/** * * \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 #include #include #include #include #include #include "srslte/config.h" #include "srslte/ch_estimation/chest_dl.h" #include "srslte/utils/vector.h" #include "srslte/utils/convolution.h" //#define DEFAULT_FILTER_LEN 3 #ifdef DEFAULT_FILTER_LEN static void set_default_filter(srslte_chest_dl_t *q, int filter_len) { float fil[SRSLTE_CHEST_DL_MAX_SMOOTH_FIL_LEN]; for (int i=0;icsr_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) * SRSLTE_REFSIGNAL_MAX_NUM_SF(cell.nof_prb)); if (!q->tmp_noise) { perror("malloc"); goto clean_exit; } q->pilot_estimates = srslte_vec_malloc(sizeof(cf_t) * SRSLTE_REFSIGNAL_MAX_NUM_SF(cell.nof_prb)); if (!q->pilot_estimates) { perror("malloc"); goto clean_exit; } q->pilot_estimates_average = srslte_vec_malloc(sizeof(cf_t) * SRSLTE_REFSIGNAL_MAX_NUM_SF(cell.nof_prb)); if (!q->pilot_estimates_average) { perror("malloc"); goto clean_exit; } q->pilot_recv_signal = srslte_vec_malloc(sizeof(cf_t) * SRSLTE_REFSIGNAL_MAX_NUM_SF(cell.nof_prb)); if (!q->pilot_recv_signal) { perror("malloc"); goto clean_exit; } if (srslte_interp_linear_vector_init(&q->srslte_interp_linvec, SRSLTE_NRE*cell.nof_prb)) { fprintf(stderr, "Error initializing vector interpolator\n"); goto clean_exit; } if (srslte_interp_linear_init(&q->srslte_interp_lin, 2*cell.nof_prb, SRSLTE_NRE/2)) { fprintf(stderr, "Error initializing interpolator\n"); goto clean_exit; } if (srslte_pss_generate(q->pss_signal, cell.id%3)) { fprintf(stderr, "Error initializing PSS signal for noise estimation\n"); goto clean_exit; } q->noise_alg = SRSLTE_NOISE_ALG_REFS; q->smooth_filter_len = 3; srslte_chest_dl_set_smooth_filter3_coeff(q, 0.1); q->cell = cell; } ret = SRSLTE_SUCCESS; clean_exit: if (ret != SRSLTE_SUCCESS) { srslte_chest_dl_free(q); } return ret; } void srslte_chest_dl_free(srslte_chest_dl_t *q) { srslte_refsignal_cs_free(&q->csr_signal); if (q->tmp_noise) { free(q->tmp_noise); } srslte_interp_linear_vector_free(&q->srslte_interp_linvec); srslte_interp_linear_free(&q->srslte_interp_lin); if (q->pilot_estimates) { free(q->pilot_estimates); } if (q->pilot_estimates_average) { free(q->pilot_estimates_average); } if (q->pilot_recv_signal) { free(q->pilot_recv_signal); } bzero(q, sizeof(srslte_chest_dl_t)); } /* Uses the difference between the averaged and non-averaged pilot estimates */ static float estimate_noise_pilots(srslte_chest_dl_t *q, uint32_t port_id) { int nref=SRSLTE_REFSIGNAL_NUM_SF(q->cell.nof_prb, port_id); /* Substract noisy pilot estimates */ srslte_vec_sub_ccc(q->pilot_estimates_average, q->pilot_estimates, q->tmp_noise, nref); #ifdef FREQ_SEL_SNR /* Compute frequency-selective SNR */ srslte_vec_abs_square_cf(q->tmp_noise, q->snr_vector, nref); srslte_vec_abs_square_cf(q->pilot_estimates, q->pilot_power, nref); srslte_vec_div_fff(q->pilot_power, q->snr_vector, q->snr_vector, nref); srslte_vec_fprint_f(stdout, q->snr_vector, nref); #endif /* Compute average power. Normalized for filter len 3 using matlab */ float norm = 1; if (q->smooth_filter_len == 3) { float a = q->smooth_filter[0]; float norm3 = 6.143*a*a+0.04859*a-0.002774; norm /= norm3; } float power = norm*q->cell.nof_ports*srslte_vec_avg_power_cf(q->tmp_noise, nref); return power; } static float estimate_noise_pss(srslte_chest_dl_t *q, cf_t *input, cf_t *ce) { /* Get PSS from received signal */ srslte_pss_get_slot(input, q->tmp_pss, q->cell.nof_prb, q->cell.cp); /* Get channel estimates for PSS position */ srslte_pss_get_slot(ce, q->tmp_pss_noisy, q->cell.nof_prb, q->cell.cp); /* Multiply known PSS by channel estimates */ srslte_vec_prod_ccc(q->tmp_pss_noisy, q->pss_signal, q->tmp_pss_noisy, SRSLTE_PSS_LEN); /* Substract received signal */ srslte_vec_sub_ccc(q->tmp_pss_noisy, q->tmp_pss, q->tmp_pss_noisy, SRSLTE_PSS_LEN); /* Compute average power */ float power = q->cell.nof_ports*srslte_vec_avg_power_cf(q->tmp_pss_noisy, SRSLTE_PSS_LEN)/sqrt(2); return power; } /* Uses the 5 empty transmitted SC before and after the SSS and PSS sequences for noise estimation */ static float estimate_noise_empty_sc(srslte_chest_dl_t *q, cf_t *input) { int k_sss = (SRSLTE_CP_NSYMB(q->cell.cp) - 2) * q->cell.nof_prb * SRSLTE_NRE + q->cell.nof_prb * SRSLTE_NRE / 2 - 31; float noise_power = 0; noise_power += srslte_vec_avg_power_cf(&input[k_sss-5], 5); // 5 empty SC before SSS noise_power += srslte_vec_avg_power_cf(&input[k_sss+62], 5); // 5 empty SC after SSS int k_pss = (SRSLTE_CP_NSYMB(q->cell.cp) - 1) * q->cell.nof_prb * SRSLTE_NRE + q->cell.nof_prb * SRSLTE_NRE / 2 - 31; noise_power += srslte_vec_avg_power_cf(&input[k_pss-5], 5); // 5 empty SC before PSS noise_power += srslte_vec_avg_power_cf(&input[k_pss+62], 5); // 5 empty SC after PSS return noise_power; } #define cesymb(i) ce[SRSLTE_RE_IDX(q->cell.nof_prb,i,0)] static void interpolate_pilots(srslte_chest_dl_t *q, cf_t *pilot_estimates, cf_t *ce, uint32_t port_id) { /* interpolate the symbols with references in the freq domain */ uint32_t l; uint32_t nsymbols = srslte_refsignal_cs_nof_symbols(port_id); /* Interpolate in the frequency domain */ for (l=0;lcell, l, port_id, 0); srslte_interp_linear_offset(&q->srslte_interp_lin, &pilot_estimates[2*q->cell.nof_prb*l], &ce[srslte_refsignal_cs_nsymbol(l,q->cell.cp, port_id) * q->cell.nof_prb * SRSLTE_NRE], fidx_offset, SRSLTE_NRE/2-fidx_offset); } /* Now interpolate in the time domain between symbols */ if (SRSLTE_CP_ISNORM(q->cell.cp)) { if (nsymbols == 4) { srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(0), &cesymb(4), &cesymb(1), 3); srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(4), &cesymb(7), &cesymb(5), 2); srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(7), &cesymb(11), &cesymb(8), 3); srslte_interp_linear_vector2(&q->srslte_interp_linvec, &cesymb(7), &cesymb(11), &cesymb(11), &cesymb(12), 2); } else { srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(8), &cesymb(1), &cesymb(0), 1); srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(1), &cesymb(8), &cesymb(2), 6); srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(1), &cesymb(8), &cesymb(9), 5); } } else { if (nsymbols == 4) { srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(0), &cesymb(3), &cesymb(1), 2); srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(3), &cesymb(6), &cesymb(4), 2); srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(6), &cesymb(9), &cesymb(7), 2); srslte_interp_linear_vector2(&q->srslte_interp_linvec, &cesymb(6), &cesymb(9), &cesymb(9), &cesymb(10), 2); } else { srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(7), &cesymb(1), &cesymb(0), 1); srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(1), &cesymb(7), &cesymb(2), 5); srslte_interp_linear_vector(&q->srslte_interp_linvec, &cesymb(1), &cesymb(7), &cesymb(8), 4); } } } void srslte_chest_dl_set_smooth_filter(srslte_chest_dl_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_dl_set_noise_alg(srslte_chest_dl_t *q, srslte_chest_dl_noise_alg_t noise_estimation_alg) { q->noise_alg = noise_estimation_alg; } void srslte_chest_dl_set_smooth_filter3_coeff(srslte_chest_dl_t* q, float w) { q->smooth_filter_len = 3; q->smooth_filter[0] = w; q->smooth_filter[2] = w; q->smooth_filter[1] = 1-2*w; } static void average_pilots(srslte_chest_dl_t *q, cf_t *input, cf_t *output, uint32_t port_id) { uint32_t nsymbols = srslte_refsignal_cs_nof_symbols(port_id); uint32_t nref = 2*q->cell.nof_prb; for (int l=0;lsmooth_filter, &output[l*nref], nref, q->smooth_filter_len); } } float srslte_chest_dl_rssi(srslte_chest_dl_t *q, cf_t *input, uint32_t port_id) { uint32_t l; float rssi = 0; uint32_t nsymbols = srslte_refsignal_cs_nof_symbols(port_id); for (l=0;lcell.cp, port_id) * q->cell.nof_prb * SRSLTE_NRE]; rssi += srslte_vec_dot_prod_conj_ccc(tmp, tmp, q->cell.nof_prb * SRSLTE_NRE); } return rssi/nsymbols; } int srslte_chest_dl_estimate_port(srslte_chest_dl_t *q, cf_t *input, cf_t *ce, uint32_t sf_idx, uint32_t port_id) { /* Get references from the input signal */ srslte_refsignal_cs_get_sf(q->cell, port_id, input, q->pilot_recv_signal); /* Use the known CSR signal to compute Least-squares estimates */ srslte_vec_prod_conj_ccc(q->pilot_recv_signal, q->csr_signal.pilots[port_id/2][sf_idx], q->pilot_estimates, SRSLTE_REFSIGNAL_NUM_SF(q->cell.nof_prb, port_id)); if (ce != NULL) { /* Smooth estimates (if applicable) and interpolate */ if (q->smooth_filter_len == 0 || (q->smooth_filter_len == 3 && q->smooth_filter[0] == 0)) { interpolate_pilots(q, q->pilot_estimates, ce, port_id); } else { average_pilots(q, q->pilot_estimates, q->pilot_estimates_average, port_id); interpolate_pilots(q, q->pilot_estimates_average, ce, port_id); } /* Estimate noise power */ if (q->noise_alg == SRSLTE_NOISE_ALG_REFS && q->smooth_filter_len > 0) { q->noise_estimate[port_id] = estimate_noise_pilots(q, port_id); } else if (q->noise_alg == SRSLTE_NOISE_ALG_PSS) { if (sf_idx == 0 || sf_idx == 5) { q->noise_estimate[port_id] = estimate_noise_pss(q, input, ce); } } else { if (sf_idx == 0 || sf_idx == 5) { q->noise_estimate[port_id] = estimate_noise_empty_sc(q, input); } } } /* Compute RSRP for the channel estimates in this port */ q->rsrp[port_id] = srslte_vec_avg_power_cf(q->pilot_recv_signal, SRSLTE_REFSIGNAL_NUM_SF(q->cell.nof_prb, port_id)); if (port_id == 0) { /* compute rssi only for port 0 */ q->rssi[port_id] = srslte_chest_dl_rssi(q, input, port_id); } return 0; } int srslte_chest_dl_estimate(srslte_chest_dl_t *q, cf_t *input, cf_t *ce[SRSLTE_MAX_PORTS], uint32_t sf_idx) { uint32_t port_id; for (port_id=0;port_idcell.nof_ports;port_id++) { srslte_chest_dl_estimate_port(q, input, ce[port_id], sf_idx, port_id); } return SRSLTE_SUCCESS; } float srslte_chest_dl_get_noise_estimate(srslte_chest_dl_t *q) { return srslte_vec_acc_ff(q->noise_estimate, q->cell.nof_ports)/q->cell.nof_ports; } float srslte_chest_dl_get_snr(srslte_chest_dl_t *q) { #ifdef FREQ_SEL_SNR int nref=SRSLTE_REFSIGNAL_NUM_SF(q->cell.nof_prb, 0); return srslte_vec_acc_ff(q->snr_vector, nref)/nref; #else return srslte_chest_dl_get_rsrp(q)/srslte_chest_dl_get_noise_estimate(q); #endif } float srslte_chest_dl_get_rssi(srslte_chest_dl_t *q) { return 4*q->rssi[0]/q->cell.nof_prb/SRSLTE_NRE; } /* q->rssi[0] is the average power in all RE in all symbol containing references for port 0 . q->rssi[0]/q->cell.nof_prb is the average power per PRB * q->rsrp[0] is the average power of RE containing references only (for port 0). */ float srslte_chest_dl_get_rsrq(srslte_chest_dl_t *q) { return q->cell.nof_prb*q->rsrp[0] / q->rssi[0]; } float srslte_chest_dl_get_rsrp(srslte_chest_dl_t *q) { // return sum of power received from all tx ports return srslte_vec_acc_ff(q->rsrp, q->cell.nof_ports); }