FreeCalypso > hg > freecalypso-sw
view gsm-fw/L1/tpudrv/tpudrv12.h @ 699:64745cdedf15
gsm-fw/g23m-gsm/cc/Makefile: link xipcode.o
author | Michael Spacefalcon <msokolov@ivan.Harhan.ORG> |
---|---|
date | Tue, 30 Sep 2014 02:26:35 +0000 |
parents | 47754cdb6248 |
children | 7f305eb3c530 |
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/****************** Revision Controle System Header *********************** * GSM Layer 1 software * Copyright (c) Texas Instruments 1998 * * Filename tpudrv12.h * Copyright 2003 (C) Texas Instruments * ****************** Revision Controle System Header ***********************/ //--- Configuration values #define FEM_TEST 0 // 1 => ENABLE the FEM_TEST mode #define RF_VERSION 1 // 1 or V1, 5 for V5, etc #define SAFE_INIT_WA 0 // 1 => ENABLE the "RITA safe init" // TeST - Enable Main VCO buffer for test #define MAIN_VCO_ACCESS_WA 0 // 1 => ENABLE the Main VCO buffer #if 0 // FreeCalypso #include "rf.cfg" #endif //--- RITA PG declaration #define R_PG_10 0 #define R_PG_13 1 #define R_PG_20 2 // For RFPG 2.2, use 2.0 #define R_PG_23 3 //--- PA declaration #define PA_MGF9009 0 #define PA_RF3146 1 #define PA_RF3133 2 #define PA_PF08123B 3 #define PA_AWT6108 4 #if (RF_PA == PA_MGF9009 || RF_PA == PA_PF08123B) #define PA_CTRL_INT 0 #else #define PA_CTRL_INT 1 #endif //- Select the RF PG (x10), i.e. 10 for 1.0, 11 for 1.1 or 20 for 2.0 // AlphaRF7 => "PG #1.3" for TPU purposes (not an official PC number) // This is also used in l1_rf12.h to select the SWAP_IQ #if (RF_PG >= R_PG_20) // TeST - PLL2 WA activation => Set PLL2 Speed-up ON in RX #define PLL2_WA 0 // 0 => DISABLE the PLL2_WA (Rene's "Work-Around") #define ALPHA_RF7_WA 0 // 0 => DISABLE the Alpha RF7 work-arounds #elif (RF_PG == R_PG_13) // TeST - PLL2 WA activation => Set PLL2 Speed-up ON in RX #define PLL2_WA 1 // 1 => ENABLE the PLL2_WA (Rene's "Work-Around") #define ALPHA_RF7_WA 1 // 1 => ENABLE the Alpha RF7 work-arounds #else // TeST - PLL2 WA activation => Set PLL2 Speed-up ON in RX #define PLL2_WA 1 // 1 => ENABLE the PLL2_WA (Rene's "Work-Around") #define ALPHA_RF7_WA 1 // 1 => ENABLE the Alpha RF7 work-arounds #endif //- Bit definitions for TST register programings, etc #define BIT_0 0x000001 #define BIT_1 0x000002 #define BIT_2 0x000004 #define BIT_3 0x000008 #define BIT_4 0x000010 #define BIT_5 0x000020 #define BIT_6 0x000040 #define BIT_7 0x000080 #define BIT_8 0x000100 #define BIT_9 0x000200 #define BIT_10 0x000400 #define BIT_11 0x000800 #define BIT_12 0x001000 #define BIT_13 0x002000 #define BIT_14 0x004000 #define BIT_15 0x008000 #define BIT_16 0x010000 #define BIT_17 0x020000 #define BIT_18 0x040000 #define BIT_19 0x080000 #define BIT_20 0x100000 #define BIT_21 0x200000 #define BIT_22 0x400000 #define BIT_23 0x800000 //--- TRF6151 definitions ------------------------------------------ //- BASE REGISTER definitions #define REG_RX 0x000000 // MODE0 #define REG_PLL 0x000001 // MODE1 #define REG_PWR 0x000002 // MODE2 #define REG_CFG 0x000003 // MODE3 //- TeST REGISTER definitions => Used for WA only // TeST - PLL2 WA => Define PLL2 TEST register #define TST_PLL2 0x00001E // MODE 14 // TeST - Enable Main VCO buffer for test => Define TST_VCO3 register #define TST_VCO3 0x00000F // MODE 15 (0*16+15*1) #define TST_VCO4 0x000024 // MODE 36 (2*16+4*1) // Alpha RF7 WA TeST registers #define TST_LDO 0x000027 // MODE 39 (2*16+7*1) #define TST_PLL1 0x00001D // MODE 29 (1*16+13*1) #define TST_TX2 0x000037 // MODE 55 (3*16+7*1) // More Alpha RF7 WA TeST registers #define TST_TX3 0x00003C // MODE 61 (3*16+12*1) #define TST_TX4 0x00003D // MODE 61 (3*16+13*1) // PG 2.1 WA TeST registers #define TST_PLL3 0x00001F // MODE 31 (1*16+15*1) // #define TST_PLL4 0x00002C // MODE 44 (2*16+12*1) #define TST_MISC 0x00003E // MODE 62 (3*16+14*1) => Used for setting the VCXO current #define TST_LO 0x00001C // MODE 28 (1*16+12*1) // Registers used to improve the Modulation Spectrum in DCS/PCS for PG2.1 V1 // UPDATE_SERIAL_REGISTER_COPY is a "dummy addres" that, // when accessed, triggers the copy of the serial registers. // This is necessary to switch into "manual operation mode" #define UPDATE_SERIAL_INTERFACE_COPY 0x000007 #define TX_LOOP_MANUAL BIT_3 //- REG_RX - MODE0 #define BLOCK_DETECT_0 BIT_3 #define BLOCK_DETECT_1 BIT_4 #define RST_BLOCK_DETECT_0 BIT_5 #define RST_BLOCK_DETECT_1 BIT_6 #define READ_EN BIT_7 #define RX_CAL_MODE BIT_8 #define RF_GAIN (BIT_10 | BIT_9) //- REG_PLL - MODE1 //PLL_REGB //PLL_REGA //- REG_PWR - MODE2 #define BANDGAP_MODE_OFF 0x0 #define BANDGAP_MODE_ON_ENA BIT_4 #define BANDGAP_MODE_ON_DIS (BIT_4 | BIT_3) #define REGUL_MODE_ON BIT_5 // BIT[8..6] band #define BAND_SELECT_GSM BIT_6 #define BAND_SELECT_DCS BIT_7 #define BAND_SELECT_850_LO BIT_8 #define BAND_SELECT_850_HI (BIT_8 | BIT_6) #define BAND_SELECT_PCS (BIT_8 | BIT_7) #define SYNTHE_MODE_OFF 0x0 #define SYNTHE_MODE_RX BIT_9 #define SYNTHE_MODE_TX BIT_10 #define RX_MODE_OFF 0x0 #define RX_MODE_A BIT_11 #define RX_MODE_B1 BIT_12 #define RX_MODE_B2 (BIT_12 | BIT_11) #define TX_MODE_OFF 0x0 #define TX_MODE_ON BIT_13 #define PACTRL_APC_OFF 0x0 #define PACTRL_APC_ON BIT_14 #define PACTRL_APC_DIS 0x0 #define PACTRL_APC_ENA BIT_15 //- REG_CFG - MODE3 // Common PA controller settings: #define PACTRL_TYPE_PWR 0x0 #define PACTRL_TYPE_CUR BIT_3 #define PACTRL_IDIOD_30_UA 0x0 #define PACTRL_IDIOD_300_UA BIT_4 // PA controller Clara-like (Power Sensing) settings: #define PACTRL_VHOME_610_MV (BIT_7 | BIT_5) #define PACTRL_VHOME_839_MV (BIT_7 | BIT_5) #define PACTRL_VHOME_1000_MV (BIT_6 | BIT_9) #define PACTRL_VHOME_1600_MV (BIT_8 | BIT_5) #define PACTRL_RES_OPEN 0x0 #define PACTRL_RES_150_K BIT_10 #define PACTRL_RES_300_K BIT_11 #define PACTRL_RES_NU (BIT_10 | BIT_11) #define PACTRL_CAP_0_PF 0x0 #define PACTRL_CAP_12_5_PF BIT_12 #define PACTRL_CAP_25_PF (BIT_13 | BIT_12) #define PACTRL_CAP_50_PF BIT_13 // PACTRL_CFG contains the configuration of the PACTRL that will // be put into the REG_CFG register at initialization time // WARNING - Do not forget to set the PACTRL_TYPE (PWR or CUR) // in this #define!!! #if (RF_PA == 0) // MGF9009 (LCPA) #define PACTRL_CFG \ PACTRL_IDIOD_300_UA | \ PACTRL_CAP_25_PF | \ PACTRL_VHOME_1000_MV | \ PACTRL_RES_300_K #elif (RF_PA == 1) // 3146 #define PACTRL_CFG 0 #elif (RF_PA == 2) // 3133 #define PACTRL_CFG 0 #elif (RF_PA == 3) // PF08123B #define PACTRL_CFG \ PACTRL_TYPE_PWR | \ PACTRL_CAP_50_PF | \ PACTRL_RES_300_K | \ PACTRL_VHOME_610_MV #elif (RF_PA == 4) // AWT6108 #define PACTRL_CFG 0 #else #error Unknown PA specifiec! #endif // Temperature sensor #define TEMP_SENSOR_OFF 0x0 #define TEMP_SENSOR_ON BIT_14 // Internal Logic Init Disable #define ILOGIC_INIT_DIS BIT_15 // ILOGIC_INIT_DIS must be ALWAYS set when programming the REG_CFG register // It was introduced in PG 1.2 // For previous PGs this BIT was unused, so it can be safelly programmed // for all PGs // RF signals connected to TSPACT [0..7] //#define RESET_RF BIT_0 // act0 #define RF_SER_ON BIT_0 // act0 #define RF_SER_OFF 0 #if (FEM_TEST==1) //for test #define TEST_TX_ON BIT_2 // act2 #define TEST_RX_ON BIT_3 // act3 //3-band config (D-sample) #define FEM_1 BIT_1 // act1 #define FEM_2 0 //BIT_2 // act2 #define FEM_3 0 //BIT_3 // act3 #elif (BOARD == 42 || BOARD == 43 || BOARD == 35 || (BOARD == 41 && (RF_PA == 0 || RF_PA == 1 || RF_PA == 2 || RF_PA == 4))) // ESample, P2, Leonardo #define TEST_TX_ON 0 #define TEST_RX_ON 0 // 4-band config (E-sample, P2, Leonardo) #define FEM_7 BIT_2 // act2 #define FEM_8 BIT_1 // act1 #define FEM_9 BIT_4 // act4 #if (RF_PA == 0) // LCPA for ES, P2 and Leo #define PA_HI_BAND BIT_3 // act3 #define PA_LO_BAND 0 #define PA_OFF 0 #elif (RF_PA == 1) // RF3146 for ES and Leonardo #define PA_HI_BAND BIT_3 // act3 #define PA_LO_BAND 0 #define PA_OFF 0 #elif (RF_PA == 2) // RF3133 for P2 and Leonardo #define PA_HI_BAND BIT_3 // act3 #define PA_LO_BAND 0 #define PA_OFF 0 #elif (RF_PA == 4) // AWT6108 for Leonardo #define PA_HI_BAND BIT_3 // act3 #define PA_LO_BAND 0 #define PA_OFF 0 #else #error "RF_PA not correctly defined" #endif #else // DSample + EVARITA #if (RF_PA != 3) // Hitachi for EVARITA #error #endif //#define TEST_RX_ON 0 //#define TEST_TX_ON BIT_3 // act3 #define TEST_TX_ON 0 #define TEST_RX_ON BIT_3 // act3 //3-band config (D-sample) #define FEM_1 BIT_1 // act1 #define FEM_2 BIT_2 // act2 #define FEM_3 BIT_3 // act3 #endif #if (BOARD == 42 || BOARD == 43 || BOARD == 35 || (BOARD == 41 && (RF_PA == 0 || RF_PA == 1 || RF_PA == 2 || RF_PA == 4))) // ESample, P2, Leonardo #define FEM_PINS (FEM_7 | FEM_8 | FEM_9) #define FEM_OFF ( FEM_PINS ^ 0 ) #define FEM_SLEEP ( 0 ) // This configuration is always inverted. // 4-band config // RX_UP/DOWN and TX_UP/DOWN #define RU_900 ( PA_OFF | FEM_PINS ^ 0 ) #define RD_900 ( PA_OFF | FEM_PINS ^ 0 ) #define TU_900 ( PA_LO_BAND | FEM_PINS ^ FEM_9 ) #define TD_900 ( PA_OFF | FEM_PINS ^ 0 ) #define RU_850 ( PA_LO_BAND | FEM_PINS ^ 0 ) #define RD_850 ( PA_OFF | FEM_PINS ^ 0 ) #define TU_850 ( PA_LO_BAND | FEM_PINS ^ FEM_9 ) #define TD_850 ( PA_OFF | FEM_PINS ^ 0 ) #define RU_1800 ( PA_OFF | FEM_PINS ^ 0 ) #define RD_1800 ( PA_OFF | FEM_PINS ^ 0 ) #define TU_1800 ( PA_HI_BAND | FEM_PINS ^ FEM_7 ) #define TD_1800 ( PA_OFF | FEM_PINS ^ 0 ) #define RU_1900 ( PA_LO_BAND | FEM_PINS ^ FEM_8 ) #define RD_1900 ( PA_OFF | FEM_PINS ^ 0 ) #define TU_1900 ( PA_HI_BAND | FEM_PINS ^ FEM_7 ) #define TD_1900 ( PA_OFF | FEM_PINS ^ 0 ) #else // end BOARD = 43 // start RF HW interfacing with EVARITA #define FEM_OFF (FEM_1 | FEM_2) #define FEM_SLEEP (0) // To avoid leakage during Deep-Seep // 3-band config // RX_UP/DOWN and TX_UP/DOWN #define RU_900 ( FEM_1 | FEM_2 ) #define RD_900 ( FEM_1 | FEM_2 ) #define TU_900 ( FEM_1 ) #define TD_900 ( FEM_1 | FEM_2 ) #define RU_850 ( FEM_1 | FEM_2 ) #define RD_850 ( FEM_1 | FEM_2 ) #define TU_850 ( FEM_1 ) #define TD_850 ( FEM_1 | FEM_2 ) #define RU_1800 ( FEM_1 | FEM_2 ) #define RD_1800 ( FEM_1 | FEM_2 ) #define TU_1800 ( FEM_2 ) #define TD_1800 ( FEM_1 | FEM_2 ) #define RU_1900 ( FEM_1 | FEM_2 ) #define RD_1900 ( FEM_1 | FEM_2 ) #define TU_1900 ( FEM_2) #define TD_1900 ( FEM_1 | FEM_2 ) #endif // BOARD != 43 #define TC1_DEVICE_ABB TC1_DEVICE0 // TSPEN0 #define TC1_DEVICE_RF TC1_DEVICE2 // TSPEN2 //--- TIMINGS ---------------------------------------------------------- /*------------------------------------------*/ /* Download delay values */ /*------------------------------------------*/ // 1 qbit = 12/13 usec (~0.9230769), i.e. 200 usec is ~ 217 qbit (200 * 13 / 12) #define T TPU_CLOCK_RANGE // - TPU instruction into TSP timings --- // 1 tpu instruction = 1 qbit #define DLT_1 1 // 1 tpu instruction = 1 qbit #define DLT_2 2 // 2 tpu instruction = 2 qbit #define DLT_3 3 // 3 tpu instruction = 3 qbit #define DLT_4 4 // 4 tpu instruction = 4 qbit #define SL_SU_DELAY2 DLT_3 // Needed to compile with old l1_rf12 // - Serialization timings --- // The following values where calculated with Katrin Matthes... //#define SL_7 3 // To send 7 bits to the ABB, 14*T (1/6.5MHz) are needed, // // i.e. 14 / 6 qbit = 2.333 ~ 3 qbit //#define SL_2B 6 // To send 2 bytes to the RF, 34*T (1/6.5MHz) are needed, // // i.e. 34 / 6 qbit = 5.7 ~ 6 qbit // ... while the following values are based on the HYP004.doc document #define SL_7 2 // To send 7 bits to the ABB, 12*T (1/6.5MHz) are needed, // i.e. 12 / 6 qbit = 2 qbit #define SL_2B 4 // To send 2 bytes to the RF, 21*T (1/6.5MHz) are needed, // i.e. 21 / 6 qbit = 3.5 ~ 4 qbit // - TPU command execution + serialization length --- #define DLT_1B 4 // 3*move + serialization of 7 bits #define DLT_2B 7 // 4*move + serialization of 2 bytes //#define DLT_1B DLT_3 + SL_7 // 3*move + serialization of 7 bits //#define DLT_2B DLT_4 + SL_2B // 4*move + serialization of 2 bytes // - INIT (delta or DLT) timings --- #define DLT_I1 5 // Time required to set EN high before RF_SER_OFF -> RF_SER_ON #define DLT_I2 8 // Time required to set RF_SER_OFF #define DLT_I3 5 // Time required to set RF_SER_ON #define DLT_I4 110 // Regulator Turn-ON time // - tdt & rdt --- // MAX GSM (not GPRS) rdt and tdt values are... //#define rdt 380 // MAX GSM rx delta timing //#define tdt 400 // MAX GSM tx delta timing // but current rdt and tdt values are... #define rdt 0 // rx delta timing #define tdt 0 // tx delta timing // - RX timings --- // - RX down: // The times below are offsets to when BDLENA goes down #define TRF_R10 ( 0 - DLT_1B ) // disable BDLENA & BDLON -> power DOWN ABB (end of RX burst), needs DLT_1B to execute #define TRF_R9 ( - 30 - DLT_2B ) // disable RF SWITCH, power DOWN Rita (go to Idle2 mode) // - RX up: // The times below are offsets to when BDLENA goes high // Burst data comes here #define TRF_R8 ( PROVISION_TIME - 0 - DLT_1B ) // enable BDLENA, disable BDLCAL (I/Q comes 32qbit later) #define TRF_R7 ( PROVISION_TIME - 7 - DLT_1 ) // enable RF SWITCH #define TRF_R6 ( PROVISION_TIME - 67 - DLT_1B ) // enable BDLCAL -> ABB DL filter init #define TRF_R5 ( PROVISION_TIME - 72 - DLT_1B ) // enable BDLON -> power ON ABB DL path #define TRF_R4 ( PROVISION_TIME - 76 - DLT_2B - rdt ) // power ON RX #define TRF_R3 (PROVISION_TIME - 143 - DLT_2B - rdt ) // select the AGC & LNA gains + start DC offset calibration (stops automatically) //l1dmacro_adc_read_rx() called here requires ~ 16 tpuinst #define TRF_R2 (PROVISION_TIME - 198 - DLT_2B - rdt ) // set BAND + power ON RX Synth #define TRF_R1 (PROVISION_TIME - 208 - DLT_2B - rdt ) // set RX Synth channel // - TX timings --- // - TX down: // The times below are offsets to when BULENA goes down #if (PA_CTRL_INT == 1) #define TRF_T13 ( 35 - DLT_1B ) // right after, BULON low #define TRF_T12_5 ( 32 - DLT_2B ) // Power OFF TX loop => power down RF. #define TRF_T12_3 ( 23 - DLT_1 ) // Disable TXEN. #endif #if (PA_CTRL_INT == 0) #define TRF_T13 ( 35 - DLT_1B ) // right after, BULON low #define TRF_T12_2 ( 32 - DLT_2B ) // power down RF step 2 #define TRF_T12 ( 18 - DLT_2B ) // power down RF step 1 #endif #define TRF_T11 ( 0 - DLT_1B ) // disable BULENA -> end of TX burst #define TRF_T10_5 ( - 40 - DLT_1B ) // ADC read // - TX up: // The times below are offsets to when BULENA goes high //burst data comes here #define TRF_T10_4 ( 22 - DLT_1 ) // enable RF SWITCH + TXEN #define TRF_T10 ( 17 - DLT_1 ) // enable RF SWITCH #if (PA_CTRL_INT == 0) #define TRF_T9 ( 8 - DLT_2B ) // enable PACTRL #endif #define TRF_T8 ( - 0 - DLT_1B ) // enable BULENA -> start of TX burst #define TRF_T7 ( - 50 - DLT_1B - tdt ) // disable BULCAL -> stop ABB UL calibration #define TRF_T6 ( - 130 - DLT_1B - tdt ) // enable BULCAL -> start ABB UL calibration #define TRF_T5 ( - 158 - DLT_2B - tdt ) // power ON TX #define TRF_T4 ( - 190 - DLT_1B - tdt ) // enable BULON -> power ON ABB UL path // TRF_T3_MAN_1, TRF_T3_MAN_2 & TRF_T3_MAN_3 are only executed in DCS for PG 2.0 and above #define TRF_T3_MAN_3 ( - 239 - DLT_2B - tdt ) // PG2.1: Set the right TX loop charge pump current for DCS & PCS #define TRF_T3_MAN_2 ( - 249 - DLT_2B - tdt ) // PG2.1: Go into "TX Manual mode" #define TRF_T3_MAN_1 ( - 259 - DLT_2B - tdt ) // PG2.1: IN DCS, use manual mode: Copy Serial Interface Registers for "Manual operation" #define TRF_T3 ( - 259 - DLT_2B - tdt ) // PG2.1: In GSM & PCS go to "Automatic TX mode" #define TRF_T2 ( - 269 - DLT_2B - tdt ) // PG2.0: set BAND + Power ON Main TX PLL + PACTRL ON #define TRF_T1 ( - 279 - DLT_2B - tdt ) // set TX Main PLL channel