#!/usr/bin/env python2 # -*- coding: utf-8 -*- # GR-GSM based transceiver # Follow graph implementation # # (C) 2016-2017 by Vadim Yanitskiy # (C) 2017 by Piotr Krysik # # All Rights Reserved # # This program 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 2 of the License, or # (at your option) any later version. # # This program 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 this program; if not, write to the Free Software Foundation, Inc., # 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. import pmt import time import grgsm from math import pi from gnuradio import digital from gnuradio import blocks from gnuradio import uhd from gnuradio import gr from gnuradio import filter from gnuradio.filter import firdes # HACK: should be implemented in C++! class dict_toggle_sign(gr.basic_block): def __init__(self): # only default arguments here gr.basic_block.__init__(self, name='Change sign of elts in dict', in_sig=[], out_sig=[] ) self.message_port_register_in(pmt.intern("dict_in")) self.message_port_register_out(pmt.intern("dict_out")) self.set_msg_handler(pmt.intern("dict_in"), self.change_sign) def change_sign(self, msg): if pmt.is_dict(msg): d = pmt.to_python(msg) for key, value in d.items(): d[key] *= -1 self.message_port_pub(pmt.intern("dict_out"), pmt.to_pmt(d)) class radio_if(gr.top_block): # PHY specific variables rx_freq = 935e6 tx_freq = 890e6 osr = 4 # Application state flags trx_started = False # GSM timings (in microseconds [uS]) # One timeslot duration is 576.9 μs = 15/26 ms, # or 156.25 symbol periods (a symbol period is 48/13 μs) GSM_SYM_PERIOD_uS = 48.0 / 13.0 GSM_TS_PERIOD_uS = GSM_SYM_PERIOD_uS * 156.25 GSM_UL_DL_SHIFT_uS = -(GSM_TS_PERIOD_uS * 3) # FIXME: shall be measured (automatically?) for # particular device and particular clock rate. # The current value is measured for USRP B2X0 at 26e6. delay_correction = (285.616 + 2 * GSM_SYM_PERIOD_uS) * 1e-6 def __init__(self, phy_args, phy_sample_rate, phy_rx_gain, phy_tx_gain, phy_ppm, phy_rx_antenna, phy_tx_antenna, trx_remote_addr, trx_base_port, trx_bind_addr = "0.0.0.0"): print("[i] Init Radio interface") # PHY specific variables self.sample_rate = phy_sample_rate self.rx_gain = phy_rx_gain self.tx_gain = phy_tx_gain self.ppm = phy_ppm gr.top_block.__init__(self, "GR-GSM TRX") # TRX Burst Interface self.trx_burst_if = grgsm.trx_burst_if( trx_bind_addr, trx_remote_addr, str(trx_base_port)) # RX path definition self.phy_src = uhd.usrp_source(phy_args, uhd.stream_args(cpu_format="fc32", channels=range(1))) self.phy_src.set_clock_rate(26e6, uhd.ALL_MBOARDS) self.phy_src.set_center_freq(self.rx_freq, 0) self.phy_src.set_antenna(phy_rx_antenna, 0) self.phy_src.set_samp_rate(phy_sample_rate) self.phy_src.set_bandwidth(650e3, 0) self.phy_src.set_gain(phy_rx_gain) self.msg_to_tag_src = grgsm.msg_to_tag() self.rotator_src = grgsm.controlled_rotator_cc( self.calc_phase_inc(self.rx_freq)) self.lpf = filter.fir_filter_ccf(1, firdes.low_pass( 1, phy_sample_rate, 125e3, 5e3, firdes.WIN_HAMMING, 6.76)) self.gsm_receiver = grgsm.receiver(self.osr, ([0]), ([])) self.ts_filter = grgsm.burst_timeslot_filter(0) self.ts_filter.set_policy(grgsm.FILTER_POLICY_DROP_ALL) # Connections self.connect( (self.phy_src, 0), (self.msg_to_tag_src, 0)) self.connect( (self.msg_to_tag_src, 0), (self.rotator_src, 0)) self.connect( (self.rotator_src, 0), (self.lpf, 0)) self.connect( (self.lpf, 0), (self.gsm_receiver, 0)) self.msg_connect( (self.gsm_receiver, 'C0'), (self.ts_filter, 'in')) self.msg_connect( (self.ts_filter, 'out'), (self.trx_burst_if, 'bursts')) # TX Path Definition self.phy_sink = uhd.usrp_sink(phy_args, uhd.stream_args(cpu_format="fc32", channels=range(1)), "packet_len") self.phy_sink.set_clock_rate(26e6, uhd.ALL_MBOARDS) self.phy_sink.set_antenna(phy_tx_antenna, 0) self.phy_sink.set_samp_rate(phy_sample_rate) self.phy_sink.set_center_freq(self.tx_freq, 0) self.phy_sink.set_gain(self.tx_gain) self.tx_time_setter = grgsm.txtime_setter( 0xffffffff, 0, 0, 0, 0, 0, self.delay_correction + self.GSM_UL_DL_SHIFT_uS * 1e-6) self.tx_burst_proc = grgsm.preprocess_tx_burst() self.pdu_to_tagged_stream = blocks.pdu_to_tagged_stream( blocks.byte_t, 'packet_len') self.gmsk_mod = grgsm.gsm_gmsk_mod( BT = 0.3, pulse_duration = 4, sps = self.osr) self.burst_shaper = digital.burst_shaper_cc( (firdes.window(firdes.WIN_HANN, 16, 0)), 0, 20, False, "packet_len") self.msg_to_tag_sink = grgsm.msg_to_tag() self.rotator_sink = grgsm.controlled_rotator_cc( -self.calc_phase_inc(self.tx_freq)) # Connections self.msg_connect( (self.trx_burst_if, 'bursts'), (self.tx_time_setter, 'bursts_in')) self.msg_connect( (self.tx_time_setter, 'bursts_out'), (self.tx_burst_proc, 'bursts_in')) self.msg_connect( (self.tx_burst_proc, 'bursts_out'), (self.pdu_to_tagged_stream, 'pdus')) self.connect( (self.pdu_to_tagged_stream, 0), (self.gmsk_mod, 0)) self.connect( (self.gmsk_mod, 0), (self.burst_shaper, 0)) self.connect( (self.burst_shaper, 0), (self.msg_to_tag_sink, 0)) self.connect( (self.msg_to_tag_sink, 0), (self.rotator_sink, 0)) self.connect( (self.rotator_sink, 0), (self.phy_sink, 0)) # RX & TX synchronization self.bt_filter = grgsm.burst_type_filter([3]) self.burst_to_fn_time = grgsm.burst_to_fn_time() # Connections self.msg_connect( (self.gsm_receiver, 'C0'), (self.bt_filter, 'bursts_in')) self.msg_connect( (self.bt_filter, 'bursts_out'), (self.burst_to_fn_time, 'bursts_in')) self.msg_connect( (self.burst_to_fn_time, 'fn_time_out'), (self.tx_time_setter, 'fn_time')) # AFC (Automatic Frequency Correction) self.gsm_clck_ctrl = grgsm.clock_offset_control( self.rx_freq, phy_sample_rate, osr = self.osr) self.dict_toggle_sign = dict_toggle_sign() # Connections self.msg_connect( (self.gsm_receiver, 'measurements'), (self.gsm_clck_ctrl, 'measurements')) self.msg_connect( (self.gsm_clck_ctrl, 'ctrl'), (self.msg_to_tag_src, 'msg')) self.msg_connect( (self.gsm_clck_ctrl, 'ctrl'), (self.dict_toggle_sign, 'dict_in')) self.msg_connect( (self.dict_toggle_sign, 'dict_out'), (self.msg_to_tag_sink, 'msg')) # Some UHD devices (such as UmTRX) do start the clock # not from 0, so it's required to reset it manually. # Resetting UHD source will also affect the sink. self.phy_src.set_time_now(uhd.time_spec(0.0)) def shutdown(self): print("[i] Shutdown Radio interface") self.stop() self.wait() def calc_phase_inc(self, fc): return self.ppm / 1.0e6 * 2 * pi * fc / self.sample_rate def set_rx_freq(self, fc): self.phy_src.set_center_freq(fc, 0) self.rotator_src.set_phase_inc(self.calc_phase_inc(fc)) self.rx_freq = fc def set_tx_freq(self, fc): self.phy_sink.set_center_freq(fc, 0) self.rotator_sink.set_phase_inc(-self.calc_phase_inc(fc)) self.tx_freq = fc def set_rx_gain(self, gain): self.phy_src.set_gain(gain, 0) self.rx_gain = gain def set_tx_gain(self, gain): self.phy_sink.set_gain(gain, 0) self.tx_gain = gain def set_ta(self, ta): print("[i] Setting TA value %d" % ta) advance_time_sec = ta * self.GSM_SYM_PERIOD_uS * 1e-6 self.tx_time_setter.set_timing_advance(advance_time_sec)