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author | andreas128 <Andreas> | 2017-09-27 12:46:40 +0200 |
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committer | andreas128 <Andreas> | 2017-09-27 12:46:40 +0200 |
commit | 9434dcbc564526232667d7c547ee40bf72d631b4 (patch) | |
tree | c6587729d5bb1a7a866be5b0bf33f593fbfc4814 /dpd/src | |
parent | 1fff3ceab051fc795b0b09f451c2f8c4ffa59fcf (diff) | |
download | dabmod-9434dcbc564526232667d7c547ee40bf72d631b4.tar.gz dabmod-9434dcbc564526232667d7c547ee40bf72d631b4.tar.bz2 dabmod-9434dcbc564526232667d7c547ee40bf72d631b4.zip |
Add n_bins, n_per_bin, n_meas parameter; Cleanup import
Diffstat (limited to 'dpd/src')
-rw-r--r-- | dpd/src/Const.py | 84 |
1 files changed, 84 insertions, 0 deletions
diff --git a/dpd/src/Const.py b/dpd/src/Const.py new file mode 100644 index 0000000..2504c1e --- /dev/null +++ b/dpd/src/Const.py @@ -0,0 +1,84 @@ +# DAB Frame constants +# Sources: +# - etsi_EN_300_401_v010401p p145 +# - Measured with USRP B200 + +import numpy as np + +class Const: + def __init__(self, sample_rate, target_median, n_bins, n_per_bin, n_meas): + self.sample_rate = sample_rate + self.n_meas = n_meas + + # Time domain + self.T_F = sample_rate / 2048000 * 196608 # Transmission frame duration + self.T_NULL = sample_rate / 2048000 * 2656 # Null symbol duration + self.T_S = sample_rate / 2048000 * 2552 # Duration of OFDM symbols of indices l = 1, 2, 3,... L; + self.T_U = sample_rate / 2048000 * 2048 # Inverse of carrier spacing + self.T_C = sample_rate / 2048000 * 504 # Duration of cyclic prefix + + # Frequency Domain + # example: np.delete(fft[3328:4865], 768) + self.FFT_delete = 768 + self.FFT_delta = 1536 # Number of carrier frequencies + if sample_rate == 2048000: + self.FFT_start = 256 + self.FFT_end = 1793 + elif sample_rate == 8192000: + self.FFT_start = 3328 + self.FFT_end = 4865 + else: + raise RuntimeError("Sample Rate '{}' not supported".format( + sample_rate + )) + + # Calculate sample offset from phase rotation + # time per sample = 1 / sample_rate + # frequency per bin = 1kHz + # phase difference per sample offset = delta_t * 2 * pi * delta_freq + self.phase_offset_per_sample = 1. / sample_rate * 2 * np.pi * 1000 + + # Constants for ExtractStatistic + self.ES_plot = False + self.ES_start = 0.0 + self.ES_end = 1.0 + self.ES_n_bins = n_bins + self.ES_n_per_bin = n_per_bin + + # Constants for TX_Agc + self.TAGC_max_txgain = 89 + self.TAGC_tx_median_target = target_median + self.TAGC_tx_median_max = self.TAGC_tx_median_target*1.4 + self.TAGC_tx_median_min = self.TAGC_tx_median_target/1.4 + + + self.RAGC_min_rxgain = 25 + self.RAGC_rx_median_target = self.TAGC_tx_median_target + + # Constants for Model + self.MDL_plot = False + + # Constants for MER + self.MER_plot = False + + # Constants for Model_PM + self.MPM_tx_min = 0.1 + + # Constants for Measure_Shoulder + self.MS_enable = False + self.MS_plot = False + assert sample_rate==8192000 + meas_offset = 976 # Offset from center frequency to measure shoulder [kHz] + meas_width = 100 # Size of frequency delta to measure shoulder [kHz] + shoulder_offset_edge = np.abs(meas_offset - self.FFT_delta) + self.MS_shoulder_left_start = self.FFT_start - shoulder_offset_edge - meas_width / 2 + self.MS_shoulder_left_end = self.FFT_start - shoulder_offset_edge + meas_width / 2 + self.MS_shoulder_right_start = self.FFT_end + shoulder_offset_edge - meas_width / 2 + self.MS_shoulder_right_end = self.FFT_end + shoulder_offset_edge + meas_width / 2 + self.MS_peak_start = self.FFT_start + 100 # Ignore region near edges + self.MS_peak_end = self.FFT_end - 100 + + self.MS_FFT_size = 8192 + self.MS_averaging_size = 4 * self.MS_FFT_size + self.MS_n_averaging = 40 + self.MS_n_proc = 4 |