public Dictionary <string, double> BeginTest(DUT dut, Dictionary <string, IEquipment> equipments, Dictionary <string, string> inPara)
{
//get the current test channel
int channel = ConditionParaByTestPlan.Channel;
try
{
//get equipment object
Attennuator attennuator = (Attennuator)equipments["ATTENNUATOR"];
ErrorDetector ed = (ErrorDetector)equipments["ERRORDETECTOR"];
//change to Rx path, if have this equipment, it can not run parallel test, just to do one by one.
//due to it is the common equipment between Tx and Rx.
if (equipments.Keys.Contains("NA_OPTICALSWITCH"))
{
Log.SaveLogToTxt("It can not parallel initial, due to Tx/Rx have common equipment NA_OPTICALSWITCH.");
Log.SaveLogToTxt("have to test one by one.");
OpticalSwitch opticalSwitch = (OpticalSwitch)equipments["NA_OPTICALSWITCH"];
opticalSwitch.CheckEquipmentRole(2, (byte)channel);
}
lock (attennuator)
{
Log.SaveLogToTxt("Start to do sensitivity test");
//get input parameters
ArrayList erList = Algorithm.StringtoArraylistDeletePunctuations(GlobalParaByPN.OpticalSourceERArray, new char[] { ',' });
double senAlignRxPwr = Convert.ToDouble(inPara["CSENALIGNRXPWR(DBM)"]); //自动对齐时的入射光: -7
double senStartingRxPwr = Convert.ToDouble(inPara["CSENSTARTINGRXPWR(DBM)"]); //目标点搜索起始点,开始灵敏度测试时设定接收端光功率: -13
double searchTargetBerUL = Convert.ToDouble(inPara["SEARCHTARGETBERUL"]); //第一点误码率的上限: 0.00001
double searchTargetBerLL = Convert.ToDouble(inPara["SEARCHTARGETBERLL"]); //第一点误码率的下限: 0.00000001
double searchTargetBerRxpowerUL = Convert.ToDouble(inPara["SEARCHTARGETRXPOWERUL"]); //寻找误码率点的光功率下限: -15
double searchTargetBerRxpowerLL = Convert.ToDouble(inPara["SEARCHTARGETRXPOWERLL"]); //寻找误码率点的光功率上限: -10
double coefCsenSubStep = Convert.ToDouble(inPara["COEFCSENSUBSTEP(DBM)"]); //推算灵敏度找误码点时减小光功率的步长: 0.3
double coefCsenAddStep = Convert.ToDouble(inPara["COEFCSENADDSTEP(DBM)"]); //推算灵敏度找误码点时增大光功率的步长: 0.5
bool isBerQuickTest = inPara["ISBERQUICKTEST"].Trim().ToUpper() == "FALSE" ? false : true; //快速测试还是具体值?
bool isOpticalSourceUnitOMA = inPara["ISOPTICALSOURCEUNITOMA"].Trim().ToUpper() == "FALSE" ? false : true; //光源是否是OMA输入: false
double searchTargetBerStep = Convert.ToDouble(inPara["SEARCHTARGETSTEP"]); //搜寻目标值步长: 0.5
byte searchTargetBerMethod = Convert.ToByte(inPara["SEARCHTARGETBERMETHOD"]); //搜寻第一点的方法0=二分法,1=Step: 0
double ber_ERP = Convert.ToDouble(inPara["BER_ERP"]); //目标误码率: 1E-12
//change unit from OMA to dBm
if (isOpticalSourceUnitOMA)
{
senAlignRxPwr = Algorithm.CalculateFromOMAtoDBM(senAlignRxPwr, Convert.ToDouble(erList[channel - 1]));
senStartingRxPwr = Algorithm.CalculateFromOMAtoDBM(senStartingRxPwr, Convert.ToDouble(erList[channel - 1]));
searchTargetBerRxpowerUL = Algorithm.CalculateFromOMAtoDBM(searchTargetBerRxpowerUL, Convert.ToDouble(erList[channel - 1]));
searchTargetBerRxpowerLL = Algorithm.CalculateFromOMAtoDBM(searchTargetBerRxpowerLL, Convert.ToDouble(erList[channel - 1]));
}
// open apc
Log.SaveLogToTxt("Close apc for module.");
dut.CloseAndOpenAPC(Convert.ToByte(DUT.APCMODE.IBAISandIMODON));
//auto align
Log.SaveLogToTxt("Set atten value.");
attennuator.AttnValue(senAlignRxPwr.ToString());
Log.SaveLogToTxt("Auto alaign...");
if (!ed.AutoAlign(true))
{
Log.SaveLogToTxt("Auto align failed");
return(null);
}
Log.SaveLogToTxt("Auto align successfully");
//search the points to calulate sensitivity
double sensitivity = Algorithm.MyNaN;
double currentBer;
if (isBerQuickTest == true)
{
//QuickTest(attennuator, ed);
//quickly search, direct to test sensitivity, not to search points
attennuator.AttnValue(senStartingRxPwr.ToString());
currentBer = ed.RapidErrorRate();
Log.SaveLogToTxt("SetAtten=" + senStartingRxPwr.ToString());
Log.SaveLogToTxt("QUICBER=" + currentBer.ToString());
if (currentBer >= 1)
{
sensitivity = 1;
return(null);
}
if (currentBer <= ber_ERP)
{
sensitivity = senStartingRxPwr;
}
else
{
sensitivity = currentBer;
Log.SaveLogToTxt("AttPoint=" + senStartingRxPwr.ToString() + ber_ERP.ToString());
}
//calculate the OMA sensitivity
double sensitivity_OMA = Algorithm.CalculateOMA(sensitivity, Convert.ToDouble(erList[channel - 1]));
//save testdata
Dictionary <string, double> dictionary = new Dictionary <string, double>();
dictionary.Add("Sensitivity", sensitivity);
dictionary.Add("Sensitivity_OMA", sensitivity_OMA);
dictionary.Add("Result", 1);
return(dictionary);
}
//detailed search points
ArrayList serchAttPoints = new ArrayList();
ArrayList serchRxDmiPoints = new ArrayList();
ArrayList serchBerPoints = new ArrayList();
byte count = 0;
double currentInputPower = senStartingRxPwr;
//first: search the first point
double firstPoint = 0;
switch (searchTargetBerMethod)
{
case 1:
//attPoint = StepSearchTargetPoint(csenStartingRxPwr, searchTargetBerRxpowerLL, searchTargetBerRxpowerUL, testBerStruct.SearchTargetBerLL, testBerStruct.SearchTargetBerUL, tempAtten, tempED, out serchAttPoints, out serchRxDmidPoints, out serchBerPoints);
//search the first point by step
while (currentInputPower <= searchTargetBerRxpowerUL && currentInputPower >= searchTargetBerRxpowerLL && count <= 20)
{
attennuator.AttnValue(currentInputPower.ToString());
double rxDmiPower = dut.ReadDmiRxP(channel);
currentBer = ed.RapidErrorRate();
serchAttPoints.Add(senStartingRxPwr);
serchRxDmiPoints.Add(rxDmiPower);
serchBerPoints.Add(currentBer);
if (currentBer < searchTargetBerLL) // 误码太小->光太大->减小光
{
currentInputPower -= searchTargetBerStep;
count++;
}
else if (currentBer > searchTargetBerUL) // 误码太大->光太小->加大入射光
{
currentInputPower += searchTargetBerStep;
count++;
}
else
{
firstPoint = currentInputPower;
break;
}
}
break;
default:
//attPoint = binarySearchTargetPoint(testBerStruct.CsenStartingRxPwr, testBerStruct.SearchTargetBerRxpowerLL, testBerStruct.SearchTargetBerRxpowerUL, testBerStruct.SearchTargetBerLL, testBerStruct.SearchTargetBerUL, tempAtten, tempED, out serchAttPoints, out serchRxDmidPoints, out serchBerPoints);
//search the first point by binary search
double low = searchTargetBerRxpowerLL;
double high = searchTargetBerRxpowerUL;
attennuator.AttnValue(((high + low) / 2).ToString(), 1);
currentBer = ed.RapidErrorRate();
while (low <= high && count <= 20)
{
if (Math.Abs(low - high) < 0.2)
{
break;
}
double mid = (high + low) / 2;
attennuator.AttnValue(mid.ToString(), 1);
double rxDmiPower = dut.ReadDmiRxP(channel);
currentBer = ed.RapidErrorRate();
serchAttPoints.Add(mid);
serchRxDmiPoints.Add(rxDmiPower);
serchBerPoints.Add(currentBer);
if (currentBer < searchTargetBerLL)
{
high = mid;
count++;
}
else if (currentBer > searchTargetBerUL)
{
low = mid;
count++;
}
else
{
firstPoint = mid;
break;
}
}
break;
}//completed to search the first point
//second: search other points
//define BER of the final point
double terminativeBer = 0;
if (ber_ERP < searchTargetBerLL)
{
if (ber_ERP > 1E-12)//如果是大于E-12 ,并且比第一点的下限要小 ,那么就以目标值为下限
{
terminativeBer = ber_ERP;
}
else////如果是小于E-12 ,并且比第一点的下限要小 ,那么就以-为11下限
{
terminativeBer = 1E-11;
}
// terminativeBer = targetBer * 100;
}
else if (ber_ERP > searchTargetBerUL)
{
// terminativeBer = targetBer * 1E-1;
terminativeBer = ber_ERP;
}
attennuator.AttnValue(firstPoint.ToString(), 0);
Thread.Sleep(1500);
double point = firstPoint;
int i = 0;
bool done = false;
ArrayList points = new ArrayList();
ArrayList ber = new ArrayList();
do
{
attennuator.AttnValue(point.ToString(), 0);
Thread.Sleep(1000);
double rxDmiPower = dut.ReadDmiRxP(channel);
currentBer = ed.RapidErrorRate();
Log.SaveLogToTxt("RxInputPower=" + point);
Log.SaveLogToTxt("RxDmiPower=" + rxDmiPower.ToString("f2"));
Log.SaveLogToTxt("CurrentBer=" + currentBer.ToString());
if (ber_ERP < searchTargetBerLL)
{
done = currentBer > terminativeBer;
}
else if (ber_ERP > searchTargetBerUL)
{
done = currentBer < terminativeBer;
}
if (done == true && currentBer != 0)
{
points.Add(point);
ber.Add(currentBer);
}
if (currentBer > ber_ERP)
{
point += coefCsenAddStep;
}
else
{
point -= coefCsenSubStep;
}
i++;
} while (i < 8 && done);//completed to search points
//calculate the sensitivity
byte minCount = (byte)Math.Min(points.Count, ber.Count);
double[] pointsArray = new double[minCount];
double[] berArray = new double[minCount];
for (int j = 0; j < minCount; j++)
{
pointsArray[j] = double.Parse(points[j].ToString());
berArray[j] = double.Parse(ber[j].ToString());
Log.SaveLogToTxt("attPoints[ " + j + "] " + points[j].ToString() + " " + "berPoints[ " + j + "] " + ber[j].ToString());
}
double slope, intercept;
Algorithm.LinearRegression(Algorithm.Getlog10(Algorithm.GetNegative(Algorithm.Getlog10(berArray))), pointsArray, out slope, out intercept);
sensitivity = slope + (intercept * Math.Log10(Math.Log10(ber_ERP) * (-1)));
if (double.IsNaN(sensitivity) || double.IsInfinity(sensitivity))
{
sensitivity = Algorithm.MyNaN;
}
sensitivity = Math.Round(sensitivity, 2);
Log.SaveLogToTxt("sensitivity = " + sensitivity.ToString());
//calculate the OMA sensitivity
double sensOMA = Algorithm.CalculateOMA(sensitivity, Convert.ToDouble(erList[channel - 1]));
Log.SaveLogToTxt("OMA sensitivity = " + sensOMA.ToString("f2"));
Log.SaveLogToTxt("End sensitivity test for channel " + channel + "\r\n");
//save testdata
Dictionary <string, double> dic = new Dictionary <string, double>();
dic.Add("Sensitivity", sensitivity);
dic.Add("Sensitivity_OMA", sensOMA);
dic.Add("Result", 1);
return(dic);
}
}
catch
{
Log.SaveLogToTxt("Failed sensitivity test for channel " + channel + "\r\n");
return(null);
}
}
public Dictionary <string, double> BeginTest(DUT dut, Dictionary <string, IEquipment> equipments, Dictionary <string, string> inPara)
{
//get the current test channel
int channel = ConditionParaByTestPlan.Channel;
try
{
//get equipment object
Attennuator attennuator = (Attennuator)equipments["ATTENNUATOR"];
//change to Rx path, if have this equipment, it can not run parallel test, just to do one by one.
//due to it is the common equipment between Tx and Rx.
if (equipments.Keys.Contains("NA_OPTICALSWITCH"))
{
Log.SaveLogToTxt("It can not parallel initial, due to Tx/Rx have common equipment NA_OPTICALSWITCH.");
Log.SaveLogToTxt("have to test one by one.");
OpticalSwitch opticalSwitch = (OpticalSwitch)equipments["NA_OPTICALSWITCH"];
opticalSwitch.CheckEquipmentRole(2, (byte)channel);
}
lock (attennuator)
{
Log.SaveLogToTxt("Start to do RxLos test");
//get input parameters
double step = Convert.ToDouble(inPara["LOSADTUNESTEP"]); //调整步长: 0.3
bool isDetailedTest = Convert.ToBoolean(inPara["ISLOSDETAIL"]); //是否测具体值?: true
// open apc
Log.SaveLogToTxt("Close apc for module.");
dut.CloseAndOpenAPC(Convert.ToByte(DUT.APCMODE.IBAISandIMODON));
//get spec
double LosDMax = -14, LosAMin = -30;
double startAttValue = -6;
attennuator.AttnValue(startAttValue.ToString());
dut.ChkRxLos(channel);//清理Luanch
//test losA
double losA = 0, losD = 0;
bool isLosA = false, isLosD = true;
int i = 0;
if (isDetailedTest)
{
//detailed test
startAttValue = LosDMax;
int count = Convert.ToInt16((LosDMax + 1 - LosAMin) / step);
do
{
attennuator.AttnValue(startAttValue.ToString());
isLosA = dut.ChkRxLos(channel);
Thread.Sleep(100);
isLosA = dut.ChkRxLos(channel);
if (isLosA == false)
{
startAttValue -= step;
i++;
}
losA = startAttValue;
} while (isLosA == false && startAttValue >= LosAMin && i < count);
}
else
{
//quickly test
startAttValue = LosAMin;
attennuator.AttnValue(startAttValue.ToString(), 1);
Thread.Sleep(300);
isLosA = dut.ChkRxLos(channel);
losA = startAttValue;
}
if (isLosA == false)
{
Log.SaveLogToTxt("failed to assert los");
}
else
{
Log.SaveLogToTxt("successful to assert los");
}
Log.SaveLogToTxt("LosA = " + losA);
//test losD
if (isDetailedTest)
{
//detailed test
startAttValue = losA;
i = 0;
do
{
attennuator.AttnValue(startAttValue.ToString());
isLosD = dut.ChkRxLos(channel);
Thread.Sleep(100);
isLosD = dut.ChkRxLos(channel);
if (isLosD == true)
{
startAttValue += step;
i++;
}
losD = startAttValue;
} while (isLosD == true && startAttValue <= LosDMax && i < 30);
}
else
{
//quickly test
startAttValue = LosDMax;
attennuator.AttnValue(startAttValue.ToString(), 1);
Thread.Sleep(50);
isLosD = dut.ChkRxLos(channel);
losD = startAttValue;
}
if (isLosD == true)
{
Log.SaveLogToTxt("failed to deassert los");
}
else
{
Log.SaveLogToTxt("successful to deassert los");
}
//calculate losH
double losH = losD - losA;
Log.SaveLogToTxt("LosA = " + losA);
Log.SaveLogToTxt("LosD = " + losD);
Log.SaveLogToTxt("LosH = " + losH.ToString("f3"));
Log.SaveLogToTxt("End rxlos test for channel " + channel + "\r\n");
//get erList
ArrayList erList = Algorithm.StringtoArraylistDeletePunctuations(GlobalParaByPN.OpticalSourceERArray, new char[] { ',' });
double losA_OMA = Algorithm.CalculateOMA(losA, Convert.ToDouble(erList[channel - 1]));
double losD_OMA = Algorithm.CalculateOMA(losD, Convert.ToDouble(erList[channel - 1]));
//save testdata
Dictionary <string, double> dictionary = new Dictionary <string, double>();
dictionary.Add("LosA", losA);
dictionary.Add("LosD", losD);
dictionary.Add("LosH", losH);
dictionary.Add("LosA_OMA", losA);
dictionary.Add("LosD_OMA", losD);
dictionary.Add("Result", 1);
return(dictionary);
}
}
catch
{
Log.SaveLogToTxt("Failed rxlos test for channel " + channel + "\r\n");
return(null);
}
}
public Dictionary <string, double> BeginTest(DUT dut, Dictionary <string, IEquipment> equipments, Dictionary <string, string> inPara)
{
//get the current test channel
int channel = ConditionParaByTestPlan.Channel;
try
{
//get equipment object
Attennuator attennuator = (Attennuator)equipments["ATTENNUATOR"];
//change to Rx path, if have this equipment, it can not run parallel test, just to do one by one.
//due to it is the common equipment between Tx and Rx.
if (equipments.Keys.Contains("NA_OPTICALSWITCH"))
{
Log.SaveLogToTxt("It can not parallel initial, due to Tx/Rx have common equipment NA_OPTICALSWITCH.");
Log.SaveLogToTxt("have to test one by one.");
OpticalSwitch opticalSwitch = (OpticalSwitch)equipments["NA_OPTICALSWITCH"];
opticalSwitch.CheckEquipmentRole(2, (byte)channel);
}
lock (attennuator)
{
Log.SaveLogToTxt("Start to do RxPowerDmi test for channel " + channel);
//get input para
ArrayList rxInputPower = Algorithm.StringtoArraylistDeletePunctuations(inPara["RXPOWERARRLIST(DBM)"], new char[] { ',' });
if (rxInputPower == null)
{
return(null);
}
//set different point to get rxPowerDmi
attennuator.AttnValue(rxInputPower[0].ToString(), 1);
Thread.Sleep(3000);
double[] rxPowerDmiArray = new double[rxInputPower.Count];
double[] rxPowerErrArray = new double[rxInputPower.Count];
double[] rxPowerErrRawArray = new double[rxInputPower.Count];
for (byte i = 0; i < rxInputPower.Count; i++)
{
attennuator.AttnValue(rxInputPower[i].ToString(), 1);
rxPowerDmiArray[i] = dut.ReadDmiRxP(channel);
rxPowerErrArray[i] = Math.Abs(Convert.ToDouble(rxInputPower[i].ToString()) - rxPowerDmiArray[i]);
rxPowerErrRawArray[i] = Convert.ToDouble(rxInputPower[i].ToString()) - rxPowerDmiArray[i];
Log.SaveLogToTxt("rxInputPower[" + i.ToString() + "]: " + rxInputPower[i].ToString() + " rxPowerDmiArray[" + i.ToString("f3") + "]: " + rxPowerDmiArray[i].ToString() + " rxPowerErrArray[" + i.ToString() + "]: " + rxPowerErrArray[i].ToString("f3"));
}
//calculate delta and get the max
byte maxIndex;
Algorithm.SelectMaxValue(ArrayList.Adapter(rxPowerErrArray), out maxIndex);
double maxErr = rxPowerErrRawArray[maxIndex];
double errMaxPoint = Convert.ToDouble(rxInputPower[maxIndex].ToString());
Log.SaveLogToTxt("ErrMaxPoint = " + errMaxPoint.ToString() + " MaxErr = " + maxErr.ToString("f3"));
//get rxPowerDmi without any input optical power
attennuator.OutPutSwitch(false);
Thread.Sleep(2000);
double rxNopticalPoint = dut.ReadDmiRxP(channel);
Log.SaveLogToTxt("RxNopticalPoint=" + rxNopticalPoint.ToString());
attennuator.OutPutSwitch(true);
Log.SaveLogToTxt("End RxPowerDmi test for channel " + channel + "\r\n");
//save testdata
Dictionary <string, double> dictionary = new Dictionary <string, double>();
dictionary.Add("DmiRxPWRErr", maxErr);
dictionary.Add("DmiRxNOptical", rxNopticalPoint);
dictionary.Add("Result", 1);
return(dictionary);
}
}
catch
{
Log.SaveLogToTxt("Failed DMI_ICC test for channel " + channel + "\r\n");
return(null);
}
}
