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Commit bab0bf57 authored by Matthieu Kanj's avatar Matthieu Kanj
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adding new file pusch_pc_NB_IoT.c

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openair1/SCHED/pusch_pc_NB_IoT.c 0 → 100644
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/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.0 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
/*! \file pusch_pc.c
* \brief Implementation of UE PUSCH Power Control procedures from 36.213 LTE specifications (Section
* \author R. Knopp
* \date 2011
* \version 0.1
* \company Eurecom
* \email: knopp@eurecom.fr
* \note
* \warning
*/
#include "defs_nb_iot.h"
#include "PHY/defs_nb_iot.h"
#include "PHY/LTE_TRANSPORT/proto_nb_iot.h"
#include "PHY/extern_NB_IoT.h"
// This is the formula from Section 5.1.1.1 in 36.213 100*10*log10((2^(MPR*Ks)-1)), where MPR is in the range [0,6] and Ks=1.25
int16_t hundred_times_delta_TF_NB_IoT[100] = {-32768,-1268,-956,-768,-631,-523,-431,-352,-282,-219,-161,-107,-57,-9,36,79,120,159,197,234,269,304,337,370,402,434,465,495,525,555,583,612,640,668,696,723,750,777,803,829,856,881,907,933,958,983,1008,1033,1058,1083,1108,1132,1157,1181,1205,1229,1254,1278,1302,1325,1349,1373,1397,1421,1444,1468,1491,1515,1538,1562,1585,1609,1632,1655,1679,1702,1725,1748,1772,1795,1818,1841,1864,1887,1910,1933,1956,1980,2003,2026,2049,2072,2095,2118,2141,2164,2186,2209,2232,2255};
uint16_t hundred_times_log10_NPRB_NB_IoT[100] = {0,301,477,602,698,778,845,903,954,1000,1041,1079,1113,1146,1176,1204,1230,1255,1278,1301,1322,1342,1361,1380,1397,1414,1431,1447,1462,1477,1491,1505,1518,1531,1544,1556,1568,1579,1591,1602,1612,1623,1633,1643,1653,1662,1672,1681,1690,1698,1707,1716,1724,1732,1740,1748,1755,1763,1770,1778,1785,1792,1799,1806,1812,1819,1826,1832,1838,1845,1851,1857,1863,1869,1875,1880,1886,1892,1897,1903,1908,1913,1919,1924,1929,1934,1939,1944,1949,1954,1959,1963,1968,1973,1977,1982,1986,1991,1995,2000};
int16_t get_hundred_times_delta_IF_eNB_NB_IoT(PHY_VARS_eNB_NB_IoT *eNB,uint8_t UE_id,uint8_t harq_pid, uint8_t bw_factor)
{
uint32_t Nre,sumKr,MPR_x100,Kr,r;
uint16_t beta_offset_pusch;
DevAssert( UE_id < NUMBER_OF_UE_MAX_NB_IoT+1 );
DevAssert( harq_pid < 8 );
Nre = eNB->ulsch[UE_id]->harq_processes[harq_pid]->Nsymb_initial *
eNB->ulsch[UE_id]->harq_processes[harq_pid]->nb_rb*12;
sumKr = 0;
for (r=0; r<eNB->ulsch[UE_id]->harq_processes[harq_pid]->C; r++) {
if (r<eNB->ulsch[UE_id]->harq_processes[harq_pid]->Cminus)
Kr = eNB->ulsch[UE_id]->harq_processes[harq_pid]->Kminus;
else
Kr = eNB->ulsch[UE_id]->harq_processes[harq_pid]->Kplus;
sumKr += Kr;
}
if (Nre==0)
return(0);
MPR_x100 = 100*sumKr/Nre;
// Note: MPR=is the effective spectral efficiency of the PUSCH
// FK 20140908 sumKr is only set after the ulsch_encoding
beta_offset_pusch = 8;
//(eNB->ulsch[UE_id]->harq_processes[harq_pid]->control_only == 1) ? eNB->ulsch[UE_id]->beta_offset_cqi_times8:8;
DevAssert( UE_id < NUMBER_OF_UE_MAX_NB_IoT );
//#warning "This condition happens sometimes. Need more investigation" // navid
//DevAssert( MPR_x100/6 < 100 );
if (eNB->ul_power_control_dedicated[UE_id].deltaMCS_Enabled == 1) {
// This is the formula from Section 5.1.1.1 in 36.213 10*log10(deltaIF_PUSCH = (2^(MPR*Ks)-1)*beta_offset_pusch)
if (bw_factor == 1) {
uint8_t nb_rb = eNB->ulsch[UE_id]->harq_processes[harq_pid]->nb_rb;
return(hundred_times_delta_TF_NB_IoT[MPR_x100/6]+10*dB_fixed_times10((beta_offset_pusch)>>3)) + hundred_times_log10_NPRB_NB_IoT[nb_rb-1];
} else
return(hundred_times_delta_TF_NB_IoT[MPR_x100/6]+10*dB_fixed_times10((beta_offset_pusch)>>3));
} else {
return(0);
}
}
/*
int16_t get_hundred_times_delta_IF_mac(module_id_t module_idP, uint8_t CC_id, rnti_t rnti, uint8_t harq_pid)
{
int8_t UE_id = find_ue( rnti, PHY_vars_eNB_g[module_idP][CC_id] );
if (UE_id == -1) {
// not found
return 0;
}
return get_hundred_times_delta_IF_eNB( PHY_vars_eNB_g[module_idP][CC_id], UE_id, harq_pid, 0 );
}
int16_t get_hundred_times_delta_IF(PHY_VARS_UE *ue,uint8_t eNB_id,uint8_t harq_pid)
{
uint32_t Nre = 2*ue->ulsch[eNB_id]->harq_processes[harq_pid]->Nsymb_initial *
ue->ulsch[eNB_id]->harq_processes[harq_pid]->nb_rb*12;
if (Nre==0)
return(0);
uint32_t MPR_x100 = 100*ue->ulsch[eNB_id]->harq_processes[harq_pid]->TBS/Nre;
// Note: MPR=is the effective spectral efficiency of the PUSCH
// FK 20140908 sumKr is only set after the ulsch_encoding
uint16_t beta_offset_pusch = (ue->ulsch[eNB_id]->harq_processes[harq_pid]->control_only == 1) ?
ue->ulsch[eNB_id]->beta_offset_cqi_times8:8;
if (ue->ul_power_control_dedicated[eNB_id].deltaMCS_Enabled == 1) {
// This is the formula from Section 5.1.1.1 in 36.213 10*log10(deltaIF_PUSCH = (2^(MPR*Ks)-1)*beta_offset_pusch)
return(hundred_times_delta_TF[MPR_x100/6]+10*dB_fixed_times10((beta_offset_pusch)>>3));
} else {
return(0);
}
}
uint8_t alpha_lut[8] = {0,40,50,60,70,80,90,100};
void pusch_power_cntl(PHY_VARS_UE *ue,UE_rxtx_proc_t *proc,uint8_t eNB_id,uint8_t j, uint8_t abstraction_flag)
{
uint8_t harq_pid = subframe2harq_pid(&ue->frame_parms,
proc->frame_tx,
proc->subframe_tx);
uint8_t nb_rb = ue->ulsch[eNB_id]->harq_processes[harq_pid]->nb_rb;
int16_t PL;
// P_pusch = 10*log10(nb_rb + P_opusch(j)+ alpha(u)*PL + delta_TF(i) + f(i))
//
// P_opusch(0) = P_oPTR + deltaP_Msg3 if PUSCH is transporting Msg3
// else
// P_opusch(0) = PO_NOMINAL_PUSCH(j) + P_O_UE_PUSCH(j)
PL = get_PL(ue->Mod_id,ue->CC_id,eNB_id);
ue->ulsch[eNB_id]->Po_PUSCH = (hundred_times_log10_NPRB[nb_rb-1]+
get_hundred_times_delta_IF(ue,eNB_id,harq_pid) +
100*ue->ulsch[eNB_id]->f_pusch)/100;
if(ue->ulsch_Msg3_active[eNB_id] == 1) { // Msg3 PUSCH
ue->ulsch[eNB_id]->Po_PUSCH += (mac_xface->get_Po_NOMINAL_PUSCH(ue->Mod_id,0) + PL);
LOG_I(PHY,"[UE %d][RAPROC] AbsSubframe %d.%d: Msg3 (%d PRBs) Po_PUSCH %d dBm (%d,%d,100*PL=%d,%d,%d)\n",
ue->Mod_id,proc->frame_tx,proc->subframe_tx,nb_rb,ue->ulsch[eNB_id]->Po_PUSCH,
100*mac_xface->get_Po_NOMINAL_PUSCH(ue->Mod_id,0),
hundred_times_log10_NPRB[nb_rb-1],
100*PL,
get_hundred_times_delta_IF(ue,eNB_id,harq_pid),
100*ue->ulsch[eNB_id]->f_pusch);
} else if (j==0) { // SPS PUSCH
} else if (j==1) { // Normal PUSCH
ue->ulsch[eNB_id]->Po_PUSCH += ((alpha_lut[ue->frame_parms.ul_power_control_config_common.alpha]*PL)/100);
ue->ulsch[eNB_id]->Po_PUSCH += ue->frame_parms.ul_power_control_config_common.p0_NominalPUSCH;
ue->ulsch[eNB_id]->PHR = ue->tx_power_max_dBm-ue->ulsch[eNB_id]->Po_PUSCH;
if (ue->ulsch[eNB_id]->PHR < -23)
ue->ulsch[eNB_id]->PHR = -23;
else if (ue->ulsch[eNB_id]->PHR > 40)
ue->ulsch[eNB_id]->PHR = 40;
LOG_D(PHY,"[UE %d][PUSCH %d] AbsSubframe %d.%d: nb_rb: %d, Po_PUSCH %d dBm : tx power %d, Po_NOMINAL_PUSCH %d,log10(NPRB) %f,PHR %d, PL %d, alpha*PL %f,delta_IF %f,f_pusch %d\n",
ue->Mod_id,harq_pid,proc->frame_tx,proc->subframe_tx,nb_rb,
ue->ulsch[eNB_id]->Po_PUSCH,
ue->tx_power_max_dBm,
ue->frame_parms.ul_power_control_config_common.p0_NominalPUSCH,
hundred_times_log10_NPRB[nb_rb-1]/100.0,
ue->ulsch[eNB_id]->PHR,
PL,
alpha_lut[ue->frame_parms.ul_power_control_config_common.alpha]*PL/100.0,
get_hundred_times_delta_IF(ue,eNB_id,harq_pid)/100.0,
ue->ulsch[eNB_id]->f_pusch);
}
}
int8_t get_PHR(uint8_t Mod_id, uint8_t CC_id,uint8_t eNB_index)
{
return PHY_vars_UE_g[Mod_id][CC_id]->ulsch[eNB_index]->PHR;
}
// uint8_t eNB_id,uint8_t harq_pid, uint8_t UE_id,
int16_t estimate_ue_tx_power(uint32_t tbs, uint32_t nb_rb, uint8_t control_only, lte_prefix_type_t ncp, uint8_t use_srs)
{
/// The payload + CRC size in bits, "B"
uint32_t B;
/// Number of code segments
uint32_t C;
/// Number of "small" code segments
uint32_t Cminus;
/// Number of "large" code segments
uint32_t Cplus;
/// Number of bits in "small" code segments (<6144)
uint32_t Kminus;
/// Number of bits in "large" code segments (<6144)
uint32_t Kplus;
/// Total number of bits across all segments
uint32_t sumKr;
/// Number of "Filler" bits
uint32_t F;
// num resource elements
uint32_t num_re=0.0;
// num symbols
uint32_t num_symb=0.0;
/// effective spectral efficiency of the PUSCH
uint32_t MPR_x100=0;
/// beta_offset
uint16_t beta_offset_pusch_x8=8;
/// delta mcs
float delta_mcs=0.0;
/// bandwidth factor
float bw_factor=0.0;
B= tbs+24;
lte_segmentation(NULL,
NULL,
B,
&C,
&Cplus,
&Cminus,
&Kplus,
&Kminus,
&F);
sumKr = Cminus*Kminus + Cplus*Kplus;
num_symb = 12-(ncp<<1)-(use_srs==0?0:1);
num_re = num_symb * nb_rb * 12;
if (num_re == 0)
return(0);
MPR_x100 = 100*sumKr/num_re;
if (control_only == 1 )
beta_offset_pusch_x8=8; // fixme
//(beta_offset_pusch_x8=ue->ulsch[eNB_id]->harq_processes[harq_pid]->control_only == 1) ? ue->ulsch[eNB_id]->beta_offset_cqi_times8:8;
// if deltamcs_enabledm
delta_mcs = ((hundred_times_delta_TF[MPR_x100/6]+10*dB_fixed_times10((beta_offset_pusch_x8)>>3))/100.0);
bw_factor = (hundred_times_log10_NPRB[nb_rb-1]/100.0);
#ifdef DEBUG_SEGMENTATION
printf("estimated ue tx power %d (num_re %d, sumKr %d, mpr_x100 %d, delta_mcs %f, bw_factor %f)\n",
(int16_t)ceil(delta_mcs + bw_factor), num_re, sumKr, MPR_x100, delta_mcs, bw_factor);
#endif
return (int16_t)ceil(delta_mcs + bw_factor);
}
*/
\ No newline at end of file
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