adapt NPUSCH demod to 3.75 kHz

b7514c6f · Vincent Savaux · 7cb7efe9 · b7514c6f · b7514c6f · b7514c6f
Commit b7514c6f authored Dec 01, 2017 by Vincent Savaux
3 changed files
--- a/openair1/PHY/LTE_ESTIMATION/lte_ul_channel_estimation_NB_IoT.c
+++ b/openair1/PHY/LTE_ESTIMATION/lte_ul_channel_estimation_NB_IoT.c
@@ -62,6 +62,37 @@ static int16_t temp_out_ifft_1[2048*4] __attribute__((aligned(16)));

 #define SCALE 0x3FFF 

+
+void rotate_channel_single_carrier_NB_IoT(int16_t *estimated_channel,unsigned char l, uint8_t Qm)
+{
+  int16_t pi_2_re[2] = {32767 , 0}; 
+  int16_t pi_2_im[2] = {0 , 32768}; 
+  int16_t pi_4_re[2] = {32767 , 25735}; 
+  int16_t pi_4_im[2] = {0 , 25736}; 
+  int k; 
+  int16_t est_channel_re, est_channel_im;    
+
+  for (k=0;k<12;k++){
+    est_channel_re = estimated_channel[k<<1]; 
+    est_channel_im = estimated_channel[(k<<1)+1]; 
+
+    if (Qm == 1){
+      estimated_channel[k<<1] = (int16_t)(((int32_t)pi_2_re[l%2] * (int32_t)est_channel_re + 
+                          (int32_t)pi_2_im[l%2] * (int32_t)est_channel_im)>>15); 
+      estimated_channel[(k<<1)+1] = (int16_t)(((int32_t)pi_2_re[l%2] * (int32_t)est_channel_im - 
+                          (int32_t)pi_2_im[l%2] * (int32_t)est_channel_re)>>15); 
+    }
+    if(Qm == 2){
+      estimated_channel[k<<1] = (int16_t)(((int32_t)pi_4_re[l%2] * (int32_t)est_channel_re + 
+                          (int32_t)pi_4_im[l%2] * (int32_t)est_channel_im)>>15); 
+      estimated_channel[(k<<1)+1] = (int16_t)(((int32_t)pi_4_re[l%2] * (int32_t)est_channel_im - 
+                          (int32_t)pi_4_im[l%2] * (int32_t)est_channel_re)>>15); 
+    }
+
+  }
+
+} 
+
 int32_t ul_channel_estimation_NB_IoT(PHY_VARS_eNB_NB_IoT      *eNB,
                                         eNB_rxtx_proc_NB_IoT_t   *proc,
                                         uint8_t                  eNB_id,
@@ -88,8 +119,13 @@ int32_t ul_channel_estimation_NB_IoT(PHY_VARS_eNB_NB_IoT      *eNB,
  uint16_t aa; //,Msc_RS,Msc_RS_idx;
  //uint16_t * Msc_idx_ptr;
  // int k,pilot_pos1 = 3 - frame_parms->Ncp, pilot_pos2 = 10 - 2*frame_parms->Ncp; 
-  int pilot_pos1 = 3, pilot_pos2 = 10; // holds for npusch format 1, and 15 kHz subcarrier bandwidth
-  int pilot_pos_format2[6] = {2,3,4,9,10,11}; // holds for npusch format 2, and 15 kHz subcarrier bandwidth
+  int pilot_pos1_15k = 3, pilot_pos2_15k = 10; // holds for npusch format 1, and 15 kHz subcarrier bandwidth
+  int pilot_pos_format2_15k[6] = {2,3,4,9,10,11}; // holds for npusch format 2, and 15 kHz subcarrier bandwidth 
+  int pilot_pos1_3_75k = 4, pilot_pos2_3_75k = 11; // holds for npusch format 1, and 3.75 kHz subcarrier bandwidth
+  int pilot_pos_format2_3_75k[6] = {0,1,2,7,8,9}; // holds for npusch format 2, and 3.75 kHz subcarrier bandwidth 
+
+  int pilot_pos1, pilot_pos2; // holds for npusch format 1, and 15 kHz subcarrier bandwidth
+  int *pilot_pos_format2; // holds for npusch format 2, and 15 kHz subcarrier bandwidth
  int16_t *ul_ch1=NULL, *ul_ch2=NULL, *ul_ch3=NULL, *ul_ch4=NULL, *ul_ch5=NULL, *ul_ch6=NULL; 
  int16_t average_channel[24]; // average channel over a RB and 2 slots
  int32_t *p_average_channel = (int32_t *)&average_channel; 
@@ -98,8 +134,9 @@ int32_t ul_channel_estimation_NB_IoT(PHY_VARS_eNB_NB_IoT      *eNB,

  //uint8_t nb_antennas_rx = frame_parms->nb_antenna_ports_eNB;
  uint8_t nb_antennas_rx = frame_parms->nb_antennas_rx; 
-  //uint8_t cyclic_shift;
+  uint8_t subcarrier_spacing = frame_parms->subcarrier_spacing; // 15 kHz or 3.75 kHz 

+  uint8_t Qm; // needed to rotate the estimated channel
  //uint32_t alpha_ind;
  uint32_t u;//=frame_parms->npusch_config_common.ul_ReferenceSignalsNPUSCH.grouphop[Ns+(subframe<<1)];
  //uint32_t v=frame_parms->npusch_config_common.ul_ReferenceSignalsNPUSCH.seqhop[Ns+(subframe<<1)];
@@ -181,11 +218,21 @@ int32_t ul_channel_estimation_NB_IoT(PHY_VARS_eNB_NB_IoT      *eNB,
      break;
  }

+  if (subcarrier_spacing){
+    pilot_pos_format2 = pilot_pos_format2_15k; 
+    pilot_pos1 = pilot_pos1_15k; 
+    pilot_pos2 = pilot_pos2_15k;
+  }else{
+    pilot_pos_format2 = pilot_pos_format2_3_75k; 
+    pilot_pos1 = pilot_pos1_3_75k; 
+    pilot_pos2 = pilot_pos2_3_75k;
+  }
+
  ul_sc_start = get_UL_sc_start_NB_IoT(I_sc); // NB-IoT: get the used subcarrier in RB
  u=frame_parms->npusch_config_common.ul_ReferenceSignalsNPUSCH.grouphop[n_s][index_Nsc_RU]; // Vincent: may be adapted for Nsc_RU, see 36.211, Section 10.1.4.1.3
  switch (npusch_format){
  case 1: 
-      if (l == 3) { // NB-IoT: no extended CP 
+      if (l == pilot_pos1) { // NB-IoT: no extended CP 

        symbol_offset = frame_parms->N_RB_UL*12*(l+(7*(Ns&1)));

@@ -207,6 +254,12 @@ int32_t ul_channel_estimation_NB_IoT(PHY_VARS_eNB_NB_IoT      *eNB,
                        (int32_t)received_data[k<<1]*(int32_t)pilot_sig[(k<<1)+1])>>15); //imaginary part of estimated channel 
          }

+          if (Nsc_RU == 1){ // rotate the estimated channel by pi/2 or pi/4, due to mapping b2c
+            Qm       = get_Qm_ul_NB_IoT(eNB->ulsch[UE_id]->harq_process->mcs,Nsc_RU);
+            rotate_channel_single_carrier_NB_IoT(estimated_channel,l,Qm); 
+
+          }
+
          if(Nsc_RU != 1 && Nsc_RU != 12) {
            // Compensating for the phase shift introduced at the transmitter
            // In NB-IoT NPUSCH format 1, phase alpha is zero when 1 and 12 subcarriers are allocated
@@ -273,7 +326,7 @@ int32_t ul_channel_estimation_NB_IoT(PHY_VARS_eNB_NB_IoT      *eNB,
      }
    break; 
  case 2: 
-    if (l == 2 || l == 3 || l == 4){ 
+    if (l == pilot_pos_format2[0] || l == pilot_pos_format2[1] || l == pilot_pos_format2[2]){ 

      symbol_offset = frame_parms->N_RB_UL*12*(l+(7*(Ns&1))); 
      index_w = (uint8_t)l-2 + 3*(((uint8_t*)&s)[n_s&3]%3); // base index in w_format2_re and w_format2_im, see 36.211, Section 10.1.4.1.1
@@ -292,6 +345,9 @@ int32_t ul_channel_estimation_NB_IoT(PHY_VARS_eNB_NB_IoT      *eNB,
                      (int32_t)received_data[k<<1]*(int32_t)pilot_sig[(k<<1)+1])>>15); //imaginary part of estimated channel 
        }

+        // rotate the estimated channel by pi/2 or pi/4, due to mapping b2c
+        rotate_channel_single_carrier_NB_IoT(estimated_channel,l,1); // last input: Qm = 1 in format 2
+
        // Compensating for the phase shift introduced at the transmitter
        // In NB-IoT NPUSCH format 1, phase alpha is zero when 1 and 12 subcarriers are allocated
        // else (still format 1), alpha is defined in 36.211, Table 10.1.4.1.2-3
@@ -308,7 +364,7 @@ int32_t ul_channel_estimation_NB_IoT(PHY_VARS_eNB_NB_IoT      *eNB,
          (int16_t) (((int32_t) (w_format2_re[index_w]) * (int32_t) (ul_ch_estimates_im) -
                      (int32_t) (w_format2_im[index_w]) * (int32_t) (ul_ch_estimates_re))>>15); 

-        if (Ns&1 && l==4) {//we are in the second slot of the sub-frame, so do the interpolation
+        if (Ns&1 && l==pilot_pos_format2[2]) {//we are in the second slot of the sub-frame, so do the interpolation

          ul_ch1 = (int16_t *)&ul_ch_estimates[aa][frame_parms->N_RB_UL*12*pilot_pos_format2[0]];
          ul_ch2 = (int16_t *)&ul_ch_estimates[aa][frame_parms->N_RB_UL*12*pilot_pos_format2[1]]; 

--- a/openair1/PHY/LTE_TRANSPORT/ulsch_demodulation_NB_IoT.c
+++ b/openair1/PHY/LTE_TRANSPORT/ulsch_demodulation_NB_IoT.c
@@ -1358,13 +1358,13 @@ void rotate_single_carrier_NB_IoT(PHY_VARS_eNB_NB_IoT *eNB,
  if (Qm == 1){
    rxdataF_comp16[0] = (int16_t)(((int32_t)pi_2_re[symbol%2] * (int32_t)rxdataF_comp16_re + 
                        (int32_t)pi_2_im[symbol%2] * (int32_t)rxdataF_comp16_im)>>15); 
-    rxdataF_comp16[1] = (int16_t)(((int32_t)pi_2_re[symbol%1] * (int32_t)rxdataF_comp16_im - 
+    rxdataF_comp16[1] = (int16_t)(((int32_t)pi_2_re[symbol%2] * (int32_t)rxdataF_comp16_im - 
                        (int32_t)pi_2_im[symbol%2] * (int32_t)rxdataF_comp16_re)>>15); 
  }
  if(Qm == 2){
    rxdataF_comp16[0] = (int16_t)(((int32_t)pi_4_re[symbol%2] * (int32_t)rxdataF_comp16_re + 
                        (int32_t)pi_4_im[symbol%2] * (int32_t)rxdataF_comp16_im)>>15); 
-    rxdataF_comp16[1] = (int16_t)(((int32_t)pi_4_re[symbol%1] * (int32_t)rxdataF_comp16_im - 
+    rxdataF_comp16[1] = (int16_t)(((int32_t)pi_4_re[symbol%2] * (int32_t)rxdataF_comp16_im - 
                        (int32_t)pi_4_im[symbol%2] * (int32_t)rxdataF_comp16_re)>>15); 
  }

@@ -1574,9 +1574,18 @@ void rx_ulsch_NB_IoT(PHY_VARS_eNB_NB_IoT     *eNB,

  uint8_t npusch_format = 1; // NB-IoT: format 1 (data), or 2: ack. Should be defined in higher layer 
  uint8_t Nsc_RU = eNB->ulsch[UE_id]->harq_process->N_sc_RU; // Vincent: number of sc 1,3,6,12 
+  uint8_t subcarrier_spacing = frame_parms->subcarrier_spacing; // 15 kHz or 3.75 kHz 
+
+  int pilot_pos1_15k = 3, pilot_pos2_15k = 10; // holds for npusch format 1, and 15 kHz subcarrier bandwidth
+  int pilot_pos_format2_15k[2] = {2,9}; // holds for npusch format 2, and 15 kHz subcarrier bandwidth 
+  int pilot_pos1_3_75k = 4, pilot_pos2_3_75k = 11; // holds for npusch format 1, and 3.75 kHz subcarrier bandwidth
+  int pilot_pos_format2_3_75k[2] = {0,7}; // holds for npusch format 2, and 3.75 kHz subcarrier bandwidth 
+
+  int pilot_pos1, pilot_pos2; // holds for npusch format 1, and 15 kHz subcarrier bandwidth
+  int *pilot_pos_format2; // holds for npusch format 2, and 15 kHz subcarrier bandwidth

  harq_pid = subframe2harq_pid_NB_IoT(frame_parms,proc->frame_rx,subframe);
-  Qm       = get_Qm_ul_NB_IoT(ulsch[UE_id]->harq_process->mcs,ulsch[UE_id]->harq_process->N_sc_RU);
+  Qm       = get_Qm_ul_NB_IoT(ulsch[UE_id]->harq_process->mcs,Nsc_RU);

  rx_power_correction = 1;

@@ -1585,6 +1594,16 @@ void rx_ulsch_NB_IoT(PHY_VARS_eNB_NB_IoT     *eNB,
    return;
  }

+  if (subcarrier_spacing){
+    pilot_pos_format2 = pilot_pos_format2_15k; 
+    pilot_pos1 = pilot_pos1_15k; 
+    pilot_pos2 = pilot_pos2_15k;
+  }else{
+    pilot_pos_format2 = pilot_pos_format2_3_75k; 
+    pilot_pos1 = pilot_pos1_3_75k; 
+    pilot_pos2 = pilot_pos2_3_75k;
+  }
+
  for (l=0; l<frame_parms->symbols_per_tti; l++) { 

    ulsch_extract_rbs_single_NB_IoT(common_vars->rxdataF[eNB_id],
@@ -1706,13 +1725,13 @@ void rx_ulsch_NB_IoT(PHY_VARS_eNB_NB_IoT     *eNB,

  for (l=0; l<frame_parms->symbols_per_tti; l++) {
    if (npusch_format == 1){
-      if (l==3 || l==10)   // skip pilots
+      if (l==pilot_pos1 || l==pilot_pos2)   // skip pilots
      {
        l++;
      }
    }
    if (npusch_format == 2){
-      if (l == 2 || l == 9)   // skip 3 pilots
+      if (l == pilot_pos_format2[0] || l == pilot_pos_format2[1])   // skip 3 pilots
      {
        l = l + 3;
      }
@@ -1849,7 +1868,7 @@ void rx_ulsch_NB_IoT(PHY_VARS_eNB_NB_IoT     *eNB,
    //   l++;
    // } 
    if (npusch_format == 1){
-      if (l==3 || l==10)   // skip pilots
+      if (l==pilot_pos1 || l==pilot_pos2)   // skip pilots
      {
        l++;
      }
@@ -1868,7 +1887,7 @@ void rx_ulsch_NB_IoT(PHY_VARS_eNB_NB_IoT     *eNB,

    }
    if (npusch_format == 2){
-      if (l == 2 || l == 9)   // skip 3 pilots
+      if (l == pilot_pos_format2[0] || l == pilot_pos_format2[1])   // skip 3 pilots
      {
        l = l + 3;
      }

--- a/openair1/PHY/impl_defs_lte_NB_IoT.h
+++ b/openair1/PHY/impl_defs_lte_NB_IoT.h
@@ -509,6 +509,11 @@ typedef struct {
   */
  uint16_t eutra_NumCRS_ports;

+  /* Subcarrier bandwidth
+  0 -> 3.75 kHz
+  1 -> 15 kHz
+  */
+  uint8_t subcarrier_spacing; 

 } NB_IoT_DL_FRAME_PARMS;