/** * \file talise_config.c * \brief Contains Talise configuration settings for the Talise API * * Copyright 2015-2017 Analog Devices Inc. * Released under the AD9378-AD9379 API license, for more information see the "LICENSE.txt" file in this zip file. * * The top level structure taliseDevice_t talDevice uses keyword * extern to allow the application layer main() to have visibility * to these settings. * * This file may not be fully complete for the end user application and * may need to updated for AGC, GPIO, and DAC full scale settings. * To create a full initialisation routine, the user should also refer to the * Iron Python initialisation routine generated by the GUI, and also the Talise User Guide. * */ #include "talise_types.h" #include "talise_config.h" #include "talise_error.h" #include "talise_agc.h" #ifdef ADI_ZYNQ_PLATFORM #include "zynq_platform.h" #endif int16_t txFirCoefs[20] = {-3, 9, -28, 69, -131, 246, -507, 1182, -2648, 19449, -2648, 1182, -507, 246, -131, 69, -28, 9, -3, 0}; int16_t obsrxFirCoefs[24] = {-118, -553, 395, 960, -868, -1855, 1717, 3340, -3525, -6850, 8901, 30982, 30982, 8901, -6850, -3525, 3340, 1717, -1855, -868, 960, 395, -553, -118}; #ifdef ADI_ZYNQ_PLATFORM /** < Insert Customer Platform HAL State Container here>*/ /* * Platform Layer SPI settings - this structure is specific to ADI's platform layer code. * User should replace with their own structure or settings for their hardware */ zynqSpiSettings_t spiDev1 = { .chipSelectIndex = 1, .writeBitPolarity = 0, .longInstructionWord = 1, .CPHA = 0, .CPOL = 0, .mode = 0, .spiClkFreq_Hz = 25000000 }; /* * Platform Layer settings - this structure is specific to ADI's platform layer code. * User should replace with their own structure or settings for their hardware * The structure is held in taliseDevice_t below as a void pointer, allowing * the customer to pass any information for their specific hardware down to the * hardware layer code. */ zynqAdiDev_t talDevHalInfo = { .devIndex = 1, .spiSettings = &spiDev1, .spiErrCode = 0, .timerErrCode = 0, .gpioErrCode = 0, .logLevel = ADIHAL_LOG_ALL }; #endif /** * TalDevice a structure used by the Talise API to hold the platform hardware * structure information, as well as an internal Talise API state container * (devStateInfo) of runtime information used by the API. **/ taliseDevice_t talDevice = { #ifdef ADI_ZYNQ_PLATFORM /* Void pointer of users platform HAL settings to pass to HAL layer calls * Talise API does not use the devHalInfo member */ .devHalInfo = &talDevHalInfo, #else .devHalInfo = NULL, /*/** < Insert Customer Platform HAL State Container here>*/ #endif /* devStateInfo is maintained internal to the Talise API, just create the memory */ .devStateInfo = {0} }; taliseInit_t talInit = { /* SPI settings */ .spiSettings = { .MSBFirst = 1, /* 1 = MSBFirst, 0 = LSBFirst */ .enSpiStreaming = 0, /* Not implemented in ADIs platform layer. SW feature to improve SPI throughput */ .autoIncAddrUp = 1, /* Not implemented in ADIs platform layer. For SPI Streaming, set address increment direction. 1= next addr = addr+1, 0:addr=addr-1 */ .fourWireMode = 1, /* 1: Use 4-wire SPI, 0: 3-wire SPI (SDIO pin is bidirectional). NOTE: ADI's FPGA platform always uses 4-wire mode */ .cmosPadDrvStrength = TAL_CMOSPAD_DRV_2X /* Drive strength of CMOS pads when used as outputs (SDIO, SDO, GP_INTERRUPT, GPIO 1, GPIO 0) */ }, /* Tx settings */ .tx = { .txProfile = { .dacDiv = 1, /* The divider used to generate the DAC clock */ .txFir = { .gain_dB = 0, /* filter gain */ .numFirCoefs = 20, /* number of coefficients in the FIR filter */ .coefs = &txFirCoefs[0] }, .txFirInterpolation = 1, /* The Tx digital FIR filter interpolation (1,2,4) */ .thb1Interpolation = 2, /* Tx Halfband1 filter interpolation (1,2) */ .thb2Interpolation = 2, /* Tx Halfband2 filter interpolation (1,2)*/ .thb3Interpolation = 1, /* Tx Halfband3 filter interpolation (1,2)*/ .txInt5Interpolation = 1, /* Tx Int5 filter interpolation (1,5) */ .txInputRate_kHz = 491520, /* Primary Signal BW */ .primarySigBandwidth_Hz = 200000000, /* The Rx RF passband bandwidth for the profile */ .rfBandwidth_Hz = 450000000, /* The Tx RF passband bandwidth for the profile */ .txDac3dBCorner_kHz = 450000, /* The DAC filter 3dB corner in kHz */ .txBbf3dBCorner_kHz = 225000, /* The BBF 3dB corner in kHz */ .loopBackAdcProfile = {150, 178, 181, 90, 1280, 1338, 1699, 493, 1386, 162, 934, 4, 48, 46, 35, 201, 0, 0, 0, 0, 50, 0, 0, 6, 24, 0, 0, 6, 24, 0, 25, 27, 0, 0, 25, 27, 0, 0, 165, 44, 15, 905} }, .deframerSel = TAL_DEFRAMER_A, /* Talise JESD204b deframer config for the Tx data path */ .txChannels = TAL_TX1TX2, /* The desired Tx channels to enable during initialization */ .txAttenStepSize = TAL_TXATTEN_0P05_DB, /* Tx Attenuation step size */ .tx1Atten_mdB = 0, /* Initial Tx1 Attenuation */ .tx2Atten_mdB = 0, /* Initial Tx2 Attenuation */ .disTxDataIfPllUnlock = TAL_TXDIS_TX_RAMP_DOWN_TO_ZERO /* Options to disable the transmit data when the RFPLL unlocks. */ }, /* ObsRx settings */ .obsRx = { .orxProfile = { .rxFir = { .gain_dB = -6, /* filter gain */ .numFirCoefs = 24, /* number of coefficients in the FIR filter */ .coefs = &obsrxFirCoefs[0] }, .rxFirDecimation = 1, /* Rx FIR decimation (1,2,4) */ .rxDec5Decimation = 4, /* Decimation of Dec5 or Dec4 filter (5,4) */ .rhb1Decimation = 1, /* RX Half band 1 decimation (1 or 2) */ .orxOutputRate_kHz = 491520, /* Rx IQ data rate in kHz */ .rfBandwidth_Hz = 450000000, /* The Rx RF passband bandwidth for the profile */ .rxBbf3dBCorner_kHz = 225000, /* Rx BBF 3dB corner in kHz */ .orxLowPassAdcProfile = {155, 163, 181, 90, 1280, 1254, 1572, 340, 1431, 142, 973, 8, 48, 47, 36, 205, 0, 0, 0, 0, 51, 0, 0, 6, 24, 0, 0, 6, 24, 0, 25, 27, 0, 0, 25, 27, 0, 0, 165, 44, 15, 905}, .orxBandPassAdcProfile = {124, 131, 154, 90, 1280, 2779, 1986, 0, 1037, 839, 988, 109, 11, 15, 28, 179, 0, 0, 0, 0, 45, 0, 0, 0, 24, 0, 0, 0, 24, 0, 25, 27, 0, 0, 25, 27, 0, 0, 165, 44, 15, 905}, .orxDdcMode = TAL_ORXDDC_DISABLED, /* ORx DDC mode */ .orxMergeFilter = {-167, 419, -208, -498, 968, -320, -1273, 2154, -402, -4155, 9170, 21413} }, .orxGainCtrl = { .gainMode = TAL_MGC, .orx1GainIndex = 255, .orx2GainIndex = 255, .orx1MaxGainIndex = 255, .orx1MinGainIndex = 195, .orx2MaxGainIndex = 255, .orx2MinGainIndex = 195 }, .framerSel = TAL_FRAMER_B, /* ObsRx JESD204b framer configuration */ .obsRxChannelsEnable = TAL_ORX1, /* The desired ObsRx Channels to enable during initialization */ .obsRxLoSource = TAL_OBSLO_RF_PLL /* The ORx mixers can use the TX_PLL */ }, /* Digital Clock Settings */ .clocks = { .deviceClock_kHz = 245760, /* CLKPLL and device reference clock frequency in kHz */ .clkPllVcoFreq_kHz = 9830400, /* CLKPLL VCO frequency in kHz */ .clkPllHsDiv = TAL_HSDIV_2P5, /* CLKPLL high speed clock divider */ .rfPllUseExternalLo = 0, /* 1= Use external LO for RF PLL, 0 = use internal LO generation for RF PLL */ .rfPllPhaseSyncMode = TAL_RFPLLMCS_INIT_AND_CONTTRACK /* RFPLL MCS (Phase sync) mode */ }, /* JESD204B settings */ .jesd204Settings = { /* Framer B settings */ .framerB = { .bankId = 0, /* JESD204B Configuration Bank ID -extension to Device ID (Valid 0..15) */ .deviceId = 0, /* JESD204B Configuration Device ID - link identification number. (Valid 0..255) */ .lane0Id = 0, /* JESD204B Configuration starting Lane ID. If more than one lane used, each lane will increment from the Lane0 ID. (Valid 0..31) */ .M = 2, /* number of ADCs (0, 2, or 4) - 2 ADCs per receive chain */ .K = 32, /* number of frames in a multiframe (default=32), F*K must be a multiple of 4. (F=2*M/numberOfLanes) */ .F = 2, /* F (number of bytes per frame) */ .Np = 16, /* Np (converter sample resolution) */ .scramble = 1, /* scrambling off if framerScramble= 0, if framerScramble>0 scramble is enabled. */ .externalSysref = 1, /* 0=use internal SYSREF, 1= use external SYSREF */ .serializerLanesEnabled = 0x0C, /* serializerLanesEnabled - bit per lane, [0] = Lane0 enabled, [1] = Lane1 enabled */ .serializerLaneCrossbar = 0xE4, /* serializerLaneCrossbar */ .lmfcOffset = 31, /* lmfcOffset - LMFC offset value for deterministic latency setting */ .newSysrefOnRelink = 0, /* newSysrefOnRelink */ .syncbInSelect = 1, /* syncbInSelect; */ .overSample = 0, /* 1=overSample, 0=bitRepeat */ .syncbInLvdsMode = 1, .syncbInLvdsPnInvert = 0, .enableManualLaneXbar = 0 /* 0=auto, 1=manual */ }, /* Framer A settings */ .framerA = { .bankId = 0, /* JESD204B Configuration Bank ID -extension to Device ID (Valid 0..15) */ .deviceId = 0, /* JESD204B Configuration Device ID - link identification number. (Valid 0..255) */ .lane0Id = 0, /* JESD204B Configuration starting Lane ID. If more than one lane used, each lane will increment from the Lane0 ID. (Valid 0..31) */ .M = 2, /* number of ADCs (0, 2, or 4) - 2 ADCs per receive chain */ .K = 32, /* number of frames in a multiframe (default=32), F*K must be a multiple of 4. (F=2*M/numberOfLanes) */ .F = 0, /* F (number of bytes per frame) */ .Np = 16, /* Np (converter sample resolution) */ .scramble = 1, /* scrambling off if framerScramble= 0, if framerScramble>0 scramble is enabled. */ .externalSysref = 1, /* 0=use internal SYSREF, 1= use external SYSREF */ .serializerLanesEnabled = 0x03, /* serializerLanesEnabled - bit per lane, [0] = Lane0 enabled, [1] = Lane1 enabled */ .serializerLaneCrossbar = 0xE4, /* serializerLaneCrossbar */ .lmfcOffset = 31, /* lmfcOffset - LMFC offset value for deterministic latency setting */ .newSysrefOnRelink = 0, /* newSysrefOnRelink */ .syncbInSelect = 1, /* syncbInSelect; */ .overSample = 0, /* 1=overSample, 0=bitRepeat */ .syncbInLvdsMode = 1, .syncbInLvdsPnInvert = 0, .enableManualLaneXbar = 0 /* 0=auto, 1=manual */ }, /* Deframer A settings */ .deframerA = { .bankId = 0, /* bankId extension to Device ID (Valid 0..15) */ .deviceId = 0, /* deviceId link identification number. (Valid 0..255) */ .lane0Id = 0, /* lane0Id Lane0 ID. (Valid 0..31) */ .M = 4, /* M number of DACss (0, 2, or 4) - 2 DACs per transmit chain */ .K = 32, /* K #frames in a multiframe (default=32), F*K=multiple of 4. (F=2*M/numberOfLanes) */ .scramble = 1, /* scramble scrambling off if scramble= 0 */ .externalSysref = 1, /* externalSysref 0= use internal SYSREF, 1= external SYSREF */ .deserializerLanesEnabled = 0x0F, /* deserializerLanesEnabled bit per lane, [0] = Lane0 enabled */ .deserializerLaneCrossbar = 0xE4, /* deserializerLaneCrossbar */ .lmfcOffset = 17, /* lmfcOffset LMFC offset value to adjust deterministic latency */ .newSysrefOnRelink = 0, /* newSysrefOnRelink */ .syncbOutSelect = 0, /* SYNCBOUT0/1 select */ .Np = 16, /* Np (converter sample resolution) */ .syncbOutLvdsMode = 1, .syncbOutLvdsPnInvert = 0, .syncbOutCmosSlewRate = 0, .syncbOutCmosDriveLevel = 0, .enableManualLaneXbar = 0 /* 0=auto, 1=manual */ }, /* Deframer B settings */ .deframerB = { .bankId = 0, /* bankId extension to Device ID (Valid 0..15) */ .deviceId = 0, /* deviceId link identification number. (Valid 0..255) */ .lane0Id = 0, /* lane0Id Lane0 ID. (Valid 0..31) */ .M = 0, /* M number of DACss (0, 2, or 4) - 2 DACs per transmit chain */ .K = 32, /* K #frames in a multiframe (default=32), F*K=multiple of 4. (F=2*M/numberOfLanes) */ .scramble = 1, /* scramble scrambling off if scramble= 0 */ .externalSysref = 1, /* externalSysref 0= use internal SYSREF, 1= external SYSREF */ .deserializerLanesEnabled = 0x00, /* deserializerLanesEnabled bit per lane, [0] = Lane0 enabled */ .deserializerLaneCrossbar = 0xE4, /* deserializerLaneCrossbar */ .lmfcOffset = 0, /* lmfcOffset LMFC offset value to adjust deterministic latency */ .newSysrefOnRelink = 0, /* newSysrefOnRelink */ .syncbOutSelect = 1, /* SYNCBOUT0/1 select */ .Np = 16, /* Np (converter sample resolution) */ .syncbOutLvdsMode = 1, .syncbOutLvdsPnInvert = 0, .syncbOutCmosSlewRate = 0, .syncbOutCmosDriveLevel = 0, .enableManualLaneXbar = 0 /* 0=auto, 1=manual */ }, .serAmplitude = 15, /* Serializer amplitude setting. Default = 15. Range is 0..15 */ .serPreEmphasis = 1, /* Serializer pre-emphasis setting. Default = 1 Range is 0..4 */ .serInvertLanePolarity = 0, /* Serializer Lane PN inversion select. Default = 0. Where, bit[0] = 1 will invert lane [0], bit[1] = 1 will invert lane 1, etc. */ .desInvertLanePolarity = 0, /* Deserializer Lane PN inversion select. bit[0] = 1 Invert PN of Lane 0, bit[1] = Invert PN of Lane 1, etc */ .desEqSetting = 1, /* Deserializer Equalizer setting. Applied to all deserializer lanes. Range is 0..4 */ .sysrefLvdsMode = 1, /* Use LVDS inputs on Talise for SYSREF */ .sysrefLvdsPnInvert = 0 /*0= Do not PN invert SYSREF */ } }; //Only needs to be called if user wants to setup AGC parameters static taliseAgcCfg_t rxAgcCtrl = { 4, 255, 195, 255, 195, 30720, /* AGC gain update time in us (125us-250us - based on IQ data rate - set for 125us @ 245.76 Mhz) */ 10, 10, 16, 0, 1, 0, 0, 0, 1, 31, 246, 4, 1, /*!<1- bit field to enable the multiple time constants in AGC loop for fast attack and fast recovery to max gain. */ /* agcPower */ { 1, /*!<1-bit field, enables the Rx power measurement block. */ 1, /*!<1-bit field, allows using Rx PFIR for power measurement. */ 0, /*!<1-bit field, allows to use the output of the second digital offset block in the Rx datapath for power measurement. */ 9, /*!