4*(q_fr2 - q_fr3);
q_sum = Avd0_val*q_fr3 + Avcm_val*(v_3 + v_4);
q_sum_help = FCNq_sum_limit(       q_sum,       q_fp1,       v_pos,       v_neg,       vcp_abs,       vcm_abs);
der(q_fp1) = 2.0*pi*fp1*(q_sum_help - q_fp1);	der(q_fp1) = 2.0*Pi*fp1*(q_sum_help - q_fp1);
der(x) = (q_fp1 - v_source)/Ts; ...

---

model Electrical.Analog.Ideal.IdealCommutingSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	=1e-5	=1.E-5
Goff	=1e-5	=1.E-5

---

model Electrical.Analog.Ideal.IdealIntermediateSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	=1e-5	=1.E-5
Goff	=1e-5	=1.E-5

---

model Electrical.Analog.Ideal.ControlledIdealCommutingSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	=1e-5	=1.E-5
Goff	=1e-5	=1.E-5

---

model Electrical.Analog.Ideal.ControlledIdealIntermediateSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	=1e-5	=1.E-5
Goff	=1e-5	=1.E-5

---

model Electrical.Analog.Ideal.IdealOpAmpLimited

Component	Modelica 3.2.3	Modelica 3.2.2
s	start=0

---

model Electrical.Analog.Ideal.IdealizedOpAmpLimted

Component	Modelica 3.2.3	Modelica 3.2.2
strict	Present
homotopyType	Present
simplifiedExpr	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... in_n.i = 0;
simplifiedExpr = (if homotopyType == Modelica323.Blocks.Types.LimiterHomotopy.Linear then V0*v_in else if homotopyType == Modelica323.Blocks.Types.LimiterHomotopy.UpperLimit then vps else if homotopyType == Modelica323.Blocks.Types.LimiterHomotopy.LowerLimit then vns else 0);	v_out = smooth(0, min(Vps, max(Vns, V0*v_in)));
if strict then if homotopyType == Modelica323.Blocks.Types.LimiterHomotopy.NoHomotopy then v_out = smooth(0, noEvent(if V0*v_in>vps then vps else if V0*v_in<vns then vns else V0*v_in)); else v_out = homotopy(actual = smooth(0, noEvent(if V0*v_in>vps then vps else if V0*v_in<vns then vns else V0*v_in)),                            simplified=simplifiedExpr); end if; else if homotopyType == Modelica323.Blocks.Types.LimiterHomotopy.NoHomotopy then v_out = smooth(0, if V0*v_in>vps then vps else if V0*v_in<vns then vns else V0*v_in); else v_out = homotopy(actual = smooth(0, if V0*v_in>vps then vps else if V0*v_in<vns then vns else V0*v_in),                            simplified=simplifiedExpr); end if; end if;

---

model Electrical.Analog.Ideal.IdealTriac

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	=1e-5	=1.e-5
Goff	=1e-5	=1.e-5

---

model Electrical.Analog.Ideal.AD_Converter

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial algorithm	initial equation
for i in 1:N loop ...

---

connector Electrical.Analog.Interfaces.Pin

Component	Modelica 3.2.3	Modelica 3.2.2
v	SIunits.ElectricPotential	SIunits.Voltage

---

connector Electrical.Analog.Interfaces.PositivePin

Component	Modelica 3.2.3	Modelica 3.2.2
v	SIunits.ElectricPotential	SIunits.Voltage

---

connector Electrical.Analog.Interfaces.NegativePin

Component	Modelica 3.2.3	Modelica 3.2.2
v	SIunits.ElectricPotential	SIunits.Voltage

---

model Electrical.Analog.Interfaces.ConditionalHeatPort

Component	Modelica 3.2.3	Modelica 3.2.2
heatPort	final T=T_heatPort
	final Q_flow=-LossPower
		T(start=T) = T_heatPort
		Q_flow=-LossPower

---

model Electrical.Analog.Interfaces.IdealSemiconductor

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	=1e-5	=1.E-5
Goff	=1e-5	=1.E-5

---

model Electrical.Analog.Interfaces.IdealSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	=1e-5	=1.E-5
Goff	=1e-5	=1.E-5

---

model Electrical.Analog.Lines.OLine

Component	Modelica 3.2.3	Modelica 3.2.2
R	R=rm	R=fill(r*length/(N + 1), N + 1)
L	L=lm	L=fill(l*length/(N + 1), N + 1)
rm	Present
lm	Present

---

model Electrical.Analog.Lines.M_OLine

Component	Modelica 3.2.3	Modelica 3.2.2
g	={8.05e-6,3.42e-5,2.91e-5,1.76e-6,9.16e-6,7.12e-6,2.43e-5,5.93e-6,4.19e-5,6.64e-6}	={8.05e-6,3.42e-5,2 - 91e-5,1.76e-6,9.16e-6,7.12e-6,2.43e-5,5.93e-6,4.19e-5,6.64e-6}

---

model Electrical.Analog.Lines.ULine

Component	Modelica 3.2.3	Modelica 3.2.2
R	R=rm	R=fill(r*length/(N + 1), N + 1)
rm	Present

---

model Electrical.Analog.Semiconductors.Diode

Component	Modelica 3.2.3	Modelica 3.2.2
Ids	=1e-6	=1.e-6
R	=1e8	=1.e8

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
i = smooth(1, Ids*(exlin(v/Vt, Maxexp) - 1) + v/R);	i = smooth(1,(if (v/Vt > Maxexp) then Ids*(exp(Maxexp)*(1 + v/Vt - Maxexp) - 1) + v/R else Ids*(exp(v/Vt) - 1) + v/R));
LossPower = v*i;

---

model Electrical.Analog.Semiconductors.Diode2

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... LossPower=i*v;
assert(Bv>0, "Bv must be greater than zero");	assert(Bv>0, "Bv must be greater than zero", AssertionLevel.error);
assert(Vf>0, "Vf must be greater than zero");	assert(Vf>0, "Vf must be greater than zero", AssertionLevel.error);
assert(Vt>0, "Vt must be greater than zero");	assert(Vt>0, "Vt must be greater than zero", AssertionLevel.error);

---

model Electrical.Analog.Semiconductors.ZDiode

Component	Modelica 3.2.3	Modelica 3.2.2
Ids	=1e-6	=1.e-6
R	=1e8	=1.e8
maxexp		Present

---

model Electrical.Analog.Semiconductors.PMOS

Component	Modelica 3.2.3	Modelica 3.2.2
RDS	=1e7	=1.e+7

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... assert(W + dW > 0, "PMOS: Effective width must be positive");
gds = if (RDS < 1e-20 and RDS > -1e-20) then 1e20 else 1/RDS;	gds = if (RDS < 1.e-20 and RDS > -1.e-20) then 1.e20 else 1/RDS;
v = Beta*(W + dW)/(L + dL); ...

---

model Electrical.Analog.Semiconductors.NMOS

Component	Modelica 3.2.3	Modelica 3.2.2
RDS	=1e7	=1.e+7

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... assert(W + dW > 0, "NMOS: Effective width must be positive");
gds = if (RDS < 1e-20 and RDS > -1e-20) then 1e20 else 1/RDS;	gds = if (RDS < 1.e-20 and RDS > -1.e-20) then 1.e20 else 1/RDS;
v = Beta*(W + dW)/(L + dL); ...

---

model Electrical.Analog.Semiconductors.NPN

Component	Modelica 3.2.3	Modelica 3.2.2
Is	=1e-16	=1.e-16
vbc	SIunits.Voltage	Real
		protected
vbe	SIunits.Voltage	Real
		protected
qbk		protected
ibc	SIunits.Current	Real
		protected
ibe	SIunits.Current	Real
		protected
cbc	SIunits.Capacitance	Real
		protected
cbe	SIunits.Capacitance	Real
		protected
Capcje	SIunits.Capacitance	Real
		protected
Capcjc	SIunits.Capacitance	Real
		protected
ExMin		Present
ExMax		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
...
equation vbc = B.v - C.v;	equation ExMin = exp(EMin);
	ExMax = exp(EMax); vbc = B.v - C.v;
vbe = B.v - E.v;
qbk = 1 - vbc*Vak;
ibc = smooth(1, Is*(exlin2(vbc/Vt, EMin, EMax) - 1) + vbc*Gbc);	ibc = smooth(1,if (vbc/Vt < EMin) then Is*(ExMin*(vbc/Vt - EMin + 1) - 1) + vbc*Gbc else if (vbc/Vt > EMax) then Is*(ExMax*(vbc/Vt - EMax + 1) - 1) + vbc* Gbc else Is*(exp(vbc/Vt) - 1) + vbc*Gbc);
ibe = smooth(1, Is*(exlin2(vbe/Vt, EMin, EMax) - 1) + vbe*Gbe);	ibe = smooth(1,if (vbe/Vt < EMin) then Is*(ExMin*(vbe/Vt - EMin + 1) - 1) + vbe*Gbe else if (vbe/Vt > EMax) then Is*(ExMax*(vbe/Vt - EMax + 1) - 1) + vbe* Gbe else Is*(exp(vbe/Vt) - 1) + vbe*Gbe);
Capcjc = smooth(1, Cjc*powlin(vbc/Phic, Mc));	Capcjc = smooth(1,(if (vbc/Phic > 0) then Cjc*(1 + Mc*vbc/Phic) else Cjc*pow(1 - vbc /Phic, -Mc)));
Capcje = smooth(1, Cje*powlin(vbe/Phie, Me));	Capcje = smooth(1,(if (vbe/Phie > 0) then Cje*(1 + Me*vbe/Phie) else Cje*pow(1 - vbe /Phie, -Me)));
cbc = smooth(1, Taur*Is/Vt*exlin2(vbc/Vt, EMin, EMax) + Capcjc);	cbc = smooth(1,(if (vbc/Vt < EMin) then Taur*Is/Vt*ExMin*(vbc/Vt - EMin + 1) + Capcjc else if (vbc/Vt > EMax) then Taur*Is/Vt*ExMax*(vbc/Vt - EMax + 1) + Capcjc else Taur*Is/Vt*exp(vbc/Vt) + Capcjc));
cbe = smooth(1, Tauf*Is/Vt*exlin2(vbe/Vt, EMin, EMax) + Capcje);	cbe = smooth(1,(if (vbe/Vt < EMin) then Tauf*Is/Vt*ExMin*(vbe/Vt - EMin + 1) + Capcje else if (vbe/Vt > EMax) then Tauf*Is/Vt*ExMax*(vbe/Vt - EMax + 1) + Capcje else Tauf*Is/Vt*exp(vbe/Vt) + Capcje));
C.i = (ibe - ibc)*qbk - ibc/Br - cbc*der(vbc) + Ccs*der(C.v); ...

---

model Electrical.Analog.Semiconductors.PNP

Component	Modelica 3.2.3	Modelica 3.2.2
Is	=1e-16	=1.e-16
vbc	SIunits.Voltage	Real
		protected
vbe	SIunits.Voltage	Real
		protected
qbk		protected
ibc	SIunits.Current	Real
		protected
ibe	SIunits.Current	Real
		protected
cbc	SIunits.Capacitance	Real
		protected
cbe	SIunits.Capacitance	Real
		protected
Capcje	SIunits.Capacitance	Real
		protected
Capcjc	SIunits.Capacitance	Real
		protected
ExMin		Present
ExMax		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	ExMin = exp(EMin); ExMax = exp(EMax);
vbc = C.v - B.v; ... qbk = 1 - vbc*Vak;
ibc = smooth(1, Is*(exlin2(vbc/Vt, EMin, EMax) - 1) + vbc*Gbc);	ibc = smooth(1,(if (vbc/Vt < EMin) then Is*(ExMin*(vbc/Vt - EMin + 1) - 1) + vbc*Gbc else if (vbc/Vt > EMax) then Is*(ExMax*(vbc/Vt - EMax + 1) - 1) + vbc* Gbc else Is*(exp(vbc/Vt) - 1) + vbc*Gbc));
ibe = smooth(1, Is*(exlin2(vbe/Vt, EMin, EMax) - 1) + vbe*Gbe);	ibe = smooth(1,(if (vbe/Vt < EMin) then Is*(ExMin*(vbe/Vt - EMin + 1) - 1) + vbe*Gbe else if (vbe/Vt > EMax) then Is*(ExMax*(vbe/Vt - EMax + 1) - 1) + vbe* Gbe else Is*(exp(vbe/Vt) - 1) + vbe*Gbe));
Capcjc = smooth(1, Cjc*powlin(vbc/Phic, Mc));	Capcjc = smooth(1,(if (vbc/Phic > 0) then Cjc*(1 + Mc*vbc/Phic) else Cjc*pow(1 - vbc /Phic, -Mc)));
Capcje = smooth(1, Cje*powlin(vbe/Phie, Me));	Capcje = smooth(1,if (vbe/Phie > 0) then Cje*(1 + Me*vbe/Phie) else Cje*pow(1 - vbe /Phie, -Me));
cbc = smooth(1, Taur*Is/Vt*exlin2(vbc/Vt, EMin, EMax) + Capcjc);	cbc = smooth(1,(if (vbc/Vt < EMin) then Taur*Is/Vt*ExMin*(vbc/Vt - EMin + 1) + Capcjc else if (vbc/Vt > EMax) then Taur*Is/Vt*ExMax*(vbc/Vt - EMax + 1) + Capcjc else Taur*Is/Vt*exp(vbc/Vt) + Capcjc));
cbe = smooth(1, Tauf*Is/Vt*exlin2(vbe/Vt, EMin, EMax) + Capcje);	cbe = smooth(1,(if (vbe/Vt < EMin) then Tauf*Is/Vt*ExMin*(vbe/Vt - EMin + 1) + Capcje else if (vbe/Vt > EMax) then Tauf*Is/Vt*ExMax*(vbe/Vt - EMax + 1) + Capcje else Tauf*Is/Vt*exp(vbe/Vt) + Capcje));
C.i = -((ibe - ibc)*qbk - ibc/Br - cbc*der(vbc) - Ccs*der(C.v)); ...

---

model Electrical.Analog.Semiconductors.HeatingDiode

Component	Modelica 3.2.3	Modelica 3.2.2
Ids	=1e-6	=1.e-6
R	=1e8	=1.e8
vt_t	SIunits.Voltage	SIunits.Temperature
q		Present
maxexp		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
assert(T_heatPort > 0,"Temperature must be positive");	assert( T_heatPort > 0,"temperature must be positive");
htemp = T_heatPort; ...

---

model Electrical.Analog.Semiconductors.HeatingNMOS

Component	Modelica 3.2.3	Modelica 3.2.2
RDS	=1e7	=1.e+7
kk2	=6e-4	=6.0e-4

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... assert(T_heatPort > 0,"Heating NMOS: Temperature must be positive");
gds = if (RDS < 1e-20 and RDS > -1e-20) then 1e20 else 1/RDS;	gds = if (RDS < 1.e-20 and RDS > -1.e-20) then 1.e20 else 1/RDS;
v = beta_t*(W + dW)/(L + dL); ...

---

model Electrical.Analog.Semiconductors.HeatingPMOS

Component	Modelica 3.2.3	Modelica 3.2.2
RDS	=1e7	=1.e+7

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... assert(T_heatPort > 0,"HeatingPMOS: Temperature must be positive");
gds = if (RDS < 1e-20 and RDS > -1e-20) then 1e20 else 1/RDS;	gds = if (RDS < 1.e-20 and RDS > -1.e-20) then 1.e20 else 1/RDS;
v = beta_t*(W + dW)/(L + dL); ...

---

model Electrical.Analog.Semiconductors.HeatingNPN

Component	Modelica 3.2.3	Modelica 3.2.2
Is	=1e-16	=1.e-16
EG	SIunits.Voltage	Real
vbc	SIunits.Voltage	Real
vbe	SIunits.Voltage	Real
ibc	SIunits.Current	Real
ibe	SIunits.Current	Real
cbc	SIunits.Capacitance	Real
cbe	SIunits.Capacitance	Real
Capcje	SIunits.Capacitance	Real
Capcjc	SIunits.Capacitance	Real
is_t	SIunits.Current	Real
vt_t	SIunits.Voltage	Real
q		Present
ExMin		Present
ExMax		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
assert(T_heatPort > 0,"Temperature must be positive");	assert( T_heatPort > 0,"temperature must be positive");
	ExMin = exp(EMin); ExMax = exp(EMax);
vbc = B.v - C.v; ... hexp = (T_heatPort/Tnom - 1)*EG/vt_t;
htempexp = smooth(1, exlin2(hexp, EMin, EMax));	htempexp = smooth(1,if (hexp < EMin) then ExMin*(hexp - EMin + 1) else if ( hexp > EMax) then ExMax*(hexp - EMax + 1) else exp(hexp));
is_t = Is*pow((T_heatPort/Tnom), XTI)*htempexp; ... vt_t = (k/q)*T_heatPort;
ibc = smooth(1, is_t*(exlin2(vbc/(NR*vt_t), EMin, EMax) - 1) + vbc*Gbc);	ibc = smooth(1,(if (vbc/(NR*vt_t) < EMin) then is_t*(ExMin*(vbc/(NR*vt_t) - EMin + 1) - 1) + vbc*Gbc else if (vbc/(NR*vt_t) > EMax) then is_t*( ExMax*(vbc/(NR*vt_t) - EMax + 1) - 1) + vbc*Gbc else is_t*(exp(vbc/ (NR*vt_t)) - 1) + vbc*Gbc));
ibe = smooth(1, is_t*(exlin2(vbe/(NF*vt_t), EMin, EMax) - 1) + vbe*Gbe);	ibe = smooth(1,(if (vbe/(NF*vt_t) < EMin) then is_t*(ExMin*(vbe/(NF*vt_t) - EMin + 1) - 1) + vbe*Gbe else if (vbe/(NF*vt_t) > EMax) then is_t*( ExMax*(vbe/(NF*vt_t) - EMax + 1) - 1) + vbe*Gbe else is_t*(exp(vbe/ (NF*vt_t)) - 1) + vbe*Gbe));
Capcjc = smooth(1, Cjc*powlin(vbc/Phic, Mc));	Capcjc = smooth(1,(if (vbc/Phic > 0) then Cjc*(1 + Mc*vbc/Phic) else Cjc*pow(1 - vbc/Phic, -Mc)));
Capcje = smooth(1, Cje*powlin(vbe/Phie, Me));	Capcje = smooth(1,(if (vbe/Phie > 0) then Cje*(1 + Me*vbe/Phie) else Cje*pow(1 - vbe/Phie, -Me)));
cbc = smooth(1, Taur*is_t/(NR*vt_t)*exlin2(vbc/(NR*vt_t), EMin, EMax) + Capcjc);	cbc = smooth(1,(if (vbc/(NR*vt_t) < EMin) then Taur*is_t/(NR*vt_t)*ExMin*(vbc/( NR*vt_t) - EMin + 1) + Capcjc else if (vbc/(NR*vt_t) > EMax) then Taur*is_t/(NR*vt_t)*ExMax*(vbc/(NR*vt_t) - EMax + 1) + Capcjc else Taur*is_t/(NR*vt_t)*exp(vbc/(NR*vt_t)) + Capcjc));
cbe = smooth(1, Tauf*is_t/(NF*vt_t)*exlin2(vbe/(NF*vt_t), EMin, EMax) + Capcje);	cbe = smooth(1,(if (vbe/(NF*vt_t) < EMin) then Tauf*is_t/(NF*vt_t)*ExMin*(vbe/( NF*vt_t) - EMin + 1) + Capcje else if (vbe/(NF*vt_t) > EMax) then Tauf*is_t/(NF*vt_t)*ExMax*(vbe/(NF*vt_t) - EMax + 1) + Capcje else Tauf*is_t/(NF*vt_t)*exp(vbe/(NF*vt_t)) + Capcje));
C.i = (ibe - ibc)*qbk - ibc/br_t - cbc*der(vbc) + Ccs*der(C.v); ...

---

model Electrical.Analog.Semiconductors.HeatingPNP

Component	Modelica 3.2.3	Modelica 3.2.2
Is	=1e-16	=1.e-16
EG	SIunits.Voltage	Real
vcb	SIunits.Voltage	Real
		protected
veb	SIunits.Voltage	Real
		protected
qbk		protected
icb	SIunits.Current	Real
		protected
ieb	SIunits.Current	Real
		protected
ccb	SIunits.Capacitance	Real
		protected
ceb	SIunits.Capacitance	Real
		protected
Capcje	SIunits.Capacitance	Real
		protected
Capcjc	SIunits.Capacitance	Real
		protected
is_t	SIunits.Current	Real
		protected
br_t		protected
bf_t		protected
vt_t	SIunits.Voltage	Real
		protected
hexp		protected
htempexp		protected
q		Present
ExMin		Present
ExMax		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
assert(T_heatPort > 0,"Temperature must be positive");	assert( T_heatPort > 0,"temperature must be positive");
	ExMin = exp(EMin); ExMax = exp(EMax);
vcb = C.v - B.v; ... hexp = (T_heatPort/Tnom - 1)*EG/vt_t;
htempexp = smooth(1, exlin2(hexp, EMin, EMax));	htempexp = smooth(1,if (hexp < EMin) then ExMin*(hexp - EMin + 1) else if ( hexp > EMax) then ExMax*(hexp - EMax + 1) else exp(hexp));
is_t = Is*pow((T_heatPort/Tnom), XTI)*htempexp; ... vt_t = (k/q)*T_heatPort;
icb = smooth(1, is_t*(exlin2(vcb/(NR*vt_t), EMin, EMax) - 1) + vcb*Gbc);	icb = smooth(1,(if (vcb/(NR*vt_t) < EMin) then is_t*(ExMin*(vcb/(NR*vt_t) - EMin + 1) - 1) + vcb*Gbc else if (vcb/(NR*vt_t) > EMax) then is_t*( ExMax*(vcb/(NR*vt_t) - EMax + 1) - 1) + vcb*Gbc else is_t*(exp(vcb/ (NR*vt_t)) - 1) + vcb*Gbc));
ieb = smooth(1, is_t*(exlin2(veb/(NF*vt_t), EMin, EMax) - 1) + veb*Gbe);	ieb = smooth(1,(if (veb/(NF*vt_t) < EMin) then is_t*(ExMin*(veb/(NF*vt_t) - EMin + 1) - 1) + veb*Gbe else if (veb/(NF*vt_t) > EMax) then is_t*( ExMax*(veb/(NF*vt_t) - EMax + 1) - 1) + veb*Gbe else is_t*(exp(veb/ (NF*vt_t)) - 1) + veb*Gbe));
Capcjc = smooth(1, Cjc*powlin(vcb/Phic, Mc));	Capcjc = smooth(1,(if (vcb/Phic > 0) then Cjc*(1 + Mc*vcb/Phic) else Cjc*pow(1 - vcb/Phic, -Mc)));
Capcje = smooth(1, Cje*powlin(veb/Phie, Me));	Capcje = smooth(1,(if (veb/Phie > 0) then Cje*(1 + Me*veb/Phie) else Cje*pow(1 - veb/Phie, -Me)));
ccb = smooth(1, Taur*is_t/(NR*vt_t)*exlin2(vcb/(NR*vt_t), EMin, EMax) + Capcjc);	ccb = smooth(1,(if (vcb/(NR*vt_t) < EMin) then Taur*is_t/(NR*vt_t)*ExMin*(vcb/( NR*vt_t) - EMin + 1) + Capcjc else if (vcb/(NR*vt_t) > EMax) then Taur*is_t/(NR*vt_t)*ExMax*(vcb/(NR*vt_t) - EMax + 1) + Capcjc else Taur*is_t/(NR*vt_t)*exp(vcb/(NR*vt_t)) + Capcjc));
ceb = smooth(1, Tauf*is_t/(NF*vt_t)*exlin2(veb/(NF*vt_t), EMin, EMax) + Capcje);	ceb = smooth(1,(if (veb/(NF*vt_t) < EMin) then Tauf*is_t/(NF*vt_t)*ExMin*(veb/( NF*vt_t) - EMin + 1) + Capcje else if (veb/(NF*vt_t) > EMax) then Tauf*is_t/(NF*vt_t)*ExMax*(veb/(NF*vt_t) - EMax + 1) + Capcje else Tauf*is_t/(NF*vt_t)*exp(veb/(NF*vt_t)) + Capcje));
C.i = icb/br_t + ccb*der(vcb) + Ccs*der(C.v) + (icb - ieb)*qbk; ...

---

model Electrical.Analog.Semiconductors.Thyristor

Component	Modelica 3.2.3	Modelica 3.2.2
iGK	SIunits.Current	Real
vGK	SIunits.Voltage	Real
vAK	SIunits.Voltage	Real
vControl	SIunits.Voltage	Real
vContot	SIunits.Voltage	Real
vConmain	SIunits.Voltage	Real

---

model Electrical.Analog.Semiconductors.SimpleTriac

Component	Modelica 3.2.3	Modelica 3.2.2
thyristor	IDRM=IDRM
	VTM=VTM
	IH=IH
	ITM=ITM
	VGT=VGT
	IGT=IGT
	TON=TON
	TOFF=TOFF
	Vt=Vt
	Nbv=Nbv
thyristor1	IDRM=IDRM
	VTM=VTM
	IH=IH
	ITM=ITM
	VGT=VGT
	IGT=IGT
	TON=TON
	TOFF=TOFF
	Vt=Vt
	Nbv=Nbv

---

model Electrical.Digital.Delay.TransportDelay

Component	Modelica 3.2.3	Modelica 3.2.2
xr	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
xr = Integer(pre(x));	x_delayed = LogicValues[integer(delay(Integer(pre(x)), delayTime))];
x_delayed = LogicValues[integer(delay(xr, delayTime))];
y = if delayTime > 0 then            (if time >= delayTime then x_delayed else y0) else              pre(x);

---

block Electrical.Digital.Converters.LogicToBoolean

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
for i in 1:n loop
y[i] = (x[i] == L.'1' or x[i] == L.'H');	y[i] = if x[i] == L.'1' or x[i] == L.'H' then true else false;
end for;

---

model Electrical.Digital.Memories.DLATRAM

Component	Modelica 3.2.3	Modelica 3.2.2
tHL		Present
tLH		Present
strength		Present
n_addr		Present
n_data		Present
fileName		Present
RE		Present
addr		Present
dataOut		Present
nextstate		Present
mem_word		Present
int_addr		Present
yy		Present
inertialDelaySensitive		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
...
	equation   for i in 1:n_data loop connect(yy[i], inertialDelaySensitive[i].x); connect(inertialDelaySensitive[i].y, dataOut[i]); end for;

---

model Electrical.Digital.Memories.DLATROM

Component	Modelica 3.2.3	Modelica 3.2.2
tHL		Present
tLH		Present
strength		Present
n_addr		Present
n_data		Present
fileName		Present
RE		Present
addr		Present
dataOut		Present
nextstate		Present
mem_word		Present
addr_bit		Present
int_addr		Present
yy		Present
inertialDelaySensitive		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... elseif RE == L.'1' or RE == L.'H' then
int_addr = address(n_addr, addr);	int_addr = 1;
	for i in 1:n_addr loop addr_bit = T.X01Table[addr[i]]; if addr_bit == L.'1' then int_addr = int_addr + integer(2^(i-1)); elseif addr_bit == L.'X' then int_addr = 0; break; end if; end for;
if int_addr > 0 then ...
	equation   for i in 1:n_data loop connect(yy[i], inertialDelaySensitive[i].x); connect(inertialDelaySensitive[i].y, dataOut[i]); end for;

---

model Electrical.Machines.Examples.AsynchronousInductionMachines.AIMC_withLosses

Component	Modelica 3.2.3	Modelica 3.2.2
w_meas	displayUnit="rev/min"
combiTable1Ds	table={{Ptable[j],Itable[j],wtable[j],ctable[j],etable[j]} for j in 1:size(Ptable, 1)}	table={{Ptable[j],Itable[j],ntable[j],ctable[j],etable[j]} for j in 1:size(Ptable, 1)}
PsNominal	Present
lossNominal	Present
etaNominal	Present
wtable	Present
Ps_sim	Present
Ps_meas	Present
loss_sim	Present
loss_meas	Present
ntable		Present

---

model Electrical.Machines.Examples.DCMachines.DCPM_Cooling

Component	Modelica 3.2.3	Modelica 3.2.2
cooling	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe

---

model Electrical.Machines.BasicMachines.AsynchronousInductionMachines.AIM_SquirrelCage

Component	Modelica 3.2.3	Modelica 3.2.2
squirrelCageR		final T=TrRef

---

model Electrical.Machines.BasicMachines.SynchronousInductionMachines.SM_PermanentMagnet

Component	Modelica 3.2.3	Modelica 3.2.2
ir	graphical
idq_dr	graphical
damperCage		final T=TrRef

---

model Electrical.Machines.BasicMachines.SynchronousInductionMachines.SM_ElectricalExcited

Component	Modelica 3.2.3	Modelica 3.2.2
ir	graphical
idq_dr	graphical
damperCage		final T=TrRef
re		final T=TeRef

---

model Electrical.Machines.BasicMachines.SynchronousInductionMachines.SM_ReluctanceRotor

Component	Modelica 3.2.3	Modelica 3.2.2
ir	graphical
idq_dr	graphical
damperCage		final T=TrRef

---

model Electrical.Machines.BasicMachines.DCMachines.DC_ElectricalExcited

Component	Modelica 3.2.3	Modelica 3.2.2
re		final T=TeRef

---

model Electrical.Machines.BasicMachines.DCMachines.DC_SeriesExcited

Component	Modelica 3.2.3	Modelica 3.2.2
re		final T=TeRef

---

model Electrical.Machines.Sensors.RotorDisplacementAngle

Component	Modelica 3.2.3	Modelica 3.2.2
positiveRange	Present
threshold	Present
wrapAngle	Present
lessThreshold	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(add.y, rotatorVS2R.angle);
connect(wrapAngle.y, rotorDisplacementAngle);	connect(ToPolarVSR.y[2], rotorDisplacementAngle);
connect(ToPolarVSR.y, lessThreshold.u); connect(lessThreshold.y, wrapAngle.u);

---

block Electrical.Machines.SpacePhasors.Blocks.Rotator

Component	Modelica 3.2.3	Modelica 3.2.2
angle	unit="rad"

---

model Electrical.Machines.Losses.Friction

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
tau = -(if noEvent(abs(w)>frictionParameters.wLinear) then frictionParameters.tauRef*sign(w)*(abs(w)/frictionParameters.wRef)^frictionParameters.power_w else frictionParameters.tauLinear*w/frictionParameters.wLinear);	tau = -smooth(1, if w >= +frictionParameters.wLinear then + frictionParameters.tauRef*(+w/frictionParameters.wRef)^ frictionParameters.power_w else if w <= -frictionParameters.wLinear then -frictionParameters.tauRef*(-w/frictionParameters.wRef)^ frictionParameters.power_w else frictionParameters.tauLinear*(w/ frictionParameters.wLinear));
end if; ...

---

model Electrical.Machines.Losses.InductionMachines.StrayLoad

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
tau = -strayLoadParameters.tauRef*(iRMS/strayLoadParameters.IRef)^2* sign(w)*(abs(w)/strayLoadParameters.wRef)^strayLoadParameters.power_w;	tau = -strayLoadParameters.tauRef*(iRMS/strayLoadParameters.IRef)^2* smooth(1, if w >= 0 then +(+w/strayLoadParameters.wRef)^ strayLoadParameters.power_w else -(-w/strayLoadParameters.wRef)^ strayLoadParameters.power_w);
end if; ...

---

model Electrical.Machines.Losses.InductionMachines.PermanentMagnetLosses

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
tau = -permanentMagnetLossParameters.tauRef*(permanentMagnetLossParameters.c + (1 - permanentMagnetLossParameters.c)* (iRMS/permanentMagnetLossParameters.IRef)^permanentMagnetLossParameters.power_I)* sign(w)*(abs(w)/permanentMagnetLossParameters.wRef)^permanentMagnetLossParameters.power_w;	tau = -permanentMagnetLossParameters.tauRef*( permanentMagnetLossParameters.c + (1 - permanentMagnetLossParameters.c)*(iRMS/ permanentMagnetLossParameters.IRef)^permanentMagnetLossParameters.power_I) *smooth(1, if w >= 0 then +(+w/permanentMagnetLossParameters.wRef)^ permanentMagnetLossParameters.power_w else -(-w/ permanentMagnetLossParameters.wRef)^permanentMagnetLossParameters.power_w);
end if; ...

---

model Electrical.Machines.Losses.InductionMachines.Core

Component	Modelica 3.2.3	Modelica 3.2.2
coreParameters	m=3

---

model Electrical.Machines.Losses.DCMachines.Brush

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
v = smooth(0, if (i > +brushParameters.ILinear) then +brushParameters.V else if (i < -brushParameters.ILinear) then -brushParameters.V else brushParameters.V*i/brushParameters.ILinear);	v = smooth(1, if (i > +brushParameters.ILinear) then +brushParameters.V else if (i < -brushParameters.ILinear) then -brushParameters.V else brushParameters.V*i/brushParameters.ILinear);
end if; ...

---

model Electrical.Machines.Losses.DCMachines.StrayLoad

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
tau = -strayLoadParameters.tauRef*(i/strayLoadParameters.IRef)^2* sign(w)*(abs(w)/strayLoadParameters.wRef)^strayLoadParameters.power_w;	tau = -strayLoadParameters.tauRef*(i/strayLoadParameters.IRef)^2* smooth(1, if w >= 0 then +(+w/strayLoadParameters.wRef)^ strayLoadParameters.power_w else -(-w/strayLoadParameters.wRef)^ strayLoadParameters.power_w);
end if; ...

---

model Electrical.Machines.Losses.DCMachines.Core

Component	Modelica 3.2.3	Modelica 3.2.2
coreParameters	m=1

---

model Electrical.Machines.Interfaces.PartialBasicDCMachine

Component	Modelica 3.2.3	Modelica 3.2.2
ra		final T=TaRef

---

record Electrical.Machines.Utilities.ParameterRecords.InductionMachineData

Component	Modelica 3.2.3	Modelica 3.2.2
effectiveStatorTurns	Present

---

block Electrical.Machines.Utilities.VfController

Component	Modelica 3.2.3	Modelica 3.2.2
EconomyMode	Present
pow	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
amplitude = sqrt(2)*VNominal*(if abs(u) < fNominal then (abs(u)/fNominal)^pow else 1);	amplitude = sqrt(2)*VNominal*(if abs(u) < fNominal then abs(u)/fNominal else 1);
der(x) = 2*pi*u; ...

---

block Electrical.Machines.Utilities.ToDQ

Component	Modelica 3.2.3	Modelica 3.2.2
phi	unit="rad"

---

block Electrical.Machines.Utilities.FromDQ

Component	Modelica 3.2.3	Modelica 3.2.2
phi	unit="rad"

---

model Electrical.Machines.Utilities.CurrentController

Component	Modelica 3.2.3	Modelica 3.2.2
m	parameter	constant
phi	unit="rad"
fromSpacePhasor	final m=m

---

model Electrical.Machines.Utilities.VoltageController

Component	Modelica 3.2.3	Modelica 3.2.2
phi	unit="rad"
iActual	sizes= -1	sizes= 3
fromDQ	final m=m
toDQ	final m=m

---

record Electrical.Machines.Utilities.SynchronousMachineData

Component	Modelica 3.2.3	Modelica 3.2.2
effectiveStatorTurns	Present

---

model Electrical.MultiPhase.Examples.Rectifier

Component	Modelica 3.2.3	Modelica 3.2.2
V	=100	=1
f	=50	=5
L	=0.0001	=0.001
C	=0.005	=0.05
Ron	=1e-5	=1.E-5
Goff	=1e-5	=1.E-5
sineVoltage	V=sqrt(2)*fill(V, m)	V=fill(V, m)
VDC	Present
IDC	Present
powerSensorSpacePhasor	Present
aronSensor	Present
powerSensor	Present
reactivePowerSensor	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial equation
cDC1.v = VDC/2;	cDC1.v = 0;
cDC2.v = VDC/2;	cDC2.v = 0;
supplyL.i[2]=-IDC;	supplyL.i[1:m - 1] = zeros(m - 1) "Y-connection";
supplyL.i[3]= IDC;
... connect(sineVoltage.plug_p, supplyL.plug_p);
	connect(idealDiode1.plug_p, supplyL.plug_n); connect(idealDiode2.plug_n, supplyL.plug_n);
connect(idealDiode1.plug_n, star1.plug_p); ... connect(star1.pin_n, cDC1.p);
connect(idealDiode1.plug_p, idealDiode2.plug_n); connect(supplyL.plug_n, powerSensor.pc); connect(powerSensor.nc, powerSensorSpacePhasor.plug_p); connect(powerSensorSpacePhasor.plug_ni, aronSensor.plug_p); connect(aronSensor.plug_n, reactivePowerSensor.plug_p); connect(idealDiode1.plug_p, reactivePowerSensor.plug_n); connect(powerSensor.pc, powerSensor.pv); connect(starS.plug_p, powerSensor.nv); connect(starS.plug_p, powerSensorSpacePhasor.plug_nv);

---

model Electrical.MultiPhase.Examples.TestSensors

Component	Modelica 3.2.3	Modelica 3.2.2
IRMS	=VRMS/Z	=VRMS/sqrt(R^2 + (2*pi*f*L)^2)
realExpression	y=Modelica.Electrical.MultiPhase.Functions.activePower(voltageQuasiRMSSensor.v, currentQuasiRMSSensor.i)	y=Modelica322.Electrical.MultiPhase.Functions.activePower(voltageQuasiRMSSensor.v, currentQuasiRMSSensor.i)
Z	Present
P	Present
Q	Present
S	Present
powerSensorSpacePhasor	Present
feedbackSpacePhasor	Present
aronSensor	Present
feedbackAron	Present
reactivePowerSensor	Present
feedbackQ	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... equation   connect(star.pin_n, ground.p);
	connect(sineVoltage.plug_n, star.plug_p);
connect(resistor.plug_n, inductor.plug_p);
connect(inductor.plug_n, starLoad.plug_p);
	connect(currentQuasiRMSSensor.I, feedbackI.u1); connect(feedbackI.u2, constI.y); connect(sineVoltage.plug_p, currentQuasiRMSSensor.plug_p);
connect(voltageQuasiRMSSensor.plug_n, sineVoltage.plug_n); ... connect(powerSensor.nc, resistor.plug_p);
	connect(currentQuasiRMSSensor.plug_n, powerSensor.pc);
connect(powerSensor.pc, powerSensor.pv); ... connect(powerSensor.power, feedbackP.u1);
connect(aronSensor.plug_n, powerSensor.pc);	connect(realExpression.y, feedbackP.u2);
connect(sineVoltage.plug_n, star.plug_p); connect(feedbackI.u2, constI.y); connect(feedbackI.u1, currentQuasiRMSSensor.I); connect(currentQuasiRMSSensor.plug_p, sineVoltage.plug_p); connect(feedbackP.u2, realExpression.y); connect(powerSensorSpacePhasor.plug_p, currentQuasiRMSSensor.plug_n); connect(powerSensorSpacePhasor.plug_nv, starLoad.plug_p); connect(powerSensorSpacePhasor.plug_ni, reactivePowerSensor.plug_p); connect(reactivePowerSensor.plug_n, aronSensor.plug_p); connect(reactivePowerSensor.reactivePower, feedbackQ.u1); connect(powerSensorSpacePhasor.Q, feedbackQ.u2); connect(aronSensor.power, feedbackAron.u1); connect(feedbackSpacePhasor.u1, powerSensorSpacePhasor.P); connect(realExpression.y, feedbackAron.u2); connect(realExpression.y, feedbackSpacePhasor.u2);

---

model Electrical.MultiPhase.Basic.Resistor

Component	Modelica 3.2.3	Modelica 3.2.2
resistor		final T=T

---

model Electrical.MultiPhase.Basic.Conductor

Component	Modelica 3.2.3	Modelica 3.2.2
conductor		final T=T

---

model Electrical.MultiPhase.Basic.MutualInductor

Component	Modelica 3.2.3	Modelica 3.2.2
epsilon	parameter	constant
m		Present

---

model Electrical.MultiPhase.Basic.VariableResistor

Component	Modelica 3.2.3	Modelica 3.2.2
variableResistor		final T=T

---

model Electrical.MultiPhase.Basic.VariableConductor

Component	Modelica 3.2.3	Modelica 3.2.2
variableConductor		final T=T

---

model Electrical.MultiPhase.Ideal.IdealDiode

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.MultiPhase.Ideal.IdealThyristor

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.MultiPhase.Ideal.IdealGTOThyristor

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.MultiPhase.Ideal.IdealCommutingSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.MultiPhase.Ideal.IdealIntermediateSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.MultiPhase.Ideal.IdealOpeningSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.MultiPhase.Ideal.IdealClosingSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.MultiPhase.Ideal.OpenerWithArc

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.MultiPhase.Ideal.CloserWithArc

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

function Electrical.MultiPhase.Functions.symmetricOrientationMatrix

Component	Modelica 3.2.3	Modelica 3.2.2
oM	Present
nBase	Present
mBase	Present
o	Present
oBase	Present
orientation		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
oM := zeros(m, m);	orientation := zeros(m, m);
if mBase==2 then	if mod(m, 2) == 0 then
oM[1:mBase,1:mBase] = {o[1:mBase],-o[1:mBase]};	if m == 2 then
	orientation = {{0,+pi/2},{0,-pi/2}};
else
for j in 1:mBase loop	orientation[1:integer(m/2), 1:integer(m/2)] = symmetricOrientationMatrix(integer(m/2));
oM[j,1:mBase] = j*o[1:mBase];	orientation[1 + integer(m/2):m, 1 + integer(m/2):m] = symmetricOrientationMatrix(integer(m/2)) - fill( pi/m, integer(m/2), integer(m/2));
end for;
end if;
for i in 2:nBase loop	else
for k in 1:mBase loop	for k in 1:m loop
oM[(i - 1)*mBase + k, (i - 1)*mBase + 1:i*mBase] = oM[k, 1:mBase] + fill(oBase[i], mBase);	orientation[k, :] = Modelica322.Electrical.MultiPhase.Functions.symmetricOrientation(m)*k;
end for;
end for;	end if;

---

function Electrical.MultiPhase.Functions.symmetricTransformationMatrix

Component	Modelica 3.2.3	Modelica 3.2.2
tM	Present
nBase	Present
mBase	Present
factor	Present
oM	Present
transformation		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
for i in 1:nBase loop	transformation := Modelica322.ComplexMath.fromPolar(fill( numberOfSymmetricBaseSystems(m)/m, m, m), Electrical.MultiPhase.Functions.symmetricOrientationMatrix(m));
for j in 1:nBase loop
for ii in (i - 1)*mBase + 1:i*mBase loop for jj in (j - 1)*mBase + 1:j*mBase loop tM[ii,jj] = fromPolar(if i==j then factor else 0, oM[ii,jj]); end for; end for; end for; end for;

---

function Electrical.MultiPhase.Functions.indexPositiveSequence

Component	Modelica 3.2.3	Modelica 3.2.2
n	=numberOfSymmetricBaseSystems(m)	=Electrical.MultiPhase.Functions.numberOfSymmetricBaseSystems(m)

---

function Electrical.MultiPhase.Functions.indexNonPositiveSequence

Component	Modelica 3.2.3	Modelica 3.2.2
nBase	Present
mBase	Present
n		Present
mbas		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
if mBase == 1 then	if mbas == 1 then
ind = fill(0, 0);
elseif mBase == 2 then	elseif mbas == 2 then
for k in 1:nBase loop	for k in 1:n loop
ind[k] = 2 + 2*(k - 1); ... else
for k in 1:nBase loop	for k in 1:n loop
ind[(mBase - 1)*(k - 1) + 1:(mBase - 1)*k] = (2:mBase) + mBase*(k - 1)*ones(mBase - 1);	ind[(mbas - 1)*(k - 1) + 1:(mbas - 1)*k] = (2:mbas) + mbas*(k - 1)* ones(mbas - 1);
end for; ...

---

model Electrical.PowerConverters.Examples.ACDC.RectifierCenterTapmPulse.DiodeCenterTapmPulse

Component	Modelica 3.2.3	Modelica 3.2.2
sineVoltage_p	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Electrical.PowerConverters.Examples.ACDC.RectifierBridge2mPulse.DiodeBridge2mPulse

Component	Modelica 3.2.3	Modelica 3.2.2
sineVoltage	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Electrical.PowerConverters.Examples.ACDC.RectifierBridge2mPulse.ThyristorBridge2mPulse_DC_Drive

Component	Modelica 3.2.3	Modelica 3.2.2
Vrms	=dcpmData.VaNominal/Modelica323.Electrical.MultiPhase.Functions.factorY2DC(m)	=dcpmData.VaNominal/Modelica.Electrical.MultiPhase.Functions.factorY2DC(m)

---

model Electrical.PowerConverters.Examples.ACDC.RectifierCenterTap2mPulse.DiodeCenterTap2mPulse

Component	Modelica 3.2.3	Modelica 3.2.2
sineVoltage_p	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)
sineVoltage_n	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Electrical.PowerConverters.Examples.ACDC.ExampleTemplates.ThyristorCenterTap2Pulse

Component	Modelica 3.2.3	Modelica 3.2.2
model	partial

---

model Electrical.PowerConverters.Examples.ACDC.ExampleTemplates.ThyristorCenterTapmPulse

Component	Modelica 3.2.3	Modelica 3.2.2
sineVoltage_p	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Electrical.PowerConverters.Examples.ACDC.ExampleTemplates.ThyristorBridge2mPulse

Component	Modelica 3.2.3	Modelica 3.2.2
sineVoltage	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Electrical.PowerConverters.Examples.ACDC.ExampleTemplates.ThyristorCenterTap2mPulse

Component	Modelica 3.2.3	Modelica 3.2.2
sineVoltage_p	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)
sineVoltage_n	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Electrical.PowerConverters.Examples.DCDC.ExampleTemplates.ChopperStepDown

Component	Modelica 3.2.3	Modelica 3.2.2
constantVoltage	final V=Vsource
		V=100
signalPWM	final constantDutyCycle=dutyCycle
	final f=f
		constantDutyCycle=0.25
		f=f
Vsource	Present
dutyCycle	Present
V0	Present

---

block Electrical.PowerConverters.ACDC.Control.Signal2mPulse

Component	Modelica 3.2.3	Modelica 3.2.2
filter	each final fCut=fCut	each final fCut=2*f

---

block Electrical.PowerConverters.DCDC.Control.VoltageToDutyCycle

Component	Modelica 3.2.3	Modelica 3.2.2
vMax	=0
add	k1=0.5
	k2=1
useConstantMaximumVoltage	Present
divisionUnipolar	Present
divisionBipolar	Present
vMaxExt	Present
vMaxConst	Present
vMaxInt	Present
gainUnipolar		Present
gainBipolar		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
connect(divisionBipolar.y, add.u1);	connect(v, gainUnipolar.u);
	connect(v, gainBipolar.u); connect(gainBipolar.y, add.u1);
connect(offset.y, add.u2);
connect(divisionUnipolar.y, dutyCycle);	connect(gainUnipolar.y, dutyCycle);
connect(add.y, dutyCycle);
connect(v, divisionUnipolar.u1); connect(v, divisionBipolar.u1); connect(vMaxExt, vMaxInt); connect(vMaxInt, divisionUnipolar.u2); connect(vMaxInt, vMaxConst.y); connect(vMaxInt, divisionBipolar.u2);

---

model Electrical.PowerConverters.DCDC.HBridge

Component	Modelica 3.2.3	Modelica 3.2.2
dc_p1		Present
dc_n1		Present
dc_n2		Present
dc_p2		Present

---

model Electrical.PowerConverters.Interfaces.ACDC.ACtwoPin

Component	Modelica 3.2.3	Modelica 3.2.2
powerAC	Present

---

model Electrical.PowerConverters.Interfaces.ACDC.ACplug

Component	Modelica 3.2.3	Modelica 3.2.2
powerAC	Present
powerTotalAC	Present

---

model Electrical.PowerConverters.Interfaces.ACDC.ACtwoPlug

Component	Modelica 3.2.3	Modelica 3.2.2
powerAC	Present
powerTotalAC	Present

---

model Electrical.PowerConverters.Interfaces.ACDC.DCtwoPin

Component	Modelica 3.2.3	Modelica 3.2.2
powerDC	Present

---

model Electrical.PowerConverters.Interfaces.ACDC.DCpin

Component	Modelica 3.2.3	Modelica 3.2.2
powerDC	Present

---

model Electrical.PowerConverters.Interfaces.DCAC.DCtwoPin

Component	Modelica 3.2.3	Modelica 3.2.2
powerDC	Present

---

model Electrical.PowerConverters.Interfaces.DCAC.ACpin

Component	Modelica 3.2.3	Modelica 3.2.2
powerAC	Present

---

model Electrical.PowerConverters.Interfaces.DCAC.ACplug

Component	Modelica 3.2.3	Modelica 3.2.2
powerAC	Present
powerTotalAC	Present

---

model Electrical.PowerConverters.Interfaces.DCDC.DCtwoPin1

Component	Modelica 3.2.3	Modelica 3.2.2
powerDC1	Present

---

model Electrical.PowerConverters.Interfaces.DCDC.DCtwoPin2

Component	Modelica 3.2.3	Modelica 3.2.2
powerDC2	Present

---

model Electrical.QuasiStationary.SinglePhase.Basic.Impedance

Component	Modelica 3.2.3	Modelica 3.2.2
frequencyDependent	Present
f_ref	Present
X_actual	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... R_actual = R_ref*(1 + alpha_ref*(T_heatPort - T_ref));
X_actual = X_ref*(if not frequencyDependent then 1 else (if X_ref >= 0 then omega/(2*Modelica323.Constants.pi*f_ref) else 2*Modelica323.Constants.pi* f_ref/omega));	v = Complex(R_actual, X_ref)*i;
v = Complex(R_actual, X_actual) * i;
LossPower = real(v*conj(i));

---

model Electrical.QuasiStationary.SinglePhase.Basic.Admittance

Component	Modelica 3.2.3	Modelica 3.2.2
frequencyDependent	Present
f_ref	Present
B_actual	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... G_actual = G_ref/(1 + alpha_ref*(T_heatPort - T_ref));
B_actual = B_ref*(if not frequencyDependent then 1 else (if B_ref >= 0 then omega/(2*Modelica323.Constants.pi*f_ref) else 2*Modelica323.Constants.pi* f_ref/omega));	i = Complex(G_actual, B_ref)*v;
i = Complex(G_actual, B_actual) * v;
LossPower = real(v*conj(i));

---

model Electrical.QuasiStationary.SinglePhase.Basic.VariableImpedance

Component	Modelica 3.2.3	Modelica 3.2.2
frequencyDependent	Present
f_ref	Present
X_actual	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... R_actual = R_ref*(1 + alpha_ref*(T_heatPort - T_ref));
X_actual = X_ref*(if not frequencyDependent then 1 else (if X_ref >= 0 then omega/(2*Modelica323.Constants.pi*f_ref) else 2*Modelica323.Constants.pi* f_ref/omega));	v = Complex(R_actual, X_ref)*i;
v = Complex(R_actual, X_actual) * i;
LossPower = real(v*conj(i));

---

model Electrical.QuasiStationary.SinglePhase.Basic.VariableAdmittance

Component	Modelica 3.2.3	Modelica 3.2.2
frequencyDependent	Present
f_ref	Present
B_actual	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... G_actual = G_ref/(1 + alpha_ref*(T_heatPort - T_ref));
B_actual = B_ref*(if not frequencyDependent then 1 else (if B_ref >= 0 then omega/(2*Modelica323.Constants.pi*f_ref) else 2*Modelica323.Constants.pi* f_ref/omega));	i = Complex(G_actual, B_ref)*v;
i = Complex(G_actual, B_actual) * v;
LossPower = real(v*conj(i));

---

model Electrical.QuasiStationary.SinglePhase.Ideal.IdealCommutingSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	=1e-5	=1.E-5
Goff	=1e-5	=1.E-5

---

model Electrical.QuasiStationary.SinglePhase.Ideal.IdealIntermediateSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	=1e-5	=1.E-5
Goff	=1e-5	=1.E-5

---

model Electrical.QuasiStationary.SinglePhase.Ideal.IdealOpeningSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron		graphical
	=1e-5	=1.E-5
Goff		graphical
	=1e-5	=1.E-5

---

model Electrical.QuasiStationary.SinglePhase.Ideal.IdealClosingSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron		graphical
	=1e-5	=1.E-5
Goff		graphical
	=1e-5	=1.E-5

---

model Electrical.QuasiStationary.SinglePhase.Ideal.IdealTransformer

Component	Modelica 3.2.3	Modelica 3.2.2
abs_v1	Present
arg_v1	Present
abs_i1	Present
arg_i1	Present
P1	Present
Q1	Present
S1	Present
pf1	Present
abs_v2	Present
arg_v2	Present
abs_i2	Present
arg_i2	Present
P2	Present
Q2	Present
S2	Present
pf2	Present

---

model Electrical.QuasiStationary.SinglePhase.Sensors.ReferenceSensor

Component	Modelica 3.2.3	Modelica 3.2.2
y	unit="rad"

---

model Electrical.QuasiStationary.SinglePhase.Sensors.FrequencySensor

Component	Modelica 3.2.3	Modelica 3.2.2
y	unit="Hz"

---

model Electrical.QuasiStationary.SinglePhase.Sources.VariableVoltageSource

Component	Modelica 3.2.3	Modelica 3.2.2
f	unit="Hz"

---

model Electrical.QuasiStationary.SinglePhase.Sources.VariableCurrentSource

Component	Modelica 3.2.3	Modelica 3.2.2
f	unit="Hz"

---

connector Electrical.QuasiStationary.SinglePhase.Interfaces.Pin

Component	Modelica 3.2.3	Modelica 3.2.2
v	SIunits.ComplexElectricPotential	SIunits.ComplexVoltage

---

model Electrical.QuasiStationary.Machines.Examples.TransformerTestbench

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(load.plug_n, starL.plug_p);
	connect(source.plug_p, electricalPowerSensorS.currentP);
connect(electricalPowerSensorS.currentP, electricalPowerSensorS.voltageP); ... connect(symmetricalComponentsVL.y[1], polarVL.u);
connect(electricalPowerSensorS.currentP, source.plug_p);

---

model Electrical.QuasiStationary.Machines.BasicMachines.Components.PartialCore

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... plug_p1.reference.gamma = plug_p3.reference.gamma;
	Connections.potentialRoot(plug_p1.reference); Connections.potentialRoot(plug_p2.reference); Connections.potentialRoot(plug_p3.reference);
plug_p1.pin.i + plug_n1.pin.i = fill(Complex(0), m); ...

---

model Electrical.QuasiStationary.MultiPhase.Basic.MultiStar

Component	Modelica 3.2.3	Modelica 3.2.2
mSystems	=Modelica323.Electrical.MultiPhase.Functions.numberOfSymmetricBaseSystems(m)	=Modelica.Electrical.MultiPhase.Functions.numberOfSymmetricBaseSystems(m)

---

model Electrical.QuasiStationary.MultiPhase.Basic.MultiDelta

Component	Modelica 3.2.3	Modelica 3.2.2
mSystems	=Modelica323.Electrical.MultiPhase.Functions.numberOfSymmetricBaseSystems(m)	=Modelica.Electrical.MultiPhase.Functions.numberOfSymmetricBaseSystems(m)

---

model Electrical.QuasiStationary.MultiPhase.Basic.Impedance

Component	Modelica 3.2.3	Modelica 3.2.2
impedance	final frequencyDependent=fill(frequencyDependent, m)
	final f_ref=fill(f_ref, m)
frequencyDependent	Present
f_ref	Present

---

model Electrical.QuasiStationary.MultiPhase.Basic.Admittance

Component	Modelica 3.2.3	Modelica 3.2.2
admittance	final frequencyDependent=fill(frequencyDependent, m)
	final f_ref=fill(f_ref, m)
frequencyDependent	Present
f_ref	Present

---

model Electrical.QuasiStationary.MultiPhase.Basic.VariableImpedance

Component	Modelica 3.2.3	Modelica 3.2.2
variableImpedance	final frequencyDependent=fill(frequencyDependent, m)
	final f_ref=fill(f_ref, m)
frequencyDependent	Present
f_ref	Present

---

model Electrical.QuasiStationary.MultiPhase.Basic.VariableAdmittance

Component	Modelica 3.2.3	Modelica 3.2.2
variableImpedance	final frequencyDependent=fill(frequencyDependent, m)
	final f_ref=fill(f_ref, m)
frequencyDependent	Present
f_ref	Present

---

model Electrical.QuasiStationary.MultiPhase.Ideal.IdealCommutingSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.QuasiStationary.MultiPhase.Ideal.IdealIntermediateSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.QuasiStationary.MultiPhase.Ideal.IdealOpeningSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

model Electrical.QuasiStationary.MultiPhase.Ideal.IdealClosingSwitch

Component	Modelica 3.2.3	Modelica 3.2.2
Ron	start=fill(1e-5, m)	start=fill(1.E-5, m)
Goff	start=fill(1e-5, m)	start=fill(1.E-5, m)

---

function Electrical.QuasiStationary.MultiPhase.Functions.quasiRMS

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
y :=sum({sqrt(u[k].re^2 + u[k].im^2) for k in 1:m})/m;	y := sum({'abs'(u[k]) for k in 1:m})/m;

---

block Electrical.QuasiStationary.MultiPhase.Blocks.QuasiRMS

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
y = Modelica323.Electrical.QuasiStationary.MultiPhase.Functions.quasiRMS(u);	y = Modelica.Electrical.QuasiStationary.MultiPhase.Functions.quasiRMS(u);

---

block Electrical.QuasiStationary.MultiPhase.Blocks.SymmetricalComponents

Component	Modelica 3.2.3	Modelica 3.2.2
sTM	=Electrical.MultiPhase.Functions.symmetricTransformationMatrix(m)	=Modelica322.Electrical.MultiPhase.Functions.symmetricTransformationMatrix(m)
abs_u	Present
arg_u	Present
abs_y	Present
arg_y	Present

---

block Electrical.QuasiStationary.MultiPhase.Blocks.SingleToMultiPhase

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
y = u*Modelica323.ComplexMath.fromPolar(fill(1, m), - Electrical.MultiPhase.Functions.symmetricOrientation(m));	y = u*Modelica322.ComplexMath.fromPolar(fill(1, m), - Modelica322.Electrical.MultiPhase.Functions.symmetricOrientation(m));

---

block Electrical.QuasiStationary.MultiPhase.Blocks.ToSpacePhasor

Component	Modelica 3.2.3	Modelica 3.2.2
phi	=Electrical.MultiPhase.Functions.symmetricOrientation(m)	=Modelica322.Electrical.MultiPhase.Functions.symmetricOrientation(m)

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
c.re = sqrt(2)/m*sum(u[k].re*cos(phi[k])-u[k].im*sin(phi[k]) for k in 1:m);	c = sqrt(2)/m*'sum'({u[k]*exp(j*phi[k]) for k in 1:m});
c.im = sqrt(2)/m*sum(u[k].re*sin(phi[k])+u[k].im*cos(phi[k]) for k in 1:m);
y = {c.re,c.im};

---

block Electrical.QuasiStationary.MultiPhase.Blocks.FromSpacePhasor

Component	Modelica 3.2.3	Modelica 3.2.2
phi	=Electrical.MultiPhase.Functions.symmetricOrientation(m)	=Modelica322.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Electrical.Spice3.Examples.CoupledInductors

Component	Modelica 3.2.3	Modelica 3.2.2
C1	C=1e-6	C=1.e-6

---

record Electrical.Spice3.Internal.ModelcardMOS

Component	Modelica 3.2.3	Modelica 3.2.2
IS	=1e-14	=1.e-14

---

record Electrical.Spice3.Internal.ModelcardMOS2

Component	Modelica 3.2.3	Modelica 3.2.2
UCRIT	=1e4	=1.e4

---

record Electrical.Spice3.Internal.ModelcardJFET

Component	Modelica 3.2.3	Modelica 3.2.2
IS	=1e-14	=1.e-14

---

record Electrical.Spice3.Internal.ModelcardR

Component	Modelica 3.2.3	Modelica 3.2.2
TC1	SIunits.LinearTemperatureCoefficientResistance	SIunits.Conversions.NonSIunits.FirstOrderTemperaturCoefficient
TC2	SIunits.QuadraticTemperatureCoefficientResistance	SIunits.Conversions.NonSIunits.SecondOrderTemperaturCoefficient

---

record Electrical.Spice3.Internal.SpiceConstants

Component	Modelica 3.2.3	Modelica 3.2.2
CONSTvt0	final unit="(J)/(A.s)"	final unit="(J/K)/(A.s)"

---

function Electrical.Spice3.Internal.Functions.junctionPotDepTemp

Component	Modelica 3.2.3	Modelica 3.2.2
phibtemp	SIunits.GapEnergy	SIunits.Voltage
phibtnom	SIunits.GapEnergy	SIunits.Voltage
unitGapEnergy	Present
unitVoltage	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... vt = Spice3.Internal.SpiceConstants.CONSTKoverQ*     temp;
ret = (phi0 - phibtnom*(unitVoltage/unitGapEnergy))*temp/tnom + phibtemp*( unitVoltage/unitGapEnergy) + vt*3*Modelica323.Math.log(tnom/temp);	ret = (phi0 - phibtnom)*temp/tnom + phibtemp + vt*3*Modelica322.Math.log(tnom/ temp);

---

function Electrical.Spice3.Internal.Functions.saturationCurDepTempSPICE3MOSFET

Component	Modelica 3.2.3	Modelica 3.2.2
energygaptnom	SIunits.GapEnergy	SIunits.Voltage
energygaptemp	SIunits.GapEnergy	SIunits.Voltage
unitGapEnergy	Present
unitVoltage	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... energygaptemp =   Modelica323.Electrical.Spice3.Internal.Functions.energyGapDepTemp(temp);
ret = satcur0 * exp( energygaptnom*(unitVoltage/unitGapEnergy) / vtnom - energygaptemp*(unitVoltage/unitGapEnergy) / vt);	ret = satcur0 * exp( energygaptnom / vtnom - energygaptemp / vt);

---

function Electrical.Spice3.Internal.Functions.junctionParamDepTempSPICE3

Component	Modelica 3.2.3	Modelica 3.2.2
phibtemp	SIunits.GapEnergy	SIunits.Voltage
phibtnom	SIunits.GapEnergy	SIunits.Voltage

---

function Electrical.Spice3.Internal.Functions.junction2SPICE3MOSFETRevised

Component	Modelica 3.2.3	Modelica 3.2.2
max_current	=1e4	=1.e4

---

function Electrical.Spice3.Internal.Functions.junction2SPICE3MOSFET

Component	Modelica 3.2.3	Modelica 3.2.2
max_current	=1e4	=1.e4

---

function Electrical.Spice3.Internal.Functions.energyGapDepTemp

Component	Modelica 3.2.3	Modelica 3.2.2
ret	SIunits.GapEnergy	SIunits.Voltage

---

function Electrical.Spice3.Internal.Mos2.drainCurRevised

Component	Modelica 3.2.3	Modelica 3.2.2
dbsrdb	=0.0
x4	=fill(0.0, 8)

---

function Electrical.Spice3.Internal.Mos2.drainCur

Component	Modelica 3.2.3	Modelica 3.2.2
dbsrdb	=0.0
x4	=fill(0.0, 8)

---

record Electrical.Spice3.Internal.Rsemiconductor.ResistorModelLineParams

Component	Modelica 3.2.3	Modelica 3.2.2
m_dTC1	SIunits.LinearTemperatureCoefficientResistance	SIunits.Conversions.NonSIunits.FirstOrderTemperaturCoefficient
m_dTC2	SIunits.QuadraticTemperatureCoefficientResistance	SIunits.Conversions.NonSIunits.SecondOrderTemperaturCoefficient

---

model Magnetic.FluxTubes.Examples.MovingCoilActuator.Components.ConstantActuator

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(electroTranslationalConverter.flange, armature.flange_a);
connect(p, p);

---

model Magnetic.FluxTubes.Examples.Hysteresis.HysteresisModelComparison

Component	Modelica 3.2.3	Modelica 3.2.2
winding1	Present
resistor1	Present
vSource1	Present
winding2	Present
tellinenTable	Present
resistor2	Present
vSource2	Present
winding3	Present
preisachEverett	Present
resistor3	Present
vSource3	Present
tellinenSoft	Present
W1		Present
R1		Present
V1		Present
W2		Present
TellinenTable		Present
R2		Present
V2		Present
W3		Present
PreisachEverett		Present
R3		Present
V3		Present
TellinenSoft		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
connect(winding1.port_n, magGnd1.port);	connect(W1.port_n, magGnd1.port);
connect(resistor1.n, winding1.p);	connect(R1.n, W1.p);
connect(winding1.n, elGnd1.p);	connect(W1.n, elGnd1.p);
connect(vSource1.p, resistor1.p);	connect(V1.p, R1.p);
connect(elGnd1.p, vSource1.n);	connect(elGnd1.p, V1.n);
connect(winding2.port_n, magGnd2.port);	connect(W2.port_n, magGnd2.port);
connect(winding2.port_p, tellinenTable.port_p);	connect(W2.port_p, TellinenTable.port_p);
connect(resistor2.n, winding2.p);	connect(R2.n, W2.p);
connect(winding2.n, elGnd2.p);	connect(W2.n, elGnd2.p);
connect(vSource2.p, resistor2.p);	connect(V2.p, R2.p);
connect(elGnd2.p, vSource2.n);	connect(elGnd2.p, V2.n);
connect(tellinenTable.port_n, magGnd2.port);	connect(TellinenTable.port_n, magGnd2.port);
connect(vSource2.v, vSource1.v);	connect(V2.v, V1.v);
connect(winding3.port_n, magGnd3.port);	connect(W3.port_n, magGnd3.port);
connect(winding3.port_p, preisachEverett.port_p);	connect(W3.port_p, PreisachEverett.port_p);
connect(resistor3.n, winding3.p);	connect(R3.n, W3.p);
connect(winding3.n, elGnd3.p);	connect(W3.n, elGnd3.p);
connect(vSource3.p, resistor3.p);	connect(V3.p, R3.p);
connect(elGnd3.p, vSource3.n);	connect(elGnd3.p, V3.n);
connect(preisachEverett.port_n, magGnd3.port);	connect(PreisachEverett.port_n, magGnd3.port);
connect(vSource3.v, vSource1.v);	connect(V3.v, V1.v);
connect(timeTable.y, gain.u);
connect(gain.y, vSource1.v);	connect(gain.y, V1.v);
connect(winding1.port_p, tellinenSoft.port_p);	connect(W1.port_p, TellinenSoft.port_p);
connect(magGnd1.port,tellinenSoft. port_n);	connect(magGnd1.port, TellinenSoft.port_n);

---

model Magnetic.FluxTubes.Examples.Hysteresis.InductorWithHysteresis

Component	Modelica 3.2.3	Modelica 3.2.2
winding	Present
resistor	Present
vSource	Present
core	Present
Winding		Present
R		Present
SineVoltage		Present
Core		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
connect(winding.port_n, mag_ground.port);	connect(Winding.port_n, mag_ground.port);
connect(vSource.p, resistor.p);	connect(SineVoltage.p, R.p);
connect(vSource.n, el_ground.p);	connect(SineVoltage.n, el_ground.p);
connect(winding.n, el_ground.p);	connect(Winding.n, el_ground.p);
connect(resistor.n, winding.p);	connect(R.n, Winding.p);
connect(winding.port_p,core. port_p);	connect(Winding.port_p, Core.port_p);
connect(mag_ground.port,core. port_n);	connect(mag_ground.port, Core.port_n);

---

model Magnetic.FluxTubes.Examples.Hysteresis.SinglePhaseTransformerWithHysteresis1

Component	Modelica 3.2.3	Modelica 3.2.2
winding1	Present
resistor1	Present
vSource	Present
winding2	Present
resistor2	Present
core	Present
WindingPrim		Present
Rprim		Present
SineVoltage		Present
WindingSec		Present
Rsec		Present
Core		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
connect(winding1.port_n, mag_ground.port);	connect(WindingPrim.port_n, mag_ground.port);
connect(vSource.p, resistor1.p);	connect(SineVoltage.p, Rprim.p);
connect(vSource.n, el_ground1.p);	connect(SineVoltage.n, el_ground1.p);
connect(winding1.n, el_ground1.p);	connect(WindingPrim.n, el_ground1.p);
connect(resistor1.n, winding1.p);	connect(Rprim.n, WindingPrim.p);
connect(winding2.port_n, mag_ground.port);	connect(WindingSec.port_n, mag_ground.port);
connect(winding2.p, resistor2.p);	connect(WindingSec.p, Rsec.p);
connect(winding2.n, el_ground2.p);	connect(WindingSec.n, el_ground2.p);
connect(resistor2.n, el_ground2.p);	connect(Rsec.n, el_ground2.p);
connect(winding1.port_p, core.port_p);	connect(WindingPrim.port_p, Core.port_p);
connect(core.port_n, winding2.port_p);	connect(Core.port_n, WindingSec.port_p);

---

model Magnetic.FluxTubes.Examples.Hysteresis.SinglePhaseTransformerWithHysteresis2

Component	Modelica 3.2.3	Modelica 3.2.2
resistor1	Present
resistor2	Present
transformer	Present
Rprim		Present
Rsec		Present
tr		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
connect(SineVoltage.p, resistor1.p);	connect(SineVoltage.p, Rprim.p);
connect(SineVoltage.n, el_ground1.p);
connect(resistor2.n, el_ground2.p);	connect(Rsec.n, el_ground2.p);
connect(resistor1.n, transformer.p1);	connect(Rprim.n, tr.p_A);
connect(transformer.n1, el_ground1.p);	connect(tr.p_N, el_ground1.p);
connect(transformer.p2, resistor2.p);	connect(tr.p_a, Rsec.p);
connect(transformer.n2, el_ground2.p);	connect(tr.p_n, el_ground2.p);

---

model Magnetic.FluxTubes.Examples.Hysteresis.ThreePhaseTransformerWithRectifier

Component	Modelica 3.2.3	Modelica 3.2.2
rExp1	y=transformer.LossPowerStat	y=TR3PhaseYy.LossPowerStat
rExp2	y=transformer.LossPowerEddy	y=TR3PhaseYy.LossPowerEddy
rExp3	y=transformer.LossPowerWinding	y=TR3PhaseYy.LossPowerWinding
ground1	Present
ground2	Present
vSource1	Present
transformer	Present
vSource2	Present
vSource3	Present
resistor1	Present
resistor2	Present
resistor3	Present
diode1	Present
diode2	Present
resistorL	Present
diode3	Present
diode4	Present
diode5	Present
diode6	Present
inductor3	Present
pdissStatAvg	Present
pdissEddyAvg	Present
pdissCopAvg	Present
G1		Present
G2		Present
VA		Present
TR3PhaseYy		Present
VB		Present
VC		Present
RA		Present
RB		Present
RC		Present
D1		Present
D2		Present
RL		Present
D3		Present
D4		Present
D5		Present
D6		Present
inductor		Present
PdissStatAvg		Present
PdissEddyAvg		Present
PdissCopAvg		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
connect(vSource1.n, ground1.p);	connect(VA.n, G1.p);
connect(vSource2.n, ground1.p);	connect(VB.n, G1.p);
connect(vSource3.n, ground1.p);	connect(VC.n, G1.p);
connect(resistor1.n, transformer.p1);	connect(RA.n, TR3PhaseYy.p_A);
connect(resistor1.p, vSource1.p);	connect(RA.p, VA.p);
connect(resistor2.n, transformer.p2);	connect(RB.n, TR3PhaseYy.p_B);
connect(resistor2.p, vSource2.p);	connect(RB.p, VB.p);
connect(vSource3.p, resistor3.p);	connect(VC.p, RC.p);
connect(resistor3.n, transformer.p3);	connect(RC.n, TR3PhaseYy.p_C);
connect(diode2.n, diode1.p);	connect(D2.n, D1.p);
connect(diode4.n, diode3.p);	connect(D4.n, D3.p);
connect(diode6.n, diode5.p);	connect(D6.n, D5.p);
connect(diode2.p, diode4.p);	connect(D2.p, D4.p);
connect(diode4.p, diode6.p);	connect(D4.p, D6.p);
connect(diode1.n, diode3.n);	connect(D1.n, D3.n);
connect(diode3.n, diode5.n);	connect(D3.n, D5.n);
connect(diode5.n, capacitor1.p);	connect(D5.n, capacitor1.p);
connect(resistorL.p, capacitor1.p);	connect(RL.p, capacitor1.p);
connect(transformer.n1, inductor1.p);	connect(TR3PhaseYy.p_a, inductor.p);
connect(transformer.n2, inductor2.p);	connect(TR3PhaseYy.p_b, inductor1.p);
connect(inductor2.n, diode3.p);	connect(inductor1.n, D3.p);
connect(inductor3.p, transformer.n3);	connect(inductor2.p, TR3PhaseYy.p_c);
connect(inductor3.n, diode6.n);	connect(inductor2.n, D6.n);
connect(capacitor2.n, diode6.p);	connect(capacitor2.n, D6.p);
connect(capacitor2.p, capacitor1.n);
connect(inductor1.n, diode1.p);	connect(inductor.n, D1.p);
connect(resistorL.n, capacitor2.n);	connect(RL.n, capacitor2.n);
connect(transformer.starPoint1, ground1.p);	connect(TR3PhaseYy.pN, G1.p);
connect(transformer.starPoint2, ground2.p);	connect(TR3PhaseYy.pn, G2.p);
connect(ground2.p, capacitor2.p);	connect(G2.p, capacitor2.p);
connect(rExp3.y,pdissCopAvg. u);	connect(rExp3.y, PdissCopAvg.u);
connect(rExp2.y,pdissEddyAvg. u);	connect(rExp2.y, PdissEddyAvg.u);
connect(rExp1.y,pdissStatAvg. u);	connect(rExp1.y, PdissStatAvg.u);

---

model Magnetic.FluxTubes.Examples.Hysteresis.Components.Transformer1PhaseWithHysteresis

Component	Modelica 3.2.3	Modelica 3.2.2
n1	Present
p1	Present
n2	Present
p2	Present
tempSource	Present
N1	Present
L1	Present
d1	Present
rho1	Present
alpha1	Present
N2	Present
L2	Present
d2	Present
rho2	Present
alpha2	Present
v1	Present
v2	Present
R1	Present
R2	Present
i1	Present
i2	Present
I1Start	Present
I1Fixed	Present
L_l1	Present
A_l1	Present
mu_rel1	Present
L_l2	Present
A_l2	Present
mu_rel2	Present
winding1	Present
winding2	Present
resistor1	Present
resistor2	Present
core	Present
p_N		Present
p_A		Present
p_n		Present
p_a		Present
Temp		Present
N_p		Present
l_p		Present
d_p		Present
rho_p		Present
alpha_p		Present
N_s		Present
l_s		Present
d_s		Present
rho_s		Present
alpha_s		Present
v_p		Present
v_s		Present
R_p		Present
R_s		Present
i_p		Present
i_s		Present
IpStart		Present
IpFixed		Present
L_lp		Present
A_lp		Present
mu_relp		Present
L_ls		Present
A_ls		Present
mu_rels		Present
Wp		Present
Ws		Present
Rp		Present
Rs		Present
Core		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
v1 =p1.v - n1.v;	v_p = p_A.v-p_N.v;
i1 =resistor1.i;	i_p = Rp.i;
R1 =resistor1.R_actual;	R_p = Rp.R_actual;
v2 =p2.v - n2.v;	v_s = p_a.v-p_n.v;
i2 =resistor2.i;	i_s = Rs.i;
R2 =resistor2.R_actual;	R_s = Rs.R_actual;
B =core.B;	B = Core.B;
Hstat =core.Hstat;	Hstat = Core.Hstat;
Heddy =core.Heddy;	Heddy = Core.Heddy;
H =core.H;	H = Core.H;
tempSource.T = if useHeatPort then T_heatPort else T;	Temp.T = if useHeatPort then T_heatPort else T;
LossPowerWinding =resistor1.LossPower + resistor2.LossPower;	LossPowerWinding = Rp.LossPower + Rs.LossPower;
LossPowerStat =core.LossPowerStat;	LossPowerStat = Core.LossPowerStat;
LossPowerEddy =core.LossPowerEddy;	LossPowerEddy = Core.LossPowerEddy;
LossPower = LossPowerWinding + LossPowerEddy + LossPowerStat;
connect(winding1.port_n, ground.port);	connect(Wp.port_n, ground.port);
connect(resistor1.n, winding1.p);	connect(Rp.n, Wp.p);
connect(resistor1.p, p1);	connect(Rp.p, p_A);
connect(resistor2.n, p2);	connect(Rs.n, p_a);
connect(winding1.n, n1);	connect(Wp.n, p_N);
connect(tempSource.port, resistor1.heatPort);	connect(Temp.port, Rp.heatPort);
connect(resistor2.heatPort, tempSource.port);	connect(Rs.heatPort, Temp.port);
connect(winding2.port_n, ground.port);	connect(Ws.port_n, ground.port);
connect(winding2.n, resistor2.p);	connect(Ws.n, Rs.p);
connect(n2, winding2.p);	connect(p_n, Ws.p);
connect(core.port_p, winding1.port_p);	connect(Core.port_p, Wp.port_p);
connect(core.port_n, winding2.port_p);	connect(Core.port_n, Ws.port_p);

---

model Magnetic.FluxTubes.Examples.Hysteresis.Components.Transformer3PhaseYyWithHysteresis

Component	Modelica 3.2.3	Modelica 3.2.2
N1	Present
L1	Present
d1	Present
rho1	Present
alpha1	Present
N2	Present
L2	Present
d2	Present
rho2	Present
alpha2	Present
v1	Present
v2	Present
R1	Present
R2	Present
i1	Present
i2	Present
I1Start	Present
I1Fixed	Present
I2Start	Present
I2Fixed	Present
L_l1	Present
A_l1	Present
mu_rel1	Present
L_l2	Present
A_l2	Present
mu_rel2	Present
core1	Present
core2	Present
core3	Present
winding11	Present
winding12	Present
winding13	Present
winding21	Present
winding22	Present
winding23	Present
resistor11	Present
resistor21	Present
resistor12	Present
resistor22	Present
resistor23	Present
resistor13	Present
leakage	Present
p1	Present
p2	Present
p3	Present
n1	Present
n2	Present
n3	Present
starPoint2	Present
starPoint1	Present
N_p		Present
l_p		Present
d_p		Present
rho_p		Present
alpha_p		Present
N_s		Present
l_s		Present
d_s		Present
rho_s		Present
alpha_s		Present
v_p		Present
v_s		Present
R_p		Present
R_s		Present
i_p		Present
i_s		Present
IprimStart		Present
IprimFixed		Present
IsecStart		Present
IsecFixed		Present
L_lp		Present
A_lp		Present
mu_relp		Present
L_ls		Present
A_ls		Present
mu_rels		Present
CoreA		Present
CoreB		Present
CoreC		Present
WA		Present
WB		Present
WC		Present
Wa		Present
Wb		Present
Wc		Present
RA		Present
Ra		Present
RB		Present
Rb		Present
Rc		Present
RC		Present
Leakage		Present
p_A		Present
p_B		Present
p_C		Present
p_a		Present
p_b		Present
p_c		Present
pn		Present
pN		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
v1[1] =resistor11.p.v - winding11.n.v;	v_p[1] = RA.p.v-WA.n.v;
v1[2] =resistor12.p.v - winding12.n.v;	v_p[2] = RB.p.v-WB.n.v;
v1[3] =resistor13.p.v - winding13.n.v;	v_p[3] = RC.p.v-WC.n.v;
i1[1] =resistor11.i;	i_p[1] = RA.i;
i1[2] =resistor12.i;	i_p[2] = RB.i;
i1[3] =resistor13.i;	i_p[3] = RC.i;
R1[1] =resistor11.R_actual;	R_p[1] = RA.R_actual;
R1[2] =resistor12.R_actual;	R_p[2] = RB.R_actual;
R1[3] =resistor13.R_actual;	R_p[3] = RC.R_actual;
v2[1] =resistor21.n.v - winding21.n.v;	v_s[1] = Ra.n.v-Wa.n.v;
v2[2] =resistor21.n.v - winding21.n.v;	v_s[2] = Ra.n.v-Wa.n.v;
v2[3] =resistor21.n.v - winding21.n.v;	v_s[3] = Ra.n.v-Wa.n.v;
i2[1] =resistor21.i;	i_s[1] = Ra.i;
i2[2] =resistor22.i;	i_s[2] = Rb.i;
i2[3] =resistor23.i;	i_s[3] = Rc.i;
R2[1] =resistor21.R_actual;	R_s[1] = Ra.R_actual;
R2[2] =resistor22.R_actual;	R_s[2] = Rb.R_actual;
R2[3] =resistor23.R_actual;	R_s[3] = Rc.R_actual;
B[1] =core1.B;	B[1] = CoreA.B;
B[2] =core2.B;	B[2] = CoreB.B;
B[3] =core3.B;	B[3] = CoreC.B;
Phi[1] =core1.Phi;	Phi[1] = CoreA.Phi;
Phi[2] =core2.Phi;	Phi[2] = CoreB.Phi;
Phi[3] =core3.Phi;	Phi[3] = CoreC.Phi;
Hstat[1] =core1.Hstat;	Hstat[1] = CoreA.Hstat;
Hstat[2] =core2.Hstat;	Hstat[2] = CoreB.Hstat;
Hstat[3] =core3.Hstat;	Hstat[3] = CoreC.Hstat;
Heddy[1] =core1.Heddy;	Heddy[1] = CoreA.Heddy;
Heddy[2] =core2.Heddy;	Heddy[2] = CoreB.Heddy;
Heddy[3] =core3.Heddy;	Heddy[3] = CoreC.Heddy;
H[1] =core1.H;	H[1] = CoreA.H;
H[2] =core2.H;	H[2] = CoreB.H;
H[3] =core3.H;	H[3] = CoreC.H;
Temp.T = if useHeatPort then T_heatPort else T;
LossPowerWinding =resistor11.LossPower + resistor12.LossPower + resistor13.LossPower + resistor21.LossPower + resistor22.LossPower + resistor23.LossPower;	LossPowerWinding = RA.LossPower + RB.LossPower + RC.LossPower + Ra.LossPower + Rb.LossPower + Rc.LossPower;
LossPowerStat =core1.LossPowerStat +core2.LossPowerStat +core3.LossPowerStat;	LossPowerStat = CoreA.LossPowerStat + CoreB.LossPowerStat + CoreC.LossPowerStat;
LossPowerEddy =core1.LossPowerEddy +core2.LossPowerEddy +core3.LossPowerEddy;	LossPowerEddy = CoreA.LossPowerEddy + CoreB.LossPowerEddy + CoreC.LossPowerEddy;
LossPower = LossPowerWinding + LossPowerEddy + LossPowerStat;
connect(winding11.port_n, winding21.port_p);	connect(WA.port_n, Wa.port_p);
connect(winding11.p, resistor11.n);	connect(WA.p, RA.n);
connect(resistor11.p, p1);	connect(RA.p, p_A);
connect(winding12.p, resistor12.n);	connect(WB.p, RB.n);
connect(winding13.p, resistor13.n);	connect(WC.p, RC.n);
connect(winding12.port_p, core2.port_n);	connect(WB.port_p, CoreB.port_n);
connect(winding12.port_n, winding22.port_p);	connect(WB.port_n, Wb.port_p);
connect(winding21.port_n, ground.port);	connect(Wa.port_n, ground.port);
connect(ground.port, winding22.port_n);	connect(ground.port, Wb.port_n);
connect(winding23.port_n, ground.port);	connect(Wc.port_n, ground.port);
connect(winding23.port_p, winding13.port_n);	connect(Wc.port_p, WC.port_n);
connect(winding13.port_p, core3.port_n);	connect(WC.port_p, CoreC.port_n);
connect(p2, resistor12.p);	connect(p_B, RB.p);
connect(p3, resistor13.p);	connect(p_C, RC.p);
connect(Temp.port, resistor11.heatPort);	connect(Temp.port, RA.heatPort);
connect(resistor12.heatPort, Temp.port);	connect(RB.heatPort, Temp.port);
connect(resistor13.heatPort, Temp.port);	connect(RC.heatPort, Temp.port);
connect(resistor23.heatPort, Temp.port);	connect(Rc.heatPort, Temp.port);
connect(resistor22.heatPort, Temp.port);	connect(Rb.heatPort, Temp.port);
connect(resistor21.heatPort, Temp.port);	connect(Ra.heatPort, Temp.port);
connect(resistor21.p, winding21.p);	connect(Ra.p, Wa.p);
connect(resistor22.p, winding22.p);	connect(Rb.p, Wb.p);
connect(resistor23.p, winding23.p);	connect(Rc.p, Wc.p);
connect(resistor21.n, n1);	connect(Ra.n, p_a);
connect(resistor22.n, n2);	connect(Rb.n, p_b);
connect(resistor23.n, n3);	connect(Rc.n, p_c);
connect(leakage.port_n, ground.port);	connect(Leakage.port_n, ground.port);
connect(winding11.port_p, core1.port_n);	connect(WA.port_p, CoreA.port_n);
connect(core1.port_p,core2. port_p);	connect(CoreA.port_p, CoreB.port_p);
connect(core3.port_p,core1. port_p);	connect(CoreC.port_p, CoreA.port_p);
connect(leakage.port_p,core3. port_p);	connect(Leakage.port_p, CoreC.port_p);
connect(winding11.n, starPoint1);	connect(WA.n, pN);
connect(starPoint1, winding13.n);	connect(pN, WC.n);
connect(starPoint1, winding12.n);	connect(pN, WB.n);
connect(winding21.n, starPoint2);	connect(Wa.n, pn);
connect(starPoint2, winding22.n);	connect(pn, Wb.n);
connect(winding23.n, starPoint2);	connect(Wc.n, pn);

---

model Magnetic.FluxTubes.Basic.ElectroMagneticConverter

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Phi = port_p.Phi;
V_m = i*N "Ampere's law";	V_m = i*N;
N*der(Phi) = -v "Faraday's law";	N*der(Phi) = -v;
Psi = N*Phi; ...

---

model Magnetic.FluxTubes.Shapes.HysteresisAndMagnets.GenericHystPreisachEverett

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
...
equation init2 = time >= 1.5*t1;	equation init2 = time > 1.5*t1;
init3 = edge(init2); ... del = delAsc or delDesc or evInit;
init = (abs(alpha) >= pre(hmax)) and time>=2*t1;	init = (abs(alpha) >= pre(hmax)) and time>2*t1;
evInit = init and not pre(init); ...

---

model Magnetic.FluxTubes.Interfaces.ConditionalHeatPort

Component	Modelica 3.2.3	Modelica 3.2.2
heatPort	final T=T_heatPort
	final Q_flow=-LossPower
		T(start=T) = T_heatPort
		Q_flow=-LossPower

---

model Magnetic.FluxTubes.Interfaces.PartialGenericHysteresis

Component	Modelica 3.2.3	Modelica 3.2.2
derHstat		fixed=true

---

model Magnetic.FundamentalWave.Examples.BasicMachines.AIMC_DOL

Component	Modelica 3.2.3	Modelica 3.2.2
fNominal	=aimcData.fsNominal	=50
aimcM	effectiveStatorTurns=aimcData.effectiveStatorTurns

---

model Magnetic.FundamentalWave.Examples.BasicMachines.AIMC_DOL_MultiPhase

Component	Modelica 3.2.3	Modelica 3.2.2
fNominal	=aimcData.fsNominal	=50
aimcM	effectiveStatorTurns=aimcData.effectiveStatorTurns
aimc3	effectiveStatorTurns=aimcData.effectiveStatorTurns

---

model Magnetic.FundamentalWave.Examples.BasicMachines.AIMS_Start

Component	Modelica 3.2.3	Modelica 3.2.2
fNominal	=aimsData.fsNominal	=50
aimsM	effectiveStatorTurns=aimsData.effectiveStatorTurns

---

model Magnetic.FundamentalWave.Examples.BasicMachines.AIMS_Start_MultiPhase

Component	Modelica 3.2.3	Modelica 3.2.2
fNominal	=aimsData.fsNominal	=50
w_Load	=Modelica323.SIunits.Conversions.from_rpm(1440.45)	=Modelica.SIunits.Conversions.from_rpm(1440.45)
aimsM	effectiveStatorTurns=aimsData.effectiveStatorTurns
aims3	effectiveStatorTurns=aimsData.effectiveStatorTurns
sineVoltageM	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)
sineVoltage3	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m3)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m3)

---

model Magnetic.FundamentalWave.Examples.BasicMachines.SMPM_Inverter

Component	Modelica 3.2.3	Modelica 3.2.2
fsNominal	=smpmData.fsNominal	=50
smpmM	ir(each fixed=true)
	effectiveStatorTurns=smpmData.effectiveStatorTurns
		ir(fixed=true)
smpmE	ir(each fixed=true)
		ir(fixed=true)
thetaM	Present
thetaE	Present

---

model Magnetic.FundamentalWave.Examples.BasicMachines.SMPM_Inverter_MultiPhase

Component	Modelica 3.2.3	Modelica 3.2.2
fsNominal	=smpmData.fsNominal	=50
vfController3	BasePhase=+Modelica323.Constants.pi/2	BasePhase=+Modelica.Constants.pi/2
	orientation=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m3)	orientation=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m3)
smpmM	ir(each fixed=true)
	effectiveStatorTurns=smpmData.effectiveStatorTurns
		ir(fixed=true)
smpm3	ir(each fixed=true)
	effectiveStatorTurns=smpmData.effectiveStatorTurns
		ir(fixed=true)
vfController	BasePhase=+Modelica323.Constants.pi/2	BasePhase=+Modelica.Constants.pi/2
	orientation=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	orientation=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Magnetic.FundamentalWave.Examples.BasicMachines.SMEE_Generator_MultiPhase

Component	Modelica 3.2.3	Modelica 3.2.2
fsNominal	=smeeData.fsNominal	=50
w	=Modelica323.SIunits.Conversions.from_rpm(1499)	=Modelica.SIunits.Conversions.from_rpm(1499)
Lssigma	=0.1/(2*Modelica323.Constants.pi*fsNominal)	=0.1/(2*Modelica.Constants.pi*fsNominal)
Lmd	=1.5/(2*Modelica323.Constants.pi*fsNominal)	=1.5/(2*Modelica.Constants.pi*fsNominal)
Lmq	=1.5/(2*Modelica323.Constants.pi*fsNominal)	=1.5/(2*Modelica.Constants.pi*fsNominal)
Lrsigmad	=0.05/(2*Modelica323.Constants.pi*fsNominal)	=0.05/(2*Modelica.Constants.pi*fsNominal)
sineVoltage3	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m3)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m3)
smeeM	phiMechanical(start=-(Modelica323.Constants.pi + gamma0)/p, fixed=true)	phiMechanical(start=-(Modelica.Constants.pi + gamma0)/p, fixed=true)
	sigmae=smeeData.sigmae*m/3	sigmae=smeeData.sigmae
	ir(each fixed=true)
	effectiveStatorTurns=smeeData.effectiveStatorTurns
		ir(fixed=true)
smee3	phiMechanical(start=-(Modelica323.Constants.pi + gamma0)/p, fixed=true)	phiMechanical(start=-(Modelica.Constants.pi + gamma0)/p, fixed=true)
	ir(each fixed=true)
	effectiveStatorTurns=smeeData.effectiveStatorTurns
		ir(fixed=true)
smeeData	alpha20s(displayUnit="1/K") = Modelica323.Electrical.Machines.Thermal.Constants.alpha20Zero	alpha20s(displayUnit="1/K") = Modelica.Electrical.Machines.Thermal.Constants.alpha20Zero
	alpha20r(displayUnit="1/K") = Modelica323.Electrical.Machines.Thermal.Constants.alpha20Zero	alpha20r(displayUnit="1/K") = Modelica.Electrical.Machines.Thermal.Constants.alpha20Zero
	alpha20e(displayUnit="1/K") = Modelica323.Electrical.Machines.Thermal.Constants.alpha20Zero	alpha20e(displayUnit="1/K") = Modelica.Electrical.Machines.Thermal.Constants.alpha20Zero
sineVoltageM	phase=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	phase=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Magnetic.FundamentalWave.Examples.BasicMachines.SMEE_Generator

Component	Modelica 3.2.3	Modelica 3.2.2
fsNominal	=smeeData.fsNominal	=50
smeeM	effectiveStatorTurns=smeeData.effectiveStatorTurns
thetaM	Present
thetaE	Present

---

model Magnetic.FundamentalWave.Examples.BasicMachines.SMR_Inverter

Component	Modelica 3.2.3	Modelica 3.2.2
fsNominal	=smrData.fsNominal	=50
smrM	ir(each fixed=true)
	effectiveStatorTurns=smrData.effectiveStatorTurns
		ir(fixed=true)
smrE	ir(each fixed=true)
		ir(fixed=true)
thetaM	Present
thetaE	Present

---

model Magnetic.FundamentalWave.Examples.BasicMachines.SMR_Inverter_MultiPhase

Component	Modelica 3.2.3	Modelica 3.2.2
fsNominal	=smrData.fsNominal	=50
smrM	ir(each fixed=true)
	effectiveStatorTurns=smrData.effectiveStatorTurns
		ir(fixed=true)
smr3	ir(each fixed=true)
	effectiveStatorTurns=smrData.effectiveStatorTurns
		ir(fixed=true)
vfController3	BasePhase=+Modelica323.Constants.pi/2	BasePhase=+Modelica.Constants.pi/2
	orientation=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m3)	orientation=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m3)
vfControllerM	BasePhase=+Modelica323.Constants.pi/2	BasePhase=+Modelica.Constants.pi/2
	orientation=-Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	orientation=-Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)

---

model Magnetic.FundamentalWave.BasicMachines.SynchronousInductionMachines.SM_PermanentMagnet

Component	Modelica 3.2.3	Modelica 3.2.2
ir	graphical
groundR		Present

---

model Magnetic.FundamentalWave.BasicMachines.SynchronousInductionMachines.SM_ElectricalExcited

Component	Modelica 3.2.3	Modelica 3.2.2
ir	graphical

---

model Magnetic.FundamentalWave.BasicMachines.SynchronousInductionMachines.SM_ReluctanceRotor

Component	Modelica 3.2.3	Modelica 3.2.2
ir	graphical
groundR		Present

---

model Magnetic.FundamentalWave.BasicMachines.Components.SymmetricMultiPhaseWinding

Component	Modelica 3.2.3	Modelica 3.2.2
nBase	Present
mBase	Present
short	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(resistor.plug_n, zeroInductor.plug_p);
	connect(zeroInductor.plug_n, electroMagneticConverter.plug_p);
connect(electroMagneticConverter.plug_n, plug_n); ... connect(strayReluctance.port_p, electroMagneticConverter.port_p);
connect(zeroInductor.plug_n, electroMagneticConverter.plug_p); connect(resistor.plug_n, short.plug_p); connect(electroMagneticConverter.plug_p, short.plug_n);

---

model Magnetic.FundamentalWave.BasicMachines.Components.RotorSaliencyAirGap

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
port_sp.Phi = Phi_ss "Stator flux into positive stator port";	port_sp.Phi = Phi_ss;
port_sp.Phi + port_sn.Phi = Complex(0, 0) "Balance of stator flux";	port_sp.Phi + port_sn.Phi = Complex(0, 0);
port_rp.Phi = Phi_rr "Rotor flux into positive rotor port";	port_rp.Phi = Phi_rr;
port_rp.Phi + port_rn.Phi = Complex(0, 0) "Balance of rotor flux";	port_rp.Phi + port_rn.Phi = Complex(0, 0);
port_sp.V_m - port_sn.V_m = V_mss "Magnetomotive force of stator";	port_sp.V_m - port_sn.V_m = V_mss;
port_rp.V_m - port_rn.V_m = V_mrr "Magnetomotive force of rotor";	port_rp.V_m - port_rn.V_m = V_mrr;
V_msr = V_mss*Modelica323.ComplexMath.conj(rotator);
Phi_sr = Phi_ss*Modelica323.ComplexMath.conj(rotator);
Phi_sr = Phi_rr;
	V_msr = V_mss*Modelica322.ComplexMath.conj(rotator);
(pi/2.0)*(V_mrr.re + V_msr.re) = Phi_rr.re*R_m.d; ...

---

model Magnetic.FundamentalWave.BasicMachines.Components.SymmetricMultiPhaseCageWinding

Component	Modelica 3.2.3	Modelica 3.2.2
alphaRef	=Modelica323.Electrical.Machines.Thermal.convertAlpha(alpha20, TRef, 293.15)	=Modelica.Electrical.Machines.Thermal.convertAlpha(alpha20, TRef, 293.15)
electroMagneticConverter	final orientation=Modelica323.Electrical.MultiPhase.Functions.symmetricOrientation(m)	final orientation=Modelica.Electrical.MultiPhase.Functions.symmetricOrientation(m)
resistor	final T=fill(TOperational, m)	final T=fill(TRef, m)
star	final m=nBase	final m=m
nBase	Present
multiStar	Present
starAuxiliary		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(ground.p, star.pin_n);
	connect(star.plug_p, electroMagneticConverter.plug_n);
connect(thermalCollector.port_a, resistor.heatPort);
connect(thermalCollector.port_b, heatPortWinding);
	connect(resistor.plug_n, starAuxiliary.plug_p);
connect(strayReluctance.port_p, port_p); ... connect(electroMagneticConverter.plug_p, resistor.plug_p);
connect(electroMagneticConverter.plug_n, multiStar.plug_p); connect(multiStar.starpoints, star.plug_p); connect(resistor.plug_n, multiStar.plug_p);

---

model Magnetic.FundamentalWave.BasicMachines.Components.SaliencyCageWinding

Component	Modelica 3.2.3	Modelica 3.2.2
alphaRef	=Modelica323.Electrical.Machines.Thermal.convertAlpha(alpha20, TRef, 293.15)	=Modelica.Electrical.Machines.Thermal.convertAlpha(alpha20, TRef, 293.15)
electroMagneticConverter	final orientation={0,Modelica323.Constants.pi/2}	final orientation={0,Modelica.Constants.pi/2}

---

model Magnetic.FundamentalWave.BasicMachines.Components.SymmetricMultiPhaseCageWinding_obsolete

Component	Modelica 3.2.3	Modelica 3.2.2
resistor	final T=fill(TOperational, m)	final T=fill(TRef, m)

---

connector Magnetic.FundamentalWave.Interfaces.MagneticPort

Component	Modelica 3.2.3	Modelica 3.2.2
V_m	SIunits.ComplexMagneticPotential	SIunits.ComplexMagneticPotentialDifference

---

model Magnetic.FundamentalWave.Interfaces.PartialBasicInductionMachine

Component	Modelica 3.2.3	Modelica 3.2.2
pi	SIunits.Angle	Real
		protected
statorCoreParameters	final m=m	final m=3
internalThermalPort		protected
internalSupport		protected

---

model Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMC_DOL

Component	Modelica 3.2.3	Modelica 3.2.2
m	=3	=5
fNominal	=imc.fsNominal	=50
imc	effectiveStatorTurns=imcData.effectiveStatorTurns
imcQS	effectiveStatorTurns=imcData.effectiveStatorTurns
terminalBox	Present
starMachine	Present
groundMachine	Present
terminalBoxM		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial equation
sum(imc.is) = 0;
imc.is[1:2] = zeros(2);
imc.rotorCage.electroMagneticConverter.V_m = Complex(0, 0);	imc.rotorCage.electroMagneticConverter.Phi = Complex(0, 0);
... connect(loadInertia.flange_b, quadraticLoadTorque.flange);
connect(terminalBox.plug_sn, imc.plug_sn);	connect(terminalBoxM.plug_sn, imc.plug_sn);
connect(terminalBox.plug_sp, imc.plug_sp);	connect(terminalBoxM.plug_sp, imc.plug_sp);
connect(booleanStep.y, idealCloser.control); ... connect(powerSensor.nc, currentQuasiRMSSensor.plug_p);
connect(currentQuasiRMSSensor.plug_n, terminalBox.plugSupply);	connect(currentQuasiRMSSensor.plug_n, terminalBoxM.plugSupply);
connect(loadInertiaQS.flange_b, quadraticLoadTorqueQS.flange); ... connect(starMachineQS.pin_n, groundMachineQS.pin);
connect(starMachine.plug_p, terminalBox.starpoint); connect(groundMachine.p, starMachine.pin_n);

---

model Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMS_Start

Component	Modelica 3.2.3	Modelica 3.2.2
fNominal	=ims.fsNominal	=50
terminalBoxM	Electrical.Machines.Utilities.MultiTerminalBox	Electrical.Machines.Utilities.TerminalBox
ims	effectiveStatorTurns=imsData.effectiveStatorTurns
imsQS	effectiveStatorTurns=imsData.effectiveStatorTurns
rheostatQS	Present
loadInertiaQS	Present
quadraticLoadTorqueQS	Present
starMachine	Present
groundMachine	Present
rheostatE		Present
loadInertiaE		Present
quadraticLoadTorqueE		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial equation
sum(ims.is) = 0;
ims.is[1:2] = zeros(2);
sum(ims.ir) = 0;	ims.ir[1:mr] = zeros(mr);
ims.ir[1:2] = zeros(2);
... connect(sineVoltage.plug_n, star.plug_p);
connect(loadInertiaQS.flange_b, quadraticLoadTorqueQS.flange);	connect(loadInertiaE.flange_b, quadraticLoadTorqueE.flange);
connect(imsQS.flange, loadInertiaQS.flange_a);	connect(imsQS.flange, loadInertiaE.flange_a);
connect(booleanStep.y, idealCloser.control); ... connect(idealCloser.plug_p, sineVoltage.plug_p);
connect(imsQS.plug_rp, rheostatQS.plug_p);	connect(imsQS.plug_rp, rheostatE.plug_p);
connect(rheostatQS.plug_n, imsQS.plug_rn);	connect(rheostatE.plug_n, imsQS.plug_rn);
connect(groundQS.pin, starQS.pin_n); ... connect(starMachineQS.plug_p, terminalBoxQS.starpoint);
connect(groundMachine.p,starMachine. pin_n); connect(terminalBoxM.starpoint, starMachine.plug_p);

---

model Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.SynchronousMachines.SMPM_OpenCircuit

Component	Modelica 3.2.3	Modelica 3.2.2
smpmQS	effectiveStatorTurns=smpmData.effectiveStatorTurns
smpm	effectiveStatorTurns=smpmData.effectiveStatorTurns

---

model Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.SynchronousMachines.SMPM_Mains

Component	Modelica 3.2.3	Modelica 3.2.2
smpmQS	effectiveStatorTurns=smpmData.effectiveStatorTurns
smpm	ir(each fixed=true, start=zeros(2))
	effectiveStatorTurns=smpmData.effectiveStatorTurns
		ir(fixed=true, start=zeros(2))
terminalBox	Electrical.Machines.Utilities.MultiTerminalBox	Electrical.Machines.Utilities.TerminalBox
starMachine	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial equation
sum(smpm.is)=0;	smpm.is=zeros(m);
smpm.is[1:2]=zeros(2);
... connect(star.pin_n, ground.p);
	connect(groundMachine.p, terminalBox.starpoint);
connect(powerSensor.nv, star.plug_p);
connect(terminalBox.starpoint, starMachine.plug_p); connect(starMachine.pin_n, groundMachine.p);

---

model Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.SynchronousMachines.SMPM_CurrentSource

Component	Modelica 3.2.3	Modelica 3.2.2
fNominal	=smpmData.fsNominal	=50
smpm	m=m
	effectiveStatorTurns=smpmData.effectiveStatorTurns
currentController	m=m
iq	k=84.6*3/m	k=84.6
id	k=-53.5*3/m	k=-53.5
voltageQuasiRMSSensor	m=m
terminalBox	Electrical.Machines.Utilities.MultiTerminalBox	Electrical.Machines.Utilities.TerminalBox
currentRMSsensor	m=m
smpmQS	m=m
	effectiveStatorTurns=smpmData.effectiveStatorTurns
thetaQS	Present
theta	Present
rotorAngle	Present
currentControllerQS	Present
referenceCurrentSourceQS	Present
resistorQS	Present
rotorAngleQS	Present
currentRMSSensorQS	Present
voltageQuasiRMSSensorQS	Present
starMQS	Present
starMachine	Present
rotorDisplacementAngle		Present
currentController1		Present
referenceCurrentSource		Present
resistor		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
connect(star.pin_n, ground.p);
connect(rotorAngle.plug_n, smpm.plug_sn);	connect(rotorDisplacementAngle.plug_n, smpm.plug_sn);
connect(rotorAngle.plug_p, smpm.plug_sp);	connect(rotorDisplacementAngle.plug_p, smpm.plug_sp);
connect(terminalBox.plug_sn, smpm.plug_sn);
connect(terminalBox.plug_sp, smpm.plug_sp);
connect(smpm.flange, rotorAngle.flange);	connect(smpm.flange, rotorDisplacementAngle.flange);
connect(signalCurrent.plug_p, star.plug_p);
connect(angleSensor.flange, rotorAngle.flange);	connect(angleSensor.flange, rotorDisplacementAngle.flange);
	connect(angleSensor.phi, currentController.phi); connect(id.y, currentController.id_rms); connect(iq.y, currentController.iq_rms); connect(groundM.p, terminalBox.starpoint);
connect(voltageQuasiRMSSensor.plug_p, terminalBox.plugSupply); ... connect(starM.pin_n, groundM.p);
	connect(currentController.y, signalCurrent.i);
connect(quadraticSpeedDependentTorque.flange, inertiaLoad.flange_b); ... connect(quadraticSpeedDependentTorqueQS.flange, inertiaLoadQS.flange_b);
	connect(smpmQS.flange, inertiaLoadQS.flange_a);
connect(starMachineQS.plug_p, terminalBoxQS.starpoint); ... connect(terminalBoxQS.plug_sp, smpmQS.plug_sp);
connect(currentControllerQS.I, referenceCurrentSourceQS.I);	connect(angleSensorQS.phi, currentController1.phi);
connect(referenceCurrentSourceQS.plug_p, starQS.plug_p);	connect(currentController1.I, referenceCurrentSource.I);
	connect(referenceCurrentSource.plug_p, starQS.plug_p);
connect(starQS.pin_n, groundeQS.pin);
	connect(currentController1.id_rms, id.y); connect(iq.y, currentController1.iq_rms);
connect(angleSensorQS.flange, smpmQS.flange);
connect(referenceCurrentSourceQS.plug_p, resistorQS.plug_p);	connect(currentController1.gamma, referenceCurrentSource.gamma);
connect(resistorQS.plug_n, referenceCurrentSourceQS.plug_n);	connect(referenceCurrentSource.plug_n, terminalBoxQS.plugSupply);
connect(id.y, currentControllerQS.id_rms);	connect(referenceCurrentSource.plug_p, resistor.plug_p);
connect(id.y, currentController.id_rms);	connect(resistor.plug_n, referenceCurrentSource.plug_n);
connect(iq.y, currentControllerQS.iq_rms); connect(iq.y, currentController.iq_rms); connect(currentController.y, signalCurrent.i); connect(currentControllerQS.gamma, referenceCurrentSourceQS.gamma); connect(angleSensorQS.phi, currentControllerQS.phi); connect(angleSensor.phi, currentController.phi); connect(smpmQS.flange, rotorAngleQS.flange); connect(terminalBoxQS.plug_sp, rotorAngleQS.plug_p); connect(terminalBoxQS.plugSupply, currentRMSSensorQS.plug_n); connect(currentRMSSensorQS.plug_p, referenceCurrentSourceQS.plug_n); connect(inertiaLoadQS.flange_a, smpmQS.flange); connect(rotorAngleQS.plug_n, terminalBoxQS.plug_sn); connect(voltageQuasiRMSSensorQS.plug_n, currentRMSSensorQS.plug_n); connect(starMQS.pin_n, starMachineQS.pin_n); connect(starMQS.plug_p, voltageQuasiRMSSensorQS.plug_p); connect(starMachine.plug_p, terminalBox.starpoint); connect(starMachine.pin_n, groundM.p);

---

model Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.SynchronousMachines.SMEE_Generator

Component	Modelica 3.2.3	Modelica 3.2.2
fsNominal	=smeeData.fsNominal	=50
terminalBoxM	Electrical.Machines.Utilities.MultiTerminalBox	Electrical.Machines.Utilities.TerminalBox
smee	sigmae=smeeData.sigmae*m/3	sigmae=smeeData.sigmae
	ir(each fixed=true)
	effectiveStatorTurns=smeeData.effectiveStatorTurns
		ir(fixed=true)
smeeQS	effectiveStatorTurns=smeeData.effectiveStatorTurns
thetaQS	Present
theta	Present
rotorAngle	Present
rotorAngleQS	Present
groundMachine	Present
starMachine	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial equation
sum(smee.is) = 0;
smee.is[1:2] = zeros(2); ... connect(star.plug_p, sineVoltage.plug_n);
	connect(smeeQS.flange, mechanicalPowerSensorQS.flange_a);
connect(mechanicalPowerSensorQS.flange_b, constantSpeedQS.flange); ... connect(starMachineQS.plug_p, terminalBoxQS.starpoint);
connect(smee.flange, rotorAngle.flange); connect(rotorAngle.plug_p, smee.plug_sp); connect(smee.plug_sn, rotorAngle.plug_n); connect(terminalBoxQS.plug_sp, rotorAngleQS.plug_p); connect(rotorAngleQS.plug_n, terminalBoxQS.plug_sn); connect(smeeQS.flange, rotorAngleQS.flange); connect(smeeQS.flange, mechanicalPowerSensorQS.flange_a); connect(starMachine.pin_n,groundMachine. p); connect(starMachine.plug_p, terminalBoxM.starpoint);

---

model Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.SynchronousMachines.SMR_CurrentSource

Component	Modelica 3.2.3	Modelica 3.2.2
fNominal	=smrData.fsNominal	=50
currentController	m=m
iq	k=84.6*3/m	k=84.6
id	k=53.5*3/m	k=53.5
voltageQuasiRMSSensor	m=m
terminalBox	Electrical.Machines.Utilities.MultiTerminalBox	Electrical.Machines.Utilities.TerminalBox
rotorDisplacementAngle	m=m
currentRMSsensor	m=m
referenceCurrentSource	m=m
smrQS	effectiveStatorTurns=smrData.effectiveStatorTurns
smr	ir(each fixed=true)
	effectiveStatorTurns=smrData.effectiveStatorTurns
		ir(fixed=true)
thetaQS	Present
theta	Present
currentControllerQS	Present
resistorQS	Present
rotorAngleQS	Present
currentRMSSensorQS	Present
voltageQuasiRMSSensorQS	Present
starMQS	Present
starMachine	Present
currentController1		Present
resistor		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(angleSensor.flange, rotorDisplacementAngle.flange);
	connect(angleSensor.phi, currentController.phi); connect(id.y, currentController.id_rms); connect(iq.y, currentController.iq_rms); connect(groundM.p, terminalBox.starpoint);
connect(voltageQuasiRMSSensor.plug_p, terminalBox.plugSupply); ... connect(starM.pin_n, groundM.p);
	connect(currentController.y, signalCurrent.i);
connect(quadraticSpeedDependentTorque.flange, inertiaLoad.flange_b); ... connect(groundMQS.pin, starMachineQS.pin_n);
connect(currentControllerQS.I, referenceCurrentSource.I);	connect(angleSensorQS.phi, currentController1.phi);
	connect(currentController1.I, referenceCurrentSource.I);
connect(referenceCurrentSource.plug_p, starQS.plug_p);
connect(starQS.pin_n, groundeQS.pin);
connect(referenceCurrentSource.plug_p, resistorQS.plug_p);	connect(currentController1.id_rms, id.y);
connect(resistorQS.plug_n, referenceCurrentSource.plug_n);	connect(iq.y, currentController1.iq_rms);
	connect(currentController1.gamma, referenceCurrentSource.gamma); connect(referenceCurrentSource.plug_n, terminalBoxQS.plugSupply); connect(referenceCurrentSource.plug_p, resistor.plug_p); connect(resistor.plug_n, referenceCurrentSource.plug_n);
connect(terminalBoxQS.plug_sn, smrQS.plug_sn);
connect(terminalBoxQS.plug_sp, smrQS.plug_sp);
	connect(smrQS.flange, inertiaLoadQS.flange_a);
connect(angleSensorQS.flange, smrQS.flange); ... connect(rotorDisplacementAngle.flange, inertiaLoad.flange_a);
connect(smrQS.flange, rotorAngleQS.flange); connect(smrQS.plug_sp, rotorAngleQS.plug_p); connect(smrQS.plug_sn, rotorAngleQS.plug_n); connect(inertiaLoadQS.flange_a, smrQS.flange); connect(currentRMSSensorQS.plug_p, referenceCurrentSource.plug_n); connect(currentRMSSensorQS.plug_n, terminalBoxQS.plugSupply); connect(id.y, currentControllerQS.id_rms); connect(id.y, currentController.id_rms); connect(iq.y, currentControllerQS.iq_rms); connect(iq.y, currentController.iq_rms); connect(angleSensor.phi, currentController.phi); connect(currentController.y, signalCurrent.i); connect(currentControllerQS.gamma, referenceCurrentSource.gamma); connect(angleSensorQS.phi, currentControllerQS.phi); connect(starMQS.plug_p, voltageQuasiRMSSensorQS.plug_p); connect(voltageQuasiRMSSensorQS.plug_n, currentRMSSensorQS.plug_n); connect(starMQS.pin_n, groundMQS.pin); connect(starMachine.pin_n, groundM.p); connect(starMachine.plug_p, terminalBox.starpoint);

---

model Magnetic.QuasiStatic.FundamentalWave.BasicMachines.SynchronousMachines.SM_PermanentMagnet

Component	Modelica 3.2.3	Modelica 3.2.2
ir	graphical

---

model Magnetic.QuasiStatic.FundamentalWave.BasicMachines.SynchronousMachines.SM_ElectricalExcited

Component	Modelica 3.2.3	Modelica 3.2.2
ir	graphical

---

model Magnetic.QuasiStatic.FundamentalWave.BasicMachines.SynchronousMachines.SM_ReluctanceRotor

Component	Modelica 3.2.3	Modelica 3.2.2
ir	graphical

---

model Magnetic.QuasiStatic.FundamentalWave.BasicMachines.Components.RotorSaliencyAirGap

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
port_sp.Phi = Phi_s "Stator flux into positive stator port";	port_sp.Phi = Phi_s;
port_sp.Phi + port_sn.Phi = Complex(0, 0) "Balance of stator flux";	port_sp.Phi + port_sn.Phi = Complex(0, 0);
port_rp.Phi = Phi_r "Rotor flux into positive rotor port";	port_rp.Phi = Phi_r;
port_rp.Phi + port_rn.Phi = Complex(0, 0) "Balance of rotor flux";	port_rp.Phi + port_rn.Phi = Complex(0, 0);
port_sp.V_m - port_sn.V_m = V_ms "Magnetomotive force of stator";	port_sp.V_m - port_sn.V_m = V_ms;
port_rp.V_m - port_rn.V_m = V_mr "Magnetomotive force of rotor";	port_rp.V_m - port_rn.V_m = V_mr;
Phi_s = Phi_r; ...

---

model Magnetic.QuasiStatic.FundamentalWave.BasicMachines.Components.SymmetricMultiPhaseCageWinding

Component	Modelica 3.2.3	Modelica 3.2.2
resistor	final T=fill(TOperational, m)	final T=fill(TRef, m)
star	final m=nBase	final m=m
nBase	Present
multiStar	Present
starAuxiliary		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(electroMagneticConverter.port_n, port_n);
	connect(starAuxiliary.plug_p, resistor.plug_n); connect(electroMagneticConverter.plug_n, star.plug_p);
connect(star.pin_n, ground.pin);
	connect(starAuxiliary.pin_n, ground.pin);
connect(strayReluctance.port_p, port_p); ... connect(electroMagneticConverter.plug_p, resistor.plug_p);
connect(electroMagneticConverter.plug_n, multiStar.plug_p); connect(multiStar.starpoints, star.plug_p); connect(multiStar.plug_p, resistor.plug_n);

---

model Magnetic.QuasiStatic.FundamentalWave.BasicMachines.Components.SaliencyCageWinding

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(electroMagneticConverter.port_n, port_n);
	connect(electroMagneticConverter.plug_n, resistor.plug_n); connect(resistor.plug_n, star.plug_p);
connect(star.pin_n, ground.pin);
	connect(electroMagneticConverter.plug_p, resistor.plug_p);
connect(strayReluctance.port_p, port_p);
connect(strayReluctance.port_n, port_n);
connect(electroMagneticConverter.plug_p, resistor.plug_p); connect(electroMagneticConverter.plug_n, star.plug_p); connect(star.plug_p, resistor.plug_n);

---

model Magnetic.QuasiStatic.FundamentalWave.BasicMachines.Components.PermanentMagnet

Component	Modelica 3.2.3	Modelica 3.2.2
abs_V_m	=Modelica323.ComplexMath.'abs'(V_m)	=Modelica.ComplexMath.'abs'(V_m)
arg_V_m	=Modelica323.ComplexMath.arg(V_m)	=Modelica.ComplexMath.arg(V_m)
abs_Phi	=Modelica323.ComplexMath.'abs'(Phi)	=Modelica.ComplexMath.'abs'(Phi)
arg_Phi	=Modelica323.ComplexMath.arg(Phi)	=Modelica.ComplexMath.arg(Phi)
V_mGamma	=V_m*Modelica323.ComplexMath.fromPolar(1, -gamma)	=V_m*Modelica.ComplexMath.fromPolar(1, -gamma)

---

model Magnetic.QuasiStatic.FundamentalWave.BasicMachines.BaseClasses.PartialBasicMachine

Component	Modelica 3.2.3	Modelica 3.2.2
pi	SIunits.Angle	Real
		protected
statorCoreParameters	final m=m	final m=3
abs_vs	=Modelica323.ComplexMath.'abs'(vs)	=Modelica.ComplexMath.'abs'(vs)
arg_vs	=Modelica323.ComplexMath.arg(vs)	=Modelica.ComplexMath.arg(vs)
abs_is	=Modelica323.ComplexMath.'abs'(is)	=Modelica.ComplexMath.'abs'(is)
arg_is	=Modelica323.ComplexMath.arg(is)	=Modelica.ComplexMath.arg(is)
Ps	={Modelica323.ComplexMath.real(vs[k]*Modelica323.ComplexMath.conj(is[k])) for k in 1:m}	={Modelica.ComplexMath.real(vs[k]*Modelica.ComplexMath.conj(is[k])) for k in 1:m}
Qs	={Modelica323.ComplexMath.imag(vs[k]*Modelica323.ComplexMath.conj(is[k])) for k in 1:m}	={Modelica.ComplexMath.imag(vs[k]*Modelica.ComplexMath.conj(is[k])) for k in 1:m}
Ss	={Modelica323.ComplexMath.'abs'(vs[k]*Modelica323.ComplexMath.conj(is[k])) for k in 1:m}	={Modelica.ComplexMath.'abs'(vs[k]*Modelica.ComplexMath.conj(is[k])) for k in 1:m}
pfs	={cos(Modelica323.ComplexMath.arg(Complex(Ps[k], Qs[k]))) for k in 1:m}	={cos(Modelica.ComplexMath.arg(Complex(Ps[k], Qs[k]))) for k in 1:m}
internalThermalPort		protected
internalSupport		protected

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
initial algorithm
assert(not Modelica323.Math.isPowerOf2(m), String(m) + " phases are currently not supported in this version of FundametalWave");	assert(not Modelica.Math.isPowerOf2(m), String(m) + " phases are currently not supported in this version of FundametalWave");
...

---

model Magnetic.QuasiStatic.FundamentalWave.Losses.StrayLoad

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
tau = -strayLoadParameters.tauRef*(iRMS/strayLoadParameters.IRef)^2* sign(w)*(abs(w)/strayLoadParameters.wRef)^strayLoadParameters.power_w;	tau = -strayLoadParameters.tauRef*(iRMS/strayLoadParameters.IRef)^2* smooth(1, if w >= 0 then +(+w/strayLoadParameters.wRef)^ strayLoadParameters.power_w else -(-w/strayLoadParameters.wRef)^ strayLoadParameters.power_w);
end if; ...

---

model Magnetic.QuasiStatic.FundamentalWave.Losses.PermanentMagnetLosses

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
tau = -permanentMagnetLossParameters.tauRef*(permanentMagnetLossParameters.c + (1 - permanentMagnetLossParameters.c)* (iRMS/permanentMagnetLossParameters.IRef)^permanentMagnetLossParameters.power_I)* sign(w)*(abs(w)/permanentMagnetLossParameters.wRef)^permanentMagnetLossParameters.power_w;	tau = -permanentMagnetLossParameters.tauRef*( permanentMagnetLossParameters.c + (1 - permanentMagnetLossParameters.c) *(iRMS/permanentMagnetLossParameters.IRef)^ permanentMagnetLossParameters.power_I)*smooth(1, if w >= 0 then +(+w/ permanentMagnetLossParameters.wRef)^permanentMagnetLossParameters.power_w else -(-w/permanentMagnetLossParameters.wRef)^ permanentMagnetLossParameters.power_w);
end if; ...

---

block Magnetic.QuasiStatic.FundamentalWave.Utilities.VfController

Component	Modelica 3.2.3	Modelica 3.2.2
u	unit="Hz"

---

model Magnetic.QuasiStatic.FundamentalWave.Utilities.CurrentController

Component	Modelica 3.2.3	Modelica 3.2.2
gamma	unit="rad"

---

model Mechanics.MultiBody.World

Component	Modelica 3.2.3	Modelica 3.2.2
g	=Modelica323.Constants.g_n	=9.81
mue	=3.986004418e14	=3.986e14
animateGround	Present
groundAxis_u	Present
groundLength_u	Present
groundLength_v	Present
groundColor	Present
surface	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
Connections.root(frame_b.R);
assert(Modelica323.Math.Vectors.length(n) > 1e-10, "Parameter n of World object is wrong (length(n) > 0 required)");	assert(Modelica322.Math.Vectors.length(n) > 1.e-10, "Parameter n of World object is wrong (length(n) > 0 required)");
frame_b.r_0 = zeros(3); ...

---

model Mechanics.MultiBody.Examples.Elementary.DoublePendulumInitTip

Component	Modelica 3.2.3	Modelica 3.2.2
revolute2	phi(start=Modelica323.Constants.pi/2)

---

model Mechanics.MultiBody.Examples.Elementary.PointGravityWithPointMasses2

Component	Modelica 3.2.3	Modelica 3.2.2
pointMass3	r_0(start={2,1,0}, fixed={true,false,false})	r_0(start={2,1,0}, each fixed=true)
	v_0(start={0,0,-1}, fixed={true,false,false})	v_0(start={0,0,-1}, each fixed=true)
pointMass4	r_0(start={2,-1,0}, fixed={false,false,true})
	v_0(start={0,0,-1}, fixed={false,false,true})
pointMass5	r_0(start={2,0,1}, fixed={false,false,true})
	v_0(start={0,0,-1}, fixed={false,false,true})

---

model Mechanics.MultiBody.Examples.Elementary.RollingWheel

Component	Modelica 3.2.3	Modelica 3.2.2
world	animateGround=true
	groundLength_u=4
	groundColor={130,200,130}
ground		Present

---

model Mechanics.MultiBody.Examples.Elementary.RollingWheelSetDriving

Component	Modelica 3.2.3	Modelica 3.2.2
world	animateGround=true
	groundLength_u=3
	groundColor={130,200,130}
ground		Present

---

model Mechanics.MultiBody.Examples.Elementary.RollingWheelSetPulling

Component	Modelica 3.2.3	Modelica 3.2.2
world	animateGround=true
	groundLength_u=3
	groundColor={130,200,130}
ground		Present

---

model Mechanics.MultiBody.Examples.Elementary.Surfaces

Component	Modelica 3.2.3	Modelica 3.2.2
world	animateGround=true
	groundLength_u=4
	groundColor={215,215,215}
pipeWithScalarField	T=Modelica323.Math.sin(Modelica323.Constants.pi*pipeWithScalarField.xsi)*Modelica323.Math.cos(Modelica323.Constants.pi*time) .+ 1	T=sin(Modelica322.Constants.pi*pipeWithScalarField.xsi)*cos(Modelica322.Constants.pi*time) .+ 1
ground		Present

---

function Mechanics.MultiBody.Examples.Elementary.Utilities.sineSurface

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Y[i,j] = aux_y;
Z[i, j] = A*Modelica323.Math.sin(wz + 0.1*j + 0.1*i) + A;	Z[i,j] = A*sin(wz + 0.1*j + 0.1*i)+A;
end for; ...

---

model Mechanics.MultiBody.Examples.Loops.Fourbar2

Component	Modelica 3.2.3	Modelica 3.2.2
j1	useAxisFlange=false	useAxisFlange=true
	w(displayUnit="deg/s", start=5.235987755983, fixed=true)	w(displayUnit="deg/s", start=5.235987755982989, fixed=true)

---

model Mechanics.MultiBody.Examples.Loops.Fourbar_analytic

Component	Modelica 3.2.3	Modelica 3.2.2
j1	useAxisFlange=false	useAxisFlange=true
	w(displayUnit="deg/s", start=5.235987755983, fixed=true)	w(displayUnit="deg/s", start=5.235987755982989, fixed=true)

---

model Mechanics.MultiBody.Examples.Loops.Utilities.Cylinder

Component	Modelica 3.2.3	Modelica 3.2.2
CylinderInclination	n_y={0,Modelica323.Math.cos(cylinderInclination),Modelica323.Math.sin(cylinderInclination)}	n_y={0,cos(cylinderInclination),sin(cylinderInclination)}
CrankAngle1	n_y={0,Modelica323.Math.cos(crankAngleOffset),Modelica323.Math.sin(crankAngleOffset)}	n_y={0,cos(crankAngleOffset),sin(crankAngleOffset)}
CrankAngle2	n_y={0,Modelica323.Math.cos(-crankAngleOffset),Modelica323.Math.sin(-crankAngleOffset)}	n_y={0,cos(-crankAngleOffset),sin(-crankAngleOffset)}
gasForce	Mechanics.MultiBody.Examples.Loops.Utilities.GasForce2	Mechanics.MultiBody.Examples.Loops.Utilities.GasForce

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(Crank4.frame_b, CrankAngle2.frame_a);
	connect(Cylinder.support, gasForce.flange_b); connect(Cylinder.axis, gasForce.flange_a);
connect(CylinderInclination.frame_b, CylinderTop.frame_a); ... connect(CrankAngle2.frame_b, crank_b);
connect(Cylinder.axis, gasForce.flange_b); connect(Cylinder.support, gasForce.flange_a);

---

model Mechanics.MultiBody.Examples.Loops.Utilities.GasForce2

Component	Modelica 3.2.3	Modelica 3.2.2
R_air	constant

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... v_rel = der(s_rel);
press = 1e5 * ( if v_rel < 0 then ( if x < 0.986061 then 177.4132*x^4 - 287.2189*x^3 + 151.8252*x^2 - 24.9973*x + 2.4 else 2836360*x^4 - 10569296*x^3 + 14761814*x^2 - 9158505*x + 2129670) else ( if x > 0.933 then -3929704*x^4 + 14748765*x^3 - 20747000*x^2 + 12964477*x - 3036495 else 145.930*x^4 - 131.707*x^3 + 17.3438*x^2 + 17.9272*x + 2.4));	press = 1.0E5*(if v_rel < 0 then (if x < 0.987 then 177.4132*x^4 - 287.2189*x^3 + 151.8252*x^2 - 24.9973*x + 2.4 else 2836360*x^4 - 10569296*x^3 + 14761814 *x^2 - 9158505*x + 2129670) else (if x > 0.93 then -3929704*x^4 + 14748765*x^3 - 20747000*x^2 + 12964477*x - 3036495 else 145.930*x^4 - 131.707*x^3 + 17.3438*x^2 + 17.9272*x + 2.4));
f = -press*pi*d^2/4; ... press*V = k*T;
assert(s_rel >= -1e-12, "flange_b.s - flange_a.s (= " + String(s_rel, significantDigits=14) + ") >= 0 required for GasForce component.\n" + "Most likely, the component has to be flipped.");	assert(s_rel >= -1.e-12, "flange_b.s - flange_a.s (= " + String(s_rel, significantDigits=14) + ") >= 0 required for GasForce component.\n" + "Most likely, the component has to be flipped.");
assert(s_rel <= L + 1e-12, " flange_b.s - flange_a.s (= " + String(s_rel, significantDigits=14) + ") <= L (= " + String(L, significantDigits=14) + ") required for GasForce component.\n" + "Most likely, parameter L is not correct.");	assert(s_rel <= L + 1.e-12, " flange_b.s - flange_a.s (= " + String(s_rel, significantDigits=14) + ") <= L (= " + String(L, significantDigits=14) + ") required for GasForce component.\n" + "Most likely, parameter L is not correct.");

---

model Mechanics.MultiBody.Examples.Loops.Utilities.CylinderBase

Component	Modelica 3.2.3	Modelica 3.2.2
gasForce	Mechanics.MultiBody.Examples.Loops.Utilities.GasForce2	Mechanics.MultiBody.Examples.Loops.Utilities.GasForce

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(Mid.frame_b, jointRRP.frame_a);
	connect(gasForce.flange_a, jointRRP.axis); connect(jointRRP.bearing, gasForce.flange_b);
connect(jointRRP.frame_ib, Piston.frame_b); ... connect(Crank.frame_b, crank_b);
connect(gasForce.flange_a, jointRRP.bearing); connect(gasForce.flange_b, jointRRP.axis);

---

model Mechanics.MultiBody.Examples.Loops.Utilities.Engine1bBase

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(Crank2.frame_a, Crank1.frame_b);
	connect(Crank2.frame_b, Crank3.frame_a);
connect(Bearing.frame_b, Crank1.frame_a); ... connect(Inertia.flange_b, Bearing.axis);
connect(Crank2.frame_b, Crank3.frame_a);	connect(Mid.frame_a, Crank2.frame_b);
connect(Crank2.frame_b, Mid.frame_a);

---

model Mechanics.MultiBody.Examples.Rotational3DEffects.ActuatedDrive

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(torque.frame_b, bodyCylinder.frame_b);
	connect(torque.frame_resolve, world.frame_b);
connect(torque.frame_a, world.frame_b); ...

---

model Mechanics.MultiBody.Examples.Rotational3DEffects.MovingActuatedDrive

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(r1.frame_b, revolute.frame_a);
	connect(torque.frame_resolve, revolute.frame_a);
connect(torque.frame_a, revolute.frame_a); ...

---

model Mechanics.MultiBody.Examples.Constraints.PrismaticConstraint

Component	Modelica 3.2.3	Modelica 3.2.2
jointPrismatic_x	stateSelect=StateSelect.always	stateSelect=StateSelect.never
jointPrismatic_y	stateSelect=StateSelect.always	stateSelect=StateSelect.never

---

model Mechanics.MultiBody.Examples.Constraints.RevoluteConstraint

Component	Modelica 3.2.3	Modelica 3.2.2
joint	stateSelect=StateSelect.always	stateSelect=StateSelect.never

---

model Mechanics.MultiBody.Examples.Constraints.UniversalConstraint

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(joint.frame_b, bodyOfJoint.frame_a);
	connect(sensorConstraintRelative.frame_b, constraint.frame_b);
connect(fixedTranslation.frame_b, springOfJoint.frame_a); ... connect(bodyOfConstraint.frame_a, freeMotionScalarInit.frame_b);
connect(bodyOfConstraint.frame_a, sensorConstraintRelative.frame_b);

---

model Mechanics.MultiBody.Examples.Systems.RobotR3.Components.AxisType2

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(gear.flange_b, accSensor.flange);
	connect(controller.axisControlBus, axisControlBus);
connect(motor.axisControlBus, axisControlBus); ... connect(const.y, initializeFlange.a_start);
connect(controller.axisControlBus, axisControlBus);

---

model Mechanics.MultiBody.Examples.Systems.RobotR3.Components.MechanicalStructure

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	connect(r6.frame_b, b6.frame_a);
q = {r1.phi,r2.phi,r3.phi,r4.phi,r5.phi,r6.phi}; ... connect(r6.axis, axis6);
connect(r6.frame_b, b6.frame_a);

---

model Mechanics.MultiBody.Forces.LineForceWithMass

Component	Modelica 3.2.3	Modelica 3.2.2
s_small		Present
fixedRotationAtFrame_a		Present
fixedRotationAtFrame_b		Present
length		Present
r_rel_0		Present
e_rel_0		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	assert(noEvent(length > s_small), " The distance between the origin of frame_a and the origin of frame_b of a LineForceWithMass component became smaller as parameter s_small (= a small number, defined in the \"Advanced\" menu). The distance is set to s_small, although it is smaller, to avoid a division by zero when computing the direction of the line force. Possible reasons for this situation: - At initial time the distance may already be zero: Change the initial   positions of the bodies connected by this element. - Hardware stops are not modeled or are modeled not stiff enough.   Include stops, e.g., stiff springs, or increase the stiffness   if already present. - Another error in your model may lead to unrealistically large forces   and torques that would in reality destroy the stops. - The flange_b connector might be defined by a pre-defined motion,   e.g., with Modelica.Mechanics.Translational.Position and the   predefined flange_b.s is zero or negative. "); r_rel_0 = frame_b.r_0 - frame_a.r_0; length = Modelica322.Math.Vectors.length(r_rel_0);
flange_a.s = 0;
flange_b.s = length;
	e_rel_0 = r_rel_0/Frames.Internal.maxWithoutEvent(length, s_small);
if cardinality(flange_a) > 0 and cardinality(flange_b) > 0 then ... end if;
	if fixedRotationAtFrame_a then Connections.root(frame_a.R); frame_a.R = Frames.nullRotation(); else frame_a.t = zeros(3); end if; if fixedRotationAtFrame_b then Connections.root(frame_b.R); frame_b.R = Frames.nullRotation(); else frame_b.t = zeros(3); end if;

---

model Mechanics.MultiBody.Forces.LineForceWithTwoMasses

Component	Modelica 3.2.3	Modelica 3.2.2
s_small		Present
fixedRotationAtFrame_a		Present
fixedRotationAtFrame_b		Present
length		Present
r_rel_0		Present
e_rel_0		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	assert(noEvent(length > s_small), " The distance between the origin of frame_a and the origin of frame_b of a LineForceWithTwoMasses component became smaller as parameter s_small (= a small number, defined in the \"Advanced\" menu). The distance is set to s_small, although it is smaller, to avoid a division by zero when computing the direction of the line force. Possible reasons for this situation: - At initial time the distance may already be zero: Change the initial   positions of the bodies connected by this element. - Hardware stops are not modeled or are modeled not stiff enough.   Include stops, e.g., stiff springs, or increase the stiffness   if already present. - Another error in your model may lead to unrealistically large forces   and torques that would in reality destroy the stops. - The flange_b connector might be defined by a pre-defined motion,   e.g., with Modelica.Mechanics.Translational.Position and the   predefined flange_b.s is zero or negative. "); r_rel_0 = frame_b.r_0 - frame_a.r_0; length = Modelica322.Math.Vectors.length(r_rel_0);
flange_a.s = 0;
flange_b.s = length;
	e_rel_0 = r_rel_0/Frames.Internal.maxWithoutEvent(length, s_small);
if cardinality(flange_a) > 0 and cardinality(flange_b) > 0 then ... end if;
	if fixedRotationAtFrame_a then Connections.root(frame_a.R); frame_a.R = Frames.nullRotation(); else frame_a.t = zeros(3); end if; if fixedRotationAtFrame_b then Connections.root(frame_b.R); frame_b.R = Frames.nullRotation(); else frame_b.t = zeros(3); end if;

---

model Mechanics.MultiBody.Forces.Spring

Component	Modelica 3.2.3	Modelica 3.2.2
lineForce	s_small=s_small
s_small	Present
r_rel_a	Present
e_a	Present
f	Present
length	Present
s	Present
r_rel_0	Present
e_rel_0	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
r_rel_a = Frames.resolve2(frame_a.R, r_rel_0);	connect(lineForce.frame_a, frame_a);
e_a = r_rel_a/s;	connect(lineForce.frame_b, frame_b);
f = spring.f;	connect(spring.flange_b, lineForce.flange_b);
length = lineForce.length;	connect(spring.flange_a, lineForce.flange_a);
s = lineForce.s; r_rel_0 = lineForce.r_rel_0; e_rel_0 = lineForce.e_rel_0; connect(lineForce.frame_a, frame_a); connect(lineForce.frame_b, frame_b); connect(spring.flange_b, lineForce.flange_b); connect(spring.flange_a, lineForce.flange_a);

---

model Mechanics.MultiBody.Forces.SpringDamperParallel

Component	Modelica 3.2.3	Modelica 3.2.2
shape	specularCoefficient=specularCoefficient
length_a	Present
diameter_a	Present
diameter_b	Present
color_a	Present
color_b	Present
shape_a	Present
shape_b	Present

---

model Mechanics.MultiBody.Forces.SpringDamperSeries

Component	Modelica 3.2.3	Modelica 3.2.2
animation	Present
length_a	Present
diameter_a	Present
diameter_b	Present
color_a	Present
color_b	Present
specularCoefficient	Present
width	Present
coilWidth	Present
numberOfWindings	Present
color	Present
shape_a	Present
shape_b	Present
shape	Present

---

function Mechanics.MultiBody.Frames.planarRotation

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
R := Orientation(T=outerProduct(e,e) + (identity(3) - outerProduct(e,e))* Math.cos(angle) - skew(e)*Math.sin(angle),w= e*der_angle);	R := Orientation(T=[e]*transpose([e]) + (identity(3) - [e]*transpose([e]))* Math.cos(angle) - skew(e)*Math.sin(angle),w= e*der_angle);

---

function Mechanics.MultiBody.Frames.axisRotation

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
R := Orientation(T=(if axis == 1 then [1,0,0; 0,Modelica323.Math.cos(angle), Modelica323.Math.sin(angle); 0,-Modelica323.Math.sin(angle), Modelica323.Math.cos(angle)] else if axis == 2 then [Modelica323.Math.cos( angle),0,-Modelica323.Math.sin(angle); 0,1,0; Modelica323.Math.sin(angle),0, Modelica323.Math.cos(angle)] else [Modelica323.Math.cos(angle), Modelica323.Math.sin(angle),0; -Modelica323.Math.sin(angle), Modelica323.Math.cos(angle),0; 0,0,1]), w=if axis == 1 then {der_angle,0,0} else if axis == 2 then {0,der_angle,0} else {0,0,der_angle});	R := Orientation(T=(if axis == 1 then [1, 0, 0; 0, cos(angle), sin(angle); 0, -sin(angle), cos(angle)] else if axis == 2 then [cos(angle), 0, -sin( angle); 0, 1, 0; sin(angle), 0, cos(angle)] else [cos(angle), sin(angle), 0; -sin(angle), cos(angle), 0; 0, 0, 1]),w= if axis == 1 then {der_angle, 0,0} else if axis == 2 then {0,der_angle,0} else {0,0,der_angle});

---

function Mechanics.MultiBody.Frames.axesRotationsAngles

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... B = cross(e1_1, e2_1a)*e3_1;
if abs(A) <= 1e-12 and abs(B) <= 1e-12 then	if abs(A) <= 1.e-12 and abs(B) <= 1.e-12 then
angles[1] = guessAngle1; ...

---

function Mechanics.MultiBody.Frames.from_nxy

Component	Modelica 3.2.3	Modelica 3.2.2
abs_n_x		Present
e_x		Present
n_z_aux		Present
n_y_aux		Present
e_z_aux		Present
e_z		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
R := Orientation(T=TransformationMatrices.from_nxy(n_x,n_y),w= zeros(3));	R := Orientation(T={e_x,cross(e_z, e_x),e_z},w= zeros(3));

---

function Mechanics.MultiBody.Frames.from_nxz

Component	Modelica 3.2.3	Modelica 3.2.2
abs_n_x		Present
e_x		Present
n_y_aux		Present
n_z_aux		Present
e_y_aux		Present
e_y		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
R := Orientation(T=TransformationMatrices.from_nxz(n_x,n_z),w= zeros(3));	R := Orientation(T={e_x,e_y,cross(e_x, e_y)},w= zeros(3));

---

function Mechanics.MultiBody.Frames.Quaternions.multipleResolve1

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
v1 := ((2*Q[4]*Q[4] - 1)*identity(3) + 2*(outerProduct(Q[1:3],Q[1:3]) + Q[4]*skew(Q[1:3])))*v2;	v1 := ((2*Q[4]*Q[4] - 1)*identity(3) + 2*([Q[1:3]]*transpose([Q[1:3]]) + Q[4]*skew(Q[1:3])))*v2;

---

function Mechanics.MultiBody.Frames.Quaternions.multipleResolve2

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
v2 := ((2*Q[4]*Q[4] - 1)*identity(3) + 2*(outerProduct(Q[1:3],Q[1:3]) - Q[4]*skew(Q[1:3])))*v1;	v2 := ((2*Q[4]*Q[4] - 1)*identity(3) + 2*([Q[1:3]]*transpose([Q[1:3]]) - Q[4]*skew(Q[1:3])))*v1;

---

function Mechanics.MultiBody.Frames.TransformationMatrices.planarRotation

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
T := outerProduct(e,e) + (identity(3) - outerProduct(e,e))*Math.cos( angle) - skew(e)*Math.sin(angle);	T := [e]*transpose([e]) + (identity(3) - [e]*transpose([e]))*Math.cos( angle) - skew(e)*Math.sin(angle);

---

function Mechanics.MultiBody.Frames.TransformationMatrices.axisRotation

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
T := if axis == 1 then [1,0,0; 0,Modelica323.Math.cos(angle), Modelica323.Math.sin(angle); 0,-Modelica323.Math.sin(angle), Modelica323.Math.cos(angle)] else if axis == 2 then [Modelica323.Math.cos( angle),0,-Modelica323.Math.sin(angle); 0,1,0; Modelica323.Math.sin(angle),0, Modelica323.Math.cos(angle)] else [Modelica323.Math.cos(angle), Modelica323.Math.sin(angle),0; -Modelica323.Math.sin(angle), Modelica323.Math.cos(angle),0; 0,0,1];	T := if axis == 1 then [1, 0, 0; 0, cos(angle), sin(angle); 0, -sin(angle), cos(angle)] else if axis == 2 then [cos(angle), 0, -sin(angle); 0, 1, 0; sin(angle), 0, cos(angle)] else [cos(angle), sin(angle), 0; -sin( angle), cos(angle), 0; 0, 0, 1];

---

function Mechanics.MultiBody.Frames.TransformationMatrices.axesRotationsAngles

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... B = cross(e1_1, e2_1a)*e3_1;
if abs(A) <= 1e-12 and abs(B) <= 1e-12 then	if abs(A) <= 1.e-12 and abs(B) <= 1.e-12 then
angles[1] = guessAngle1; ...

---

function Mechanics.MultiBody.Frames.TransformationMatrices.from_nxy

Component	Modelica 3.2.3	Modelica 3.2.2
e_x	=if length(n_x) < 1e-10 then {1,0,0} else normalize(n_x)	=if abs_n_x < 1.e-10 then {1,0,0} else n_x/abs_n_x
e_z	=normalize(e_z_aux)	=e_z_aux/sqrt(e_z_aux*e_z_aux)
abs_n_x		Present

---

function Mechanics.MultiBody.Frames.TransformationMatrices.from_nxz

Component	Modelica 3.2.3	Modelica 3.2.2
e_x	=if length(n_x) < 1e-10 then {1,0,0} else normalize(n_x)	=if abs_n_x < 1.e-10 then {1,0,0} else n_x/abs_n_x
e_y	=normalize(e_y_aux)	=e_y_aux/sqrt(e_y_aux*e_y_aux)
abs_n_x		Present

---

model Mechanics.MultiBody.Interfaces.PartialForce

Component	Modelica 3.2.3	Modelica 3.2.2
frame_a		Present
frame_b		Present
world		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	assert(cardinality(frame_a) > 0,     "Connector frame_a of force object is not connected"); assert(cardinality(frame_b) > 0,     "Connector frame_b of force object is not connected");
r_rel_b = Frames.resolve2(frame_b.R, frame_b.r_0 - frame_a.r_0); ...

---

model Mechanics.MultiBody.Interfaces.PartialLineForce

Component	Modelica 3.2.3	Modelica 3.2.2
s_small		Present
fixedRotationAtFrame_a		Present
fixedRotationAtFrame_b		Present
frame_a		Present
frame_b		Present
s		Present
world		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
r_rel_a = Frames.resolve2(frame_a.R, r_rel_0);	assert(cardinality(frame_a) > 0, "Connector frame_a of line force object is not connected");
	assert(cardinality(frame_b) > 0,     "Connector frame_b of line force object is not connected"); r_rel_a = Frames.resolve2(frame_a.R, frame_b.r_0 - frame_a.r_0); s = noEvent(max(Modelica322.Math.Vectors.length(r_rel_a), s_small));
e_a = r_rel_a/s; ... frame_b.f = -Frames.resolve2(Frames.relativeRotation(frame_a.R, frame_b.R), frame_a.f);
	if fixedRotationAtFrame_a then Connections.root(frame_a.R); frame_a.R = Frames.nullRotation(); else frame_a.t = zeros(3); end if; if fixedRotationAtFrame_b then Connections.root(frame_b.R); frame_b.R = Frames.nullRotation(); else frame_b.t = zeros(3); end if;

---

model Mechanics.MultiBody.Joints.RevolutePlanarLoopConstraint

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... ey_b = Frames.resolve2(R_rel, ey_a);
assert(noEvent(abs(e*r_rel_a) <= 1e-10 and abs(e*ex_b) <= 1e-10 and abs(e*ey_b) <= 1e-10), " The MultiBody.Joints.RevolutePlanarLoopConstraint joint is used as cut-joint of a planar loop. However, the revolute joint is not part of a planar loop where the axis of the revolute joint (parameter n) is orthogonal to the possible movements. Either use instead joint MultiBody.Joints.Revolute or correct the definition of the axes vectors n in the revolute joints of the planar loop. ");	assert(noEvent(abs(e*r_rel_a) <= 1.e-10 and abs(e*ex_b) <= 1.e-10 and abs(e*ey_b) <= 1.e-10), " The MultiBody.Joints.RevolutePlanarLoopConstraint joint is used as cut-joint of a planar loop. However, the revolute joint is not part of a planar loop where the axis of the revolute joint (parameter n) is orthogonal to the possible movements. Either use instead joint MultiBody.Joints.Revolute or correct the definition of the axes vectors n in the revolute joints of the planar loop. ");

---

model Mechanics.MultiBody.Joints.UniversalSpherical

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... length2_n2_a = n2_a*n2_a;
assert(length2_n2_a > 1e-10, " A Modelica.Mechanics.MultiBody.Joints.UniversalSpherical joint (consisting of a universal joint and a spherical joint connected together by a rigid rod) is in the singular configuration of the universal joint. This means that axis 1 of the universal joint defined via parameter \"n1_a\" is parallel to vector \"rRod_ia\" that is directed from the origin of frame_a to the origin of frame_b. You may try to use another \"n1_a\" vector. If this fails, use instead Modelica.Mechanics.MultiBody.Joints.SphericalSpherical, if this is possible, because this joint aggregation does not have a singular configuration. ");	assert(length2_n2_a > 1.e-10, " A Modelica.Mechanics.MultiBody.Joints.UniversalSpherical joint (consisting of a universal joint and a spherical joint connected together by a rigid rod) is in the singular configuration of the universal joint. This means that axis 1 of the universal joint defined via parameter \"n1_a\" is parallel to vector \"rRod_ia\" that is directed from the origin of frame_a to the origin of frame_b. You may try to use another \"n1_a\" vector. If this fails, use instead Modelica.Mechanics.MultiBody.Joints.SphericalSpherical, if this is possible, because this joint aggregation does not have a singular configuration. ");
length_n2_a = sqrt(length2_n2_a); ...

---

model Mechanics.MultiBody.Joints.Assemblies.JointUPS

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... length2_n2_a = n2_a*n2_a;
assert(noEvent(length2_n2_a > 1e-10), " A Modelica.Mechanics.MultiBody.Joints.Assemblies.JointUPS joint (consisting of a universal, prismatic and spherical joint) is in the singular configuration of the universal joint. This means that axis 1 of the universal joint defined via parameter \"n1_a\" is parallel to vector \"eAxis_ia\" that is directed from the origin of frame_a to the origin of frame_b. You may try to use another \"n1_a\" vector. ");	assert(noEvent(length2_n2_a > 1.e-10), " A Modelica.Mechanics.MultiBody.Joints.Assemblies.JointUPS joint (consisting of a universal, prismatic and spherical joint) is in the singular configuration of the universal joint. This means that axis 1 of the universal joint defined via parameter \"n1_a\" is parallel to vector \"eAxis_ia\" that is directed from the origin of frame_a to the origin of frame_b. You may try to use another \"n1_a\" vector. ");
length_n2_a = sqrt(length2_n2_a); ...

---

model Mechanics.MultiBody.Joints.Assemblies.JointUSR

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
aux = cross(revolute.e, rRod2_ib)*Frames.resolveRelative(rod1.eRod_a,     rod1.frame_a.R, rod1.frame_b.R);
f_rod = (-revolute.tau - revolute.e*(frame_ib.t + frame_im.t + cross( rRod2_ib, frame_im.f) - cross(rRod2_ib, Frames.resolveRelative(rod1. f_b_a1, rod1.frame_a.R, rod1.frame_b.R))))/noEvent(if abs(aux) < 1e-10 then 1e-10 else aux);	f_rod = (-revolute.tau - revolute.e*(frame_ib.t + frame_im.t + cross( rRod2_ib, frame_im.f) - cross(rRod2_ib, Frames.resolveRelative(rod1. f_b_a1, rod1.frame_a.R, rod1.frame_b.R))))/noEvent(if abs(aux) < 1.e-10 then 1.e-10 else aux);
if checkTotalPower then ...

---

model Mechanics.MultiBody.Joints.Assemblies.JointUSP

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
aux = prismatic.e*Frames.resolveRelative(rod1.eRod_a, rod1.frame_a.R,     rod1.frame_b.R);
f_rod = (-prismatic.f - prismatic.e*(frame_ib.f + frame_im.f - Frames.resolveRelative(rod1.f_b_a1, rod1.frame_a.R, rod1.frame_b.R)))/ noEvent(if abs(aux) < 1e-10 then 1e-10 else aux);	f_rod = (-prismatic.f - prismatic.e*(frame_ib.f + frame_im.f - Frames.resolveRelative(rod1.f_b_a1, rod1.frame_a.R, rod1.frame_b.R)))/ noEvent(if abs(aux) < 1.e-10 then 1.e-10 else aux);
if checkTotalPower then ...

---

model Mechanics.MultiBody.Joints.Assemblies.JointSSR

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
aux = cross(revolute.e, rRod2_ib)*Frames.resolveRelative(rod1.eRod_a,     rod1.frame_a.R, rod1.frame_b.R);
f_rod = (-revolute.tau - revolute.e*(frame_ib.t + frame_im.t + cross( rRod2_ib, frame_im.f) - cross(rRod2_ib, Frames.resolveRelative(rod1. f_b_a1, rod1.frame_a.R, rod1.frame_b.R))))/noEvent(if abs(aux) < 1e-10 then 1e-10 else aux);	f_rod = (-revolute.tau - revolute.e*(frame_ib.t + frame_im.t + cross( rRod2_ib, frame_im.f) - cross(rRod2_ib, Frames.resolveRelative(rod1. f_b_a1, rod1.frame_a.R, rod1.frame_b.R))))/noEvent(if abs(aux) < 1.e-10 then 1.e-10 else aux);
if checkTotalPower then ...

---

model Mechanics.MultiBody.Joints.Assemblies.JointSSP

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
aux = prismatic.e*Frames.resolveRelative(rod1.eRod_a, rod1.frame_a.R,     rod1.frame_b.R);
f_rod = (-prismatic.f - prismatic.e*(frame_ib.f + frame_im.f))/ noEvent(if abs(aux) < 1e-10 then 1e-10 else aux);	f_rod = (-prismatic.f - prismatic.e*(frame_ib.f + frame_im.f))/ noEvent(if abs(aux) < 1.e-10 then 1.e-10 else aux);
if checkTotalPower then ...

---

model Mechanics.MultiBody.Joints.Internal.RevoluteWithLengthConstraint

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... k1a = k1 - C*C;
assert(k1a > 1e-10, " Singular position of loop (either no or two analytic solutions; the mechanism has lost one-degree-of freedom in this position). Try first to use another Modelica.Mechanics.MultiBody.Joints.Assemblies.JointXXX component. In most cases it is best that the joints outside of the JointXXX component are revolute and NOT prismatic joints. If this also lead to singular positions, it could be that this kinematic loop cannot be solved analytically. In this case you have to build up the loop with basic joints (NO aggregation JointXXX components) and rely on dynamic state selection, i.e., during simulation the states will be dynamically selected in such a way that in no position a degree of freedom is lost. ");	assert(k1a > 1.e-10, " Singular position of loop (either no or two analytic solutions; the mechanism has lost one-degree-of freedom in this position). Try first to use another Modelica.Mechanics.MultiBody.Joints.Assemblies.JointXXX component. In most cases it is best that the joints outside of the JointXXX component are revolute and NOT prismatic joints. If this also lead to singular positions, it could be that this kinematic loop cannot be solved analytically. In this case you have to build up the loop with basic joints (NO aggregation JointXXX components) and rely on dynamic state selection, i.e., during simulation the states will be dynamically selected in such a way that in no position a degree of freedom is lost. ");
k1b = Frames.Internal.maxWithoutEvent(k1a, 1.0e-12); ...

---

model Mechanics.MultiBody.Joints.Internal.PrismaticWithLengthConstraint

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... k1a = k1*k1 - C;
assert(noEvent(k1a > 1e-10), " Singular position of loop (either no or two analytic solutions; the mechanism has lost one-degree-of freedom in this position). Try first to use another Modelica.Mechanics.MultiBody.Joints.Assemblies.JointXXX component. If this also lead to singular positions, it could be that this kinematic loop cannot be solved analytically with a fixed state selection. In this case you have to build up the loop with basic joints (NO aggregation JointXXX components) and rely on dynamic state selection, i.e., during simulation the states will be dynamically selected in such a way that in no position a degree of freedom is lost. ");	assert(noEvent(k1a > 1.e-10), " Singular position of loop (either no or two analytic solutions; the mechanism has lost one-degree-of freedom in this position). Try first to use another Modelica.Mechanics.MultiBody.Joints.Assemblies.JointXXX component. If this also lead to singular positions, it could be that this kinematic loop cannot be solved analytically with a fixed state selection. In this case you have to build up the loop with basic joints (NO aggregation JointXXX components) and rely on dynamic state selection, i.e., during simulation the states will be dynamically selected in such a way that in no position a degree of freedom is lost. ");
k1b = Frames.Internal.maxWithoutEvent(k1a, 1.0e-12); ...

---

model Mechanics.MultiBody.Sensors.AbsoluteAngles

Component	Modelica 3.2.3	Modelica 3.2.2
frame_a		Present

---

model Mechanics.MultiBody.Sensors.RelativeAngles

Component	Modelica 3.2.3	Modelica 3.2.2
frame_a		Present
frame_b		Present

---

model Mechanics.MultiBody.Sensors.Distance

Component	Modelica 3.2.3	Modelica 3.2.2
s_small	=1e-10	=1.E-10

---

model Mechanics.MultiBody.Visualizers.Advanced.Arrow

Component	Modelica 3.2.3	Modelica 3.2.2
e_x	=noEvent(if length < 1e-10 then {1,0,0} else r_head/length)	=noEvent(if length < 1.e-10 then {1,0,0} else r_head/length)

---

model Mechanics.MultiBody.Visualizers.Advanced.DoubleArrow

Component	Modelica 3.2.3	Modelica 3.2.2
e_x	=noEvent(if length < 1e-10 then {1,0,0} else r_head/length)	=noEvent(if length < 1.e-10 then {1,0,0} else r_head/length)

---

function Mechanics.MultiBody.Visualizers.Advanced.SurfaceCharacteristics.torus

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... beta = phi_start + (phi_stop-phi_start)*(j-1)/(nv-1);
X[i, j] = (ri + ro*Modelica323.Math.cos(beta))*Modelica323.Math.sin(alpha);	X[i,j] = (ri + ro*cos(beta))*sin(alpha);
Y[i, j] = ro*Modelica323.Math.sin(beta);	Y[i,j] = ro*sin(beta);
Z[i, j] = (ri + ro*Modelica323.Math.cos(beta))*Modelica323.Math.cos(alpha);	Z[i,j] = (ri + ro*cos(beta))*cos(alpha);
end for; ...

---

function Mechanics.MultiBody.Visualizers.Advanced.SurfaceCharacteristics.pipeWithScalarField

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... X[i,j] = length*xsi_i;
Y[i, j] = rOuter*Modelica323.Math.sin(beta);	Y[i,j] = rOuter*sin(beta);
Z[i, j] = rOuter*Modelica323.Math.cos(beta);	Z[i,j] = rOuter*cos(beta);
C[i,j,:] = Ci; ...

---

package Mechanics.MultiBody.Types.Defaults

Component	Modelica 3.2.3	Modelica 3.2.2
BodyCylinderDiameterFraction	Real	SIunits.Diameter

---

model Mechanics.Rotational.Examples.CoupledClutches

Component	Modelica 3.2.3	Modelica 3.2.2
sin2	phase=1.570796326794897	phase=1.57

---

model Mechanics.Rotational.Examples.GenerationOfFMUs

Component	Modelica 3.2.3	Modelica 3.2.2
force3	Present
sine2		Present
sine3		Present
torque3		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... connect(inverseInertia.tau, directInertia.tau);
connect(sine1.y, torque2.tau); connect(sine1.y, force3.tau); connect(torqueToAngle2b.flange, inertia2b.flange_a); connect(inertia2a.flange_b, torqueToAngle2a.flange);
connect(torque2.flange, inertia2a.flange_a);
	connect(sine2.y, torque2.tau); connect(inertia2a.flange_b, torqueToAngle2a.flange); connect(torqueToAngle2a.phi, springDamper.phi1); connect(torqueToAngle2a.w, springDamper.w1); connect(springDamper.tau1, torqueToAngle2a.tau); connect(torqueToAngle2b.phi, springDamper.phi2); connect(torqueToAngle2b.w, springDamper.w2); connect(springDamper.tau2, torqueToAngle2b.tau); connect(inertia2b.flange_a, torqueToAngle2b.flange); connect(torque3.flange, inertia3a.flange_a); connect(sine3.y, torque3.tau);
connect(inertia3a.flange_b, torqueToAngle3a.flange);
connect(force3.flange, inertia3a.flange_a);	connect(torqueToAngle3a.phi, spring.phi1);
connect(torqueToAngle3b.flange, inertia3b.flange_a);	connect(spring.tau1, torqueToAngle3a.tau);
connect(torqueToAngle2a.phi, springDamper.phi1);	connect(torqueToAngle3b.phi, spring.phi2);
connect(torqueToAngle2a.w, springDamper.w1);	connect(spring.tau2, torqueToAngle3b.tau);
connect(torqueToAngle2a.tau, springDamper.tau1);	connect(inertia3b.flange_a, torqueToAngle3b.flange);
connect(springDamper.tau2, torqueToAngle2b.tau); connect(springDamper.phi2, torqueToAngle2b.phi); connect(springDamper.w2, torqueToAngle2b.w); connect(torqueToAngle3a.phi, spring.phi1); connect(torqueToAngle3a.tau, spring.tau1); connect(spring.phi2, torqueToAngle3b.phi); connect(spring.tau2, torqueToAngle3b.tau);

---

model Mechanics.Rotational.Examples.Utilities.DirectInertia

Component	Modelica 3.2.3	Modelica 3.2.2
torqueSource	Present
torque		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
connect(tauDrive, torqueSource.tau);	connect(torque.flange, inertia.flange_a);
connect(torqueSource.flange, inertia.flange_a);	connect(torque.tau, tauDrive);
connect(inertia.flange_b, torqueToAngle.flange); ... connect(torqueToAngle.w, w);
	connect(torqueToAngle.tau, tau);
connect(torqueToAngle.a, a);
connect(torqueToAngle.tau, tau);

---

model Mechanics.Rotational.Examples.Utilities.InverseInertia

Component	Modelica 3.2.3	Modelica 3.2.2
inertia	phi(start=0)	phi(start=0, fixed=false)
	w(start=0)	w(start=0, fixed=false)

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	connect(angleToTorque.phi, phi); connect(angleToTorque.w, w); connect(angleToTorque.a, a);
connect(angleToTorque.flange, inertia.flange_a);
connect(phi, angleToTorque.phi);	connect(angleToTorque.tau, tau);
connect(w, angleToTorque.w); connect(a, angleToTorque.a); connect(tau, angleToTorque.tau);

---

model Mechanics.Rotational.Examples.Utilities.SpringDamper

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	connect(angleToTorque1.phi, phi1); connect(angleToTorque1.w, w1); connect(angleToTorque1.tau, tau1); connect(angleToTorque1.flange, springDamper.flange_a);
connect(springDamper.flange_b, angleToTorque2.flange);
connect(angleToTorque1.flange, springDamper.flange_a);	connect(phi2, angleToTorque2.phi);
connect(phi1, angleToTorque1.phi);	connect(w2, angleToTorque2.w);
connect(w1, angleToTorque1.w);	connect(angleToTorque2.tau, tau2);
connect(tau1, angleToTorque1.tau); connect(angleToTorque2.phi, phi2); connect(w2, angleToTorque2.w); connect(angleToTorque2.tau, tau2);

---

model Mechanics.Rotational.Examples.Utilities.Spring

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	connect(angleToTorque1.phi, phi1); connect(angleToTorque1.tau, tau1);
connect(angleToTorque1.flange, spring.flange_a);
connect(spring.flange_b, angleToTorque2.flange);
connect(phi1, angleToTorque1.phi);	connect(phi2, angleToTorque2.phi);
connect(tau1, angleToTorque1.tau);	connect(angleToTorque2.tau, tau2);
connect(angleToTorque2.phi, phi2); connect(angleToTorque2.tau, tau2);

---

model Mechanics.Rotational.Components.Inertia

Component	Modelica 3.2.3	Modelica 3.2.2
flange_a		Present
flange_b		Present

---

model Mechanics.Rotational.Sources.SignTorque

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... if reg == Modelica323.Blocks.Types.Regularization.Exp then
tau = tau_constant*(2/(1 + Modelica323.Math.exp(-w/(0.01*w0))) - 1);	tau = tau_constant*(2/(1+exp(-w/(0.01*w0)))-1);
elseif reg == Modelica323.Blocks.Types.Regularization.Sine then
tau = tau_constant*smooth(1, (if abs(w) >= w0 then sign(w) else Modelica323.Math.sin(pi/2*w/w0)));	tau = tau_constant*smooth(1, (if abs(w)>=w0 then sign(w) else sin(pi/2*w/w0)));
elseif reg == Modelica323.Blocks.Types.Regularization.Linear then ... else
tau = tau_constant*(if abs(w) >= w0 then sign(w) else sign(w)*(1 - Modelica323.Math.cos(pi/2*w/w0)));	tau = tau_constant*(if abs(w)>=w0 then sign(w) else sign(w)*(1 - cos(pi/2*w/w0)));
end if;

---

connector Mechanics.Rotational.Interfaces.Flange_a

Component	Modelica 3.2.3	Modelica 3.2.2
phi		Present
tau		Present

---

connector Mechanics.Rotational.Interfaces.Flange_b

Component	Modelica 3.2.3	Modelica 3.2.2
phi		Present
tau		Present

---

connector Mechanics.Rotational.Interfaces.Support

Component	Modelica 3.2.3	Modelica 3.2.2
phi		Present
tau		Present

---

model Mechanics.Translational.Examples.SignConvention

Component	Modelica 3.2.3	Modelica 3.2.2
force3	useSupport=false	useSupport=true

---

function Mechanics.Translational.Examples.Utilities.GenerateStribeckFrictionTable

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... table[i, 1] = v_max*(i - 1)/(nTable - 1);
table[i, 2] = F_Coulomb + F_prop*table[i, 1] + F_Stribeck*Modelica323.Math.exp( -fexp*table[i, 1]);	table[i, 2] = F_Coulomb + F_prop*table[i, 1] + F_Stribeck*exp(-fexp* table[i, 1]);
end for; ...

---

model Mechanics.Translational.Components.MassWithStopAndFriction

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... 0 = flange_a.f + flange_b.f - f - m*der(v);
f = if locked then sa*unitForce else if free then 0 else (if startForward then F_prop*v + F_Coulomb + F_Stribeck else if startBackward then F_prop*v - F_Coulomb - F_Stribeck else if pre(mode) == Forward then F_prop*v + F_Coulomb + F_Stribeck*Modelica323.Math.exp(-fexp*abs(v)) else F_prop*v - F_Coulomb - F_Stribeck*Modelica323.Math.exp(-fexp*abs(v)));	f = if locked then sa*unitForce else if free then 0 else (if startForward then F_prop*v + F_Coulomb + F_Stribeck else if startBackward then F_prop*v - F_Coulomb - F_Stribeck else if pre(mode) == Forward then F_prop*v + F_Coulomb + F_Stribeck*exp(-fexp*abs(v)) else F_prop*v - F_Coulomb - F_Stribeck*exp(-fexp*abs(v)));
lossPower = f*v_relfric; ...

---

model Mechanics.Translational.Sources.SignForce

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... if reg == Modelica323.Blocks.Types.Regularization.Exp then
f = -f_nominal*(2/(1 + Modelica323.Math.exp(-v/(0.01*v0))) - 1);	f = -f_nominal*(2/(1+exp(-v/(0.01*v0)))-1);
elseif reg == Modelica323.Blocks.Types.Regularization.Sine then
f = -f_nominal*smooth(1, (if abs(v) >= v0 then sign(v) else Modelica323.Math.sin(pi/2*v/v0)));	f = -f_nominal*smooth(1, (if abs(v)>=v0 then sign(v) else sin(pi/2*v/v0)));
elseif reg == Modelica323.Blocks.Types.Regularization.Linear then ... else
f = -f_nominal*(if abs(v) >= v0 then sign(v) else sign(v)*(1 - Modelica323.Math.cos(pi/2*v/v0)));	f = -f_nominal*(if abs(v)>=v0 then sign(v) else sign(v)*(1 - cos(pi/2*v/v0)));
end if;

---

connector Mechanics.Translational.Interfaces.Flange_a

Component	Modelica 3.2.3	Modelica 3.2.2
s		Present
f		Present

---

connector Mechanics.Translational.Interfaces.Flange_b

Component	Modelica 3.2.3	Modelica 3.2.2
s		Present
f		Present

---

connector Mechanics.Translational.Interfaces.Support

Component	Modelica 3.2.3	Modelica 3.2.2
s		Present
f		Present

---

model Fluid.Examples.HeatingSystem

Component	Modelica 3.2.3	Modelica 3.2.2
tank	ports(each p(start=1.1e5))	ports(each p(start=1e5))

---

model Fluid.Examples.DrumBoiler.DrumBoiler

Component	Modelica 3.2.3	Modelica 3.2.2
T_S	final unit="degC"
p_S	final unit="bar"
qm_S	unit="kg/s"
V_l	unit="m3"

---

model Fluid.Examples.DrumBoiler.BaseClasses.EquilibriumDrumBoiler

Component	Modelica 3.2.3	Modelica 3.2.2
V	unit="m3"

---

model Fluid.Examples.Tanks.TanksWithOverflow

Component	Modelica 3.2.3	Modelica 3.2.2
upperTank	portsData={Modelica323.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1),Modelica323.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1),Modelica323.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1, height=6)}	portsData={Modelica322.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1),Modelica322.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1),Modelica322.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1, height=10)}
pipe	height_ab=-5	height_ab=-20
lowerTank	portsData={Modelica323.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1),Modelica323.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1, height=6)}	portsData={Modelica322.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1),Modelica322.Fluid.Vessels.BaseClasses.VesselPortsData(diameter=0.1, height=10)}
overflow	height_ab=-5	height_ab=-20

---

block Fluid.Examples.ControlledTankSystem.Utilities.RadioButton

Component	Modelica 3.2.3	Modelica 3.2.2
on	start=false
	fixed=true
table	y(start=false, fixed=true)

---

model Fluid.Examples.AST_BatchPlant.BaseClasses.Controller

Component	Modelica 3.2.3	Modelica 3.2.2
BooleanExpression1	y=time >= 2500	y=time > 2500

---

model Fluid.Examples.TraceSubstances.RoomCO2WithControls

Component	Modelica 3.2.3	Modelica 3.2.2
volume	medium(Xi(each nominal=0.01))
		medium(Xi(nominal=0.01))
ductOut	mediums(each Xi(each nominal=0.01))
		mediums(each Xi(nominal=0.01))
ductIn	mediums(each Xi(each nominal=0.01))
		mediums(each Xi(nominal=0.01))

---

model Fluid.Examples.InverseParameterization

Component	Modelica 3.2.3	Modelica 3.2.2
system	m_flow_start=0.4

---

model Fluid.Pipes.BaseClasses.FlowModels.PartialGenericPipeFlow

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... equation   for i in 1:n-1 loop
assert(m_flows[i] > -m_flow_small or allowFlowReversal, "Reversing flow occurs even though allowFlowReversal is false");	assert(m_flows[i] > -m_flow_small or allowFlowReversal, "Reverting flow occurs even though allowFlowReversal is false");
end for; ...

---

model Fluid.Pipes.BaseClasses.WallFriction.TestWallFrictionAndGravity

Component	Modelica 3.2.3	Modelica 3.2.2
mu_a	=if not WallFriction.use_mu then 1e-10 else (if use_nominal then mu_nominal else Medium.dynamicViscosity(state_a))	=if not WallFriction.use_mu then 1.e-10 else (if use_nominal then mu_nominal else Medium.dynamicViscosity(state_a))
mu_b	=if not WallFriction.use_mu then 1e-10 else (if use_nominal then mu_nominal else Medium.dynamicViscosity(state_b))	=if not WallFriction.use_mu then 1.e-10 else (if use_nominal then mu_nominal else Medium.dynamicViscosity(state_b))

---

model Fluid.Machines.BaseClasses.PartialPump

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... if not checkValve then
head = homotopy((N/N_nominal)^2*flowCharacteristic(V_flow_single*N_nominal/N), N/N_nominal*(flowCharacteristic(0)+V_flow_single*noEvent(if abs(V_flow_single_init)>0 then delta_head_init/V_flow_single_init else 0)));	head = homotopy((N/N_nominal)^2*flowCharacteristic(V_flow_single*N_nominal/N), N/N_nominal*(flowCharacteristic(0)+delta_head_init*V_flow_single));
s = 0;
else
head = homotopy(if s > 0 then (N/N_nominal)^2*flowCharacteristic(V_flow_single*N_nominal/N) else (N/N_nominal)^2*flowCharacteristic(0) - s*unitHead, N/N_nominal*(flowCharacteristic(0)+V_flow_single*noEvent(if abs(V_flow_single_init)>0 then delta_head_init/V_flow_single_init else 0)));	head = homotopy(if s > 0 then (N/N_nominal)^2*flowCharacteristic(V_flow_single*N_nominal/N) else (N/N_nominal)^2*flowCharacteristic(0) - s*unitHead, N/N_nominal*(flowCharacteristic(0)+delta_head_init*V_flow_single));
V_flow_single = homotopy(if s > 0 then s*unitMassFlowRate/rho else 0,                                s*unitMassFlowRate/rho_nominal); ...

---

model Fluid.Valves.BaseClasses.PartialValve

Component	Modelica 3.2.3	Modelica 3.2.2
Av	fixed=CvData == Modelica323.Fluid.Types.CvTypes.Av	fixed=if CvData == Modelica322.Fluid.Types.CvTypes.Av then true else false

---

model Fluid.Sources.FixedBoundary

Component	Modelica 3.2.3	Modelica 3.2.2
C	=Medium.C_default	=fill(0, Medium.nC)

---

model Fluid.Sources.Boundary_pT

Component	Modelica 3.2.3	Modelica 3.2.2
C	=Medium.C_default	=fill(0, Medium.nC)

---

model Fluid.Sources.Boundary_ph

Component	Modelica 3.2.3	Modelica 3.2.2
C	=Medium.C_default	=fill(0, Medium.nC)

---

model Fluid.Sources.MassFlowSource_T

Component	Modelica 3.2.3	Modelica 3.2.2
C	=Medium.C_default	=fill(0, Medium.nC)

---

model Fluid.Sources.MassFlowSource_h

Component	Modelica 3.2.3	Modelica 3.2.2
C	=Medium.C_default	=fill(0, Medium.nC)

---

model Fluid.Sources.BaseClasses.PartialFlowSource

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
assert(abs(sum(abs(ports.m_flow)) - max(abs(ports.m_flow))) <= Modelica323.Constants.small,   "FlowSource only supports one connection with flow");
assert(nPorts > 0, "At least one port needs to be present (nPorts > 0), otherwise the model is singular");
for i in 1:nPorts loop ...

---

model Fluid.Sensors.MassFractionsTwoPort

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... ind:= -1;
for i in 1:Medium.nXi loop	for i in 1:Medium.nC loop
if (Modelica323.Utilities.Strings.isEqual(Medium.substanceNames[i],   substanceName)) then ...

---

model Fluid.Interfaces.PartialTwoPortTransport

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... m_flow = port_a.m_flow;
assert(m_flow > -m_flow_small or allowFlowReversal, "Reversing flow occurs even though allowFlowReversal is false");	assert(m_flow > -m_flow_small or allowFlowReversal, "Reverting flow occurs even though allowFlowReversal is false");
port_a.m_flow + port_b.m_flow = 0; ...

---

model Fluid.Interfaces.PartialLumpedVolume

Component	Modelica 3.2.3	Modelica 3.2.2
C_start	=Medium.C_default	=fill(0, Medium.nC)

---

model Fluid.Interfaces.PartialDistributedVolume

Component	Modelica 3.2.3	Modelica 3.2.2
C_start	=Medium.C_default	=fill(0, Medium.nC)

---

function Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=(IN_var.rho*velocity*d_hyd/max(MIN, IN_var.eta))	=max(1, IN_var.rho*velocity*d_hyd/max(MIN, IN_var.eta))

---

function Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapOverall_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=(IN_var.rho*velocity*d_hyd/max(MIN, IN_var.eta))	=max(1, IN_var.rho*velocity*d_hyd/max(MIN, IN_var.eta))

---

function Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapTurbulent_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=max(MIN, (IN_var.rho*velocity*d_hyd/max(MIN, IN_var.eta)))	=max(2.6, IN_var.rho*velocity*d_hyd/max(MIN, IN_var.eta))

---

function Fluid.Dissipation.HeatTransfer.General.kc_approxForcedConvection_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=(4*abs(IN_var.m_flow)/max(MIN, IN_con.perimeter*IN_var.eta))	=max(1, 4*abs(IN_var.m_flow)/max(MIN, IN_con.perimeter*IN_var.eta))

---

function Fluid.Dissipation.HeatTransfer.HeatExchanger.kc_flatTube

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... if IN_con.geometry == TYP.LouverFin then
Re = abs(IN_var.m_flow)*IN_con.L_p/(IN_var.eta*A_c);	Re = max(1e-3, abs(IN_var.m_flow)*IN_con.L_p/(IN_var.eta*A_c));
Nu = max(1e-3, kc*IN_con.L_p/IN_var.lambda);
elseif IN_con.geometry == TYP.RectangularFin then
Re = abs(IN_var.m_flow)*IN_con.D_h/(IN_var.eta*A_c);	Re = max(1e-3, abs(IN_var.m_flow)*IN_con.D_h/(IN_var.eta*A_c));
Nu = max(1e-3, kc*IN_con.D_h/IN_var.lambda); ...

---

function Fluid.Dissipation.HeatTransfer.HeatExchanger.kc_flatTube_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re_Dh	=max(MIN, (abs(IN_var.m_flow)*IN_con.D_h/(IN_var.eta*A_c)))	=max(1e-3, abs(IN_var.m_flow)*IN_con.D_h/(IN_var.eta*A_c))
Re_Lp	=max(MIN, (abs(IN_var.m_flow)*IN_con.L_p/(IN_var.eta*A_c)))	=max(1e-3, abs(IN_var.m_flow)*IN_con.L_p/(IN_var.eta*A_c))

---

function Fluid.Dissipation.HeatTransfer.HeatExchanger.kc_roundTube

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... if IN_con.geometry == TYP.PlainFin or IN_con.geometry == TYP.LouverFin or       IN_con.geometry == TYP.SlitFin or IN_con.geometry == TYP.WavyFin then
Re = abs(IN_var.m_flow)*IN_con.D_c/(IN_var.eta*A_c);	Re = max(1e-3, abs(IN_var.m_flow)*IN_con.D_c/(IN_var.eta*A_c));
Nu = max(1e-3, kc*IN_con.D_c/IN_var.lambda); ...

---

function Fluid.Dissipation.HeatTransfer.HeatExchanger.kc_roundTube_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re_Dc	=max(MIN, (abs(IN_var.m_flow)*IN_con.D_c/(IN_var.eta*A_c)))	=max(1e-3, abs(IN_var.m_flow)*IN_con.D_c/(IN_var.eta*A_c))
Re_i	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... elseif IN_con.geometry == TYP.WavyFin then
Re_i = 2*exp(2.921)^(1/(A_c/IN_con.A_fr));	if Re_Dc < exp(2.921) then
if Re_Dc > Re_i then	j = 1.201/(log(exp(2.921)^(A_c/IN_con.A_fr)))^2.921;
j = 1.201/((Modelica323.Math.log(Re_Dc^(A_c/IN_con.A_fr)))^2.921);	kc = j*(exp(2.921)*Pr^(1/3)*IN_var.lambda/IN_con.D_c);
else
j = (Re_Dc - Re_i)*(-1.201*2.921*(A_c/IN_con.A_fr)/((Modelica323.Math.log(Re_i^ (A_c/IN_con.A_fr)))^3.921*Re_i)) + 1.201/((Modelica323.Math.log(Re_i^(A_c/ IN_con.A_fr)))^2.921);	j = 1.201/((log(Re_Dc^(A_c/IN_con.A_fr)))^2.921);
	kc = j*(Re_Dc*Pr^(1/3)*IN_var.lambda/IN_con.D_c);
end if;
kc = j*(Re_Dc*Pr^(1/3)*IN_var.lambda/IN_con.D_c);
else ...

---

function Fluid.Dissipation.HeatTransfer.HelicalPipe.kc_laminar

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Pr := abs(IN_var.eta*IN_var.cp/max(MIN, IN_var.lambda));
Re = abs(IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta));	Re = max(1, abs(IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta)));
kc = Modelica323.Fluid.Dissipation.HeatTransfer.HelicalPipe.kc_laminar_KC(   IN_con, IN_var); ...

---

function Fluid.Dissipation.HeatTransfer.HelicalPipe.kc_laminar_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=(IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))	=max(1, IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))

---

function Fluid.Dissipation.HeatTransfer.HelicalPipe.kc_overall

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Pr := abs(IN_var.eta*IN_var.cp/max(MIN, IN_var.lambda));
Re = (IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta));	Re = max(MIN, IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta));
kc = Modelica323.Fluid.Dissipation.HeatTransfer.HelicalPipe.kc_overall_KC(   IN_con, IN_var); ...

---

function Fluid.Dissipation.HeatTransfer.HelicalPipe.kc_overall_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=(IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))	=max(1e-3, IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))

---

function Fluid.Dissipation.HeatTransfer.HelicalPipe.kc_turbulent

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Pr := abs(IN_var.eta*IN_var.cp/IN_var.lambda);
Re = abs(IN_var.rho*velocity*IN_con.d_hyd/IN_var.eta);	Re = max(1e-3, abs(IN_var.rho*velocity*IN_con.d_hyd/IN_var.eta));
kc = Modelica323.Fluid.Dissipation.HeatTransfer.HelicalPipe.kc_turbulent_KC(   IN_con, IN_var); ...

---

function Fluid.Dissipation.HeatTransfer.HelicalPipe.kc_turbulent_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=(IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))	=max(1e-3, IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))

---

function Fluid.Dissipation.HeatTransfer.Plate.kc_laminar

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Pr := IN_var.eta*IN_var.cp/max(MIN, IN_var.lambda);
Re = abs(IN_var.rho*IN_var.velocity*IN_con.L/max(MIN, IN_var.eta));	Re = max(1e-3, abs(IN_var.rho*IN_var.velocity*IN_con.L/max(MIN, IN_var.eta)));
kc = Modelica323.Fluid.Dissipation.HeatTransfer.Plate.kc_laminar_KC(IN_con,   IN_var); ...

---

function Fluid.Dissipation.HeatTransfer.Plate.kc_laminar_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=(rho*velocity*L/eta)	=max(1e-3, rho*velocity*L/eta)

---

function Fluid.Dissipation.HeatTransfer.Plate.kc_overall

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Pr := IN_var.eta*IN_var.cp/max(MIN, IN_var.lambda);
Re = abs(IN_var.rho*IN_var.velocity*IN_con.L/max(MIN, IN_var.eta));	Re = max(1e-3, abs(IN_var.rho*IN_var.velocity*IN_con.L/max(MIN, IN_var.eta)));
kc = Modelica323.Fluid.Dissipation.HeatTransfer.Plate.kc_overall_KC(IN_con,   IN_var); ...

---

function Fluid.Dissipation.HeatTransfer.Plate.kc_turbulent

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Pr := abs(IN_var.eta*IN_var.cp/max(MIN, IN_var.lambda));
Re = abs(IN_var.rho*IN_var.velocity*IN_con.L/max(MIN, IN_var.eta));	Re = max(1e-3, abs(IN_var.rho*IN_var.velocity*IN_con.L/max(MIN, IN_var.eta)));
kc = Modelica323.Fluid.Dissipation.HeatTransfer.Plate.kc_turbulent_KC(IN_con,   IN_var); ...

---

function Fluid.Dissipation.HeatTransfer.Plate.kc_turbulent_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=abs(rho*velocity*L/eta)	=max(1e-3, abs(rho*velocity*L/eta))

---

function Fluid.Dissipation.HeatTransfer.StraightPipe.kc_laminar

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Pr := abs(IN_var.eta*IN_var.cp/max(MIN, IN_var.lambda));
Re = (IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta));	Re = max(1e-3, IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta));
kc = Modelica323.Fluid.Dissipation.HeatTransfer.StraightPipe.kc_laminar_KC(   IN_con, IN_var); ...

---

function Fluid.Dissipation.HeatTransfer.StraightPipe.kc_laminar_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=(IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))	=max(1e-3, IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))

---

function Fluid.Dissipation.HeatTransfer.StraightPipe.kc_overall

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Pr := abs(IN_var.eta*IN_var.cp/max(MIN, IN_var.lambda));
Re = (IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta));	Re = max(1e-3, IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta));
kc = Modelica323.Fluid.Dissipation.HeatTransfer.StraightPipe.kc_overall_KC(   IN_con, IN_var); ...

---

function Fluid.Dissipation.HeatTransfer.StraightPipe.kc_overall_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=(IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))	=max(1e-3, IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta))

---

function Fluid.Dissipation.HeatTransfer.StraightPipe.kc_turbulent

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Pr := abs(IN_var.eta*IN_var.cp/max(MIN, IN_var.lambda));
Re = (IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta));	Re = max(1e-3, IN_var.rho*velocity*IN_con.d_hyd/max(MIN, IN_var.eta));
kc = Modelica323.Fluid.Dissipation.HeatTransfer.StraightPipe.kc_turbulent_KC(   IN_con, IN_var); ...

---

function Fluid.Dissipation.HeatTransfer.StraightPipe.kc_turbulent_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re	=max(MIN, (IN_var.rho*velocity*IN_con.d_hyd/IN_var.eta))	=max(2.6, IN_var.rho*velocity*IN_con.d_hyd/IN_var.eta)

---

function Fluid.Dissipation.Utilities.Functions.HeatTransfer.TwoPhase.kc_twoPhase_condensationHorizontal_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re_l	=(IN_var.rho_l*velocity*d_hyd/max(MIN, IN_var.eta_l))	=max(1, IN_var.rho_l*velocity*d_hyd/max(MIN, IN_var.eta_l))

---

function Fluid.Dissipation.Utilities.Functions.HeatTransfer.TwoPhase.kc_twoPhase_boilingVertical_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re_l	=(IN_var.rho_l*velocity_l*d_hyd/max(MIN, IN_var.eta_l))	=max(1, IN_var.rho_l*velocity_l*d_hyd/max(MIN, IN_var.eta_l))

---

function Fluid.Dissipation.Utilities.Functions.HeatTransfer.TwoPhase.kc_twoPhase_boilingHorizontal_KC

Component	Modelica 3.2.3	Modelica 3.2.2
Re_l	=(IN_var.rho_l*velocity_l*d_hyd/max(MIN, IN_var.eta_l))	=max(1, IN_var.rho_l*velocity_l*d_hyd/max(MIN, IN_var.eta_l))

---

function Fluid.Utilities.checkBoundary

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... end for;
if nX > 0 and abs(sum(X_boundary) - 1.0) > 1e-10 then	if nX > 0 and abs(sum(X_boundary) - 1.0) > 1.e-10 then
X_str = ""; ...

---

model Media.Examples.ReferenceAir.Inverse_sh_T

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
h1 = if time < 0 then h_min else if time >= 1 then h_max else h_min + time /timeUnit*(h_max - h_min);	h1 = if time < 0 then h_min else if time > 1 then h_max else h_min + time /timeUnit*(h_max - h_min);
s1 = if time < 0 then s_min else if time >= 1 then s_max else s_min + time /timeUnit*(s_max - s_min);	s1 = if time < 0 then s_min else if time > 1 then s_max else s_min + time /timeUnit*(s_max - s_min);
Th = Medium.temperature_phX(           p,           h1,           fill(0.0, 0)); ...

---

model Media.Examples.ReferenceAir.Inverse_sh_TX

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
h1 = if time < 0 then h_min else if time >= 1 then h_max else h_min + time /timeUnit*(h_max - h_min);	h1 = if time < 0 then h_min else if time > 1 then h_max else h_min + time /timeUnit*(h_max - h_min);
s1 = if time < 0 then s_min else if time >= 1 then s_max else s_min + time /timeUnit*(s_max - s_min);	s1 = if time < 0 then s_min else if time > 1 then s_max else s_min + time /timeUnit*(s_max - s_min);
Th = Medium.temperature_phX(           p,           h1,           X); ...

---

model Media.Examples.TestOnly.MixIdealGasAir

Component	Modelica 3.2.3	Modelica 3.2.2
medium2	X(start={0.2,0.8}, each fixed=true)	X(start={0.2,0.8}, fixed=true)

---

model Media.Examples.TestOnly.FlueGas

Component	Modelica 3.2.3	Modelica 3.2.2
medium2	X(start={0.2,0.1,0.3,0.4}, each fixed=true)	X(start={0.2,0.1,0.3,0.4}, fixed=true)

---

model Media.Examples.Tests.Components.ShortPipe

Component	Modelica 3.2.3	Modelica 3.2.2
dp_nominal	min=1e-10	min=1.e-10
m_flow_nominal	min=1e-10	min=1.e-10

---

package Media.Interfaces.PartialMedium

Component	Modelica 3.2.3	Modelica 3.2.2
C_default	Present

---

function Media.Air.MoistAir.molarMass

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
MM := Modelica323.Constants.R/Modelica323.Media.Air.MoistAir.gasConstant(state);	MM := Modelica322.Media.Air.MoistAir.gasConstant(state)/Modelica322.Constants.R;

---

function Media.Air.MoistAir.s_pTX_der

Component	Modelica 3.2.3	Modelica 3.2.2
dX	each unit="1/s"
		unit="1/s"

---

model Media.Air.ReferenceMoistAir.BaseProperties

Component	Modelica 3.2.3	Modelica 3.2.2
x_water	Real	Media.Interfaces.Types.MassFraction
x_sat	Real	Media.Interfaces.Types.MassFraction

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... p_steam_sat = Modelica323.Media.Air.ReferenceMoistAir.Utilities.pds_pT(p, T);
X_sat = Modelica323.Media.Air.ReferenceMoistAir.Xsaturation(state);	X_sat = k_mair/(p/p_steam_sat - 1 + k_mair);
X_liquid = max(Xi[Water] - X_sat, 0.0);	X_liquid = Xi[Water] - X_sat;
X_steam = Xi[Water] - X_liquid; ... state.X = X;
x_sat = Modelica323.Media.Air.ReferenceMoistAir.xsaturation(state);	x_sat = k_mair*p_steam_sat/max(100*Constants.eps, p - p_steam_sat);
x_water = Modelica323.Media.Air.ReferenceMoistAir.waterContent_X(state.X);	x_water = Xi[Water]/max(X_air, 100*Constants.eps);
phi = Modelica323.Media.Air.ReferenceMoistAir.Utilities.phi_pTX(   p,   T,   Xi);

---

function Media.Air.ReferenceMoistAir.massFractionWaterVapor

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
xw := state.X[1]/max(100*Modelica323.Constants.eps, (1 - state.X[1]));	xw := state.X[1]/(1 - state.X[1]);
xws = Utilities.xws_pT(state.p, state.T); ...

---

function Media.Air.ReferenceMoistAir.massFractionWaterNonVapor

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
xw := state.X[1]/max(100*Modelica323.Constants.eps, (1 - state.X[1]));	xw := state.X[1]/(1 - state.X[1]);
xws = Utilities.xws_pT(state.p, state.T); ...

---

function Media.Air.ReferenceMoistAir.waterContent_X

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
xw := X[1]/max(100*Modelica323.Constants.eps, (1 - X[1]));	xw := X[1]/(1 - X[1]);

---

function Media.Air.ReferenceMoistAir.molarMass

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
MM := 1/(state.X[1]/steam.MM + state.X[2]/dryair.MM);	MM := 1/(state.X[1]*steam.MM + state.X[2]*dryair.MM);

---

function Media.Air.ReferenceMoistAir.Utilities.pds_pT

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
pds = p;	pds = -1;
end if; ...

---

function Media.Air.ReferenceMoistAir.Utilities.xws_pT

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Tlim = if (T <= 273.16) then   Modelica323.Media.Air.ReferenceMoistAir.Utilities.Ice09_Utilities.Basic.Tsub(   p) else   Modelica323.Media.Air.ReferenceMoistAir.Utilities.Water95_Utilities.Tsat(p);
xws = if (pds < p) then pds*Modelica323.Media.Air.ReferenceMoistAir.k_mair/(p - pds) else Modelica323.Constants.inf;	xws = if (T <= Tlim) then Modelica322.Media.Air.ReferenceMoistAir.k_mair*pds/(p - pds) else -1;

---

function Media.Air.ReferenceMoistAir.Utilities.phi_pTX

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... pd = xw/(Modelica323.Media.Air.ReferenceMoistAir.k_mair + xw)*p;
phi = pd/max(100*Modelica323.Constants.eps, pds);	if (pd <= pds) then
end if;	phi = pd/pds;
	else
	phi = -1; end if; end if;

---

function Media.Air.ReferenceMoistAir.Utilities.pd_pTX_der

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... xws = Modelica323.Media.Air.ReferenceMoistAir.Utilities.xws_pT(p, T);
pd_der = if (xw <= xws) then pd_der else pds_der;	pd_der = if ((xw <= xws) or (xws == -1)) then pd_der else pds_der;
end if; ...

---

function Media.Air.ReferenceMoistAir.Utilities.xws_pT_der

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... Tlim = if (T <= 273.16) then   Modelica323.Media.Air.ReferenceMoistAir.Utilities.Ice09_Utilities.Basic.Tsub(   p) else   Modelica323.Media.Air.ReferenceMoistAir.Utilities.Water95_Utilities.Tsat(p);
if (pds < p) then	if (T <= Tlim) then
xws_der = Modelica323.Media.Air.ReferenceMoistAir.k_mair*((pds_der*(p - pds) +   pds*pds_der)/(p - pds)^2); ...

---

function Media.Air.ReferenceMoistAir.Utilities.pds_pT_der

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
pds_der = p_der;	pds_der = 0;
end if; ...

---

function Media.IdealGases.Common.Functions.thermalConductivityEstimate

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
lambda := if method == 1 then eta*(Cp - data.R + (9/4)*data.R) else eta*(Cp - data.R)*(1.32 + 1.77/((Cp/data.R) - 1.0));	lambda := if method == 1 then eta*(Cp - data.R + (9/4)*data.R) else eta*(Cp - data.R)*(1.32 + 1.77/((Cp/Modelica322.Constants.R) - 1.0));

---

function Media.IdealGases.Common.MixtureGasNasa.specificEntropy

Component	Modelica 3.2.3	Modelica 3.2.2
Y	each unit="mol/mol"
		unit="mol/mol"

---

function Media.IdealGases.Common.MixtureGasNasa.mixtureViscosityChung

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... mum = (sigmam3*(sum(sum(y[i]*y[j]*mu[i]^2*mu[j]^2/sigma[i,j]^3 for j in 1:n) for i in 1:n)))^(1/4);
Vcm = sigmam3/(0.809)^3 "eq. (4)";	Vcm = sigmam3/(0.809)^3;
Tcm = 1.2593*edivkm "eq. (5)";	Tcm = 1.2593*edivkm;
murm = 131.3*mum/(Vcm*Tcm)^(1/2) "eq. (8)";	murm = 131.3*mum/(Vcm*Tcm)^(1/2);
kappam = (sigmam3*(sum(sum(y[i]*y[j]*kappaij[i,j] for j in 1:n) for i in 1:n)));
Fcm = 1 - 0.275*wm + 0.059035*murm^4 + kappam "eq. (7)";	Fcm = 1 - 0.275*wm + 0.059035*murm^4 + kappam;
Tmstar = T/edivkm "eq. (3)";	Tmstar = T/edivkm;
omegav = 1.16145*(Tmstar)^(-0.14874) + 0.52487*Modelica323.Math.exp(-0.77320* Tmstar) + 2.16178*Modelica323.Math.exp(-2.43787*Tmstar) "eq. (2)";	omegav = 1.16145*(Tmstar)^(-0.14874) + 0.52487*Math.exp(-0.77320*Tmstar) + 2.16178*Math.exp(-2.43787*Tmstar);
etam = 26.69*Fcm*(Mm*T)^(1/2)/(sigmam3^(2/3)*omegav) "eq. (1)";	etam = 26.69*Fcm*(Mm*T)^(1/2)/(sigmam3^(2/3)*omegav);
etaMixture = etam*1e-7;	etaMixture = etam*1e7;

---

package Media.IdealGases.Common.SingleGasesData

Component	Modelica 3.2.3	Modelica 3.2.2
CH2	blow={4.733624710e+004,-2.143628603e+000}	blow={0,47336.2471}
	ahigh={2550418.031,-7971.62539,12.28924487,-0.001699122922,2.991728605e-007,-2.767007492e-011,1.051341740e-015}	ahigh={10027.417,2550418.031,-7971.62539,12.28924487,-0.001699122922,2.991728605e-007,-2.767007492e-011}
	bhigh={9.642216890e+004,-6.094739910e+001}	bhigh={1.05134174e-015,0}
CH3	blow={1.408271825e+004,2.022772791e+001}	blow={0,14082.71825}
	ahigh={2760802.663,-9336.53117,14.87729606,-0.001439429774,2.444477951e-007,-2.224555778e-011,8.395065760e-016}	ahigh={10366.34,2760802.663,-9336.53117,14.87729606,-0.001439429774,2.444477951e-007,-2.224555778e-011}
	bhigh={7.481809480e+004,-7.919682400e+001}	bhigh={8.39506576e-016,0}
CH3OOH	blow={-3.058414201e+004,1.031696850e+002}	blow={0,-30584.14201}
	ahigh={3060740.61,-12829.59627,25.41021168,-0.002394481095,4.44342991e-007,-4.4166595e-011,1.819673372e-015}	ahigh={13918.692,3060740.61,-12829.59627,25.41021168,-0.002394481095,4.44342991e-007,-4.4166595e-011}
	bhigh={5.837492360e+004,-1.387713096e+002}	bhigh={1.819673372e-015,0}
C2CL2	alow={3.871168730e+004,-9.336870210e+002,1.119377832e+001,-3.746287380e-003,6.770471350e-006,-4.910387450e-009,1.299068486e-012}	alow={38711.6908,-933.6870729999999,11.19377861,-0.0037462882,6.77047256e-006,-4.91038835e-009,1.299068749e-012}
	blow={2.948153174e+004,-3.310723530e+001}	blow={0,29481.53198}
	ahigh={2.961995390e+005,-2.044290845e+003,1.187529729e+001,-5.115031340e-004,1.072666588e-007,-1.183417569e-011,5.326530480e-016}	ahigh={14592.612,296197.8472,-2044.286552,11.87529315,-0.000511501145,1.072661556e-007,-1.183411171e-011}
	bhigh={3.636802500e+004,-4.000826050e+001}	bhigh={5.32649834e-016,0}
C2CL4	alow={3.746257500e+004,-8.481774390e+002,1.009156041e+001,1.845463807e-002,-2.390899731e-005,1.514828471e-008,-3.841119950e-012}	alow={37462.583,-848.177563,10.0915611,0.01845463613,-2.390899444e-005,1.514828257e-008,-3.84111932e-012}
	blow={-1.598289063e+003,-2.368079134e+001}	blow={0,-1598.288471}
	ahigh={-3.001289625e+005,-1.132413909e+003,1.683073063e+001,-3.288820170e-004,7.220975400e-008,-8.245417760e-012,3.810154710e-016}	ahigh={19605.643,-300131.5659,-1132.407598,16.8307247,-0.000328879249,7.22090703e-008,-8.24533269e-012}
	bhigh={-2.292758158e+003,-5.980164420e+001}	bhigh={3.81011278e-016,0}
C2CL6	alow={1.593451902e+005,-2.606697262e+003,2.028011918e+001,1.769364625e-002,-3.133104894e-005,2.389395021e-008,-6.893037660e-012}	alow={159345.1813,-2606.697136,20.28011847,0.01769364822,-3.133105185e-005,2.389395238e-008,-6.8930383e-012}
	blow={-9.038007040e+003,-7.953073010e+001}	blow={0,-9038.00764}
	ahigh={-5.577351940e+005,-4.976576790e+002,2.237042798e+001,-1.477797229e-004,3.257641460e-008,-3.727218070e-012,1.723860648e-016}	ahigh={27129.39,-557738.632,-497.649124,22.37041989,-0.0001477759098,3.25754658e-008,-3.72709921e-012}
	bhigh={-2.335217699e+004,-8.381736910e+001}	bhigh={1.723801704e-016,0}
C2HCL	alow={1.329784931e+005,-2.174542005e+003,1.497980787e+001,-1.290343200e-002,1.602596399e-005,-9.152047430e-009,2.021222995e-012}	alow={132978.5007,-2174.542126,14.97980854,-0.01290343389,1.602596678e-005,-9.152049509999999e-009,2.021223607e-012}
	blow={3.604801260e+004,-5.958236750e+001}	blow={0,36048.0132}
	ahigh={1.152149855e+006,-4.461204350e+003,1.281367818e+001,-6.797397460e-004,1.151395389e-007,-1.046657798e-011,3.949939170e-016}	ahigh={11787.625,1152145.326,-4461.192999999999,12.81366744,-0.000679734676,1.151382756e-007,-1.046641954e-011}
	bhigh={5.233955000e+004,-5.320661700e+001}	bhigh={3.94986052e-016,0}
C2HCL3	alow={3.959233060e+004,-5.178756040e+002,5.155030160e+000,2.816922101e-002,-3.624741150e-005,2.392073843e-008,-6.362400700e-012}	alow={39592.3125,-517.875358,5.15502877,0.02816922486,-3.62474172e-005,2.39207427e-008,-6.36240196e-012}
	blow={-1.534345080e+003,1.209377115e+000}	blow={0,-1534.346259}
	ahigh={6.049298240e+005,-4.237003190e+003,1.846274582e+001,-8.137243260e-004,1.551223511e-007,-1.584645594e-011,6.701006540e-016}	ahigh={16604.624,604925.466,-4236.992319999999,18.46273557,-0.000813719506,1.551211545e-007,-1.584630634e-011}
	bhigh={1.848292676e+004,-7.698375250e+001}	bhigh={6.70093249e-016,0}
CH2CO_ketene	blow={-5.209992580e+003,3.839604220e+000}	blow={0,-5209.99258}
	ahigh={2013564.915,-8200.88746,17.59694074,-0.001464544521,2.695886969e-007,-2.66567484e-011,1.094204522e-015}	ahigh={11795.805,2013564.915,-8200.88746,17.59694074,-0.001464544521,2.695886969e-007,-2.66567484e-011}
	bhigh={4.177776880e+004,-8.725803580e+001}	bhigh={1.094204522e-015,0}
O_CH_2O	blow={-4.454486010e+004,1.327028760e+002}	blow={0,-44544.8601}
	ahigh={267806.3593,-4436.61748,17.81696797,-0.000709717378,1.272621878e-007,-1.237226678e-011,5.025057520e-016}	ahigh={13682.443,267806.3593,-4436.61748,17.81696797,-0.000709717378,1.272621878e-007,-1.237226678e-011}
	bhigh={-4.479608280e+003,-8.156700640e+001}	bhigh={5.02505752e-016,0}
HO_CO_2OH	blow={-8.797942550e+004,9.751091370e+000}	blow={0,-87979.4255}
	ahigh={1805560.696,-9240.33315,26.25742604,-0.001418458557,2.526840574e-007,-2.521005198e-011,1.040036111e-015}	ahigh={17321.662,1805560.696,-9240.33315,26.25742604,-0.001418458557,2.526840574e-007,-2.521005198e-011}
	bhigh={-3.754286460e+004,-1.326879788e+002}	bhigh={1.040036111e-015,0}
CH2BrminusCOOH	blow={-5.541187620e+004,8.165423200e+001}	blow={0,-55411.8762}
	ahigh={2486349.85,-11402.56346,27.56020307,-0.00184318701,3.26539274e-007,-3.122663159e-011,1.223452495e-015}	ahigh={16862.437,2486349.85,-11402.56346,27.56020307,-0.00184318701,3.26539274e-007,-3.122663159e-011}
	bhigh={1.837013127e+004,-1.420040888e+002}	bhigh={1.223452495e-015,0}
C2H3CL	alow={-1.688896130e+004,8.545105550e+002,-6.514968110e+000,4.944682090e-002,-6.117756910e-005,4.067294030e-008,-1.101392662e-011}	alow={-16888.95457,854.510455,-6.51496755,0.0494468193,-6.11775667e-005,4.067293850000001e-008,-1.101392611e-011}
	blow={-2.069321797e+003,5.928435530e+001}	blow={0,-2069.321321}
	ahigh={2.456178566e+006,-1.047452720e+004,2.178736544e+001,-1.816893523e-003,3.296374030e-007,-3.214400710e-011,1.302256512e-015}	ahigh={11819.647,2456176.938,-10474.52327,21.78736181,-0.001816891849,3.29636995e-007,-3.21439569e-011}
	bhigh={6.346231290e+004,-1.149890773e+002}	bhigh={1.302254061e-015,0}
CH2CLminusCOOH	alow={-1.122506431e+005,2.168288546e+003,-1.227791221e+001,7.514388060e-002,-9.083158490e-005,5.812363980e-008,-1.518247440e-011}	alow={-112250.6518,2168.288658,-12.27791286,0.0751438825,-9.083158770000001e-005,5.81236419e-008,-1.518247503e-011}
	blow={-6.314314500e+004,9.694389710e+001}	blow={0,-63143.1455}
	ahigh={2.472881709e+006,-1.152275613e+004,2.766275288e+001,-1.886429520e-003,3.361772590e-007,-3.231268060e-011,1.273273865e-015}	ahigh={16513.941,2472883.176,-11522.75963,27.66275606,-0.001886430963,3.36177605e-007,-3.23127225e-011}
	bhigh={1.370384800e+004,-1.443191119e+002}	bhigh={1.273275883e-015,0}
HO2	blow={-5.873350960e+003,5.193602140e+001}	blow={0,-5873.35096}
	ahigh={-1810669.724,4963.19203,-1.039498992,0.004560148530000001,-1.061859447e-006,1.144567878e-010,-4.763064160e-015}	ahigh={10002.162,-1810669.724,4963.19203,-1.039498992,0.004560148530000001,-1.061859447e-006,1.144567878e-010}
	bhigh={-3.200817190e+004,4.066850920e+001}	bhigh={-4.76306416e-015,0}
HO2minus	blow={-7.417741590e+003,-1.251878002e+001}	blow={0,-7417.741590000001}
	ahigh={793330.6,-2503.312417,7.54896233,8.308390149999999e-005,-5.96973091e-008,9.955377000000001e-012,-5.606477280e-016}	ahigh={10245.32,793330.6,-2503.312417,7.54896233,8.308390149999999e-005,-5.96973091e-008,9.955377000000001e-012}
	bhigh={2.512079084e+003,-2.070065846e+001}	bhigh={-5.60647728e-016,0}
OD	alow={2.118691536e+004,-2.785982360e+002,5.456210120e+000,-6.148119830e-003,9.117670560e-006,-5.527812710e-009,1.239794711e-012}	alow={21186.91536,-278.598236,5.45621012,-0.00614811983,9.117670560000001e-006,-5.527812710000001e-009,1.239794711e-012}
	blow={4.464878250e+003,-7.616618910e+000}	blow={0,4464.87825}
	ahigh={7.832473160e+005,-2.532992554e+003,5.952124650e+000,-3.743595280e-004,4.959527620e-008,3.454454730e-012,-7.380626800e-016}	ahigh={8999.108,783247.316,-2532.992554,5.95212465,-0.000374359528,4.95952762e-008,3.45445473e-012}
	bhigh={1.930492973e+004,-1.568898441e+001}	bhigh={-7.3806268e-016,0}
ODminus	alow={5.606128320e+004,-7.514156150e+002,7.544188470e+000,-1.092083064e-002,1.503688938e-005,-9.351665840e-009,2.246466046e-012}	alow={56061.2832,-751.415615,7.54418847,-0.01092083064,1.503688938e-005,-9.35166584e-009,2.246466046e-012}
	blow={-1.515707370e+004,-2.106498377e+001}	blow={0,-15157.0737}
	ahigh={3.029467029e+005,-1.079684654e+003,4.211417380e+000,6.260830070e-004,-2.411665054e-007,4.248425540e-011,-2.387099102e-015}	ahigh={8642.103999999999,302946.7029,-1079.684654,4.21141738,0.000626083007,-2.411665054e-007,4.248425540000001e-011}
	bhigh={-1.188935343e+004,-4.724898790e+000}	bhigh={-2.387099102e-015,-11889.35343}

---

model Media.Incompressible.TableBased.BaseProperties

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... assert(T >= T_min and T <= T_max, "Temperature T (= " + String(T) +          " K) is not in the allowed range (" + String(T_min) +          " K <= T <= " + String(T_max) + " K) required from medium model \""          + mediumName + "\".");
R = Modelica323.Constants.R/MM_const;	R = Modelica322.Constants.R;
cp = Poly.evaluate(poly_Cp,if TinK then T else T_degC); ...

---

function Media.Water.IF97_Utilities.BaseIF97.Basic.psat

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
assert(T >= 273.16, "IF97 medium function psat: input temperature (= " + String(triple.Ttriple) + " K).\n" + "lower than the triple point temperature 273.16 K");	assert(T >= 273.16, "IF97 medium function psat: input temperature (= " + String(triple.ptriple) + " K).\n" + "lower than the triple point temperature 273.16 K");
o[1] = -650.17534844798 + Tlim; ...

---

model Thermal.FluidHeatFlow.Examples.SimpleCooling

Component	Modelica 3.2.3	Modelica 3.2.2
medium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
dTtoPipe	=prescribedHeatFlow.port.T - pipe.T_q	=prescribedHeatFlow.port.T - pipe.heatPort.T
pipe	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe

---

model Thermal.FluidHeatFlow.Examples.ParallelCooling

Component	Modelica 3.2.3	Modelica 3.2.2
medium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
dTtoPipe1	=prescribedHeatFlow1.port.T - pipe1.T_q	=prescribedHeatFlow1.port.T - pipe1.heatPort.T
dTtoPipe2	=prescribedHeatFlow2.port.T - pipe2.T_q	=prescribedHeatFlow2.port.T - pipe2.heatPort.T
pipe1	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe
pipe2	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe
pipe3	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.IsolatedPipe

---

model Thermal.FluidHeatFlow.Examples.IndirectCooling

Component	Modelica 3.2.3	Modelica 3.2.2
outerMedium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
innerMedium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
dTtoPipe	=prescribedHeatFlow.port.T - pipe1.T_q	=prescribedHeatFlow.port.T - pipe1.heatPort.T
dTCooler	=innerPipe.T_q - outerPipe.T_q	=innerPipe.heatPort.T - outerPipe.heatPort.T
pipe1	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe
outerPipe	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe
innerPipe	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe

---

model Thermal.FluidHeatFlow.Examples.PumpAndValve

Component	Modelica 3.2.3	Modelica 3.2.2
medium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
dTtoPipe	=prescribedHeatFlow.port.T - pipe.T_q	=prescribedHeatFlow.port.T - pipe.heatPort.T
idealPump		V_flow(start=0)
pipe	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe

---

model Thermal.FluidHeatFlow.Examples.PumpDropOut

Component	Modelica 3.2.3	Modelica 3.2.2
medium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
dTtoPipe	=prescribedHeatFlow.port.T - pipe.T_q	=prescribedHeatFlow.port.T - pipe.heatPort.T
pipe	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe

---

model Thermal.FluidHeatFlow.Examples.ParallelPumpDropOut

Component	Modelica 3.2.3	Modelica 3.2.2
medium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
dTtoPipe1	=prescribedHeatFlow1.port.T - pipe1.T_q	=prescribedHeatFlow1.port.T - pipe1.heatPort.T
dTtoPipe2	=prescribedHeatFlow2.port.T - pipe2.T_q	=prescribedHeatFlow2.port.T - pipe2.heatPort.T
pipe1	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe
pipe2	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe
pipe3	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.IsolatedPipe

---

model Thermal.FluidHeatFlow.Examples.OneMass

Component	Modelica 3.2.3	Modelica 3.2.2
medium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
dTtoPipe	=heatCapacitor.port.T - pipe.T_q	=heatCapacitor.port.T - pipe.heatPort.T
pipe	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe

---

model Thermal.FluidHeatFlow.Examples.TwoMass

Component	Modelica 3.2.3	Modelica 3.2.2
medium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
dTtoPipe1	=heatCapacitor1.port.T - pipe1.T_q	=heatCapacitor1.port.T - pipe1.heatPort.T
dTtoPipe2	=heatCapacitor2.port.T - pipe2.T_q	=heatCapacitor2.port.T - pipe2.heatPort.T
pipe1	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe
pipe2	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.HeatedPipe
pipe3	Thermal.FluidHeatFlow.Components.Pipe	Thermal.FluidHeatFlow.Components.IsolatedPipe

---

model Thermal.FluidHeatFlow.Components.IsolatedPipe

Component	Modelica 3.2.3	Modelica 3.2.2
h_g		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	volumeFlow = V_flow; dp = pressureDrop + medium.rho*Modelica322.Constants.g_n*h_g; Q_flow = Q_friction;

---

model Thermal.FluidHeatFlow.Components.HeatedPipe

Component	Modelica 3.2.3	Modelica 3.2.2
h_g		Present
heatPort		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	volumeFlow = V_flow; dp = pressureDrop + medium.rho*Modelica322.Constants.g_n*h_g; Q_flow = heatPort.Q_flow + Q_friction; heatPort.T = T_q;

---

model Thermal.FluidHeatFlow.Sources.AbsolutePressure

Component	Modelica 3.2.3	Modelica 3.2.2
medium		Present
flowPort		Present

---

model Thermal.FluidHeatFlow.Sources.IdealPump

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... else
dp = -dp1*(1 - V_flow/V_flow1);	dp = -dp1*(1-noEvent(abs(V_flow/V_flow1)));
flange_a.tau*w = -dp*V_flow; ...

---

model Thermal.FluidHeatFlow.Interfaces.Partials.TwoPort

Component	Modelica 3.2.3	Modelica 3.2.2
medium	=Modelica323.Thermal.FluidHeatFlow.Media.Medium()	=FluidHeatFlow.Media.Medium()
V_flow	start=0
T_q		protected
h	start=medium.cp*T0

---

model Thermal.FluidHeatFlow.Interfaces.Partials.Ambient

Component	Modelica 3.2.3	Modelica 3.2.2
medium		Present
T		Present
T_port		Present
h		Present
flowPort		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	T_port=flowPort.h/medium.cp; h = medium.cp*T; flowPort.H_flow = semiLinear(flowPort.m_flow,flowPort.h,h);

---

function Math.Matrices.LU

Component	Modelica 3.2.3	Modelica 3.2.2
m	Present
n	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgetrf( m, n, LU, lda, pivots, info);	external "FORTRAN 77" dgetrf( size(A, 1), size(A, 2), LU, lda, pivots, info);

---

function Math.Matrices.LAPACK.dgeev

Component	Modelica 3.2.3	Modelica 3.2.2
ldvl	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgeev( "N", "V", n, Awork, n, eigenReal, eigenImag, dummy, ldvl, eigenVectors, n, work, lwork, info);	external "FORTRAN 77" dgeev( "N", "V", n, Awork, n, eigenReal, eigenImag, dummy, 1, eigenVectors, n, work, size(work, 1), info);

---

function Math.Matrices.LAPACK.dgeev_eigenValues

Component	Modelica 3.2.3	Modelica 3.2.2
lwork	=8*n	=8*size(A, 1)
n	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgeev( "N", "N", n, Awork, n, EigenReal, EigenImag, EigenvectorsL, n, EigenvectorsL, n, work, lwork, info);	external "FORTRAN 77" dgeev( "N", "N", size(A, 1), Awork, size(A, 1), EigenReal, EigenImag, EigenvectorsL, size(EigenvectorsL, 1), EigenvectorsL, size(EigenvectorsL, 1), work, size(work, 1), info);

---

function Math.Matrices.LAPACK.dgegv

Component	Modelica 3.2.3	Modelica 3.2.2
ldvl	Present
ldvr	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgegv( "N", "N", n, Awork, n, Bwork, n, alphaReal, alphaImag, beta, dummy1, ldvl, dummy2, ldvr, work, lwork, info);	external "FORTRAN 77" dgegv( "N", "N", n, Awork, n, Bwork, n, alphaReal, alphaImag, beta, dummy1, 1, dummy2, 1, work, size(work, 1), info);

---

function Math.Matrices.LAPACK.dgelsx_vec

Component	Modelica 3.2.3	Modelica 3.2.2
nrhs	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgelsx( nrow, ncol, nrhs, Awork, nrow, x, nx, jpvt, rcond, rank, work, info);	external "FORTRAN 77" dgelsx( nrow, ncol, 1, Awork, nrow, x, nx, jpvt, rcond, rank, work, info);

---

function Math.Matrices.LAPACK.dgelsy_vec

Component	Modelica 3.2.3	Modelica 3.2.2
nrhs	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgelsy( nrow, ncol, nrhs, Awork, nrow, x, nx, jpvt, rcond, rank, work, lwork, info);	external "FORTRAN 77" dgelsy( nrow, ncol, 1, Awork, nrow, x, nx, jpvt, rcond, rank, work, lwork, info);

---

function Math.Matrices.LAPACK.dgels_vec

Component	Modelica 3.2.3	Modelica 3.2.2
nrhs	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgels( "N", nrow, ncol, nrhs, Awork, nrow, x, nx, work, lwork, info);	external "FORTRAN 77" dgels( "N", nrow, ncol, 1, Awork, nrow, x, nx, work, lwork, info);

---

function Math.Matrices.LAPACK.dgesv

Component	Modelica 3.2.3	Modelica 3.2.2
n	Present
nrhs	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgesv( n, nrhs, Awork, lda, ipiv, X, ldb, info);	external "FORTRAN 77" dgesv( size(A, 1), size(B, 2), Awork, lda, ipiv, X, ldb, info);

---

function Math.Matrices.LAPACK.dgesv_vec

Component	Modelica 3.2.3	Modelica 3.2.2
n	Present
nrhs	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgesv( n, nrhs, Awork, lda, ipiv, x, ldb, info);	external "FORTRAN 77" dgesv( size(A, 1), 1, Awork, lda, ipiv, x, ldb, info);

---

function Math.Matrices.LAPACK.dgtsv

Component	Modelica 3.2.3	Modelica 3.2.2
n	Present
nrhs	Present
ldb	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgtsv( n, nrhs, subdiagwork, diagwork, superdiagwork, X, ldb, info);	external "FORTRAN 77" dgtsv( size(diag, 1), size(B, 2), subdiagwork, diagwork, superdiagwork, X, size(B, 1), info);

---

function Math.Matrices.LAPACK.dgtsv_vec

Component	Modelica 3.2.3	Modelica 3.2.2
n	Present
nrhs	Present
ldb	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgtsv( n, nrhs, subdiagwork, diagwork, superdiagwork, x, ldb, info);	external "FORTRAN 77" dgtsv( size(diag, 1), 1, subdiagwork, diagwork, superdiagwork, x, size(b, 1), info);

---

function Math.Matrices.LAPACK.dgbsv

Component	Modelica 3.2.3	Modelica 3.2.2
nrhs	Present
ldab	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgbsv( n, kLower, kUpper, nrhs, Awork, ldab, ipiv, X, n, info);	external "FORTRAN 77" dgbsv( n, kLower, kUpper, size(B, 2), Awork, size(Awork, 1), ipiv, X, n, info);

---

function Math.Matrices.LAPACK.dgbsv_vec

Component	Modelica 3.2.3	Modelica 3.2.2
nrhs	Present
ldab	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgbsv( n, kLower, kUpper, nrhs, Awork, ldab, ipiv, x, n, info);	external "FORTRAN 77" dgbsv( n, kLower, kUpper, 1, Awork, size(Awork, 1), ipiv, x, n, info);

---

function Math.Matrices.LAPACK.dgesvd

Component	Modelica 3.2.3	Modelica 3.2.2
m	Present
n	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgesvd( "A", "A", m, n, Awork, m, sigma, U, m, VT, n, work, lwork, info);	external "FORTRAN 77" dgesvd( "A", "A", size(A, 1), size(A, 2), Awork, size(A, 1), sigma, U, size(A, 1), VT, size(A, 2), work, lwork, info);

---

function Math.Matrices.LAPACK.dgesvd_sigma

Component	Modelica 3.2.3	Modelica 3.2.2
m	Present
n	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgesvd( "N", "N", m, n, Awork, m, sigma, U, m, VT, n, work, lwork, info);	external "FORTRAN 77" dgesvd( "N", "N", size(A, 1), size(A, 2), Awork, size(A, 1), sigma, U, size(A, 1), VT, size(A, 2), work, lwork, info);

---

function Math.Matrices.LAPACK.dgetrf

Component	Modelica 3.2.3	Modelica 3.2.2
m	Present
n	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgetrf( m, n, LU, lda, pivots, info);	external "FORTRAN 77" dgetrf( size(A, 1), size(A, 2), LU, lda, pivots, info);

---

function Math.Matrices.LAPACK.dgetrs

Component	Modelica 3.2.3	Modelica 3.2.2
n	Present
nrhs	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgetrs( "N", n, nrhs, work, lda, pivots, X, ldb, info);	external "FORTRAN 77" dgetrs( "N", size(LU, 1), size(B, 2), work, lda, pivots, X, ldb, info);

---

function Math.Matrices.LAPACK.dgetrs_vec

Component	Modelica 3.2.3	Modelica 3.2.2
n	Present
nrhs	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgetrs( "N", n, nrhs, work, lda, pivots, x, ldb, info);	external "FORTRAN 77" dgetrs( "N", size(LU, 1), 1, work, lda, pivots, x, ldb, info);

---

function Math.Matrices.LAPACK.dgetri

Component	Modelica 3.2.3	Modelica 3.2.2
n	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgetri( n, inv, lda, pivots, work, lwork, info);	external "FORTRAN 77" dgetri( size(LU, 1), inv, lda, pivots, work, lwork, info);

---

function Math.Matrices.LAPACK.dgeqpf

Component	Modelica 3.2.3	Modelica 3.2.2
m	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgeqpf( m, ncol, QR, lda, p, tau, work, info);	external "FORTRAN 77" dgeqpf( size(A, 1), ncol, QR, lda, p, tau, work, info);

---

function Math.Matrices.LAPACK.dorgqr

Component	Modelica 3.2.3	Modelica 3.2.2
m	Present
n	Present
k	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dorgqr( m, n, k, Q, lda, tau, work, lwork, info);	external "FORTRAN 77" dorgqr( size(QR, 1), size(QR, 2), size(tau, 1), Q, lda, tau, work, lwork, info);

---

function Math.Matrices.LAPACK.dgesvx

Component	Modelica 3.2.3	Modelica 3.2.2
n	Present
nrhs	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgesvx( "N", transA, n, nrhs, Awork, lda, AF, lda, ipiv, equed, R, C, Bwork, lda, X, lda, rcond, ferr, berr, work, iwork, info);	external "FORTRAN 77" dgesvx( "N", transA, size(A, 1), size(B, 2), Awork, lda, AF, lda, ipiv, equed, R, C, Bwork, lda, X, lda, rcond, ferr, berr, work, iwork, info);

---

function Math.Matrices.LAPACK.dgesdd

Component	Modelica 3.2.3	Modelica 3.2.2
m	Present
n	Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "FORTRAN 77" dgesdd( "A", m, n, Awork, lda, sigma, U, ldu, VT, ldvt, work, lwork, iwork, info);	external "FORTRAN 77" dgesdd( "A", size(A, 1), size(A, 2), Awork, lda, sigma, U, ldu, VT, ldvt, work, lwork, iwork, info);

---

function Math.Matrices.Utilities.toUpperHessenberg

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... if n > 0 then
if n == 1 then H = A; V = {{0.0}}; tau = zeros(0); info = 0; else
(Aout, tau, info) = LAPACK.dgehrd(A, ilo, ihi);
H = zeros(size(H, 1), size(H, 2));	H[1:2, 1:ihi] = Aout[1:2, 1:ihi];
H[1:2, 1:n] = Aout[1:2, 1:n];	H[1:2, ihi + 1:n] = A[1:2, ihi + 1:n];
for i in 3:n loop
H[i, (i - 1):n] = Aout[i, (i - 1):n];	H[i, i - 1:ihi] = Aout[i, i - 1:ihi];
	H[i, ihi + 1:n] = A[i, ihi + 1:n];
end for;
V = zeros(size(V, 1), size(V, 2));	for i in 1:min(n - 2, ihi) loop
for i in ilo:min(n - 2, ihi) loop
V[i + 1, i] = 1.0;
V[(i + 2):n, i] = Aout[(i + 2):n, i];	V[i + 2:n, i] = Aout[i + 2:n, i];
end for; ... end if;
end if;

---

function Math.Random.Utilities.impureRandomInteger

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... r := impureRandom(id=id);
y = min(imax, integer(r*(imax-imin+1))+imin);	y = integer(r*imax) + integer((1-r)*imin);
	y = min(imax, max(imin, y));

---

model Math.FastFourierTransform.Examples.RealFFT1

Component	Modelica 3.2.3	Modelica 3.2.2
y_buf	start=vector([6.5; fill(0, ns - 1)])
		each start=0

---

model Math.FastFourierTransform.Examples.RealFFT2

Component	Modelica 3.2.3	Modelica 3.2.2
FFT_resultFileName	="RealFFT2_resultFFT.mat"	="RealFFT1_resultFFT.mat"
y_buf	start=vector([6.5; fill(0, ns - 1)])
		each start=0

---

function Math.FastFourierTransform.realFFTwriteToFile

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... if success then
print("... FFT result computed at time = " + String(t_computed) + " s stored on file: " + Modelica323.Utilities.Files.fullPathName(fileName));	print("... FFT result computed at time = " + String(t_computed) + " s stored on file: " + fileName);
end if; ...

---

model Utilities.Examples.WriteRealMatrixToFile

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
algorithm
when initial() then ... end when;

---

model Utilities.Examples.ReadRealMatrixFromFile

Component	Modelica 3.2.3	Modelica 3.2.2
dim	=Modelica323.Utilities.Streams.readMatrixSize(file, matrixName)	=Modelica322.Utilities.Streams.readMatrixSize(file1, matrixName)
A	=Modelica323.Utilities.Streams.readRealMatrix(file, matrixName, dim1[1], dim1[2])	=Modelica322.Utilities.Streams.readRealMatrix(file1, matrixName1, dim1[1], dim1[2])

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
... der(x) = -A[1,1]*x;
algorithm
when initial() then ... end when;

---

function Utilities.Files.temporaryFileName

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
external "C" fileName=ModelicaInternal_temporaryFileName();	external "C" fileName=ModelicaInternal_temporaryFileName(0);

---

function Utilities.System.exit

Component	Modelica 3.2.3	Modelica 3.2.2
status		Present

Equations in Modelica 3.2.3	Equations in Modelica 3.2.2
	external "C" exit(status);

---

package Constants

Component	Modelica 3.2.3	Modelica 3.2.2
q	Present

---

Class	Modelica 3.2.3	Modelica 3.2.2
Modelica323.Blocks.Sources.Exponentials	block	model
package Modelica323.UsersGuide.Conventions.Terms	Present
class Modelica323.UsersGuide.Conventions.Icons	Present
class Modelica323.UsersGuide.ReleaseNotes.Version_3_2_3	Present
model Modelica323.Blocks.Examples.SlewRateLimiter	Present
model Modelica323.Blocks.Examples.Rectifier6pulseFFT	Present
model Modelica323.Blocks.Examples.Rectifier12pulseFFT	Present
model Modelica323.Blocks.Examples.TotalHarmonicDistortion	Present
model Modelica323.Blocks.Interfaces.Adaptors.FlowToPotentialAdaptor	Present
model Modelica323.Blocks.Interfaces.Adaptors.PotentialToFlowAdaptor	Present
package Modelica323.Blocks.Interfaces.Adaptors.Functions	Present
connector Modelica323.Blocks.Interfaces.RealVectorOutput	Present
block Modelica323.Blocks.Math.Power	Present
block Modelica323.Blocks.Math.WrapAngle	Present
block Modelica323.Blocks.Math.TotalHarmonicDistortion	Present
block Modelica323.Blocks.Math.RealFFT	Present
block Modelica323.Blocks.Math.Pythagoras	Present
block Modelica323.Blocks.Routing.Multiplex	Present
block Modelica323.Blocks.Routing.DeMultiplex	Present
block Modelica323.Blocks.Tables.CombiTable2Dv	Present
package Modelica323.Blocks.Tables.Internal	Present
type Modelica323.Blocks.Types.TimeEvents	Present
type Modelica323.Blocks.Types.LimiterHomotopy	Present
type Modelica323.Blocks.Types.VariableLimiterHomotopy	Present
block Modelica323.ComplexBlocks.ComplexMath.Bode	Present
block Modelica323.ComplexBlocks.Sources.ComplexRampPhasor	Present
package Modelica323.ComplexBlocks.Routing	Present
model Modelica323.Electrical.Analog.Examples.Utilities.DirectCapacitor	Present
model Modelica323.Electrical.Analog.Examples.Utilities.InverseCapacitor	Present
model Modelica323.Electrical.Analog.Examples.Utilities.SwitchedCapacitor	Present
model Modelica323.Electrical.Analog.Examples.Utilities.Resistor	Present
model Modelica323.Electrical.Analog.Examples.Utilities.DirectInductor	Present
model Modelica323.Electrical.Analog.Examples.Utilities.InverseInductor	Present
model Modelica323.Electrical.Analog.Examples.Utilities.Conductor	Present
model Modelica323.Electrical.Analog.Examples.HeatingPNP_NORGate	Present
model Modelica323.Electrical.Analog.Examples.GenerationOfFMUs	Present
model Modelica323.Electrical.Analog.Examples.ResonanceCircuits	Present
model Modelica323.Electrical.Analog.Examples.InvertingAmp	Present
model Modelica323.Electrical.Analog.Basic.GeneralCurrentToVoltageAdaptor	Present
model Modelica323.Electrical.Analog.Basic.GeneralVoltageToCurrentAdaptor	Present
function Modelica323.Electrical.Analog.Semiconductors.powlin	Present
function Modelica323.Electrical.Analog.Semiconductors.exlin2	Present
model Modelica323.Electrical.Analog.Sensors.MultiSensor	Present
model Modelica323.Electrical.Digital.Interfaces.MemoryBase	Present
model Modelica323.Electrical.Machines.Examples.AsynchronousInductionMachines.AIMC_InverterDrive	Present
model Modelica323.Electrical.Machines.Examples.SynchronousInductionMachines.SMR_DOL	Present
model Modelica323.Electrical.Machines.Examples.SynchronousInductionMachines.SMPM_NoLoad	Present
model Modelica323.Electrical.Machines.Examples.SynchronousInductionMachines.SMEE_DOL	Present
model Modelica323.Electrical.Machines.Examples.DCMachines.DCPM_CurrentControlled	Present
package Modelica323.Electrical.Machines.Examples.ControlledDCDrives	Present
model Modelica323.Electrical.Machines.Sensors.HallSensor	Present
block Modelica323.Electrical.Machines.SpacePhasors.Blocks.LessThreshold	Present
function Modelica323.Electrical.Machines.Thermal.linearTemperatureDependency	Present
model Modelica323.Electrical.Machines.Icons.Machine	Present
model Modelica323.Electrical.Machines.Icons.Drive	Present
class Modelica323.Electrical.MultiPhase.UsersGuide.PhaseOrientation	Present
function Modelica323.Electrical.MultiPhase.Functions.symmetricBackTransformationMatrix	Present
model Modelica323.Electrical.MultiPhase.Sensors.MultiSensor	Present
model Modelica323.Electrical.MultiPhase.Sensors.AronSensor	Present
model Modelica323.Electrical.MultiPhase.Sensors.ReactivePowerSensor	Present
model Modelica323.Electrical.PowerConverters.Examples.DCAC.MultiPhaseTwoLevel.ThreePhaseTwoLevel_PWM	Present
model Modelica323.Electrical.PowerConverters.Examples.DCDC.ExampleTemplates.ChopperStepUp	Present
package Modelica323.Electrical.PowerConverters.Examples.DCDC.ChopperStepUp	Present
package Modelica323.Electrical.PowerConverters.DCAC.Control	Present
model Modelica323.Electrical.PowerConverters.DCDC.ChopperStepUp	Present
package Modelica323.Electrical.PowerConverters.Types	Present
model Modelica323.Electrical.QuasiStationary.SinglePhase.Examples.SeriesBode	Present
model Modelica323.Electrical.QuasiStationary.SinglePhase.Sensors.MultiSensor	Present
model Modelica323.Electrical.QuasiStationary.SinglePhase.Sources.FrequencySweepVoltageSource	Present
model Modelica323.Electrical.QuasiStationary.SinglePhase.Sources.FrequencySweepCurrentSource	Present
model Modelica323.Electrical.QuasiStationary.MultiPhase.Examples.UnsymmetricalLoad	Present
model Modelica323.Electrical.QuasiStationary.MultiPhase.Examples.TestSensors	Present
model Modelica323.Electrical.QuasiStationary.MultiPhase.Basic.MutualInductor	Present
block Modelica323.Electrical.QuasiStationary.MultiPhase.Blocks.FromSymmetricalComponents	Present
model Modelica323.Electrical.QuasiStationary.MultiPhase.Sensors.MultiSensor	Present
model Modelica323.Electrical.QuasiStationary.MultiPhase.Sensors.AronSensor	Present
model Modelica323.Electrical.QuasiStationary.MultiPhase.Sensors.ReactivePowerSensor	Present
model Modelica323.Electrical.QuasiStationary.MultiPhase.Sources.FrequencySweepVoltageSource	Present
model Modelica323.Electrical.QuasiStationary.MultiPhase.Sources.FrequencySweepCurrentSource	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.AIMC_YD	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.AIMC_Transformer	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.AIMC_Inverter	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.AIMC_Conveyor	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.AIMC_Steinmetz	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.AIMC_withLosses	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.AIMC_Initialize	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.SMPM_CurrentSource	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.SMPM_VoltageSource	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.SMPM_Braking	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.SMEE_DOL	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.SMEE_LoadDump	Present
model Modelica323.Magnetic.FundamentalWave.Examples.BasicMachines.SMEE_Rectifier	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMC_Characteristics	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMC_YD	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMC_Transformer	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMC_Conveyor	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMC_withLosses	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMC_Initialize	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMS_Characteristics	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.SynchronousMachines.SMPM_MTPA	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Sensors.RotorDisplacementAngle	Present
model Modelica323.Magnetic.QuasiStatic.FundamentalWave.Utilities.SwitchYD	Present
package Modelica323.Magnetic.QuasiStatic.FluxTubes	Present
model Modelica323.Mechanics.MultiBody.Examples.Loops.PlanarFourbar	Present
model Modelica323.Mechanics.MultiBody.Interfaces.LineForceBase	Present
function Modelica323.Mechanics.MultiBody.Visualizers.Advanced.SurfaceCharacteristics.rectangle	Present
model Modelica323.Mechanics.MultiBody.Visualizers.Rectangle	Present
model Modelica323.Mechanics.Rotational.Examples.EddyCurrentBrake	Present
model Modelica323.Mechanics.Rotational.Examples.OneWayClutch	Present
model Modelica323.Mechanics.Rotational.Examples.OneWayClutchDisengaged	Present
model Modelica323.Mechanics.Rotational.Components.GeneralAngleToTorqueAdaptor	Present
model Modelica323.Mechanics.Rotational.Components.GeneralTorqueToAngleAdaptor	Present
model Modelica323.Mechanics.Rotational.Sources.EddyCurrentTorque	Present
connector Modelica323.Mechanics.Rotational.Interfaces.Flange	Present
model Modelica323.Mechanics.Translational.Examples.Utilities.DirectMass	Present
model Modelica323.Mechanics.Translational.Examples.Utilities.InverseMass	Present
model Modelica323.Mechanics.Translational.Examples.Utilities.SpringDamper	Present
model Modelica323.Mechanics.Translational.Examples.Utilities.Spring	Present
model Modelica323.Mechanics.Translational.Examples.Utilities.SpringDamperNoRelativeStates	Present
model Modelica323.Mechanics.Translational.Examples.EddyCurrentBrake	Present
model Modelica323.Mechanics.Translational.Examples.GenerationOfFMUs	Present
model Modelica323.Mechanics.Translational.Components.GeneralForceToPositionAdaptor	Present
model Modelica323.Mechanics.Translational.Components.GeneralPositionToForceAdaptor	Present
model Modelica323.Mechanics.Translational.Sources.EddyCurrentForce	Present
connector Modelica323.Mechanics.Translational.Interfaces.Flange	Present
package Modelica323.Media.Examples.Utilities	Present
model Modelica323.Thermal.FluidHeatFlow.Examples.WaterPump	Present
model Modelica323.Thermal.FluidHeatFlow.Examples.TestOpenTank	Present
model Modelica323.Thermal.FluidHeatFlow.Examples.TwoTanks	Present
model Modelica323.Thermal.FluidHeatFlow.Examples.TestCylinder	Present
model Modelica323.Thermal.FluidHeatFlow.Components.Pipe	Present
model Modelica323.Thermal.FluidHeatFlow.Components.OpenTank	Present
model Modelica323.Thermal.FluidHeatFlow.Components.Cylinder	Present
model Modelica323.Thermal.FluidHeatFlow.Components.OneWayValve	Present
record Modelica323.Thermal.FluidHeatFlow.Media.Water_10degC	Present
record Modelica323.Thermal.FluidHeatFlow.Media.Water_90degC	Present
record Modelica323.Thermal.FluidHeatFlow.Media.Gylcol20_20degC	Present
record Modelica323.Thermal.FluidHeatFlow.Media.Gylcol50_20degC	Present
record Modelica323.Thermal.FluidHeatFlow.Media.MineralOil	Present
model Modelica323.Thermal.FluidHeatFlow.Interfaces.Partials.SinglePortLeft	Present
model Modelica323.Thermal.FluidHeatFlow.Interfaces.Partials.SinglePortBottom	Present
model Modelica323.Thermal.HeatTransfer.Examples.GenerationOfFMUs	Present
package Modelica323.Thermal.HeatTransfer.Examples.Utilities	Present
model Modelica323.Thermal.HeatTransfer.Components.GeneralHeatFlowToTemperatureAdaptor	Present
model Modelica323.Thermal.HeatTransfer.Components.GeneralTemperatureToHeatFlowAdaptor	Present
function Modelica323.Math.wrapAngle	Present
package Modelica323.Utilities.Internal.PartialModelicaServices.System	Present
package Modelica323.Icons.FunctionsPackage	Present
package Modelica323.Icons.RecordsPackage	Present
type Modelica323.SIunits.LinearTemperatureCoefficientResistance	Present
type Modelica323.SIunits.QuadraticTemperatureCoefficientResistance	Present
operator record Modelica323.SIunits.ComplexPerUnit	Present
class Modelica322.UsersGuide.ModelicaLicense2		Present
class Modelica322.Electrical.MultiPhase.UsersGuide.Concept		Present
model Modelica322.Magnetic.QuasiStatic.FundamentalWave.Examples.BasicMachines.InductionMachines.IMC_Inverter		Present
class Modelica322.Media.UsersGuide.Future		Present