One Dimensional Tracking Algorithm

This algorithm is used always in simple axis based MF tracking:

The algorithm consist of a state machine with the following states:

1. Tracking process
2. Full Synchronization follow the master
3. Stopping (de-synchronization process)

State: Full Synchronization follow the master

• Check if master velocity or acceleration exceeds max master frame's values if yes return an error
• track ← master copying all derivatives
• reset: flopstime = flops = 0

State: Tracking process

Initial Setup and testing

• Check if master velocity or acceleration exceeds max master frame's values if yes return an error
  

• Compute differences:
  

${\displaystyle pos_{diff}=master_{pos}-track_{pos}}$    pure delta-position
${\displaystyle vel_{diff}=master_{vel}-track_{vel}}$    pure delta-velocity

Time-to-Reach initial estimation

This is an estimation of time needed to reach the target. It is not an exact formula
if the velocity difference is positive, it means the robot velocity is lower then conveyors
therefore we need more time once to get to a higher velocity then the conveyers and once
to get from that (higher) velocity to conveyers - therefore the multiplication by 2

${\displaystyle time_{toreach}={\sqrt {\frac {K*|{vel_{diff}}|}{sync_{jrk}}}}+{\sqrt {\frac {4*|{pos_{diff}}|}{sync_{acc}}}}}$

where ${\displaystyle K={\begin{cases}4,&{\mbox{if }}vel_{diff}>0\\2,&{\mbox{if }}vel_{diff}\leq 0\end{cases}}}$

Additionally we multiply by a prediction factor - to decrease acc/jerk
(rounding to integer number of samples):

time_to_reach *= DampingFactor
time_to_reach = T*int(time_to_reach/T+1) 

Prediction of the Rendezvous-Point

The predicted position of the rendezvous (minus T, if it will happen in this sample!)
${\displaystyle pred_{pos}}$:  position prediction assuming constant acceleration
${\displaystyle pred_{diff}}$: Predicted position difference
${\displaystyle pred_{vel}}$:  velocity prediction

${\displaystyle t=(time_{toreach}-T)}$
${\displaystyle pred_{pos}=master_{pos}+t*master_{vel}+t^{2}*master_{acc}/2}$
${\displaystyle pred_{diff}=pred_{pos}-track_{pos}}$
${\displaystyle pred_{vel}=master_{vel}+t*master_{acc}}$

Assuming the acceleration will be zero:
${\displaystyle pred_{acc}=0}$

Polynomial coefficients of 5-degree polynom connecting the current p,v,a to the randevous p,v,a
${\displaystyle a0=track_{pos}}$ - not used, directly written into code
${\displaystyle a1=track_{vel}}$ - not used, directly written into code
${\displaystyle a2=0.5*track_{acc}}$ - not used, directly written into code
${\displaystyle a3=(0.5*(pred_{acc}-3*track_{acc})~+~(10*pred_{diff}/time_{toreach}}$${\displaystyle -~6*track_{vel}~-~4*pred_{vel})/time_{toreach})/time_{toreach}}$
${\displaystyle a4=(((5*pred_{diff}/time_{toreach}~-~(pred_{vel}+4*track_{vel}))/time_{toreach}}$${\displaystyle -1.5*track_{acc})/time_{toreach}~-~2*a3)/time_{toreach}}$
${\displaystyle a5=((((pred_{diff}/time_{toreach}~-~track_{vel})/time_{toreach}}$${\displaystyle -0.5*track_{acc})/time_{toreach}~-~a3)/time_{toreach}~-~a4)/time_{toreach}}$

Next SamplePosition

The position at the next sample will be:
Initial increment (full displacement): ${\displaystyle dp=a5*T^{5}+a4*T^{4}+a3*T^{3}+0.5*track_{acc}*T^{2}+track_{vel}*T}$

The accleration and jerk increments could be computed in this way also.
But they are computed as average values for the time of sample duration, this approach doeas fit more to
the tools we are using to test this feature, as they all compute acceleration & jerk by numeric differentiation
inside one sample.
The side effect of all this is that we can have a change in jerk/acc sign inside one sample and the average value we are using
ddp,dddp could have an opposite sign, so we are seeing effects like jerk or acceleration is limited from a "wrong side" i.e. instead
using jmax -jmax is used. There is not much we can do against it, using exact jerk/acc values (from polynom) returns than wrong average values
we observe as jerk/acc exceed over theri max values. So the average value approach is not perfect but gives results within the given limits.

Initial setting of predicted time and the filter limit flag (if the filter did work - this flag will be on)

limit        = false 
state.satVel = false 
state.satAcc = false  
state.satJrk = false 

Velocity, Acceleration and Jerk Filter

${\displaystyle dp={\begin{cases}sync_{velT},&{\mbox{if }}dp>sync_{velT}\\limit=true\\-sync_{velT},&{\mbox{if }}dp<-sync_{velT}\\limit=true\end{cases}}}$

Setting Initial velocity delta

${\displaystyle ddp=dp-dp_{0}}$

${\displaystyle ddp={\begin{cases}sync_{accT2},&{\mbox{if }}ddp>sync_{accT2}\\dp=sync_{accT2}+dp_{0}\\limit=true\\-sync_{accT2},&{\mbox{if }}ddp<-sync_{accT2}\\dp=-sync_{accT2}+dp_{0}\\limit=true\end{cases}}}$

Setting Initial acceleration delta

${\displaystyle dddp=ddp-ddp_{0}}$

${\displaystyle dddp={\begin{cases}sync_{jrkT3},&{\mbox{if }}dddp>sync_{jrkT3}\\ddp=sync_{jrkT3}+ddp_{0}\\dp=ddp+dp_{0}\\limit=true\\-sync_{jrkT3},&{\mbox{if }}dddp<-sync_{jrkT3}\\ddp=-sync_{jrkT3}+ddp_{0}\\dp=ddp+dp_{0}\\limit=true\end{cases}}}$

New position is:

${\displaystyle track_{pos}=track_{pos}+dp}$

If the filter was activated then:

if the velocity,accleration or jerk is limited (limit = true) then the velocity computed using polynomials does
${\displaystyle track_{vel}=dp/T}$
${\displaystyle track_{acc}=ddp/T^{2}}$

Velocity & Accleration will be computed exactly not using dp and ddp, it has been shown that this approach is much better - means more stable

${\displaystyle track_{vel}=5*a5*T^{4}+4*a4)*T^{3}+3*a3*T^{2}+track_{acc}*T+track_{vel}}$
${\displaystyle track_{acc}=20*a5*T^{3}+12*a4*T^{2}+6*a3*T+track_{acc}}$

keep the old values for next sample

ddp0 = ddp; 
dp0  = dp;

System is synchronized if NEW delta's are under certesian thresholds:

${\displaystyle dv_{0}=dv}$; - keep the previous dv
${\displaystyle dv=master_{vel}-track_{vel}}$

Successful tracking completion

if((fabs(dv) <= syncGain * sync_accT) && (fabs(master_pos - track_pos) <= syncGain * sync_accT2))
Synchronization
Take the middle for an additional smoothing:

track_pos	   =	0.5*(track_pos + master_pos);
track_vel	   =	0.5*(track_vel + master_vel);
ResetFilter();		// Reset the filter
state.tracking     =    MOT_MASTER_SYNC; // System synchronized<br>

else if( dv0*dv < 0)
Check against over-oscillation

if (flops == -1) flops = 0; // ignore the first sample
else	         flops++;
flopstime = 0;

Over-Oscillation Check

if (flops > maxFlops && (flopstime > maxFlopsTime && fabs(dv) > syncGain * sync_accT2))

state.tracking 	= MOT_MASTER_OSC; // OScilationss

else

flopstime++;

State: Stopping (de-synchronization process)

flopstime = flops = 0;

• De-Syncing profile, follow the given profile, ignore the real source

desync.Profile();
track_pos = track_pos_0+master_direction*desync.path.curr_pos;   	
track_vel = master_direction*desync.path.vel;			
track_acc = master_direction*desync.path.acc;			
if(desync.path.Status.stop)			// if stopped,change the state to OFF
	 SetState(MOT_MASTER_OFF);