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C

/**
*
* \section COPYRIGHT
*
* Copyright 2013-2015 Software Radio Systems Limited
*
* \section LICENSE
*
* This file is part of the srsLTE library.
*
* srsLTE is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as
* published by the Free Software Foundation, either version 3 of
* the License, or (at your option) any later version.
*
* srsLTE 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 Affero General Public License for more details.
*
* A copy of the GNU Affero General Public License can be found in
* the LICENSE file in the top-level directory of this distribution
* and at http://www.gnu.org/licenses/.
*
*/
#include <stdio.h>
#include <stdlib.h>
#include <strings.h>
#include <string.h>
#include <complex.h>
#include <math.h>
#include "srslte/config.h"
#include "srslte/dft/dft_precoding.h"
#include "srslte/ch_estimation/chest_ul.h"
#include "srslte/utils/vector.h"
#include "srslte/utils/convolution.h"
#define NOF_REFS_SYM (q->cell.nof_prb*SRSLTE_NRE)
#define NOF_REFS_SF (NOF_REFS_SYM*2) // 2 reference symbols per subframe
/** 3GPP LTE Downlink channel estimator and equalizer.
* Estimates the channel in the resource elements transmitting references and interpolates for the rest
* of the resource grid.
*
* The equalizer uses the channel estimates to produce an estimation of the transmitted symbol.
*
* This object depends on the srslte_refsignal_t object for creating the LTE CSR signal.
*/
int srslte_chest_ul_init(srslte_chest_ul_t *q, srslte_cell_t cell)
{
int ret = SRSLTE_ERROR_INVALID_INPUTS;
if (q != NULL &&
srslte_cell_isvalid(&cell))
{
bzero(q, sizeof(srslte_chest_ul_t));
q->cell = cell;
ret = srslte_refsignal_ul_init(&q->dmrs_signal, cell);
if (ret != SRSLTE_SUCCESS) {
fprintf(stderr, "Error initializing CSR signal (%d)\n",ret);
goto clean_exit;
}
q->tmp_noise = srslte_vec_malloc(sizeof(cf_t) * NOF_REFS_SF);
if (!q->tmp_noise) {
perror("malloc");
goto clean_exit;
}
q->pilot_estimates = srslte_vec_malloc(sizeof(cf_t) * NOF_REFS_SF);
if (!q->pilot_estimates) {
perror("malloc");
goto clean_exit;
}
for (int i=0;i<4;i++) {
q->pilot_estimates_tmp[i] = srslte_vec_malloc(sizeof(cf_t) * NOF_REFS_SF);
if (!q->pilot_estimates_tmp[i]) {
perror("malloc");
goto clean_exit;
}
}
q->pilot_recv_signal = srslte_vec_malloc(sizeof(cf_t) * (NOF_REFS_SF+1));
if (!q->pilot_recv_signal) {
perror("malloc");
goto clean_exit;
}
q->pilot_known_signal = srslte_vec_malloc(sizeof(cf_t) * (NOF_REFS_SF+1));
if (!q->pilot_known_signal) {
perror("malloc");
goto clean_exit;
}
if (srslte_interp_linear_vector_init(&q->srslte_interp_linvec, NOF_REFS_SYM)) {
fprintf(stderr, "Error initializing vector interpolator\n");
goto clean_exit;
}
q->smooth_filter_len = 3;
srslte_chest_ul_set_smooth_filter3_coeff(q, 0.3333);
q->dmrs_signal_configured = false;
}
ret = SRSLTE_SUCCESS;
clean_exit:
if (ret != SRSLTE_SUCCESS) {
srslte_chest_ul_free(q);
}
return ret;
}
void srslte_chest_ul_free(srslte_chest_ul_t *q)
{
if (q->dmrs_signal_configured) {
srslte_refsignal_dmrs_pusch_pregen_free(&q->dmrs_signal, &q->dmrs_pregen);
}
srslte_refsignal_ul_free(&q->dmrs_signal);
if (q->tmp_noise) {
free(q->tmp_noise);
}
srslte_interp_linear_vector_free(&q->srslte_interp_linvec);
if (q->pilot_estimates) {
free(q->pilot_estimates);
}
for (int i=0;i<4;i++) {
if (q->pilot_estimates_tmp[i]) {
free(q->pilot_estimates_tmp[i]);
}
}
if (q->pilot_recv_signal) {
free(q->pilot_recv_signal);
}
if (q->pilot_known_signal) {
free(q->pilot_known_signal);
}
bzero(q, sizeof(srslte_chest_ul_t));
}
void srslte_chest_ul_set_cfg(srslte_chest_ul_t *q,
srslte_refsignal_dmrs_pusch_cfg_t *pusch_cfg,
srslte_pucch_cfg_t *pucch_cfg,
srslte_refsignal_srs_cfg_t *srs_cfg)
{
srslte_refsignal_ul_set_cfg(&q->dmrs_signal, pusch_cfg, pucch_cfg, srs_cfg);
srslte_refsignal_dmrs_pusch_pregen(&q->dmrs_signal, &q->dmrs_pregen);
q->dmrs_signal_configured = true;
}
/* Uses the difference between the averaged and non-averaged pilot estimates */
static float estimate_noise_pilots(srslte_chest_ul_t *q, cf_t *ce, uint32_t nrefs, uint32_t n_prb[2])
{
float power = 0;
for (int i=0;i<2;i++) {
power += srslte_chest_estimate_noise_pilots(&q->pilot_estimates[i*nrefs],
&ce[SRSLTE_REFSIGNAL_UL_L(i, q->cell.cp)*q->cell.nof_prb*SRSLTE_NRE+n_prb[i]*SRSLTE_NRE],
q->tmp_noise,
nrefs);
}
power/=2;
if (q->smooth_filter_len == 3) {
// Calibrated for filter length 3
float w=q->smooth_filter[0];
float a=7.419*w*w+0.1117*w-0.005387;
return (power/(a*0.8));
} else {
return power;
}
}
// The interpolator currently only supports same frequency allocation for each subframe
#define cesymb(i) ce[SRSLTE_RE_IDX(q->cell.nof_prb,i,n_prb[0]*SRSLTE_NRE)]
static void interpolate_pilots(srslte_chest_ul_t *q, cf_t *ce, uint32_t nrefs, uint32_t n_prb[2])
{
uint32_t L1 = SRSLTE_REFSIGNAL_UL_L(0, q->cell.cp);
uint32_t L2 = SRSLTE_REFSIGNAL_UL_L(1, q->cell.cp);
uint32_t NL = 2*SRSLTE_CP_NSYMB(q->cell.cp);
/* Interpolate in the time domain between symbols */
srslte_interp_linear_vector3(&q->srslte_interp_linvec,
&cesymb(L2), &cesymb(L1), &cesymb(L1), &cesymb(L1-1), (L2-L1), L1, false, nrefs);
srslte_interp_linear_vector3(&q->srslte_interp_linvec,
&cesymb(L1), &cesymb(L2), NULL, &cesymb(L1+1), (L2-L1), (L2-L1)-1, true, nrefs);
srslte_interp_linear_vector3(&q->srslte_interp_linvec,
&cesymb(L1), &cesymb(L2), &cesymb(L2), &cesymb(L2+1), (L2-L1), (NL-L2)-1, true, nrefs);
}
void srslte_chest_ul_set_smooth_filter(srslte_chest_ul_t *q, float *filter, uint32_t filter_len) {
if (filter_len < SRSLTE_CHEST_MAX_SMOOTH_FIL_LEN) {
if (filter) {
memcpy(q->smooth_filter, filter, filter_len*sizeof(float));
q->smooth_filter_len = filter_len;
} else {
q->smooth_filter_len = 0;
}
} else {
fprintf(stderr, "Error setting smoothing filter: filter len exceeds maximum (%d>%d)\n",
filter_len, SRSLTE_CHEST_MAX_SMOOTH_FIL_LEN);
}
}
void srslte_chest_ul_set_smooth_filter3_coeff(srslte_chest_ul_t* q, float w)
{
srslte_chest_set_smooth_filter3_coeff(q->smooth_filter, w);
q->smooth_filter_len = 3;
}
static void average_pilots(srslte_chest_ul_t *q, cf_t *input, cf_t *ce, uint32_t nrefs, uint32_t n_prb[2]) {
for (int i=0;i<2;i++) {
srslte_chest_average_pilots(&input[i*nrefs],
&ce[SRSLTE_REFSIGNAL_UL_L(i, q->cell.cp)*q->cell.nof_prb*SRSLTE_NRE+n_prb[i]*SRSLTE_NRE],
q->smooth_filter, nrefs, 1, q->smooth_filter_len);
}
}
int srslte_chest_ul_estimate(srslte_chest_ul_t *q, cf_t *input, cf_t *ce,
uint32_t nof_prb, uint32_t sf_idx, uint32_t cyclic_shift_for_dmrs, uint32_t n_prb[2])
{
if (!q->dmrs_signal_configured) {
fprintf(stderr, "Error must call srslte_chest_ul_set_cfg() before using the UL estimator\n");
return SRSLTE_ERROR;
}
if (!srslte_dft_precoding_valid_prb(nof_prb)) {
fprintf(stderr, "Error invalid nof_prb=%d\n", nof_prb);
return SRSLTE_ERROR_INVALID_INPUTS;
}
int nrefs_sym = nof_prb*SRSLTE_NRE;
int nrefs_sf = nrefs_sym*2;
/* Get references from the input signal */
srslte_refsignal_dmrs_pusch_get(&q->dmrs_signal, input, nof_prb, n_prb, q->pilot_recv_signal);
/* Use the known DMRS signal to compute Least-squares estimates */
srslte_vec_prod_conj_ccc(q->pilot_recv_signal, q->dmrs_pregen.r[cyclic_shift_for_dmrs][sf_idx][nof_prb],
q->pilot_estimates, nrefs_sf);
if (n_prb[0] != n_prb[1]) {
printf("ERROR: intra-subframe frequency hopping not supported in the estimator!!\n");
}
if (ce != NULL) {
if (q->smooth_filter_len > 0) {
average_pilots(q, q->pilot_estimates, ce, nrefs_sym, n_prb);
interpolate_pilots(q, ce, nrefs_sym, n_prb);
/* If averaging, compute noise from difference between received and averaged estimates */
q->noise_estimate = estimate_noise_pilots(q, ce, nrefs_sym, n_prb);
} else {
// Copy estimates to CE vector without averaging
for (int i=0;i<2;i++) {
memcpy(&ce[SRSLTE_REFSIGNAL_UL_L(i, q->cell.cp)*q->cell.nof_prb*SRSLTE_NRE+n_prb[i]*SRSLTE_NRE],
&q->pilot_estimates[i*nrefs_sym],
nrefs_sym*sizeof(cf_t));
}
interpolate_pilots(q, ce, nrefs_sym, n_prb);
q->noise_estimate = 0;
}
}
// Estimate received pilot power
q->pilot_power = srslte_vec_avg_power_cf(q->pilot_recv_signal, nrefs_sf);
return 0;
}
int srslte_chest_ul_estimate_pucch(srslte_chest_ul_t *q, cf_t *input, cf_t *ce,
srslte_pucch_format_t format, uint32_t n_pucch, uint32_t sf_idx,
uint8_t *pucch2_ack_bits)
{
if (!q->dmrs_signal_configured) {
fprintf(stderr, "Error must call srslte_chest_ul_set_cfg() before using the UL estimator\n");
return SRSLTE_ERROR;
}
int n_rs = srslte_refsignal_dmrs_N_rs(format, q->cell.cp);
if (!n_rs) {
fprintf(stderr, "Error computing N_rs\n");
return SRSLTE_ERROR;
}
int nrefs_sf = SRSLTE_NRE*n_rs*2;
/* Get references from the input signal */
srslte_refsignal_dmrs_pucch_get(&q->dmrs_signal, format, n_pucch, input, q->pilot_recv_signal);
/* Generate known pilots */
uint8_t pucch2_bits[2] = {0, 0};
if (format == SRSLTE_PUCCH_FORMAT_2A || format == SRSLTE_PUCCH_FORMAT_2B) {
float max = -1e9;
int i_max = 0;
int m = 0;
if (format == SRSLTE_PUCCH_FORMAT_2A) {
m = 2;
} else {
m = 4;
}
for (int i=0;i<m;i++) {
pucch2_bits[0] = i%2;
pucch2_bits[1] = i/2;
srslte_refsignal_dmrs_pucch_gen(&q->dmrs_signal, format, n_pucch, sf_idx, pucch2_bits, q->pilot_known_signal);
srslte_vec_prod_conj_ccc(q->pilot_recv_signal, q->pilot_known_signal, q->pilot_estimates_tmp[i], nrefs_sf);
float x = cabsf(srslte_vec_acc_cc(q->pilot_estimates_tmp[i], nrefs_sf));
if (x >= max) {
max = x;
i_max = i;
}
}
memcpy(q->pilot_estimates, q->pilot_estimates_tmp[i_max], nrefs_sf*sizeof(cf_t));
pucch2_ack_bits[0] = i_max%2;
pucch2_ack_bits[1] = i_max/2;
} else {
srslte_refsignal_dmrs_pucch_gen(&q->dmrs_signal, format, n_pucch, sf_idx, pucch2_bits, q->pilot_known_signal);
/* Use the known DMRS signal to compute Least-squares estimates */
srslte_vec_prod_conj_ccc(q->pilot_recv_signal, q->pilot_known_signal, q->pilot_estimates, nrefs_sf);
}
if (ce != NULL) {
/* FIXME: Currently averaging entire slot, performance good enough? */
for (int ns=0;ns<2;ns++) {
// Average all slot
for (int i=1;i<n_rs;i++) {
srslte_vec_sum_ccc(&q->pilot_estimates[ns*n_rs*SRSLTE_NRE], &q->pilot_estimates[(i+ns*n_rs)*SRSLTE_NRE],
&q->pilot_estimates[ns*n_rs*SRSLTE_NRE],
SRSLTE_NRE);
}
srslte_vec_sc_prod_ccc(&q->pilot_estimates[ns*n_rs*SRSLTE_NRE], (float) 1.0/n_rs,
&q->pilot_estimates[ns*n_rs*SRSLTE_NRE],
SRSLTE_NRE);
// Average in freq domain
srslte_chest_average_pilots(&q->pilot_estimates[ns*n_rs*SRSLTE_NRE], &q->pilot_recv_signal[ns*n_rs*SRSLTE_NRE],
q->smooth_filter, SRSLTE_NRE, 1, q->smooth_filter_len);
// Determine n_prb
uint32_t n_prb = srslte_pucch_n_prb(&q->dmrs_signal.pucch_cfg, format, n_pucch, q->cell.nof_prb, q->cell.cp, ns);
// copy estimates to slot
for (int i=0;i<SRSLTE_CP_NSYMB(q->cell.cp);i++) {
memcpy(&ce[SRSLTE_RE_IDX(q->cell.nof_prb, i+ns*SRSLTE_CP_NSYMB(q->cell.cp), n_prb*SRSLTE_NRE)],
&q->pilot_recv_signal[ns*n_rs*SRSLTE_NRE], sizeof(cf_t)*SRSLTE_NRE);
}
}
}
return 0;
}
float srslte_chest_ul_get_noise_estimate(srslte_chest_ul_t *q) {
return q->noise_estimate;
}
float srslte_chest_ul_get_snr(srslte_chest_ul_t *q) {
return q->pilot_power/srslte_chest_ul_get_noise_estimate(q);
}