📄 dqpsk.py
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## Copyright 2005,2006 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.# # See gnuradio-examples/python/digital for examples"""differential QPSK modulation and demodulation."""from gnuradio import gr, gru, modulation_utilsfrom math import pi, sqrtimport pskimport cmathfrom pprint import pprint# default values (used in __init__ and add_options)_def_samples_per_symbol = 2_def_excess_bw = 0.35_def_gray_code = True_def_verbose = False_def_log = False_def_costas_alpha = 0.15_def_gain_mu = None_def_mu = 0.5_def_omega_relative_limit = 0.005# /////////////////////////////////////////////////////////////////////////////# DQPSK modulator# /////////////////////////////////////////////////////////////////////////////class dqpsk_mod(gr.hier_block): def __init__(self, fg, samples_per_symbol=_def_samples_per_symbol, excess_bw=_def_excess_bw, gray_code=_def_gray_code, verbose=_def_verbose, log=_def_log): """ Hierarchical block for RRC-filtered QPSK modulation. The input is a byte stream (unsigned char) and the output is the complex modulated signal at baseband. @param fg: flow graph @type fg: flow graph @param samples_per_symbol: samples per symbol >= 2 @type samples_per_symbol: integer @param excess_bw: Root-raised cosine filter excess bandwidth @type excess_bw: float @param gray_code: Tell modulator to Gray code the bits @type gray_code: bool @param verbose: Print information about modulator? @type verbose: bool @param debug: Print modualtion data to files? @type debug: bool """ self._fg = fg self._samples_per_symbol = samples_per_symbol self._excess_bw = excess_bw self._gray_code = gray_code if not isinstance(samples_per_symbol, int) or samples_per_symbol < 2: raise TypeError, ("sbp must be an integer >= 2, is %d" % samples_per_symbol) ntaps = 11 * samples_per_symbol arity = pow(2,self.bits_per_symbol()) # turn bytes into k-bit vectors self.bytes2chunks = \ gr.packed_to_unpacked_bb(self.bits_per_symbol(), gr.GR_MSB_FIRST) if self._gray_code: self.symbol_mapper = gr.map_bb(psk.binary_to_gray[arity]) else: self.symbol_mapper = gr.map_bb(psk.binary_to_ungray[arity]) self.diffenc = gr.diff_encoder_bb(arity) rot = .707 + .707j rotated_const = map(lambda pt: pt * rot, psk.constellation[arity]) self.chunks2symbols = gr.chunks_to_symbols_bc(rotated_const) # pulse shaping filter self.rrc_taps = gr.firdes.root_raised_cosine( self._samples_per_symbol, # gain (sps since we're interpolating by sps) self._samples_per_symbol, # sampling rate 1.0, # symbol rate self._excess_bw, # excess bandwidth (roll-off factor) ntaps) self.rrc_filter = gr.interp_fir_filter_ccf(self._samples_per_symbol, self.rrc_taps) if verbose: self._print_verbage() if log: self._setup_logging() # Connect & Initialize base class self._fg.connect(self.bytes2chunks, self.symbol_mapper, self.diffenc, self.chunks2symbols, self.rrc_filter) gr.hier_block.__init__(self, self._fg, self.bytes2chunks, self.rrc_filter) def samples_per_symbol(self): return self._samples_per_symbol def bits_per_symbol(self=None): # staticmethod that's also callable on an instance return 2 bits_per_symbol = staticmethod(bits_per_symbol) # make it a static method. RTFM def _print_verbage(self): print "\nModulator:" print "bits per symbol: %d" % self.bits_per_symbol() print "Gray code: %s" % self._gray_code print "RRS roll-off factor: %f" % self._excess_bw def _setup_logging(self): print "Modulation logging turned on." self._fg.connect(self.bytes2chunks, gr.file_sink(gr.sizeof_char, "tx_bytes2chunks.dat")) self._fg.connect(self.symbol_mapper, gr.file_sink(gr.sizeof_char, "tx_graycoder.dat")) self._fg.connect(self.diffenc, gr.file_sink(gr.sizeof_char, "tx_diffenc.dat")) self._fg.connect(self.chunks2symbols, gr.file_sink(gr.sizeof_gr_complex, "tx_chunks2symbols.dat")) self._fg.connect(self.rrc_filter, gr.file_sink(gr.sizeof_gr_complex, "tx_rrc_filter.dat")) def add_options(parser): """ Adds QPSK modulation-specific options to the standard parser """ parser.add_option("", "--excess-bw", type="float", default=_def_excess_bw, help="set RRC excess bandwith factor [default=%default] (PSK)") parser.add_option("", "--no-gray-code", dest="gray_code", action="store_false", default=_def_gray_code, help="disable gray coding on modulated bits (PSK)") add_options=staticmethod(add_options) def extract_kwargs_from_options(options): """ Given command line options, create dictionary suitable for passing to __init__ """ return modulation_utils.extract_kwargs_from_options(dqpsk_mod.__init__, ('self', 'fg'), options) extract_kwargs_from_options=staticmethod(extract_kwargs_from_options)# /////////////////////////////////////////////////////////////////////////////# DQPSK demodulator## Differentially coherent detection of differentially encoded qpsk# /////////////////////////////////////////////////////////////////////////////class dqpsk_demod(gr.hier_block): def __init__(self, fg, samples_per_symbol=_def_samples_per_symbol, excess_bw=_def_excess_bw, costas_alpha=_def_costas_alpha, gain_mu=_def_gain_mu, mu=_def_mu, omega_relative_limit=_def_omega_relative_limit, gray_code=_def_gray_code, verbose=_def_verbose, log=_def_log): """ Hierarchical block for RRC-filtered DQPSK demodulation The input is the complex modulated signal at baseband. The output is a stream of bits packed 1 bit per byte (LSB) @param fg: flow graph @type fg: flow graph @param samples_per_symbol: samples per symbol >= 2 @type samples_per_symbol: float @param excess_bw: Root-raised cosine filter excess bandwidth @type excess_bw: float @param costas_alpha: loop filter gain @type costas_alphas: float @param gain_mu: for M&M block @type gain_mu: float @param mu: for M&M block @type mu: float @param omega_relative_limit: for M&M block @type omega_relative_limit: float @param gray_code: Tell modulator to Gray code the bits @type gray_code: bool @param verbose: Print information about modulator? @type verbose: bool @param debug: Print modualtion data to files? @type debug: bool """ self._fg = fg self._samples_per_symbol = samples_per_symbol self._excess_bw = excess_bw self._costas_alpha = costas_alpha self._mm_gain_mu = gain_mu self._mm_mu = mu self._mm_omega_relative_limit = omega_relative_limit self._gray_code = gray_code if samples_per_symbol < 2: raise TypeError, "sbp must be >= 2, is %d" % samples_per_symbol arity = pow(2,self.bits_per_symbol()) # Automatic gain control scale = (1.0/16384.0) self.pre_scaler = gr.multiply_const_cc(scale) # scale the signal from full-range to +-1 #self.agc = gr.agc2_cc(0.6e-1, 1e-3, 1, 1, 100) self.agc = gr.feedforward_agc_cc(16, 2.0) # RRC data filter ntaps = 11 * samples_per_symbol self.rrc_taps = gr.firdes.root_raised_cosine( 1.0, # gain self._samples_per_symbol, # sampling rate 1.0, # symbol rate self._excess_bw, # excess bandwidth (roll-off factor) ntaps) self.rrc_filter=gr.interp_fir_filter_ccf(1, self.rrc_taps) if not self._mm_gain_mu: sbs_to_mm = {2: 0.050, 3: 0.075, 4: 0.11, 5: 0.125, 6: 0.15, 7: 0.15} self._mm_gain_mu = sbs_to_mm[samples_per_symbol] self._mm_omega = self._samples_per_symbol self._mm_gain_omega = .25 * self._mm_gain_mu * self._mm_gain_mu self._costas_beta = 0.25 * self._costas_alpha * self._costas_alpha fmin = -0.025 fmax = 0.025 self.receiver=gr.mpsk_receiver_cc(arity, pi/4.0, self._costas_alpha, self._costas_beta, fmin, fmax, self._mm_mu, self._mm_gain_mu, self._mm_omega, self._mm_gain_omega, self._mm_omega_relative_limit) # Perform Differential decoding on the constellation self.diffdec = gr.diff_phasor_cc() # find closest constellation point rot = 1 rotated_const = map(lambda pt: pt * rot, psk.constellation[arity]) self.slicer = gr.constellation_decoder_cb(rotated_const, range(arity)) if self._gray_code: self.symbol_mapper = gr.map_bb(psk.gray_to_binary[arity]) else: self.symbol_mapper = gr.map_bb(psk.ungray_to_binary[arity]) # unpack the k bit vector into a stream of bits self.unpack = gr.unpack_k_bits_bb(self.bits_per_symbol()) if verbose: self._print_verbage() if log: self._setup_logging() # Connect & Initialize base class self._fg.connect(self.pre_scaler, self.agc, self.rrc_filter, self.receiver, self.diffdec, self.slicer, self.symbol_mapper, self.unpack) gr.hier_block.__init__(self, self._fg, self.pre_scaler, self.unpack) def samples_per_symbol(self): return self._samples_per_symbol def bits_per_symbol(self=None): # staticmethod that's also callable on an instance return 2 bits_per_symbol = staticmethod(bits_per_symbol) # make it a static method. RTFM def _print_verbage(self): print "\nDemodulator:" print "bits per symbol: %d" % self.bits_per_symbol() print "Gray code: %s" % self._gray_code print "RRC roll-off factor: %.2f" % self._excess_bw print "Costas Loop alpha: %.2e" % self._costas_alpha print "Costas Loop beta: %.2e" % self._costas_beta print "M&M mu: %.2f" % self._mm_mu print "M&M mu gain: %.2e" % self._mm_gain_mu print "M&M omega: %.2f" % self._mm_omega print "M&M omega gain: %.2e" % self._mm_gain_omega print "M&M omega limit: %.2f" % self._mm_omega_relative_limit def _setup_logging(self): print "Modulation logging turned on." self._fg.connect(self.pre_scaler, gr.file_sink(gr.sizeof_gr_complex, "rx_prescaler.dat")) self._fg.connect(self.agc, gr.file_sink(gr.sizeof_gr_complex, "rx_agc.dat")) self._fg.connect(self.rrc_filter, gr.file_sink(gr.sizeof_gr_complex, "rx_rrc_filter.dat")) self._fg.connect(self.receiver, gr.file_sink(gr.sizeof_gr_complex, "rx_receiver.dat")) self._fg.connect(self.diffdec, gr.file_sink(gr.sizeof_gr_complex, "rx_diffdec.dat")) self._fg.connect(self.slicer, gr.file_sink(gr.sizeof_char, "rx_slicer.dat")) self._fg.connect(self.symbol_mapper, gr.file_sink(gr.sizeof_char, "rx_gray_decoder.dat")) self._fg.connect(self.unpack, gr.file_sink(gr.sizeof_char, "rx_unpack.dat")) def add_options(parser): """ Adds modulation-specific options to the standard parser """ parser.add_option("", "--excess-bw", type="float", default=_def_excess_bw, help="set RRC excess bandwith factor [default=%default] (PSK)") parser.add_option("", "--no-gray-code", dest="gray_code", action="store_false", default=_def_gray_code, help="disable gray coding on modulated bits (PSK)") parser.add_option("", "--costas-alpha", type="float", default=_def_costas_alpha, help="set Costas loop alpha value [default=%default] (PSK)") parser.add_option("", "--gain-mu", type="float", default=_def_gain_mu, help="set M&M symbol sync loop gain mu value [default=%default] (PSK)") parser.add_option("", "--mu", type="float", default=_def_mu, help="set M&M symbol sync loop mu value [default=%default] (PSK)") add_options=staticmethod(add_options) def extract_kwargs_from_options(options): """ Given command line options, create dictionary suitable for passing to __init__ """ return modulation_utils.extract_kwargs_from_options( dqpsk_demod.__init__, ('self', 'fg'), options) extract_kwargs_from_options=staticmethod(extract_kwargs_from_options)## Add these to the mod/demod registry#modulation_utils.add_type_1_mod('dqpsk', dqpsk_mod)modulation_utils.add_type_1_demod('dqpsk', dqpsk_demod)⌨️ 快捷键说明
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