qa_advanced_receiver_sb_cc.py

#!/usr/bin/env python
# -*- coding: utf-8 -*-
#
# Copyright 2016, 2019 Andrej Rode, Johannes Demel.
#
# 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.
#
# import sys
# print(sys.path)

from gnuradio import gr, gr_unittest
from gnuradio import blocks, digital
import gfdm_python as gfdm
from pygfdm import filters, utils
from pygfdm.gfdm_receiver import gfdm_demodulate_block
from pygfdm.mapping import get_subcarrier_map
from pygfdm.utils import get_random_qpsk, calculate_signal_energy
import numpy as np


def struct(data):
    return type('Struct', (object,), data)()


class qa_advanced_receiver_sb_cc(gr_unittest.TestCase):
    def setUp(self):
        self.tb = gr.top_block()

    def tearDown(self):
        self.tb = None

    def test_001_simple_receiver(self):
        # make sure advanced receiver works like simple receiver
        # in case no IC iterations are applied!
        reps = 5
        alpha = .5
        M = 127
        K = 16
        L = 2
        taps = filters.get_frequency_domain_filter('rrc', alpha, M, K, L)
        data = np.array([], dtype=np.complex)
        ref = np.array([], dtype=np.complex)
        for _11 in range(reps):
            d = utils.get_random_qpsk(M * K)
            ref = np.append(ref, gfdm_demodulate_block(d, taps, K, M, L))
            data = np.append(data, d)
        # print data
        # print ref
        # print "MAXIMUM ref value: ", np.max(abs(ref))

        src = blocks.vector_source_c(data)
        est_data = np.ones(len(data), dtype=np.complex)
        est_src = blocks.vector_source_c(est_data)
        gfdm_constellation = digital.constellation_qpsk().base()
        mod = gfdm.advanced_receiver_sb_cc(M, K, L, 0,
                                           taps, gfdm_constellation,
                                           np.arange(K), 0)
        dst = blocks.vector_sink_c()

        self.tb.connect(src, (mod, 0), dst)
        self.tb.connect(est_src, (mod, 1))
        # set up fg
        self.tb.run()
        # check data
        res = np.array(dst.data())

        self.assertComplexTuplesAlmostEqual(ref, res, 4)

    def test_002_t(self):
        n_frames = 1
        gfdm_var = struct({'subcarriers': 64,
                           'timeslots': 9,
                           'alpha': 0.5,
                           'overlap': 2, }
                          )
        gfdm_constellation = digital.constellation_qpsk().base()
        self.f_taps = f_taps = filters.get_frequency_domain_filter('rrc', 1.0,
                                                                   gfdm_var.timeslots,
                                                                   gfdm_var.subcarriers,
                                                                   gfdm_var.overlap)
        source_bits = np.random.randint(0, len(gfdm_constellation.points()),
                                        n_frames * gfdm_var.timeslots *
                                        gfdm_var.subcarriers).astype(np.uint8)
        self.random_bits = blocks.vector_source_b(source_bits,
                                                  False)
        self.bits_to_symbols = digital.chunks_to_symbols_bc((gfdm_constellation.points()), 1)
        self.mod = gfdm.simple_modulator_cc(gfdm_var.timeslots,
                                            gfdm_var.subcarriers,
                                            gfdm_var.overlap, f_taps)
        self.demod = gfdm.advanced_receiver_sb_cc(gfdm_var.timeslots,
                                                  gfdm_var.subcarriers,
                                                  gfdm_var.overlap, 64,
                                                  f_taps, gfdm_constellation,
                                                  np.arange(gfdm_var.subcarriers), 0)
        self.tx_symbols = blocks.vector_sink_c()
        self.rx_symbols = blocks.vector_sink_c()
        self.tb.connect((self.random_bits, 0), (self.bits_to_symbols, 0))
        self.tb.connect((self.bits_to_symbols, 0), (self.tx_symbols, 0))
        self.tb.connect((self.bits_to_symbols, 0), (self.mod, 0))
        self.tb.connect((self.mod, 0), (self.demod, 0))
        self.tb.connect((self.demod, 0), (self.rx_symbols, 0))
        self.tb.run()
        ref = np.array(self.tx_symbols.data())
        res = np.array(self.rx_symbols.data())
        # more or less make sure all symbols have their correct sign.
        self.assertComplexTuplesAlmostEqual(ref, res, 2)

    def test_003_setIC(self):
        ic = 2
        timeslots = 9
        subcarriers = 32
        active_subcarriers = 20
        overlap = 2
        f_taps = filters.get_frequency_domain_filter('rrc', .5, timeslots,
                                                     subcarriers, overlap)
        gfdm_constellation = digital.constellation_qpsk().base()
        subcarrier_map = get_subcarrier_map(subcarriers, active_subcarriers)
        demod = gfdm.advanced_receiver_sb_cc(timeslots, subcarriers, overlap,
                                             64, f_taps, gfdm_constellation,
                                             subcarrier_map, 0)
        demod.set_ic(ic)
        self.assertEqual(ic, demod.get_ic())

    def test_004_active_subcarriers(self):
        n_frames = 1
        timeslots = 9
        subcarriers = 32
        active_subcarriers = 20
        overlap = 2
        ic_iterations = 64
        f_taps = filters.get_frequency_domain_filter('rrc', .5, timeslots,
                                                     subcarriers, overlap)
        gfdm_constellation = digital.constellation_qpsk().base()
        print(gfdm_constellation.points())
        subcarrier_map = get_subcarrier_map(subcarriers, active_subcarriers)

        data = get_random_qpsk(n_frames * timeslots * active_subcarriers)
        data *= 2.
        src = blocks.vector_source_c(data)
        mapper = gfdm.resource_mapper_cc(timeslots, subcarriers,
                                         active_subcarriers, subcarrier_map,
                                         True)
        mod = gfdm.simple_modulator_cc(timeslots, subcarriers, overlap, f_taps)
        demod = gfdm.advanced_receiver_sb_cc(timeslots, subcarriers, overlap,
                                             ic_iterations, f_taps,
                                             gfdm_constellation,
                                             subcarrier_map, 0)
        demod.set_ic(64)
        demapper = gfdm.resource_demapper_cc(timeslots, subcarriers,
                                             active_subcarriers,
                                             subcarrier_map, True)
        snk = blocks.vector_sink_c()
        self.tb.connect(src, mapper, mod, demod, demapper, snk)
        self.tb.run()

        res = np.array(snk.data())
        print(data[0:10])
        print(res[0:10])
        self.assertComplexTuplesAlmostEqual(data, res, 1)
        # self.assertComplexTuplesAlmostEqual(data, res, 2)





if __name__ == '__main__':
    # gr_unittest.run(qa_advanced_receiver_sb_cc, "qa_advanced_receiver_sb_cc.xml")
    gr_unittest.run(qa_advanced_receiver_sb_cc)