FreeCalypso > hg > freecalypso-citrine
view L1/tpudrv/tpudrv61.c @ 43:bceffa414fc6
cst_pei.c: added the same support for DISABLE_SLEEP as in Magnetite
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Sat, 09 Sep 2017 16:16:57 +0000 |
parents | 75a11d740a02 |
children |
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/****************** Revision Controle System Header *********************** * GSM Layer 1 software * Copyright (c) Texas Instruments 1998 * * Filename tpudrv61.c * Version 1.0 * Date May 27th, 2005 * ****************** Revision Controle System Header ***********************/ #define TPUDRV61_C #include "rf.cfg" #include "drp_api.h" #include "l1_macro.h" #include "l1_confg.h" #include "l1_const.h" #include "l1_types.h" #if TESTMODE #include "l1tm_defty.h" #endif #if (AUDIO_TASK == 1) #include "l1audio_const.h" #include "l1audio_cust.h" #include "l1audio_defty.h" #endif #if (L1_GTT == 1) #include "l1gtt_const.h" #include "l1gtt_defty.h" #endif #if (L1_MP3 == 1) #include "l1mp3_defty.h" #endif #if (L1_MIDI == 1) #include "l1midi_defty.h" #endif #if (L1_AAC == 1) #include "l1aac_defty.h" #endif #include "l1_defty.h" #include "l1_time.h" #include "l1_ctl.h" #include "tpudrv.h" #include "tpudrv61.h" #include "l1_rf61.h" #include "mem.h" #include "armio.h" #include "clkm.h" #if (L1_RF_KBD_FIX == 1) #include "l1_varex.h" #endif extern const UWORD8 drp_ref_sw[] ; extern T_DRP_REGS_STR *drp_regs; extern T_DRP_SRM_API* drp_srm_api; // Global variables extern T_L1_CONFIG l1_config; extern UWORD16 AGC_TABLE[]; extern UWORD16 *TP_Ptr; #if (L1_FF_MULTIBAND == 1) extern const WORD8 rf_subband2band[RF_NB_SUBBANDS]; #endif static WORD8 rf_index; // index into rf_path[] #if( L1_TPU_DEV == 1) WORD16 rf_rx_tpu_timings[NB_TPU_TIMINGS] = { // - RX up: // The times below are offsets to when the 1st bit is at antenna // Burst data comes here (PROVISION_TIME - 203 - DLT_4B - rdt ), // TRF_R1 Set RX Synth channel //l1dmacro_adc_read_rx() called here requires ~ 16 tpuinst (PROVISION_TIME - 197 - DLT_4B - rdt ), // TRF_R2 Select the AGC & LNA gains (PROVISION_TIME - 190 - DLT_4B - rdt ) , // TRF_R3 RX_ON (PROVISION_TIME - 39 - DLT_1 - rdt ), // TRF_R4 Set RF switch for RX in selected band (PROVISION_TIME - 19 - DLT_1), // TRF_R5 Enable RX_START ( -20 - DLT_4B ), // TRF_R6 Disable RX Start and RF switch // TRF_R6 not use, warning timing TRF_R6 > TRF_R7 ( 2 - DLT_4B), // TRF_R7 Power down RF (idle script) #if (L1_MADC_ON == 1) (PROVISION_TIME - 170 - DLT_4B - rdt ), // for doing MADC #else 0, #endif 0, 0, 0, 0,0,0,0,0,0,0,0,0, 0, 0,0,0,0,0,0,0,0,0, 0,0 }; WORD16 rf_tx_tpu_timings[NB_TPU_TIMINGS] = { // - TX up: // The times below are offsets to when TXSTART goes high //burst data comes here ( - 255 - DLT_4B - tdt ), // TRF_T1 Set TX synth ( - 235 - DLT_4B - tdt ), // TRF_T2 Power ON TX ( - 225 - DLT_1 ), // TRF_T3 ( - 100 - DLT_1 ), // TRF_T4 ( - 30 - DLT_1 ), // TRF_T5 ( 0 - DLT_1 ), // TRF_T6 ( 8 - DLT_1 ), // TRF_T7 ( 16 - DLT_1 ), // TRF_T8 // - TX timings --- // - TX down: // The times below are offsets to when TXSTART goes down ( - 40 - DLT_1 ), // TRF_T9 ADC read ( 0 - DLT_1 ), // TRF_T10 Disable APC ( 16 - DLT_1 ) , // TRF_T11 Disable PA ( 20 - DLT_1 ) , // TRF_T12 Disable TXSTART ( 30 - DLT_4B ) , // TRF_T13 Power off Locosto 0, 0, 0, 0, 0,0,0, 0, 0,0,0,0,0,0,0,0,0, 0,0 }; //Flexi ABB DELAYS WORD16 rf_flexi_abb_delays[NB_ABB_DELAYS] = { //Note: 0th element is not mapped to anything should be always 0 0, 20, (45L), 12, 0 , 0 , 0 , 12, 5, 6, 1L, (63L + 4L), (DL_DELAY_RF + UL_DELAY_2RF + (GUARD_BITS*4) + UL_DELAY_1RF + UL_ABB_DELAY), 2L, 20L, 10L, 20, 6, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; #endif //TPU_DEVEL // Internal function prototypes void l1dmacro_rx_down (WORD32 t); #if (L1_FF_MULTIBAND == 0) SYS_UWORD16 Convert_l1_radio_freq(SYS_UWORD16 radio_freq); WORD32 rf_init(WORD32 t); // External function prototypes UWORD8 Cust_is_band_high(UWORD16 radio_freq); #endif extern T_RF_BAND rf_band[]; extern T_RF rf; /**************************************************************************/ /**************************************************************************/ /* DEFINITION OF MACROS FOR CHIPS SERIAL PROGRAMMATION */ /**************************************************************************/ /**************************************************************************/ /*------------------------------------------*/ /* Is arfcn in the DCS band (512-885) ? */ /*------------------------------------------*/ #define IS_HIGH_BAND(arfcn) (((arfcn >= 512) && (arfcn <= 885)) ? 1 : 0) /*------------------------------------------*/ /* Send a value to LoCosto */ /*------------------------------------------*/ #define MOVE_REG_TSP_TO_RF(data, addr)\ {\ *TP_Ptr++ = TPU_MOVE(OCP_DATA_MSB, ((data)>>8) & 0x00FF); \ *TP_Ptr++ = TPU_MOVE(OCP_DATA_LSB, (data) & 0x00FF); \ *TP_Ptr++ = TPU_MOVE(OCP_ADDRESS_MSB, ((addr)>>8) & 0x00FF); \ *TP_Ptr++ = TPU_MOVE(OCP_ADDRESS_LSB, (addr) & 0x00FF); \ *TP_Ptr++ = TPU_MOVE(OCP_ADDRESS_START, 0x0001); \ } /* RFTime environment */ #if defined (HOST_TEST) #include "hostmacros.h" #endif /*------------------------------------------*/ /* Trace arfcn for conversion debug */ /*------------------------------------------*/ #ifdef ARFCN_DEBUG // ----Debug information : record all arfcn programmed into synthesizer! #define MAX_ARFCN_TRACE 4096 // enough for 5 sessions of 124+374 SYS_UWORD16 arfcn_trace[MAX_ARFCN_TRACE]; static UWORD32 arfcn_trace_index = 0; void trace_arfcn(SYS_UWORD16 arfcn) { arfcn_trace[arfcn_trace_index++] = arfcn; // Wrap to beginning if (arfcn_trace_index == MAX_ARFCN_TRACE) arfcn_trace_index = 0; } #endif /**************************************************************************/ /**************************************************************************/ /* DEFINITION OF HARWARE DEPENDANT CONSTANTS */ /**************************************************************************/ /**************************************************************************/ /**************************************************************************/ /**************************************************************************/ /* INTERNAL FUNCTIONS OF TPUDRV14.C */ /* EFFECTIVE DOWNLOADING THROUGH TSP */ /**************************************************************************/ /**************************************************************************/ // rx & tx typedef struct tx_rx_s { UWORD16 farfcn0; WORD8 ou; } T_TX_RX; struct synth_s { // common UWORD16 arfcn0; UWORD16 limit; T_TX_RX tx_rx[2]; }; struct rf_path_s { UWORD8 rx_up; UWORD8 rx_down; UWORD8 tx_up; UWORD8 tx_down; struct synth_s *synth; }; const struct synth_s synth_900[] = { { 0, 124, {{ 890, 1}, { 935, 2}}},// gsm 0 - 124 {974, 1023, {{ 880, 1}, { 925, 2}}},// egsm 975 - 1023 }; const struct synth_s synth_1800[] = { {511, 885, {{1710, 1}, {1805, 1}}}, // dcs 512 - 885 }; const struct synth_s synth_1900[] = { {511, 810, {{1850, 1}, {1930, 1}}}, // pcs 512 - 810; }; const struct synth_s synth_850[] = { {127, 192, {{ 824, 2}, { 869, 2}}}, // gsm850 128 - 251 //low {127, 251, {{ 824, 1}, { 869, 2}}}, // gsm850 128 - 251 //high }; #if RF_BAND_SYSTEM_INDEX == RF_QUADBAND struct rf_path_s rf_path[] = { //same index used as for band_config[] - 1 { RU_900, RD_900, TU_900, TD_900, (struct synth_s *)synth_900 }, //EGSM { RU_1800, RD_1800, TU_1800, TD_1800, (struct synth_s *)synth_1800}, //DCS { RU_1900, RD_1900, TU_1900, TD_1900, (struct synth_s *)synth_1900}, //PCS { RU_850, RD_850, TU_850, TD_850, (struct synth_s *)synth_850 }, //GSM850 }; #endif #if RF_BAND_SYSTEM_INDEX == RF_EU_TRIBAND struct rf_path_s rf_path[] = { //same index used as for band_config[] - 1 { RU_850, RD_850, TU_900, TD_900, (struct synth_s *)synth_900 }, //EGSM { RU_1800, RD_1800, TU_1800, TD_1800, (struct synth_s *)synth_1800}, //DCS { RU_1900, RD_1900, TU_1900, TD_1900, (struct synth_s *)synth_1900}, //PCS { RU_850, RD_850, TU_850, TD_850, (struct synth_s *)synth_850 }, //GSM850 }; #endif #if RF_BAND_SYSTEM_INDEX == RF_US_DUALBAND struct rf_path_s rf_path[] = { //same index used as for band_config[] - 1 { RU_900, RD_900, TU_900, TD_900, (struct synth_s *)synth_900 }, //EGSM { RU_1800, RD_1800, TU_1800, TD_1800, (struct synth_s *)synth_1800}, //DCS { RU_1800, RD_1800, TU_1900, TD_1900, (struct synth_s *)synth_1900}, //PCS { RU_850, RD_850, TU_850, TD_850, (struct synth_s *)synth_850 }, //GSM850 }; #endif #if RF_BAND_SYSTEM_INDEX == RF_PCS1900_900_DUALBAND struct rf_path_s rf_path[] = { //same index used as for band_config[] - 1 { RU_850, RD_850, TU_900, TD_900, (struct synth_s *)synth_900 }, //EGSM { RU_1800, RD_1800, TU_1800, TD_1800, (struct synth_s *)synth_1800}, //DCS { RU_1800, RD_1800, TU_1900, TD_1900, (struct synth_s *)synth_1900}, //PCS { RU_850, RD_850, TU_850, TD_850, (struct synth_s *)synth_850 }, //GSM850 }; #endif UWORD32 calc_rf_freq(UWORD16 arfcn, UWORD8 downlink) { UWORD32 farfcn; struct synth_s *s; s = rf_path[rf_index].synth; while(s->limit < arfcn) s++; // Convert the ARFCN to the channel frequency (times 5 to avoid the decimal value) farfcn = 5*s->tx_rx[downlink].farfcn0 + (arfcn - s->arfcn0); // LoCosto DLO carrier frequency is programmed in 100kHz increments. // Therefore RF_FREQ = (channel frequency * 10) = (farfcn * 2) return ( 2*farfcn ); } #if (L1_FF_MULTIBAND == 0) /*------------------------------------------*/ /* Convert_l1_radio_freq */ /*------------------------------------------*/ /* conversion of l1 radio_freq to */ /* real channel number */ /*------------------------------------------*/ SYS_UWORD16 Convert_l1_radio_freq(SYS_UWORD16 radio_freq) { switch(l1_config.std.id) { case GSM: case DCS1800: case PCS1900: case GSM850: return (radio_freq); //omaps00090550 break; case DUAL: { if (radio_freq < l1_config.std.first_radio_freq_band2) // GSM band... return(radio_freq); else // DCS band... return (radio_freq - l1_config.std.first_radio_freq_band2 + 512); } //omaps00090550 break; case DUALEXT: { if (radio_freq < l1_config.std.first_radio_freq_band2) // E-GSM band... { if(radio_freq <= 124) // GSM part... return(radio_freq); if(radio_freq < 174) // Extended part... return (radio_freq - 125 + 975); else // Extended part, special case of ARFCN=0 return(0); } else { // DCS band... return (radio_freq - l1_config.std.first_radio_freq_band2 + 512); } } // break; case GSM_E: { if(radio_freq <= 124) // GSM part... return(radio_freq); else if(radio_freq < 174) // Extended part... return (radio_freq - 125 + 975); else // Extended part, special case of ARFCN=0 return(0); } //omaps00090550 break; case DUAL_US: { if (radio_freq < l1_config.std.first_radio_freq_band2) { return(radio_freq - l1_config.std.first_radio_freq + 128); } else { // PCS band... return (radio_freq - l1_config.std.first_radio_freq_band2 + 512); } } // break; default: // should never occur. return(radio_freq); } // end of switch } #else static const UWORD8 rf_band_idx_to_locosto_idx[] = { #if (GSM900_SUPPORTED == 1) 0, #endif #if (GSM850_SUPPORTED == 1) 3, #endif #if (DCS1800_SUPPORTED == 1) 1, #endif #if (PCS1900_SUPPORTED == 1) 2 #endif }; SYS_UWORD16 Convert_l1_radio_freq(SYS_UWORD16 radio_freq) { UWORD8 band_index; return(rf_convert_l1freq_to_arfcn_rfband(rf_convert_rffreq_to_l1freq(radio_freq), &band_index)); } #endif /*------------------------------------------*/ /* rf_init */ /*------------------------------------------*/ /* Initialization routine for PLL */ /* Effective downloading through TSP */ /*------------------------------------------*/ WORD32 rf_init(WORD32 t) { //UWORD16 temp=(UWORD16)( ((UWORD32)(&drp_srm_api->control.retiming))&0xFFFF) ; // enable control of retiming MOVE_REG_TSP_TO_RF(RETIM_DISABLE, ((UWORD16)( ((UWORD32)(&drp_srm_api->control.retiming))&0xFFFF))); // Power ON the regulators by sending REG_ON script MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_REG_ON), ((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))))); return(t); } #if (L1_FF_MULTIBAND == 0) UWORD8 arfcn_to_rf_index(SYS_UWORD16 arfcn) { UWORD8 index; extern const T_STD_CONFIG std_config[]; index = std_config[l1_config.std.id].band[0]; if ((std_config[l1_config.std.id].band[1] != BAND_NONE) && IS_HIGH_BAND(arfcn)) index = std_config[l1_config.std.id].band[1]; return (index - 1); } #endif /*------------------------------------------*/ /* rf_program */ /*------------------------------------------*/ /* Programs the RF synthesizer */ /* called each frame */ /* downloads NA counter value */ /* t = start time in the current frame */ /*------------------------------------------*/ //change 2 UWORD8 UWORD32 rf_program(UWORD32 t, SYS_UWORD16 radio_freq, UWORD32 rx) { UWORD32 rfdiv; SYS_UWORD16 arfcn; #ifdef ARFCN_DEBUG trace_arfcn(arfcn); #endif #if (L1_FF_MULTIBAND == 0) arfcn = Convert_l1_radio_freq(radio_freq); rf_index = arfcn_to_rf_index(arfcn); if (rf_index == 4) { rf_index = 0; } #else { UWORD8 rf_band_index; // rf_index = rf_band_idx_to_locosto_idx[rf_convert_l1freq_to_rf_band_idx(radio_freq)]; arfcn=rf_convert_rffreq_to_l1freq_rfband(radio_freq, &rf_band_index); rf_index = rf_band_idx_to_locosto_idx[rf_subband2band[rf_band_index]]; arfcn=rf_convert_l1freq_to_arfcn_rfband(arfcn, &rf_band_index); } #endif rfdiv = calc_rf_freq(arfcn, rx); MOVE_REG_TSP_TO_RF(rfdiv,((UWORD16)( ((UWORD32)(&drp_regs->RF_FREQL))&0xFFFF))); return(t); } /*------------------------------------------*/ /* rf_init_light */ /*------------------------------------------*/ /* Initialization routine for PLL */ /* Effective downloading through TSP */ /*------------------------------------------*/ WORD32 rf_init_light(WORD32 t) { // initialization for change of multi-band configuration dependent on STD return(t); } /**************************************************************************/ /**************************************************************************/ /* EXTERNAL FUNCTIONS CALLED BY LAYER1 */ /* COMMON TO L1 and TOOLKIT */ /**************************************************************************/ /**************************************************************************/ void l1dmacro_afc (SYS_UWORD16 afc_value, UWORD8 win_id) { MOVE_REG_TSP_TO_RF(afc_value, ((UWORD16)( ((UWORD32)(&drp_srm_api->inout.afc.input.mem_xtal))&0xFFFF))); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_AFC), ((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))&0xFFFF))); } #define L1_NEW_ROC_ENABLE_FLAG (1) #if (L1_NEW_ROC_ENABLE_FLAG == 1) /*------------------------------------------*/ /* cust_get_if_dco_ctl_algo */ /*------------------------------------------*/ /* Defines which IF and DCO */ /* algorythms are used */ /* */ /* */ /*------------------------------------------*/ /* NOTE: In the below code * At high power levels, IF_100KHZ_DSP-> DRP->LIF_100KHZ and DSP->DCO_IF_100KHZ/DCO_IF_0_100KHZ * low power levels IF_120KHZ_DSP-> DRP->LIF_120KHZ + HPF filter and DSP->DCO_NONE/DCO_IF_0KHZ */ void cust_get_if_dco_ctl_algo(UWORD16 *dco_algo_ctl, UWORD8 *if_ctrl, UWORD8 input_level_flag, UWORD8 input_level, UWORD16 radio_freq, UWORD8 if_threshold) { #if (L1_FF_MULTIBAND == 0) SYS_UWORD16 arfcn; #else UWORD16 rffreq; #endif if ((!input_level_flag) || (input_level < if_threshold)) { *if_ctrl = IF_100KHZ_DSP; *dco_algo_ctl = DCO_IF_100KHZ; } else { *if_ctrl = IF_120KHZ_DSP; *dco_algo_ctl = DCO_NONE; } #if (L1_FF_MULTIBAND == 0) arfcn = Convert_l1_radio_freq(radio_freq); switch(l1_config.std.id) { case GSM: case GSM_E: { if ((arfcn == 5) || (arfcn == 70)) { if (*if_ctrl == IF_100KHZ_DSP) *dco_algo_ctl = DCO_IF_0KHZ_100KHZ; else *dco_algo_ctl = DCO_IF_0KHZ; } break; } case DCS1800: { if ((arfcn == 521) || (arfcn == 586) || (arfcn == 651) || (arfcn == 716) ||(arfcn == 781) || (arfcn == 846)) { if (*if_ctrl == IF_100KHZ_DSP) *dco_algo_ctl = DCO_IF_0KHZ_100KHZ; else *dco_algo_ctl = DCO_IF_0KHZ; } break; } case PCS1900: { if ((arfcn == 546) || (arfcn == 611) ||(arfcn == 676) || (arfcn == 741) ||(arfcn == 806) ) { if (*if_ctrl == IF_100KHZ_DSP) *dco_algo_ctl = DCO_IF_0KHZ_100KHZ; else *dco_algo_ctl = DCO_IF_0KHZ; } break; } case GSM850: { if ((arfcn == 137) || (arfcn == 202)) { if (*if_ctrl == IF_100KHZ_DSP) *dco_algo_ctl = DCO_IF_0KHZ_100KHZ; else *dco_algo_ctl = DCO_IF_0KHZ; } break; } case DUAL: case DUALEXT: { if (radio_freq < l1_config.std.first_radio_freq_band2) { // GSM band... if ((arfcn == 5) ||(arfcn == 70)) { if (*if_ctrl == IF_100KHZ_DSP) *dco_algo_ctl = DCO_IF_0KHZ_100KHZ; else *dco_algo_ctl = DCO_IF_0KHZ; } } else // DCS band... { if ((arfcn == 521) || (arfcn == 586) || (arfcn == 651) || (arfcn == 716) ||(arfcn == 781) || (arfcn == 846)) { if (*if_ctrl == IF_100KHZ_DSP) *dco_algo_ctl = DCO_IF_0KHZ_100KHZ; else *dco_algo_ctl = DCO_IF_0KHZ; } } break; } case DUAL_US: { if (radio_freq < l1_config.std.first_radio_freq_band2) { // GSM 850 if ((arfcn == 137) || (arfcn == 202)) { if (*if_ctrl == IF_100KHZ_DSP) *dco_algo_ctl = DCO_IF_0KHZ_100KHZ; else *dco_algo_ctl = DCO_IF_0KHZ; } } else { // PCS band... if ((arfcn == 546) || (arfcn == 611) ||(arfcn == 676) || (arfcn == 741) ||(arfcn == 806) ) { if (*if_ctrl == IF_100KHZ_DSP) *dco_algo_ctl = DCO_IF_0KHZ_100KHZ; else *dco_algo_ctl = DCO_IF_0KHZ; } } break; } default: break;// should never occur. } // end of switch #else //#if (L1_FF_MULTIBAND == 0) //rffreq = rf_convert_l1freq_to_rffreq(radio_freq); rffreq=radio_freq; // The argument passed to this function is the radio_freq and not l1_freq if( #if (GSM850_SUPPORTED == 1) (137 == rffreq)||(202 == rffreq) || #endif #if (GSM900_SUPPORTED == 1) (5 == rffreq)||(70 == rffreq) || #endif #if (DCS1800_SUPPORTED == 1) (521 == rffreq)||(586 == rffreq) ||(651 == rffreq)||(716 == rffreq) ||(781 == rffreq)||(846 == rffreq) || #endif #if (PCS1900_SUPPORTED == 1) (546+512 == rffreq) ||(611+512 == rffreq)||(676+512 == rffreq) ||(741+512 == rffreq)||(806+512 == rffreq) || #endif 0) { if (*if_ctrl == IF_100KHZ_DSP) *dco_algo_ctl = DCO_IF_0KHZ_100KHZ; else *dco_algo_ctl = DCO_IF_0KHZ; } #endif // if (L1_FF_MULTIBAND == 0) } #else /*------------------------------------------*/ /* cust_get_if_dco_ctl_algo */ /*------------------------------------------*/ /* Defines which IF and DCO */ /* algorythms are used */ /* */ /* */ /*------------------------------------------*/ /* NOTE: Below is the Old DCO algorithm in which ROC compensation was not enabled on DSP side * To use this algorithm we need an appropriate DRP script which functions as below. * IF_100KHZ_DSP-> DRP-ZIF and DSP-DCO_ZIF * IF_120KHZ_DSP-> DRP_LIF_120KHZ + HPF filter and DSP-DCO_ZIF/DCO_NONE */ void cust_get_if_dco_ctl_algo(UWORD16 *dco_algo_ctl, UWORD8 *if_ctrl, UWORD8 input_level_flag, UWORD8 input_level, UWORD16 radio_freq, UWORD8 if_threshold) { #if (L1_FF_MULTIBAND == 0) SYS_UWORD16 arfcn; #else UWORD16 rffreq; #endif if ((!input_level_flag) | (input_level < if_threshold)) { *if_ctrl = IF_100KHZ_DSP; *dco_algo_ctl = DCO_IF_0KHZ; } else{ *if_ctrl = IF_120KHZ_DSP; //*dco_algo_ctl = DCO_IF_100KHZ; *dco_algo_ctl = DCO_NONE; #if (L1_FF_MULTIBAND == 0) arfcn = Convert_l1_radio_freq(radio_freq); switch(l1_config.std.id) { case GSM: case GSM_E: if ((arfcn == 5) |(arfcn == 70)) *dco_algo_ctl = DCO_IF_0KHZ; break; case DCS1800: if ((arfcn == 521) | (arfcn == 586) | (arfcn == 651) | (arfcn == 716) |(arfcn == 781) | (arfcn == 846)) *dco_algo_ctl = DCO_IF_0KHZ; break; case PCS1900: if ((arfcn == 546) | (arfcn == 611) |(arfcn == 676) | (arfcn == 741) |(arfcn == 806) ) *dco_algo_ctl = DCO_IF_0KHZ; break; case GSM850: if ((arfcn == 137) | (arfcn == 202)) *dco_algo_ctl = DCO_IF_0KHZ; break; case DUAL: case DUALEXT: { if (radio_freq < l1_config.std.first_radio_freq_band2) { // GSM band... if ((arfcn == 5) |(arfcn == 70)) *dco_algo_ctl = DCO_IF_0KHZ; } else // DCS band... { if ((arfcn == 521) | (arfcn == 586) | (arfcn == 651) | (arfcn == 716) |(arfcn == 781) | (arfcn == 846)) *dco_algo_ctl = DCO_IF_0KHZ; } } break; case DUAL_US: { if (radio_freq < l1_config.std.first_radio_freq_band2) { // GSM 850 if ((arfcn == 137) | (arfcn == 202)) *dco_algo_ctl = DCO_IF_0KHZ; } else { // PCS band... if ((arfcn == 546) | (arfcn == 611) |(arfcn == 676) | (arfcn == 741) |(arfcn == 806) ) *dco_algo_ctl = DCO_IF_0KHZ; } } break; default: break;// should never occur. } // end of switch #else rffreq = rf_convert_l1freq_to_rffreq(radio_freq); if( #if (GSM850_SUPPORTED == 1) (137 == rffreq)||(202 == rffreq) || #endif #if (GSM900_SUPPORTED == 1) (5 == rffreq)||(70 == rffreq) || #endif #if (DCS1800_SUPPORTED == 1) (521 == rffreq)||(586 == rffreq) ||(651 == rffreq)||(716 == rffreq) ||(781 == rffreq)||(846 == rffreq) || #endif #if (PCS1900_SUPPORTED == 1) (546+512 == rffreq) ||(611+512 == rffreq)||(676+512 == rffreq) ||(741+512 == rffreq)||(806+512 == rffreq) || #endif 0) { *dco_algo_ctl = DCO_IF_0KHZ; } #endif } } #endif /*------------------------------------------*/ /* agc */ /*------------------------------------------*/ /* Program a gain into IF amp */ /* agc_value : gain in dB */ /* */ /* additional parameter for LNA setting */ /*------------------------------------------*/ void l1dmacro_agc(SYS_UWORD16 radio_freq, WORD8 gain, UWORD8 lna_off, UWORD8 if_ctl) { signed int index; WORD16 afe; UWORD16 corner_freq = SCF_270KHZ ; //Corner frequency given in kHz UWORD16 gain_comp = GAIN_COMP_ENABLE; //gain compensation scheme UWORD16 if_setting; UWORD16 lna_setting; UWORD16 arfcn ; index = gain; // below is inserted to prevent wraparound of gain index in testmode if (index >= AGC_TABLE_SIZE) index = AGC_TABLE_SIZE-1; if (index <= MIN_AGC_INDEX) index = MIN_AGC_INDEX; if(lna_off) afe = AFE_LOW_GAIN; else afe = AFE_HIGH_GAIN; if(if_ctl == IF_120KHZ_DSP) if_setting = IF_120KHZ_DRP; else if_setting = IF_100KHZ_DRP; #if (L1_FF_MULTIBAND == 0) //LNA Changes arfcn = Convert_l1_radio_freq(radio_freq); //band_system_index = (UWORD16) convert_arfcn_to_band(arfcn); lna_setting = (UWORD16) drp_generate_dbbif_setting_arfcn( (UWORD16) RF_BAND_SYSTEM_INDEX, arfcn); //End LNA #else #if 0 rf_band_idx = rf_convert_l1freq_to_rf_band_idx(radio_freq); switch(rf_band_idx) { #if(GSM850_SUPPORTED) case RF_GSM850: drp_band_index = 0; break; #endif #if(DCS1800_SUPPORTED) case RF_DCS1800: drp_band_index = 2; break; #endif #if(PCS1900_SUPPORTED) case RF_PCS1900: drp_band_index = 3; break; #endif default: drp_band_index = 1; break; } #endif // if 0 lna_setting = (UWORD16) drp_generate_dbbif_setting_arfcn( (UWORD16) RF_BAND_SYSTEM_INDEX, radio_freq); #endif //if_setting = IF_100KHZ_DRP; // r2: implement the register rx_in for setting the configuration of the RX path *TP_Ptr++ = TPU_AT(TRF_R2); MOVE_REG_TSP_TO_RF(( (lna_setting <<8) | (corner_freq<<7) | (afe<<6) | (AGC_TABLE[index]<<2) | (gain_comp<<1) | (if_setting)), ((UWORD16)( ((UWORD32)(&drp_srm_api->inout.rx.rxon_input))&0xFFFF))); } /*------------------------------------------*/ /* l1dmacro_rx_synth */ /*------------------------------------------*/ /* programs RF synth for recceive */ /*------------------------------------------*/ void l1dmacro_rx_synth(SYS_UWORD16 radio_freq) { UWORD32 t; // Important: always use rx_synth_start_time for first TPU_AT // Never remove below 2 lines!!! t = l1_config.params.rx_synth_start_time; *TP_Ptr++ = TPU_FAT (t); t = rf_program(t, radio_freq, 1); // direction is set to 1 for Rx } /*------------------------------------------*/ /* l1dmacro_tx_synth */ /*------------------------------------------*/ /* programs RF synth for transmit */ /* programs OPLL for transmit */ /*------------------------------------------*/ void l1dmacro_tx_synth(SYS_UWORD16 radio_freq) { UWORD32 t; // Important: always use tx_synth_start_time for first TPU_AT // Never remove below 2 lines!!! t = l1_config.params.tx_synth_start_time; *TP_Ptr++ = TPU_FAT (t); t = rf_program(t, radio_freq, 0); // direction set to 0 for Tx } /*------------------------------------------*/ /* l1dmacro_rx_up */ /*------------------------------------------*/ /* Open window for normal burst reception */ /*------------------------------------------*/ #if (L1_RF_KBD_FIX == 1) #if (L1_MADC_ON == 0) void l1dmacro_rx_up (UWORD8 csf_filter_choice, UWORD8 kbd_config #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { UWORD8 kbd_tspact_config =0; if (kbd_config == KBD_DISABLED) kbd_tspact_config = KBD_DIS_TSPACT; // r3: power ON RX *TP_Ptr++ = TPU_AT(TRF_R3); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_RX_ON), ((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))))); // r3_1: disable keyboard *TP_Ptr++ = TPU_AT(TRF_R3_1); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config); // r4: enable TXM in Rx mode *TP_Ptr++ = TPU_AT(TRF_R4); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].rx_up); // Program CSF filter appropriately if(csf_filter_choice == L1_SAIC_HARDWARE_FILTER) { MOVE_REG_TSP_TO_RF(CSF_CWL_HARDWARE_FILTER_64TAP, (UWORD16)(&drp_regs->CSF_CWL)); } else { MOVE_REG_TSP_TO_RF(CSF_CWL_PROGRAMMABLE_FILTER_64TAP, (UWORD16)(&drp_regs->CSF_CWL)); } // r5: enable RX_START #if (L1_SAIC != 0)//Because for 0/2 interpolation, SAIC needs 1 additional symbol compared to legacy modem. #if (NEW_SNR_THRESHOLD==1) if(saic_flag_rx_up==1) { #endif #if (ONE_THIRD_INTRPOL == 1) *TP_Ptr++ = TPU_AT(TRF_R5-5); #else *TP_Ptr++ = TPU_AT(TRF_R5-4); #endif #if (NEW_SNR_THRESHOLD==1) } else { *TP_Ptr++ = TPU_AT(TRF_R5); } #endif #else *TP_Ptr++ = TPU_AT(TRF_R5); #endif *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | RX_START); } #endif #if (L1_MADC_ON == 1) void l1dmacro_rx_up(UWORD8 adc_active, UWORD8 csf_filter_choice, UWORD8 kbd_config #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { UWORD8 kbd_tspact_config =0; if (kbd_config == KBD_DISABLED) kbd_tspact_config = KBD_DIS_TSPACT; // r3: power ON RX *TP_Ptr++ = TPU_AT(TRF_R3); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_RX_ON), (UWORD32)(&drp_regs->SCRIPT_STARTL)); if (adc_active == ACTIVE) { *TP_Ptr++ = TPU_AT(TRF_R8); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U,START_ADC|TXM_SLEEP); *TP_Ptr++ = TPU_WAIT (2); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U,TXM_SLEEP); } // r3_1: disable keyboard *TP_Ptr++ = TPU_AT(TRF_R3_1); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config); // r4: enable TXM in Rx mode *TP_Ptr++ = TPU_AT(TRF_R4); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].rx_up); // Program CSF filter appropriately if(csf_filter_choice == L1_SAIC_HARDWARE_FILTER) { MOVE_REG_TSP_TO_RF(CSF_CWL_HARDWARE_FILTER_64TAP, (UWORD32)(&drp_regs->CSF_CWL)); } else { MOVE_REG_TSP_TO_RF(CSF_CWL_PROGRAMMABLE_FILTER_64TAP, (UWORD32)(&drp_regs->CSF_CWL)); } // r5: enable RX_START // Remember that between TRF_R5 and TRF_R4 there should be a buffer of around 4 qbits #if (L1_SAIC != 0)//Because for 0/2 interpolation, SAIC needs 1 additional symbol compared to legacy modem. #if (NEW_SNR_THRESHOLD==1) if(saic_flag_rx_up==1) { #endif #if (ONE_THIRD_INTRPOL == 1) *TP_Ptr++ = TPU_AT(TRF_R5-5); #else *TP_Ptr++ = TPU_AT(TRF_R5-4); #endif #if (NEW_SNR_THRESHOLD==1) } else { *TP_Ptr++ = TPU_AT(TRF_R5); } #endif #else *TP_Ptr++ = TPU_AT(TRF_R5); #endif *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | RX_START); } #endif #endif /* (L1_RF_KBD_FIX == 1) */ #if (L1_RF_KBD_FIX == 0) #if (L1_MADC_ON == 0) void l1dmacro_rx_up (UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { // r3: power ON RX *TP_Ptr++ = TPU_AT(TRF_R3); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_RX_ON), (UWORD16)(&drp_regs->SCRIPT_STARTL)); // r4: enable TXM in Rx mode *TP_Ptr++ = TPU_AT(TRF_R4); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].rx_up); // Program CSF filter appropriately if(csf_filter_choice == L1_SAIC_HARDWARE_FILTER) { MOVE_REG_TSP_TO_RF(CSF_CWL_HARDWARE_FILTER_64TAP, (UWORD16)(&drp_regs->CSF_CWL)); } else { MOVE_REG_TSP_TO_RF(CSF_CWL_PROGRAMMABLE_FILTER_64TAP, (UWORD16)(&drp_regs->CSF_CWL)); } // r5: enable RX_START #if (L1_SAIC != 0)//Because for 0/2 interpolation, SAIC needs 1 additional symbol compared to legacy modem. #if (NEW_SNR_THRESHOLD==1) if(saic_flag_rx_up==1) { #endif #if (ONE_THIRD_INTRPOL == 1) *TP_Ptr++ = TPU_AT(TRF_R5-5); #else *TP_Ptr++ = TPU_AT(TRF_R5-4); #endif #if (NEW_SNR_THRESHOLD==1) } else { *TP_Ptr++ = TPU_AT(TRF_R5); } #endif #else *TP_Ptr++ = TPU_AT(TRF_R5); #endif *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, RX_START); } #endif #if (L1_MADC_ON == 1) void l1dmacro_rx_up(UWORD8 adc_active, UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { // r3: power ON RX *TP_Ptr++ = TPU_AT(TRF_R3); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_RX_ON), (UWORD16)(&drp_regs->SCRIPT_STARTL)); if (adc_active == ACTIVE) { *TP_Ptr++ = TPU_AT(TRF_R8); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U,START_ADC); *TP_Ptr++ = TPU_WAIT (2); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U,0); } // r4: enable TXM in Rx mode *TP_Ptr++ = TPU_AT(TRF_R4); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].rx_up); // Program CSF filter appropriately if(csf_filter_choice == L1_SAIC_HARDWARE_FILTER) { MOVE_REG_TSP_TO_RF(CSF_CWL_HARDWARE_FILTER_64TAP, (UWORD16)(&drp_regs->CSF_CWL)); } else { MOVE_REG_TSP_TO_RF(CSF_CWL_PROGRAMMABLE_FILTER_64TAP, (UWORD16)(&drp_regs->CSF_CWL)); } // r5: enable RX_START #if (L1_SAIC != 0)//Because for 0/2 interpolation, SAIC needs 1 additional symbol compared to legacy modem. #if (NEW_SNR_THRESHOLD==1) if(saic_flag_rx_up==1) { #endif #if (ONE_THIRD_INTRPOL == 1) *TP_Ptr++ = TPU_AT(TRF_R5-5); #else *TP_Ptr++ = TPU_AT(TRF_R5-4); #endif #if (NEW_SNR_THRESHOLD==1) } else { *TP_Ptr++ = TPU_AT(TRF_R5); } #endif #else *TP_Ptr++ = TPU_AT(TRF_R5); #endif *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, RX_START); } #endif #endif /* (L1_RF_KBD_FIX == 0) */ /*------------------------------------------*/ /* l1pdmacro_rx_down */ /*------------------------------------------*/ /* Close window for normal burst reception */ /*------------------------------------------*/ void l1dmacro_rx_down (WORD32 t) { //r6: Disable ROC script *TP_Ptr++ = TPU_FAT(t + TRF_R6); MOVE_REG_TSP_TO_RF((DRP_ROC), ((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))&0xFFFF))); //r7: Disable Rx_Start & Disable RF switch & send Idle script *TP_Ptr++ = TPU_FAT(t + TRF_R7); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].rx_down); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, 0); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_IDLE),((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))&0xFFFF))); } /*------------------------------------------*/ /* l1dmacro_tx_up */ /*------------------------------------------*/ /* Open transmission window for normal burst*/ /*------------------------------------------*/ #if (L1_RF_KBD_FIX == 1) void l1dmacro_tx_up (UWORD8 kbd_config) { UWORD8 kbd_tspact_config =0; if (kbd_config == KBD_DISABLED) kbd_tspact_config = KBD_DIS_TSPACT; // t2: Power ON TX *TP_Ptr++ = TPU_AT(TRF_T2); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_TX_ON), ((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))&0xFFFF))); // t3: put the TXM in RX mode *TP_Ptr++ = TPU_AT(TRF_T3); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].tx_down); // t3_1: disable keyboard *TP_Ptr++ = TPU_AT(TRF_T3_1); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config); // t4: enable the APC LDO *TP_Ptr++ = TPU_AT(TRF_T4); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN); // t5: enable the APC module *TP_Ptr++ = TPU_AT(TRF_T5); //SG *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN | APC_EN); // t6: enable TX start and enable of Vramp //SG*TP_Ptr++ = TPU_AT(TRF_T6); //SG *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN | APC_EN | TX_START | START_APC); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN | TX_START ); *TP_Ptr++ = TPU_AT(TRF_T6); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN | APC_EN | TX_START ); *TP_Ptr++ = TPU_AT(TRF_T7); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN | APC_EN | TX_START | START_APC); // t7: enable TX start and enable of Vramp - Internal mode //*TP_Ptr++ = TPU_AT(TRF_T7); //*TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN | APC_EN | TX_START | START_APC ); // t7: enable TX start and enable of Vramp //*TP_Ptr++ = TPU_AT(TRF_T7+4); //*TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN | APC_EN | TX_START ); // t8: enable the TXEN of the TXM *TP_Ptr++ = TPU_AT(TRF_T8); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].tx_up); } #endif /*(L1_RF_KBD_FIX == 1)*/ #if (L1_RF_KBD_FIX == 0) void l1dmacro_tx_up (void) { // t2: Power ON TX *TP_Ptr++ = TPU_AT(TRF_T2); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_TX_ON),((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))&0xFFFF))); // t3: put the TXM in RX mode *TP_Ptr++ = TPU_AT(TRF_T3); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].tx_down); // t4: enable the APC LDO *TP_Ptr++ = TPU_AT(TRF_T4); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN); // t5: enable the APC module *TP_Ptr++ = TPU_AT(TRF_T5); //SG *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN | APC_EN); // t6: enable TX start and enable of Vramp //SG*TP_Ptr++ = TPU_AT(TRF_T6); //SG *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN | APC_EN | TX_START | START_APC); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN | TX_START ); *TP_Ptr++ = TPU_AT(TRF_T6); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN | APC_EN | TX_START ); *TP_Ptr++ = TPU_AT(TRF_T7); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN | APC_EN | TX_START | START_APC); // t7: enable TX start and enable of Vramp - Internal mode //*TP_Ptr++ = TPU_AT(TRF_T7); //*TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN | APC_EN | TX_START | START_APC ); // t7: enable TX start and enable of Vramp //*TP_Ptr++ = TPU_AT(TRF_T7+4); //*TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, LDO_EN | APC_EN | TX_START ); // t8: enable the TXEN of the TXM *TP_Ptr++ = TPU_AT(TRF_T8); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].tx_up); } #endif /* (L1_RF_KBD_FIX == 0)*/ /*-------------------------------------------*/ /* l1dmacro_tx_down */ /*-------------------------------------------*/ /* Close transmission window for normal burst*/ /*-------------------------------------------*/ #if (L1_RF_KBD_FIX == 1) void l1dmacro_tx_down (WORD32 t, BOOL tx_flag, UWORD8 adc_active, UWORD8 kbd_config) { UWORD8 kbd_tspact_config =0; if (kbd_config == KBD_DISABLED) kbd_tspact_config = KBD_DIS_TSPACT; if (adc_active == ACTIVE) { // 36qbits = (10qbits for TPU programming) + (26qbits duration to convert the first ADC channel (= Battery)) if ((t)<(TRF_T8+2-TRF_T9)) //Done to enable RACH Burst Support { l1dmacro_adc_read_tx (TRF_T8+10, rf_path[rf_index].tx_up); } else { l1dmacro_adc_read_tx (t + TRF_T9, rf_path[rf_index].tx_up); } } // t10: disable APC *TP_Ptr++ = TPU_FAT (t + TRF_T10); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN | APC_EN | TX_START ); // t11: disable PA *TP_Ptr++ = TPU_FAT (t + TRF_T11); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].tx_down); // disable Tx_Start *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN | APC_EN ); // t12: power off Locosto: IDLE SCRIPT *TP_Ptr++ = TPU_FAT (t + TRF_T12); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_IDLE), ((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))&0xFFFF))); // t13: Switch off APC *TP_Ptr++ = TPU_FAT (t + TRF_T13); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, 0); } #endif /*(L1_RF_KBD_FIX == 1)*/ #if (L1_RF_KBD_FIX == 0) void l1dmacro_tx_down (WORD32 t, BOOL tx_flag, UWORD8 adc_active) { if (adc_active == ACTIVE) { // 36qbits = (10qbits for TPU programming) + (26qbits duration to convert the first ADC channel (= Battery)) l1dmacro_adc_read_tx (t + TRF_T9, rf_path[rf_index].tx_up); } // t10: disable APC *TP_Ptr++ = TPU_FAT (t + TRF_T10); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN | APC_EN | TX_START ); // t11: disable PA *TP_Ptr++ = TPU_FAT (t + TRF_T11); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, rf_path[rf_index].tx_down); // disable Tx_Start *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, kbd_tspact_config | LDO_EN | APC_EN ); // t12: power off Locosto: IDLE SCRIPT *TP_Ptr++ = TPU_FAT (t + TRF_T12); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_IDLE), (UWORD16)(&drp_regs->SCRIPT_STARTL)); // t13: Switch off APC *TP_Ptr++ = TPU_FAT (t + TRF_T13); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, 0); } #endif/*(L1_RF_KBD_FIX == 0)*/ /* * l1dmacro_rx_nb * * Receive Normal burst */ #if (L1_RF_KBD_FIX == 1) #if (L1_MADC_ON == 1) void l1dmacro_rx_nb (SYS_UWORD16 radio_freq, UWORD8 adc_active, UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { l1dmacro_rx_up(adc_active, csf_filter_choice, L1_KBD_DIS_RX_NB #if(NEW_SNR_THRESHOLD==1) , saic_flag_rx_up #endif ); l1dmacro_rx_down (STOP_RX_SNB); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_RX_NB * (-TRF_R3_1 + STOP_RX_SNB - TRF_R7); } #else void l1dmacro_rx_nb (SYS_UWORD16 radio_freq,UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { l1dmacro_rx_up(csf_filter_choice, L1_KBD_DIS_RX_NB #if(NEW_SNR_THRESHOLD==1) , saic_flag_rx_up #endif ); l1dmacro_rx_down (STOP_RX_SNB); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_RX_NB * (-TRF_R3_1 + STOP_RX_SNB - TRF_R7); } #endif #endif /*(L1_RF_KBD_FIX == 1)*/ #if (L1_RF_KBD_FIX == 0) #if (L1_MADC_ON == 1) void l1dmacro_rx_nb (SYS_UWORD16 radio_freq, UWORD8 adc_active, UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { l1dmacro_rx_up(adc_active, csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , saic_flag_rx_up #endif ); l1dmacro_rx_down (STOP_RX_SNB); } #else void l1dmacro_rx_nb (SYS_UWORD16 radio_freq,UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { l1dmacro_rx_up(csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , saic_flag_rx_up #endif ); l1dmacro_rx_down (STOP_RX_SNB); } #endif #endif/*(L1_RF_KBD_FIX == 0)*/ /* * l1dmacro_rx_sb * Receive Synchro burst */ #if (L1_RF_KBD_FIX == 1) #if (L1_MADC_ON == 1) void l1dmacro_rx_sb (SYS_UWORD16 radio_freq,UWORD8 adc_active) { l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_SB #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1dmacro_rx_down (STOP_RX_SB); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_RX_SB * (-TRF_R3_1 + STOP_RX_SB - TRF_R7); } #else void l1dmacro_rx_sb (SYS_UWORD16 radio_freq) { l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_SB #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1dmacro_rx_down (STOP_RX_SB); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_RX_SB * (-TRF_R3_1 + STOP_RX_SB - TRF_R7); } #endif #endif/*(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) #if (L1_MADC_ON == 1) void l1dmacro_rx_sb (SYS_UWORD16 radio_freq,UWORD8 adc_active) { l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1dmacro_rx_down (STOP_RX_SB); } #else void l1dmacro_rx_sb (SYS_UWORD16 radio_freq) { l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1dmacro_rx_down (STOP_RX_SB); } #endif #endif/*(L1_RF_KBD_FIX == 0)*/ /* * l1dmacro_rx_ms * * Receive Power Measurement window */ #if(L1_RF_KBD_FIX == 1) #if (L1_MADC_ON == 1) void l1dmacro_rx_ms (SYS_UWORD16 radio_freq,UWORD8 adc_active) { l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_MS #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1dmacro_rx_down (STOP_RX_PW_1); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_RX_MS * (-TRF_R3_1 + STOP_RX_PW_1 - TRF_R7); } #else void l1dmacro_rx_ms (SYS_UWORD16 radio_freq) { l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_MS #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1dmacro_rx_down (STOP_RX_PW_1); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_RX_MS * (-TRF_R3_1 + STOP_RX_PW_1 - TRF_R7); } #endif #endif/*(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) #if (L1_MADC_ON == 1) void l1dmacro_rx_ms (SYS_UWORD16 radio_freq,UWORD8 adc_active) { l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1dmacro_rx_down (STOP_RX_PW_1); } #else void l1dmacro_rx_ms (SYS_UWORD16 radio_freq) { l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1dmacro_rx_down (STOP_RX_PW_1); } #endif #endif/*(L1_RF_KBD_FIX == 0)*/ /* * l1dmacro_rx_fb * * Receive Frequency burst */ #if(L1_RF_KBD_FIX == 1) #if (L1_MADC_ON == 1) void l1dmacro_rx_fb (SYS_UWORD16 radio_freq,UWORD8 adc_active) #else void l1dmacro_rx_fb (SYS_UWORD16 radio_freq) #endif { #if (L1_MADC_ON == 1) l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_FB #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); #else l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_FB #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); #endif l1s.total_kbd_on_time = 5000; *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); l1dmacro_rx_down (STOP_RX_FB); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_RX_FB * (STOP_RX_FB - TRF_R7); } #endif/*(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) #if (L1_MADC_ON == 1) void l1dmacro_rx_fb (SYS_UWORD16 radio_freq,UWORD8 adc_active) #else void l1dmacro_rx_fb (SYS_UWORD16 radio_freq) #endif { #if (L1_MADC_ON == 1) l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); #else l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); #endif *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); *TP_Ptr++ = TPU_AT(0); l1dmacro_rx_down (STOP_RX_FB); } #endif/*(L1_RF_KBD_FIX == 0)*/ /* * l1dmacro_rx_fb26 * * Receive Frequency burst for TCH. */ #if(L1_RF_KBD_FIX == 1) #if (L1_MADC_ON == 1) void l1dmacro_rx_fb26 (SYS_UWORD16 radio_freq,UWORD8 adc_active) { l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_FB26 #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1s.total_kbd_on_time = 5000; *TP_Ptr++ = TPU_AT(0); l1dmacro_rx_down (STOP_RX_FB26); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_RX_FB26 * (STOP_RX_FB26 - TRF_R7); } #else void l1dmacro_rx_fb26 (SYS_UWORD16 radio_freq) { l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_FB26 #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); l1s.total_kbd_on_time = 5000; *TP_Ptr++ = TPU_AT(0); l1dmacro_rx_down (STOP_RX_FB26); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_RX_FB26 * (STOP_RX_FB26 - TRF_R7); } #endif #endif/*(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) #if (L1_MADC_ON == 1) void l1dmacro_rx_fb26 (SYS_UWORD16 radio_freq,UWORD8 adc_active) { l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); *TP_Ptr++ = TPU_AT(0); l1dmacro_rx_down (STOP_RX_FB26); } #else void l1dmacro_rx_fb26 (SYS_UWORD16 radio_freq) { l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); *TP_Ptr++ = TPU_AT(0); l1dmacro_rx_down (STOP_RX_FB26); } #endif #endif/*(L1_RF_KBD_FIX == 0)*/ /* * l1dmacro_tx_nb * * Transmit Normal burst */ #if(L1_RF_KBD_FIX == 1) void l1dmacro_tx_nb (SYS_UWORD16 radio_freq, UWORD8 txpwr, UWORD8 adc_active) { l1dmacro_tx_up (L1_KBD_DIS_TX_NB); l1dmacro_tx_down (l1_config.params.tx_nb_duration, FALSE, adc_active, L1_KBD_DIS_TX_NB); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_TX_NB * (-TRF_T3_1 + l1_config.params.tx_nb_duration + TRF_T12); } #endif/*#if(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) void l1dmacro_tx_nb (SYS_UWORD16 radio_freq, UWORD8 txpwr, UWORD8 adc_active) { l1dmacro_tx_up (); l1dmacro_tx_down (l1_config.params.tx_nb_duration, FALSE, adc_active); } #endif/*#if(L1_RF_KBD_FIX == 0)*/ /* * l1dmacro_tx_ra * * Transmit Random Access burst */ #if(L1_RF_KBD_FIX == 1) void l1dmacro_tx_ra (SYS_UWORD16 radio_freq, UWORD8 txpwr, UWORD8 adc_active) { l1dmacro_tx_up (L1_KBD_DIS_TX_RA); l1dmacro_tx_down (l1_config.params.tx_ra_duration, FALSE, adc_active, L1_KBD_DIS_TX_RA); l1s.total_kbd_on_time = l1s.total_kbd_on_time - L1_KBD_DIS_TX_RA * (-TRF_T3_1 + l1_config.params.tx_ra_duration + TRF_T12); } #endif /*#if(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) void l1dmacro_tx_ra (SYS_UWORD16 radio_freq, UWORD8 txpwr, UWORD8 adc_active) { l1dmacro_tx_up (); l1dmacro_tx_down (l1_config.params.tx_ra_duration, FALSE, adc_active); } #endif/*#if(L1_RF_KBD_FIX == 0)*/ /* * l1dmacro_rx_cont * * Receive continuously */ #if(L1_RF_KBD_FIX == 1) #if (L1_MADC_ON == 1) void l1dmacro_rx_cont (SYS_UWORD16 radio_freq, UWORD8 txpwr, UWORD8 adc_active, UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { l1dmacro_rx_up (adc_active, csf_filter_choice, KBD_DISABLED #if(NEW_SNR_THRESHOLD==1) , saic_flag_rx_up #endif ); } #else void l1dmacro_rx_cont (SYS_UWORD16 radio_freq, UWORD8 txpwr, UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { l1dmacro_rx_up (csf_filter_choice,KBD_DISABLED #if(NEW_SNR_THRESHOLD==1) , saic_flag_rx_up #endif ); } #endif #endif/*#if(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) #if (L1_MADC_ON == 1) void l1dmacro_rx_cont (SYS_UWORD16 radio_freq, UWORD8 txpwr, UWORD8 adc_active, UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { l1dmacro_rx_up (adc_active, csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , saic_flag_rx_up #endif ); } #else void l1dmacro_rx_cont (SYS_UWORD16 radio_freq, UWORD8 txpwr, UWORD8 csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , UWORD8 saic_flag_rx_up #endif ) { l1dmacro_rx_up (csf_filter_choice #if(NEW_SNR_THRESHOLD==1) , saic_flag_rx_up #endif ); } #endif #endif/*#if(L1_RF_KBD_FIX == 0)*/ /* * l1dmacro_tx_cont * * Transmit continuously */ #if(L1_RF_KBD_FIX == 1) void l1dmacro_tx_cont (SYS_UWORD16 radio_freq, UWORD8 txpwr) { l1dmacro_tx_up (KBD_DISABLED); } #endif/*#if(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) void l1dmacro_tx_cont (SYS_UWORD16 radio_freq, UWORD8 txpwr) { l1dmacro_tx_up (); } #endif/*#if(L1_RF_KBD_FIX == 0)*/ /* * l1d_macro_stop_cont * * Stop continuous Tx or Rx */ #if(L1_RF_KBD_FIX == 1) void l1dmacro_stop_cont (void) { if (l1_config.tmode.rf_params.down_up == TMODE_DOWNLINK) l1dmacro_rx_down(STOP_RX_SNB); else l1dmacro_tx_down(l1_config.params.tx_nb_duration, FALSE, 0, KBD_DISABLED); } #endif/*#if(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) void l1dmacro_stop_cont (void) { if (l1_config.tmode.rf_params.down_up == TMODE_DOWNLINK) l1dmacro_rx_down(STOP_RX_SNB); else l1dmacro_tx_down(l1_config.params.tx_nb_duration, FALSE, 0); } #endif/* */ /*------------------------------------------*/ /* l1dmacro_reset_hw */ /*------------------------------------------*/ /* Reset and set OFFSET register */ /*------------------------------------------*/ void l1dmacro_reset_hw(UWORD32 servingCellOffset) { TPU_Reset(1); // reset TPU only, no TSP reset TPU_Reset(0); TP_Ptr = (UWORD16 *) TPU_RAM; *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, TXM_SLEEP); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_L, TXM_SLEEP); MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_IDLE),((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))&0xFFFF))); *TP_Ptr++ = TPU_OFFSET(servingCellOffset); } // l1dmacro_RF_sleep // Program RF for BIG or DEEP sleep void l1dmacro_RF_sleep (void) { // sending REG_OFF script MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_REG_OFF), ((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))&0xFFFF))); *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, TXM_SLEEP); //Shutdown FEM *TP_Ptr++ = TPU_SLEEP; TP_Ptr = (SYS_UWORD16 *) TPU_RAM; TP_Enable(1); TPU_wait_idle(); } // l1dmacro_RF_wakeup //* wakeup RF from BIG or DEEP sleep void l1dmacro_RF_wakeup (void) { // sending REG_ON script MOVE_REG_TSP_TO_RF(START_SCRIPT(DRP_REG_ON), ((UWORD16)( ((UWORD32)(&drp_regs->SCRIPT_STARTL))&0xFFFF))); *TP_Ptr++ = TPU_SLEEP; TP_Ptr = (SYS_UWORD16 *) TPU_RAM; TP_Enable(1); TPU_wait_idle(); } // l1dmacro_init_hw // Reset VEGA, then remove reset // Init RF/IF synthesizers void l1dmacro_init_hw(void) { WORD32 t = 100; // start time for actions TP_Reset(1); // reset TPU and TSP // GSM 1.5 : TPU clock enable is in TPU //--------------------------------------- TPU_ClkEnable(1); // TPU CLOCK ON TP_Reset(0); TP_Ptr = (UWORD16 *) TPU_RAM; // Set FEM to inactive state before turning ON the RF Board // At this point the RF regulators are still OFF. Thus the // FEM command is not inverted yet => Must use the FEM "SLEEP programming" // TPU_SLEEP l1dmacro_idle(); *TP_Ptr++ = TPU_AT(t); *TP_Ptr++ = TPU_SYNC(0); //Check Initialisation or Reset for TPU2OCP *TP_Ptr++ = TPU_MOVE(REG_SPI_ACT_U, TXM_SLEEP); t = 1000; // arbitrary start time t = rf_init(t); // Initialize RF Board *TP_Ptr++ = TPU_AT(t); // TPU_SLEEP l1dmacro_idle(); return; } /*------------------------------------------*/ /* l1dmacro_init_hw_light */ /*------------------------------------------*/ /* Reset VEGA, then remove reset */ /* Init RF/IF synthesizers */ /*------------------------------------------*/ void l1dmacro_init_hw_light(void) { UWORD32 t = 100; // start time for actions // TP_Ptr = (SYS_UWORD16 *) TPU_RAM; // *TP_Ptr++ = TPU_AT(t); // t = 1000; // arbitrary start time // t = rf_init_light(t); // Initialize RF Board // *TP_Ptr++ = TPU_AT(t); // l1dmacro_idle(); // return; } //BHO added /* * l1dmacro_rx_fbsb * * Receive Frequency burst */ #if ((REL99 == 1) && (FF_BHO == 1)) #if(L1_RF_KBD_FIX == 1) #if (L1_MADC_ON == 1) void l1dmacro_rx_fbsb (SYS_UWORD16 radio_freq, UWORD8 adc_active) #else void l1dmacro_rx_fbsb (SYS_UWORD16 radio_freq) #endif { #if (L1_MADC_ON == 1) l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_FB #if(NEW_SNR_THRESHOLD==1) , SAIC_OFF #endif ); #else l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER, L1_KBD_DIS_RX_FB); #endif // same as rx_fb *TP_Ptr++ = TPU_AT(0); // 1 *TP_Ptr++ = TPU_AT(0); // 2 *TP_Ptr++ = TPU_AT(0); // 3 *TP_Ptr++ = TPU_AT(0); // 4 *TP_Ptr++ = TPU_AT(0); // 5 *TP_Ptr++ = TPU_AT(0); // 6 *TP_Ptr++ = TPU_AT(0); // 7 *TP_Ptr++ = TPU_AT(0); // 8 *TP_Ptr++ = TPU_AT(0); // 9 *TP_Ptr++ = TPU_AT(0); // 10 *TP_Ptr++ = TPU_AT(0); // 11 // one more for SB *TP_Ptr++ = TPU_AT(0); // 12 l1dmacro_rx_down (STOP_RX_FBSB); } #endif/*(L1_RF_KBD_FIX == 1)*/ #if(L1_RF_KBD_FIX == 0) #if (L1_MADC_ON == 1) void l1dmacro_rx_fbsb (SYS_UWORD16 radio_freq, UWORD8 adc_active) #else void l1dmacro_rx_fbsb (SYS_UWORD16 radio_freq) #endif { #if (L1_MADC_ON == 1) l1dmacro_rx_up(adc_active, L1_SAIC_HARDWARE_FILTER); #else l1dmacro_rx_up(L1_SAIC_HARDWARE_FILTER); #endif // same as rx_fb *TP_Ptr++ = TPU_AT(0); // 1 *TP_Ptr++ = TPU_AT(0); // 2 *TP_Ptr++ = TPU_AT(0); // 3 *TP_Ptr++ = TPU_AT(0); // 4 *TP_Ptr++ = TPU_AT(0); // 5 *TP_Ptr++ = TPU_AT(0); // 6 *TP_Ptr++ = TPU_AT(0); // 7 *TP_Ptr++ = TPU_AT(0); // 8 *TP_Ptr++ = TPU_AT(0); // 9 *TP_Ptr++ = TPU_AT(0); // 10 *TP_Ptr++ = TPU_AT(0); // 11 // one more for SB *TP_Ptr++ = TPU_AT(0); // 12 l1dmacro_rx_down (STOP_RX_FBSB); } #endif/*(L1_RF_KBD_FIX == 0)*/ #endif // #if ((REL99 == 1) && (FF_BHO == 1)) ////BHO