2015-06-15 23:14:37 +02:00
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// Part of dump1090, a Mode S message decoder for RTLSDR devices.
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//
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// convert.c: support for various IQ -> magnitude conversions
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//
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// Copyright (c) 2015 Oliver Jowett <oliver@mutability.co.uk>
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//
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// This file is free software: you may copy, redistribute and/or modify it
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// under the terms of the GNU General Public License as published by the
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// Free Software Foundation, either version 2 of the License, or (at your
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// option) any later version.
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//
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// This file is distributed in the hope that it will be useful, but
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// WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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// General Public License for more details.
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//
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// You should have received a copy of the GNU General Public License
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// along with this program. If not, see <http://www.gnu.org/licenses/>.
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#include "dump1090.h"
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struct converter_state {
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float dc_a;
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float dc_b;
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float z1_I;
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float z1_Q;
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};
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2016-05-31 12:54:34 +02:00
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static void convert_uc8_nodc(void *iq_data,
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uint16_t *mag_data,
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unsigned nsamples,
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struct converter_state *state,
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double *out_power)
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2015-06-15 23:14:37 +02:00
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{
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uint16_t *in = iq_data;
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unsigned i;
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uint64_t power = 0;
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2015-06-16 11:13:25 +02:00
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uint16_t mag;
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2015-06-15 23:14:37 +02:00
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MODES_NOTUSED(state);
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// unroll this a bit
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for (i = 0; i < (nsamples>>3); ++i) {
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mag = Modes.maglut[*in++];
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*mag_data++ = mag;
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2015-06-16 11:13:25 +02:00
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power += (uint32_t)mag * (uint32_t)mag;
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2015-06-15 23:14:37 +02:00
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mag = Modes.maglut[*in++];
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*mag_data++ = mag;
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2015-06-16 11:13:25 +02:00
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power += (uint32_t)mag * (uint32_t)mag;
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2015-06-15 23:14:37 +02:00
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mag = Modes.maglut[*in++];
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*mag_data++ = mag;
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2015-06-16 11:13:25 +02:00
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power += (uint32_t)mag * (uint32_t)mag;
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2015-06-15 23:14:37 +02:00
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mag = Modes.maglut[*in++];
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*mag_data++ = mag;
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2015-06-16 11:13:25 +02:00
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power += (uint32_t)mag * (uint32_t)mag;
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2015-06-15 23:14:37 +02:00
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mag = Modes.maglut[*in++];
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*mag_data++ = mag;
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2015-06-16 11:13:25 +02:00
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power += (uint32_t)mag * (uint32_t)mag;
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2015-06-15 23:14:37 +02:00
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mag = Modes.maglut[*in++];
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*mag_data++ = mag;
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2015-06-16 11:13:25 +02:00
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power += (uint32_t)mag * (uint32_t)mag;
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2015-06-15 23:14:37 +02:00
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mag = Modes.maglut[*in++];
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*mag_data++ = mag;
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2015-06-16 11:13:25 +02:00
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power += (uint32_t)mag * (uint32_t)mag;
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2015-06-15 23:14:37 +02:00
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mag = Modes.maglut[*in++];
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*mag_data++ = mag;
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2015-06-16 11:13:25 +02:00
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power += (uint32_t)mag * (uint32_t)mag;
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2015-06-15 23:14:37 +02:00
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}
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for (i = 0; i < (nsamples&7); ++i) {
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mag = Modes.maglut[*in++];
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*mag_data++ = mag;
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2015-06-16 11:13:25 +02:00
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power += (uint32_t)mag * (uint32_t)mag;
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2015-06-15 23:14:37 +02:00
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}
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2015-06-16 11:13:25 +02:00
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if (out_power) {
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*out_power = power / 65535.0 / 65535.0;
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}
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2015-06-15 23:14:37 +02:00
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}
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static void convert_uc8_generic(void *iq_data,
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uint16_t *mag_data,
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unsigned nsamples,
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struct converter_state *state,
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double *out_power)
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{
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uint8_t *in = iq_data;
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float power = 0.0;
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float z1_I = state->z1_I;
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float z1_Q = state->z1_Q;
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const float dc_a = state->dc_a;
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const float dc_b = state->dc_b;
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unsigned i;
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uint8_t I, Q;
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float fI, fQ, magsq;
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for (i = 0; i < nsamples; ++i) {
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I = *in++;
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Q = *in++;
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fI = (I - 127.5) / 127.5;
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fQ = (Q - 127.5) / 127.5;
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// DC block
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z1_I = fI * dc_a + z1_I * dc_b;
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z1_Q = fQ * dc_a + z1_Q * dc_b;
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fI -= z1_I;
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fQ -= z1_Q;
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magsq = fI * fI + fQ * fQ;
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if (magsq > 1)
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magsq = 1;
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power += magsq;
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*mag_data++ = (uint16_t)(sqrtf(magsq) * 65535.0 + 0.5);
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}
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state->z1_I = z1_I;
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state->z1_Q = z1_Q;
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if (out_power)
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*out_power = power;
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}
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static void convert_sc16_generic(void *iq_data,
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uint16_t *mag_data,
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unsigned nsamples,
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struct converter_state *state,
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double *out_power)
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{
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uint16_t *in = iq_data;
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float power = 0.0;
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float z1_I = state->z1_I;
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float z1_Q = state->z1_Q;
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const float dc_a = state->dc_a;
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const float dc_b = state->dc_b;
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unsigned i;
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int16_t I, Q;
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float fI, fQ, magsq;
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for (i = 0; i < nsamples; ++i) {
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I = (int16_t)le16toh(*in++);
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Q = (int16_t)le16toh(*in++);
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fI = I / 32768.0;
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fQ = Q / 32768.0;
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// DC block
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z1_I = fI * dc_a + z1_I * dc_b;
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z1_Q = fQ * dc_a + z1_Q * dc_b;
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fI -= z1_I;
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fQ -= z1_Q;
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magsq = fI * fI + fQ * fQ;
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if (magsq > 1)
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magsq = 1;
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power += magsq;
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*mag_data++ = (uint16_t)(sqrtf(magsq) * 65535.0 + 0.5);
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}
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state->z1_I = z1_I;
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state->z1_Q = z1_Q;
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if (out_power)
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*out_power = power;
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}
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static void convert_sc16q11_generic(void *iq_data,
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uint16_t *mag_data,
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unsigned nsamples,
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struct converter_state *state,
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double *out_power)
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{
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uint16_t *in = iq_data;
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float power = 0.0;
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float z1_I = state->z1_I;
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float z1_Q = state->z1_Q;
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const float dc_a = state->dc_a;
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const float dc_b = state->dc_b;
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unsigned i;
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int16_t I, Q;
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float fI, fQ, magsq;
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for (i = 0; i < nsamples; ++i) {
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I = (int16_t)le16toh(*in++);
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Q = (int16_t)le16toh(*in++);
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fI = I / 2048.0;
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fQ = Q / 2048.0;
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// DC block
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z1_I = fI * dc_a + z1_I * dc_b;
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z1_Q = fQ * dc_a + z1_Q * dc_b;
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fI -= z1_I;
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fQ -= z1_Q;
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magsq = fI * fI + fQ * fQ;
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if (magsq > 1)
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magsq = 1;
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power += magsq;
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*mag_data++ = (uint16_t)(sqrtf(magsq) * 65535.0 + 0.5);
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}
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state->z1_I = z1_I;
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state->z1_Q = z1_Q;
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if (out_power)
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*out_power = power;
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}
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static struct {
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input_format_t format;
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int can_filter_dc;
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iq_convert_fn fn;
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const char *description;
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} converters_table[] = {
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// In order of preference
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{ INPUT_UC8, 0, convert_uc8_nodc, "UC8, integer/table path" },
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{ INPUT_UC8, 1, convert_uc8_generic, "UC8, float path" },
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{ INPUT_SC16, 1, convert_sc16_generic, "SC16, float path" },
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{ INPUT_SC16Q11, 1, convert_sc16q11_generic, "SC16Q11, float path" },
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{ 0, 0, NULL, NULL }
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2015-06-15 23:14:37 +02:00
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};
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iq_convert_fn init_converter(input_format_t format,
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double sample_rate,
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int filter_dc,
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struct converter_state **out_state)
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{
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int i;
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for (i = 0; converters_table[i].fn; ++i) {
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if (converters_table[i].format != format)
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continue;
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if (filter_dc && !converters_table[i].can_filter_dc)
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continue;
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break;
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}
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if (!converters_table[i].fn) {
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2016-05-31 12:54:34 +02:00
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fprintf(stderr, "no suitable converter for format=%d dc=%d\n",
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format, filter_dc);
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2015-06-15 23:14:37 +02:00
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return NULL;
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}
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fprintf(stderr, "Using sample converter: %s\n", converters_table[i].description);
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*out_state = malloc(sizeof(struct converter_state));
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if (! *out_state) {
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fprintf(stderr, "can't allocate converter state\n");
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return NULL;
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}
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(*out_state)->z1_I = 0;
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(*out_state)->z1_Q = 0;
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if (filter_dc) {
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// init DC block @ 1Hz
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(*out_state)->dc_b = exp(-2.0 * M_PI * 1.0 / sample_rate);
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(*out_state)->dc_a = 1.0 - (*out_state)->dc_b;
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} else {
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// if the converter does filtering, make sure it has no effect
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(*out_state)->dc_b = 1.0;
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(*out_state)->dc_a = 0.0;
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}
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return converters_table[i].fn;
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}
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void cleanup_converter(struct converter_state *state)
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{
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free(state);
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}
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