Example #1
0
        private void handleData(ReadingsUpdateEventArgs e)
        {
            updateStatus();
            int index1 = cmbHallProbe1.SelectedIndex;
            int index2 = cmbHallProbe2.SelectedIndex;

            if (index1 >= 0 && index2 >= 0)
            {
                double val1 = e.readings[index1, 1];
                if (Double.IsInfinity(val1) || Double.IsNaN(val1))
                {
                    val1 = 0;
                }

                double val2 = e.readings[index2, 1];
                if (Double.IsInfinity(val2) || Double.IsNaN(val2))
                {
                    val2 = 0;
                }
                try
                {
                    nudHallProbe1.Value = (decimal)val1;
                    nudHallProbe2.Value = (decimal)val2;
                }
                catch (Exception ex)
                {
                }
            }

            if (calibrationOngoing)
            {
                if (calibrationCnt >= calibration.GetLength(0))
                {
                    calibrationOngoing = false;
                    //done with the calibration. Save to disk. Work-around since XMLserializer does not support serializing multi-dimensional arrays
                    double[] calibX = new double[calibration.GetLength(0)];
                    double[] calibY = new double[calibration.GetLength(0)];
                    for (int i = 0; i < calibX.Length; i++)
                    {
                        calibX[i] = calibration[i, 0];
                        calibY[i] = calibration[i, 1];
                    }
                    SerializeData.SerializeObject <double[]>(calibX, calibrationFile + "_xvals.xml");
                    SerializeData.SerializeObject <double[]>(calibY, calibrationFile + "_yvals.xml");
                }
                else
                {
                    //position on the y-axis
                    calibration[calibrationCnt, 1] = (double)nudCurrentPos.Value;
                    double HP1 = (double)nudHallProbe1.Value;
                    double HP2 = (double)nudHallProbe2.Value;
                    //field value on the x-axis
                    calibration[calibrationCnt, 0] = Math.Sqrt(HP1 * HP1 + HP2 * HP2);
                    nudSetPos.Value = (decimal)(calibration[calibrationCnt, 1] + dtheta_calibration);
                    moveMagnet();
                    calibrationCnt++;
                    Thread.Sleep(500);
                }
            }
        }
Example #2
0
        public void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
        {
            int index = cmbSeries.SelectedIndex;

            currentStabilityValue = e.readings[index, 1];
            lblStability.Text     = currentStabilityValue.ToString("e3");
        }
Example #3
0
 private void updateExperiment(ReadingsUpdateEventArgs e)
 {
     if (experimentReadingsUpdate != null)
     {
         experimentReadingsUpdate(this, e);
     }
 }
Example #4
0
 public void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
 {
     if (experimentReadingsUpdate != null)
     {
         experimentReadingsUpdate(sender, e);
     }
 }
Example #5
0
 public void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
 {
     if (dataSaver != null)
     {
         dataSaver.writeLine(e.readings);
     }
 }
        /**
         * Event that may be raised by a dynamic temperature gauge (such as the probe). When the probe is not touching, the gauge should be disabled to avoid severe over heating
         * */
        /*   public void temperatureGaugeStateChanged(Object sender, TemperatureGaugeEventArgs e)
         * {
         *     temperatureGaugeEnabled = e.temperatureGaugeEnabled;
         * }
         */
        public void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
        {
            //when getting some data update the PV, the error and thus the output
            if (chkEnabled.Checked && temperatureGaugeEnabled)
            {
                int port = cmbKeithleyPort.SelectedIndex;

                double time   = e.readings[port, 0];
                double Tprobe = e.readings[port, 1];

                double output = getOutput(Tprobe, time);

                //if a relay is attached this means the current should be reversed if the sign is negative
                if (relay != null)
                {
                    if (output > 0)
                    {
                        relay.updateState(false);
                    }
                    else
                    {
                        relay.updateState(true);
                    }
                    output = Math.Abs(output);
                }

                if (psuInterface != null)
                {
                    int psuPort = cmbPSUPort.SelectedIndex;
                    psuInterface.setCurrent(psuPort, output);

                    psuInterface.setEnabled(psuPort, true);
                }
            }
            else
            {
                if (psuInterface != null)
                {
                    int psuPort = cmbPSUPort.SelectedIndex;
                    psuInterface.setEnabled(psuPort, false);
                }
            }
        }
Example #7
0
        public void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
        {
            if (experimentRunning)
            {
                if (experimentReadingsUpdate != null)
                {
                    experimentReadingsUpdate(sender, e);
                }

                if (currentExperiment < experimentList.Count)
                {
                    if (experimentList[currentExperiment].updateExperimentFlow())
                    {
                        experimentList[currentExperiment] = null;
                        currentExperiment++;
                    }
                }
            }
        }
        private void saveData(double[,] dat)
        {
            int nExtra = additionalData.Count();
            int n      = dat.GetLength(0) + nExtra;

            double[,] dat_out = new double[n, 2];
            for (int i = 0; i < dat.GetLength(0); i++)
            {
                dat_out[i, 0] = dat[i, 0];
                dat_out[i, 1] = dat[i, 1];
            }
            //pad the extra data
            for (int i = dat.GetLength(0); i < n; i++)
            {
                dat_out[i, 1] = additionalData[i - dat.GetLength(0)];
            }

            //remember to clear the additional data list
            additionalData.Clear();

            int selExp = k2700Setup.getSelectedExperimentMode();

            if (dataWriter != null && dataWriter[selExp] != null)
            {
                if (selExp >= 0 && selExp < dataWriter.Length)
                {
                    dataWriter[selExp].writeLine(dat_out);
                    txtFilename.Text = dataWriter[selExp].getFilenameData();
                }
            }

            if (ReadingsUpdate != null)
            {
                ReadingsUpdateEventArgs e = new ReadingsUpdateEventArgs();
                e.readings         = dat;
                e.measurementTypes = getMeasurementTypes();
                e.names            = getMeasurementNames();
                e.chanEnabled      = getMeasurementChanEnabled();
                ReadingsUpdate(this, e);
            }
        }
        private void picoInstrument_SaveData(object sender, InstrumentDatasetEventArgs e)
        {
            double[,] dat = e.dataSet.getLatestData();

            object[] args = new object[2];
            args[0] = datGrdPico;
            args[1] = dat;

            if (ReadingsUpdate != null)
            {
                ReadingsUpdateEventArgs ex = new ReadingsUpdateEventArgs();
                ex.readings = dat;
                //e.measurementTypes = getMeasurementTypes();
                //e.names = getMeasurementNames();
                //e.chanEnabled = getMeasurementChanEnabled();
                ReadingsUpdate(this, ex);
            }


            BeginInvoke(new UpdateDataGridAsync(updateDataGridView), args);
        }
 /**
  * Listener for updates from the Keithley readings
  */
 public void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
 {
     /*
      * //extract the data from the load cell port
      * //should be changed so the keithleyControl can provide the correct
      * //port info, but is hardly a big issue at the moment.
      * int port = cmbLoadPort.SelectedIndex;
      * double load = e.readings[port, 1];
      *
      *
      * double excitation = e.readings[cmbSelectLoadCellExcitation.SelectedIndex, 1];
      *
      * doubleCurrentLoad = LCEB_LoadCell.getLoadNewton(load, excitation);
      * doubleCurrentLoad = doubleCurrentLoad - loadOffset;
      * txtCurrentLoad.Text = doubleCurrentLoad.ToString();
      *
      * updateProbeContact();
      *
      * // Initiate the probe scanning routine if flagged by isScanning
      * scanningRoutine();
      */
 }
        internal void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
        {
            //check all temperature readings if they are above the accepted limit
            for (int i = 0; i < e.chanEnabled.Length; i++)
            {
                switch (e.measurementTypes[i])
                {
                case Keithley2700MeasurementTypes.TC_E:
                case Keithley2700MeasurementTypes.TC_K:

                    double val = e.readings[i, 1];
                    if (!Double.IsInfinity(val) && !Double.IsNaN(val) && val > temperatureLimit)
                    {
                        onCloseInstruments();
                    }
                    break;

                default:
                    break;
                }
            }
        }
        private void saveData(double [,] rawData, double[] meanVals, double[] stdevVals)
        {
            if (plotValIndex >= plotValues.GetLength(0))
            {
                plotValIndex = 0;
            }
            for (int i = 0; i < plotValues.GetLength(1); i++)
            {
                plotValues[plotValIndex, i] = meanVals[i];
            }
            ReadingsUpdateEventArgs evt = new ReadingsUpdateEventArgs();

            double[,] dat = new double[4, 2];
            for (int i = 0; i < 4; i++)
            {
                dat[i, 0] = meanVals[5];
                dat[i, 1] = meanVals[i];
            }
            evt.readings = dat;
            graphXYPlot1.readingsUpdate(null, evt);

            plotValIndex++;



            nMeasurements++;
            nudCurrentMeasurement.Value = (decimal)nMeasurements;
            datasaverRaw.writeRaw(rawData);
            datasaverProcessed.writeProcessed(meanVals, stdevVals);
            if (nMeasurements >= (int)nudNMea.Value)
            {
                //fire the event that the no. of data points has been reached
                if (measurementsCompleted != null)
                {
                    measurementsCompleted(this, null);
                }
            }
        }
Example #13
0
 /**
  * Called when the data system pushes new data
  * */
 public void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
 {
     object[] dat = new object[1];
     dat[0] = e;
     BeginInvoke(new HandleData(handleData), dat);
 }
 /**
  * Called when the Keithley or other data acquisition has new data
  * */
 public void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
 {
     object[] dat = new object[1];
     dat[0] = e.readings;
     BeginInvoke(new UpdateSeries(updateSeries), dat);
 }
Example #15
0
        private void filterData(ReadingsUpdateEventArgs e)
        {
            double [,] data = e.readings;
            //init the amended data set, i.e. the raw data concatenated with the results of the filtering
            double[,] datOut = new double[data.GetLength(0) + nFilters, 2];
            //copy the raw data
            for (int i = 0; i < data.GetLength(0); i++)
            {
                datOut[i, 0] = data[i, 0];
                datOut[i, 1] = data[i, 1];
            }

            //now do the filtering
            EFMExperimentFilters[] filters = (EFMExperimentFilters[])settings.transformation.ToArray(typeof(int));
            int[]    chnA      = (int[])settings.channelA.ToArray(typeof(int));
            int[]    chnB      = (int[])settings.channelB.ToArray(typeof(int));
            string[] names_arr = (string[])settings.names.ToArray(typeof(string));
            double[] K1        = (double[])settings.K1_vals.ToArray(typeof(double));
            double[] K2        = (double[])settings.K2_vals.ToArray(typeof(double));
            double[] K3        = (double[])settings.K3_vals.ToArray(typeof(double));
            for (int i = 0; i < nFilters; i++)
            {
                int index = i + data.GetLength(0);
                switch (filters[i])
                {
                case EFMExperimentFilters.HallProbeSignal:
                    //transfer the time of the channel
                    datOut[index, 0] = data[chnA[i], 0];
                    //filter the data point
                    double scale       = K1[i];
                    double offset      = K2[i];
                    double nom_current = K3[i];
                    double voltage     = data[chnA[i], 1];
                    double current     = data[chnB[i], 1];
                    datOut[index, 1] = 1 / scale * (voltage * nom_current / current + offset);
                    break;

                case EFMExperimentFilters.PeltierDifference:
                    //transfer the time
                    datOut[index, 0] = 0.5 * (data[chnA[i], 0] + data[chnB[i], 0]);
                    //Subtract the two peltier signals
                    datOut[index, 1] = data[chnA[i], 1] - data[chnB[i], 1];
                    break;

                case EFMExperimentFilters.PeltierStability:
                    datOut[index, 0] = data[chnA[i], 0];
                    if (curStabilityPos >= stabilityDataBuffer.Length)
                    {
                        curStabilityPos = 0;
                    }
                    //use the peltier difference as the variable to check for stability
                    stabilityDataBuffer[curStabilityPos] = data[chnA[i], 1] - data[chnB[i], 1];
                    //increment the position counter
                    curStabilityPos++;
                    double mean = 0;
                    double std  = 0;
                    if (curStabilityPos > 0)
                    {
                        for (int j = 0; j < stabilityDataBuffer.Length; j++)
                        {
                            mean += stabilityDataBuffer[j];
                        }
                        mean = mean / (stabilityDataBuffer.Length - 1);

                        for (int j = 0; j < stabilityDataBuffer.Length; j++)
                        {
                            std += Math.Pow((stabilityDataBuffer[j] - mean), 2);
                        }
                        std = Math.Sqrt(std / (curStabilityPos + 1));
                        //stability = Math.Abs(std / mean);
                        datOut[index, 1] = std;
                    }
                    break;

                default:
                    break;
                }
            }

            if (FilterReadingsUpdate != null)
            {
                e.readings = datOut;
                FilterReadingsUpdate(this, e);
            }
        }
Example #16
0
 /**
  * Data from the data collector
  * */
 public void readingsUpdate(object sender, ReadingsUpdateEventArgs e)
 {
     object[] dat = new object[1];
     dat[0] = e;
     BeginInvoke(new UpdateExperiment(updateExperiment), dat);
 }