/* -*- c++ -*- */ /* * @file * @author (C) 2009-2017 by Piotr Krysik * @section LICENSE * * Gr-gsm 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. * * Gr-gsm 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 gr-gsm; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, * Boston, MA 02110-1301, USA. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include #include #include #include #include #include #include "receiver_impl.h" #include "viterbi_detector.h" #include "sch.h" #if 0 /* Files included for debuging */ #include "plotting/plotting.hpp" #include #include #endif #define SYNC_SEARCH_RANGE 30 namespace gr { namespace gsm { /* The public constructor */ receiver::sptr receiver::make( int osr, const std::vector &cell_allocation, const std::vector &tseq_nums, bool process_uplink) { return gnuradio::get_initial_sptr (new receiver_impl(osr, cell_allocation, tseq_nums, process_uplink)); } /* The private constructor */ receiver_impl::receiver_impl( int osr, const std::vector &cell_allocation, const std::vector &tseq_nums, bool process_uplink ) : gr::sync_block("receiver", gr::io_signature::make(1, -1, sizeof(gr_complex)), gr::io_signature::make(0, 0, 0)), d_OSR(osr), d_process_uplink(process_uplink), d_chan_imp_length(CHAN_IMP_RESP_LENGTH), d_counter(0), d_fcch_start_pos(0), d_freq_offset_setting(0), d_state(fcch_search), d_burst_nr(osr), d_failed_sch(0), d_signal_dbm(-120), d_tseq_nums(tseq_nums), d_cell_allocation(cell_allocation), d_last_time(0.0) { /** * Don't send samples to the receiver * until there are at least samples for one */ set_output_multiple(floor((TS_BITS + 2 * GUARD_PERIOD) * d_OSR)); /** * Prepare SCH sequence bits * * (TS_BITS + 2 * GUARD_PERIOD) * Burst and two guard periods * (one guard period is an arbitrary overlap) */ gmsk_mapper(SYNC_BITS, N_SYNC_BITS, d_sch_training_seq, gr_complex(0.0, -1.0)); /* Prepare bits of training sequences */ for (int i = 0; i < TRAIN_SEQ_NUM; i++) { /** * If first bit of the sequence is 0 * => first symbol is 1, else -1 */ gr_complex startpoint = train_seq[i][0] == 0 ? gr_complex(1.0, 0.0) : gr_complex(-1.0, 0.0); gmsk_mapper(train_seq[i], N_TRAIN_BITS, d_norm_training_seq[i], startpoint); } /* Register output ports */ message_port_register_out(pmt::mp("C0")); message_port_register_out(pmt::mp("CX")); message_port_register_out(pmt::mp("measurements")); /** * Configure the receiver, * i.e. tell it where to find which burst type */ configure_receiver(); } /* Our virtual destructor */ receiver_impl::~receiver_impl() {} int receiver_impl::work( int noutput_items, gr_vector_const_void_star &input_items, gr_vector_void_star &output_items) { gr_complex *input = (gr_complex *) input_items[0]; uint64_t start = nitems_read(0); uint64_t stop = start + noutput_items; d_freq_offset_tag_in_fcch = false; #if 0 /* FIXME: jak zrobić to rzutowanie poprawnie */ std::vector iii = (std::vector) input_items; #endif /* Time synchronization loop */ float current_time = static_cast(start / (GSM_SYMBOL_RATE * d_OSR)); if ((current_time - d_last_time) > 0.1) { pmt::pmt_t msg = pmt::make_tuple(pmt::mp("current_time"), pmt::from_double(current_time)); message_port_pub(pmt::mp("measurements"), msg); d_last_time = current_time; } /* Frequency correction loop */ std::vector freq_offset_tags; pmt::pmt_t key = pmt::string_to_symbol("setting_freq_offset"); get_tags_in_range(freq_offset_tags, 0, start, stop, key); if (!freq_offset_tags.empty()) { tag_t freq_offset_tag = freq_offset_tags[0]; uint64_t tag_offset = freq_offset_tag.offset - start; d_freq_offset_setting = pmt::to_double(freq_offset_tag.value); burst_type b_type = d_channel_conf.get_burst_type(d_burst_nr); if (d_state == synchronized && b_type == fcch_burst){ uint64_t last_sample_nr = ceil((GUARD_PERIOD + 2.0 * TAIL_BITS + 156.25) * d_OSR) + 1; d_freq_offset_tag_in_fcch = tag_offset < last_sample_nr; } } /* Main state machine */ switch (d_state) { case fcch_search: fcch_search_handler(input, noutput_items); break; case sch_search: sch_search_handler(input, noutput_items); break; case synchronized: synchronized_handler(input, input_items, noutput_items); break; } return 0; } void receiver_impl::fcch_search_handler(gr_complex *input, int noutput_items) { double freq_offset_tmp; /* Check if received samples is a FCCN burst */ if (!find_fcch_burst(input, noutput_items, freq_offset_tmp)) return; /* We found it, compose a message */ pmt::pmt_t msg = pmt::make_tuple( pmt::mp("freq_offset"), pmt::from_double(freq_offset_tmp - d_freq_offset_setting), pmt::mp("fcch_search") ); /* Notify FCCH loop */ message_port_pub(pmt::mp("measurements"), msg); /* Update current state */ d_state = sch_search; } void receiver_impl::sch_search_handler(gr_complex *input, int noutput_items) { std::vector channel_imp_resp(CHAN_IMP_RESP_LENGTH * d_OSR); unsigned char burst_buf[BURST_SIZE]; int rc, t1, t2, t3; int burst_start; /* Wait until we get a SCH burst */ if (!reach_sch_burst(noutput_items)) return; /* Get channel impulse response from it */ burst_start = get_sch_chan_imp_resp(input, &channel_imp_resp[0]); /* Detect bits using MLSE detection */ detect_burst(input, &channel_imp_resp[0], burst_start, burst_buf); /* Attempt to decode BSIC and frame number */ rc = decode_sch(&burst_buf[3], &t1, &t2, &t3, &d_ncc, &d_bcc); if (rc) { /** * There is error in the SCH burst, * go back to the FCCH search state */ d_state = fcch_search; return; } /* Set counter of bursts value */ d_burst_nr.set(t1, t2, t3, 0); d_burst_nr++; /* Consume samples up to the next guard period */ consume_each(burst_start + BURST_SIZE * d_OSR + 4 * d_OSR); /* Update current state */ d_state = synchronized; } void receiver_impl::synchronized_handler(gr_complex *input, gr_vector_const_void_star &input_items, int noutput_items) { /** * In this state receiver is synchronized and it processes * bursts according to burst type for given burst number */ std::vector channel_imp_resp(CHAN_IMP_RESP_LENGTH * d_OSR); unsigned int inputs_to_process = d_cell_allocation.size(); unsigned char output_binary[BURST_SIZE]; burst_type b_type; int to_consume = 0; int offset = 0; if (d_process_uplink) inputs_to_process *= 2; /* Process all connected inputs */ for (int input_nr = 0; input_nr < inputs_to_process; input_nr++) { input = (gr_complex *) input_items[input_nr]; double signal_pwr = 0; for (int ii = GUARD_PERIOD; ii < TS_BITS; ii++) signal_pwr += abs(input[ii]) * abs(input[ii]); signal_pwr = signal_pwr / (TS_BITS); d_signal_dbm = round(10 * log10(signal_pwr / 50)); if (input_nr == 0) d_c0_signal_dbm = d_signal_dbm; /* Get burst type for given burst number */ b_type = input_nr == 0 ? d_channel_conf.get_burst_type(d_burst_nr) : normal_or_noise; /* Process burst according to its type */ switch (b_type) { case fcch_burst: { if (d_freq_offset_tag_in_fcch) break; /* Send all-zero sequence message */ send_burst(d_burst_nr, fc_fb, GSMTAP_BURST_FCCH, input_nr); /* Extract frequency offset */ const unsigned first_sample = ceil((GUARD_PERIOD + 2 * TAIL_BITS) * d_OSR) + 1; const unsigned last_sample = first_sample + USEFUL_BITS * d_OSR - TAIL_BITS * d_OSR; double freq_offset_tmp = compute_freq_offset(input, first_sample, last_sample); /* Frequency correction loop */ pmt::pmt_t msg = pmt::make_tuple( pmt::mp("freq_offset"), pmt::from_double(freq_offset_tmp - d_freq_offset_setting), pmt::mp("synchronized")); message_port_pub(pmt::mp("measurements"), msg); break; } case sch_burst: { int d_ncc, d_bcc; int t1, t2, t3; int rc; /* Get channel impulse response */ d_c0_burst_start = get_sch_chan_imp_resp(input, &channel_imp_resp[0]); /* Perform MLSE detection */ detect_burst(input, &channel_imp_resp[0], d_c0_burst_start, output_binary); /* Compose a message with GSMTAP header and bits */ send_burst(d_burst_nr, output_binary, GSMTAP_BURST_SCH, input_nr); /* Attempt to decode SCH burst */ rc = decode_sch(&output_binary[3], &t1, &t2, &t3, &d_ncc, &d_bcc); if (rc) { if (++d_failed_sch >= MAX_SCH_ERRORS) { /* We have to resynchronize, change state */ d_state = fcch_search; /* Frequency correction loop */ pmt::pmt_t msg = pmt::make_tuple(pmt::mp("freq_offset"), pmt::from_double(0.0),pmt::mp("sync_loss")); message_port_pub(pmt::mp("measurements"), msg); } break; } /** * Decoding was successful, now * compute offset from burst_start, * burst should start after a guard period. */ offset = d_c0_burst_start - floor((GUARD_PERIOD) * d_OSR); to_consume += offset; d_failed_sch = 0; break; } case normal_burst: { float normal_corr_max; /** * Get channel impulse response for given * training sequence number - d_bcc */ d_c0_burst_start = get_norm_chan_imp_resp(input, &channel_imp_resp[0], &normal_corr_max, d_bcc); /* Perform MLSE detection */ detect_burst(input, &channel_imp_resp[0], d_c0_burst_start, output_binary); /* Compose a message with GSMTAP header and bits */ send_burst(d_burst_nr, output_binary, GSMTAP_BURST_NORMAL, input_nr); break; } case dummy_or_normal: { unsigned int normal_burst_start, dummy_burst_start; float dummy_corr_max, normal_corr_max; dummy_burst_start = get_norm_chan_imp_resp(input, &channel_imp_resp[0], &dummy_corr_max, TS_DUMMY); normal_burst_start = get_norm_chan_imp_resp(input, &channel_imp_resp[0], &normal_corr_max, d_bcc); if (normal_corr_max > dummy_corr_max) { d_c0_burst_start = normal_burst_start; /* Perform MLSE detection */ detect_burst(input, &channel_imp_resp[0], normal_burst_start, output_binary); /* Compose a message with GSMTAP header and bits */ send_burst(d_burst_nr, output_binary, GSMTAP_BURST_NORMAL, input_nr); } else { d_c0_burst_start = dummy_burst_start; /* Compose a message with GSMTAP header and bits */ send_burst(d_burst_nr, dummy_burst, GSMTAP_BURST_DUMMY, input_nr); } break; } case normal_or_noise: { std::vector v(input, input + noutput_items); float normal_corr_max = -1e6; float normal_corr_max_tmp; unsigned int burst_start; int max_tn, tseq_num; if (d_tseq_nums.size() == 0) { /** * There is no information about training sequence, * however the receiver can detect it with use of a * very simple algorithm based on finding */ get_norm_chan_imp_resp(input, &channel_imp_resp[0], &normal_corr_max, 0); float ts_max = normal_corr_max; int ts_max_num = 0; for (int ss = 1; ss <= 7; ss++) { get_norm_chan_imp_resp(input, &channel_imp_resp[0], &normal_corr_max, ss); if (ts_max < normal_corr_max) { ts_max = normal_corr_max; ts_max_num = ss; } } d_tseq_nums.push_back(ts_max_num); } /* Choose proper training sequence number */ tseq_num = input_nr <= d_tseq_nums.size() ? d_tseq_nums[input_nr - 1] : d_tseq_nums.back(); /* Get channel impulse response */ burst_start = get_norm_chan_imp_resp(input, &channel_imp_resp[0], &normal_corr_max, tseq_num); /* Perform MLSE detection */ detect_burst(input, &channel_imp_resp[0], burst_start, output_binary); /* Compose a message with GSMTAP header and bits */ send_burst(d_burst_nr, output_binary, GSMTAP_BURST_NORMAL, input_nr); break; } case dummy: send_burst(d_burst_nr, dummy_burst, GSMTAP_BURST_DUMMY, input_nr); break; case rach_burst: case empty: /* Do nothing */ break; } if (input_nr == input_items.size() - 1) { /* Go to the next burst */ d_burst_nr++; /* Consume samples of the burst up to next guard period */ to_consume += TS_BITS * d_OSR + d_burst_nr.get_offset(); consume_each(to_consume); } } } bool receiver_impl::find_fcch_burst(const gr_complex *input, const int nitems, double &computed_freq_offset) { /* Circular buffer used to scan through signal to find */ boost::circular_buffer phase_diff_buffer(FCCH_HITS_NEEDED * d_OSR); boost::circular_buffer::iterator buffer_iter; float lowest_max_min_diff; float phase_diff; /* Best match for FCCH burst */ float min_phase_diff; float max_phase_diff; double best_sum = 0; gr_complex conjprod; int start_pos; int hit_count; int miss_count; int sample_number = 0; int to_consume = 0; bool result = false; bool end = false; /* Possible states of FCCH search algorithm */ enum states { init, /* initialize variables */ search, /* search for positive samples */ found_something, /* search for FCCH and the best position of it */ fcch_found, /* when FCCH was found */ search_fail /* when there is no FCCH in the input vector */ } fcch_search_state; /* Set initial state */ fcch_search_state = init; while (!end) { switch (fcch_search_state) { case init: { hit_count = 0; miss_count = 0; start_pos = -1; lowest_max_min_diff = 99999; phase_diff_buffer.clear(); /* Change current state */ fcch_search_state = search; break; } case search: { sample_number++; if (sample_number > nitems - FCCH_HITS_NEEDED * d_OSR) { /** * If it isn't possible to find FCCH, because * there is too few samples left to look into, * don't do anything with those samples which are left * and consume only those which were checked */ to_consume = sample_number; fcch_search_state = search_fail; break; } phase_diff = compute_phase_diff(input[sample_number], input[sample_number - 1]); /** * If a positive phase difference was found * switch to state in which searches for FCCH */ if (phase_diff > 0) { to_consume = sample_number; fcch_search_state = found_something; } else { fcch_search_state = search; } break; } case found_something: { if (phase_diff > 0) hit_count++; else miss_count++; if ((miss_count >= FCCH_MAX_MISSES * d_OSR) && (hit_count <= FCCH_HITS_NEEDED * d_OSR)) { /* If miss_count exceeds limit before hit_count */ fcch_search_state = init; continue; } if (((miss_count >= FCCH_MAX_MISSES * d_OSR) && (hit_count > FCCH_HITS_NEEDED * d_OSR)) || (hit_count > 2 * FCCH_HITS_NEEDED * d_OSR)) { /** * If hit_count and miss_count exceeds * limit then FCCH was found */ fcch_search_state = fcch_found; continue; } if ((miss_count < FCCH_MAX_MISSES * d_OSR) && (hit_count > FCCH_HITS_NEEDED * d_OSR)) { /** * Find difference between minimal and maximal * element in the buffer. For FCCH this value * should be low. This part is searching for * a region where this value is lowest. */ min_phase_diff = *(min_element(phase_diff_buffer.begin(), phase_diff_buffer.end())); max_phase_diff = *(max_element(phase_diff_buffer.begin(), phase_diff_buffer.end())); if (lowest_max_min_diff > max_phase_diff - min_phase_diff) { lowest_max_min_diff = max_phase_diff - min_phase_diff; start_pos = sample_number - FCCH_HITS_NEEDED * d_OSR - FCCH_MAX_MISSES * d_OSR; best_sum = 0; for (buffer_iter = phase_diff_buffer.begin(); buffer_iter != (phase_diff_buffer.end()); buffer_iter++) { /* Store best value of phase offset sum */ best_sum += *buffer_iter - (M_PI / 2) / d_OSR; } } } /* If there is no single sample left to check */ if (++sample_number >= nitems) { fcch_search_state = search_fail; continue; } phase_diff = compute_phase_diff(input[sample_number], input[sample_number-1]); phase_diff_buffer.push_back(phase_diff); fcch_search_state = found_something; break; } case fcch_found: { /* Consume one FCCH burst */ to_consume = start_pos + FCCH_HITS_NEEDED * d_OSR + 1; d_fcch_start_pos = d_counter + start_pos; /** * Compute frequency offset * * 1625000.0 / 6 - GMSK symbol rate in GSM */ double phase_offset = best_sum / FCCH_HITS_NEEDED; double freq_offset = phase_offset * 1625000.0 / 6 / (2 * M_PI); computed_freq_offset = freq_offset; end = true; result = true; break; } case search_fail: end = true; result = false; break; } } d_counter += to_consume; consume_each(to_consume); return result; } double receiver_impl::compute_freq_offset(const gr_complex * input, unsigned first_sample, unsigned last_sample) { double phase_sum = 0; unsigned ii; for (ii = first_sample; ii < last_sample; ii++) { double phase_diff = compute_phase_diff(input[ii], input[ii-1]) - (M_PI / 2) / d_OSR; phase_sum += phase_diff; } double phase_offset = phase_sum / (last_sample - first_sample); double freq_offset = phase_offset * 1625000.0 / (12.0 * M_PI); return freq_offset; } inline float receiver_impl::compute_phase_diff(gr_complex val1, gr_complex val2) { gr_complex conjprod = val1 * conj(val2); return fast_atan2f(imag(conjprod), real(conjprod)); } bool receiver_impl::reach_sch_burst(const int nitems) { /* It just consumes samples to get near to a SCH burst */ int to_consume = 0; bool result = false; unsigned sample_nr = d_fcch_start_pos + (FRAME_BITS - SAFETY_MARGIN) * d_OSR; /* Consume samples until d_counter will be equal to sample_nr */ if (d_counter < sample_nr) { to_consume = d_counter + nitems >= sample_nr ? sample_nr - d_counter : nitems; } else { to_consume = 0; result = true; } d_counter += to_consume; consume_each(to_consume); return result; } int receiver_impl::get_sch_chan_imp_resp(const gr_complex *input, gr_complex * chan_imp_resp) { std::vector correlation_buffer; std::vector window_energy_buffer; std::vector power_buffer; int chan_imp_resp_center = 0; int strongest_window_nr; int burst_start; float energy = 0; int len = (SYNC_POS + SYNC_SEARCH_RANGE) * d_OSR; for (int ii = SYNC_POS * d_OSR; ii < len; ii++) { gr_complex correlation = correlate_sequence(&d_sch_training_seq[5], N_SYNC_BITS - 10, &input[ii]); correlation_buffer.push_back(correlation); power_buffer.push_back(std::pow(abs(correlation), 2)); } /* Compute window energies */ std::vector::iterator iter = power_buffer.begin(); while (iter != power_buffer.end()) { std::vector::iterator iter_ii = iter; bool loop_end = false; energy = 0; for (int ii = 0; ii < (d_chan_imp_length) * d_OSR; ii++, iter_ii++) { if (iter_ii == power_buffer.end()) { loop_end = true; break; } energy += (*iter_ii); } if (loop_end) break; window_energy_buffer.push_back(energy); iter++; } strongest_window_nr = max_element(window_energy_buffer.begin(), window_energy_buffer.end()) - window_energy_buffer.begin(); #if 0 d_channel_imp_resp.clear(); #endif float max_correlation = 0; for (int ii = 0; ii < (d_chan_imp_length) * d_OSR; ii++) { gr_complex correlation = correlation_buffer[strongest_window_nr + ii]; if (abs(correlation) > max_correlation) { chan_imp_resp_center = ii; max_correlation = abs(correlation); } #if 0 d_channel_imp_resp.push_back(correlation); #endif chan_imp_resp[ii] = correlation; } burst_start = strongest_window_nr + chan_imp_resp_center - 48 * d_OSR - 2 * d_OSR + 2 + SYNC_POS * d_OSR; return burst_start; } void receiver_impl::detect_burst(const gr_complex * input, gr_complex * chan_imp_resp, int burst_start, unsigned char * output_binary) { std::vector rhh_temp(CHAN_IMP_RESP_LENGTH * d_OSR); unsigned int stop_states[2] = {4, 12}; gr_complex filtered_burst[BURST_SIZE]; gr_complex rhh[CHAN_IMP_RESP_LENGTH]; float output[BURST_SIZE]; int start_state = 3; autocorrelation(chan_imp_resp, &rhh_temp[0], d_chan_imp_length*d_OSR); for (int ii = 0; ii < d_chan_imp_length; ii++) rhh[ii] = conj(rhh_temp[ii*d_OSR]); mafi(&input[burst_start], BURST_SIZE, chan_imp_resp, d_chan_imp_length * d_OSR, filtered_burst); viterbi_detector(filtered_burst, BURST_SIZE, rhh, start_state, stop_states, 2, output); for (int i = 0; i < BURST_SIZE; i++) output_binary[i] = output[i] > 0; } void receiver_impl::gmsk_mapper(const unsigned char * input, int nitems, gr_complex * gmsk_output, gr_complex start_point) { gr_complex j = gr_complex(0.0, 1.0); gmsk_output[0] = start_point; int previous_symbol = 2 * input[0] - 1; int current_symbol; int encoded_symbol; for (int i = 1; i < nitems; i++) { /* Change bits representation to NRZ */ current_symbol = 2 * input[i] - 1; /* Differentially encode */ encoded_symbol = current_symbol * previous_symbol; /* And do GMSK mapping */ gmsk_output[i] = j * gr_complex(encoded_symbol, 0.0) * gmsk_output[i-1]; previous_symbol = current_symbol; } } gr_complex receiver_impl::correlate_sequence(const gr_complex * sequence, int length, const gr_complex * input) { gr_complex result(0.0, 0.0); for (int ii = 0; ii < length; ii++) result += sequence[ii] * conj(input[ii * d_OSR]); return result / gr_complex(length, 0); } /* Computes autocorrelation for positive arguments */ inline void receiver_impl::autocorrelation(const gr_complex * input, gr_complex * out, int nitems) { for (int k = nitems - 1; k >= 0; k--) { out[k] = gr_complex(0, 0); for (int i = k; i < nitems; i++) out[k] += input[i] * conj(input[i - k]); } } inline void receiver_impl::mafi(const gr_complex * input, int nitems, gr_complex * filter, int filter_length, gr_complex * output) { for (int n = 0; n < nitems; n++) { int a = n * d_OSR; output[n] = 0; for (int ii = 0; ii < filter_length; ii++) { if ((a + ii) >= nitems * d_OSR) break; output[n] += input[a + ii] * filter[ii]; } } } /* Especially computations of strongest_window_nr */ int receiver_impl::get_norm_chan_imp_resp(const gr_complex *input, gr_complex *chan_imp_resp, float *corr_max, int bcc) { std::vector correlation_buffer; std::vector window_energy_buffer; std::vector power_buffer; int search_center = (int) (TRAIN_POS + GUARD_PERIOD) * d_OSR; int search_start_pos = search_center + 1 - 5 * d_OSR; int search_stop_pos = search_center + d_chan_imp_length * d_OSR + 5 * d_OSR; for (int ii = search_start_pos; ii < search_stop_pos; ii++) { gr_complex correlation = correlate_sequence( &d_norm_training_seq[bcc][TRAIN_BEGINNING], N_TRAIN_BITS - 10, &input[ii]); correlation_buffer.push_back(correlation); power_buffer.push_back(std::pow(abs(correlation), 2)); } #if 0 plot(power_buffer); #endif /* Compute window energies */ std::vector::iterator iter = power_buffer.begin(); while (iter != power_buffer.end()) { std::vector::iterator iter_ii = iter; bool loop_end = false; float energy = 0; int len = d_chan_imp_length * d_OSR; for (int ii = 0; ii < len; ii++, iter_ii++) { if (iter_ii == power_buffer.end()) { loop_end = true; break; } energy += (*iter_ii); } if (loop_end) break; window_energy_buffer.push_back(energy); iter++; } /* Calculate the strongest window number */ int strongest_window_nr = max_element(window_energy_buffer.begin(), window_energy_buffer.end() - d_chan_imp_length * d_OSR) - window_energy_buffer.begin(); if (strongest_window_nr < 0) strongest_window_nr = 0; float max_correlation = 0; for (int ii = 0; ii < d_chan_imp_length * d_OSR; ii++) { gr_complex correlation = correlation_buffer[strongest_window_nr + ii]; if (abs(correlation) > max_correlation) max_correlation = abs(correlation); #if 0 d_channel_imp_resp.push_back(correlation); #endif chan_imp_resp[ii] = correlation; } *corr_max = max_correlation; /** * Compute first sample position, which corresponds * to the first sample of the impulse response */ return search_start_pos + strongest_window_nr - TRAIN_POS * d_OSR; } void receiver_impl::send_burst(burst_counter burst_nr, const unsigned char * burst_binary, uint8_t burst_type, unsigned int input_nr) { /* Buffer for GSMTAP header and burst */ uint8_t buf[sizeof(gsmtap_hdr) + BURST_SIZE]; uint32_t frame_number; uint16_t arfcn; uint8_t tn; /* Set pointers to GSMTAP header and burst inside buffer */ struct gsmtap_hdr *tap_header = (struct gsmtap_hdr *) buf; uint8_t *burst = buf + sizeof(gsmtap_hdr); tap_header->version = GSMTAP_VERSION; tap_header->hdr_len = sizeof(gsmtap_hdr) / 4; tap_header->type = GSMTAP_TYPE_UM_BURST; tap_header->sub_type = burst_type; bool dl_burst = !(input_nr >= d_cell_allocation.size()); if (dl_burst) { tn = static_cast(d_burst_nr.get_timeslot_nr()); frame_number = htobe32(d_burst_nr.get_frame_nr()); arfcn = htobe16(d_cell_allocation[input_nr]); } else { input_nr -= d_cell_allocation.size(); tn = static_cast (d_burst_nr.subtract_timeslots(3).get_timeslot_nr()); frame_number = htobe32( d_burst_nr.subtract_timeslots(3).get_frame_nr()); arfcn = htobe16( d_cell_allocation[input_nr] | GSMTAP_ARFCN_F_UPLINK); } tap_header->frame_number = frame_number; tap_header->timeslot = tn; tap_header->arfcn = arfcn; tap_header->signal_dbm = static_cast(d_signal_dbm); tap_header->snr_db = 0; /* FIXME: Can we calculate this? */ /* Copy burst to the buffer */ memcpy(burst, burst_binary, BURST_SIZE); /* Allocate a new message */ pmt::pmt_t blob = pmt::make_blob(buf, sizeof(gsmtap_hdr) + BURST_SIZE); pmt::pmt_t msg = pmt::cons(pmt::PMT_NIL, blob); /* Send message */ if (input_nr == 0) message_port_pub(pmt::mp("C0"), msg); else message_port_pub(pmt::mp("CX"), msg); } void receiver_impl::configure_receiver(void) { d_channel_conf.set_multiframe_type(TIMESLOT0, multiframe_51); d_channel_conf.set_burst_types(TIMESLOT0, TEST51, sizeof(TEST51) / sizeof(unsigned), dummy_or_normal); d_channel_conf.set_burst_types(TIMESLOT0, TEST_CCH_FRAMES, sizeof(TEST_CCH_FRAMES) / sizeof(unsigned), dummy_or_normal); d_channel_conf.set_burst_types(TIMESLOT0, FCCH_FRAMES, sizeof(FCCH_FRAMES) / sizeof(unsigned), fcch_burst); d_channel_conf.set_burst_types(TIMESLOT0, SCH_FRAMES, sizeof(SCH_FRAMES) / sizeof(unsigned), sch_burst); d_channel_conf.set_multiframe_type(TIMESLOT1, multiframe_51); d_channel_conf.set_burst_types(TIMESLOT1, TEST51, sizeof(TEST51) / sizeof(unsigned), dummy_or_normal); d_channel_conf.set_multiframe_type(TIMESLOT2, multiframe_51); d_channel_conf.set_burst_types(TIMESLOT2, TEST51, sizeof(TEST51) / sizeof(unsigned), dummy_or_normal); d_channel_conf.set_multiframe_type(TIMESLOT3, multiframe_51); d_channel_conf.set_burst_types(TIMESLOT3, TEST51, sizeof(TEST51) / sizeof(unsigned), dummy_or_normal); d_channel_conf.set_multiframe_type(TIMESLOT4, multiframe_51); d_channel_conf.set_burst_types(TIMESLOT4, TEST51, sizeof(TEST51) / sizeof(unsigned), dummy_or_normal); d_channel_conf.set_multiframe_type(TIMESLOT5, multiframe_51); d_channel_conf.set_burst_types(TIMESLOT5, TEST51, sizeof(TEST51) / sizeof(unsigned), dummy_or_normal); d_channel_conf.set_multiframe_type(TIMESLOT6, multiframe_51); d_channel_conf.set_burst_types(TIMESLOT6, TEST51, sizeof(TEST51) / sizeof(unsigned), dummy_or_normal); d_channel_conf.set_multiframe_type(TIMESLOT7, multiframe_51); d_channel_conf.set_burst_types(TIMESLOT7, TEST51, sizeof(TEST51) / sizeof(unsigned), dummy_or_normal); } void receiver_impl::set_cell_allocation( const std::vector &cell_allocation) { d_cell_allocation = cell_allocation; } void receiver_impl::set_tseq_nums(const std::vector &tseq_nums) { d_tseq_nums = tseq_nums; } void receiver_impl::reset(void) { d_state = fcch_search; } } /* namespace gsm */ } /* namespace gr */