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MoveTo.ino
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MoveTo.ino
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// -----------------------------------------------------------------------------------
// Functions to move the mount to the a new position
// moves the mount
void moveTo() {
// HA goes from +90...0..-90
// W . E
// meridian flip, first phase. only happens for GEM mounts
if ((pierSideControl == PierSideFlipEW1) || (pierSideControl == PierSideFlipWE1)) {
// save destination
cli();
origTargetAxis1.fixed = targetAxis1.fixed;
origTargetAxis2.fixed = targetAxis2.fixed;
timerRateAxis1=siderealRate;
timerRateAxis2=siderealRate;
sei();
// first phase, decide if we should move to 60 deg. HA (4 hours) to get away from the horizon limits or just go straight to the home position
if (pierSideControl == PierSideFlipWE1) {
if (homePositionAxis1 == 0.0) setTargetAxis1(0.0,PierSideWest); else {
if ((currentAlt < 10.0) && (getStartAxis1() > -90.0)) setTargetAxis1(-60.0,PierSideWest); else setTargetAxis1(-homePositionAxis1,PierSideWest);
}
setTargetAxis2(homePositionAxis2,PierSideWest);
} else {
if (homePositionAxis1 == 0.0) setTargetAxis1(0.0,PierSideEast); else {
if ((currentAlt < 10.0) && (getStartAxis1() < 90.0)) setTargetAxis1(60.0,PierSideEast); else setTargetAxis1(homePositionAxis1,PierSideEast);
}
setTargetAxis2(homePositionAxis2,PierSideEast);
}
// first phase, override above for additional waypoints
if (homePositionAxis2 > 0.0) {
if (getInstrAxis2() > 90.0-latitude) {
// if Dec is in the general area of the pole, slew both axis back at once
if (pierSideControl == PierSideFlipWE1) setTargetAxis1(-homePositionAxis1,PierSideWest); else setTargetAxis1(homePositionAxis1,PierSideEast);
} else {
// if we're at a low latitude and in the opposite sky, |HA|=6 is very low on the horizon in this orientation and we need to delay arriving there during a meridian flip
// in the extreme case, where the user is very near the (Earths!) equator an Horizon limit of -10 or -15 may be necessary for proper operation.
if (currentAlt < 20.0 && latitudeAbs < 45.0 && getInstrAxis2() < 0.0) {
if (pierSideControl == PierSideFlipWE1) setTargetAxis1(-45.0,PierSideWest); else setTargetAxis1(45.0,PierSideEast);
}
}
} else {
if (getInstrAxis2() < -90.0-latitude) {
// if Dec is in the general area of the pole, slew both axis back at once
if (pierSideControl == PierSideFlipWE1) setTargetAxis1(-homePositionAxis1,PierSideWest); else setTargetAxis1(homePositionAxis1,PierSideEast);
} else {
// if we're at a low latitude and in the opposite sky, |HA|=6 is very low on the horizon in this orientation and we need to delay arriving there during a meridian flip
if (currentAlt < 20.0 && latitudeAbs < 45.0 && getInstrAxis2() > 0.0) {
if (pierSideControl == PierSideFlipWE1) setTargetAxis1(-45.0,PierSideWest); else setTargetAxis1(45.0,PierSideEast);
}
}
}
pierSideControl++;
forceRefreshGetEqu();
}
long distStartAxis1,distStartAxis2,distDestAxis1,distDestAxis2;
cli();
distStartAxis1=labs(posAxis1-startAxis1); // distance from start Axis1
distStartAxis2=labs(posAxis2-startAxis2); // distance from start Axis2
sei();
if (distStartAxis1 < 1) distStartAxis1=1;
if (distStartAxis2 < 1) distStartAxis2=1;
cli();
distDestAxis1=labs(posAxis1-(long)targetAxis1.part.m); // distance from dest Axis1
distDestAxis2=labs(posAxis2-(long)targetAxis2.part.m); // distance from dest Axis2
sei();
// adjust rates near the horizon to help keep from exceeding the minAlt limit
#if MOUNT_TYPE != ALTAZM
if (latitudeAbs > 10) {
long posAxis2=latitudeSign*getInstrAxis2()*axis2Settings.stepsPerMeasure;
static long lastPosAxis2=0;
double distDestLimit=currentAlt-(minAlt+10.0); if (distDestLimit < SLEW_ACCELERATION_DIST/8.0) distDestLimit=SLEW_ACCELERATION_DIST/8.0;
// if Dec is decreasing slow down the Dec axis, if Dec is increasing slow down the RA axis
if (posAxis2 < lastPosAxis2) {
if (distDestLimit*axis2Settings.stepsPerMeasure < distDestAxis2) distDestAxis2=distDestLimit*axis2Settings.stepsPerMeasure;
} else {
if (distDestLimit*axis1Settings.stepsPerMeasure < distDestAxis1) distDestAxis1=distDestLimit*axis1Settings.stepsPerMeasure;
}
lastPosAxis2=posAxis2;
}
#endif
if (distDestAxis1 < 1) distDestAxis1=1;
if (distDestAxis2 < 1) distDestAxis2=1;
// quickly slow the motors and stop in SLEW_RAPID_STOP_DIST
static double deaccXPerSec=0;
static double a1r=0;
static double a2r=0;
if (abortGoto == 1) {
// aborts any meridian flip
if ((pierSideControl == PierSideFlipWE1) || (pierSideControl == PierSideFlipWE2) || (pierSideControl == PierSideFlipWE3)) pierSideControl=PierSideWest;
if ((pierSideControl == PierSideFlipEW1) || (pierSideControl == PierSideFlipEW2) || (pierSideControl == PierSideFlipEW3)) pierSideControl=PierSideEast;
if (pauseHome) { waitingHome=false; waitingHomeContinue=false; }
// stop parking/homing
if (parkStatus == Parking) {
lastTrackingState=abortTrackingState;
parkStatus=NotParked;
nv.write(EE_parkStatus,parkStatus);
} else
if (homeMount) {
lastTrackingState=abortTrackingState;
homeMount=false;
}
// set rate (in X sidereal) at which we slow down from
double rateXPerSec = RateToXPerSec/(maxRate/16.0);
double numSecToStop = (SLEW_RAPID_STOP_DIST/(rateXPerSec/240.0));
deaccXPerSec = (SLEW_RAPID_STOP_DIST/numSecToStop)*240.0;
abortGoto++;
}
// First, for Right Ascension
long temp;
if (distStartAxis1 > distDestAxis1) {
temp=(stepsForRateChangeAxis1/isqrt32(distDestAxis1)); // slow down (temp gets bigger)
} else {
temp=(stepsForRateChangeAxis1/isqrt32(distStartAxis1)); // speed up (temp gets smaller)
}
if (temp < maxRate) temp=maxRate; // fastest rate
if (temp > backlashTakeupRate) temp=backlashTakeupRate; // slowest rate
if (abortGoto != 0) {
if (abortGoto == 2) { a1r=(double)siderealRate/(double)temp; } else
if (abortGoto == 3) {
double r=1.2-sqrt((fabs(a1r)/slewRateX));
if (r < 0.2) r=0.2; if (r > 1.2) r=1.2;
a1r-=(deaccXPerSec/100.0)*r; if (a1r < 2.0) a1r=2.0;
}
temp=round((double)siderealRate/a1r);
}
cli(); timerRateAxis1=temp; sei();
// Now, for Declination
if (distStartAxis2 > distDestAxis2) {
temp=(stepsForRateChangeAxis2/isqrt32(distDestAxis2)); // slow down
} else {
temp=(stepsForRateChangeAxis2/isqrt32(distStartAxis2)); // speed up
}
if (temp < maxRate) temp=maxRate; // fastest rate
if (temp > backlashTakeupRate) temp=backlashTakeupRate; // slowest rate
if (abortGoto != 0) {
if (abortGoto == 2) { a2r=(double)siderealRate/(double)temp; abortGoto++; } else
if (abortGoto == 3) {
double r=1.2-sqrt((fabs(a2r)/slewRateX));
if (r < 0.2) r=0.2; if (r > 1.2) r=1.2;
a2r-=(deaccXPerSec/100.0)*r;
if (a2r < 2.00) a2r=2.0;
if ((a1r < 2.00001) && (a2r < 2.00001)) abortGoto++;
} else
if (abortGoto == 4) { abortGoto=0; cli(); targetAxis1.part.m=posAxis1; targetAxis2.part.m=posAxis2; sei(); distDestAxis1=0; distDestAxis2=0; }
temp=round((double)siderealRate/a2r);
}
cli(); timerRateAxis2=temp; sei();
// make sure we're using the tracking mode microstep setting near the end of slew
if (distDestAxis1 <= getstepsPerSecondAxis1()) axis1DriverTrackingMode(false);
if (distDestAxis2 <= getstepsPerSecondAxis2()) axis2DriverTrackingMode(false);
// the end of slew doesn't get close enough within 4 seconds force the slew to end
static unsigned long slewStopTime=0;
static bool slewEnding=false;
static bool slewForceEnd=false;
if (!slewEnding && (distDestAxis1 <= getstepsPerSecondAxis1()*4.0) && (distDestAxis2 <= getstepsPerSecondAxis2()*4.0) ) { slewStopTime=millis()+4000L; slewEnding=true; }
if (slewEnding && ((long)(millis()-slewStopTime) > 0)) {
if (abortGoto != 0) { cli(); targetAxis1.part.m=posAxis1; targetAxis2.part.m=posAxis2; sei(); }
slewForceEnd=true;
}
if ( ((distDestAxis1 <= ceil(fabs(fixedToDouble(fstepAxis1)))+4) && (distDestAxis2 <= ceil(fabs(fixedToDouble(fstepAxis2)))+4) ) || slewForceEnd ) {
slewEnding=false;
slewForceEnd=false;
abortGoto=0;
// assurance that we're really in tracking mode
axis1DriverTrackingMode(false);
axis2DriverTrackingMode(false);
if ((pierSideControl == PierSideFlipEW2) || (pierSideControl == PierSideFlipWE2)) {
// just wait stop here until we get notification to continue
if (pauseHome) {
if (!waitingHomeContinue) { waitingHome=true; return; }
soundAlert(); waitingHome=false; waitingHomeContinue=false;
}
// make sure we're at the home position just before flipping sides of the mount
cli();
startAxis1=posAxis1;
startAxis2=posAxis2;
sei();
if (homePositionAxis1 == 0.0) {
// for fork mounts
if (pierSideControl == PierSideFlipEW2) setTargetAxis1(180.0,PierSideEast); else setTargetAxis1(-180.0,PierSideWest);
} else {
// for eq mounts
if (pierSideControl == PierSideFlipEW2) setTargetAxis1(homePositionAxis1,PierSideEast); else setTargetAxis1(-homePositionAxis1,PierSideWest);
}
pierSideControl++;
axis1DriverGotoMode();
axis2DriverGotoMode();
forceRefreshGetEqu();
} else
if ((pierSideControl == PierSideFlipEW3) || (pierSideControl == PierSideFlipWE3)) {
if (pierSideControl == PierSideFlipEW3) pierSideControl=PierSideWest; else pierSideControl=PierSideEast;
// now complete the slew
cli();
startAxis1=posAxis1;
targetAxis1.fixed=origTargetAxis1.fixed;
startAxis2=posAxis2;
targetAxis2.fixed=origTargetAxis2.fixed;
sei();
axis1DriverGotoMode();
axis2DriverGotoMode();
forceRefreshGetEqu();
} else {
// other special gotos: for parking the mount and homing the mount
if (parkStatus == Parking) {
// clear the backlash
int pcbStatus=parkClearBacklash();
if (pcbStatus == PCB_BUSY) return;
// stop the motor timers (except guiding)
cli(); trackingTimerRateAxis1=0.0; trackingTimerRateAxis2=0.0; sei(); delay(11);
// restore trackingState
trackingState=lastTrackingState; lastTrackingState=TrackingNone;
SiderealClockSetInterval(siderealInterval);
// validate location
byte parkPierSide=nv.read(EE_pierSide);
if (pierSideControl != parkPierSide || pcbStatus != PCB_SUCCESS) { parkStatus=ParkFailed; nv.write(EE_parkStatus,parkStatus); }
// sound park done
soundAlert();
// wrap it up
parkFinish();
} else {
// restore last tracking state
cli();
timerRateAxis1=siderealRate;
timerRateAxis2=siderealRate;
sei();
if (homeMount) {
// clear the backlash
if (parkClearBacklash() == -1) return; // working, no error flagging
// sound goto done
soundAlert();
// restore trackingState
trackingState=lastTrackingState; lastTrackingState=TrackingNone;
SiderealClockSetInterval(siderealInterval);
// at the polar home position
homeMount=false;
if (AXIS2_TANGENT_ARM == OFF) atHome=true;
VLF("MSG: Homing done");
} else {
// restore trackingState
trackingState=lastTrackingState; lastTrackingState=TrackingNone;
SiderealClockSetInterval(siderealInterval);
setDeltaTrackingRate();
VLF("MSG: Goto done");
// allow 5 seconds for synchronization of coordinates after goto ends
if (trackingState == TrackingSidereal) {
trackingSyncSeconds=5;
VLF("MSG: Tracking sync started");
}
}
}
}
}
}
// fast integer square root routine, Integer Square Roots by Jack W. Crenshaw
uint32_t isqrt32 (uint32_t n) {
register uint32_t root=0, remainder, place= 0x40000000;
remainder = n;
while (place > remainder) place = place >> 2;
while (place) {
if (remainder >= root + place) {
remainder = remainder - root - place;
root = root + (place << 1);
}
root = root >> 1;
place = place >> 2;
}
return root;
}
// check for platform rate limit (lowest maxRate) in 1/16us units
long maxRateLowerLimit() {
double r_us=HAL_MAXRATE_LOWER_LIMIT; // for example 16us, this basis rate has platform (STM32/Teensy3.2/3.5/3.6/Mega2560), clock rate, and ISR operating mode (Sqw/Pulse/Dedge) factored in (from HAL.)
// higher speed ISR code path?
#if STEP_WAVE_FORM == PULSE || STEP_WAVE_FORM == DEDGE
r_us=r_us/1.6; // about 1.6x faster than SQW mode in my testing
#endif
// on-the-fly mode switching used?
#if MODE_SWITCH_BEFORE_SLEW == OFF
if (axis1StepsGoto != 1 || axis2StepsGoto != 1) r_us=r_us*1.7; // if this code is enabled, 27us
#endif
// average required goto us rates for each axis with any micro-step mode switching applied, if tracking in 32X mode using 4X for gotos (32/4 = 8,) that's an 8x lower true rate so 27/8 = 3.4 is allowed
double r_us_axis1=r_us/axis1StepsGoto;
double r_us_axis2=r_us/axis2StepsGoto;
// average in axis2 step rate scaling for drives where the reduction ratio isn't equal
r_us=(r_us_axis1+r_us_axis2/timerRateRatio)/2.0; // if Axis1 is 10000 step/deg & Axis2 is 20000 steps/deg, Axis2 needs to run 2x speed so we must slow down. 3.4 on one axis and 6.8 on the other for an average of 5.1
// the timer granulaity can start to make for some very abrupt rate changes below 0.25us
if (r_us < 0.25) { r_us=0.25; DLF("WRN, maxRateLowerLimit(): r_us exceeds design limit"); }
// return rate in 1/16us units
return round(r_us*16.0);
}