PBSwissMX/python/MXTuning.py

#!/usr/bin/env python
# *-----------------------------------------------------------------------*
# |                                                                       |
# |  Copyright (c) 2016 by Paul Scherrer Institute (http://www.psi.ch)    |
# |                                                                       |
# |              Author Thierry Zamofing (thierry.zamofing@psi.ch)        |
# *-----------------------------------------------------------------------*
'''
tuning functions for ESB-MX

Modes:
1 full recording current step
2 full recording open loop
3 full recording closed loop
4 plot the full bode recording
5 plot the full bode recording with an approximation model
6 plot all raw acquired data files

     -> check https://github.com/klauer/ppmac for fast data gathering server which supports
        phase gathering -> not yet compiling: /home/zamofing_t/Documents/prj/SwissFEL/PowerBrickInspector/ppmac/fast_gather
     BUT data acquired and stored in: /media/zamofing_t/DataUbuHD/VirtualBox/shared/data
'''

import os, sys, json, time
import numpy as np
import matplotlib as mpl
#mpl.use('GTKAgg')
import matplotlib.pyplot as plt
from scipy import signal

sys.path.insert(0,os.path.expanduser('~/Documents/prj/SwissFEL/PBTools/'))
#import pbtools.misc.pp_comm as pp_comm   -> pp_comm.PPComm
from  pbtools.misc.pp_comm import PPComm,GpasciiChannel
from  pbtools.misc.gather import Gather
from  pbtools.misc.tuning import Tuning


class MXTuning(Tuning):
    tuneDir='/opt/ppmac/tune/'

    def __init__(self,comm,gather):
      Tuning.__init__(self,comm,gather)


    def init_stage(self):
      comm=self.comm
      if comm is None: return
      gpascii=comm.gpascii
      sys.stdout.write('homing stage');sys.stdout.flush()
      gpascii.send_line('enable plc1')
      time.sleep(.2)
      while True:
        act=gpascii.get_variable('Plc[1].Active',type_=int)
        if act==0:
          sys.stdout.write('\n')
          break
        sys.stdout.write('.');sys.stdout.flush()
        time.sleep(.2)

      #Coord[%d].ProgActive if a running proc

    def bode_model_plot(self, mot,base):
      self.bode_full_plot(mot,base)
      fig=plt.gcf()
      _N=1.#E-3 # normalization factor: -> moves 3 decades to right but has factors around 1
                #  s     -> ms
                #  Hz    -> kHz
                #  rad/s -> rad/ms
      if mot==1:
        #identify matlab: k:0.671226 w0:134.705 damp:0.191004
        mag1=0.671226 #10**(db_mag1/20)
        db_mag1=20*np.log10(mag1)#dB
        w1=134.705*_N #rad/sec
        f1=w1/2/np.pi; # ca. 6.5Hz
        T1=1/w1
        d1=0.19 # daempfung =1 -> keine resonanz -> den1= np.poly1d([T1,1])**2
        num1=np.poly1d([mag1])
        den1 = np.poly1d([T1**2,2*T1*d1,1])

        #reiner integrator: 30Hz=0dB -> k=30*2*pi=180
        #num1=np.poly1d([120*120])
        #den1 = np.poly1d([1,0,0])


        #first resonance frequency
        f2=np.array([197,199])
        d2=np.array([.02,.02])#daempfung
        w2=f2*2*np.pi*_N #rad/sec
        T2=1/w2
        num2 = np.poly1d([T2[0]**2,2*T2[0]*d2[0],1])
        den2 = np.poly1d([T2[1]**2,2*T2[1]*d2[1],1])
        mdl= signal.lti(num2, den2) #num denum
        #bode(mdl)


        #current loop 2nd order approx
        #identification with matlab: k=1, w0=8725, d=0.75
        dc=.75        # daempfung =1 -> keine resonanz -> den1= np.poly1d([T1,1])**2
        wc=8725.*_N   # rad/sec
        #...but phase lag seems to have earlier effect -> reduce wc
        wc*=.5       # rad/sec
        fc=wc/2/np.pi # ca 1388Hz
        Tc=1/wc
        numc = np.poly1d([1.])
        denc = np.poly1d([Tc**2,2*Tc*dc,1])

        num=num1*num2*numc#*num3
        den=den1*den2*denc#*den3
        mdl= signal.lti(num, den) #num denum
        print(num)
        print(den)
        print(mdl)
        d={'num':num.coeffs,'num1':num1.coeffs,'num2':num2.coeffs,'numc':numc.coeffs,
           'den':den.coeffs,'den1':den1.coeffs,'den2':den2.coeffs,'denc':denc.coeffs}
        fn=os.path.join(base,'model%d.mat'%mot)
        import scipy.io
        scipy.io.savemat(fn, mdict=d)
        print('save to matlab file:'+fn)

      elif mot==2:
        #identify matlab: k:1.7282 w0:51.069 damp:0.327613
        mag1=1.7282 #10**(db_mag1/20)
        db_mag1=20*np.log10(mag1)#dB
        w1=51.069*_N #rad/sec
        f1=w1/2/np.pi; # ca. 6.5Hz
        T1=1/w1
        d1=0.32 # daempfung =1 -> keine resonanz -> den1= np.poly1d([T1,1])**2
        num1=np.poly1d([mag1])
        den1 = np.poly1d([T1**2,2*T1*d1,1])

        #resonance frequency
        f2=np.array([57.8,61.8])
        d2=np.array([.08,.095])#daempfung
        w2=f2*2*np.pi #rad/sec
        T2=1/w2
        num2 = np.poly1d([T2[0]**2,2*T2[0]*d2[0],1])
        den2 = np.poly1d([T2[1]**2,2*T2[1]*d2[1],1])
        mdl= signal.lti(num2, den2) #num denum
        #bode(mdl)

        #resonance frequency
        f3=np.array([136,148])
        d3=np.array([.05,.05])#daempfung
        w3=f3*2*np.pi #rad/sec
        T3=1/w3
        num3 = np.poly1d([T3[0]**2,2*T3[0]*d3[0],1])
        den3 = np.poly1d([T3[1]**2,2*T3[1]*d3[1],1])
        #mdl= signal.lti(num3, den3) #num denum
        #bode(mdl)

        #resonance frequency
        f4=np.array([410,417])
        d4=np.array([.015,.015])#daempfung
        w4=f4*2*np.pi #rad/sec
        T4=1/w4
        num4 = np.poly1d([T4[0]**2,2*T4[0]*d4[0],1])
        den4 = np.poly1d([T4[1]**2,2*T4[1]*d4[1],1])
        #mdl= signal.lti(num3, den3) #num denum
        #bode(mdl)

        #resonance frequency
        f5=np.array([230,233])
        d5=np.array([.04,.04])#daempfung
        w5=f5*2*np.pi #rad/sec
        T5=1/w5
        num5 = np.poly1d([T5[0]**2,2*T5[0]*d5[0],1])
        den5 = np.poly1d([T5[1]**2,2*T5[1]*d5[1],1])


        #current loop 2nd order approx
        #identification with matlab: k=1, w0=8725, d=0.75
        dc=.75        # daempfung =1 -> keine resonanz -> den1= np.poly1d([T1,1])**2
        wc=8725.*_N   # rad/sec
        #...but phase lag seems to have earlier effect -> reduce wc
        wc*=.5       # rad/sec
        fc=wc/2/np.pi # ca 1388Hz
        Tc=1/wc
        numc = np.poly1d([1.])
        denc = np.poly1d([Tc**2,2*Tc*dc,1])

        num=num1*num2*num3*num4*num5*numc
        den=den1*den2*den3*den4*den5*denc
        mdl= signal.lti(num, den) #num denum
        print(num)
        print(den)
        print(mdl)
        d={'num':num.coeffs,'num1':num1.coeffs,'num2':num2.coeffs,'num3':num3.coeffs,'num4':num4.coeffs,'num5':num5.coeffs,'numc':numc.coeffs,
           'den':den.coeffs,'den1':den1.coeffs,'den2':den2.coeffs,'den3':den3.coeffs,'den4':den4.coeffs,'den5':den5.coeffs,'denc':denc.coeffs}
        fn=os.path.join(base,'model%d.mat'%mot)
        import scipy.io
        scipy.io.savemat(fn, mdict=d)
        print('save to matlab file:'+fn)

      bode(mdl)
      w=np.logspace(0,np.log10(2000),1000)*2*np.pi
      w,mag,phase = signal.bode(mdl,w)
      f=w/(2*np.pi)
      ax=fig.axes[0]
      ax.semilogx(f, mag,'-k',lw=1)    # Bode magnitude plot
      ax=fig.axes[1]
      ax.semilogx(f, phase,'-k',lw=1)  # Bode phase plot
      # tp print see also: print(np.poly1d([1,2,3], variable='s')), print(np.poly1d([1,2,3], r=True, variable='s'))


def bode(mdl):
  w,mag,phase = signal.bode(mdl,1000)
  f=w/(2*np.pi)
  fig = plt.figure()
  ax = fig.add_subplot(2, 1, 1)
  ax.semilogx(f,mag,'-')  # Bode magnitude plot
  ax.yaxis.set_label_text('dB ampl')
  plt.grid(True)
  ax = fig.add_subplot(2, 1, 2)
  ax.semilogx(f,phase,'-')  # Bode magnitude plot
  ax.yaxis.set_label_text('phase')
  ax.xaxis.set_label_text('frequency [Hz]')
  plt.grid(True)
  #plt.show()


if __name__=='__main__':
  from argparse import ArgumentParser,RawDescriptionHelpFormatter
  import logging
  logger = logging.getLogger(__name__)
  #logger = logging.getLogger('pbtools.misc.pp_comm')
  logger.setLevel(logging.DEBUG)
  logging.basicConfig(format=('%(asctime)s %(name)-12s '
                              '%(levelname)-8s %(message)s'),
                      datefmt='%m-%d %H:%M',
                      )


  def parse_args():
    'main command line interpreter function'
    #usage: gpasciiCommunicator.py --host=PPMACZT84 myPowerBRICK.cfg
    (h, t)=os.path.split(sys.argv[0]);cmd='\n  '+(t if len(h)>3 else sys.argv[0])+' '
    exampleCmd=('-n',
                '-v15'
               )
    epilog=__doc__+'''
Examples:'''+''.join(map(lambda s:cmd+s, exampleCmd))+'\n '

    parser=ArgumentParser(epilog=epilog,formatter_class=RawDescriptionHelpFormatter)

    parser.add_argument('--host', help='hostname', metavar='HOST', default='SAR-CPPM-EXPMX1')
    parser.add_argument('--mode', '-m', type=int, help='modes (see below)', default=1)
    parser.add_argument('--dir', help='dir', default=None)

    args=parser.parse_args()

    #plt.ion()
    args.host='MOTTEST-CPPM-CRM0573'
    if args.host is None:
      comm=gt=None
    else:
      comm = PPComm(host=args.host)
      gt = Gather(comm)
    tune=MXTuning(comm,gt)
    base='MXTuning'
    if args.dir is not None:
      base=args.dir
    assert(os.path.exists(base))
      #base=os.path.join(base,args.dir)
      #if not os.path.exists(base):
      #  os.mkdir(base)


    mode=args.mode
    #plt.ion()
    if mode==1: # full recording current step
      homed=False
      for mot in (1, 2):
        fn=os.path.join(base, 'curr_step%d.npz' % mot)
        if not os.path.isfile(fn) and not homed: tune.init_stage();homed=True
        fig=plt.figure(mot)
        tune.bode_current(motor=mot, magMove=1000, magPhase=500, dwell=10, file=fn,fig=fig)
        plt.show(block=False)
        f=np.load(fn)
        fn=fn[:-3]+'mat'
        import scipy.io
        scipy.io.savemat(fn, mdict=f)
        print('save to matlab file:'+fn)


    elif mode==2:  # full recording open loop
      for mot in (1, 2):
        fsin=os.path.join(base, 'sine_ol_mot%d.npz' % (mot))
        fcrp=os.path.join(base, 'chirp_ol_mot%d' % (mot))
        if not os.path.isfile(fsin): tune.init_stage();plt.close('all')
        tune.bode_sine(openloop=True, file=fsin, motor=mot)
        plt.show(block=False)
        for ext,amp,minFrq,maxFrq,tSec in (('a', 10, 10, 300,30),
                                           ('b', 50,100, 500,30),
                                           ('c', 50,300,1500,10),
                                           ('d',100,300,2000,10)):
          f=fcrp+ext+'.npz'
          if not os.path.isfile(f): tune.init_stage();plt.close('all')
          tune.bode_chirp(openloop=True, file=f, motor=mot, amp=amp, minFrq=minFrq, maxFrq=maxFrq, tSec=tSec)
          plt.show(block=False)
    elif mode==3: # full recording closed loop
      for mot in (1,2):
        #fsin=os.path.join(base, 'sine_cl_mot%d.npz' % (mot))
        fcrp=os.path.join(base, 'chirp_cl_mot%d' % (mot))
        #if not os.path.isfile(fsin): tune.init_stage();plt.close('all')
        #tune.bode_sine(openloop=False, file=fsin, motor=mot)

        #the generated program is prog 999 (only during acquisition)
        # Gather.MaxLines=174762 -> ca 15 sec. is max.
        #with higher frequency and amplitudes often is in DacLimit !
        for ext,amp,minFrq,maxFrq,tSec in (('a',100,  1, 200,15),
                                           ('b', 20,10, 300,5),
                                           ('c',  5,10, 300,5),
                                           ('d',  1,10,1000,5),
                                           ):
          f=fcrp+ext+'.npz'
          if not os.path.isfile(f): tune.init_stage();plt.close('all')
          tune.bode_chirp(openloop=False, file=f, motor=mot, amp=amp, minFrq=minFrq, maxFrq=maxFrq, tSec=tSec)
          plt.show(block=False)
    elif mode==4: #plot the full bode recording
      tune.bode_full_plot(mot=1,base=base)
      tune.bode_full_plot(mot=2,base=base)
    elif mode==5: #plot the full bode recording with an approximation model
      tune.bode_model_plot(mot=1,base=base)
      tune.bode_model_plot(mot=2,base=base)

    elif mode == 6:  # plot all raw acquired data files
      # display bode plots
      for fn in args.plot:
        if os.path.basename(fn).startswith('sine_ol_mot'):
          tune.bode_sine(openloop=True, file=fn)
        if os.path.basename(fn).startswith('chirp_ol_mot'):
          tune.bode_chirp(openloop=True, file=fn)
        if os.path.basename(fn).startswith('sine_cl_mot'):
          tune.bode_sine(openloop=False, file=fn)
        if os.path.basename(fn).startswith('chirp_cl_mot'):
          tune.bode_chirp(openloop=False, file=fn)
      print('done')
    elif mode==7: #further tests
      #tune.init_stage();
      plt.close('all')
      #tune.custom_chirp()
      tune.custom_chirp(motor=1,minFrq=100,maxFrq=3000,amp=10,tSec=5,mode=0,file='/tmp/cst_chirp0.npz')
      #tune.custom_chirp(motor=2,minFrq=1,maxFrq=1000,tSec=5,mode=1,file='/tmp/cst_chirp1.npz')
      #tune.custom_chirp(motor=1,minFrq=1,maxFrq=3000,tSec=5,mode=2,file='/tmp/cst_chirp2.npz')

    plt.show()
  #------------------ Main Code ----------------------------------
  #ssh_test()
  ret=parse_args()
  exit(ret)

#enable plc1
#./PBTuning.py --host SAR-CPPM-EXPMX1 --mode 1 --mot 1 --dir tmp
#./PBTuning.py --host SAR-CPPM-EXPMX1 --mode 1 --mot 2 --dir tmp
#-> at low frequencied the speed is too high and encoder looses steps

#enable plc1
#AFTER each chirp measurement do enable plc1 again!
#./PBTuning.py --host SAR-CPPM-EXPMX1 --mode 2 --mot 1 --dir tmp
#./PBTuning.py --host SAR-CPPM-EXPMX1 --mode 2 --mot 2 --dir tmp


#./PBTuning.py --host SAR-CPPM-EXPMX1 --plot tmp