Пример #1
0
    def xtest_005_interp_random_vals(self):
        MAX_TAPS = 9
        MAX_INTERP = 7
        INPUT_LEN = 9

        random.seed(0)    # we want reproducibility

        for ntaps in xrange(1, MAX_TAPS + 1):
            for interp in xrange(1, MAX_INTERP+1):
                for ilen in xrange(ntaps, ntaps + INPUT_LEN):
                    src_data = random_floats(ilen)
                    taps = random_floats(ntaps)
                    expected_result = reference_interp_filter(src_data, interp, taps)

                    tb = gr.top_block()
                    src = gr.vector_source_f(src_data)
                    op = filter.rational_resampler_base_fff(interp, 1, taps)
                    dst = gr.vector_sink_f()
                    tb.connect(src, op, dst)
                    tb.run()
                    tb = None
                    result_data = dst.data()
                    L1 = len(result_data)
                    L2 = len(expected_result)
                    L = min(L1, L2)
                    #if True or abs(L1-L2) > 1:
                    if False:
                        sys.stderr.write('delta = %2d: ntaps = %d interp = %d ilen = %d\n' % (L2 - L1, ntaps, interp, ilen))
                        #sys.stderr.write('  len(result_data) = %d  len(expected_result) = %d\n' %
                        #                 (len(result_data), len(expected_result)))
                    #self.assertEqual(expected_result[0:L], result_data[0:L])
                    # FIXME check first ntaps+1 answers
                    self.assertEqual(expected_result[ntaps+1:L], result_data[ntaps+1:L])
Пример #2
0
    def xtest_004_decim_random_vals(self):
        MAX_TAPS = 9
        MAX_DECIM = 7
        OUTPUT_LEN = 9

        random.seed(0)    # we want reproducibility

        for ntaps in xrange(1, MAX_TAPS + 1):
            for decim in xrange(1, MAX_DECIM+1):
                for ilen in xrange(ntaps + decim, ntaps + OUTPUT_LEN*decim):
                    src_data = random_floats(ilen)
                    taps = random_floats(ntaps)
                    expected_result = reference_dec_filter(src_data, decim, taps)

                    tb = gr.top_block()
                    src = gr.vector_source_f(src_data)
                    op = filter.rational_resampler_base_fff(1, decim, taps)
                    dst = gr.vector_sink_f()
                    tb.connect(src, op, dst)
                    tb.run()
                    tb = None
                    result_data = dst.data()

                    L1 = len(result_data)
                    L2 = len(expected_result)
                    L = min(L1, L2)
                    if False:
                        sys.stderr.write('delta = %2d: ntaps = %d decim = %d ilen = %d\n' % (L2 - L1, ntaps, decim, ilen))
                        sys.stderr.write('  len(result_data) = %d  len(expected_result) = %d\n' %
                                         (len(result_data), len(expected_result)))
                    self.assertEqual(expected_result[0:L], result_data[0:L])
Пример #3
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    def test_000_1_to_1(self):
        taps = (-4, 5)
        src_data = (234,  -4,  23,  -56,  45,    98,  -23,  -7)
        xr = (1186, -112, 339, -460, -167, 582)
        expected_result = tuple([float(x) for x in xr])

	tb = gr.top_block()
        src = gr.vector_source_f(src_data)
        op = filter.rational_resampler_base_fff(1, 1, taps)
        dst = gr.vector_sink_f()
        tb.connect(src, op)
        tb.connect(op, dst)
        tb.run()
        result_data = dst.data()
        self.assertEqual(expected_result, result_data)
Пример #4
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    def test_001_interp(self):
        taps = [1, 10, 100, 1000, 10000]
        src_data = (0, 2, 3, 5, 7, 11, 13, 17)
        interpolation = 3
        xr = (0, 2, 20, 200, 2003, 20030, 300, 3005, 30050, 500, 5007, 50070,
              700, 7011, 70110, 1100, 11013, 110130, 1300, 13017, 130170,
              1700.0, 17000.0, 170000.0)
        expected_result = tuple([float(x) for x in xr])

        tb = gr.top_block()
        src = blocks.vector_source_f(src_data)
        op = filter.rational_resampler_base_fff(interpolation, 1, taps)
        dst = blocks.vector_sink_f()
        tb.connect(src, op)
        tb.connect(op, dst)
        tb.run()
        result_data = dst.data()
        self.assertEqual(expected_result, result_data)
Пример #5
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    def test_002_interp(self):
        taps = random_floats(31)
        src_data = random_floats(10000)
        interpolation = 3

        expected_result = reference_interp_filter(src_data, interpolation, taps)

	tb = gr.top_block()
        src = gr.vector_source_f(src_data)
        op = filter.rational_resampler_base_fff(interpolation, 1, taps)
        dst = gr.vector_sink_f()
        tb.connect(src, op)
        tb.connect(op, dst)
        tb.run()
        result_data = dst.data()

        N = 1000
        offset = len(taps)-1
        self.assertEqual(expected_result[offset:offset+N], result_data[0:N])
Пример #6
0
    def xtest_003_interp(self):
        taps = random_floats(9)
        src_data = random_floats(10000)
        decimation = 3

        expected_result = reference_dec_filter(src_data, decimation, taps)

	tb = gr.top_block()
        src = gr.vector_source_f(src_data)
        op = filter.rational_resampler_base_fff(1, decimation, taps)
        dst = gr.vector_sink_f()
        tb.connect(src, op)
        tb.connect(op, dst)
        tb.run()
        result_data = dst.data()

        N = 10
        offset = 10#len(taps)-1
        print expected_result[100+offset:100+offset+N]
        print result_data[100:100+N]
Пример #7
0
    def test_006_interp_decim(self):
        taps = random_floats(31)
        src_data = random_floats(10000)
        interp = 3
        decimation = 2

        expected_result = reference_interp_dec_filter(src_data, interp, decimation, taps)

        tb = gr.top_block()
        src = blocks.vector_source_f(src_data)
        op = filter.rational_resampler_base_fff(interp, decimation, taps)
        dst = blocks.vector_sink_f()
        tb.connect(src, op)
        tb.connect(op, dst)
        tb.run()
        result_data = dst.data()

        N = 1000
        offset = len(taps) / 2
        self.assertFloatTuplesAlmostEqual(expected_result[offset : offset + N], result_data[0:N], 5)
Пример #8
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    def test_001_interp(self):
        taps = [1, 10, 100, 1000, 10000]
        src_data = (0, 2, 3, 5, 7, 11, 13, 17)
        interpolation = 3
        xr = (
            0,
            2,
            20,
            200,
            2003,
            20030,
            300,
            3005,
            30050,
            500,
            5007,
            50070,
            700,
            7011,
            70110,
            1100,
            11013,
            110130,
            1300,
            13017,
            130170,
            1700.0,
            17000.0,
            170000.0,
        )
        expected_result = tuple([float(x) for x in xr])

        tb = gr.top_block()
        src = blocks.vector_source_f(src_data)
        op = filter.rational_resampler_base_fff(interpolation, 1, taps)
        dst = blocks.vector_sink_f()
        tb.connect(src, op)
        tb.connect(op, dst)
        tb.run()
        result_data = dst.data()
        self.assertEqual(expected_result, result_data)
Пример #9
0
    def test_006_interp_decim(self):
        taps = random_floats(31)
        src_data = random_floats(10000)
        interp = 3
        decimation = 2

        expected_result = reference_interp_dec_filter(src_data, interp,
                                                      decimation, taps)

        tb = gr.top_block()
        src = blocks.vector_source_f(src_data)
        op = filter.rational_resampler_base_fff(interp, decimation, taps)
        dst = blocks.vector_sink_f()
        tb.connect(src, op)
        tb.connect(op, dst)
        tb.run()
        result_data = dst.data()

        N = 1000
        offset = len(taps) / 2
        self.assertFloatTuplesAlmostEqual(expected_result[offset:offset + N],
                                          result_data[0:N], 5)