Labrador/Desktop_Interface/isodriver.cpp

1662 lines
50 KiB
C++

#include "isodriver.h"
#include "isobuffer.h"
#include "isobuffer_file.h"
#include "platformspecific.h"
#include <math.h>
#include "daqloadprompt.h"
#include <iostream>
#include <omp.h>
static constexpr int kSpectrumCounterMax = 4;
isoDriver::isoDriver(QWidget *parent) : QLabel(parent)
{
this->hide();
internalBuffer375_CH1 = new isoBuffer(this, MAX_WINDOW_SIZE*ADC_SPS/20*21, this, 1);
internalBuffer375_CH2 = new isoBuffer(this, MAX_WINDOW_SIZE*ADC_SPS/20*21, this, 2);
internalBuffer750 = new isoBuffer(this, MAX_WINDOW_SIZE*ADC_SPS/10*21, this, 1);
isoTemp = (char *) malloc(TIMER_PERIOD*ADC_SPF + 8); //8-byte header contains (unsigned long) length
char volts[2] = "V";
char seconds[2] = "s";
char hertz[3] = "Hz";
v0 = new siprint(volts, 1234);
v1 = new siprint(volts, 0);
dv = new siprint(volts, 0);
t0 = new siprint(seconds, 0);
t1 = new siprint(seconds, 0);
dt = new siprint(seconds, 0);
f = new siprint(hertz, 0);
startTimer();
slowTimer = new QTimer;
slowTimer->setTimerType(Qt::PreciseTimer);
slowTimer->start(MULTIMETER_PERIOD);
connect(slowTimer, SIGNAL(timeout()), this, SLOT(slowTimerTick()));
}
void isoDriver::setDriver(genericUsbDriver *newDriver){
driver = newDriver;
qDebug() << "driver = " << driver;
}
void isoDriver::setAxes(QCustomPlot *newAxes){
axes = newAxes;
qDebug() << "axes = " << axes;
}
void isoDriver::timerTick(void){
//qDebug() << "isoDriver SEZ Tick!";
if(firstFrame){
autoGain();
firstFrame = false;
}
isoTemp = driver->isoRead(&length);
//qDebug() << length << "read in!!";
total_read += length;
if(fileModeEnabled){
qDebug() << "File mode is active. Abort live refresh";
return;
}
if (length==0){
//Zero length packet means something's gone wrong. Probably a disconnect.
qDebug() << "Zero length iso packet!";
//driver->killMe();
return;
}
// TODO: Do we need to invalidate state when the device is reconnected?
bool invalidateTwoWireState = true;
switch(driver->deviceMode){
case 0:
if (deviceMode_prev != 0 && deviceMode_prev != 1 && deviceMode_prev != 2)
clearBuffers(true, false, false);
frameActionGeneric(1,0);
break;
case 1:
if (deviceMode_prev != 0 && deviceMode_prev != 1 && deviceMode_prev != 2)
clearBuffers(true, false, false);
if (deviceMode_prev != 1)
clearBuffers(false, true, false);
internalBuffer375_CH2->m_channel = 1;
frameActionGeneric(1,2);
if(serialDecodeEnabled_CH1 && serialType == 0){
internalBuffer375_CH2->serialManage(baudRate_CH1, parity_CH1, hexDisplay_CH1);
}
break;
case 2:
if (deviceMode_prev != 0 && deviceMode_prev != 1 && deviceMode_prev != 2)
clearBuffers(true, false, false);
if (deviceMode_prev != 2)
clearBuffers(false, true, false);
frameActionGeneric(1,1);
break;
case 3:
if (deviceMode_prev != 3 && deviceMode_prev != 4)
clearBuffers(true, false, false);
frameActionGeneric(2,0);
if(serialDecodeEnabled_CH1 && serialType == 0){
internalBuffer375_CH1->serialManage(baudRate_CH1, parity_CH1, hexDisplay_CH1);
}
break;
case 4:
if (deviceMode_prev != 3 && deviceMode_prev != 4)
clearBuffers(true, false, false);
if (deviceMode_prev != 4)
clearBuffers(false, true, false);
internalBuffer375_CH2->m_channel = 2;
frameActionGeneric(2,2);
if(serialDecodeEnabled_CH1 && serialType == 0){
internalBuffer375_CH1->serialManage(baudRate_CH1, parity_CH1, hexDisplay_CH1);
}
if(serialDecodeEnabled_CH2 && serialType == 0){
internalBuffer375_CH2->serialManage(baudRate_CH2, parity_CH2, hexDisplay_CH2);
}
if (serialDecodeEnabled_CH1 && serialType == 1)
{
if (twoWireStateInvalid)
twoWire->reset();
try
{
twoWire->run();
}
catch(...)
{
qDebug() << "Resetting I2C";
twoWire->reset();
}
invalidateTwoWireState = false;
twoWireStateInvalid = false;
}
break;
case 5:
break;
case 6:
if (deviceMode_prev != 6)
clearBuffers(false, false, true);
frameActionGeneric(-1,0);
break;
case 7:
if (deviceMode_prev != 7)
clearBuffers(true, false, false);
multimeterAction();
break;
default:
qFatal("Error in isoDriver::timerTick. Invalid device mode.");
}
if (invalidateTwoWireState)
twoWireStateInvalid = true;
deviceMode_prev = driver->deviceMode;
//free(isoTemp);
}
void isoDriver::analogConvert(short *shortPtr, QVector<double> *doublePtr, int TOP, bool AC, int channel){
double scope_gain = (double)(driver->scopeGain);
double accumulated = 0;
double accumulated_square = 0;
currentVmax = -20;
currentVmin = 20;
double ref = (channel == 1 ? ch1_ref : ch2_ref);
double frontendGain = (channel == 1 ? frontendGain_CH1 : frontendGain_CH2);
double *data = doublePtr->data();
for (int i=0;i<doublePtr->size();i++){
data[i] = (shortPtr[i] * (vcc/2)) / (frontendGain*scope_gain*TOP);
if (driver->deviceMode != 7) data[i] += ref;
#ifdef INVERT_MM
if(driver->deviceMode == 7) data[i] *= -1;
#endif
accumulated += data[i];
accumulated_square += data[i] * data[i];
if (data[i] > currentVmax) currentVmax = data[i];
if (data[i] < currentVmin) currentVmin = data[i];
}
currentVmean = accumulated / doublePtr->size();
currentVRMS = sqrt(accumulated_square / doublePtr->size());
if(AC){
//Previous measurments are wrong, edit and redo.
accumulated = 0;
accumulated_square = 0;
currentVmax = -20;
currentVmin = 20;
for (int i=0;i<doublePtr->size();i++){
data[i] -= currentVmean;
accumulated += data[i];
accumulated_square += (data[i] * data[i]);
if (data[i] > currentVmax) currentVmax = data[i];
if (data[i] < currentVmin) currentVmin = data[i];
}
currentVmean = accumulated / doublePtr->size();
currentVRMS = sqrt(accumulated_square / doublePtr->size());
}
//cool_waveform = cool_waveform - AC_offset;
}
void isoDriver::digitalConvert(short *shortPtr, QVector<double> *doublePtr){
double *data = doublePtr->data();
double top = display.topRange - (display.topRange - display.botRange) / 10;
double bot = display.botRange + (display.topRange - display.botRange) / 10;
for (int i=0;i<GRAPH_SAMPLES;i++){
data[i] = shortPtr[i] ? top : bot;
}
//cool_waveform = cool_waveform - AC_offset;
}
void isoDriver::fileStreamConvert(float *floatPtr, QVector<double> *doublePtr){
double *data = doublePtr->data();
for (int i=0;i<GRAPH_SAMPLES;i++){
data[i] = floatPtr[i];
}
}
void isoDriver::startTimer(){
/*if (isoTimer!=NULL){
delete isoTimer;
isoTimer = NULL;
}
isoTimer = new QTimer();
isoTimer->setTimerType(Qt::PreciseTimer);
isoTimer->start(TIMER_PERIOD);
connect(isoTimer, SIGNAL(timeout()), this, SLOT(timerTick()));
//qFatal("ISO TIMER STARTED");*/
}
void isoDriver::clearBuffers(bool ch3751, bool ch3752, bool ch750){
if(ch3751) internalBuffer375_CH1->clearBuffer();
if(ch3752) internalBuffer375_CH2->clearBuffer();
if(ch750) internalBuffer750->clearBuffer();
}
void isoDriver::setVisible_CH2(bool visible){
axes->graph(1)->setVisible(visible);
}
void isoDriver::setVoltageRange(QWheelEvent* event)
{
if(doNotTouchGraph && !fileModeEnabled) return;
bool isProperlyPaused = properlyPaused();
double maxWindowSize = fileModeEnabled ? daq_maxWindowSize : ((double)MAX_WINDOW_SIZE);
display.setVoltageRange(event, isProperlyPaused, maxWindowSize, axes);
if (!(event->modifiers() == Qt::ControlModifier))
if (autoGainEnabled && !isProperlyPaused)
autoGain();
}
void DisplayControl::setVoltageRange (QWheelEvent* event, bool isProperlyPaused, double maxWindowSize, QCustomPlot* axes)
{
if (!(event->modifiers() == Qt::ControlModifier) && event->orientation() == Qt::Orientation::Vertical) {
double c = (topRange - botRange) / (double)400;
QCPRange range = axes->yAxis->range();
double pixPct = (double)100 - ((double)100 * (((double)axes->yAxis->pixelToCoord(event->y())-range.lower) / range.size()));
if (pixPct < 0) pixPct = 0;
if (pixPct > 100) pixPct = 100;
qDebug() << "WHEEL @ " << pixPct << "%";
qDebug() << range.upper;
topRange -= event->delta() / 120.0 * c * pixPct;
botRange += event->delta() / 120.0 * c * (100.0 - pixPct);
if (topRange > (double)20) topRange = (double)20;
if (botRange < -(double)20) botRange = (double)-20;
topRangeUpdated(topRange);
botRangeUpdated(botRange);
}
else
{
double c = (window) / (double)200;
QCPRange range = axes->xAxis->range();
double pixPct = (double)100 * ((double)axes->xAxis->pixelToCoord(event->x()) - range.lower);
pixPct /= isProperlyPaused ? (double)(range.upper - range.lower)
: (double)(window);
if (pixPct < 0)
pixPct = 0;
if (pixPct > 100)
pixPct = 100;
qDebug() << "WHEEL @ " << pixPct << "%";
qDebug() << event->delta();
if (! isProperlyPaused)
{
qDebug() << "TIGGERED";
qDebug() << "upper = " << range.upper << "lower = " << range.lower;
qDebug() << "window = " << window;
qDebug() << c * ((double)pixPct);
qDebug() << c * ((double)100 - (double)pixPct) * pixPct / 100;
}
window -= event->delta() / 120.0 * c * pixPct;
delay += event->delta() / 120.0 * c * (100.0 - pixPct) * pixPct / 100.0;
// NOTE: delayUpdated and timeWindowUpdated are called more than once beyond here,
// maybe they should only be called once at the end?
delayUpdated(delay);
timeWindowUpdated(window);
qDebug() << window << delay;
if (window > maxWindowSize)
{
window = maxWindowSize;
timeWindowUpdated(window);
}
if ((window + delay) > maxWindowSize)
{
delay = maxWindowSize - window;
delayUpdated(delay);
}
if (delay < 0)
{
delay = 0;
delayUpdated(delay);
}
}
}
bool isoDriver::properlyPaused(){
if(paused_CH1 & paused_CH2){
qDebug() << "Properly paused";
return true;
}
if ((driver->deviceMode == 0) || (driver->deviceMode == 3) || (driver->deviceMode == 6)){
if(paused_CH1) qDebug() << "Properly paused"; else qDebug() << "Not properly paused";
return paused_CH1;
}
if(paused_multimeter){
qDebug() << "Properly paused";
return true;
}
qDebug() << "Not properly paused";
return false;
}
void isoDriver::pauseEnable_CH1(bool enabled){
paused_CH1 = enabled;
if(!properlyPaused()) {
display.delay = 0;
delayUpdated(display.delay);
if (autoGainEnabled) autoGain();
}
if(!enabled) clearBuffers(1,0,1);
qDebug() << "pauseEnable_CH1" << enabled;
}
void isoDriver::pauseEnable_CH2(bool enabled){
paused_CH2 = enabled;
if(!properlyPaused()){
display.delay = 0;
delayUpdated(display.delay);
if (autoGainEnabled) autoGain();
}
if(!enabled) clearBuffers(0,1,0);
}
void isoDriver::pauseEnable_multimeter(bool enabled){
paused_multimeter = enabled;
if(!properlyPaused()) {
display.delay = 0;
delayUpdated(display.delay);
}
if(!enabled) clearBuffers(1,0,0);
qDebug() << "pauseEnable_multimeter" << enabled;
}
void isoDriver::autoGain(){
double maxgain = vcc / (2 * ((double)display.topRange - vref) * R4/(R3+R4));
double mingain = vcc / (2 * ((double)display.botRange - vref) * R4/(R3+R4));
maxgain = fmin(fabs(mingain) * 0.98, fabs(maxgain) * 0.98);
double snap[8] = {64, 32, 16, 8, 4, 2, 1, 0.5};
for (int i=0;i<8;i++){
if (maxgain>snap[i]){
setGain(snap[i]);
return;
}
}
}
void isoDriver::gainBuffers(double multiplier){
multi = multiplier;
QTimer::singleShot(TIMER_PERIOD*4, this, SLOT(gainTick()));
}
void isoDriver::gainTick(void){
#ifdef PLATFORM_ANDROID
#warning: "gainTick does nothing on Android!!"
#else
qDebug() << "Multiplying by " << multi;
if (driver->deviceMode <5) internalBuffer375_CH1->gainBuffer(log2(multi));
if ((driver->deviceMode == 1) | (driver->deviceMode == 2) | (driver->deviceMode == 4)) internalBuffer375_CH2->gainBuffer(log2(multi));
if ((driver->deviceMode == 6) | (driver->deviceMode == 7)) internalBuffer750->gainBuffer(log2(multi));
#endif
}
void isoDriver::setAutoGain(bool enabled){
autoGainEnabled = enabled;
if(enabled){
autoGain();
}
}
void isoDriver::graphMousePress(QMouseEvent *event){
qDebug() << event->button();
if (horiCursorEnabled && (event->button() == Qt::LeftButton)){
placingHoriAxes = true;
display.y0 = axes->yAxis->pixelToCoord(event->y());
#ifndef PLATFORM_ANDROID
}else if(vertCursorEnabled && (event->button() == Qt::RightButton)){
#else
}if(vertCursorEnabled){
#endif
placingVertAxes = true;
display.x0 = axes->xAxis->pixelToCoord(event->x());
}
qDebug() << "x0 =" << display.x0 << "x1 =" << display.x1 << "y0 =" << display.y0 << "y1 =" << display.y1;
}
void isoDriver::graphMouseRelease(QMouseEvent *event){
if(horiCursorEnabled && placingHoriAxes && (event->button() == Qt::LeftButton)){
placingHoriAxes = false;
#ifndef PLATFORM_ANDROID
} else if (vertCursorEnabled && placingVertAxes && (event->button() == Qt::RightButton)){
#else
} if (vertCursorEnabled && placingVertAxes){
#endif
placingVertAxes = false;
}
qDebug() << "x0 =" << display.x0 << "x1 =" << display.x1 << "y0 =" << display.y0 << "y1 =" << display.y1;
}
void isoDriver::graphMouseMove(QMouseEvent *event){
if(horiCursorEnabled && placingHoriAxes){
display.y1 = axes->yAxis->pixelToCoord(event->y());
#ifndef PLATFORM_ANDROID
} else if(vertCursorEnabled && placingVertAxes){
#else
} if(vertCursorEnabled && placingVertAxes){
#endif
display.x1 = axes->xAxis->pixelToCoord(event->x());
}
}
void isoDriver::cursorEnableHori(bool enabled){
horiCursorEnabled = enabled;
axes->graph(4)->setVisible(enabled);
axes->graph(5)->setVisible(enabled);
}
void isoDriver::cursorEnableVert(bool enabled){
vertCursorEnabled = enabled;
axes->graph(2)->setVisible(enabled);
axes->graph(3)->setVisible(enabled);
}
void isoDriver::udateCursors(void){
if(!(vertCursorEnabled || horiCursorEnabled)){
#if QCP_VER == 1
cursorTextPtr->setVisible(0);
#endif
return;
}
QVector<double> vert0x(2), vert1x(2), hori0x(2), hori1x(2), vert0y(2), vert1y(2), hori0y(2), hori1y(2);
vert0x[0] = display.x0;
vert0x[1] = display.x0;
vert0y[0] = display.botRange;
vert0y[1] = display.topRange;
vert1x[0] = display.x1;
vert1x[1] = display.x1;
vert1y[0] = display.botRange;
vert1y[1] = display.topRange;
hori0x[0] = -display.window - display.delay;
hori0x[1] = -display.delay;
hori0y[0] = display.y0;
hori0y[1] = display.y0;
hori1x[0] = -display.window - display.delay;
hori1x[1] = -display.delay;
hori1y[0] = display.y1;
hori1y[1] = display.y1;
if(vertCursorEnabled){
axes->graph(2)->setData(vert0x, vert0y);
axes->graph(3)->setData(vert1x, vert1y);
}
if(horiCursorEnabled){
axes->graph(4)->setData(hori0x, hori0y);
axes->graph(5)->setData(hori1x, hori1y);
}
#if QCP_VER == 1
cursorTextPtr->setVisible(cursorStatsEnabled);
#endif
if (!cursorStatsEnabled) return;
QString *cursorStatsString = new QString();
v0->value = display.y0;
v1->value = display.y1;
dv->value = display.y0-display.y1;
t0->value = display.x0;
t1->value = display.x1;
dt->value = fabs(display.x0 - display.x1);
f->value = 1 / (display.x1 - display.x0);
char temp_hori[64];
char temp_vert[64];
char temp_separator[2];
sprintf(temp_hori, "V0 = %s, V1 = %s, ΔV = %s", v0->printVal(), v1->printVal(), dv->printVal());
sprintf(temp_vert, "t0 = %s, t1 = %s, Δt = %s, f = %s", t0->printVal(), t1->printVal(), dt->printVal(), f->printVal());
sprintf(temp_separator, "\n");
//sprintf(temp, "hello!");
if(horiCursorEnabled) cursorStatsString->append(temp_hori);
if(horiCursorEnabled && vertCursorEnabled) cursorStatsString->append(temp_separator);
if(vertCursorEnabled) cursorStatsString->append(temp_vert);
//qDebug() << temp;
#if QCP_VER == 1
cursorTextPtr->setText(*(cursorStatsString));
#endif
delete cursorStatsString;
}
short isoDriver::reverseFrontEnd(double voltage){
//qFatal("reverseFrontEnd driver mode 7");
#ifdef INVERT_MM
if(driver->deviceMode == 7) voltage *= -1;
#endif
double vn = vcc * (R2/(R1+R2));
double vx = vn + (voltage - vn) * (R4 / (R3+R4));
double TOP = (driver->deviceMode == 7) ? 2048 : 128;
if (driver->deviceMode == 7){
qDebug() << "SEEEKING";
qDebug() << ((vx - vn)/vref * (double)driver->scopeGain * (double)TOP + (double)0.5);
qDebug() << "SEEEKING";
return ((vx - vn)/vref * (double)driver->scopeGain * (double)TOP + (double)0.5);
}
//qDebug() << "seeking" << voltage << "V";
return ((vx - vn)/vref * (double)driver->scopeGain * (double)TOP + (double)0.5);
}
void isoDriver::setTriggerEnabled(bool enabled)
{
triggerEnabled = enabled;
triggerStateChanged();
}
void isoDriver::setTriggerLevel(double level)
{
internalBuffer375_CH1->setTriggerLevel(level, (driver->deviceMode == 7 ? 2048 : 128), AC_CH1);
internalBuffer375_CH2->setTriggerLevel(level, 128, AC_CH2);
internalBuffer750->setTriggerLevel(level, 128, AC_CH1);
triggerStateChanged();
}
void isoDriver::setSingleShotEnabled(bool enabled)
{
singleShotEnabled = enabled;
triggerStateChanged();
}
void isoDriver::setTriggerMode(int newMode)
{
triggerMode = newMode;
triggerStateChanged();
}
//0 for off, 1 for ana, 2 for dig, -1 for ana750, -2 for file
void isoDriver::frameActionGeneric(char CH1_mode, char CH2_mode)
{
// The Spectrum is computationally expensive to calculate, so we don't want to do it on every frame
static int spectrumCounter = 0;
if(spectrum)
{
spectrumCounter = (spectrumCounter + 1) % kSpectrumCounterMax;
if (spectrumCounter != 0)
return;
}
//qDebug() << "made it to frameActionGeneric";
if(!paused_CH1 && CH1_mode == - 1){
for (unsigned int i=0;i<(length/ADC_SPF);i++){
internalBuffer750->writeBuffer_char(&isoTemp[ADC_SPF*i], VALID_DATA_PER_750);
}
}
if(!paused_CH1 && CH1_mode > 0){
for (unsigned int i=0;i<(length/ADC_SPF);i++){
internalBuffer375_CH1->writeBuffer_char(&isoTemp[ADC_SPF*i], VALID_DATA_PER_375);
}
}
if(!paused_CH2 && CH2_mode > 0){
for (unsigned int i=0;i<(length/ADC_SPF);i++){
internalBuffer375_CH2->writeBuffer_char(&isoTemp[ADC_SPF*i+ADC_SPF/2], VALID_DATA_PER_375); //+375 to get the second half of the packet
}
}
if(!paused_CH1)
{
int offset = -2; //No trigger!
int backLength = length/750;
backLength *= (CH1_mode == -1) ? VALID_DATA_PER_750 : VALID_DATA_PER_375;
if(offset>0){
int temp_offset = offset % 750;
offset /= 750;
offset *= (CH1_mode == -1) ? VALID_DATA_PER_750 : VALID_DATA_PER_375;
offset += temp_offset;
}
//qDebug() << "Now offset = " << offset;
}
double triggerDelay = 0;
if (triggerEnabled)
{
isoBuffer* internalBuffer_CH1 = (CH1_mode == -1) ? internalBuffer750 : internalBuffer375_CH1;
triggerDelay = (triggerMode < 2) ? internalBuffer_CH1->getDelayedTriggerPoint(display.window) - display.window : internalBuffer375_CH2->getDelayedTriggerPoint(display.window) - display.window;
if (triggerDelay < 0)
triggerDelay = 0;
}
if(singleShotEnabled && (triggerDelay != 0))
singleShotTriggered(1);
if (!spectrum) {
readData375_CH1 = internalBuffer375_CH1->readBuffer(display.window,GRAPH_SAMPLES,CH1_mode==2, display.delay + triggerDelay);
if(CH2_mode) readData375_CH2 = internalBuffer375_CH2->readBuffer(display.window,GRAPH_SAMPLES,CH2_mode==2, display.delay + triggerDelay);
if(CH1_mode == -1) readData750 = internalBuffer750->readBuffer(display.window,GRAPH_SAMPLES,false, display.delay + triggerDelay);
if(CH1_mode == -2) readDataFile = internalBufferFile->readBuffer(display.window,GRAPH_SAMPLES,false, display.delay);
} else {
/*Don't allow moving frequency spectrum right or left
* by overwriting display window and delay before reading
* the buffer each time.
* @TODO improve this limitation.
*/
double const_displ_window = ((double)internalBuffer375_CH1->async_dft.n_samples)/(internalBuffer375_CH1->m_samplesPerSecond);
double const_displ_delay = 0;
display.delay = const_displ_delay;
display.window = const_displ_window;
readData375_CH1 = internalBuffer375_CH1->readBuffer(display.window,GRAPH_SAMPLES,CH1_mode==2, display.delay + triggerDelay);
if(CH2_mode) readData375_CH2 = internalBuffer375_CH2->readBuffer(display.window,GRAPH_SAMPLES,CH2_mode==2, display.delay + triggerDelay);
if(CH1_mode == -1) readData750 = internalBuffer750->readBuffer(display.window,GRAPH_SAMPLES,false, display.delay + triggerDelay);
}
/*Convert data also for spectrum CH1 and CH2*/
std::unique_ptr<short[]> dt_samples1 = internalBuffer375_CH1->async_dft.getWindow();
std::unique_ptr<short[]> dt_samples2 = internalBuffer375_CH2->async_dft.getWindow();
QVector<double> x(GRAPH_SAMPLES), CH1(GRAPH_SAMPLES), CH2(GRAPH_SAMPLES),
converted_dt_samples1(internalBuffer375_CH1->async_dft.n_samples),
converted_dt_samples2(internalBuffer375_CH2->async_dft.n_samples);
if (CH1_mode == 1){
analogConvert(readData375_CH1.get(), &CH1, 128, AC_CH1, 1);
analogConvert(dt_samples1.get(), &converted_dt_samples1, 128, AC_CH1, 1);
for (int i=0; i < CH1.size(); i++)
{
CH1[i] /= m_attenuation_CH1;
CH1[i] += m_offset_CH1;
}
for (int i=0; i < converted_dt_samples1.size(); i++)
{
converted_dt_samples1[i] /= m_attenuation_CH1;
converted_dt_samples1[i] += m_offset_CH1;
}
xmin = (currentVmin < xmin) ? currentVmin : xmin;
xmax = (currentVmax > xmax) ? currentVmax : xmax;
broadcastStats(0);
}
/*After conversion of dt samples, sending them again to asyncDFT*/
if (CH1_mode == 2) digitalConvert(readData375_CH1.get(), &CH1);
if (CH2_mode == 1){
analogConvert(readData375_CH2.get(), &CH2, 128, AC_CH2, 2);
analogConvert(dt_samples2.get(), &converted_dt_samples2, 128, AC_CH2, 2);
for (int i=0; i < GRAPH_SAMPLES; i++)
{
CH2[i] /= m_attenuation_CH2;
CH2[i] += m_offset_CH2;
}
for (int i=0; i < converted_dt_samples2.size(); i++)
{
converted_dt_samples2[i] /= m_attenuation_CH1;
converted_dt_samples2[i] += m_offset_CH1;
}
ymin = (currentVmin < ymin) ? currentVmin : ymin;
ymax = (currentVmax > ymax) ? currentVmax : ymax;
broadcastStats(1);
}
if (CH2_mode == 2) digitalConvert(readData375_CH2.get(), &CH2);
if(CH1_mode == -1) {
analogConvert(readData750.get(), &CH1, 128, AC_CH1, 1);
xmin = (currentVmin < xmin) ? currentVmin : xmin;
xmax = (currentVmax > xmax) ? currentVmax : xmax;
broadcastStats(0);
}
if(CH1_mode == -2) {
fileStreamConvert(readDataFile, &CH1);
}
for (double i=0; i<GRAPH_SAMPLES; i++){
x[i] = -(display.window*i)/((double)(GRAPH_SAMPLES-1)) - display.delay;
if (x[i]>0) {
CH1[i] = 0;
CH2[i] = 0;
}
}
udateCursors();
if(XYmode){
QCPCurve* curve = reinterpret_cast<QCPCurve*>(axes->plottable(0));
curve->setData(CH1, CH2);
axes->xAxis->setRange(xmin, xmax);
axes->yAxis->setRange(ymin, ymax);
} else{
if (spectrum) { /*If frequency spectrum mode*/
try {
/*Creating DFT amplitudes*/
QVector<double> amplitude1 = internalBuffer375_CH1->async_dft.getPowerSpectrum(converted_dt_samples1);
/*Getting array of frequencies for display purposes*/
QVector<double> f = internalBuffer375_CH1->async_dft.getFrequenciyWindow(internalBuffer375_CH1->m_samplesPerSecond);
/*Max amplitude for display purposes*/
double max1 = internalBuffer375_CH1->async_dft.maximum;
double max2 = -1;
if(CH2_mode) {
QVector<double> amplitude2 = internalBuffer375_CH2->async_dft.getPowerSpectrum(converted_dt_samples2);
max2 = internalBuffer375_CH2->async_dft.maximum;
/*Normalization with respect to amplitude1*/
amplitude2 = internalBuffer375_CH2->async_dft.normalizeDFT(max1, amplitude2);
axes->graph(1)->setData(f,amplitude2);
}
/*Decision for normalization & display purposes*/
amplitude1 = internalBuffer375_CH1->async_dft.normalizeDFT(max2, amplitude1);
axes->graph(0)->setData(f, amplitude1);
axes->xAxis->setRange(m_spectrumMinX, m_spectrumMaxX);
/*Setting maximum/minimum y-axis 0%-100%*/
axes->yAxis->setRange(100,0);
} catch (std::exception) {
std::cout << "Cannot yet get correct value for DFT" << std::endl;
}
} else {
axes->graph(0)->setData(x,CH1);
if(CH2_mode) axes->graph(1)->setData(x,CH2);
axes->xAxis->setRange(-display.window - display.delay, -display.delay);
axes->yAxis->setRange(display.topRange, display.botRange);
}
}
if(snapshotEnabled_CH1){
snapshotFile_CH1->open(QIODevice::WriteOnly);
snapshotFile_CH1->write("t, v\n");
char tempchar[32];
for(int i=0; i<GRAPH_SAMPLES; i++){
sprintf(tempchar, "%f, %f\n", x.at(i), CH1.at(i));
snapshotFile_CH1->write(tempchar);
}
snapshotEnabled_CH1 = false;
snapshotFile_CH1->close();
delete(snapshotFile_CH1);
}
if(snapshotEnabled_CH2){
snapshotFile_CH2->open(QIODevice::WriteOnly);
snapshotFile_CH2->write("t, v\n");
char tempchar[32];
for(int i=0; i<GRAPH_SAMPLES; i++){
sprintf(tempchar, "%f, %f\n", x.at(i), CH2.at(i));
snapshotFile_CH2->write(tempchar);
}
snapshotEnabled_CH2 = false;
snapshotFile_CH2->close();
delete(snapshotFile_CH2);
}
axes->replot();
}
void isoDriver::multimeterAction(){
isoTemp_short = (short *)isoTemp;
if(!paused_multimeter){
for (unsigned int i=0;i<(length/ADC_SPF);i++){
internalBuffer375_CH1->writeBuffer_short(&isoTemp_short[ADC_SPF/2*i], ADC_SPF/2-1); //Offset because the first 8 bytes of the array contain the length (no samples!!)!
}
}
double triggerDelay = 0;
if (triggerEnabled)
{
triggerDelay = internalBuffer375_CH1->getDelayedTriggerPoint(display.window) - display.window;
if (triggerDelay < 0)
triggerDelay = 0;
}
if(singleShotEnabled && (triggerDelay != 0))
singleShotTriggered(1);
readData375_CH1 = internalBuffer375_CH1->readBuffer(display.window,GRAPH_SAMPLES, false, display.delay + triggerDelay);
QVector<double> x(GRAPH_SAMPLES), CH1(GRAPH_SAMPLES);
analogConvert(readData375_CH1.get(), &CH1, 2048, 0, 1); //No AC coupling!
for (double i=0; i<GRAPH_SAMPLES; i++){
x[i] = -(display.window*i)/((double)(GRAPH_SAMPLES-1)) - display.delay;
if (x[i]>0) {
CH1[i] = 0;
}
}
axes->graph(0)->setData(x,CH1);
udateCursors();
axes->xAxis->setRange(-display.window - display.delay, -display.delay);
axes->yAxis->setRange(display.topRange, display.botRange);
axes->replot();
multimeterStats();
}
void isoDriver::setAC_CH1(bool enabled){
AC_CH1 = enabled;
}
void isoDriver::setAC_CH2(bool enabled){
AC_CH2 = enabled;
}
void isoDriver::setMultimeterType(int type){
multimeterType = (multimeterType_enum) type;
switch (type){
case R:
multimeterREnabled(multimeterRsource);
break;
case C:
multimeterREnabled(254);
break;
default:
multimeterREnabled(255);
}
qDebug() << "multimeterType = " << multimeterType;
}
void isoDriver::setSeriesResistance(double resistance){
seriesResistance = resistance;
qDebug() << "seriesResistance = " << seriesResistance;
}
void isoDriver::multimeterStats(){
//qDebug() << "Entering isoDriver::multimeterStats()";
if (!multimeterShow) return;
QTimer::singleShot(MULTIMETER_PERIOD, this, SLOT(enableMM()));
multimeterShow = false;
bool mvMax, mvMin, mvMean, mvRMS, maMax, maMin, maMean, maRMS, kOhms, uFarads; //We'll let the compiler work out this one.
if(autoMultimeterV){
mvMax = abs(currentVmax) < 1.;
mvMin = abs(currentVmin) < 1.;
mvMean = abs(currentVmean) < 1.;
mvRMS = abs(currentVRMS) < 1.;
}
if(autoMultimeterI){
maMax = abs(currentVmax / seriesResistance) < 1.;
maMin = abs(currentVmin / seriesResistance) < 1.;
maMean = abs(currentVmean / seriesResistance) < 1.;
maRMS = abs(currentVRMS / seriesResistance) < 1.;
}
if(forceMillivolts){
mvMax = true;
mvMin = true;
mvMean = true;
mvRMS = true;
}
if(forceMilliamps){
maMax = true;
maMin = true;
maMean = true;
maRMS = true;
}
if(forceKiloOhms){
kOhms = true;
}
if(forceUFarads){
uFarads = true;
}
if(forceVolts){
mvMax = false;
mvMin = false;
mvMean = false;
mvRMS = false;
}
if(forceAmps){
maMax = false;
maMin = false;
maMean = false;
maRMS = false;
}
if(forceOhms){
kOhms = false;
}
if(forceNFarads){
uFarads = false;
}
if(multimeterType == V){
if(mvMax){
currentVmax *= 1000;
sendMultimeterLabel1("Max (mV)");
}else sendMultimeterLabel1("Max (V)");
if(mvMin){
currentVmin *= 1000;
sendMultimeterLabel2("Min (mV)");
}else sendMultimeterLabel2("Min (V)");
if(mvMean){
currentVmean *= 1000;
sendMultimeterLabel3("Mean (mV)");
}else sendMultimeterLabel3("Mean (V)");
if(mvRMS){
currentVRMS *= 1000;
sendMultimeterLabel4("RMS (mV)");
}else sendMultimeterLabel4("RMS (V)");
multimeterMax(currentVmax);
multimeterMin(currentVmin);
multimeterMean(currentVmean);
multimeterRMS(currentVRMS);
return;
}
if(multimeterType == I){
if(maMax){
currentVmax *= 1000;
sendMultimeterLabel1("Max (mA)");
}else sendMultimeterLabel1("Max (A)");
if(maMin){
currentVmin *= 1000;
sendMultimeterLabel2("Min (mA)");
}else sendMultimeterLabel2("Min (A)");
if(maMean){
currentVmean *= 1000;
sendMultimeterLabel3("Mean (mA)");
}else sendMultimeterLabel3("Mean (A)");
if(maRMS){
currentVRMS *= 1000;
sendMultimeterLabel4("RMS (mA)");
}else sendMultimeterLabel4("RMS (A)");
multimeterMax(currentVmax / seriesResistance);
multimeterMin(currentVmin / seriesResistance);
multimeterMean(currentVmean / seriesResistance);
multimeterRMS(currentVRMS / seriesResistance);
return;
}
if(multimeterType == R){
if(estimated_resistance!=estimated_resistance){
estimated_resistance = 0; //Reset resistance if it's NaN
}
double Vm = meanVoltageLast((double)MULTIMETER_PERIOD/(double)1000, 1, 2048);
double rtest_para_r = 1/(1/seriesResistance + 1/estimated_resistance);
double perturbation = ch2_ref * (rtest_para_r / (R3 + R4 + rtest_para_r));
Vm = Vm - perturbation;
double Vin = (multimeterRsource * 2) + 3;
double Vrat = (Vin-Vm)/Vin;
double Rp = 1/(1/seriesResistance + 1/(R3+R4));
estimated_resistance = ((1-Vrat)/Vrat) * Rp; //Perturbation term on V2 ignored. V1 = Vin. V2 = Vin(Rp/(R+Rp)) + Vn(Rtest||R / (R34 + (Rtest||R34));
//qDebug() << "Vm = " << Vm;
//qDebug() << "Vin = " << Vin;
//qDebug() << "perturbation = " << perturbation;
//qDebug() << "Vrat = " << Vrat;
//qDebug() << "Rp = " << Rp;
//qDebug() << "estimated_resistance = " << estimated_resistance;
multimeterMax(0);
multimeterMin(0);
multimeterMean(0);
if(autoMultimeterR){
kOhms = (estimated_resistance) > 1000;
}
if(kOhms){
estimated_resistance /= 1000;
sendMultimeterLabel4("Resistance (kΩ)");
}else sendMultimeterLabel4("Resistance (Ω)");
multimeterRMS(estimated_resistance);
}
if(multimeterType == C){
double cap_vbot = 0.8;
double cap_vtop = 2.5;
int cap_x0 = internalBuffer375_CH1->cap_x0fromLast(1, cap_vbot);
if(cap_x0 == -1){
qDebug() << "cap_x0 == -1";
return;
}
int cap_x1 = internalBuffer375_CH1->cap_x1fromLast(1, cap_x0, cap_vbot);
if(cap_x1 == -1){
qDebug() << "cap_x1 == -1";
return;
}
int cap_x2 = internalBuffer375_CH1->cap_x2fromLast(1, cap_x1, cap_vtop);
if(cap_x2 == -1){
qDebug() << "cap_x2 == -1";
return;
}
qDebug() << "x0 = " << cap_x0;
qDebug() << "x1 = " << cap_x1;
qDebug() << "x2 = " << cap_x2;
qDebug() << "dt = " << cap_x2-cap_x1;
double dt = (double)(cap_x2-cap_x1)/internalBuffer375_CH1->m_samplesPerSecond;
double Cm = -dt/(seriesResistance * log((vcc-cap_vtop)/(vcc-cap_vbot)));
qDebug() << "Cm = " << Cm;
if(autoMultimeterC){
uFarads = (Cm) > 1e-6;
}
if(uFarads){
sendMultimeterLabel4("Capacitance (μF)");
Cm = Cm*1000000;
} else {
sendMultimeterLabel4("Capacitance (nF)");
Cm = Cm*1000000000;
}
multimeterRMS(Cm);
}
}
void isoDriver::enableMM(){
multimeterShow = true;
}
void isoDriver::setAutoMultimeterV(bool enabled){
autoMultimeterV = enabled;
}
void isoDriver::setAutoMultimeterI(bool enabled){
autoMultimeterI = enabled;
}
void isoDriver::setAutoMultimeterR(bool enabled){
autoMultimeterR = enabled;
}
void isoDriver::setAutoMultimeterC(bool enabled){
autoMultimeterC = enabled;
}
void isoDriver::setForceMillivolts(bool enabled){
forceMillivolts = enabled;
}
void isoDriver::setForceMilliamps(bool enabled){
forceMilliamps = enabled;
}
void isoDriver::setForceKiloOhms(bool enabled){
forceKiloOhms = enabled;
}
void isoDriver::setForceUFarads(bool enabled){
forceUFarads = enabled;
}
void isoDriver::setForceVolts(bool enabled){
forceVolts = enabled;
}
void isoDriver::setForceAmps(bool enabled){
forceAmps = enabled;
}
void isoDriver::setForceOhms(bool enabled){
forceOhms = enabled;
}
void isoDriver::setForceNFarads(bool enabled){
forceNFarads = enabled;
}
void isoDriver::setSerialDecodeEnabled_CH1(bool enabled){
serialDecodeEnabled_CH1 = enabled;
}
void isoDriver::setSerialDecodeEnabled_CH2(bool enabled){
serialDecodeEnabled_CH2 = enabled;
}
void isoDriver::setXYmode(bool enabled){
int graphCount = axes->graphCount();
static QVector<bool> graphState;
graphState.resize(graphCount);
if(enabled) // Hide graphs - we only want the X-Y plot to appear
{
xmin = 20;
xmax = -20;
ymin = 20;
ymax = -20;
for (int i=0; i < graphCount; i++)
{
qDebug() << "isVisible" << axes->graph(i)->visible();
graphState[i] = axes->graph(i)->visible();
axes->graph(i)->setVisible(false);
}
}
else // Restore State
{
for (int i=0; i < graphCount; i++)
{
qDebug() << "graphState" << graphState[i];
axes->graph(i)->setVisible(graphState[i]);
}
}
QCPCurve* curve = reinterpret_cast<QCPCurve*>(axes->plottable(0));
curve->setVisible(enabled);
emit enableCursorGroup(!enabled);
XYmode = enabled;
}
void isoDriver::triggerGroupStateChange(bool enabled){
if(enabled) sendTriggerValue((currentVmax-currentVmin)*0.85 + currentVmin);
}
void isoDriver::broadcastStats(bool CH2){
if (CH2 && update_CH2)
{
update_CH2 = false;
sendVmax_CH2(currentVmax);
sendVmin_CH2(currentVmin);
sendVmean_CH2(currentVmean);
sendVRMS_CH2(currentVRMS);
}
else if (update_CH1)
{
update_CH1 = false;
sendVmax_CH1(currentVmax);
sendVmin_CH1(currentVmin);
sendVmean_CH1(currentVmean);
sendVRMS_CH1(currentVRMS);
}
}
void isoDriver::slowTimerTick(){
update_CH1 = true;
update_CH2 = true;
bool frequencyLabelVisible = false;
if (triggerEnabled)
{
double triggerFrequency;
switch(triggerMode)
{
case 0:
case 1:
triggerFrequency = (driver->deviceMode == 6) ? internalBuffer750->getTriggerFrequencyHz() : internalBuffer375_CH1->getTriggerFrequencyHz();
break;
case 2:
case 3:
triggerFrequency = internalBuffer375_CH2->getTriggerFrequencyHz();
break;
}
if (triggerFrequency > 0.)
{
frequencyLabelVisible = true;
siprint triggerFreqSiprint("Hz", triggerFrequency);
siprint periodSiprint("s", 1. / triggerFrequency);
QString cursorString;
cursorString.sprintf(" Trigger ΔT = %s, f = %s ", periodSiprint.printVal(), triggerFreqSiprint.printVal());
triggerFrequencyLabel->setText(cursorString);
}
qDebug() << triggerFrequency << "Hz";
}
triggerFrequencyLabel->setVisible(frequencyLabelVisible);
}
void isoDriver::setTopRange(double newTop)
{
// NOTE: Should this be clamped to 20?
display.topRange = newTop;
topRangeUpdated(display.topRange);
}
void isoDriver::setBotRange(double newBot)
{
// NOTE: Should this be clamped to 20?
display.botRange = newBot;
botRangeUpdated(display.botRange);
}
void isoDriver::setTimeWindow(double newWindow){
display.window = newWindow;
timeWindowUpdated(display.window);
}
void isoDriver::setDelay(double newDelay){
display.delay = newDelay;
delayUpdated(display.delay);
}
void isoDriver::takeSnapshot(QString *fileName, unsigned char channel){
if(channel==1){
snapshotEnabled_CH1 = true;
QString fname_CH1 = *(fileName);
snapshotFile_CH1 = new QFile(fname_CH1);
qDebug() << fname_CH1;
} else if(channel==2){
snapshotEnabled_CH2 = true;
QString fname_CH2 = *(fileName);
snapshotFile_CH2 = new QFile(fname_CH2);
qDebug() << fname_CH2;
}
}
double isoDriver::meanVoltageLast(double seconds, unsigned char channel, int TOP){
isoBuffer *currentBuffer;
switch (channel){
case 1:
currentBuffer = internalBuffer375_CH1;
break;
case 2:
currentBuffer = internalBuffer375_CH2;
break;
case 3:
currentBuffer = internalBuffer750;
break;
}
std::unique_ptr<short[]> tempBuffer = currentBuffer->readBuffer(seconds, 1024, 0, 0);
double sum = 0;
double temp;
for(int i = 0; i<1024; i++){
temp = currentBuffer->sampleConvert(tempBuffer[i], TOP, 0);
sum += temp;
}
return sum / 1024;
}
void isoDriver::rSourceChanged(int newSource){
multimeterRsource = newSource;
}
void isoDriver::serialNeedsDisabling(int channel){
qDebug("isoDriver acknowledges disconnect from channel %d", channel);
mainWindowPleaseDisableSerial(channel);
}
//Thank you https://stackoverflow.com/questions/27318631/parsing-through-a-csv-file-in-qt
void isoDriver::loadFileBuffer(QFile *fileToLoad){
//Delete the current buffer if it exists
disableFileMode();
if(internalBufferFile != NULL){
delete internalBufferFile;
}
//Load the file
if (!fileToLoad->open(QIODevice::ReadOnly)) {
qDebug() << fileToLoad->errorString();
return;
}
QByteArray currentLine;
QList<QByteArray> tempList;
//First Header line
currentLine = fileToLoad->readLine();
qDebug() << currentLine;
//Averaging line
currentLine = fileToLoad->readLine();
qDebug() << currentLine;
tempList.append(currentLine.split('\n'));
tempList.append(currentLine.split('\r'));
tempList.append(tempList.first().split(' '));
qDebug() << tempList;
int averages = tempList.back().toInt();
qDebug() << averages;
//Mode line
tempList.clear();
currentLine = fileToLoad->readLine();
qDebug() << currentLine;
tempList.append(currentLine.split('\n'));
tempList.append(currentLine.split('\r'));
tempList.append(tempList.first().split(' '));
qDebug() << tempList;
int mode = tempList.back().toInt();
qDebug() << mode;
tempList.clear();
//Count the number of elements
qulonglong numel = 0;
while (!fileToLoad->atEnd()) {
currentLine = fileToLoad->readLine();
tempList.append(currentLine.split(','));
numel += tempList.count() - 1;
tempList.clear();
}
qDebug("There are %d elements!", numel);
//Prompt user for start and end times
double defaultSampleRate = 375000;
if(mode == 6){
defaultSampleRate = 750000;
}
double minTime = ((double)averages) / defaultSampleRate;
double maxTime = numel * ((double)averages) / defaultSampleRate;
qDebug() << "maxTime =" << maxTime;
daqLoadPrompt dlp(this, minTime, maxTime);
connect(&dlp, SIGNAL(startTime(double)), this, SLOT(daqLoad_startChanged(double)));
connect(&dlp, SIGNAL(endTime(double)), this, SLOT(daqLoad_endChanged(double)));
//Defaults
daqLoad_startTime = minTime;
daqLoad_endTime = maxTime;
dlp.exec();
//Initialise the (modified) isoBuffer.
int bufferLen = (int)(((daqLoad_endTime - daqLoad_startTime)/minTime) * 1.1) + 1; //Add a bit on to account for rounding error. Int conversion rounds down, so we add 1.
qDebug() << "daqLoad_endTime" << daqLoad_endTime;
qDebug() << "daqLoad_startTime" << daqLoad_startTime;
qDebug() << "minTime" << minTime;
qDebug() << "bufferLen" << bufferLen;
double sampleRate_Hz = defaultSampleRate/averages;
internalBufferFile = new isoBuffer_file(this, bufferLen, sampleRate_Hz);
//Go to start of data section
fileToLoad->seek(0);//Return to start
currentLine = fileToLoad->readLine(); //Chew up header
qDebug() << currentLine;
currentLine = fileToLoad->readLine(); //Chew up averages line
qDebug() << currentLine;
currentLine = fileToLoad->readLine(); //Chew up mode line
qDebug() << currentLine;
tempList.clear();
//Copy the data into the (modified) isoBuffer
float tempArray[COLUMN_BREAK + 1]; //751 elements per row with the old files; this just avoids a possible crash;
int temp_len;
qulonglong sampleCount = 0;
qulonglong minCount = (daqLoad_startTime / minTime);
qulonglong maxCount = (daqLoad_endTime / minTime);
qDebug() << "minCount" << minCount;
qDebug() << "maxCount" << maxCount;
int min_i;
int tempCount;
qDebug() << "Loading data into isoBuffer_file";
while (!fileToLoad->atEnd()) {
currentLine = fileToLoad->readLine();
tempList.append(currentLine.split(','));
tempList.removeLast(); //Last element is a "\n", not a number.
temp_len = 0;
tempCount = tempList.count();
min_i = 2000000000; //Arbitrary big number.
for (int i=0; i<tempCount; i++){
if((sampleCount > minCount) && (sampleCount < maxCount)){
if(i < min_i){
min_i = i;
}
tempArray[i] = tempList.at(i).toFloat();
temp_len++;
}
sampleCount++;
}
internalBufferFile->writeBuffer_float(&tempArray[min_i], temp_len);
tempList.clear();
}
fileToLoad->close();
qDebug() << "Initialising timer";
//Initialise the file timer.
if (fileTimer != NULL){
delete fileTimer;
}
fileTimer = new QTimer();
fileTimer->setTimerType(Qt::PreciseTimer);
fileTimer->start(TIMER_PERIOD);
connect(fileTimer, SIGNAL(timeout()), this, SLOT(fileTimerTick()));
qDebug() << "File Buffer loaded!";
enableFileMode();
qDebug() << "File Mode Enabled";
}
void isoDriver::daqLoad_startChanged(double newStart){
qDebug() << "isoDriver::daqLoad_startChanged" << newStart;
daqLoad_startTime = newStart;
}
void isoDriver::daqLoad_endChanged(double newEnd){
qDebug() << "isoDriver::daqLoad_endChanged" << newEnd;
daqLoad_endTime = newEnd;
}
void isoDriver::fileTimerTick(){
//qDebug() << "isoDriver::fileTimerTick()";
frameActionGeneric(-2,0);
}
void isoDriver::enableFileMode(){
fileModeEnabled = true;
daq_maxWindowSize = daqLoad_endTime - daqLoad_startTime;
showRealtimeButton(true);
}
void isoDriver::disableFileMode(){
fileModeEnabled = false;
showRealtimeButton(false);
if(fileTimer != NULL){
fileTimer->stop();
}
//Shrink screen back, if necessary.
double mws = fileModeEnabled ? daq_maxWindowSize : ((double)MAX_WINDOW_SIZE);
if (display.window > mws)
{
display.window = mws;
timeWindowUpdated(display.window);
}
if ((display.window + display.delay) > mws)
{
display.delay -= display.window + display.delay - mws;
delayUpdated(display.delay);
}
if (display.delay < 0)
{
display.delay = 0;
delayUpdated(display.delay);
}
}
void isoDriver::setSerialType(unsigned char type)
{
serialType = type;
qDebug() << "Serial Type changed to" << serialType;
if(serialType == 1)
{
if (twoWire)
delete twoWire;
twoWire = new i2c::i2cDecoder(internalBuffer375_CH1, internalBuffer375_CH2, internalBuffer375_CH1->m_console1);
}
}
void isoDriver::hideCH1(bool enable)
{
axes->graph(0)->setVisible(!enable);
}
void isoDriver::hideCH2(bool enable)
{
axes->graph(1)->setVisible(!enable);
}
void isoDriver::triggerStateChanged()
{
if (!triggerEnabled)
{
internalBuffer375_CH1->setTriggerType(TriggerType::Disabled);
internalBuffer375_CH2->setTriggerType(TriggerType::Disabled);
internalBuffer750->setTriggerType(TriggerType::Disabled);
return;
}
qDebug() << "triggerStateChanged()";
switch(triggerMode)
{
case 0:
{
internalBuffer375_CH1->setTriggerType(TriggerType::Rising);
internalBuffer375_CH2->setTriggerType(TriggerType::Disabled);
internalBuffer750->setTriggerType(TriggerType::Rising);
break;
}
case 1:
{
internalBuffer375_CH1->setTriggerType(TriggerType::Falling);
internalBuffer375_CH2->setTriggerType(TriggerType::Disabled);
internalBuffer750->setTriggerType(TriggerType::Falling);
break;
}
case 2:
{
internalBuffer375_CH1->setTriggerType(TriggerType::Disabled);
internalBuffer375_CH2->setTriggerType(TriggerType::Rising);
internalBuffer750->setTriggerType(TriggerType::Disabled);
break;
}
case 3:
{
internalBuffer375_CH1->setTriggerType(TriggerType::Disabled);
internalBuffer375_CH2->setTriggerType(TriggerType::Falling);
internalBuffer750->setTriggerType(TriggerType::Disabled);
break;
}
}
}
void isoDriver::offsetChanged_CH1(double newOffset)
{
m_offset_CH1 = newOffset;
}
void isoDriver::offsetChanged_CH2(double newOffset)
{
m_offset_CH2 = newOffset;
}
void isoDriver::attenuationChanged_CH1(int attenuationIndex)
{
switch(attenuationIndex)
{
case 0:
m_attenuation_CH1 = 1;
break;
case 1:
m_attenuation_CH1 = 5;
break;
case 2:
m_attenuation_CH1 = 10;
break;
default:
throw std::runtime_error("Unknown attenuation index for CH1");
}
}
void isoDriver::attenuationChanged_CH2(int attenuationIndex)
{
switch(attenuationIndex)
{
case 0:
m_attenuation_CH2 = 1;
break;
case 1:
m_attenuation_CH2 = 5;
break;
case 2:
m_attenuation_CH2 = 10;
break;
default:
throw std::runtime_error("Unknown attenuation index for CH2");
}
}
void isoDriver::setHexDisplay_CH1(bool enabled)
{
hexDisplay_CH1 = enabled;
}
void isoDriver::setHexDisplay_CH2(bool enabled)
{
hexDisplay_CH2 = enabled;
}
void isoDriver::setMinSpectrum(int minSpectrum)
{
m_spectrumMinX = static_cast<double>(minSpectrum);
}
void isoDriver::setMaxSpectrum(int maxSpectrum)
{
m_spectrumMaxX = static_cast<double>(maxSpectrum);
}