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/* autogenerated from "macros/Electrical/Diode.sci" */
function Diode() {
Diode.prototype.define = function Diode() {
Ids=1.e-6;
Vt=0.04;
Maxexp=15;
R=1.e8;
model=scicos_model();
model.rpar=[[Ids],[Vt],[Maxexp],[R]];
model.in1=1;
model.out=1;
model.sim="Diode";
model.blocktype="c";
model.dep_ut=[true,false];
mo=modelica();
mo.model="Diode";
mo.inputs="p";
mo.outputs="n";
mo.parameters=list(["Ids","Vt","Maxexp","R"],list(Ids,Vt,Maxexp,R));
model.equations=mo;
exprs=string([[Ids],[Vt],[Maxexp],[R]]);
gr_i=[];
x=standard_define([2,1],model,exprs,list(gr_i,0));
x.graphics.in_implicit=["I"];
x.graphics.out_implicit=["I"];
}
Diode.prototype.details = function Diode() {
}
Diode.prototype.get = function Diode() {
}
Diode.prototype.set = function Diode() {
x=arg1;
graphics=arg1.graphics;
exprs=graphics.exprs;
model=arg1.model;
while (true) {
[ok,Ids,Vt,Maxexp,R,exprs]=scicos_getvalue("Set Diode block parameter",[["Saturation cuurent (A)"],["Voltage equivalent to temperature (Volt)"],["Max exponent for linear continuation"],["R (ohm)"]],list("vec",1,"vec",1,"vec",1,"vec",1),exprs);
if (!ok) {
break;
}
model.rpar=[[Ids],[Vt],[Maxexp],[R]];
model.equations.parameters=list(["Ids","Vt","Maxexp","R"],list(Ids,Vt,Maxexp,R));
graphics.exprs=exprs;
x.graphics=graphics;
x.model=model;
break;
}
}
}
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