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author | piotr <Piotr Krysik pkrysik@elka.pw.edu.pl> | 2014-07-08 16:38:42 +0200 |
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committer | piotr <Piotr Krysik pkrysik@elka.pw.edu.pl> | 2014-07-08 16:38:42 +0200 |
commit | 7af92cadd52b373a3a874991f9e4a100e4b2c97a (patch) | |
tree | 989225c8bf632d45096963f46140d044b1209fc1 /lib/receiver/receiver_impl.h | |
parent | f0039b49273f4dc14c9352ff77ccf57511d07247 (diff) |
Correction in plotting.h
Diffstat (limited to 'lib/receiver/receiver_impl.h')
-rw-r--r-- | lib/receiver/receiver_impl.h | 214 |
1 files changed, 214 insertions, 0 deletions
diff --git a/lib/receiver/receiver_impl.h b/lib/receiver/receiver_impl.h new file mode 100644 index 0000000..b8b8b68 --- /dev/null +++ b/lib/receiver/receiver_impl.h @@ -0,0 +1,214 @@ +/* -*- c++ -*- */ +/* + * Copyright 2014 <+YOU OR YOUR COMPANY+>. + * + * This 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. + * + * This software 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 software; see the file COPYING. If not, write to + * the Free Software Foundation, Inc., 51 Franklin Street, + * Boston, MA 02110-1301, USA. + */ + +#ifndef INCLUDED_GSM_RECEIVER_IMPL_H +#define INCLUDED_GSM_RECEIVER_IMPL_H + +#include <gsm/receiver.h> +#include <gsm_constants.h> +#include <receiver_config.h> +#include <gsmtap.h> + +namespace gr { + namespace gsm { + + typedef std::vector<gr_complex> vector_complex; + + class receiver_impl : public receiver + { + private: + /**@name Configuration of the receiver */ + //@{ + const int d_OSR; ///< oversampling ratio + const int d_chan_imp_length; ///< channel impulse length + uint16_t d_arfcn; + int8_t d_signal_dbm; + //@} + + gr_complex d_sch_training_seq[N_SYNC_BITS]; ///<encoded training sequence of a SCH burst + gr_complex d_norm_training_seq[TRAIN_SEQ_NUM][N_TRAIN_BITS]; ///<encoded training sequences of a normal bursts and dummy bursts + + feval_dd *d_tuner; ///<callback to a python object which is used for frequency tunning + + /** Counts samples consumed by the receiver + * + * It is used in beetween find_fcch_burst and reach_sch_burst calls. + * My intention was to synchronize this counter with some internal sample + * counter of the USRP. Simple access to such USRP's counter isn't possible + * so this variable isn't used in the "synchronized" state of the receiver yet. + */ + unsigned d_counter; + + /**@name Variables used to store result of the find_fcch_burst fuction */ + //@{ + unsigned d_fcch_start_pos; ///< position of the first sample of the fcch burst + float d_freq_offset; ///< frequency offset of the received signal + //@} + std::list<double> d_freq_offset_vals; + + /**@name Identifiers of the BTS extracted from the SCH burst */ + //@{ + int d_ncc; ///< network color code + int d_bcc; ///< base station color code + //@} + + /**@name Internal state of the gsm receiver */ + //@{ + enum states { + first_fcch_search, next_fcch_search, sch_search, // synchronization search part + synchronized // receiver is synchronized in this state + } d_state; + //@} + + /**@name Variables which make internal state in the "synchronized" state */ + //@{ + burst_counter d_burst_nr; ///< frame number and timeslot number + channel_configuration d_channel_conf; ///< mapping of burst_counter to burst_type + //@} + + unsigned d_failed_sch; ///< number of subsequent erroneous SCH bursts + + /** Function whis is used to search a FCCH burst and to compute frequency offset before + * "synchronized" state of the receiver + * + * TODO: Describe the FCCH search algorithm in the documentation + * @param input vector with input signal + * @param nitems number of samples in the input vector + * @return + */ + bool find_fcch_burst(const gr_complex *input, const int nitems); + + /** Computes frequency offset from FCCH burst samples + * + * @param input vector with input samples + * @param first_sample number of the first sample of the FCCH busrt + * @param last_sample number of the last sample of the FCCH busrt + * @return frequency offset + */ + double compute_freq_offset(const gr_complex * input, unsigned first_sample, unsigned last_sample); + + /** Calls d_tuner's method to set frequency offset from Python level + * + * @param freq_offset absolute frequency offset of the received signal + */ + void set_frequency(double freq_offset); + + /** Computes angle between two complex numbers + * + * @param val1 first complex number + * @param val2 second complex number + * @return + */ + inline float compute_phase_diff(gr_complex val1, gr_complex val2); + + /** Function whis is used to get near to SCH burst + * + * @param nitems number of samples in the gsm_receiver's buffer + * @return true if SCH burst is near, false otherwise + */ + bool reach_sch_burst(const int nitems); + + /** Extracts channel impulse response from a SCH burst and computes first sample number of this burst + * + * @param input vector with input samples + * @param chan_imp_resp complex vector where channel impulse response will be stored + * @return number of first sample of the burst + */ + int get_sch_chan_imp_resp(const gr_complex *input, gr_complex * chan_imp_resp); + + /** MLSE detection of a burst bits + * + * Detects bits of burst using viterbi algorithm. + * @param input vector with input samples + * @param chan_imp_resp vector with the channel impulse response + * @param burst_start number of the first sample of the burst + * @param output_binary vector with output bits + */ + void detect_burst(const gr_complex * input, gr_complex * chan_imp_resp, int burst_start, unsigned char * output_binary); + + /** Encodes differentially input bits and maps them into MSK states + * + * @param input vector with input bits + * @param nitems number of samples in the "input" vector + * @param gmsk_output bits mapped into MSK states + * @param start_point first state + */ + void gmsk_mapper(const unsigned char * input, int nitems, gr_complex * gmsk_output, gr_complex start_point); + + /** Correlates MSK mapped sequence with input signal + * + * @param sequence MKS mapped sequence + * @param length length of the sequence + * @param input_signal vector with input samples + * @return correlation value + */ + gr_complex correlate_sequence(const gr_complex * sequence, int length, const gr_complex * input); + + /** Computes autocorrelation of input vector for positive arguments + * + * @param input vector with input samples + * @param out output vector + * @param nitems length of the input vector + */ + inline void autocorrelation(const gr_complex * input, gr_complex * out, int nitems); + + /** Filters input signal through channel impulse response + * + * @param input vector with input samples + * @param nitems number of samples to pass through filter + * @param filter filter taps - channel impulse response + * @param filter_length nember of filter taps + * @param output vector with filtered samples + */ + inline void mafi(const gr_complex * input, int nitems, gr_complex * filter, int filter_length, gr_complex * output); + + /** Extracts channel impulse response from a normal burst and computes first sample number of this burst + * + * @param input vector with input samples + * @param chan_imp_resp complex vector where channel impulse response will be stored + * @param search_range possible absolute offset of a channel impulse response start + * @param bcc base station color code - number of a training sequence + * @return first sample number of normal burst + */ + int get_norm_chan_imp_resp(const gr_complex *input, gr_complex * chan_imp_resp, float *corr_max, int bcc); + + /** + * + */ + void send_burst(burst_counter burst_nr, const unsigned char * burst_binary, burst_type b_type); + + /** + * + */ + void configure_receiver(); + + public: + receiver_impl(feval_dd * tuner, int osr, int arfcn); + ~receiver_impl(); + +// void forecast(int noutput_items, gr_vector_int &ninput_items_required); + + int work(int noutput_items, gr_vector_const_void_star &input_items, gr_vector_void_star &output_items); + }; + } // namespace gsm +} // namespace gr + +#endif /* INCLUDED_GSM_RECEIVER_IMPL_H */ + |