/* autogenerated from "macros/Electrical/OpAmp.sci" */
function OpAmp() {
    OpAmp.prototype.define = function OpAmp() {
        S = [];
        Z = [];
        model = scicos_model();
        model.sim = "OpAmp";
        model.blocktype = "c";
        model.dep_ut = [true,false];
        mo = modelica();
        mo.model = model.sim;
        mo.inputs = [["in_p"],["in_n"]];
        mo.outputs = ["out"];
        mo.parameters = list(S,Z);
        model.equations = mo;
        model.in1 = ones(size(mo.inputs,"*"),1);
        model.out = ones(size(mo.outputs,"*"),1);
        model.rpar = Z;
        exprs = string(Z);
        gr_i = [];
        x = standard_define([3,5],model,exprs,gr_i);
        x.graphics.in_implicit = [["I"],["I"]];
        x.graphics.out_implicit = ["I"];
    }
    OpAmp.prototype.details = function OpAmp() {
    }
    OpAmp.prototype.get = function OpAmp() {
    }
    OpAmp.prototype.set = function OpAmp() {
        x = arg1;
        graphics = arg1.graphics;
        exprs = graphics.exprs;
        model = arg1.model;
        while (false) {
        [ok,OLGain,SatH,SatL,exprs] = scicos_getvalue("Set the Operational Amplifier parameters",[["Open Loop Gain"],["Positive saturation voltage"],["Negative saturation voltage"]],list("vec",1,"vec",1,"vec",1),exprs);
        if (!ok) {
break;
}
        model.equations.parameters[2-1] = list(OLGain,SatH,SatL);
        graphics.exprs = exprs;
        x.graphics = graphics;
        x.model = model;
break;
}
    }
}