public void updateParams(OutComp comp1, OutComp comp2)
{
this.comp1 = comp1;
this.comp2 = comp2;
updateControlComp();
}
public void compsSelected(OutComp comp1, OutComp comp2)
{
if (CompsSelected != null)
{
CompsSelected(this, comp1, comp2);
}
}
public string getText(int timei = -1)
{
List <OutComp> outcomps;
string s = "";
if (timei >= 0)
{
outcomps = timeOutSet[timei].comps;
}
else
{
outcomps = outSet.comps;
}
if (outcomps.Count > 0)
{
OutComp prevComp = null;
float rs = 0;
ControlComp comp0 = new ControlComp(outcomps[0]);
s += "<b>Label\tK\tM\tCon\tPhase\tRet (max)\tRet (avg)\tWidth\tSigma\tHeight\tPurity\tRecovery\tResolution</b>\n";
s += string.Format("<b>\t\t{0}\t{1}\t\t{2}\t{2}\t{2}\t{2}\t{1}\t\t\t</b>\n",
comp0.MassUnits, comp0.ConcentrationUnits, comp0.Units, comp0.Units, comp0.Units);
foreach (OutComp comp in outcomps)
{
s += comp.label + "\t";
s += string.Format("{0}\t", comp.k);
s += string.Format("{0}\t", comp.m);
s += string.Format("{0:0.0#E+0}\t", comp.concentration);
s += string.Format("{0}\t", comp.phase);
s += string.Format("{0:0.0#}\t", comp.retention);
s += string.Format("{0:0.0#}\t", comp.average);
s += string.Format("{0:0.0#}\t", comp.width);
s += string.Format("{0:0.0#}\t", comp.sigma);
s += string.Format("{0:0.0#E+0}\t", comp.height);
s += string.Format("{0:0.0%}\t", comp.purity);
s += string.Format("{0:0.0%}\t", comp.recovery);
if (prevComp != null)
{
rs = Equations.calcRes(prevComp, comp);
if (rs != 0)
{
s += string.Format("{0:0.000#}", rs);
}
else
{
s += "-";
}
}
s += "\n";
prevComp = comp;
}
}
return(s);
}
public void compSelected(OutComp comp)
{
if (CompSelected != null)
{
CompSelected(this, comp);
}
}
public void updateFromOutComp(OutComp outComp)
{
retention = outComp.retention;
sigma = outComp.sigma;
width = outComp.width;
height = outComp.height;
notify();
}
private void chromview_CompsSelected(object sender, OutComp comp1, OutComp comp2)
{
if (comp1 != null && comp2 != null)
{
peaksinfo.updateParams(comp1, comp2);
peaksinfo.Show();
peaksinfo.Activate();
}
else
{
peaksinfo.Hide();
}
}
private void chromview_CompSelected(object sender, OutComp comp)
{
if (comp != null)
{
peakinfo.updateParams(comp);
peakinfo.Show();
peakinfo.Activate();
}
else
{
peakinfo.Hide();
}
}
public static float calcRes(OutComp comp1, OutComp comp2)
{
float rs = 0;
float dt;
if (comp1.outCol && comp2.outCol)
{
if (comp1.phase == comp2.phase)
{
dt = Math.Abs(comp1.retention - comp2.retention);
}
else
{
dt = Math.Abs(comp1.retention) + Math.Abs(comp2.retention);
}
rs = dt / (comp1.width / 2 + comp2.width / 2);
}
return(rs);
}
public OutComp(OutComp comp)
: base(comp)
{
phase = comp.phase;
retention = comp.retention;
average = comp.average;
retention0 = comp.retention0;
retentionTime = comp.retentionTime;
drawPosition = comp.drawPosition;
sigma = comp.sigma;
width = comp.width;
hwidth = comp.hwidth;
swidth = comp.swidth;
height = comp.height;
purity = comp.purity;
recovery = comp.recovery;
totm = comp.totm;
totmup = comp.totmup;
totmlp = comp.totmlp;
willElute = comp.willElute;
eluted = comp.eluted;
outCol = comp.outCol;
intIt = comp.intIt;
intItSet = comp.intItSet;
units = comp.units;
volUnits = comp.volUnits;
timeUnits = comp.timeUnits;
massUnits = comp.massUnits;
filterSigma = comp.filterSigma;
}
public void updateParams(OutComp outComp)
{
DataContext = new ControlComp(outComp);
}
private List <OutComp> storePeaks(List <TransCon> conu0, List <TransCon> conl0, int offsetu0, int offsetl0, bool[] inversePhase, Axes axes, ViewParams viewparams, bool showCol)
{
List <OutComp> outComps = new List <OutComp>();
OutComp outComp;
TransCon compconu;
TransCon compconl;
int ncomps = inParams.comps.Count;
float cu, cl;
float con, maxcon;
float pos, normpos, realpos;
float width, hwidth, swidth;
float sumavg, avg;
float normavg, realavg;
float totm, totmup, totmlp;
bool up;
int nsteps;
int offsetu = 0;
int offsetl = 0;
bool inverseu, inversel;
float contarget, conother, conall;
float purity;
float recovery;
if (inParams.runMode == RunModeType.CoCurrent)
{
inverseu = false;
inversel = false;
offsetu = 0;
offsetl = 0;
}
else
{
inverseu = false;
inversel = true;
}
for (int compi = 0; compi < ncomps; compi++)
{
compconu = conu0[compi];
compconl = conl0[compi];
nsteps = compconu.Count + compconl.Count - inParams.column2;
if (inParams.runMode != RunModeType.CoCurrent)
{
offsetu = compconl.Count - inParams.column2;
offsetl = compconl.Count;
}
pos = 0;
maxcon = 0;
normpos = 0;
up = false;
for (int i = 0; i < nsteps; i++)
{
cu = compconu.getNormCon(i, offsetu, inverseu);
cl = compconl.getNormCon(i, offsetl, inversel);
con = cu + cl;
if (con > maxcon)
{
maxcon = con;
normpos = i;
up = (cu > cl);
}
}
hwidth = calcHeightWidth(compconu, compconl, offsetu, offsetl, inverseu, inversel, nsteps, normpos, maxcon);
swidth = calcSlopeWidth(compconu, compconl, offsetu, offsetl, inverseu, inversel, nsteps, normpos);
width = Equations.calcBestWidth(hwidth, swidth);
// totm + avg
totm = 0;
totmup = 0;
totmlp = 0;
sumavg = 0;
for (int i = 0; i < nsteps; i++)
{
cu = compconu.getNorm(i, offsetu, inverseu);
cl = compconl.getNorm(i, offsetl, inversel);
//if (inParams->runMode == RunMode::Co && i >= inParams->column2) {
// correct cu, cl ?
//}
con = cu + cl;
sumavg += (i * con);
totm += con;
totmup += cu;
totmlp += cl;
}
normavg = sumavg / totm;
// purity
contarget = 0;
conall = 0;
for (int i = 0; i < nsteps; i++)
{
cu = compconu.getNorm(i, offsetu, inverseu);
cl = compconl.getNorm(i, offsetl, inversel);
con = cu + cl;
if (con > mincon)
{
// target component present
contarget += con;
for (int c = 0; c < ncomps; c++)
{
cu = conu0[c].getNorm(i, offsetu, inverseu);
cl = conl0[c].getNorm(i, offsetl, inversel);
con = cu + cl;
conall += con;
}
}
}
purity = contarget / conall;
// recovery
contarget = 0;
for (int i = 0; i < nsteps; i++)
{
conother = 0;
for (int c = 0; c < ncomps; c++)
{
if (c != compi)
{
cu = conu0[c].getNorm(i, offsetu, inverseu);
cl = conl0[c].getNorm(i, offsetl, inversel);
con = cu + cl;
conother += con;
}
}
if (conother < mincon)
{
cu = compconu.getNorm(i, offsetu, inverseu);
cl = compconl.getNorm(i, offsetl, inversel);
con = cu + cl;
contarget += con;
}
}
recovery = contarget;
outComp = new OutComp(inParams.comps[compi]);
outComp.height = maxcon;
outComp.totm = totm;
outComp.totmup = totmup;
outComp.totmlp = totmlp;
outComp.purity = purity;
outComp.recovery = recovery;
if (up)
{
outComp.phase = PhaseType.Upper;
// convert norm back to model
pos = compconu.convNormToModel((int)normpos, offsetu, inverseu);
avg = compconu.convNormToModel((int)normavg, offsetu, inverseu);
// convert normal position back into screen position (using out/draw params):
outComp.drawPosition = compconu.convModelToNorm((int)pos, offsetu0, inversePhase[0]);
// convert position to retention
realpos = compconu.Count - pos;
realavg = compconu.Count - avg;
}
else
{
outComp.phase = PhaseType.Lower;
// convert norm back to model
pos = compconl.convNormToModel((int)normpos, offsetl, inversel);
avg = compconl.convNormToModel((int)normavg, offsetl, inversel);
// convert normal position back into screen position (using out/draw params):
outComp.drawPosition = compconl.convModelToNorm((int)pos, offsetl0, inversePhase[1]);
// convert position to retention
realpos = compconl.Count - pos;
realavg = compconl.Count - avg;
}
outComp.outCol = (pos > inParams.column2);
outComp.eluted = outComp.outCol;
if (!outComp.eluted)
{
// if not eluted; redo position calc depending on point of insertion
outComp.phase = PhaseType.None;
// if (inParams->runMode != RunMode::Lp) {
pos = compconu.convNormToModel((int)normpos, offsetu, inverseu);
avg = compconu.convNormToModel((int)normavg, offsetu, inverseu);
// } else {
// pos = compconl.convNormToModel((int)normpos,offsetl,inversel);
// avg = compconl.convNormToModel((int)normavg,offsetl,inversel);
// }
}
if (outComp.eluted)
{
outComp.retention = inParams.convertUnit(realpos, inParams.natUnits, viewparams.viewUnits, outComp.phase);
outComp.average = inParams.convertUnit(realavg, inParams.natUnits, viewparams.viewUnits, outComp.phase);
outComp.width = inParams.convertUnit(width, inParams.natUnits, viewparams.viewUnits, outComp.phase);
outComp.hwidth = inParams.convertUnit(hwidth, inParams.natUnits, viewparams.viewUnits, outComp.phase);
outComp.swidth = inParams.convertUnit(swidth, inParams.natUnits, viewparams.viewUnits, outComp.phase);
}
else
{
// if not outcol: overwrite with column value
outComp.retention = inParams.convertColUnit(pos, inParams.natUnits, viewparams.viewUnits);
outComp.average = inParams.convertColUnit(avg, inParams.natUnits, viewparams.viewUnits);
outComp.width = inParams.convertColUnit(width, inParams.natUnits, viewparams.viewUnits);
outComp.hwidth = inParams.convertColUnit(hwidth, inParams.natUnits, viewparams.viewUnits);
outComp.swidth = inParams.convertColUnit(swidth, inParams.natUnits, viewparams.viewUnits);
outComp.phase = PhaseType.None;
}
outComp.sigma = outComp.width / 4;
outComps.Add(outComp);
}
return(outComps);
}
public OutComp calcNewPos(Comp comp, float fu, float fl, float vc, float pos0, QuantityType natUnits, bool limit, float maxpos, QuantityType limitUnits)
{
OutComp outcomp = new OutComp();
float flow;
float ret;
float rettime;
float vceff;
PhaseType phase = new PhaseType();
float elutable;
float lf = inParams.lf;
float uf = inParams.uf;
float px = inParams.px;
KdefType kdef = inParams.kDefinition;
float k = comp.k;
// * flow
if (natUnits == QuantityType.Steps)
{
flow = Equations.calcStepFlow(kdef, lf, uf, fu, fl, k);
}
else
{
flow = Equations.calcFlow(kdef, fu, fl, k);
}
if (inParams.runMode != RunModeType.CoCurrent)
{
elutable = Equations.calcElutable(kdef, fu, -fl, k);
}
else
{
elutable = Equations.calcElutable(kdef, fu, fl, k);
}
if (elutable > 0.01)
{
// will elute
// * vceff
if (flow < 0)
{
vceff = pos0;
}
else
{
vceff = vc - pos0;
}
// * ret
// [time]
rettime = Equations.calcPos(kdef, vceff, lf, uf, flow, k);
outcomp.retentionTime = rettime;
if (rettime < 0)
{
phase = PhaseType.Lower;
}
else
{
phase = PhaseType.Upper;
}
if (natUnits == QuantityType.Steps)
{
// [steps]
ret = rettime;
}
else
{
// [volume] or [time]
ret = inParams.convertUnit(rettime, QuantityType.Time, natUnits, phase);
}
outcomp.retention0 = ret;
// * new pos
if (limit && (Math.Abs(rettime) > maxpos && limitUnits == QuantityType.Time || Math.Abs(ret) > maxpos && limitUnits != QuantityType.Time))
{
// [volume] or [steps]
outcomp.retention = pos0 + Equations.calcColPos(kdef, maxpos, lf, uf, flow, k);
outcomp.eluted = false;
}
else
{
outcomp.retention = ret;
outcomp.eluted = true;
}
}
else
{
outcomp.retention = pos0;
if (flow < 0)
{
phase = PhaseType.Lower;
}
else
{
phase = PhaseType.Upper;
}
}
outcomp.phase = phase;
return(outcomp);
}
public OutSet storeOutVar(ViewParams viewParams)
{
// use predictive equations
OutSet outSet = new OutSet(inParams);
OutCell[][] outCells;
Axes axes;
Comp comp;
OutComp outComp;
OutComp outCompt = null;
float pos, pos0, post;
float totposu, totposl;
float timepos;
float maxtime0;
float eepos = 0;
float intAmount = 0;
float sigma, sigma0;
float timesigma = 0;
float con, maxcon;
float amp0;
float div0;
float maxposu = 0;
float maxposl = 0;
float mindrawpos = 0;
float maxdrawpos = 0;
float range;
float stepsize;
int ncomps = inParams.comps.Count;
int nsize = 1000;
float k;
PhaseType phase = new PhaseType();
KdefType kdef = inParams.kDefinition;
RunModeType runMode = inParams.runMode;
QuantityType natUnits = inParams.natUnits;
float injectPos = 0;
float lf = inParams.lf;
float uf = inParams.uf;
float px = inParams.px;
float fu = 0;
float fl = 0;
float fnormu = 0;
float fnorml = 0;
float vc = 0;
float mixspeed = 0;
float efficiency = 0;
bool allincol = true;
bool timeMode = (inParams.viewUnits == QuantityType.Time);
bool eeMode = (inParams.eeMode != EEModeType.None);
bool intMode = (inParams.runMode == RunModeType.Intermittent);
bool intCompMode = (inParams.intMode == IntModeType.Component);
int intit;
bool eluted;
float elutable;
eeDone = false;
if (inParams.model == ModelType.CCD)
{
// [steps]
vc = inParams.column;
injectPos = inParams.getInjectPosNorm();
if (runMode == RunModeType.CoCurrent)
{
injectPos = (inParams.column - 1) - injectPos;
}
fnormu = inParams.fnormu;
fnorml = inParams.fnorml;
// always use normalised flows
fu = fnormu;
fl = fnorml;
mixspeed = 1;
efficiency = Equations.calcEff1(inParams.efficiency);
}
else if (inParams.model == ModelType.Probabilistic)
{
// [volume]
vc = inParams.vc;
injectPos = inParams.getInjectPosNorm();
fu = inParams.fu;
fl = inParams.fl;
// normalise flow
fnormu = inParams.fnormu;
fnorml = inParams.fnorml;
if (fnorml > fnormu)
{
fnormu /= fnorml;
fnorml = 1;
}
else
{
fnorml /= fnormu;
fnormu = 1;
}
mixspeed = inParams.mixSpeed;
efficiency = Equations.calcEff1(inParams.efficiency);
}
else if (inParams.model == ModelType.Transport)
{
// [time]
natUnits = QuantityType.Time;
vc = inParams.vc;
injectPos = inParams.getInjectPosNorm();
fu = inParams.fu;
fl = inParams.fl;
// normalise flow
fnormu = fu / uf;
fnorml = fl / lf;
if (fnorml > fnormu)
{
fnormu /= fnorml;
fnorml = 1;
}
else
{
fnorml /= fnormu;
fnormu = 1;
}
mixspeed = 1;
efficiency = (float)Math.Sqrt(inParams.ka * 10); // **** make correct for f? dx? dt?
}
if (runMode != RunModeType.CoCurrent)
{
fl = -fl;
fnorml = -fnorml;
}
// Set maxpos
for (int compi = 0; compi < ncomps; compi++)
{
comp = inParams.comps[compi];
outComp = outSet.comps[compi];
elutable = Equations.calcElutable(kdef, fu, fl, outComp.k);
outComp.willElute = (elutable > 0.01);
if (outComp.willElute)
{
outCompt = calcNewPos(comp, fu, fl, vc, injectPos, natUnits); // outcomp is reassigned
outComp = outSet.comps[compi]; // overwrite comp
outComp.willElute = true; // restore willElute
if (comp.elute)
{
if (outCompt.retention < 0)
{
phase = PhaseType.Lower;
if (Math.Abs(outCompt.retention) > maxposl)
{
maxposl = Math.Abs(outCompt.retention);
}
}
else
{
phase = PhaseType.Upper;
if (Math.Abs(outCompt.retention) > maxposu)
{
maxposu = Math.Abs(outCompt.retention);
}
}
sigma = Equations.calcSigma(kdef, fnormu, fnorml, comp.k * px, outCompt.retentionTime, mixspeed, efficiency);
if (runMode == RunModeType.DualMode && inParams.model != ModelType.Transport)
{
sigma *= 2;
}
sigma = inParams.convertUnit(sigma, QuantityType.Time, natUnits, phase);
}
}
else
{
if (intMode && inParams.intFinalElute)
{
outComp.willElute = true;
}
}
}
if (intMode && !intCompMode)
{
intamountu = inParams.convertUnit(inParams.intUpSwitch, (QuantityType)inParams.intMode, natUnits, PhaseType.Upper);
intamountl = inParams.convertUnit(inParams.intLpSwitch, (QuantityType)inParams.intMode, natUnits, PhaseType.Lower);
if (inParams.model == ModelType.CCD)
{
intamountut = intamountu;
}
else
{
intamountut = inParams.convertUnit(inParams.intUpSwitch, (QuantityType)inParams.intMode, QuantityType.Time, PhaseType.Upper);
}
if (inParams.model == ModelType.CCD)
{
intamountlt = intamountl;
}
else
{
intamountlt = inParams.convertUnit(inParams.intLpSwitch, (QuantityType)inParams.intMode, QuantityType.Time, PhaseType.Lower);
}
}
if (inParams.model == ModelType.CCD)
{
pos0 = vc / inParams.uf * inParams.maxIt; // in reality [steps]
}
else
{
pos0 = vc * inParams.maxIt;
}
if (inParams.doMaxIt && maxposu > pos0)
{
maxposu = pos0;
}
if (inParams.model == ModelType.CCD)
{
pos0 = vc / inParams.lf * inParams.maxIt; // in reality [steps]
}
else
{
pos0 = vc * inParams.maxIt;
}
if (inParams.doMaxIt && maxposl > pos0)
{
maxposl = pos0;
}
// init estmax [time/steps]
previewParams.estmaxtime = 0;
previewParams.estmaxstep = 0;
// Set peaks
// *** improve int mode: loop for [intit] with inner loop for [comps]: enable compmode and time scale correction
for (int i = 0; i < ncomps; i++)
{
comp = inParams.comps[i];
outComp = outSet.comps[i];
k = comp.k;
post = 0;
// Calculate pos
if (intMode)
{
// Int mode
intit = 0;
eluted = false;
totposu = 0;
totposl = 0;
timepos = 0;
pos = injectPos;
phase = inParams.intStartPhase;
while (intit / 2 < inParams.intMaxIt && !eluted)
{
if (phase == PhaseType.Upper)
{
if (!intCompMode)
{
if (natUnits == QuantityType.Steps)
{
intAmount = intamountu;
}
else
{
intAmount = intamountut;
}
}
outCompt = calcNewPos(comp, fu, 0, vc, pos, natUnits, !intCompMode, intAmount, QuantityType.Time);
}
else
{
if (!intCompMode)
{
if (natUnits == QuantityType.Steps)
{
intAmount = intamountl;
}
else
{
intAmount = intamountlt;
}
}
outCompt = calcNewPos(comp, 0, fl, vc, pos, natUnits, !intCompMode, intAmount, QuantityType.Time);
}
eluted = outCompt.eluted;
if (!eluted)
{
post += Math.Abs(outCompt.retention - pos);
pos = outCompt.retention;
if (phase == PhaseType.Upper)
{
totposu += intamountu;
timepos += intamountut;
}
else
{
totposl += intamountl;
timepos += intamountlt;
}
// prepare for next iteration/phase
if (phase == PhaseType.Upper)
{
phase = PhaseType.Lower;
}
else
{
phase = PhaseType.Upper;
}
intit++;
}
}
if (inParams.intFinalElute && !eluted)
{
// elute
if (phase == PhaseType.Upper)
{
outCompt = calcNewPos(comp, fu, 0, vc, pos, natUnits);
}
else
{
outCompt = calcNewPos(comp, fl, 0, vc, pos, natUnits);
}
eluted = outCompt.eluted;
}
if (eluted)
{
// timepos is always positive
//timepos+= inparams.convertUnit(Math::Abs(outCompt.ret),natUnits,UnitsType.Time,phase);
timepos += Math.Abs(outCompt.retentionTime);
if (timeMode)
{
// use timepos to calc pos
if (inParams.model == ModelType.CCD)
{
pos = timepos;
}
else
{
pos = inParams.convertUnit(timepos, QuantityType.Time, natUnits, phase);
}
// correct negative pos
if (phase == PhaseType.Lower)
{
pos = -Math.Abs(pos);
}
}
else if (phase == PhaseType.Upper)
{
pos = totposu + outCompt.retention0;
}
else
{
pos = -totposl + outCompt.retention0;
}
}
outComp.intIt = (float)intit / 2;
outComp.intItSet = true;
}
else
{
// Normal (not Int) mode
outCompt = calcNewPos(comp, fu, fl, vc, injectPos, natUnits, true, Math.Max(maxposu, maxposl), QuantityType.Volume);
pos = outCompt.retention;
post += Math.Abs(pos - injectPos);
timepos = Math.Abs(outCompt.retentionTime);
eluted = outCompt.eluted;
}
outComp.eluted = eluted;
outComp.outCol = eluted;
pos0 = pos;
if (!eluted && eeMode)
{
// EE mode
eeDone = true;
if (inParams.isPosEEdir())
{
eepos = inParams.convertUnit(maxposu, natUnits, inParams.viewUnits, phase);
if (!timeMode)
{
eepos += (vc - pos0);
}
else
{
eepos = 0;
}
pos = maxposu + (vc - pos0);
outCompt.phase = PhaseType.Upper;
}
else
{
eepos = inParams.convertUnit(maxposl, natUnits, inParams.viewUnits, phase);
if (!timeMode)
{
eepos += pos0;
}
else
{
eepos = 0;
}
pos = -maxposl - pos0;
outCompt.phase = PhaseType.Lower;
}
outComp.outCol = true;
}
phase = outCompt.phase;
// Calculate sigma
if (outComp.outCol || outComp.willElute)
{
// include ee outcol
timesigma = Equations.calcSigma(kdef, fnormu, fnorml, k * px, Math.Abs(timepos), mixspeed, efficiency);
if (runMode == RunModeType.DualMode)
{
timesigma *= 2;
}
if (natUnits == QuantityType.Steps)
{
// [steps]
sigma = timesigma;
}
else
{
// [volume]
if (!outComp.eluted)
{
sigma = inParams.convertColUnit(timesigma, QuantityType.Time, natUnits);
}
else
{
sigma = inParams.convertUnit(timesigma, QuantityType.Time, natUnits, phase);
}
}
if (!outComp.eluted)
{
// calc col sigma also for EE outcol
// [volume] or [steps]
sigma0 = sigma;
sigma = Equations.calcColSigma(sigma0, outCompt.retention0, post, vc);
}
if (outComp.eluted)
{
if (phase == PhaseType.Lower)
{
pos0 = pos - 3 * sigma;
if (pos0 < mindrawpos)
{
mindrawpos = pos0;
}
}
else
{
pos0 = pos + 3 * sigma;
if (pos0 > maxdrawpos)
{
maxdrawpos = pos0;
}
}
}
}
else
{
sigma = 1;
phase = PhaseType.None;
}
outComp.sigma = sigma;
outComp.phase = phase;
// set estmax [time]
if (outComp.outCol)
{
maxtime0 = Math.Abs(timepos) + 3 * timesigma;
if (maxtime0 > previewParams.estmaxtime)
{
previewParams.estmaxtime = maxtime0;
}
}
if (outComp.outCol)
{
if (outComp.eluted)
{
outComp.retention = inParams.convertUnit(Math.Abs(pos), natUnits, viewParams.viewUnits, phase);
outComp.width = inParams.convertUnit(4 * sigma, natUnits, viewParams.viewUnits, phase);
}
else
{
// not eluted but outcol (by EE)
outComp.retention = eepos;
outComp.width = 4 * sigma;
}
}
else
{
outComp.retention = inParams.convertColUnit(Math.Abs(pos), natUnits, viewParams.viewUnits);
outComp.width = inParams.convertColUnit(4 * sigma, natUnits, viewParams.viewUnits);
}
outComp.drawPosition = pos; // convert to real value later
// Calculate height
if (float.IsInfinity(k) || sigma == 0)
{
outComp.height = 1;
}
else
{
outComp.height = Equations.calcHeight(sigma); // [volume]
}
outComp.height *= comp.m;
}
// set estmax [steps]
if (inParams.doMaxIt)
{
// overwrite if maxit is set
pos0 = 0;
if (fu != 0)
{
pos0 = inParams.convertUnit(inParams.maxIt * vc, QuantityType.Volume, QuantityType.Time, PhaseType.Upper);
}
if (fl != 0)
{
pos0 = Math.Max(pos0, inParams.convertUnit(inParams.maxIt * vc, QuantityType.Volume, QuantityType.Time, PhaseType.Lower));
}
if (previewParams.estmaxtime > pos0)
{
previewParams.estmaxtime = pos0;
}
}
if (previewParams.estmaxtime == 0)
{
previewParams.estmaxtime = inParams.Tmnorm;
previewParams.estmaxstep = inParams.column;
}
else
{
if (natUnits == QuantityType.Steps)
{
// CCD mode: time units are actually step units
previewParams.estmaxstep = previewParams.estmaxtime;
}
else
{
previewParams.estmaxstep = inParams.convertUnit(previewParams.estmaxtime, QuantityType.Time, QuantityType.Steps, phase);
}
}
if (maxdrawpos == 0 && mindrawpos == 0)
{
if (inParams.doMaxIt)
{
maxdrawpos = maxposu;
mindrawpos = -maxposl;
}
}
if (eeMode)
{
if (inParams.isPosEEdir())
{
maxdrawpos += vc;
}
else
{
mindrawpos -= vc;
}
}
range = maxdrawpos - mindrawpos + vc;
// Correct drawpos
for (int i = 0; i < ncomps; i++)
{
outComp = outSet.comps[i];
pos0 = outComp.drawPosition;
if (outComp.outCol)
{
if (outComp.phase == PhaseType.Upper)
{
pos0 = maxdrawpos - pos0 + vc;
}
else
{
pos0 = mindrawpos - pos0;
}
allincol = false;
}
outComp.drawPosition = convModelToReal(pos0, mindrawpos);
}
// Set Axes
axes = outSet.axes;
axes.rangex = range; //inparams->convertUnit(drawrange,UnitsType::Time,viewparams->viewUnits,PhaseType::Up);
axes.showCol = true;
axes.colstart = convModelToReal(0, mindrawpos);
axes.colend = convModelToReal(vc, mindrawpos);
axes.scaleminulabel = 0;
axes.scalemaxulabel = inParams.convertUnit(maxdrawpos, natUnits, inParams.natUnits, PhaseType.Upper);
axes.scaleminllabel = 0;
axes.scalemaxllabel = inParams.convertUnit(-mindrawpos, natUnits, inParams.natUnits, PhaseType.Lower);
axes.scaleminu = convModelToReal(maxdrawpos + vc, mindrawpos);
axes.scalemaxu = convModelToReal(vc, mindrawpos);
axes.scaleminl = convModelToReal(mindrawpos, mindrawpos);
axes.scalemaxl = convModelToReal(0, mindrawpos);
axes.logScale = (viewParams.yScale == YScaleType.Logarithmic);
axes.update();
// init outcells
outCells = new OutCell[ncomps][];
for (int compi = 0; compi < ncomps; compi++)
{
outCells[compi] = new OutCell[nsize];
}
axes.maxcon = new List <float>(ncomps);
// Store outcells
for (int compi = 0; compi < ncomps; compi++)
{
comp = inParams.comps[compi];
outComp = outSet.comps[compi];
// Pre-calcs to improve performance
pos0 = outComp.drawPosition;
sigma = outComp.sigma;
if (sigma == 0)
{
sigma = 1;
}
amp0 = comp.m * Equations.calcHeight(sigma);
div0 = 2 * (float)Math.Pow(sigma, 2);
stepsize = range / nsize;
maxcon = 0;
for (int i = 0; i < nsize; i++)
{
pos = i * stepsize; // Real position
// make sure peak top gets drawn:
if (Math.Abs(pos - pos0) <= stepsize)
{
con = amp0;
}
else
{
con = amp0 * (float)Math.Exp(-Math.Pow(pos - pos0, 2) / div0);
}
if (con > maxcon && (outComp.outCol || allincol))
{
maxcon = con;
}
outCells[compi][i] = new OutCell(pos, con);
}
axes.maxcon.Add(maxcon);
// Correct sigma:
outComp.sigma = outComp.width / 4;
}
outSet.outCells = outCells;
return(outSet);
}
public ControlComp(OutComp outComp)
: base(outComp)
{
updateFromOutComp(outComp);
init();
}
