# # Copyright 2005,2007 Free Software Foundation, Inc. # # This file is part of GNU Radio # # GNU Radio is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3, or (at your option) # any later version. # # GNU Radio is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with GNU Radio; see the file COPYING. If not, write to # the Free Software Foundation, Inc., 51 Franklin Street, # Boston, MA 02110-1301, USA. # from gnuradio import usrp1 import time,math from usrpm import usrp_dbid import db_base import db_instantiator from usrpm.usrp_fpga_regs import * #debug_using_gui = True # Must be set to True or False debug_using_gui = False # Must be set to True or False if debug_using_gui: import flexrf_debug_gui # d'board i/o pin defs # Tx and Rx have shared defs, but different i/o regs AUX_RXAGC = (1 << 8) POWER_UP = (1 << 7) # enables power supply RX_TXN = (1 << 6) # Tx only: T/R antenna switch for TX/RX port RX2_RX1N = (1 << 6) # Rx only: antenna switch between RX2 and TX/RX port ENABLE = (1 << 5) # enables mixer AUX_SEN = (1 << 4) AUX_SCLK = (1 << 3) PLL_LOCK_DETECT = (1 << 2) AUX_SDO = (1 << 1) CLOCK_OUT = (1 << 0) SPI_ENABLE_TX_A = usrp1.SPI_ENABLE_TX_A SPI_ENABLE_TX_B = usrp1.SPI_ENABLE_TX_B SPI_ENABLE_RX_A = usrp1.SPI_ENABLE_RX_A SPI_ENABLE_RX_B = usrp1.SPI_ENABLE_RX_B class flexrf_base(db_base.db_base): """ Abstract base class for all flexrf boards. Derive board specific subclasses from db_flexrf_base_{tx,rx} """ def __init__(self, usrp, which): """ @param usrp: instance of usrp.source_c @param which: which side: 0 or 1 corresponding to side A or B respectively @type which: int """ # sets _u _which _tx and _slot db_base.db_base.__init__(self, usrp, which) self.first = True self.spi_format = usrp1.SPI_FMT_MSB | usrp1.SPI_FMT_HDR_0 self._u._write_oe(self._which, 0, 0xffff) # turn off all outputs self._enable_refclk(False) # disable refclk g = self.gain_range() # initialize gain self.set_gain(float(g[0]+g[1]) / 2) self.set_auto_tr(False) if debug_using_gui: title = "FlexRF Debug Rx" if self._tx: title = "FlexRF Debug Tx" self.gui = flexrf_debug_gui.flexrf_debug_gui(self, title) self.gui.Show(True) def __del__(self): #print "flexrf_base.__del__" self._u.write_io(self._which, self.power_off, POWER_UP) # turn off power to board self._enable_refclk(False) # turn off refclk self.set_auto_tr(False) def _write_all(self, R, control, N): """ Write R counter latch, control latch and N counter latch to VCO. Adds 10ms delay between writing control and N if this is first call. This is the required power-up sequence. @param R: 24-bit R counter latch @type R: int @param control: 24-bit control latch @type control: int @param N: 24-bit N counter latch @type N: int """ self._write_R(R) self._write_control( control) if self.first: time.sleep(0.010) self.first = False self._write_N(N) def _write_control(self, control): self._write_it((control & ~0x3) | 0) def _write_R(self, R): self._write_it((R & ~0x3) | 1) def _write_N(self, N): self._write_it((N & ~0x3) | 2) def _write_it(self, v): s = ''.join((chr((v >> 16) & 0xff), chr((v >> 8) & 0xff), chr(v & 0xff))) self._u._write_spi(0, self.spi_enable, self.spi_format, s) def _lock_detect(self): """ @returns: the value of the VCO/PLL lock detect bit. @rtype: 0 or 1 """ if self._u.read_io(self._which) & PLL_LOCK_DETECT: return True else: # Give it a second chance if self._u.read_io(self._which) & PLL_LOCK_DETECT: return True else: return False def _compute_regs(self, freq): """ Determine values of R, control, and N registers, along with actual freq. @param freq: target frequency in Hz @type freq: float @returns: (R, control, N, actual_freq) @rtype: tuple(int, int, int, float) Override this in derived classes. """ raise NotImplementedError def _refclk_freq(self): # return float(self._u.fpga_master_clock_freq())/self._refclk_divisor() return 64e6/self._refclk_divisor() def set_freq(self, freq): """ @returns (ok, actual_baseband_freq) where: ok is True or False and indicates success or failure, actual_baseband_freq is the RF frequency that corresponds to DC in the IF. """ # Offsetting the LO helps get the Tx carrier leakage out of the way. # This also ensures that on Rx, we're not getting hosed by the # FPGA's DC removal loop's time constant. We were seeing a # problem when running with discontinuous transmission. # Offsetting the LO made the problem go away. freq += self._lo_offset R, control, N, actual_freq = self._compute_regs(freq) if R==0: return(False,0) self._write_all(R, control, N) return (self._lock_detect(), actual_freq) def gain_range(self): """ Return range of gain that can be set by this d'board. @returns (min_gain, max_gain, step_size) Where gains are expressed in decibels (your mileage may vary) """ return (self._u.pga_min(), self._u.pga_max(), self._u.pga_db_per_step()) def set_gain(self, gain): """ Set the gain. @param gain: gain in decibels @returns True/False """ return self._set_pga(gain) def _set_pga(self, pga_gain): if(self._which == 0): self._u.set_pga (0, pga_gain) self._u.set_pga (1, pga_gain) else: self._u.set_pga (2, pga_gain) self._u.set_pga (3, pga_gain) def is_quadrature(self): """ Return True if this board requires both I & Q analog channels. This bit of info is useful when setting up the USRP Rx mux register. """ return True def set_lo_offset(self, offset): """ Set amount by which LO is offset from requested tuning frequency. @param offset: offset in Hz """ self._lo_offset = offset def lo_offset(self): """ Get amount by which LO is offset from requested tuning frequency. @returns Offset in Hz """ return self._lo_offset # ---------------------------------------------------------------- class flexrf_base_tx(flexrf_base): def __init__(self, usrp, which): """ @param usrp: instance of usrp.sink_c @param which: 0 or 1 corresponding to side TX_A or TX_B respectively. """ flexrf_base.__init__(self, usrp, which) self.spi_enable = (SPI_ENABLE_TX_A, SPI_ENABLE_TX_B)[which] # power up the transmit side, but don't enable the mixer self._u._write_oe(self._which,(POWER_UP|RX_TXN|ENABLE), 0xffff) self._u.write_io(self._which, (self.power_on|RX_TXN), (POWER_UP|RX_TXN|ENABLE)) self.set_lo_offset(4e6) def __del__(self): #print "flexrf_base_tx.__del__" # Power down and leave the T/R switch in the R position self._u.write_io(self._which, (self.power_off|RX_TXN), (POWER_UP|RX_TXN|ENABLE)) flexrf_base.__del__(self) def set_auto_tr(self, on): if on: self.set_atr_mask (RX_TXN | ENABLE) self.set_atr_txval(0 | ENABLE) self.set_atr_rxval(RX_TXN | 0) else: self.set_atr_mask (0) self.set_atr_txval(0) self.set_atr_rxval(0) def set_enable(self, on): """ Enable transmitter if on is True """ mask = RX_TXN | ENABLE if on: v = ENABLE else: v = RX_TXN self._u.write_io(self._which, v, mask) def gain_range(self): """ Return range of gain that can be set by this d'board. @returns (min_gain, max_gain, step_size) Where gains are expressed in decibels (your mileage may vary) Flex Tx boards require that the PGA be maxed out to properly bias their circuitry. """ g = self._u.pga_max() return (g, g, 1.0) def set_gain(self, gain): """ Set the gain. @param gain: gain in decibels @returns True/False """ return self._set_pga(self._u.pga_max()) class flexrf_base_rx(flexrf_base): def __init__(self, usrp, which): """ @param usrp: instance of usrp.source_c @param which: 0 or 1 corresponding to side RX_A or RX_B respectively. """ flexrf_base.__init__(self, usrp, which) self.spi_enable = (SPI_ENABLE_RX_A, SPI_ENABLE_RX_B)[which] self._u._write_oe(self._which, (POWER_UP|RX2_RX1N|ENABLE), 0xffff) self._u.write_io(self._which, (self.power_on|RX2_RX1N|ENABLE), (POWER_UP|RX2_RX1N|ENABLE)) # set up for RX on TX/RX port self.select_rx_antenna('TX/RX') self.bypass_adc_buffers(True) self.set_lo_offset(-4e6) def __del__(self): # print "flexrf_base_rx.__del__" # Power down self._u.write_io(self._which, self.power_off, (POWER_UP|ENABLE)) flexrf_base.__del__(self) def set_auto_tr(self, on): if on: self.set_atr_mask (ENABLE) self.set_atr_txval( 0) self.set_atr_rxval(ENABLE) else: self.set_atr_mask (0) self.set_atr_txval(0) self.set_atr_rxval(0) def select_rx_antenna(self, which_antenna): """ Specify which antenna port to use for reception. @param which_antenna: either 'TX/RX' or 'RX2' """ if which_antenna in (0, 'TX/RX'): self._u.write_io(self._which, 0, RX2_RX1N) elif which_antenna in (1, 'RX2'): self._u.write_io(self._which, RX2_RX1N, RX2_RX1N) else: raise ValueError, "which_antenna must be either 'TX/RX' or 'RX2'" def set_gain(self, gain): """ Set the gain. @param gain: gain in decibels @returns True/False """ maxgain = self.gain_range()[1] - self._u.pga_max() mingain = self.gain_range()[0] if gain > maxgain: pga_gain = gain-maxgain assert pga_gain <= self._u.pga_max() agc_gain = maxgain else: pga_gain = 0 agc_gain = gain V_maxgain = .2 V_mingain = 1.2 V_fullscale = 3.3 dac_value = (agc_gain*(V_maxgain-V_mingain)/(maxgain-mingain) + V_mingain)*4096/V_fullscale assert dac_value>=0 and dac_value<4096 return self._u.write_aux_dac(self._which, 0, int(dac_value)) and \ self._set_pga(int(pga_gain)) # ---------------------------------------------------------------- class _AD4360_common(object): def __init__(self): # R-Register Common Values self.R_RSV = 0 # bits 23,22 self.BSC = 3 # bits 21,20 Div by 8 to be safe self.TEST = 0 # bit 19 self.LDP = 1 # bit 18 self.ABP = 0 # bit 17,16 3ns # N-Register Common Values self.N_RSV = 0 # bit 7 # Control Register Common Values self.PD = 0 # bits 21,20 Normal operation self.PL = 0 # bits 13,12 11mA self.MTLD = 1 # bit 11 enabled self.CPG = 0 # bit 10 CP setting 1 self.CP3S = 0 # bit 9 Normal self.PDP = 1 # bit 8 Positive self.MUXOUT = 1 # bits 7:5 Digital Lock Detect self.CR = 0 # bit 4 Normal self.PC = 1 # bits 3,2 Core power 10mA def _compute_regs(self, freq): """ Determine values of R, control, and N registers, along with actual freq. @param freq: target frequency in Hz @type freq: float @returns: (R, control, N, actual_freq) @rtype: tuple(int, int, int, float) """ # Band-specific N-Register Values phdet_freq = self._refclk_freq()/self.R_DIV desired_n = round(freq*self.freq_mult/phdet_freq) actual_freq = desired_n * phdet_freq B = math.floor(desired_n/self._prescaler()) A = desired_n - self._prescaler()*B self.B_DIV = int(B) # bits 20:8 self.A_DIV = int(A) # bit 6:2 #assert self.B_DIV >= self.A_DIV if self.B_DIV < self.A_DIV: return (0,0,0,0) R = (self.R_RSV<<22) | (self.BSC<<20) | (self.TEST<<19) | (self.LDP<<18) \ | (self.ABP<<16) | (self.R_DIV<<2) control = (self.P<<22) | (self.PD<<20) | (self.CP2<<17) | (self.CP1<<14) | (self.PL<<12) \ | (self.MTLD<<11) | (self.CPG<<10) | (self.CP3S<<9) | (self.PDP<<8) | \ (self.MUXOUT<<5) | (self.CR<<4) | (self.PC<<2) N = (self.DIVSEL<<23) | (self.DIV2<<22) | (self.CPGAIN<<21) | (self.B_DIV<<8) | \ (self.N_RSV<<7) | (self.A_DIV<<2) return (R,control,N,actual_freq/self.freq_mult) def _refclk_divisor(self): """ Return value to stick in REFCLK_DIVISOR register """ return 1 def _prescaler(self): if self.P == 0: return 8 elif self.P == 1: return 16 else: return 32 #---------------------------------------------------------------------- class _2400_common(_AD4360_common): def __init__(self): _AD4360_common.__init__(self) # Band-specific R-Register Values self.R_DIV = 16 # bits 15:2 # Band-specific C-Register values self.P = 1 # bits 23,22 Div by 16/17 self.CP2 = 7 # bits 19:17 self.CP1 = 7 # bits 16:14 # Band specifc N-Register Values self.DIVSEL = 0 # bit 23 self.DIV2 = 0 # bit 22 self.CPGAIN = 0 # bit 21 self.freq_mult = 1 def freq_range(self): # FIXME return (2300e6, 2700e6, 4e6) #---------------------------------------------------------------------- class _1200_common(_AD4360_common): def __init__(self): _AD4360_common.__init__(self) # Band-specific R-Register Values self.R_DIV = 16 # bits 15:2 DIV by 16 for a 1 MHz phase detector freq # Band-specific C-Register values self.P = 1 # bits 23,22 Div by 16/17 self.CP2 = 7 # bits 19:17 1.25 mA self.CP1 = 7 # bits 16:14 1.25 mA # Band specifc N-Register Values self.DIVSEL = 0 # bit 23 self.DIV2 = 1 # bit 22 self.CPGAIN = 0 # bit 21 self.freq_mult = 2 def freq_range(self): # FIXME return (1150e6, 1350e6, 4e6) #------------------------------------------------------------------------- class _1800_common(_AD4360_common): def __init__(self): _AD4360_common.__init__(self) # Band-specific R-Register Values self.R_DIV = 16 # bits 15:2 DIV by 16 for a 1 MHz phase detector freq # Band-specific C-Register values self.P = 1 # bits 23,22 Div by 16/17 self.CP2 = 7 # bits 19:17 1.25 mA self.CP1 = 7 # bits 16:14 1.25 mA # Band specifc N-Register Values self.DIVSEL = 0 # bit 23 self.DIV2 = 0 # bit 22 self.freq_mult = 1 self.CPGAIN = 0 # bit 21 def freq_range(self): # FIXME return (1600e6, 2000e6, 4e6) #------------------------------------------------------------------------- class _900_common(_AD4360_common): def __init__(self): _AD4360_common.__init__(self) # Band-specific R-Register Values self.R_DIV = 16 # bits 15:2 DIV by 16 for a 1 MHz phase detector freq # Band-specific C-Register values self.P = 1 # bits 23,22 Div by 16/17 self.CP2 = 7 # bits 19:17 1.25 mA self.CP1 = 7 # bits 16:14 1.25 mA # Band specifc N-Register Values self.DIVSEL = 0 # bit 23 self.DIV2 = 1 # bit 22 self.freq_mult = 2 self.CPGAIN = 0 # bit 21 def freq_range(self): # FIXME return (800e6, 1000e6, 4e6) #------------------------------------------------------------------------- class _400_common(_AD4360_common): def __init__(self): _AD4360_common.__init__(self) # Band-specific R-Register Values self.R_DIV = 16 # bits 15:2 # Band-specific C-Register values self.P = 0 # bits 23,22 Div by 8/9 self.CP2 = 7 # bits 19:17 1.25 mA self.CP1 = 7 # bits 16:14 1.25 mA # Band specifc N-Register Values These are different for TX/RX self.DIVSEL = 0 # bit 23 if self._tx: self.DIV2 = 1 # bit 22 else: self.DIV2 = 0 # bit 22 # RX side has built-in DIV2 in AD8348 self.freq_mult = 2 self.CPGAIN = 0 # bit 21 def freq_range(self): #return (350e6, 465e6, 1e6) # FIXME prototype return (400e6, 500e6, 1e6) # final version #------------------------------------------------------------ class db_flexrf_2400_tx(_2400_common, flexrf_base_tx): def __init__(self, usrp, which): self.power_on = ~POWER_UP self.power_off = ~POWER_UP # powering it off kills the serial bus flexrf_base_tx.__init__(self, usrp, which) _2400_common.__init__(self) class db_flexrf_2400_rx(_2400_common, flexrf_base_rx): def __init__(self, usrp, which): self.power_on = ~POWER_UP self.power_off = ~POWER_UP # Powering it off kills the serial bus flexrf_base_rx.__init__(self, usrp, which) _2400_common.__init__(self) def gain_range(self): """ Return range of gain that can be set by this d'board. @returns (min_gain, max_gain, step_size) Where gains are expressed in decibels (your mileage may vary) """ return (self._u.pga_min(), self._u.pga_max() + 70, 0.05) def i_and_q_swapped(self): return True class db_flexrf_1200_tx(_1200_common, flexrf_base_tx): def __init__(self, usrp, which): self.power_on = ~POWER_UP self.power_off = ~POWER_UP # powering it off kills the serial bus flexrf_base_tx.__init__(self, usrp, which) _1200_common.__init__(self) class db_flexrf_1200_rx(_1200_common, flexrf_base_rx): def __init__(self, usrp, which): self.power_on = ~POWER_UP self.power_off = ~POWER_UP # powering it off kills the serial bus flexrf_base_rx.__init__(self, usrp, which) _1200_common.__init__(self) def gain_range(self): """ Return range of gain that can be set by this d'board. @returns (min_gain, max_gain, step_size) Where gains are expressed in decibels (your mileage may vary) """ return (self._u.pga_min(), self._u.pga_max() + 70, 0.05) def i_and_q_swapped(self): return True class db_flexrf_1800_tx(_1800_common, flexrf_base_tx): def __init__(self, usrp, which): self.power_on = ~POWER_UP self.power_off = ~POWER_UP # powering it off kills the serial bus flexrf_base_tx.__init__(self, usrp, which) _1800_common.__init__(self) class db_flexrf_1800_rx(_1800_common, flexrf_base_rx): def __init__(self, usrp, which): self.power_on = ~POWER_UP self.power_off = ~POWER_UP # powering it off kills the serial bus flexrf_base_rx.__init__(self, usrp, which) _1800_common.__init__(self) def gain_range(self): """ Return range of gain that can be set by this d'board. @returns (min_gain, max_gain, step_size) Where gains are expressed in decibels (your mileage may vary) """ return (self._u.pga_min(), self._u.pga_max() + 70, 0.05) def i_and_q_swapped(self): return True class db_flexrf_900_tx(_900_common, flexrf_base_tx): def __init__(self, usrp, which): self.power_on = ~POWER_UP self.power_off = ~POWER_UP # powering it off kills the serial bus flexrf_base_tx.__init__(self, usrp, which) _900_common.__init__(self) class db_flexrf_900_rx(_900_common, flexrf_base_rx): def __init__(self, usrp, which): self.power_on = ~POWER_UP self.power_off = ~POWER_UP # powering it off kills the serial bus flexrf_base_rx.__init__(self, usrp, which) _900_common.__init__(self) def gain_range(self): """ Return range of gain that can be set by this d'board. @returns (min_gain, max_gain, step_size) Where gains are expressed in decibels (your mileage may vary) """ return (self._u.pga_min(), self._u.pga_max() + 70, 0.05) def i_and_q_swapped(self): return True class db_flexrf_400_tx(_400_common, flexrf_base_tx): def __init__(self, usrp, which): self.power_on = POWER_UP self.power_off = ~POWER_UP flexrf_base_tx.__init__(self, usrp, which) _400_common.__init__(self) class db_flexrf_400_rx(_400_common, flexrf_base_rx): def __init__(self, usrp, which): self.power_on = POWER_UP self.power_off = ~POWER_UP flexrf_base_rx.__init__(self, usrp, which) _400_common.__init__(self) def gain_range(self): """ Return range of gain that can be set by this d'board. @returns (min_gain, max_gain, step_size) Where gains are expressed in decibels (your mileage may vary) """ return (self._u.pga_min(), self._u.pga_max() + 45, 0.035) def i_and_q_swapped(self): return True # hook these daughterboard classes into the auto-instantiation framework db_instantiator.add(usrp_dbid.FLEX_2400_TX, lambda usrp, which : (db_flexrf_2400_tx(usrp, which),)) db_instantiator.add(usrp_dbid.FLEX_2400_RX, lambda usrp, which : (db_flexrf_2400_rx(usrp, which),)) db_instantiator.add(usrp_dbid.FLEX_1200_TX, lambda usrp, which : (db_flexrf_1200_tx(usrp, which),)) db_instantiator.add(usrp_dbid.FLEX_1200_RX, lambda usrp, which : (db_flexrf_1200_rx(usrp, which),)) db_instantiator.add(usrp_dbid.FLEX_1800_TX, lambda usrp, which : (db_flexrf_1800_tx(usrp, which),)) db_instantiator.add(usrp_dbid.FLEX_1800_RX, lambda usrp, which : (db_flexrf_1800_rx(usrp, which),)) db_instantiator.add(usrp_dbid.FLEX_900_TX, lambda usrp, which : (db_flexrf_900_tx(usrp, which),)) db_instantiator.add(usrp_dbid.FLEX_900_RX, lambda usrp, which : (db_flexrf_900_rx(usrp, which),)) db_instantiator.add(usrp_dbid.FLEX_400_TX, lambda usrp, which : (db_flexrf_400_tx(usrp, which),)) db_instantiator.add(usrp_dbid.FLEX_400_RX, lambda usrp, which : (db_flexrf_400_rx(usrp, which),))