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AlignHor.ino
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AlignHor.ino
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// -----------------------------------------------------------------------------------
// GEOMETRIC ALIGN FOR ALT/AZ
//
// by Howard Dutton
//
// Copyright (C) 2012 to 2020 Howard Dutton
//
// -----------------------------------------------------------------------------------
// ADVANCED GEOMETRIC ALIGN FOR ALT/AZ MOUNTS (GOTO ASSIST)
#if MOUNT_TYPE == ALTAZM
// Initialize
void TGeoAlignH::init() {
avgAlt=0.0;
avgAzm=0.0;
ax1Cor=0; // align internal index for Axis1
ax2Cor=0; // align internal index for Axis2
altCor=0; // for geometric coordinate correction/align, - is below the Zenith, + above
azmCor=0; // - is right of the Zenith, + is left
doCor =0; // altitude axis/optics orthogonal correction
pdCor =0; // altitude axis/Azimuth orthogonal correction
dfCor =0; // altitude axis axis flex
tfCor =0; // tube flex
geo_ready=false;
}
// remember the alignment between sessions
void TGeoAlignH::readCoe() {
ax1Cor=nv.readFloat(EE_ax1Cor);
if (ax1Cor < -360 || ax1Cor > 360) { ax1Cor=0.0; DLF("ERR, readCoe(): bad NV ax1Cor"); }
ax2Cor=nv.readFloat(EE_ax2Cor);
if (ax2Cor < -360 || ax2Cor > 360) { ax2Cor=0.0; DLF("ERR, readCoe(): bad NV ax2Cor"); }
dfCor=nv.readFloat(EE_dfCor); // dfCor is ffCor for fork mounts
if (dfCor < -10 || dfCor > 10) { dfCor=0.0; DLF("ERR, readCoe(): bad NV dfCor"); }
tfCor=nv.readFloat(EE_tfCor);
if (tfCor < -10 || tfCor > 10) { tfCor=0.0; DLF("ERR, readCoe(): bad NV tfCor"); }
doCor=nv.readFloat(EE_doCor);
if (doCor < -10 || doCor > 10) { doCor=0.0; DLF("ERR, readCoe(): bad NV doCor"); }
pdCor=nv.readFloat(EE_pdCor);
if (pdCor < -10 || pdCor > 10) { pdCor=0.0; DLF("ERR, readCoe(): bad NV pdCor"); }
altCor=nv.readFloat(EE_altCor);
if (altCor < -10 || altCor > 10) { altCor=0.0; DLF("ERR, readCoe(): bad NV altCor"); }
azmCor=nv.readFloat(EE_azmCor);
if (azmCor < -10 || azmCor > 10) { azmCor=0.0; DLF("ERR, readCoe(): bad NV azmCor"); }
}
void TGeoAlignH::writeCoe() {
nv.writeFloat(EE_ax1Cor,ax1Cor);
nv.writeFloat(EE_ax2Cor,ax2Cor);
nv.writeFloat(EE_dfCor,dfCor); // dfCor is ffCor for fork mounts
nv.writeFloat(EE_tfCor,tfCor);
nv.writeFloat(EE_doCor,doCor);
nv.writeFloat(EE_pdCor,pdCor);
nv.writeFloat(EE_altCor,altCor);
nv.writeFloat(EE_azmCor,azmCor);
}
// Status
bool TGeoAlignH::isReady() {
return geo_ready;
}
// I=1 for 1st star, I=2 for 2nd star, I=3 for 3rd star
// N=total number of stars for this align (1 to 9)
// RA, Dec (all in degrees)
CommandErrors TGeoAlignH::addStar(int I, int N, double RA, double Dec) {
double a,z;
equToHor(haRange(LST()*15.0-RA),Dec,&a,&z);
// First star, just sync
if (I == 1) {
CommandErrors e=syncEqu(RA,Dec);
if (e != CE_NONE) return e;
}
mount[I-1].azm=getInstrAxis1();
mount[I-1].alt=getInstrAxis2();
horToEqu(mount[I-1].alt,mount[I-1].azm,&mount[I-1].ha,&mount[I-1].dec);
mount[I-1].azm=mount[I-1].azm/Rad;
mount[I-1].alt=mount[I-1].alt/Rad;
mount[I-1].ha=degRange(mount[I-1].ha)/Rad;
mount[I-1].dec=mount[I-1].dec/Rad;
actual[I-1].ha =haRange(LST()*15.0-RA);
actual[I-1].dec=Dec;
equToHor(actual[I-1].ha,actual[I-1].dec,&actual[I-1].alt,&actual[I-1].azm);
actual[I-1].alt=actual[I-1].alt/Rad;
actual[I-1].azm=actual[I-1].azm/Rad;
actual[I-1].ha =degRange(actual[I-1].ha)/Rad;
actual[I-1].dec=actual[I-1].dec/Rad;
if (getInstrPierSide() == PierSideWest) { actual[I-1].side=-1; mount[I-1].side=-1; } else
if (getInstrPierSide() == PierSideEast) { actual[I-1].side=1; mount[I-1].side=1; } else { actual[I-1].side=0; mount[I-1].side=0; }
// two or more stars and finished
if ((I >= 2) && (I == N)) model(N);
return CE_NONE;
}
// kick off modeling
void TGeoAlignH::model(int n) {
static bool busy=false;
static int numStars=0;
if (busy) return; // busy
if (n > 0) { numStars=n; return; } // command
if (numStars > 0) { busy=true; autoModel(numStars); busy=false; numStars=0; } // waiting to solve
}
// returns the correction to be added to the requested RA,Dec to yield the actual RA,Dec that we will arrive at
void TGeoAlignH::correct(double azm, double alt, double pierSide, double sf, double _deo, double _pd, double _pz, double _pe, double _df, double _ff, double _tf, double *z1, double *a1) {
double DO1,DOh;
double PD,PDh;
double PZ,PA;
double DF,DFd,TF,FF,FFd,TFh,TFd;
double cosAlt=cos(alt);
double tanAlt=tan(alt);
double sinAzm=sin(azm);
double cosAzm=cos(azm);
// ------------------------------------------------------------
// A. Misalignment due to tube/optics not being perp. to Dec axis
// negative numbers are further (S) from the NCP, swing to the
// equator and the effect on declination is 0. At the SCP it
// becomes a (N) offset. Unchanged with meridian flips.
DO1 =_deo*sf;
// works on HA. meridian flips effect this in HA
DOh = DO1*(1.0/cosAlt)*pierSide;
// ------------------------------------------------------------
// B. Misalignment, Declination axis relative to Polar axis
// expressed as a correction to where the Polar axis is pointing
// negative numbers are further (S) from the NCP, swing to the
// equator and the effect on declination is 0.
// At the SCP it is, again, a (S) offset
PD =_pd*sf;
// works on HA.
PDh = -PD*tanAlt*pierSide;
// ------------------------------------------------------------
// Misalignment, relative to NCP
// negative numbers are east of the pole
// C. polar left-right misalignment
PZ =_pz*sf;
// D. negative numbers are below the pole
// polar below-above misalignment
PA =_pe*sf;
// ------------------------------------------------------------
// Axis flex
DF =_df*sf;
DFd =-DF*(cosLat*cosAzm+sinLat*tanAlt);
// ------------------------------------------------------------
// Fork flex
FF =_ff*sf;
FFd =FF*cosAzm;
// ------------------------------------------------------------
// Optical axis sag
TF =_tf*sf;
TFh =TF*(cosLat*sinAzm*(1.0/cosAlt));
TFd =TF*(cosLat*cosAzm-sinLat*cosAlt);
// ------------------------------------------------------------
*z1 =(-PZ*cosAzm*tanAlt + PA*sinAzm*tanAlt + DOh + PDh + TFh);
*a1 =(+PZ*sinAzm + PA*cosAzm + DFd + FFd + TFd);
}
void TGeoAlignH::do_search(double sf, int p1, int p2, int p3, int p4, int p5, int p6, int p7, int p8, int p9)
{
long l,
_deo_m,_deo_p,
_pd_m,_pd_p,
_pz_m,_pz_p,
_pe_m,_pe_p,
_df_m,_df_p,
_tf_m,_tf_p,
_ff_m,_ff_p,
_oh_m,_oh_p,
_od_m,_od_p,
_deo,_pd,_pz,_pe, _df,_tf,_ff, _ode,_ohe;
double sf1=sf/(3600.0*Rad);
// search
// set Parameter Space
_deo_m=-p1+round(best_deo/sf); _deo_p=p1+round(best_deo/sf);
_pd_m =-p2+round(best_pd/sf); _pd_p=p2+round(best_pd/sf);
_pz_m =-p3+round(best_pz/sf); _pz_p=p3+round(best_pz/sf);
_pe_m =-p4+round(best_pe/sf); _pe_p=p4+round(best_pe/sf);
_tf_m =-p5+round(best_tf/sf); _tf_p=p5+round(best_tf/sf);
_ff_m =-p6+round(best_ff/sf); _ff_p=p6+round(best_ff/sf);
_df_m =-p7+round(best_df/sf); _df_p=p7+round(best_df/sf);
_od_m =-p8+round(best_ode/sf); _od_p=p8+round(best_ode/sf);
_oh_m =-p9+round(best_ohe/sf); _oh_p=p9+round(best_ohe/sf);
double ma,mz;
for (_deo=_deo_m; _deo <= _deo_p; _deo++)
for (_pd=_pd_m; _pd <= _pd_p; _pd++)
for (_pz=_pz_m; _pz <= _pz_p; _pz++)
for (_pe=_pe_m; _pe <= _pe_p; _pe++)
for (_df=_df_m; _df <= _df_p; _df++)
for (_ff=_ff_m; _ff <= _ff_p; _ff++)
for (_tf=_tf_m; _tf <= _tf_p; _tf++)
for (_ohe=_oh_m; _ohe <= _oh_p; _ohe++)
for (_ode=_od_m; _ode <= _od_p; _ode++) {
ode=((double)_ode)*sf1;
odw=-ode;
ohe=((double)_ohe)*sf1;
ohw=ohe;
// check the combinations for all samples
for (l=0; l < num; l++) {
mz=mount[l].azm;
ma=mount[l].alt;
if (mount[l].side == -1) // west of the mount
{
mz=mz+ohw;
ma=ma+odw;
} else
if (mount[l].side == 1) // east of the mount, default (fork mounts)
{
mz=mz+ohe;
ma=ma+ode;
}
correct(mz,ma,mount[l].side,sf1,_deo,_pd,_pz,_pe,_df,_ff,_tf,&z1,&a1);
delta[l].azm=actual[l].azm-(mz-z1);
if (delta[l].azm > PI) delta[l].azm=delta[l].azm-PI*2.0; else
if (delta[l].azm < -PI) delta[l].azm=delta[l].azm+PI*2.0;
delta[l].alt=actual[l].alt-(ma-a1);
delta[l].side=mount[l].side;
}
// calculate the standard deviations
sum1=0.0; for (l=0; l < num; l++) sum1=sum1+sq(delta[l].azm*cos(actual[l].alt)); sz=sqrt(sum1/(num-1));
sum1=0.0; for (l=0; l < num; l++) sum1=sum1+sq(delta[l].alt); sa=sqrt(sum1/(num-1));
max_dist=sqrt(sq(sz)+sq(sa));
// remember the best fit
if (max_dist < best_dist) {
best_dist =max_dist;
best_deo =((double)_deo)*sf;
best_pd =((double)_pd)*sf;
best_pz =((double)_pz)*sf;
best_pe =((double)_pe)*sf;
best_tf =((double)_tf)*sf;
best_df =((double)_df)*sf;
best_ff =((double)_ff)*sf;
if (p8 != 0) best_odw=odw*Rad*3600.0; else best_odw=best_pe/2.0;
if (p8 != 0) best_ode=ode*Rad*3600.0; else best_ode=-best_pe/2.0;
if (p9 != 0) best_ohw=ohw*Rad*3600.0;
if (p9 != 0) best_ohe=ohe*Rad*3600.0;
}
// keep the main loop running
loop2();
}
}
void TGeoAlignH::autoModel(int n) {
num=n; // how many stars?
lat=90.0/Rad; // 90 deg. latitude for Alt/Azm
cosLat=cos(lat);
sinLat=sin(lat);
best_dist =3600.0*180.0;
best_deo =0.0;
best_pd =0.0;
best_pz =0.0;
best_pe =0.0;
best_tf =0.0;
best_ff =0.0;
best_df =0.0;
best_ode =0.0;
best_ohe =0.0;
// figure out the average Az offset as a starting point
ohe=0;
for (l=0; l < num; l++) {
z1=actual[l].azm-mount[l].azm;
if (z1 > PI) z1=z1-PI*2.0;
if (z1 < -PI) z1=z1+PI*2.0;
ohe=ohe+z1;
}
ohe=ohe/num; best_ohe=round(ohe*Rad*3600.0); best_ohw=best_ohe;
// these don't apply for Alt/Az
Ff=0; Df=0;
// only search for cone error if > 2 stars
int Do=0; if (num > 2) Do=1;
// search, this can handle about 9 degrees of polar misalignment, and 4 degrees of cone error
// DoPdPzPeTfFf Df OdOh
do_search(16384,0 ,0,1,1,0, 0, 0,1,1);
do_search( 8192,Do,0,1,1,0, 0, 0,1,1);
do_search( 4096,Do,0,1,1,0, 0, 0,1,1);
do_search( 2048,Do,0,1,1,0, 0, 0,1,1);
do_search( 1024,Do,0,1,1,0, 0, 0,1,1);
do_search( 512,Do,0,1,1,0, 0, 0,1,1);
#ifdef HAL_SLOW_PROCESSOR
// DoPdPzPeTfFf Df OdOh
do_search( 256,Do,0,1,1,0, 0, 0,1,1);
do_search( 128,Do,0,1,1,0, 0, 0,1,1);
#else
if (num > 4) {
// DoPdPzPeTfFf Df OdOh
do_search( 256,Do,1,1,1,0,Ff,Df,1,1);
do_search( 128,Do,1,1,1,1,Ff,Df,1,1);
do_search( 64,Do,1,1,1,1,Ff,Df,1,1);
#ifdef HAL_FAST_PROCESSOR
do_search( 32,Do,1,1,1,1,Ff,Df,1,1);
do_search( 16,Do,1,1,1,1,Ff,Df,1,1);
#endif
} else {
do_search( 256,Do,0,1,1,0, 0, 0,1,1);
do_search( 128,Do,0,1,1,0, 0, 0,1,1);
do_search( 64,Do,0,1,1,0, 0, 0,1,1);
do_search( 32,Do,0,1,1,0, 0, 0,1,1);
#ifdef HAL_FAST_PROCESSOR
do_search( 16,Do,0,1,1,0, 0, 0,1,1);
#endif
}
#endif
// geometric corrections
doCor=best_deo/3600.0;
pdCor=best_pd/3600.0;
azmCor=best_pz/3600.0;
altCor=best_pe/3600.0;
tfCor=best_tf/3600.0;
#if MOUNT_TYPE == FORK || MOUNT_TYPE == ALTAZM
dfCor=best_ff/3600.0;
#else
dfCor=best_df/3600.0;
#endif
ax1Cor=best_ohw/3600.0;
ax2Cor=best_odw/3600.0;
geo_ready=true;
}
void TGeoAlignH::horToInstr(double Alt, double Azm, double *Alt1, double *Azm1, int PierSide) {
double p=1.0; if (PierSide == PierSideWest) p=-1.0;
double cosLat=cos(90.0/Rad); double sinLat=sin(90.0/Rad);
if (Alt > 90.0) Alt=90.0;
if (Alt < -90.0) Alt=-90.0;
// breaks-down near the Zenith (limited to > 1' from Zenith)
if (fabs(Alt) < 89.98333333) {
// initial rough guess at instrument HA,Dec
double z=Azm/Rad;
double a=Alt/Rad;
for (int pass=0; pass < 3; pass++) {
double sinAlt=sin(a);
double cosAlt=cos(a);
double sinAzm=sin(z);
double cosAzm=cos(z);
// ------------------------------------------------------------
// misalignment due to tube/optics not being perp. to Alt axis
// negative numbers are further (down) from the Zenith, swing to the
// horizon and the effect on Alt is 0. At the Nadir it
// becomes an (up) offset. Unchanged with meridian flips.
// expressed as a correction to the Zenith axis misalignment
double DOh=doCor*(1.0/cosAlt)*p;
// ------------------------------------------------------------
// misalignment due to Alt axis being perp. to Azm axis
double PDh=-pdCor*(sinAlt/cosAlt)*p;
#if MOUNT_TYPE == FORK || MOUNT_TYPE == ALTAZM
// Fork flex
double DFd=dfCor*cosAzm;
#else
// Axis flex
double DFd=-dfCor*(cosLat*cosAzm+sinLat*(sinAlt/cosAlt));
#endif
// Tube flex
double TFh=tfCor*(cosLat*sinAzm*(1.0/cosAlt));
double TFd=tfCor*(cosLat*cosAzm-sinLat*cosAlt);
// polar misalignment
double z1=-azmCor*cosAzm*(sinAlt/cosAlt) + altCor*sinAzm*(sinAlt/cosAlt);
double a1=+azmCor*sinAzm + altCor*cosAzm;
*Azm1=Azm + (z1+PDh+DOh+TFh);
*Alt1=Alt + (a1+DFd+TFd);
// improved guess at instrument Alt,Azm
z=*Azm1/Rad;
a=*Alt1/Rad;
}
} else {
// just ignore the the correction if right on the pole
*Azm1=Azm;
*Alt1=Alt;
}
// finally, apply the index offsets
*Azm1=*Azm1-ax1Cor;
*Alt1=*Alt1-ax2Cor*-p;
}
// takes the instrument equatorial coordinates and applies corrections to arrive at topocentric refracted coordinates
void TGeoAlignH::instrToHor(double Alt, double Azm, double *Alt1, double *Azm1, int PierSide) {
double p=1.0; if (PierSide == PierSideWest) p=-1.0;
double cosLat=cos(90.0/Rad); double sinLat=sin(90.0/Rad);
Azm=Azm+ax1Cor;
Alt=Alt+ax2Cor*-p;
if (Alt > 90.0) Alt=90.0;
if (Alt < -90.0) Alt=-90.0;
// breaks-down near the Zenith (limited to > 1' from Zenith)
if (fabs(Alt) < 89.98333333) {
double z=Azm/Rad;
double a=Alt/Rad;
double sinAlt=sin(a);
double cosAlt=cos(a);
double sinAzm=sin(z);
double cosAzm=cos(z);
// ------------------------------------------------------------
// misalignment due to tube/optics not being perp. to Alt axis
// negative numbers are further (S) from the Zenith, swing to the
// horizon and the effect on Alt is 0. At the Nadir it
// becomes a (N) offset. Unchanged with meridian flips.
// expressed as a correction to the Azm axis misalignment
double DOh=doCor*(1.0/cosAlt)*p;
// as the above offset becomes zero near the horizon, the affect
// works on Azm instead. meridian flips affect this in Azm
double PDh=-pdCor*(sinAlt/cosAlt)*p;
#if MOUNT_TYPE == FORK
// Fork flex
double DFd=dfCor*cosAzm;
#else
// Axis flex
double DFd=-dfCor*(cosLat*cosAzm+sinLat*(sinAlt/cosAlt));
#endif
// Tube flex
double TFh=tfCor*(cosLat*sinAzm*(1.0/cosAlt));
double TFd=tfCor*(cosLat*cosAzm-sinLat*cosAlt);
// ------------------------------------------------------------
// polar misalignment
double z1=-azmCor*cosAzm*(sinAlt/cosAlt) + altCor*sinAzm*(sinAlt/cosAlt);
double a1=+azmCor*sinAzm + altCor*cosAzm;
*Azm1=Azm - (z1+PDh+DOh+TFh);
*Alt1=Alt - (a1+DFd+TFd);
} else {
// just ignore the the correction if right on the pole
*Azm1=Azm;
*Alt1=Alt;
}
while (*Azm1 > 360.0) *Azm1-=360.0;
while (*Azm1 < -360.0) *Azm1+=360.0;
if (*Alt1 > 90.0) *Alt1=90.0;
if (*Alt1 < -90.0) *Alt1=-90.0;
}
#endif