Using SimpleMotion scope capture feature
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Alustus, asetetaan skoopin parametrit
SMP_CAPTURE_BUF_LENGHT - montako samplea kaapataan 1-2048
SMP_CAPTURE_SAMPLERATE - näytteistystaajuus (tai sen jakaja). Taajuus on 20kHz/(arvo+1), eli 0=20kHz, 1=10kHz, 2=6.66kHz jne
SMP_CAPTURE_SOURCE - päälläolevat bitit tässä parametrissa määräävät mitä signaaleja bufferiin kaapataan, seuraavat on saavatilla kaikissa firmisversioissa (samat mitä granityssä valittavissa): #define CAPTURE_TORQUE_TARGET 1 #define CAPTURE_TORQUE_ACTUAL 2 #define CAPTURE_VELOCITY_TARGET 3 #define CAPTURE_VELOCITY_ACTUAL 4 #define CAPTURE_POSITION_TARGET 5 #define CAPTURE_POSITION_ACTUAL 6 #define CAPTURE_FOLLOW_ERROR 7 #define CAPTURE_OUTPUT_VOLTAGE 8 #define CAPTURE_BUS_VOLTAGE 9 #define CAPTURE_DEBUG1 19 #define CAPTURE_DEBUG2 20 Esim arvoksi tulee 68 (bitit 2 & 6) kanavilla CAPTURE_TORQUE_ACTUAL ja CAPTURE_POSITION_ACTUAL.
SMP_CAPTURE_TRIGGER - triggeri mikä käynnistää kaappauksen, vaihtoehdot (samat mitä granityssä valittavissa): #define TRIG_NONE 0 #define TRIG_INSTANT 1 #define TRIG_FAULT 2 #define TRIG_TARGETCHANGE 3 #define TRIG_TARGETCHANGE_POS 4 #define TRIG_EXTERNAL_INPUT 5
SMP_CAPTURE_BEFORE_TRIGGER_PERCENTS - tämä tuli vasta FW versiossa 1.6.0. asettaa kaappauksen aloituksen ennen triggausta. arvo prosentteina -1000000...100. Granityt 1.13.0 voi testailla tämän toimintaa.
Skoopin luku
Pollataan arvoa SMP_CAPTURE_STATE, arvot: 0 - idle (kaappaus valmis tai ei vielä aloitettukaan) 1 - odottaa triggeriä 2 - kaappaus käynnissä
Kun kaappaus valmis (käynyt arvoissa !=0 ja sitten 0), ladataan data talteen: asetetaan SMP_CAPTURE_BUFFER_GET_ADDR = 0 luetaan parametria SMP_CAPTURE_BUFFER_GET_VALUE yhtä monta kertaa kuin alustuksessa asetettu parametrin arvo SMP_CAPTURE_BUF_LENGHT on tämän luku palauttaa kaapatut samplet. jos asetettiin kaapattavaksi kanavat a, b ja c, niin luetut arvot tulevat järjestyksesä a0,b0,c0,a1,b1,c1,a2,b2,c2,a3,b3,c3.
Example
#include <stdio.h> #include <unistd.h> //for usleep #include "simplemotion.h" smbus handle; int nodeAddress; bool setupScope() { SM_STATUS status = 0; status |= smSetParameter(handle, nodeAddress, SMP_CAPTURE_BUF_LENGHT, 2048); status |= smSetParameter(handle, nodeAddress, SMP_CAPTURE_BEFORE_TRIGGER_PERCENTS, 0); //note, requires on IONI FW 1.6.0 or later status |= smSetParameter(handle, nodeAddress, SMP_CAPTURE_SAMPLERATE, 7); //with IONI sample rate is 20000/(SMP_CAPTURE_SAMPLERATE+1) Hz, so here it is 2500 Hz status |= smSetParameter(handle, nodeAddress, SMP_CAPTURE_SOURCE, BV(CAPTURE_POSITION_ACTUAL)|BV(CAPTURE_BUS_VOLTAGE)); status |= smSetParameter(handle, nodeAddress, SMP_CAPTURE_TRIGGER, TRIG_INSTANT); status |= smSetParameter(handle, nodeAddress, SMP_CAPTURE_STATE, 1); //start capture if(status!=SM_OK) { //error return false; } return true; } //parameters: nsamples=number of samples to read 1-2048, samples=pointer to buffer with at least nsamples length bool downloadScope( int nsamples, int *samples ) { smint32 retval; int samplesread=0, storepos=0; SM_STATUS smStat=0; //setup for scope reading smStat|=smAppendSMCommandToQueue( handle, SMPCMD_SET_PARAM_ADDR, SMP_RETURN_PARAM_LEN ); smStat|=smAppendSMCommandToQueue( handle, SMPCMD_24B, SMPRET_32B );//read 32 bit (values capped to 30 bits) samples smStat|=smAppendSMCommandToQueue( handle, SMPCMD_SET_PARAM_ADDR, SMP_RETURN_PARAM_ADDR ); smStat|=smAppendSMCommandToQueue( handle, SMPCMD_24B, SMP_CAPTURE_BUFFER_GET_VALUE ); //read at get_value param smStat|=smAppendSMCommandToQueue( handle, SMPCMD_SET_PARAM_ADDR, SMP_CAPTURE_BUFFER_GET_ADDR ); //set store address to get_addr smStat|=smExecuteCommandQueue(handle,nodeAddress); smStat|=smGetQueuedSMCommandReturnValue( handle, &retval ); smStat|=smGetQueuedSMCommandReturnValue( handle, &retval ); smStat|=smGetQueuedSMCommandReturnValue( handle, &retval ); smStat|=smGetQueuedSMCommandReturnValue( handle, &retval ); smStat|=smGetQueuedSMCommandReturnValue( handle, &retval ); //loop to read samples while(samplesread<nsamples) { int i; int samplestofetch=nsamples-samplesread; if(samplestofetch>30)samplestofetch=30;//maximum per one SM cycle (4*30=120 bytes=max payload) //add read param commands to queue for(i=0;i<samplestofetch;i++) { smStat|=smAppendSMCommandToQueue( handle, SMPCMD_24B, samplesread ); samplesread++; } //transmit & redeive over SM bus smStat|=smExecuteCommandQueue(handle,nodeAddress); //read values from return data queue for(i=0;i<samplestofetch;i++) { smStat|=smGetQueuedSMCommandReturnValue( handle, &retval ); samples[storepos++]=retval; } } //read one dummy variable just to cause SMP_RETURN_PARAM_ADDR to change to non-SMP_CAPTURE_BUFFER_GET_VALUE so next time we read data, we get it all from beginning smStat |= smRead1Parameter(handle, nodeAddress, SMP_NULL, &retval ); if(smStat!=SM_OK) return false; return true; } SM_STATUS scopeWait() { smint32 state; //loop until SMP_CAPTURE_STATE is 0 (scope idle) while (true) { SM_STATUS status = smRead1Parameter(handle, nodeAddress, SMP_CAPTURE_STATE, &state); if (status != SM_OK) return status; fprintf(stderr, "scope state: %d\n", state); if (state == 0) { break; } usleep(100000); } return SM_OK; } int main( void ) { const char *portName="COM3"; //bus device name nodeAddress = 4; //SM device address int samples[2048]; fprintf(stderr, "opening bus %s\n", portName); handle = smOpenBus(portName); if (handle < 0) { fprintf(stderr, "could not open bus: %s\n", portName); return -4; } if(setupScope()==false) return -1; if(scopeWait()!=SM_OK) return -2; if(downloadScope( 2048, samples )==false) return -3; //sample list will be repeating list of samples defined to SMP_CAPTURE_SOURCE. //I.e if we capture 3 channels A, B and C, then samples will contain A0,B0,C0,A1,B1,C1,A2,B3,C3 etc for( int i=0; i<2048; i++) { fprintf(stderr, "samples[%d]=%d\n", i, samples[i]); } fprintf(stderr, "All done\n"); return 0; }
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