Exemplo n.º 1
0
    def __call__(self, lim_register_addr, cav_num=0):
        registers = []
        # Note that Tstep is the ADC time step, also clocks the LLRF controller.
        # Divide by two for the cavity simulator (rtsim) clock time step.
        Tstep = 10e-9  # s
        f0 = 1300e6  # Hz
        nyquist_sign = -1  # -1 represents frequency inversion,
        # as with high-side LO or even-numbered Nyquist zones.
        VPmax = 48.0  # V piezo drive max

        # as we scale up, the following 10 parameters replicate per cavity:
        PAmax = 6e3  # W RF amplifier max
        PAbw = 1.5e6  # Hz bandwidth of power amplifier
        cav_adc_max = 1.2  # sqrt(W)
        rfl_adc_max = 180.0  # sqrt(W)
        fwd_adc_max = 160.0  # sqrt(W)
        phase_1 = self.fwd_phase_shift  # forward monitor phase shift
        phase_2 = self.rfl_phase_shift  # reflected monitor prompt phase shift
        cav_adc_off = 10
        rfl_adc_off = 20
        fwd_adc_off = 30
        mode1 = Emode(name="pi",
                      RoverQ=1036.0,
                      foffset=self.mode1_foffset,
                      peakV=1.5e6,
                      Q_0=1e10,
                      Q_1=self.mode1_Q1,
                      Q_2=2e9,
                      phase_1=self.rfl_phase_shift,
                      phase_2=self.cav_phase_shift,
                      mech_couplings=[
                          self.net1_coupling, self.net2_coupling,
                          self.net3_coupling
                      ])
        mode2 = Emode(name="8pi/9",
                      RoverQ=10.0,
                      foffset=-8e5,
                      peakV=0.15e6,
                      Q_0=1e10,
                      Q_1=8.1e4,
                      Q_2=2e9,
                      phase_1=10,
                      phase_2=-180,
                      mech_couplings=[0, 0, 0])
        mmode1 = Mmode('silly', self.mmode1_freq, self.mmode1_Q, 1.13, 40000,
                       1, 80000)
        mmode2 = Mmode('lowQ', 100000, 5.0, 1.5, 80000, 1, 20000)
        mmode3 = Mmode('other', 24500, 25.0, 1.5, 20000, 1, 10000)

        # DDS setup for simulator should be static
        # this construction is for 20 MHz / 94.286 MHz = 7/33
        dds_num = 7
        dds_den = 33

        # The following three parameters are set in the Verilog at compile-time,
        # not run-time.  Top-level setting in larger.v needs to be mirrored here.
        lp_shift = 9  # see lp_pair.v, a.k.a. mode_shift
        n_mech_modes = 7  # number of mechanical modes handled
        df_scale = 9  # see cav4_freq.v
        omega0 = f0 * 2 * pi
        mech_tstep = Tstep * n_mech_modes
        interp_gain = n_mech_modes / 2**ceil(
            log(n_mech_modes) / log(2))  # interp0.v

        amp_bw = fix(Tstep * PAbw * 32, 18, "amp_bw")

        dds_phstep_h = int(dds_num * 2**20 / dds_den)
        dds_mult = int(4096 / dds_den)
        dds_phstep_l = (dds_num * 2**20) % dds_den * dds_mult
        dds_modulo = 4096 - dds_mult * dds_den
        dds_phstep = dds_phstep_h << 12 | dds_phstep_l
        #print "# dds",dds_mult,dds_phstep_h, dds_phstep_l, dds_modulo

        # four registers of pair_couple.v
        # neglect losses between directional coupler and cavity
        prompt = [
            fix(-sqrt(PAmax) / fwd_adc_max, 18, "out1", "cordic"),
            fix(-sqrt(PAmax) / rfl_adc_max, 18, "out2", "cordic"),
            fix(phase_1 / 180.0, 19, "out3"),
            fix(phase_2 / 180.0, 19, "out4")
        ]

        # Mechanical modes
        res_prop = []
        piezo_couple = []
        noise_couple = []
        dot_0_k = []
        outer_0_k = []
        dot_1_k = []
        outer_1_k = []
        dot_2_k = []
        outer_2_k = []
        mech_mode_list = [mmode1, mmode2, mmode3]
        for i, m in enumerate(mech_mode_list):
            # print "# Cavity mechanical mode %d: %s"%(i,m.name)
            w1 = mech_tstep * 2 * pi * m.freq
            # a1 + b1 * i represents the pole in the normalized s-plane
            a1 = w1 * (-1 / (2.0 * m.Q))
            b1 = w1 * sqrt(1 - 1 / (4.0 * m.Q**2))
            z_pole = cexp(a1 + b1 * 1j)
            # print "# z_pole = %7f + %7fi"%(z_pole.real,z_pole.imag)
            a1 = z_pole.real - 1.0
            b1 = z_pole.imag
            scale = int(-log(max(a1, b1)) / log(4))
            scale = max(min(scale, 9), 2)
            a2 = a1 * 4**scale
            b2 = b1 * 4**scale
            # print "# debug",w1,a1,b1,scale,a2,b2
            # c1 = -w1**2 / (k*b1)
            res_prop.append((fix(a2, 18, "a2") & (2**18 - 1)) +
                            ((9 - scale) << 18))
            res_prop.append((fix(b2, 18, "b2") & (2**18 - 1)) +
                            ((9 - scale) << 18))
            # the above is tested.  Onwards to the work-in-progress
            dc_gain = b2 / (a2**2 + b2**2)  # resonator.v
            m.dc_gain = dc_gain  # per-electical mode coupling computation will need this
            piezo_couple.append(m.piezo_hack)
            piezo_couple.append(0)
            noise_couple.append(m.vibration_hack)
            noise_couple.append(0)
            # dot_2_k.append(0)
            # dot_2_k.append(m.piezo_hack)

        for i, m in enumerate([mode1, mode2]):
            # print "# Cavity electrical mode %d: %s"%(i,m.name)
            Q_L = 1 / (1 / m.Q_0 + 1 / m.Q_1 + 1 / m.Q_2)
            # x is defined as sqrt(U)
            xmax = m.peakV / sqrt(m.RoverQ * omega0)
            # four registers of pair_couple.v
            out_coupling = [
                fix(
                    sqrt(omega0 / m.Q_1) * xmax / rfl_adc_max, 18,
                    m.name + ".out1", "cordic"),
                fix(
                    sqrt(omega0 / m.Q_2) * xmax / cav_adc_max, 18,
                    m.name + ".out2", "cordic"),
                fix(m.phase_1 / 180.0, 19, m.name + "out3"),
                fix(m.phase_2 / 180.0, 19, m.name + "out4")
            ]
            print out_coupling
            # see Pro tip in cav4_elec.v for better limit on foffset
            # XXX document using 33 for what's really a 28-bit register
            coarse_freq = fix(Tstep * nyquist_sign * m.foffset, 33,
                              m.name + "coarse_freq")
            V_achievable = 2 * sqrt(PAmax * m.Q_1 * m.RoverQ)
            drive_coupling = fix(V_achievable / m.peakV, 18,
                                 m.name + "drive_coupling", "cordic")
            # bandwidth in Hz = f_clk/2/2^shift/(2*pi) * bw_register/2^17 = omega_0/(2*pi*2*Q_L)
            # XXX document origin of *2.0 better, compensates for shift right in lp_pair.v
            bw = fix(Tstep * omega0 / (2 * Q_L) * (2**lp_shift) * 2.0, 18,
                     m.name + ".bw")
            registers.append(['coarse_freq', [cav_num, i], coarse_freq])
            registers.append(['drive_coupling', [cav_num, i], drive_coupling])
            registers.append(['bw', [cav_num, i], bw])
            registers.append(['out_coupling', [cav_num, i], out_coupling])
            for j, mech_couple in enumerate(m.mech_couplings):
                # print "# elec mode %d coupling index %d value %f"%(i,j,mech_couple)
                # Number of electrical modes implemented in the hardware is set by the
                # parameter mode_count in cav4_elec.v, frozen at the time of synthesis.
                # The address decode generator (newad.py) will embed mode index into a
                # text name, which is then given an address by addr_map.vh.  This explains
                # the funny-looking exec at the end of this stanze.
                mech_mode = mech_mode_list[j]
                Amn = sqrt(mech_couple / m.RoverQ) / omega0  # sqrt(J)/V^2
                Cmn = -sqrt(mech_couple * m.RoverQ) * omega0  # 1/s/sqrt(J)
                lorentz_en = 1
                outer = lorentz_en * Amn / mech_mode.mx * m.peakV**2 / mech_mode.dc_gain  # dimensionless
                inner = lorentz_en * Cmn * mech_mode.mx * Tstep / 2**df_scale / interp_gain  # dimensionless
                # note that inner*outer = net_coupling * mode1.peakV**2 * Tstep
                #print "# outer =",outer,"inner =",inner
                # additional scaling below comes from the 32-bit mech_phase_fine
                # accumulator, but only 18-bit d_result
                xx = fix(outer / 128, 18, "outer")
                yy = fix(inner / 128, 18, "inner")
                if i == 0:
                    outer_0_k.append(xx)
                    outer_0_k.append(0)
                    dot_0_k.append(0)
                    dot_0_k.append(yy)
                elif i == 1:
                    outer_1_k.append(xx)
                    outer_1_k.append(0)
                    dot_1_k.append(0)
                    dot_1_k.append(yy)
                #exec '''outer_%d_k.append(xx); outer_%d_k.append(0); dot_%d_k.append(0); dot_%d_k.append(yy)''' % (i,i,i,i)

        # Must be after electrical mode processing, to pick up outer_0_k etc.
        registers.append(['cav4_elec_phase_step', [cav_num], dds_phstep])
        registers.append(['cav4_elec_modulo', [cav_num], dds_modulo])
        registers.append(['amp_lp_bw', [cav_num], amp_bw])
        registers.append(['drive_couple_out_coupling', [cav_num], prompt])
        registers.append(['a_cav_offset', [cav_num], cav_adc_off])
        registers.append(['a_rfl_offset', [cav_num], rfl_adc_off])
        registers.append(['a_for_offset', [cav_num], fwd_adc_off])
        registers.append(['resonator_prop_const', [cav_num], res_prop])
        registers.append(['dot_0_k_out', [cav_num], dot_0_k])
        registers.append(['dot_1_k_out', [cav_num], dot_1_k])
        registers.append(['dot_2_k_out', [cav_num], dot_2_k])
        registers.append(['outer_prod_0_k_out', [cav_num], outer_0_k])
        registers.append(['outer_prod_1_k_out', [cav_num], outer_1_k])
        registers.append(['outer_prod_2_k_out', [cav_num], outer_2_k])
        registers.append(['piezo_couple', [cav_num], piezo_couple])
        registers.append(['noise_couple', [cav_num], noise_couple])

        # Pseudo-random generator initialization, see tt800v.v and prng.v
        prng_seed = "pushmi-pullyu"
        if prng_seed:
            #print "# PRNG subsystem seed is '%s'"%prng_seed
            hf = sha1()
            hf.update(prng_seed)
            for x in generate_seed(hf):
                registers.append(['prng_iva', [cav_num], x])
            for x in generate_seed(hf):
                registers.append(['prng_ivb', [cav_num], x])
        registers.append(['prng_random_run', [cav_num], self.PRNG_en])

        # Just hack in a few quick values for the controller
        # This should really be another construction as above, maybe in a separate Python module?
        # static DDS config, 7/33 as above
        # #print "17 %d  # phase_step"%dds_phstep
        # #print "18 %d  # modulo"%dds_modulo
        #print "phase_step %d  # phase_step"%dds_phstep
        #print "modulo %d  # modulo"%dds_modulo
        wave_samp_per = 1
        wave_shift = 3
        # The LO amplitude in the FPGA is scaled by (32/33)^2, so that yscale
        # fits nicely within the 32768 limit for small values of wave_samp_per
        lo_cheat = (32 / 33.0)**2
        yscale = lo_cheat * (33 * wave_samp_per)**2 * 4**(8 - wave_shift) / 32

        registers.append(['phase_step', [cav_num], dds_phstep])
        registers.append(['modulo', [cav_num], 4])
        registers.append(['wave_samp_per', [cav_num], wave_samp_per])
        registers.append(['wave_shift', [cav_num], wave_shift])
        registers.append(['piezo_dc', [cav_num], self.piezo_dc])
        registers.append(['sel_thresh', [cav_num], 5000])
        registers.append(['ph_offset', [cav_num], self.ph_offset])
        registers.append(['sel_en', [cav_num], self.sel_en])
        registers.append(['lp1a_kx', [cav_num], 20486])
        registers.append(['lp1a_ky', [cav_num], -20486])
        registers.append(['chan_keep', [cav_num], 4080])

        registers.append(
            ['setmp', [cav_num], [int(self.set_X),
                                  int(self.set_P)]])
        registers.append(
            ['coeff', [cav_num], [-100, -100, self.k_PA, self.k_PP]])
        registers.append(['lim', [cav_num], [0, 0, 0, 0]])
        self.delay_pc = 0

        def delay_set(ticks, addr, data):
            self.delay_pc += 4
            return [
                ['XXX_%d' % (self.delay_pc - 4), [cav_num], ticks],
                ['XXX_%d' % (self.delay_pc - 3), [cav_num], addr],
                ['XXX_%d' % (self.delay_pc - 2), [cav_num],
                 int(data) / 65536],
                ['XXX_%d' % (self.delay_pc - 1), [cav_num],
                 int(data) % 65536]
            ]

        if 0:
            pass
        #     # FGEN
        #     regs.append(c_regs('duration',3,duration))
        #     regs.append(c_regs('amp_slope',4,5000))
        #     regs.append(c_regs('amp_max',7,amp_max))
        #     regs.append(c_regs('amp_dest_addr',10,36))
        #     regs.append(c_regs('amp_dest_addr',12,38))
        # elif 0:
        #     # TGEN
        #     delay_pc = 4096
        #     # start the pulse in open loop (fixed drive amplitude) mode
        #     regs.extend(delay_set(0, 'lim_Y_hi', 0))
        #     regs.extend(delay_set(0, 'lim_Y_lo', 0))
        #     regs.extend(delay_set(0, 'lim_X_hi', 22640))
        #     regs.extend(delay_set(500*8, 'lim_X_lo', 22640))
        #     # allow the amplitude loop to run
        #     #regs.extend(delay_set(0, 52, 26000))
        #     regs.extend(delay_set(duration*8, 'lim_X_lo', 16000))
        #     # allow the phase loop to run
        #     regs.extend(delay_set(0, 'lim_Y_hi',  self.maxq))
        #     regs.extend(delay_set(5000*8, 'lim_Y_lo', -self.maxq))
        #     regs.extend(delay_set(0, 'lim_X_hi', 0))
        #     regs.extend(delay_set(0, 'lim_X_lo', 0))
        else:
            registers.extend(delay_set(0, lim_register_addr, self.amp_max))
            registers.extend(
                delay_set(self.duration * 8, lim_register_addr + 2,
                          self.amp_max))
            registers.extend(delay_set(0, lim_register_addr, 0))
            registers.extend(delay_set(0, lim_register_addr + 2, 0))
            for jx in range(6):
                registers.extend(delay_set(0, 0, 0))

            # regs.append(c_regs('Mode Select', 65536+554, 0))
        if error_cnt > 0:
            print "# %d scaling errors found" % error_cnt
            #exit(1)
        convert = lambda x: x + 2**32 if x < 0 else x
        for r in registers:
            if type(r[2]) is list:
                r[2] = map(convert, r[2])
            else:
                r[2] = convert(r[2])
        global print_once
        if print_once == True:
            for r in registers:
                print r[0], r[2]
            print_once = False
        return registers
Exemplo n.º 2
0
def gen_reg_list(mode1_foffset=5.0,mode1_Q1=8.1e4,mmode1_freq=30e3,mmode1_Q=5.0,net1_coupling=100,net2_coupling=200,net3_coupling=150,sel_en=1,set_X=0.0,set_P=0.0,k_PA=0,k_PP=0,maxq=0,ph_offset=-35500,amp_max=22640,fwd_phase_shift=0,rfl_phase_shift=0,cav_phase_shift=0,duration=300,PRNG_en=1,piezo_dc=0):
	regs=[]
	error_cnt=0

	#print 'mode1_foffset=%f,mode1_Q1=%f,mmode1_freq=%f,mmode1_Q=%f,net_coupling=%f'%(mode1_foffset,mode1_Q1,mmode1_freq,mmode1_Q,net_coupling)

# Gang humbly requests that Q_1 be renamed Q_drive, and Q_2 as Q_probe.
# Should apply here, physics.tex, elsewhere?

	# Note that Tstep is the ADC time step, also clocks the LLRF controller.
	# Divide by two for the cavity simulator (rtsim) clock time step.
	Tstep = 10e-9 # s
	f0 = 1300e6   # Hz
	nyquist_sign = -1    # -1 represents frequency inversion,
	# as with high-side LO or even-numbered Nyquist zones.

	VPmax = 48.0  # V piezo drive max

	# as we scale up, the following 10 parameters replicate per cavity:
	PAmax = 6e3   # W RF amplifier max
	PAbw = 1.5e6  # Hz bandwidth of power amplifier
	cav_adc_max = 1.2 # sqrt(W)
	rfl_adc_max = 180.0 # sqrt(W)
	fwd_adc_max = 160.0 # sqrt(W)
	phase_1 = fwd_phase_shift  # forward monitor phase shift
	phase_2 = rfl_phase_shift  # reflected monitor prompt phase shift
	cav_adc_off = 10
	rfl_adc_off = 20
	fwd_adc_off = 30


	mode1=Emode(name="pi",RoverQ=1036.0,foffset=mode1_foffset,peakV=1.5e6,Q_0=1e10,Q_1=mode1_Q1,Q_2=2e9,phase_1=rfl_phase_shift,phase_2=cav_phase_shift,mech_couplings=[net1_coupling,net2_coupling,net3_coupling])
	mode2=Emode(name="8pi/9",RoverQ=10.0,foffset=-8e5,peakV=0.15e6,Q_0=1e10,Q_1=8.1e4,Q_2=2e9,phase_1=10,phase_2=-180,mech_couplings=[0,0,0])

	mmode1=Mmode('silly', mmode1_freq, mmode1_Q, 1.13, 40000, 1, 80000)
	mmode2=Mmode('lowQ',       100000,      5.0,  1.5, 80000, 1, 20000)
	mmode3=Mmode('other',       24500,     25.0,  1.5, 20000, 1, 10000)

	# DDS setup for simulator should be static
	# this construction is for 20 MHz / 94.286 MHz = 7/33
	dds_num=7
	dds_den=33

	# The following three parameters are set in the Verilog at compile-time,
	# not run-time.  Top-level setting in larger.v needs to be mirrored here.
	lp_shift = 9  # see lp_pair.v, a.k.a. mode_shift
	n_mech_modes = 7  # number of mechanical modes handled
	df_scale = 9  # see cav4_freq.v

# ==== end of system configuration

# ==== the following dictionaries should get pulled in from Verilog somehow
	sim_base=16384  # base address for vmod1, see larger.v line 33

	regmap_global = {
'dds_phstep' : 1,
'dds_modulo' : 2,
'amp_bw' : 5,
'prompt' : 8,  # base address of 4 registers
'cav_adc_off' : 49,
'rfl_adc_off' : 50,
'fwd_adc_off' : 51,
'sat_ctl'     : 55,
'res_prop'    : 1*1024,  # base address of 1024 registers
'dot_0_k'     : 2*1024,  # base address of 1024 registers
'outer_0_k'   : 3*1024,  # base address of 1024 registers
'dot_1_k'     : 4*1024,  # base address of 1024 registers
'outer_1_k'   : 5*1024,  # base address of 1024 registers
'dot_2_k'     : 6*1024,  # base address of 1024 registers
'outer_2_k'   : 7*1024,  # base address of 1024 registers
'piezo_couple' : 8*1024,  # base address of 1024 registers
'noise_couple' : 9*1024}  # base address of 1024 registers

# base address for cavity n (zero-based) is 16+8*n
	regmap_emode = {
	  'coarse_freq' : 1,
	  'drive_coupling' : 2,
	  'bw' : 3,
	  'out_couple' : 4}   # base address of 4 registers

# ==== end of hardware register dictionaries

# send a register value "out"
# looks address up in regmap[name]
# finds value via name in python global namespace
# value can be a scalar or a list
# prefix and name are used to give a helpful comment
# ==== now start the application-specific computations

# Still may have bugs:
#   Mechanical mode coupling
# Needs a lot of work:
#   LLRF controller

	omega0 = f0*2*pi
	mech_tstep = Tstep * n_mech_modes
	interp_gain = n_mech_modes / 2**ceil(log(n_mech_modes)/log(2)) # interp0.v

#print "# Globals"
	amp_bw = fix(Tstep*PAbw*32, 18, "amp_bw")

	dds_phstep_h = int(dds_num*2**20/dds_den)
	dds_mult = int(4096/dds_den)
	dds_phstep_l = (dds_num*2**20)%dds_den * dds_mult
	dds_modulo = 4096 - dds_mult*dds_den
	dds_phstep = dds_phstep_h << 12 | dds_phstep_l
	sat_ctl = 65535
	#print "# dds",dds_mult,dds_phstep_h, dds_phstep_l, dds_modulo

	# four registers of pair_couple.v
	# neglect losses between directional coupler and cavity
	prompt = [
		fix(-sqrt(PAmax) / fwd_adc_max, 18, "out1", "cordic"),
		fix(-sqrt(PAmax) / rfl_adc_max, 18, "out2", "cordic"),
		fix(phase_1 / 180.0, 19, "out3"),
		fix(phase_2 / 180.0, 19, "out4")]

# Mechanical modes
	res_prop=[]
	piezo_couple=[]
	noise_couple=[]
	dot_0_k=[];  outer_0_k=[]
	dot_1_k=[];  outer_1_k=[]
	dot_2_k=[];  outer_2_k=[]
	mech_mode_list = [mmode1,mmode2,mmode3]
	for i,m in enumerate(mech_mode_list):
	  #print "# Cavity mechanical mode %d: %s"%(i,m.name)
	  w1 = mech_tstep * 2*pi*m.freq
	  # a1 + b1 * i represents the pole in the normalized s-plane
	  a1 = w1 * (-1/(2.0*m.Q))
	  b1 = w1 * sqrt(1-1/(4.0*m.Q**2))
	  z_pole = cexp(a1+b1*1j)
	  #print "# z_pole = %7f + %7fi"%(z_pole.real,z_pole.imag)
	  a1 = z_pole.real-1.0
	  b1 = z_pole.imag
	  scale = int(-log(max(a1,b1))/log(4))
	  scale = max(min(scale,9),2)
	  a2 = a1 * 4**scale
	  b2 = b1 * 4**scale
	  #print "# debug",w1,a1,b1,scale,a2,b2
	  #c1 = -w1**2 / (k*b1)
	  res_prop.append( (fix(a2,18,"a2")&(2**18-1)) + ((9-scale) << 18) )
	  res_prop.append( (fix(b2,18,"b2")&(2**18-1)) + ((9-scale) << 18) )
	  # the above is tested.  Onwards to the work-in-progress
	  dc_gain = b2/(a2**2+b2**2)  # resonator.v
	  m.dc_gain = dc_gain   # per-electical mode coupling computation will need this
	  piezo_couple.append(m.piezo_hack)
	  piezo_couple.append(0)
	  noise_couple.append(m.vibration_hack)
	  noise_couple.append(0)
	  #dot_2_k.append(0)
	  #dot_2_k.append(m.piezo_hack)

	for i,m in enumerate([mode1,mode2]):
	  #print "# Cavity electrical mode %d: %s"%(i,m.name)
	  Q_L = 1 / (1/m.Q_0 + 1/m.Q_1 + 1/m.Q_2)
	  # x is defined as sqrt(U)
	  xmax = m.peakV / sqrt(m.RoverQ*omega0)
	  # four registers of pair_couple.v
	  out_couple = [
		fix(sqrt(omega0/m.Q_1) * xmax / rfl_adc_max, 18, m.name+".out1", "cordic"),
		fix(sqrt(omega0/m.Q_2) * xmax / cav_adc_max, 18, m.name+".out2", "cordic"),
		fix(m.phase_1 / 180.0, 19, m.name+"out3"),
		fix(m.phase_2 / 180.0, 19, m.name+"out4")]
	  # see Pro tip in eav4_elec.v for better limit on foffset
	  # XXX document using 33 for what's really a 28-bit register
	  coarse_freq = fix(Tstep*nyquist_sign*m.foffset, 33, m.name+"coarse_freq")
	  V_achievable = 2*sqrt(PAmax*m.Q_1*m.RoverQ)
	  drive_coupling = fix( V_achievable / m.peakV, 18, m.name+"drive_coupling", "cordic")
	  # bandwidth in Hz = f_clk/2/2^shift/(2*pi) * bw_register/2^17 = omega_0/(2*pi*2*Q_L)
	  # XXX document origin of *2.0 better, compensates for shift right in lp_pair.v
	  bw = fix(Tstep*omega0/(2*Q_L)*(2**lp_shift)*2.0, 18, m.name+".bw")
	  for n in regmap_emode.keys():
		regs.extend(set_reg(16+8*i,m.name+".",n,regmap_emode,locals(),sim_base))
	  for j,mech_couple in enumerate(m.mech_couplings):
		#print "# elec mode %d coupling index %d value %f"%(i,j,mech_couple)
		# Number of electrical modes implemented in the hardware is set by the
		# parameter mode_count in cav4_elec.v, frozen at the time of synthesis.
		# The address decode generator (newad.py) will embed mode index into a
		# text name, which is then given an address by addr_map.vh.  This explains
		# the funny-looking exec at the end of this stanze.
		mech_mode = mech_mode_list[j]
		Amn =   sqrt(mech_couple/m.RoverQ) / omega0  # sqrt(J)/V^2
		Cmn = - sqrt(mech_couple*m.RoverQ) * omega0  # 1/s/sqrt(J)
		lorentz_en = 1
		outer = lorentz_en * Amn / mech_mode.mx * m.peakV**2 / mech_mode.dc_gain # dimensionless
		inner = lorentz_en * Cmn * mech_mode.mx * Tstep / 2**df_scale / interp_gain # dimensionless
		# note that inner*outer = net_coupling * mode1.peakV**2 * Tstep
		#print "# outer =",outer,"inner =",inner
		# additional scaling below comes from the 32-bit mech_phase_fine
		# accumulator, but only 18-bit d_result
		exec '''outer_%d_k.append(fix(outer/128,18,"outer")); outer_%d_k.append(0); dot_%d_k.append(0); dot_%d_k.append(fix(inner/128,18,"inner"))''' % (i,i,i,i)

	# Must be after electrical mode processing, to pick up outer_0_k etc.
	for n in regmap_global.keys():
	  r_hg_0=set_reg(0,"",n,regmap_global,locals(),sim_base)
	  regs.extend(r_hg_0)

	# Pseudo-random generator initialization, see tt800v.v and prng.v
	prng_seed="pushmi-pullyu"
	if prng_seed:
	  #print "# PRNG subsystem seed is '%s'"%prng_seed
	  hf = sha1()
	  hf.update(prng_seed)
	  r53=push_seed(53+sim_base,hf)
	  r54=push_seed(54+sim_base,hf)
	  #print "%d 1  # turn on PRNG"%(52+sim_base)
	regs.extend(r53)
	regs.extend(r54)
	regs.append(c_regs('turn on PRNG',52+sim_base,PRNG_en))

# Just hack in a few quick values for the controller
# This should really be another construction as above, maybe in a separate Python module?
# static DDS config, 7/33 as above
# #print "17 %d  # phase_step"%dds_phstep
# #print "18 %d  # modulo"%dds_modulo
#print "phase_step %d  # phase_step"%dds_phstep
#print "modulo %d  # modulo"%dds_modulo
	wave_samp_per=1
	wave_shift=3
# The LO amplitude in the FPGA is scaled by (32/33)^2, so that yscale
# fits nicely within the 32768 limit for small values of wave_samp_per
	lo_cheat=(32/33.0)**2
	yscale=lo_cheat*(33*wave_samp_per)**2*4**(8-wave_shift)/32

	regs.append(set_ctl('phase_step',dds_phstep))
	regs.append(set_ctl('modulo',4))
	regs.append(set_ctl('wave_samp_per',wave_samp_per))
	regs.append(set_ctl('wave_shift',wave_shift))
	regs.append(set_ctl('piezo_dc',piezo_dc))
	regs.append(set_ctl('sel_thresh',5000))
	regs.append(set_ctl('ph_offset',ph_offset))
	regs.append(set_ctl('sel_en',sel_en))
	regs.append(set_ctl('lp1a_kx_re',20486))
	regs.append(set_ctl('lp1a_ky_re',-20486))

	#regs.append(c_regs('wait',555,150-12))
	regs.append(set_ctl('chan_keep',4080))
	#regs.append(set_ctl('lim',22640))
	#regs.append(set_ctl('lim',22640))
	regs.append(set_ctl('set_X',int(set_X)))
	regs.append(set_ctl('set_Y',int(set_P)))
	regs.append(set_ctl('coeff_X_I',-100))
	regs.append(set_ctl('coeff_X_P',k_PA))
	regs.append(set_ctl('coeff_Y_I',-100))
	regs.append(set_ctl('coeff_Y_P',k_PP))
	regs.append(set_ctl('lim_X_hi',0))
	regs.append(set_ctl('lim_Y_hi',0))
	regs.append(set_ctl('lim_X_lo',0))
	regs.append(set_ctl('lim_Y_lo',0))

	global delay_pc
	if 0:  # FGEN
	  regs.append(c_regs('duration',3,duration))
	  regs.append(c_regs('amp_slope',4,5000))
	  regs.append(c_regs('amp_max',7,amp_max))
	  regs.append(c_regs('amp_dest_addr',10,36))
	  regs.append(c_regs('amp_dest_addr',12,38))
	elif 0: # TGEN
	  delay_pc = 4096
	  # start the pulse in open loop (fixed drive amplitude) mode
	  regs.extend(delay_set(0, 'lim_Y_hi', 0))
	  regs.extend(delay_set(0, 'lim_Y_lo', 0))
	  regs.extend(delay_set(0, 'lim_X_hi', 22640))
	  regs.extend(delay_set(500*8, 'lim_X_lo', 22640))
	  # allow the amplitude loop to run
	  #regs.extend(delay_set(0, 52, 26000))
	  regs.extend(delay_set(duration*8, 'lim_X_lo', 16000))
	  # allow the phase loop to run
	  regs.extend(delay_set(0, 'lim_Y_hi',  maxq))
	  regs.extend(delay_set(5000*8, 'lim_Y_lo', -maxq))
	  regs.extend(delay_set(0, 'lim_X_hi', 0))
	  regs.extend(delay_set(0, 'lim_X_lo', 0))
	else:
	  delay_pc = 4096
	  regs.extend(delay_set(0, 'lim_X_hi', amp_max))
	  regs.extend(delay_set(duration*8, 'lim_X_lo', amp_max))
	  regs.extend(delay_set(0, 'lim_X_hi', 0))
	  regs.extend(delay_set(0, 'lim_X_lo', 0))
	  for jx in range(6):
		regs.extend(delay_set(0,'null',0))

	if error_cnt > 0:
	  print "# %d scaling errors found"%error_cnt
	  #exit(1)

	return [regs,error_cnt]
Exemplo n.º 3
0
# Mechanical modes
res_prop = []
piezo_couple = []
dot_0_k = []
outer_0_k = []
dot_1_k = []
outer_1_k = []
dot_2_k = []
outer_2_k = []
for i, m in enumerate([mmode1, mmode2]):
    print "# Cavity mechanical mode %d: %s" % (i, m.name)
    w1 = mech_tstep * 2 * pi * m.freq
    # a1 + b1 * i represents the pole in the normalized s-plane
    a1 = w1 * (-1 / (2.0 * m.Q))
    b1 = w1 * sqrt(1 - 1 / (4.0 * m.Q**2))
    z_pole = cexp(a1 + b1 * 1j)
    print "# z_pole = %7f + %7fi" % (z_pole.real, z_pole.imag)
    a1 = z_pole.real - 1.0
    b1 = z_pole.imag
    scale = int(-log(max(a1, b1)) / log(4))
    scale = max(min(scale, 9), 2)
    a2 = a1 * 4**scale
    b2 = b1 * 4**scale
    print "# debug", w1, a1, b1, scale, a2, b2
    #c1 = -w1**2 / (k*b1)
    res_prop.append((fix(a2, 18, "a2") & (2**18 - 1)) + ((9 - scale) << 18))
    res_prop.append((fix(b2, 18, "b2") & (2**18 - 1)) + ((9 - scale) << 18))
    # the above is tested.  Onwards to the work-in-progress
    dc_gain = b2 / (a2**2 + b2**2)  # resonator.v
    net_coupling = 130.0  # Hz / V^2, negative is implicit
    Amn = sqrt(net_coupling / mode1.RoverQ) / omega0  # sqrt(J)/V^2