public AddLaser ( string name, string photodiode ) : void | ||
name | string | |
photodiode | string | |
return | void |
public DecelerationHardware() { // YAG laser yag = new MiniliteLaser(); // add the boards Boards.Add("daq", "/dev2"); Boards.Add("multiDAQ", "/dev1"); Boards.Add("pg", "/dev1"); Boards.Add("aoBoard", "/PXI1Slot5"); Boards.Add("usbDev", "/dev4"); //Boards.Add("PXI6", "/PXI1Slot6_4"); Boards.Add("PXI6", "/PXI1Slot6"); Boards.Add("PXI4", "/PXI1Slot4"); Boards.Add("PXI5", "/PXI1Slot5"); string pgBoard = (string)Boards["pg"]; string usbBoard = (string)Boards["usbDev"]; string daqBoard = (string)Boards["daq"]; string PXIBoard = (string)Boards["PXI6"]; string TCLBoard = (string)Boards["PXI4"]; string TCLBoard2 = (string)Boards["PXI6"]; string aoBoard = (string)Boards["aoBoard"]; //configure instance 1 of transfer cavity lock TCLConfig tcl1 = new TCLConfig("Hamish McCavity"); tcl1.AddLaser("v00cooling", "p1"); tcl1.AddLaser("v10repump", "p2"); tcl1.AddLaser("eylsa", "p3"); tcl1.Trigger = TCLBoard + "/PFI0"; tcl1.Cavity = "cavity"; tcl1.MasterLaser = "master"; tcl1.Ramp = "rampfb"; tcl1.TCPChannel = 1190; Info.Add("Hamish", tcl1); //configure instance 2 of transfer cavity lock TCLConfig tcl2 = new TCLConfig("Carlos the Cavity"); tcl2.AddLaser("v21repump", "p12"); tcl2.AddLaser("v32repump", "p22"); tcl2.Trigger = TCLBoard2 + "/PFI0"; tcl2.Cavity = "cavity2"; tcl2.MasterLaser = "master2"; tcl2.Ramp = "rampfb2"; tcl2.TCPChannel = 1191; Info.Add("Carlos", tcl2); //MotMaster configuration MMConfig mmConfig = new MMConfig(false, false, false, false); mmConfig.ExternalFilePattern = "*.tif"; Info.Add("MotMasterConfiguration", mmConfig); Instruments.Add("synth", new HP8673BSynth("GPIB0::19::INSTR")); //Instruments.Add("counter", new HP5350BCounter("GPIB0::14::INSTR")); //Instruments.Add("flowmeter", new FlowMeter("ASRL1::INSTR")); //VCO lock //AddAnalogOutputChannel("VCO_Out", PXIBoard + "/ao12", 0.0, 10.0); // add things to the info Info.Add("PGClockLine", Boards["pg"] + "/PFI2"); Info.Add("PatternGeneratorBoard", pgBoard); Info.Add("PGType", "dedicated"); Info.Add("AOPatternTrigger", aoBoard + "/PFI0"); Info.Add("defaultTOFRange", new double[] {4000, 12000}); // these entries are the two ends of the range for the upper TOF graph Info.Add("defaultTOF2Range", new double[] { 0, 1000 }); // these entries are the two ends of the range for the middle TOF graph Info.Add("defaultGate", new double[] { 6000, 2000 }); // the first entry is the centre of the gate, the second is the half width of the gate (upper TOF graph) // the analog triggers Info.Add("analogTrigger0", (string)Boards["daq"] + "/PFI0");// pin 11 Info.Add("analogTrigger1", (string)Boards["daq"] + "/PFI1");// pin 10 //Info.Add("TCLTrigger", (string)Boards["PXI4"] + "/PFI0"); //Info.Add("analogTrigger2", (string)Boards["usbDev"] + "/PFI0"); //Pin 29 Info.Add("analogTrigger3", (string)Boards["daq"] + "/PFI6"); //Pin 5 - breakout 31 Info.Add("usbAnalogTrigger", usbBoard + "/PFI0"); //distance information Info.Add("sourceToDetect", 0.535); //in m Info.Add("sourceToSoftwareDecelerator", 0.12); //in m //information about the molecule Info.Add("molecule", "caf"); Info.Add("Element", "CaF"); Info.Add("moleculeMass", 58.961); // this is 40CaF in atomic mass units Info.Add("moleculeRotationalConstant", 1.02675E10); //in Hz Info.Add("moleculeDipoleMoment", 15400.0); //in Hz/(V/m) //information about the decelerator //These settings for WF Info.Add("deceleratorStructure", DecelerationConfig.DecelerationExperiment.SwitchStructure.V_H); //Vertical first Info.Add("deceleratorLensSpacing", 0.006); Info.Add("deceleratorFieldMap", "RodLayout3_EonAxis.dat"); Info.Add("mapPoints", 121); Info.Add("mapStartPoint", 0.0); Info.Add("mapResolution", 0.0001); // These settings for AG // Info.Add("deceleratorStructure", DecelerationConfig.DecelerationExperiment.SwitchStructure.H_V); //Horizontal first // Info.Add("deceleratorLensSpacing", 0.024); // Info.Add("deceleratorFieldMap", "Section1v1_onAxisFieldTemplate.dat"); // Info.Add("mapPoints", 481); // Info.Add("mapStartPoint", 0.0); // Info.Add("mapResolution", 0.0001); //Here are constants for 174YbF for future reference //Info.Add("molecule", "ybf"); //Info.Add("moleculeMass", 192.937); // this is 174YbF in atomic mass units //Info.Add("moleculeRotationalConstant", 7.2338E9); //in Hz //Info.Add("moleculeDipoleMoment", 19700.0); //in Hz/(V/m) // map the digital channels AddDigitalOutputChannel("valve", pgBoard, 0, 6); AddDigitalOutputChannel("tclBlock", pgBoard, 0, 6); //Same as valve; deliberately! AddDigitalOutputChannel("flash", pgBoard, 0, 0);//Changed from pg board P.0.5 because that appears to have died mysteriously (line dead in ribbon cable?) TEW 06/04/09 AddDigitalOutputChannel("q", pgBoard, 0,2 ); AddDigitalOutputChannel("chirpTrigger", pgBoard, 1, 0); AddDigitalOutputChannel("detector", pgBoard, 3, 7); AddDigitalOutputChannel("detectorprime", pgBoard, 3, 6); AddDigitalOutputChannel("aom", pgBoard, 2, 1);//Same channel as "ttl2" as used by the AomLevelControlPlugin. Now commented out. AddDigitalOutputChannel("aom2", pgBoard, 1, 6); // Pin 21 of PG board. Output 31 of front panel AddDigitalOutputChannel("ttlSwitch", pgBoard, 2,2); // This is the output that the pg will switch if it's switch scanning. //AddDigitalOutputChannel("digitalSwitchChannel", pgBoard, 2, 2); AddDigitalOutputChannel("motAOM", pgBoard, 1, 1); //Pin 17 AddDigitalOutputChannel("motRampTrigger", pgBoard, 1, 2); //Pin 51 AddDigitalOutputChannel("bTrigger", pgBoard, 1, 3); //Pin 52 AddDigitalOutputChannel("cameraTrigger", pgBoard, 0, 4); // Pin 13 AddDigitalOutputChannel("AnalogPatternTrigger", pgBoard, 3, 3); //Pin 31 // map the analog channels AddAnalogInputChannel("pmt", daqBoard + "/ai0", AITerminalConfiguration.Rse); AddAnalogInputChannel("pmt2", daqBoard + "/ai1", AITerminalConfiguration.Rse); AddAnalogInputChannel("refcavity", daqBoard + "/ai1", AITerminalConfiguration.Rse); AddAnalogInputChannel("lockcavity", daqBoard + "/ai2", AITerminalConfiguration.Rse); AddAnalogInputChannel("master", TCLBoard + "/ai1", AITerminalConfiguration.Rse); AddAnalogInputChannel("cavity", TCLBoard + "/ai15", AITerminalConfiguration.Rse); AddAnalogInputChannel("p1", TCLBoard + "/ai3", AITerminalConfiguration.Rse); AddAnalogInputChannel("p2", TCLBoard + "/ai10", AITerminalConfiguration.Rse); AddAnalogInputChannel("p3", TCLBoard + "/ai4", AITerminalConfiguration.Rse); AddAnalogOutputChannel("v10repump", TCLBoard + "/ao0"); AddAnalogOutputChannel("rampfb", TCLBoard + "/ao1"); AddAnalogOutputChannel("v00cooling", TCLBoard2 + "/ao2"); AddAnalogOutputChannel("eylsa", TCLBoard2 + "/ao3"); AddAnalogOutputChannel("slowingChirp", aoBoard + "/ao8"); AddAnalogOutputChannel("v0IntensityRamp", aoBoard + "/ao9"); //second cavity AddAnalogInputChannel("master2", TCLBoard2 + "/ai0", AITerminalConfiguration.Rse); AddAnalogInputChannel("cavity2", TCLBoard2 + "/ai4", AITerminalConfiguration.Rse); AddAnalogInputChannel("p12", TCLBoard2 + "/ai1", AITerminalConfiguration.Rse); AddAnalogInputChannel("p22", TCLBoard2 + "/ai2", AITerminalConfiguration.Rse); AddAnalogOutputChannel("v21repump", TCLBoard2 + "/ao0"); AddAnalogOutputChannel("v32repump", usbBoard + "/ao0", 0 , 5); AddAnalogOutputChannel("rampfb2", TCLBoard2 + "/ao1"); // map the counter channels AddCounterChannel("pmt", daqBoard + "/ctr0"); AddCounterChannel("sample clock", daqBoard + "/ctr1"); //map the monitoring source chamber in deceleration hardware AddAnalogInputChannel("RoughVacuum", PXIBoard + "/ai0", AITerminalConfiguration.Rse); AddAnalogInputChannel("PressureSourceChamber", PXIBoard + "/ai1", AITerminalConfiguration.Rse); AddAnalogInputChannel("VoltageReference", PXIBoard + "/ai2", AITerminalConfiguration.Rse); AddAnalogInputChannel("10KThermistor30KPlate", PXIBoard + "/ai3", AITerminalConfiguration.Rse); AddAnalogInputChannel("30KShield", PXIBoard + "/ai4", AITerminalConfiguration.Rse); AddAnalogInputChannel("4KCell", PXIBoard + "/ai5", AITerminalConfiguration.Rse); //map the channels to monitor the sidebands in deceleration hardware AddAnalogInputChannel("cavityVoltage", usbBoard + "/ai0", AITerminalConfiguration.Rse); AddAnalogInputChannel("mot606", usbBoard + "/ai1", AITerminalConfiguration.Rse); AddAnalogInputChannel("mot628V1", usbBoard + "/ai2", AITerminalConfiguration.Rse); AddAnalogInputChannel("mot628V2", usbBoard + "/ai3", AITerminalConfiguration.Rse); //AddAnalogInputChannel("mot628V3", usbBoard + "/ai4", AITerminalConfiguration.Rse); AddAnalogInputChannel("slowing531", usbBoard + "/ai4", AITerminalConfiguration.Rse); AddAnalogInputChannel("slowing628V1", usbBoard + "/ai7", AITerminalConfiguration.Rse); //analog output channels controlled by the hardware controller and/or MOTMaster AddAnalogOutputChannel("motAOMFreq", aoBoard + "/ao10"); AddAnalogOutputChannel("motAOMAmp", aoBoard + "/ao11"); AddCalibration("motAOMFreq", new PolynomialCalibration(new double[] { -9.7727, 0.16604, -0.0000272 }, 70, 130)); //this is a quadratic fit to the manufacturer's data for a POS-150 AddCalibration("motAOMAmp", new LinearCalibration(1, 0, 0, -10, 10)); // needs calibrating }
public PXIEDMHardware() { // add the boards Boards.Add("daq", "/PXI1Slot18"); Boards.Add("pg", "/PXI1Slot10"); Boards.Add("counter", "/PXI1Slot3"); Boards.Add("aoBoard", "/PXI1Slot4"); // this drives the rf attenuators Boards.Add("usbDAQ1", "/Dev6"); Boards.Add("analogIn", "/PXI1Slot2"); Boards.Add("usbDAQ2", "/Dev4"); Boards.Add("usbDAQ3", "/Dev2"); Boards.Add("usbDAQ4", "/Dev5"); Boards.Add("tclBoard", "/PXI1Slot9"); string pgBoard = (string)Boards["pg"]; string daqBoard = (string)Boards["daq"]; string counterBoard = (string)Boards["counter"]; string aoBoard = (string)Boards["aoBoard"]; string usbDAQ1 = (string)Boards["usbDAQ1"]; string analogIn = (string)Boards["analogIn"]; string usbDAQ2 = (string)Boards["usbDAQ2"]; string usbDAQ3 = (string)Boards["usbDAQ3"]; string usbDAQ4 = (string)Boards["usbDAQ4"]; string tclBoard = (string)Boards["tclBoard"]; // add things to the info // the analog triggersf Info.Add("analogTrigger0", (string)Boards["analogIn"] + "/PFI0"); Info.Add("analogTrigger1", (string)Boards["analogIn"] + "/PFI1"); Info.Add("sourceToDetect", 1.3); Info.Add("moleculeMass", 193.0); Info.Add("machineLengthRatio", 3.842); Info.Add("defaultGate",new double[] {2190, 80}); Info.Add("phaseLockControlMethod", "synth"); Info.Add("PGClockLine", pgBoard + "/PFI4"); //Mapped to PFI2 on 6533 connector Info.Add("PatternGeneratorBoard", pgBoard); Info.Add("PGType", "dedicated"); // rf counter switch control seq`` Info.Add("IodineFreqMon", new bool[] { false, false }); // IN 1 Info.Add("pumpAOMFreqMon", new bool[] { false, true }); // IN 2 Info.Add("FLModulationFreqMon", new bool[] { true, false }); // IN 3 Info.Add("PGTrigger", pgBoard + "/PFI5"); //Mapped to PFI7 on 6533 connector // YAG laser yag = new BrilliantLaser("ASRL9::INSTR"); // add the GPIB/RS232 instruments Instruments.Add("green", new HP8657ASynth("GPIB0::7::INSTR")); Instruments.Add("gigatronix", new Gigatronics7100Synth("GPIB0::19::INSTR")); Instruments.Add("red", new HP3325BSynth("GPIB0::12::INSTR")); Instruments.Add("4861", new ICS4861A("GPIB0::4::INSTR")); Instruments.Add("bCurrentMeter", new HP34401A("GPIB0::22::INSTR")); Instruments.Add("rfCounter", new Agilent53131A("GPIB0::3::INSTR")); //Instruments.Add("rfCounter2", new Agilent53131A("GPIB0::5::INSTR")); Instruments.Add("rfPower", new HP438A("GPIB0::13::INSTR")); Instruments.Add("BfieldController", new SerialDAQ("ASRL7::INSTR")); Instruments.Add("rfCounter2", new SerialAgilent53131A("ASRL14::INSTR")); Instruments.Add("probePolControl", new SerialMotorControllerBCD("ASRL8::INSTR")); Instruments.Add("pumpPolControl", new SerialMotorControllerBCD("ASRL11::INSTR")); // map the digital channels // these channels are generally switched by the pattern generator // they're all in the lower half of the pg AddDigitalOutputChannel("valve", pgBoard, 0, 0); AddDigitalOutputChannel("flash", pgBoard, 0, 1); AddDigitalOutputChannel("q", pgBoard, 0, 2); AddDigitalOutputChannel("detector", pgBoard, 0, 3); AddDigitalOutputChannel("detectorprime", pgBoard, 1, 2); // this trigger is for switch scanning // see ModulatedAnalogShotGatherer.cs // for details. AddDigitalOutputChannel("rfSwitch", pgBoard, 0, 4); AddDigitalOutputChannel("pumprfSwitch", pgBoard, 3, 4); AddDigitalOutputChannel("fmSelect", pgBoard, 1, 0); // This line selects which fm voltage is // sent to the synth. AddDigitalOutputChannel("attenuatorSelect", pgBoard, 0, 5); // This line selects the attenuator voltage // sent to the voltage-controlled attenuator. AddDigitalOutputChannel("piFlip", pgBoard, 1, 1); AddDigitalOutputChannel("ttlSwitch", pgBoard, 1, 3); // This is the output that the pg // will switch if it's switch scanning. AddDigitalOutputChannel("scramblerEnable", pgBoard, 1, 4); //RF Counter Control (single pole 4 throw) //AddDigitalOutputChannel("rfCountSwBit1", pgBoard, 3, 5); //AddDigitalOutputChannel("rfCountSwBit2", pgBoard, 3, 6); // new rf amp blanking AddDigitalOutputChannel("rfAmpBlanking", pgBoard, 1, 5); // these channel are usually software switched - they should not be in // the lower half of the pattern generator AddDigitalOutputChannel("b", pgBoard, 2, 0); AddDigitalOutputChannel("notB", pgBoard, 2, 1); AddDigitalOutputChannel("db", pgBoard, 2, 2); AddDigitalOutputChannel("notDB", pgBoard, 2, 3); // AddDigitalOutputChannel("notEOnOff", pgBoard, 2, 4); // this line seems to be broken on our pg board // AddDigitalOutputChannel("eOnOff", pgBoard, 2, 5); // this and the above are not used now we have analog E control AddDigitalOutputChannel("targetStepper", pgBoard, 2, 5); AddDigitalOutputChannel("ePol", pgBoard, 2, 6); AddDigitalOutputChannel("notEPol", pgBoard, 2, 7); AddDigitalOutputChannel("eBleed", pgBoard, 3, 0); AddDigitalOutputChannel("eSwitching", aoBoard, 0, 6); AddDigitalOutputChannel("piFlipEnable", pgBoard, 3, 1); AddDigitalOutputChannel("notPIFlipEnable", pgBoard, 3, 5); AddDigitalOutputChannel("mwEnable", pgBoard, 3, 3); AddDigitalOutputChannel("argonShutter", pgBoard, 3, 2); AddDigitalOutputChannel("patternTTL", aoBoard, 0, 7); //I2 Lock Control AddDigitalOutputChannel("I2PropSwitch", pgBoard, 2, 4); AddDigitalOutputChannel("I2IntSwitch", pgBoard, 3, 6); AddDigitalOutputChannel("fibreAmpEnable", aoBoard, 0, 0); // Map the digital input channels AddDigitalInputChannel("fibreAmpMasterErr", aoBoard, 0, 1); AddDigitalInputChannel("fibreAmpSeedErr", aoBoard, 0, 2); AddDigitalInputChannel("fibreAmpBackFeflectErr", aoBoard, 0, 3); AddDigitalInputChannel("fibreAmpTempErr", aoBoard, 0, 4); AddDigitalInputChannel("fibreAmpPowerSupplyErr", aoBoard, 0, 5); // map the analog channels // These channels are on the daq board. Used mainly for diagnostic purposes. // On no account should they switch during the edm acquisition pattern. //AddAnalogInputChannel("diodeLaserCurrent", daqBoard + "/ai0", AITerminalConfiguration.Differential); AddAnalogInputChannel("iodine", daqBoard + "/ai2", AITerminalConfiguration.Nrse); AddAnalogInputChannel("cavity", daqBoard + "/ai3", AITerminalConfiguration.Nrse); AddAnalogInputChannel("probePD", daqBoard + "/ai4", AITerminalConfiguration.Nrse); AddAnalogInputChannel("pumpPD", daqBoard + "/ai5", AITerminalConfiguration.Nrse); AddAnalogInputChannel("northLeakage", daqBoard + "/ai6", AITerminalConfiguration.Nrse); AddAnalogInputChannel("southLeakage", daqBoard + "/ai7", AITerminalConfiguration.Nrse); // Used ai13,11 & 12 over 6,7 & 8 for miniFluxgates, because ai8, 9 have an isolated ground. AddAnalogInputChannel("miniFlux1", daqBoard + "/ai13", AITerminalConfiguration.Nrse); AddAnalogInputChannel("miniFlux2", daqBoard + "/ai11", AITerminalConfiguration.Nrse); AddAnalogInputChannel("miniFlux3", daqBoard + "/ai12", AITerminalConfiguration.Nrse); AddAnalogInputChannel("ground", daqBoard + "/ai14", AITerminalConfiguration.Nrse); AddAnalogInputChannel("piMonitor", daqBoard + "/ai10", AITerminalConfiguration.Nrse); //AddAnalogInputChannel("diodeLaserRefCavity", daqBoard + "/ai13", AITerminalConfiguration.Nrse); // Don't use ai10, cross talk with other channels on this line // high quality analog inputs (will be) on the S-series analog in board // The last number in AddAnalogInputChannel is an optional calibration which turns VuS and MHz AddAnalogInputChannel("topProbe", analogIn + "/ai0", AITerminalConfiguration.Differential, 0.1); AddAnalogInputChannel("bottomProbe", analogIn + "/ai1", AITerminalConfiguration.Differential, 0.02); AddAnalogInputChannel("magnetometer", analogIn + "/ai2", AITerminalConfiguration.Differential); AddAnalogInputChannel("gnd", analogIn + "/ai3", AITerminalConfiguration.Differential); AddAnalogInputChannel("battery", analogIn + "/ai4", AITerminalConfiguration.Differential); //AddAnalogInputChannel("piMonitor", analogIn + "/ai5", AITerminalConfiguration.Differential); //AddAnalogInputChannel("bFieldCurrentMonitor", analogIn + "/ai6", AITerminalConfiguration.Differential); AddAnalogInputChannel("reflectedrf1Amplitude", analogIn + "/ai5", AITerminalConfiguration.Differential); AddAnalogInputChannel("reflectedrf2Amplitude", analogIn + "/ai6", AITerminalConfiguration.Differential); AddAnalogInputChannel("rfCurrent", analogIn + "/ai7 ", AITerminalConfiguration.Differential); AddAnalogOutputChannel("phaseScramblerVoltage", aoBoard + "/ao10"); AddAnalogOutputChannel("b", aoBoard + "/ao2"); // rf rack control //AddAnalogInputChannel("rfPower", usbDAQ1 + "/ai0", AITerminalConfiguration.Rse); AddAnalogOutputChannel("rf1Attenuator", usbDAQ1 + "/ao0", 0, 5); AddAnalogOutputChannel("rf2Attenuator", usbDAQ1 + "/ao1", 0, 5); AddAnalogOutputChannel("rf1FM", usbDAQ2 + "/ao0", 0, 5); AddAnalogOutputChannel("rf2FM", usbDAQ2 + "/ao1", 0, 5); // E field control and monitoring //AddAnalogInputChannel("cPlusMonitor", usbDAQ3 + "/ai1", AITerminalConfiguration.Differential); //AddAnalogInputChannel("cMinusMonitor", usbDAQ3 + "/ai2", AITerminalConfiguration.Differential); AddAnalogInputChannel("cPlusMonitor", daqBoard + "/ai0", AITerminalConfiguration.Differential); AddAnalogInputChannel("cMinusMonitor", daqBoard + "/ai1", AITerminalConfiguration.Differential); AddAnalogOutputChannel("cPlus", usbDAQ3 + "/ao0", 0, 10); AddAnalogOutputChannel("cMinus", usbDAQ3 + "/ao1", 0, 10); // B field control //AddAnalogOutputChannel("steppingBBias", usbDAQ4 + "/ao0", 0, 5); // map the counter channels AddCounterChannel("phaseLockOscillator", counterBoard + "/ctr7"); AddCounterChannel("phaseLockReference", counterBoard + "/pfi10"); //AddCounterChannel("northLeakage", counterBoard + "/ctr0"); //AddCounterChannel("southLeakage", counterBoard + "/ctr1"); //TCL configuration TCLConfig tcl1 = new TCLConfig("Hamish McCavity"); tcl1.AddLaser("MenloPZT", "p1"); tcl1.AddLaser("899ExternalScan", "p2"); tcl1.Trigger = tclBoard + "/PFI0"; tcl1.Cavity = "transCavV"; tcl1.MasterLaser = "master"; tcl1.Ramp = "rampfb"; tcl1.TCPChannel = 1190; tcl1.AnalogSampleRate = 50000; tcl1.DefaultScanPoints = 300; Info.Add("Hamish", tcl1); Info.Add("DefaultCavity", tcl1); //TCL Lockable lasers - this stuff should not now be needed - leave here for reference just in case //Info.Add("TCLLockableLasers", new string[][] { new string[] { "flPZT2" }, /*new string[] { "flPZT2Temp" },*/ new string[] { "fibreAOM", "flPZT2Temp" } }); //Info.Add("TCLLockableLasers", new string[] { "MenloPZT", "899ExternalScan" }); //, new string[] { "flPZT2Temp" }, new string[] { "fibreAOM"} }); //Info.Add("TCLPhotodiodes", new string[] {"transCavV", "master", "p1", "p2" });// THE FIRST TWO MUST BE CAVITY AND MASTER PHOTODIODE!!!! //Info.Add("TCL_Default_Master_Gain", -1.1); //Info.Add("TCL_Default_Lockable_Laser_Gains",-0.1); //Info.Add("TCL_Default_VoltageToLaser", 2.5); //Info.Add("TCL_Default_VoltageToDependent", 1.0); //Info.Add("TCL_Default_ScanPoints",300); // Some matching up for TCL //Info.Add("MenloPZT", "p1"); //Info.Add("flPZT2Temp", "p1"); //Info.Add("899ExternalScan", "p2"); //Info.Add("fibreAOM", "p1"); //Info.Add("TCLTrigger", tclBoard + "/PFI0"); //Info.Add("TCL_MAX_INPUT_VOLTAGE", 10.0); AddAnalogInputChannel("transCavV", tclBoard + "/ai0", AITerminalConfiguration.Rse); AddAnalogInputChannel("master", tclBoard + "/ai1", AITerminalConfiguration.Rse); AddAnalogInputChannel("p1", tclBoard + "/ai2", AITerminalConfiguration.Rse); AddAnalogInputChannel("p2", tclBoard + "/ai3", AITerminalConfiguration.Rse); // Laser control //AddAnalogOutputChannel("flPZT", usbDAQ4 + "/ao1", 0, 5); AddAnalogOutputChannel("899ExternalScan", aoBoard + "/ao4", 0, 7.5); AddAnalogOutputChannel("MenloPZT", tclBoard + "/ao0", 0, 10); AddAnalogOutputChannel("probeAOM", aoBoard + "/ao9", 0, 10); AddAnalogOutputChannel("pumpAOM", aoBoard + "/ao8", 0, 10); AddAnalogOutputChannel("fibreAmpPwr", aoBoard + "/ao3"); //AddAnalogOutputChannel("pumpAOM", aoBoard + "/ao4", 0, 10); //AddAnalogOutputChannel("flPZT2Temp", aoBoard + "/ao5", 0, 4); //voltage must not exceed 4V for Koheras laser //AddAnalogOutputChannel("flPZT2Cur", aoBoard + "/ao6", 0, 5); //voltage must not exceed 5V for Koheras laser //AddAnalogOutputChannel("fibreAOM", usbDAQ4 + "/ao1", 0, 5); AddAnalogOutputChannel("rampfb", tclBoard + "/ao1", -10, 10); AddAnalogOutputChannel("I2LockBias", aoBoard + "/ao5", 0, 5); //Microwave Control Channels AddAnalogOutputChannel("uWaveDCFM", aoBoard + "/ao11", -2.5, 2.5); AddAnalogOutputChannel("uWaveMixerV", aoBoard + "/ao12", 0, 10); AddAnalogOutputChannel("VCO161Amp", aoBoard + "/ao13", 0, 10); AddAnalogOutputChannel("VCO161Freq", aoBoard + "/ao14", 0, 10); AddAnalogOutputChannel("VCO30Amp", aoBoard + "/ao15", 0, 10); AddAnalogOutputChannel("VCO30Freq", aoBoard + "/ao16", 0, 10); AddAnalogOutputChannel("VCO155Amp", aoBoard + "/ao17", 0, 10); AddAnalogOutputChannel("VCO155Freq", aoBoard + "/ao18", 0, 10); }
public RainbowHardware() { // add the boards Boards.Add("daq", "/PXI1Slot4"); Boards.Add("TCLBoard", "/PXI1Slot6"); string daqBoard = (string)Boards["daq"]; string TCLBoard = (string)Boards["TCLBoard"]; // add things to the info // the analog triggers Info.Add("analogTrigger0", (string)Boards["daq"] + "/PFI1"); Info.Add("analogTrigger1", (string)Boards["daq"] + "/PFI2"); Info.Add("sourceToDetect", 0.4); Info.Add("moleculeMass", 100.0); Info.Add("phaseLockControlMethod", "synth"); Info.Add("PGClockLine", daqBoard + "/PFI4"); Info.Add("PatternGeneratorBoard", daqBoard); Info.Add("PGType", "integrated"); Info.Add("PGClockCounter", "/ctr0"); //TCL Configuration TCLConfig tcl1 = new TCLConfig("Hamish McCavity"); tcl1.AddLaser("laser", "p1"); tcl1.AddLaser("laser2", "p2"); tcl1.AddLaser("laser4", "p4"); tcl1.Trigger = TCLBoard + "/PFI0"; tcl1.Cavity = "cavityRampMonitor"; tcl1.MasterLaser = "master"; tcl1.Ramp = "rampfb"; tcl1.AnalogSampleRate = 50000; tcl1.TCPChannel = 1190; Info.Add("Hamish", tcl1); Info.Add("DefaultCavity", tcl1); //TCL Lockable lasers - this stuff should no longer be needed - leave here for reference //Info.Add("TCLLockableLasers", new string[] { "laser","laser2","laser4"}); //Info.Add("TCLPhotodiodes", new string[] { "cavityRampMonitor", "master", "p1", "p2","p4"});// THE FIRST TWO MUST BE CAVITY AND MASTER PHOTODIODE!!!! //Info.Add("TCL_Slave_Voltage_Limit_Upper", 2.0); //volts: Laser control //Info.Add("TCL_Slave_Voltage_Limit_Lower", -2.0); //volts: Laser control //Info.Add("TCL_Default_Gain", -0.01); //Info.Add("TCL_Default_VoltageToLaser", 0.0); //Info.Add("TCL_MAX_INPUT_VOLTAGE", 10.0); //// Some matching up for TCL //Info.Add("laser", "p1"); //Info.Add("laser2", "p2"); //Info.Add("laser4", "p4"); //Info.Add("TCLTrigger", TCLBoard + "/PFI0"); // YAG laser yag = new BrilliantLaser("ASRL3::INSTR"); // add the GPIB instruments // map the digital channels AddDigitalOutputChannel("valve", daqBoard, 0, 0); AddDigitalOutputChannel("flash", daqBoard, 0, 1); AddDigitalOutputChannel("q", daqBoard, 0, 2); AddDigitalOutputChannel("detector", daqBoard, 0, 3); AddDigitalOutputChannel("detectorprime", daqBoard, 0, 4); // this trigger is for switch scanning AddDigitalOutputChannel("aom", daqBoard, 0, 5); // this trigger is for switch scanning // map the analog input channels AddAnalogInputChannel("pmt", daqBoard + "/ai1", AITerminalConfiguration.Nrse); AddAnalogInputChannel("norm", daqBoard + "/ai0", AITerminalConfiguration.Nrse); AddAnalogInputChannel("iodine", daqBoard + "/ai2", AITerminalConfiguration.Nrse); AddAnalogInputChannel("cavity", daqBoard + "/ai3", AITerminalConfiguration.Nrse); AddAnalogInputChannel("master", TCLBoard + "/ai1", AITerminalConfiguration.Rse); AddAnalogInputChannel("p1", TCLBoard + "/ai3", AITerminalConfiguration.Rse); AddAnalogInputChannel("cavityRampMonitor", TCLBoard + "/ai2", AITerminalConfiguration.Rse); AddAnalogInputChannel("p4", TCLBoard + "/ai0", AITerminalConfiguration.Rse); AddAnalogInputChannel("p2", TCLBoard + "/ai5", AITerminalConfiguration.Rse); // map the analog output channels AddAnalogOutputChannel("laser", TCLBoard + "/ao0"); AddAnalogOutputChannel("laser4", TCLBoard + "/ao1"); AddAnalogOutputChannel("laser2", daqBoard + "/ao1"); AddAnalogOutputChannel("laser3", daqBoard + "/ao2"); AddAnalogOutputChannel("rampfb", daqBoard + "/ao0"); //Transfer Cavity Lock //AddAnalogOutputChannel("cavity", daqBoard + "/ao1"); //Info.Add("analogTrigger2", (string)Boards["daq"] + "/PFI0"); //Info.Add("analogTrigger3", (string)Boards["daq"] + "/PFI3"); //AddDigitalOutputChannel("scanTrigger", daqBoard, 0, 6); //AddAnalogInputChannel("slavepd", daqBoard + "/ai4", AITerminalConfiguration.Nrse); //AddAnalogInputChannel("masterpd", daqBoard + "/ai5", AITerminalConfiguration.Nrse); // map the counter channels //AddCounterChannel("phaseLockOscillator", daqBoard + "/ctr7"); //AddCounterChannel("phaseLockReference", daqBoard + "/pfi10"); //AddCounterChannel("northLeakage", counterBoard + "/ctr0"); //AddCounterChannel("southLeakage", counterBoard + "/ctr1"); }
public SympatheticHardware() { // YAG laser yag = new QuantaRayLaser(); // add the boards Boards.Add("daq", "/dev2"); Boards.Add("pg", "/dev1"); Boards.Add("usbDAQ2", "/dev3"); Boards.Add("TCLAIBoard", "/dev4"); //Boards.Add("usbDAQ1", "/dev4"); string pgBoard = (string)Boards["pg"]; string daqBoard = (string)Boards["daq"]; string usbDAQ1 = (string)Boards["usbDAQ1"]; string usbDAQ2 = (string)Boards["usbDAQ2"]; string TCLBoard = (string)Boards["TCLAIBoard"]; // add things to the info Info.Add("PGClockLine", Boards["pg"] + "/PFI2"); Info.Add("PatternGeneratorBoard", pgBoard); Info.Add("PGType", "dedicated"); // the analog triggers Info.Add("analogTrigger0", (string)Boards["daq"] + "/PFI0"); //DAQ Pin 11 Info.Add("analogTrigger1", (string)Boards["daq"] + "/PFI1"); //DAQ Pin 10 //Info.Add("analogTrigger2", (string)Boards["daq"] + "/PFI5"); //DAQ Pin 6 //Info.Add("analogTrigger2", (string)Boards["usbDAQ2"] + "/PFI0"); Info.Add("analogTrigger2", TCLBoard + "/PFI0"); //Info.Add("analogTrigger2", (string)Boards["daq"] + "/PFI1"); //DAQ Pin 10 //distance information Info.Add("sourceToDetect", 0.787); Info.Add("sourceToSoftwareDecelerator", 0.123); //information about the molecule Info.Add("moleculeMass", 8.024); //this is 7LiH in amu Info.Add("moleculeRotationalConstant", 2.22545E11); //in Hz Info.Add("moleculeDipoleMoment", 29600.0); //in Hz/(V/m) //information about the decelerator Info.Add("deceleratorStructure", DecelerationConfig.DecelerationExperiment.SwitchStructure.H_V); //Horizontal first Info.Add("deceleratorLensSpacing", 0.006); Info.Add("deceleratorFieldMap", "RodLayout3_EonAxis.dat"); Info.Add("mapPoints", 121); Info.Add("mapStartPoint", 0.0); Info.Add("mapResolution", 0.0001); // TCL configuration TCLConfig tcl1 = new TCLConfig("Hamish McCavity"); tcl1.AddLaser("laser", "p1"); tcl1.Trigger = TCLBoard + "/PFI0"; tcl1.Cavity = "cavity"; tcl1.MasterLaser = "master"; tcl1.Ramp = "rampfb"; tcl1.TCPChannel = 1190; Info.Add("Hamish", tcl1); Info.Add("DefaultCavity", tcl1); //TCL Lockable lasers - I'm not yet sure whether these settings are redundant for the SympatheticHardware - may be using an old version of TransferCavityLock?? Info.Add("TCLLockableLasers", new string[] { "laser" }); Info.Add("TCLPhotodiodes", new string[] { "cavity", "master", "p1" });// THE FIRST TWO MUST BE CAVITY AND MASTER PHOTODIODE!!!! Info.Add("TCL_Slave_Voltage_Limit_Upper", 10.0); //volts: Laser control Info.Add("TCL_Slave_Voltage_Limit_Lower", -10.0); //volts: Laser control Info.Add("TCL_Default_Gain", 0.5); Info.Add("TCL_Default_VoltageToLaser", 0.0); Info.Add("TCL_MAX_INPUT_VOLTAGE", 10.0); // map the GPIB instruments Instruments.Add("microwave", new EIP578Synth("GPIB0::19::INSTR")); Instruments.Add("agilent", new Agilent33250Synth("GPIB0::10::INSTR")); Instruments.Add("gigatronics", new Gigatronics7100Synth("GPIB0::6::INSTR")); // map the digital channels // these channels are to be part of the "PatternList" and shoud all be on the low half of the board AddDigitalOutputChannel("valve", pgBoard, 0, 0); //Pin 10 AddDigitalOutputChannel("flash", pgBoard, 0, 1); //Pin 44 AddDigitalOutputChannel("valve2", pgBoard, 0, 1); AddDigitalOutputChannel("discharge", pgBoard, 0, 3); AddDigitalOutputChannel("q", pgBoard, 0,2 ); //Pin 45 AddDigitalOutputChannel("detector", pgBoard, 0,7); //Pin 15 AddDigitalOutputChannel("detectorprime", pgBoard, 1, 7); //Pin 22 // AddDigitalOutputChannel("fig", pgBoard, 3, 1); //Pin 63 AddDigitalOutputChannel("aom", pgBoard, 0, 4); //Pin 13 AddDigitalOutputChannel("flash2", pgBoard, 0, 5); //Pin 47 AddDigitalOutputChannel("q2", pgBoard, 0, 6); //Pin 48 AddDigitalOutputChannel("cavityTriggerOut", usbDAQ2, 0, 1); //Pin 17 // the following are the decelerator channels for the burst AddDigitalOutputChannel("decelhplus", pgBoard, 1, 0); //Pin 16 AddDigitalOutputChannel("decelhminus", pgBoard, 1, 1); //Pin 17 AddDigitalOutputChannel("decelvplus", pgBoard, 1, 2); //Pin 51 AddDigitalOutputChannel("decelvminus", pgBoard, 1, 3); //Pin 52 AddDigitalOutputChannel("SynthTrigger", pgBoard, 0, 3); //Pin 48 // these channels are to be switched "manually" and should all be on the high half of the board // the following set of switches are used to enable or disable the burst AddDigitalOutputChannel("hplusBurstEnable", pgBoard, 2, 0); AddDigitalOutputChannel("hminusBurstEnable", pgBoard, 3, 4); AddDigitalOutputChannel("vplusBurstEnable", pgBoard, 2, 2); AddDigitalOutputChannel("vminusBurstEnable", pgBoard, 2, 3); // the following set of switches are used for dc on or off AddDigitalOutputChannel("hplusdc", pgBoard, 2, 4); AddDigitalOutputChannel("hminusdc", pgBoard, 2, 5); AddDigitalOutputChannel("vplusdc", pgBoard, 2, 6); AddDigitalOutputChannel("vminusdc", pgBoard, 3, 3); // map the analog input channels AddAnalogInputChannel("pmt", daqBoard + "/ai0", AITerminalConfiguration.Rse); //Pin 68 //AddAnalogInputChannel("p1", daqBoard + "/ai7", AITerminalConfiguration.Rse);//Pin 57 //AddAnalogInputChannel("p2", daqBoard + "/ai14", AITerminalConfiguration.Rse);//Pin 58 //AddAnalogInputChannel("cavityVoltageRead", daqBoard + "/ai12", AITerminalConfiguration.Rse); //Pin 61 //AddAnalogInputChannel("p1", usbDAQ2 + "/ai0", AITerminalConfiguration.Rse);//Pin 2 //AddAnalogInputChannel("p2", usbDAQ2 + "/ai1", AITerminalConfiguration.Rse);//Pin 5 //AddAnalogInputChannel("cavityVoltageRead", usbDAQ2 + "/ai2", AITerminalConfiguration.Rse); //Pin 8 AddAnalogInputChannel("p1", TCLBoard + "/ai0", AITerminalConfiguration.Rse);//Pin 2 AddAnalogInputChannel("p2", TCLBoard + "/ai1", AITerminalConfiguration.Rse);//Pin 5 AddAnalogInputChannel("cavityVoltageRead", TCLBoard + "/ai2", AITerminalConfiguration.Rse); //Pin 8 AddAnalogInputChannel("lockcavity", daqBoard + "/ai1", AITerminalConfiguration.Rse); //Pin 33 AddAnalogInputChannel("probepower", daqBoard + "/ai9", AITerminalConfiguration.Rse); //Pin 66 //AddAnalogInputChannel("refcavity", daqBoard + "/ai2", AITerminalConfiguration.Rse); //Pin 65 AddAnalogInputChannel("pressureP1", daqBoard + "/ai2", AITerminalConfiguration.Rse); //Pin 65 AddAnalogInputChannel("fig", daqBoard + "/ai5", AITerminalConfiguration.Rse); //Pin 60 AddAnalogInputChannel("atomSourcePressure1", usbDAQ1 + "/ai0", AITerminalConfiguration.Differential); //ai0+ is pin 2, ai0- is pin 3 AddAnalogInputChannel("atomSourcePressure2", usbDAQ1 + "/ai1", AITerminalConfiguration.Differential); //ai1+ is pin 5, ai1- is pin 6 //map the analog output channels AddAnalogOutputChannel("laser", daqBoard + "/ao0"); // Pin 22 // AddAnalogOutputChannel("dyelaser", daqBoard + "/ao1",-5,5); // Pin 21 AddAnalogOutputChannel("highvoltage", daqBoard + "/ao1"); // Note - this is just here because a channel called "highvoltage" has been hard-wired into DecelerationHardwareControl - this needs to be rectified AddAnalogOutputChannel("cavity", daqBoard + "/ao1"); // Pin 21 //AddAnalogOutputChannel("cavity", usbDAQ2 + "/ao0"); // Pin 14 // map the counter channels AddCounterChannel("pmt", daqBoard + "/ctr0"); //Source is pin 37, gate is pin 3, out is pin 2 AddCounterChannel("sample clock", daqBoard + "/ctr1"); //Source is pin 42, gate is pin 41, out is pin 40 }