Exemplo n.º 1
0
/* Function: mdlTerminate =====================================================
 * Abstract:
 *    In this function, you should perform any actions that are necessary
 *    at the termination of a simulation.  For example, if memory was
 *    allocated in mdlStart, this is the place to free it.
 */
static void mdlTerminate(SimStruct *S)
{
    //Move stepper to zero, disconnect lidar and stepper
    stepperMove(0, stepper);
    urg_disconnect(&urg);
    stepperDisconnect(stepper);
}
/* Function: mdlTerminate =====================================================
 * Abstract:
 *    In this function, you should perform any actions that are necessary
 *    at the termination of a simulation.  For example, if memory was
 *    allocated in mdlStart, this is the place to free it.
 */
static void mdlTerminate(SimStruct *S) {
    //Move stepper to zero, disconnect lidar and stepper
    stepperMove(0, stepper);
    urg_disconnect(&urg);
    stepperDisconnect(stepper);
    //Disconnect From Target Camera
    cvReleaseCapture( &capture1 );
}
Exemplo n.º 3
0
/**
"SM" — Stepper Move

Command: SM,duration,axis1[,axis2]<CR>
Response: OK<NL><CR>
Firmware versions: all (with changes)
Execution: Added to FIFO motion queue
Arguments:
duration is an integer in the range from 1 to 16777215, giving time in
milliseconds.
axis1 and axis2 are integers, each in the range from -16777215 to 16777215,
giving movement distance in steps.
Description:
Use this command to make the motors draw a straight line at constant velocity,
or to add a delay to the motion queue.

If both axis1 and axis2 are zero, then a delay of duration ms is executed. axis2
is an optional value, and if it is not included in the command, zero steps are
assumed for axis 2.

The sign of axis1 and axis2 represent the direction each motor should turn.

The minimum speed at which the EBB can generate steps for each motor is 1.31
steps/second. The maximum speed is 25,000 steps/second. If the SM command finds
that this speed range will be violated on either axis, it will output an error
message declaring such and it will not complete the move.

Note that internally the EBB generates an Interrupt Service Routine (ISR) at the
25 kHz rate. Each time the ISR fires, the EBB determines if a step needs to be
taken for a given axis or not. The practical result of this is that all steps
will be 'quantized' to the 25 kHz (40 μs) time intervals, and thus as the step
rate gets close to 25 kHz the 'correct' time between steps will not be
generated, but instead each step will land on a 40 μs tick in time. In almost
all cases normally used by the EBB, this doesn't make any difference because the
overall proper length for the entire move will be correct.

A value of 0 for duration is invalid and will be rejected.

The EBB firmware can sustain moves of 3ms of more continuously without any
inter-move gaps in time.

Example: SM,1000,250,-766\r Move axis1 by 250 steps and axis2 by -766 steps, in
1000 ms of duration.
*/
void EBBParser::parseSM(const char* arg1, const char* arg2, const char* arg3)
{
    if (arg1 == NULL || arg2 == NULL) {
        sendError();
        return;
    }
    sendAck();

    const int duration = atoi(arg1);
    const int axis1 = atoi(arg2);
    const int axis2 = (arg3 != NULL) ? atoi(arg3) : 0;

    stepperMove(duration, axis1, axis2);
}
Exemplo n.º 4
0
 /* Function: mdlStart =======================================================
  * Abstract:
  *    This function is called once at start of model execution. If you
  *    have states that should be initialized once, this is the place
  *    to do it.
  */
 static void mdlStart(SimStruct *S)
 {
   const real_T   *Upos  = (const real_T*) ssGetInputPortSignal(S,1);
   
   ret = urg_connect(&urg, device, 115200);
   if (ret < 0) {
       urg_exit(&urg, "urg_connect()");
   }
   else
       urg_setCaptureTimes(&urg, UrgInfinityTimes);
   
   CPhidgetStepper_create(&stepper);
   stepperConnect(600000, 1214,stepper);
   
   stepperMove(*Upos, stepper);
 }
Exemplo n.º 5
0
/* Function: mdlOutputs =======================================================
 *
*/
static void mdlOutputs(SimStruct *S, int_T tid)
{
    const int32_T   *potVal  = (const int32_T*) ssGetInputPortSignal(S,0);
    const real_T   *Speed  = (const real_T*) ssGetInputPortSignal(S,1);
    const real_T   *Upos  = (const real_T*) ssGetInputPortSignal(S,2);
    const real_T   *Dpos  = (const real_T*) ssGetInputPortSignal(S,3);
    real_T        *lidarData  = (real_T *)ssGetOutputPortRealSignal(S,0);
    
    //Request data
    urg_setCaptureTimes(&urg, 65);
    ret = urg_requestData(&urg, URG_MD, 0, 1080);
    if (ret < 0) {
        urg_exit(&urg, "urg_requestData()");
    }
    
    //Tell stepper to move to new position
    CPhidgetStepper_setTargetPosition(stepper, 0, *Dpos);
    
    for (j=0;j<65;j++) {       

      // Receive Data
      n = urg_receiveData(&urg, data, 1080);
      // Error, can't receive negative data points
        if (n < 0) {
            urg_exit(&urg, "urg_receiveData()");
	    // Disconnect Lidar 
    		urg_disconnect(&urg);
   
        } 

      // Data Received, Construct Partial Image 
        else{ 
          	for(k=0;k<1080;k++){ 
            	lidarData[(j*1080)+k] = data[k];  
          	}
        }
    }
    
    stepperMove(*Upos, stepper);

    //lidar_zero_test_Outputs_wrapper(potVal, Speed, Upos, Dpos, lidarData);
    
}
Exemplo n.º 6
0
 /* Function: mdlStart =======================================================
  * Abstract:
  *    This function is called once at start of model execution. If you
  *    have states that should be initialized once, this is the place
  *    to do it.
  */
 static void mdlStart(SimStruct *S)
 {
   const real_T   *Upos  = (const real_T*) ssGetInputPortSignal(S,1);
   const int32_T   *potVal  = (const int32_T*) ssGetInputPortSignal(S,0);
    
   
   ret = urg_connect(&urg, device, 115200);
   if (ret < 0) {
       urg_exit(&urg, "urg_connect()");
   }
   else
       urg_setCaptureTimes(&urg, UrgInfinityTimes);
   
   CPhidgetStepper_create(&stepper);
   stepperConnect(600000, 1214,stepper);
   
   //Zero prameters
   int zeroPos = 418;
   int dpot;
   int dstep;
   
   //Zero stepper on start
   if (zeroPos > *potVal) {
       zeroPos = 418;
   }
   if (zeroPos < *potVal) {
       zeroPos = 419;
   }
   
   
   printf("potVal:%d\n",*potVal);
   dpot = zeroPos - *potVal;
   printf("Dpot:%d\n",dpot);
   dstep = -1036/45*dpot;
   printf("Dstep:%d\n",dstep);
   //stepperMove(dstep, stepper);
   
   CPhidgetStepper_setCurrentPosition(stepper, 0, 0);
   stepperMove(*Upos, stepper);
   
   
   
 }
Exemplo n.º 7
0
/* Function: mdlTerminate =====================================================
 * Abstract:
 *    In this function, you should perform any actions that are necessary
 *    at the termination of a simulation.  For example, if memory was
 *    allocated in mdlStart, this is the place to free it.
 */
static void mdlTerminate(SimStruct *S)
{
    stepperMove(0, stepper);
    urg_disconnect(&urg);
    stepperDisconnect(stepper);
}
Exemplo n.º 8
0
/* Function: mdlOutputs =======================================================
 *
*/
static void mdlOutputs(SimStruct *S, int_T tid)
{
    const int32_T   *potVal  = (const int32_T*) ssGetInputPortSignal(S,0);
    const real_T   *Speed  = (const real_T*) ssGetInputPortSignal(S,1);
    const real_T   *Upos  = (const real_T*) ssGetInputPortSignal(S,2);
    const real_T   *Dpos  = (const real_T*) ssGetInputPortSignal(S,3);
    const real_T   *ScanNumber  = (const real_T*) ssGetInputPortSignal(S,4);
    real_T        *lidarData  = (real_T *)ssGetOutputPortRealSignal(S,0);
    real_T        *udOut  = (real_T *)ssGetOutputPortRealSignal(S,1);
    
    //Read number of scans
    int ScanNum = *ScanNumber;
    
    CPhidgetStepper_setVelocityLimit(stepper, 0, *Speed);
    
    //Variables required for zeroing
    //Calibrated for three turn pot
    int zeroPos = 517;
    int dpot;
    int dstep;
    
    //Pot reader may take a minute to initialize and will send zero
    //If this is the case do nothing
    if (*potVal == 0) {}
    // Otherwise scan
    else {
        
        //Zero stepper on first run
        //Account for differnces coming from different directions
        if (counter == 0) {
            
            if (zeroPos > *potVal) {
                zeroPos = 515;
            }
            if (zeroPos < *potVal) {
                zeroPos = 519;
            }
            
            //Find required steps and move to zero position
            printf("potVal:%d\n", *potVal);
            dpot = zeroPos - *potVal;
            printf("Dpot:%d\n", dpot);
            dstep = -1036/125*dpot;
            //If error occurs dstep may be very large
            //Limit dstep value to prevent damage to system
            if (dstep > 1600) {
                dstep = 1600;
            }
            if (dstep < -1600) {
                dstep = -1600;
            }
            printf("Dstep:%d\n", dstep);
            stepperMove(dstep, stepper);
            
            //Set current position to zero
            CPhidgetStepper_setCurrentPosition(stepper, 0, 0);
            //Move to Up position to begin scanning process
            stepperMove(*Upos, stepper);
            counter = 1;
        }
        
        //Request data
        urg_setCaptureTimes(&urg, ScanNum);
        ret = urg_requestData(&urg, URG_MD, 0, 1080);
        if (ret < 0) {
            urg_exit(&urg, "urg_requestData()");
        }
        
        //Tell stepper to move to new position
        if (counter == 1) {
            CPhidgetStepper_setTargetPosition(stepper, 0, *Dpos);
            counter = 2;
            *udOut = 0;
        }
        else if (counter == 2) {
            CPhidgetStepper_setTargetPosition(stepper, 0, *Upos);
            counter = 1;
            *udOut = 1;
        }
        
        for (j=0;j<ScanNum;j++) {
            
            // Receive Data
            n = urg_receiveData(&urg, data, 1080);
            // Error, can't receive negative data points
            if (n < 0) {
                urg_exit(&urg, "urg_receiveData()");
                // Disconnect Lidar
                urg_disconnect(&urg);
                
            }
            
            // Data Received, Construct Partial Image
            else{
                for(k=0;k<1080;k++){
                    lidarData[(j*1080)+k] = data[k];
                }
            }
        }
        
        //stepperMove(*Upos, stepper);
        
    }

    //lidar_zero_test_v4_Outputs_wrapper(potVal, Speed, Upos, Dpos, ScanNumber, lidarData, udOut);
}
Exemplo n.º 9
0
/* Function: mdlOutputs =======================================================
 *
*/
static void mdlOutputs(SimStruct *S, int_T tid)
{
    const int32_T   *potVal  = (const int32_T*) ssGetInputPortSignal(S,0);
    const real_T   *Speed  = (const real_T*) ssGetInputPortSignal(S,1);
    const real_T   *Upos  = (const real_T*) ssGetInputPortSignal(S,2);
    const real_T   *Dpos  = (const real_T*) ssGetInputPortSignal(S,3);
    const real_T   *ScanNumber  = (const real_T*) ssGetInputPortSignal(S,4);
    real_T        *lidarData  = (real_T *)ssGetOutputPortRealSignal(S,0);
    uint8_T        *Red  = (uint8_T *)ssGetOutputPortRealSignal(S,1);
    uint8_T        *Green  = (uint8_T *)ssGetOutputPortRealSignal(S,2);
    uint8_T        *Blue  = (uint8_T *)ssGetOutputPortRealSignal(S,3);
    real_T        *udOut  = (real_T *)ssGetOutputPortRealSignal(S,4);

      //Read number of scans
    int ScanNum = *ScanNumber;
    
    CPhidgetStepper_setVelocityLimit(stepper, 0, *Speed);
    
    //Parameters required for zeroing
    //Calibrated for three turn pot
    int zeroPos = 534; //Potentiometer reading at level position
    int stepRes = 3950; //Number of steps to move the stepper 180 degrees
    int potRes = 323; //Number of potValues that represent the rotation of the gimbal 180 degrees
    int potGive = 2; //Accounts for slack in gearing for pot
    
    //Variables required for zeroing
    int dpot; //difference to desired pot value from current
    int dstep; //number of steps the stepper must move to get to desired position
    
    //Pot reader may take a minute to initialize and will send zero
    //If this is the case do nothing
    if (*potVal != 0){
        //Zero stepper on first run
        //Account for differnces coming from different directions
        if (counter == 0) {
            
            //write pot value
            printf("potVal:%d\n", *potVal);
            
            //Find pot value difference to calculate steps needed to level
            if (zeroPos > *potVal) {
                dpot = zeroPos - potGive - *potVal;
            }
            if (zeroPos < *potVal) {
                dpot = zeroPos + potGive -*potVal;
            }
            //write difference
            printf("Dpot:%d\n", dpot);
            
            //Find required steps and move to level position
            dstep = -stepRes/potRes*dpot;
            
            //If error occurs dstep may be very large
            //Limit dstep value to prevent damage to system
            if (dstep > 1600) {
                dstep = 1600;
            }
            if (dstep < -1600) {
                dstep = -1600;
            }
            //write number of steps to zero
            printf("Dstep:%d\n", dstep);
            stepperMove(dstep, stepper);
            
            //Set current position to zero
            CPhidgetStepper_setCurrentPosition(stepper, 0, 0);
            //Move to Up position to begin scanning process
            stepperMove(*Upos, stepper);
            counter = 1;
        }
        
        //Request data
        urg_setCaptureTimes(&urg, ScanNum);
        ret = urg_requestData(&urg, URG_MD, 0, 1080);
        if (ret < 0) {
            urg_exit(&urg, "urg_requestData()");
        }
        
        //Tell stepper to move to new position
        if (counter == 1) {
            CPhidgetStepper_setTargetPosition(stepper, 0, *Dpos);
            counter = 2;
            *udOut = 0;
        }
        else if (counter == 2) {
            CPhidgetStepper_setTargetPosition(stepper, 0, *Upos);
            counter = 1;
            *udOut = 1;
        }
        
        for (j=0;j<ScanNum;j++) {
            
            // Receive Data
            n = urg_receiveData(&urg, data, 1080);
            // Error, can't receive negative data points
            if (n < 0) {
                urg_exit(&urg, "urg_receiveData()");
                // Disconnect Lidar
                urg_disconnect(&urg);
                
            }
            
            // Data Received, Construct Partial Image
            else{
                for(k=0;k<1080;k++){
                    lidarData[(j*1080)+k] = data[k];
                }
            }
        }
    }// END OF LIDAR DATA ACQ
    // START CAM ACQ
    // Grab a number of frames in order to flush the data buffer
    int flush1 = cvGrabFrame( capture1 );
    int flush2 = cvGrabFrame( capture1 );
    int flush3 = cvGrabFrame( capture1 );
    int flush4 = cvGrabFrame( capture1 );

    IplImage *frame1 = cvQueryFrame( capture1 ); //Gets Frame from Camera

    unsigned char *data1 = frame1->imageData;
    long iNew, jNew = 0, kNew = 0; 
    for(iNew = 0; iNew < 480*640*3; iNew+=3){
        //printf("data: %d, %d, %d \n",data[i],data[i+1], data[i+2]);
        Blue[jNew*480+kNew] = data1[iNew];
        Green[jNew*480+kNew] = data1[iNew+1];
        Red[jNew*480+kNew] = data1[iNew+2];
        jNew++;
        if(jNew==640){kNew++; jNew = 0;}
    }
}
/* Function: mdlOutputs =======================================================
 *
 */
static void mdlOutputs(SimStruct *S, int_T tid) {
    const int32_T   *choice  = (const int32_T*) ssGetInputPortSignal(S, 0);
    const int32_T   *potVal  = (const int32_T*) ssGetInputPortSignal(S, 1);
    const real_T   *Speed  = (const real_T*) ssGetInputPortSignal(S, 2);
    const real_T   *Upos  = (const real_T*) ssGetInputPortSignal(S, 3);
    const real_T   *Dpos  = (const real_T*) ssGetInputPortSignal(S, 4);
    const real_T   *ScanNumber  = (const real_T*) ssGetInputPortSignal(S, 5);
    real_T        *lidarData  = (real_T *)ssGetOutputPortRealSignal(S, 0);
    uint8_T        *Red  = (uint8_T *)ssGetOutputPortRealSignal(S, 1);
    uint8_T        *Green  = (uint8_T *)ssGetOutputPortRealSignal(S, 2);
    uint8_T        *Blue  = (uint8_T *)ssGetOutputPortRealSignal(S, 3);
    real_T        *udOut  = (real_T *)ssGetOutputPortRealSignal(S, 4);
    
    //Read number of scans
    int ScanNum = *ScanNumber;
    
    IplImage *frame1;
    
    CPhidgetStepper_setVelocityLimit(stepper, 0, *Speed);
    
    //Parameters required for zeroing
    //Calibrated for three turn pot
    int zeroPos = 483; //Potentiometer reading at level position
    int stepRes = 7328; //Number of steps to move the gimbal 180 degrees
    int potRes = 741; //Number of potValues that represent the rotation of the gimbal 180 degrees
    int potGive = 14; //Accounts for slack in gearing for pot
    
    //Variables required for zeroing
    int dpot; //difference to desired pot value from current
    int dstep; //number of steps the stepper must move to get to desired position
    
    int midscan = ScanNum/2;
    
    
    // Stepper Always On
    // Option 0 - Lidar Only
    // Option 1 - Cam Only
    // Option 2 - All On
    // Default case - Do Nothing/Error Recovery
    switch(*choice){
        
        //////////////////////////////////////////////////////
        /////////////// Option 0 - Lidar Only  ///////////////
        //////////////////////////////////////////////////////
        
        case 0:{ 
            //Pot reader may take a minute to initialize and will send zero
            //If this is the case do nothing
            if (*potVal != 0) {
                //Zero stepper on first run
                //Account for differnces coming from different directions
                if (counter == 0) {
                    printf("potVal:%d\n", *potVal);
                    //Find pot value difference to calculate steps needed to level
                    if (zeroPos > *potVal) {
                        dpot = zeroPos - potGive - *potVal;
                    }
                    else if (zeroPos < *potVal) {
                        dpot = zeroPos + potGive -*potVal;
                    }
                    else {
                        dpot = 0;
                    }
                    printf("Dpot:%d\n", dpot);
                    
                    //Find required steps and move to level position
                    dstep = -stepRes/potRes*dpot;
                    
                    //If error occurs dstep may be very large
                    //Limit dstep value to prevent damage to system
                    if (dstep > 3000)
                        dstep = 3000;
                    if (dstep < -3000)
                        dstep = -3000;
                    
                    printf("Dstep:%d\n", dstep);
                    stepperMove(dstep, stepper);
                    
                    //Set current position to zero
                    CPhidgetStepper_setCurrentPosition(stepper, 0, 0);
                    //Move to Up position to begin scanning process
                    stepperMove(*Upos, stepper);
                    counter = 1;
                }
                
                if (lidarCounter == 0) {
                    camCounter = 0;
                    bothCounter = 0;
                    lidarCounter = 1;
                }
                
                //Tell stepper to move to new position
                if (counter == 1) {
                    CPhidgetStepper_setTargetPosition(stepper, 0, *Dpos);
                    counter = 2;
                    *udOut = 0;
                }
                else if (counter == 2) {
                    CPhidgetStepper_setTargetPosition(stepper, 0, *Upos);
                    counter = 1;
                    *udOut = 1;
                }
                //Sleep to allow stepper to start moving
                usleep(120000);
                
                //Request data
                urg_setCaptureTimes(&urg, ScanNum);
                ret = urg_requestData(&urg, URG_MD, 0, 1080);
                if (ret < 0)
                    urg_exit(&urg, "urg_requestData()");
                
                               
                for (j=0;j<ScanNum;j++) {
                    // Receive Data
                    n = urg_receiveData(&urg, data, 1080);
                    // Error, can't receive negative data points
                    if (n < 0) {
                        urg_exit(&urg, "urg_receiveData()");
                        // Disconnect Lidar
                        urg_disconnect(&urg);
                    }
                    
                    // Data Received, Construct Partial Image
                    else{
                        for(k=0;k<1080;k++){
                            lidarData[(j*1080)+k] = data[k];
                        }
                    }
                }
            }// END OF LIDAR DATA ACQ
            break;
        }
        
        ///////////////////////////////////////////////////
        /////////////// Option 1 - Cam Only ///////////////
        ///////////////////////////////////////////////////
        
        case 1:{ 
            
            if (camCounter == 0) {
                // Grab a number of frames in order to flush the data buffer
                int flush1 = cvGrabFrame( capture1 );
                int flush2 = cvGrabFrame( capture1 );
                int flush3 = cvGrabFrame( capture1 );
                int flush4 = cvGrabFrame( capture1 );
                
                lidarCounter = 0;
                bothCounter = 0;
                camCounter = 1;
            }
            
            frame1 = cvQueryFrame( capture1 ); //Gets Frame from Camera
            
            unsigned char *data1 = frame1->imageData;
            long iNew, jNew = 0, kNew = 0;
            for(iNew = 0; iNew < 480*640*3; iNew+=3){
                //printf("data: %d, %d, %d \n",data[i],data[i+1], data[i+2]);
                Blue[jNew*480+kNew] = data1[iNew];
                Green[jNew*480+kNew] = data1[iNew+1];
                Red[jNew*480+kNew] = data1[iNew+2];
                jNew++;
                if(jNew==640){kNew++; jNew = 0;}
            }
            break;
        }
        
        ///////////////////////////////////////////////////
        //////////////// Option 2  - All On ///////////////
        ///////////////////////////////////////////////////
        
        case 2:{ 
            //Pot reader may take a minute to initialize and will send zero
            //If this is the case do nothing
            
            
            //Zero stepper on first run
            //Account for differnces coming from different directions
            if (counter == 0) {
                printf("potVal:%d\n", *potVal);
                //Find pot value difference to calculate steps needed to level
                if (zeroPos > *potVal) {
                    dpot = zeroPos - potGive - *potVal;
                }
                else if (zeroPos < *potVal) {
                    dpot = zeroPos + potGive -*potVal;
                }
                else {
                    dpot = 0;
                }
                printf("Dpot:%d\n", dpot);
                
                //Find required steps and move to level position
                dstep = -stepRes/potRes*dpot;
                
                //If error occurs dstep may be very large
                //Limit dstep value to prevent damage to system
                if (dstep > 3000)
                    dstep = 3000;
                if (dstep < -3000)
                    dstep = -3000;
                
                printf("Dstep:%d\n", dstep);
                stepperMove(dstep, stepper);
                
                //Set current position to zero
                CPhidgetStepper_setCurrentPosition(stepper, 0, 0);
                //Move to Up position to begin scanning process
                stepperMove(*Upos, stepper);
                counter = 1;
            }
            
            if (bothCounter == 0) {
                //Preform on first run
                lidarCounter = 0;
                camCounter = 0;
                bothCounter = 1;
            }
            
            //START OF DATA ACQUISITION
                                  
            //Tell stepper to move to new position
            if (counter == 1) {
                CPhidgetStepper_setTargetPosition(stepper, 0, *Dpos);
                counter = 2;
                *udOut = 0;
            }
            else if (counter == 2) {
                CPhidgetStepper_setTargetPosition(stepper, 0, *Upos);
                counter = 1;
                *udOut = 1;
            }
            
            //Sleep to allow stepper to start moving
            usleep(120000);
            
            //Request data
            urg_setCaptureTimes(&urg, ScanNum);
            ret = urg_requestData(&urg, URG_MD, 0, 1080);
            if (ret < 0)
                urg_exit(&urg, "urg_requestData()");
            
            //Sleep so image will be taken in middle of lidar scan
            //usleep(100000);
            
            // Grab a number of frames in order to flush the data buffer
            int flush1 = cvGrabFrame( capture1 );
            int flush2 = cvGrabFrame( capture1 );
            int flush3 = cvGrabFrame( capture1 );
            int flush4 = cvGrabFrame( capture1 );
            
            // Acquire from from webcam
            //IplImage *frame1 = cvQueryFrame( capture1 );
            
            
            for (j=0;j<ScanNum;j++) {
                // Receive Data
                n = urg_receiveData(&urg, data, 1080);
                
                // Grab frame from webcam in middle of scan
                if (j == midscan) {
                    frame1 = cvQueryFrame( capture1 );
                }
                
                // Error, can't receive negative data points
                if (n < 0) {
                    urg_exit(&urg, "urg_receiveData()");
                    // Disconnect Lidar
                    urg_disconnect(&urg);
                }
                
                // Data Received, Construct Partial Image
                else{
                    for(k=0;k<1080;k++){
                        lidarData[(j*1080)+k] = data[k];
                    }
                }
            }
            
            
            
            unsigned char *data1 = frame1->imageData;
            long iNew, jNew = 0, kNew = 0;
            for(iNew = 0; iNew < 480*640*3; iNew+=3){
                //printf("data: %d, %d, %d \n",data[i],data[i+1], data[i+2]);
                Blue[jNew*480+kNew] = data1[iNew];
                Green[jNew*480+kNew] = data1[iNew+1];
                Red[jNew*480+kNew] = data1[iNew+2];
                jNew++;
                if(jNew==640){kNew++; jNew = 0;}
            }
            break;
        }
        
        ///// Default Case for all other invalid input /////
        
        default:{
            lidarCounter = 0;
            camCounter = 0;
            bothCounter = 0;
            break;
        }
        // END OF LIDAR DATA ACQ
    }
}