FSUDAQ/DigitizerClass.cpp

#include "DigitizerClass.h"

Digitizer::Digitizer(){

  portID = -1;
  boardID = -1;
  handle = -1;
  NChannel = 0;
  ADCbits  = 1;
  DPPType = 0;
  ADCFullSize = 0;
  ch2ns = 0; 
  BoardInfo = {};

  VMEBaseAddress = 0;
  LinkType = CAEN_DGTZ_USB;      /// default USB
  IOlev = CAEN_DGTZ_IOLevel_NIM; ///default NIM  
  AcqMode  = CAEN_DGTZ_DPP_ACQ_MODE_List; ///default list mode 
  
  channelMask = 0xFFFF;
  
  data = new Data();
  
  ret = -1;
  isConnected = false; 

}

Digitizer::Digitizer(int boardID, int portID){
  Digitizer();
  OpenDigitizer(boardID, portID);
}

Digitizer::~Digitizer(){
  CloseDigitizer();
  
  delete data;
}

void Digitizer::Reset(){
  ret = CAEN_DGTZ_Reset(handle);
  if( ret != 0 ) ErrorMsg("Reset");
}

int Digitizer::OpenDigitizer(int boardID, int portID, bool verbose){
  
  this->boardID = boardID;
  this->portID = portID;
    
  /***************************************************/
  /** Open the digitizer and read board information  */
  /***************************************************/

  if( verbose) printf("============= Opening Digitizer at Board %d, Port %d \n", boardID, portID);
  
  ///-------- try USB first
  LinkType = CAEN_DGTZ_USB;     /// Link Type
  ret = (int) CAEN_DGTZ_OpenDigitizer(LinkType, boardID, 0, VMEBaseAddress, &handle);
  if (ret != 0){ ///---------- try Optical link
    LinkType = CAEN_DGTZ_OpticalLink ; 
    ret = (int) CAEN_DGTZ_OpenDigitizer(LinkType, portID, boardID, VMEBaseAddress, &handle);
  }
  
  if (ret != 0) {
    if( verbose) printf("Can't open digitizer\n");
    return -1;
  }else{
    ///----- Getting Board Info
    ret = (int) CAEN_DGTZ_GetInfo(handle, &BoardInfo);
    if (ret != 0) {
      if( verbose) printf("Can't read board info\n");
    }else{
      isConnected = true;
      NChannel = BoardInfo.Channels;
      channelMask = pow(2, NChannel)-1;
      switch(BoardInfo.Model){
            case CAEN_DGTZ_V1730: ch2ns = 2.0; break; ///ns -> 500 MSamples/s
            case CAEN_DGTZ_V1725: ch2ns = 4.0; break; ///ns -> 250 MSamples/s
      }
      ADCbits = BoardInfo.ADC_NBits;
      ADCFullSize = (unsigned int)( pow(2, ADCbits) -1 );
      
      if( verbose) {      
        printf("Connected to Model %s with handle %d using %s\n", BoardInfo.ModelName, handle, LinkType == CAEN_DGTZ_USB ? "USB" : "Optical Link");
        printf("Sampling rate : %.0f MHz = %.1f ns \n", 1000/ch2ns, ch2ns);
        printf("Number of Channels : %d = 0x%X\n", NChannel, channelMask);
        printf("SerialNumber :\e[1m\e[33m %d\e[0m\n", BoardInfo.SerialNumber);
        printf("ADC bit is \e[33m%d\e[0m, %d = 0x%x\n", ADCbits, ADCFullSize, ADCFullSize);
        printf("ROC FPGA Release is %s\n", BoardInfo.ROC_FirmwareRel);
        printf("AMC FPGA Release is %s\n", BoardInfo.AMC_FirmwareRel);
      }
      int DPPType;
      sscanf(BoardInfo.AMC_FirmwareRel, "%d", &DPPType);
      if (DPPType != V1730_DPP_PHA_CODE) {
        if( verbose) printf("This digitizer does not have DPP-PHA firmware\n");
      }
    }
  }

  // Check firmware revision (DPP firmwares cannot be used with this demo */
  sscanf(BoardInfo.AMC_FirmwareRel, "%d", &DPPType);
  if (DPPType >= 128 && verbose) {
    printf("\t==== This digitizer has a DPP firmware!\n");
    printf("\e[32m");
    switch (DPPType){
      case 0x80: printf("\tDPP-PHA for x724 boards \n"); break;
      case 0x82: printf("\tDPP-CI for x720 boards  \n"); break;
      case 0x83: printf("\tDPP-PSD for x720 boards \n"); break;
      case 0x84: printf("\tDPP-PSD for x751 boards \n"); break;
      case 0x85: printf("\tDPP-ZLE for x751 boards \n"); break;
      case 0x86: printf("\tDPP-PSD for x743 boards \n"); break;
      case 0x87: printf("\tDPP-QDC for x740 boards \n"); break;
      case 0x88: printf("\tDPP-PSD for x730 boards \n"); break;
      case 0x8B: printf("\tDPP-PHA for x730 boards \n"); break;
      case 0x8C: printf("\tDPP-ZLE for x730 boards \n"); break;
      case 0x8D: printf("\tDPP-DAW for x730 boards \n"); break;
    }
    printf("\e[0m");
  }
    
  int probes[MAX_SUPPORTED_PROBES];
  int numProbes;
  ret = CAEN_DGTZ_GetDPP_SupportedVirtualProbes(handle, 1, probes, &numProbes);
  if( verbose ){
    printf("\t==== supported virtual probe (number of Probe : %d)\n", numProbes);
    for( int i = 0 ; i < numProbes; i++){
      switch (probes[i]){
         case  0: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_Input\n"); break;
         case  1: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_Delta\n"); break;
         case  2: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_Delta2\n"); break;
         case  3: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_Trapezoid\n"); break;
         case  4: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_TrapezoidReduced\n"); break;
         case  5: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_Baseline\n"); break;
         case  6: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_Threshold\n"); break;
         case  7: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_CFD\n"); break;
         case  8: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_SmoothedInput\n"); break;
         case  9: printf("\t\t CAEN_DGTZ_DPP_VIRTUALPROBE_None\n"); break;
         case 10: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_TRGWin\n"); break;
         case 11: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_Armed\n"); break;
         case 12: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_PkRun\n"); break;
         case 13: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_Peaking\n"); break;
         case 14: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_CoincWin\n"); break;
         case 15: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_BLHoldoff\n"); break;
         case 16: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_TRGHoldoff\n"); break;
         case 17: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_TRGVal\n"); break;
         case 18: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_ACQVeto\n"); break;
         case 19: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_BFMVeto\n"); break;
         case 20: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_ExtTRG\n"); break;
         case 21: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_OverThr\n"); break;
         case 22: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_TRGOut\n"); break;
         case 23: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_Coincidence \n"); break;
         case 24: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_PileUp \n"); break;
         case 25: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_Gate \n");  break;
         case 26: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_GateShort \n"); break;
         case 27: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_Trigger \n"); break;
         case 28: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_None  \n"); break;
         case 29: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_BLFreeze  \n"); break;
         case 30: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_Busy  \n"); break;
         case 31: printf("\t\t CAEN_DGTZ_DPP_DIGITALPROBE_PrgVeto \n"); break;
      }  
    }
  }
  
  ErrorMsg("end of OpenDigitizer");
  
  if( isConnected ) {
    ProgramBoard();
  }
  
  return ret;
}

int Digitizer::CloseDigitizer(){

  if( !isConnected ) return 0;
  isConnected = false;
  printf("-------- Closing Digtizer Board : %d Port : %d \n", boardID, portID);
  printf("  Model %s with handle %d using %s\n", BoardInfo.ModelName, handle, LinkType == CAEN_DGTZ_USB ? "USB" : "Optical Link");
  ret  = CAEN_DGTZ_SWStopAcquisition(handle);
  ret |= CAEN_DGTZ_CloseDigitizer(handle);
  
  return ret;
}

void Digitizer::ErrorMsg(string header){
  switch (ret){
    ///case CAEN_DGTZ_Success                 : /**   0 */ printf("%s | Operation completed successfully.\n", header.c_str()); break;
    case CAEN_DGTZ_CommError               : /**  -1 */ printf("%s | Communication Error.\n", header.c_str()); break;
    case CAEN_DGTZ_GenericError            : /**  -2 */ printf("%s | Unspecified error.\n", header.c_str()); break;
    case CAEN_DGTZ_InvalidParam            : /**  -3 */ printf("%s | Invalid parameter.\n", header.c_str()); break;
    case CAEN_DGTZ_InvalidLinkType         : /**  -4 */ printf("%s | Invalid Link Type.\n", header.c_str()); break;
    case CAEN_DGTZ_InvalidHandle           : /**  -5 */ printf("%s | Invalid device handler.\n", header.c_str()); break;
    case CAEN_DGTZ_MaxDevicesError         : /**  -6 */ printf("%s | Maximum number of devices exceeded.\n", header.c_str()); break;
    case CAEN_DGTZ_BadBoardType            : /**  -7 */ printf("%s | Operation not allowed on this type of board.\n", header.c_str()); break;
    case CAEN_DGTZ_BadInterruptLev         : /**  -8 */ printf("%s | The interrupt level is not allowed.\n", header.c_str()); break;
    case CAEN_DGTZ_BadEventNumber          : /**  -9 */ printf("%s | The event number is bad.\n", header.c_str()); break;
    case CAEN_DGTZ_ReadDeviceRegisterFail  : /** -10 */ printf("%s | Unable to read the registry.\n", header.c_str()); break;
    case CAEN_DGTZ_WriteDeviceRegisterFail : /** -11 */ printf("%s | Unable to write the registry.\n", header.c_str()); break;
    case CAEN_DGTZ_InvalidChannelNumber    : /** -13 */ printf("%s | The channel number is invalid.\n", header.c_str()); break;
    case CAEN_DGTZ_ChannelBusy             : /** -14 */ printf("%s | The channel is busy.\n", header.c_str()); break;
    case CAEN_DGTZ_FPIOModeInvalid         : /** -15 */ printf("%s | Invalid FPIO mode.\n", header.c_str()); break;
    case CAEN_DGTZ_WrongAcqMode            : /** -16 */ printf("%s | Wrong Acquistion mode.\n", header.c_str()); break;
    case CAEN_DGTZ_FunctionNotAllowed      : /** -17 */ printf("%s | This function is not allowed on this module.\n", header.c_str()); break;
    case CAEN_DGTZ_Timeout                 : /** -18 */ printf("%s | Communication Timeout.\n", header.c_str()); break;
    case CAEN_DGTZ_InvalidBuffer           : /** -19 */ printf("%s | The buffer is invalid.\n", header.c_str()); break;
    case CAEN_DGTZ_EventNotFound           : /** -20 */ printf("%s | The event is not found.\n", header.c_str()); break;
    case CAEN_DGTZ_InvalidEvent            : /** -21 */ printf("%s | The event is invalid.\n", header.c_str()); break;
    case CAEN_DGTZ_OutOfMemory             : /** -22 */ printf("%s | Out of memory.\n", header.c_str()); break;
    case CAEN_DGTZ_CalibrationError        : /** -23 */ printf("%s | Unable to calibrate the board.\n", header.c_str()); break;
    case CAEN_DGTZ_DigitizerNotFound       : /** -24 */ printf("%s | Unbale to open the digitizer.\n", header.c_str()); break;
    case CAEN_DGTZ_DigitizerAlreadyOpen    : /** -25 */ printf("%s | The digitizer is already open.\n", header.c_str()); break;
    case CAEN_DGTZ_DigitizerNotReady       : /** -26 */ printf("%s | The digitizer is not ready.\n", header.c_str()); break;
    case CAEN_DGTZ_InterruptNotConfigured  : /** -27 */ printf("%s | The digitizer has no IRQ configured.\n", header.c_str()); break;
    case CAEN_DGTZ_DigitizerMemoryCorrupted: /** -28 */ printf("%s | The digitizer flash memory is corrupted.\n", header.c_str()); break;
    case CAEN_DGTZ_DPPFirmwareNotSupported : /** -29 */ printf("%s | The digitier DPP firmware is not supported in this lib version.\n", header.c_str()); break;
    case CAEN_DGTZ_InvalidLicense          : /** -30 */ printf("%s | Invalid firmware licence.\n", header.c_str()); break;
    case CAEN_DGTZ_InvalidDigitizerStatus  : /** -31 */ printf("%s | The digitizer is found in a corrupted status.\n", header.c_str()); break;
    case CAEN_DGTZ_UnsupportedTrace        : /** -32 */ printf("%s | The given trace is not supported.\n", header.c_str()); break;
    case CAEN_DGTZ_InvalidProbe            : /** -33 */ printf("%s | The given probe is not supported.\n", header.c_str()); break;
    case CAEN_DGTZ_UnsupportedBaseAddress  : /** -34 */ printf("%s | The base address is not supported.\n", header.c_str()); break;
    case CAEN_DGTZ_NotYetImplemented       : /** -99 */ printf("%s | The function is not yet implemented.\n", header.c_str()); break;
  }
  
}

int Digitizer::ProgramBoard(){

  ret = CAEN_DGTZ_Reset(handle);
  if (ret) {
    printf("ERROR: can't reset the digitizer.\n");
    return -1;
  }
  
  /// Board Configuration without PHA or PSD fireware
  ///bx0000 0000 0000 0000 0000 0000 0001 0000  = 
  ///                                 |   | +- (1) trigger overlap not allowed
  ///                                 |   +- (3) test pattern disable  
  ///                                 + (6) Self-trigger polarity, 1 = negative, 0 = Positive
  ret = CAEN_DGTZ_WriteRegister(handle,  (uint32_t) Register::BoardConfiguration , 0x000E0114);  /// Channel Control Reg (indiv trg, seq readout) ??
  
  /// Set the I/O level (CAEN_DGTZ_IOLevel_NIM or CAEN_DGTZ_IOLevel_TTL)
  ret |= CAEN_DGTZ_SetIOLevel(handle, IOlev);

  /// Set the enabled channels
  ret |= CAEN_DGTZ_SetChannelEnableMask(handle, channelMask);

  /// Set the number of samples for each waveform
  SetRecordLength(2000); /// ns
  
  /// Set Extras 2 to enable, this override Accusition mode, focring list mode
  ret |= CAEN_DGTZ_WriteRegister(handle, Register::BoardConfiguration , 0x00E8114 );

  /// Set how many events to accumulate in the board memory before being available for readout
  SetEventAggregation(0); /// when zero, digitizer auto set

  /// Set the digitizer acquisition mode (CAEN_DGTZ_SW_CONTROLLED or CAEN_DGTZ_S_IN_CONTROLLED)
  ret |= CAEN_DGTZ_SetAcquisitionMode(handle, CAEN_DGTZ_SW_CONTROLLED); /// software command
  ret |= CAEN_DGTZ_SetDPPAcquisitionMode(handle, AcqMode, CAEN_DGTZ_DPP_SAVE_PARAM_EnergyAndTime);

  /** Set the digitizer's behaviour when an external trigger arrives:
  CAEN_DGTZ_TRGMODE_DISABLED: do nothing
  CAEN_DGTZ_TRGMODE_EXTOUT_ONLY: generate the Trigger Output signal
  CAEN_DGTZ_TRGMODE_ACQ_ONLY = generate acquisition trigger
  CAEN_DGTZ_TRGMODE_ACQ_AND_EXTOUT = generate both Trigger Output and acquisition trigger
  see CAENDigitizer user manual, chapter "Trigger configuration" for details */
  ret |= CAEN_DGTZ_SetExtTriggerInputMode(handle, CAEN_DGTZ_TRGMODE_ACQ_ONLY);

  /** Set the mode used to syncronize the acquisition between different boards.
  In this example the sync is disabled */
  ret |= CAEN_DGTZ_SetRunSynchronizationMode(handle, CAEN_DGTZ_RUN_SYNC_Disabled);

  ErrorMsg("End of ProgramBoard");
  return ret;

}

//===========================================================
void Digitizer::WriteRegister(uint32_t address, uint32_t value, int ch ){
  if( ch < 0 ) {
    ret = CAEN_DGTZ_WriteRegister(handle, address + 0x7000, value);
  }else{
    ret = CAEN_DGTZ_WriteRegister(handle, address +  (ch<<8), value);
  }
  ErrorMsg("WriteRegister");
}

uint32_t Digitizer::ReadRegister(uint32_t address, unsigned int ch, string str ){
  uint32_t * Data = new uint32_t[NChannel];
  if( ch < 0 ) {
    ret = CAEN_DGTZ_ReadRegister(handle, address + 0x7000, Data);
  }else{
    ret = CAEN_DGTZ_ReadRegister(handle, address + (ch << 8), Data);
  }
  ErrorMsg("ReadRegister");
  if( str != "" ) printf("%s : 0x%x \n", str.c_str(), Data[0]);
  return Data[0];
}

void Digitizer::SetChannelMask(uint32_t mask){
  channelMask = mask;
  ret |= CAEN_DGTZ_SetChannelEnableMask(handle, channelMask);
  ErrorMsg("SetChannelMask");
}

void Digitizer::SetRecordLength(unsigned int ns, int ch)                        { WriteRegister( Register::DPP::RecordLength_G,     ns / ch2ns / 8 , ch); ErrorMsg("SetRecordLength"); }
void Digitizer::SetEventAggregation(unsigned int numEvent, int ch)              { WriteRegister( Register::DPP::NumberEventsPerAggregate_G,numEvent, ch); ErrorMsg("SetEventAggregation"); }
void Digitizer::SetInputDynamicRange(unsigned int TwoVol_0_or_halfVol_1, int ch){ WriteRegister( Register::InputDynamicRange, TwoVol_0_or_halfVol_1, ch); ErrorMsg("SetInputDynamicRange");}
void Digitizer::SetPreTriggerSample(unsigned int nSample, int ch)               { WriteRegister( Register::DPP::PreTrigger,             nSample / 4, ch); ErrorMsg("SetPreTriggerSample");}
void Digitizer::SetPreTriggerDuration(unsigned int ns, int ch)                  { WriteRegister( Register::DPP::PreTrigger,          ns / ch2ns / 4, ch); ErrorMsg("SetPreTriggerSample");}
void Digitizer::SetDCOffset(float offsetPrecentage, int ch)                     { WriteRegister( Register::DPP::ChannelDCOffset, uint( ADCFullSize * offsetPrecentage), ch ); ErrorMsg("SetDCOffset");}
void Digitizer::SetVetoWidth(uint32_t bit, int ch)                              { WriteRegister( Register::DPP::VetoWidth,                      bit, ch); ErrorMsg("SetVetoWidth");}

void Digitizer::SetTriggerPolarity(bool RiseingIsZero, int ch ){
  if ( DPPType >= 128 ) return; /// do thing for DPP firmware
  if( ch < 0 ) {
    ret = 0;
    for (int i = 0; i < NChannel; i++){
      ret |= CAEN_DGTZ_SetTriggerPolarity(handle, i, CAEN_DGTZ_TriggerPolarity_t(RiseingIsZero));  
    }
  }else{
    ret = CAEN_DGTZ_SetTriggerPolarity(handle, ch, CAEN_DGTZ_TriggerPolarity_t(RiseingIsZero));
  }
  if( ret != 0 ) ErrorMsg("SetTriggerPolarity");
}

//============================== DPP-Alpgorthm Control 
void Digitizer::SetDPPAlgorithmControl(uint32_t bit, int ch){
  ///============= DPP algorithm control is 32 bit 
  ///   [ 0: 5] Trapazoid Rescaling. the trapazoid ADC is 48 bit. it need to bit-shift before the 0x3FFF (14 bit filter)
  ///   [ 8: 9] Decimation. 00 = disable, 01 = 2 samples, 10 = 4 samples, 11 = 8 sample
  ///   [10:11] Decimation Gain. This gain apply to the Trapazoid Rescaling and fine gain
  ///   [12:13] Peak Mean. sample for averaging the trapezoid height calculation. 00 = 1 sample, 01 = 4 samples, 10 = 16 sample, 11 = 64 sample
  ///   [16]    pulse polarity. 0 = positve, 1 = negative
  ///   [18:19] Trigger mode. 00 = normal, 01 = coincident, 10 = reserved. 11 = anti coincident
  ///   [20:22] number of samples for the baseline average calculation. 000 = baseline disable (energy not subtraced with baseline)
  ///                                                                   001 =    16 samples  
  ///                                                                   010 =    64 samples  
  ///                                                                   011 =   256 samples  
  ///                                                                   100 =  1024 samples  
  ///                                                                   101 =  4096 samples  
  ///                                                                   110 = 16384 samples  
  ///                                                                   111 = resertved.
  ///    [24]    Disable self trigger. 0 = self‐trigger used to acquire and propagated to the trigger logic;
  ///                                  1 = self‐trigger only propagated to the trigger logic.
  ///    [26]    Enable Roll-Over flag. see manual 0 = disable, 1 = enable
  ///    [27]    Enable pile-up flag.
  
  ///============= PHA - DPP algorithm control 2 is 32 bit 
  ///   [ 0: 1] Local Shaped Trigger mode. see manual
  ///   [ 2]    Enable Local Shaped Trigger
  ///   [ 4: 5] Local Trigger Validation mode, see manual
  ///   [ 6]    Enable Local Trigger Validation
  ///   [ 8:10] Extra 2 word option. 000 = [0:15] baseline *4 [16:31] extended time stamp
  ///                                001 = reserved
  ///                                010 = [0:15] fine time stamp [16:31] extended time stamp
  ///                                011 = reserved
  ///                                100 = [0:15] total tigger counter [16:31] Lost trigger counter
  ///                                101 = [0:15] event after the zero crosiing [16:31] event before zero crossing
  ///                                110, 111 = reserved.
  ///   [14:15] source of veto. 00 = disable, 01 veto is common to all channels, 10 = veto for coupled channels, 11 = veto comes from negative saturation
  ///   [16:17] Select the step for the trigger counter rate flag. see manual
  ///   [18]    baseline calculation is active also when the acquisition is not running. 0 = disbale, 1 = enable
  ///   [19]    Tag correlated events. see manual  0 = disbale, 1 = enable
  ///   [29]    Enable the optimization of the Baseline Restorer to avoid tails in the energy peaks.  0 = disbale, 1 = enable
  
  WriteRegister( Register::DPP::DPPAlgorithmControl, bit, ch);    
  if( ret != 0 ) ErrorMsg("SetDPPAlgorithmControl");
}

void Digitizer::SetBits(uint32_t address, unsigned int bitValue, unsigned int bitLength, unsigned int bitSmallestPos, int ch){
  uint32_t bit ;
  uint32_t bitmask = (uint(pow(2, bitLength)-1) << bitSmallestPos);
  if (ch < 0 ) ch = 0; /// take ch-0 
  bit = ReadRegister(address, ch);
  bit = (bit & ~bitmask) | (bitValue << bitSmallestPos);
  WriteRegister(address, bit, ch);
  if( ret != 0 ) ErrorMsg("SetBits");  
}

int Digitizer::SetAcqMode(string list_mixed){
  
  if( list_mixed == "list"){
    AcqMode = CAEN_DGTZ_DPP_ACQ_MODE_List;           /// enables the acquisition of time stamps and energy value
  }else if ( list_mixed == "mixed"){
    AcqMode = CAEN_DGTZ_DPP_ACQ_MODE_Mixed;          /// enables the acquisition of both waveforms, energies, and timestamps.
  }else{
    printf("############ AcqMode must be either list or mixed\n");
    return -1;
  }
  
  int ret = 0;
  if( isConnected ){
    /********************* Set the DPP acquisition mode
    This setting affects the modes Mixed and List (see CAEN_DGTZ_DPP_AcqMode_t definition for details)
    CAEN_DGTZ_DPP_SAVE_PARAM_EnergyOnly        Only energy (DPP-PHA) or charge (DPP-PSD/DPP-CI v2) is returned
    CAEN_DGTZ_DPP_SAVE_PARAM_TimeOnly        Only time is returned
    CAEN_DGTZ_DPP_SAVE_PARAM_EnergyAndTime    Both energy/charge and time are returned
    CAEN_DGTZ_DPP_SAVE_PARAM_None            No histogram data is returned */

    if( AcqMode ==  CAEN_DGTZ_DPP_ACQ_MODE_List){
      ret = CAEN_DGTZ_SetDPPAcquisitionMode(handle, AcqMode, CAEN_DGTZ_DPP_SAVE_PARAM_EnergyAndTime);
    }
    
    if( AcqMode == CAEN_DGTZ_DPP_ACQ_MODE_Mixed ){
      ///ret = CAEN_DGTZ_SetDPPAcquisitionMode(handle, AcqMode, CAEN_DGTZ_DPP_SAVE_PARAM_TimeOnly);
      ret = CAEN_DGTZ_SetDPPAcquisitionMode(handle, AcqMode, CAEN_DGTZ_DPP_SAVE_PARAM_EnergyAndTime);
    }
    
    if( ret == 0 ) {
      printf("Setting digitizer to \e[33m%s\e[0m mode.\n", list_mixed.c_str());
    }else{
      ErrorMsg("Set AcqMode");
    }
  }
  return ret;
}


int Digitizer::GetChTemperature(int ch){
  
  if( BoardInfo.Model != CAEN_DGTZ_V1730 &&
      BoardInfo.Model != CAEN_DGTZ_V1725 &&
      BoardInfo.Model != CAEN_DGTZ_V1751 ) return -404;
  
  uint32_t * temp;
  ret |= CAEN_DGTZ_ReadTemperature(handle, ch, temp);
  if( ret != 0 ) ErrorMsg("GetChTemperature");
  return temp[0];
}