File content as of revision 85:4ca74d007fe7:

/**
  ******************************************************************************
  * @file    SPIRIT_Management.c
  * @author  VMA division - AMS
  * @version 3.2.2
  * @date    08-July-2015
  * @brief   The management layer for SPIRIT1 library.
  * @details
  *
  * @attention
  *
  * <h2><center>&copy; COPYRIGHT(c) 2015 STMicroelectronics</center></h2>
  *
  * Redistribution and use in source and binary forms, with or without modification,
  * are permitted provided that the following conditions are met:
  *   1. Redistributions of source code must retain the above copyright notice,
  *      this list of conditions and the following disclaimer.
  *   2. Redistributions in binary form must reproduce the above copyright notice,
  *      this list of conditions and the following disclaimer in the documentation
  *      and/or other materials provided with the distribution.
  *   3. Neither the name of STMicroelectronics nor the names of its contributors
  *      may be used to endorse or promote products derived from this software
  *      without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
  * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
  * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
  * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
  * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  *
  ******************************************************************************
  */

/* Includes ------------------------------------------------------------------*/
#include "SPIRIT_Management.h"

/**
* @addtogroup SPIRIT_Libraries
* @{
*/


/**
* @defgroup SPIRIT_MANAGEMENT              SPIRIT Management
* @{
*/



//180619 HJM : init 재시작을 위한 카운팅 변수
static int iSpiritManagementErrorCounting = 0;
#define MAX_ERROR_COUNTING  3
#define RETURN_ERROR_NUMBER     100


/**
* @brief  BS value to write in the SYNT0 register according to the selected band
*/
static const uint8_t s_vectcBandRegValue[4]={SYNT0_BS_6, SYNT0_BS_12, SYNT0_BS_16, SYNT0_BS_32};

#define COMMUNICATION_STATE_TX          0
#define COMMUNICATION_STATE_RX          1
#define COMMUNICATION_STATE_NONE        2

static uint32_t s_nDesiredFrequency;

static volatile uint8_t s_cCommunicationState = COMMUNICATION_STATE_NONE;


/**
* @brief  Factor is: B/2 used in the formula for SYNTH word calculation
*/
static const uint8_t s_vectcBHalfFactor[4]={(HIGH_BAND_FACTOR/2), (MIDDLE_BAND_FACTOR/2), (LOW_BAND_FACTOR/2), (VERY_LOW_BAND_FACTOR/2)};


/**
* @defgroup SPIRIT_MANAGEMENT_FUNCTIONS    SPIRIT Management Functions
* @{
*/


/**
* @defgroup WORKAROUND_FUNCTIONS              SPIRIT Management Workaround Functions
* @{
*/

/**
* @brief  Private SpiritRadioSetFrequencyBase function only used in SpiritManagementWaVcoCalibration.
* @param  lFBase the base carrier frequency expressed in Hz as unsigned word.
* @retval None.
*/
int SpiritManagementSetFrequencyBase(uint32_t lFBase)
{
  uint32_t synthWord, Fc;
  uint8_t band = 0, anaRadioRegArray[4], wcp;
  
  int iRet = 0; 
  
  /* Check the parameter */
  iRet = s_assert_param(IS_FREQUENCY_BAND(lFBase));
  if (RETURN_ERROR_NUMBER == iRet)
  {
    return RETURN_ERROR_NUMBER;
    }
  
  /* Search the operating band */
  if(IS_FREQUENCY_BAND_HIGH(lFBase))
  {
    band = HIGH_BAND;
  }
  else if(IS_FREQUENCY_BAND_MIDDLE(lFBase))
  {
    band = MIDDLE_BAND;
  }
  else if(IS_FREQUENCY_BAND_LOW(lFBase))
  {
    band = LOW_BAND;
  }
  else if(IS_FREQUENCY_BAND_VERY_LOW(lFBase))
  {
    band = VERY_LOW_BAND;
  }
  
  int32_t FOffset  = SpiritRadioGetFrequencyOffset();
  uint32_t lChannelSpace  = SpiritRadioGetChannelSpace();
  uint8_t cChannelNum = SpiritRadioGetChannel();
  
  /* Calculates the channel center frequency */
  Fc = lFBase + FOffset + lChannelSpace*cChannelNum;
  //180619 HJM : 여기까지는 spirit1 의 상태값을 그냥 한번만 spi 통신으로 읽어와 저장함.
  
  
  
  
  
  
  
  /* Reads the reference divider */
  uint8_t cRefDiv = (uint8_t)SpiritRadioGetRefDiv()+1;
  
  switch(band)
  {
  case VERY_LOW_BAND:
    if(Fc<161281250)
    {
      SpiritCalibrationSelectVco(VCO_L);
    }
    else
    {
      SpiritCalibrationSelectVco(VCO_H);
    }
    break;
    
  case LOW_BAND:
    if(Fc<322562500)
    {
      SpiritCalibrationSelectVco(VCO_L);
    }
    else
    {
      SpiritCalibrationSelectVco(VCO_H);
    }
    break;
    
  case MIDDLE_BAND:
    if(Fc<430083334)
    {
      SpiritCalibrationSelectVco(VCO_L);
    }
    else
    {
      SpiritCalibrationSelectVco(VCO_H);
    }
    break;
    
  case HIGH_BAND:
    if(Fc<860166667)
    {
      SpiritCalibrationSelectVco(VCO_L);
    }
    else
    {
      SpiritCalibrationSelectVco(VCO_H);
    }
  }
  
  /* Search the VCO charge pump word and set the corresponding register */
  wcp = SpiritRadioSearchWCP(Fc);
  
  synthWord = (uint32_t)(lFBase*(((double)(FBASE_DIVIDER*cRefDiv*s_vectcBHalfFactor[band]))/SpiritRadioGetXtalFrequency()));
  
  /* Build the array of registers values for the analog part */
  anaRadioRegArray[0] = (uint8_t)(((synthWord>>21)&(0x0000001F))|(wcp<<5));
  anaRadioRegArray[1] = (uint8_t)((synthWord>>13)&(0x000000FF));
  anaRadioRegArray[2] = (uint8_t)((synthWord>>5)&(0x000000FF));
  anaRadioRegArray[3] = (uint8_t)(((synthWord&0x0000001F)<<3)| s_vectcBandRegValue[band]);
  
  /* Configures the needed Analog Radio registers */
  g_xStatus = SpiritSpiWriteRegisters(SYNT3_BASE, 4, anaRadioRegArray);
  
  return 0;
}

uint8_t SpiritManagementWaVcoCalibration(void)
{
  uint8_t s_cVcoWordRx;
  uint8_t s_cVcoWordTx;
  uint32_t nFreq;
  uint8_t cRestore = 0;
  uint8_t cStandby = 0;
  uint32_t xtal_frequency = SpiritRadioGetXtalFrequency();
  
  int iRet = 0;
  
  /* Enable the reference divider if the XTAL is between 48 and 52 MHz */
  if(xtal_frequency>DOUBLE_XTAL_THR)
  {
    if(!SpiritRadioGetRefDiv())
    {
      cRestore = 1;
      nFreq = SpiritRadioGetFrequencyBase();
      SpiritRadioSetRefDiv(S_ENABLE);
      //180621 HJM : 여기(아래) 수정함
      iRet = SpiritManagementSetFrequencyBase(nFreq);
      if (RETURN_ERROR_NUMBER == iRet)
      {
          return RETURN_ERROR_NUMBER;
        }
    }
  }
  nFreq = SpiritRadioGetFrequencyBase();
  
  /* Increase the VCO current */
  uint8_t tmp = 0x19; SpiritSpiWriteRegisters(0xA1,1,&tmp);
  
  SpiritCalibrationVco(S_ENABLE);
  
  SpiritRefreshStatus();
  printf("test 9-3 g_xStatus.MC_STATE : [0x%02X] \n", g_xStatus.MC_STATE);
  if(g_xStatus.MC_STATE == MC_STATE_STANDBY)
  {
    cStandby = 1;
    SpiritCmdStrobeReady();
    printf("test 9-3 1 g_xStatus.MC_STATE : [0x%02X] \n", g_xStatus.MC_STATE);    
    do
    {
      SpiritRefreshStatus();
      printf("test 9-3 2 g_xStatus.MC_STATE : [0x%02X]\n", g_xStatus.MC_STATE);      
      if(g_xStatus.MC_STATE == 0x13)
      {
        return 1;
      }
      
    ++iSpiritManagementErrorCounting;    
    if (iSpiritManagementErrorCounting >= MAX_ERROR_COUNTING)
    {
        iSpiritManagementErrorCounting = 0;
        return RETURN_ERROR_NUMBER;
    }
      
    }while(g_xStatus.MC_STATE != MC_STATE_READY); 
  }
  iSpiritManagementErrorCounting = 0;
  
  
  
  
  
  SpiritCmdStrobeLockTx();
  printf("test 9-4 g_xStatus.MC_STATE : [0x%02X] \n", g_xStatus.MC_STATE);
  do
  {
    SpiritRefreshStatus();
    printf("test 9-4 1 g_xStatus.MC_STATE : [0x%02X] \n", g_xStatus.MC_STATE);
    if(g_xStatus.MC_STATE == 0x13)
    {
      return 1;
    }
    
    ++iSpiritManagementErrorCounting;    
    if (iSpiritManagementErrorCounting >= MAX_ERROR_COUNTING)
    {
        iSpiritManagementErrorCounting = 0;
        return RETURN_ERROR_NUMBER;
    }
    
  }while(g_xStatus.MC_STATE != MC_STATE_LOCK);
  iSpiritManagementErrorCounting = 0;
  
  
  
  
  
  s_cVcoWordTx = SpiritCalibrationGetVcoCalData();
  
  SpiritCmdStrobeReady();
  printf("test 9-5 g_xStatus.MC_STATE : [0x%02X] \n", g_xStatus.MC_STATE);
  do{
    SpiritRefreshStatus();
    
    ++iSpiritManagementErrorCounting;    
    if (iSpiritManagementErrorCounting >= MAX_ERROR_COUNTING)
    {
        iSpiritManagementErrorCounting = 0;
//        reset_board();
        return RETURN_ERROR_NUMBER;
    }    
    
  }while(g_xStatus.MC_STATE != MC_STATE_READY); 
  iSpiritManagementErrorCounting = 0;
  
    
  SpiritCmdStrobeLockRx();
  
  do{
    SpiritRefreshStatus();
    if(g_xStatus.MC_STATE == 0x13)
    {
      return 1;
    }
    
    ++iSpiritManagementErrorCounting;    
    if (iSpiritManagementErrorCounting >= MAX_ERROR_COUNTING)
    {
        iSpiritManagementErrorCounting = 0;
        return RETURN_ERROR_NUMBER;
    }
    
  }while(g_xStatus.MC_STATE != MC_STATE_LOCK);
  iSpiritManagementErrorCounting = 0;
  
  s_cVcoWordRx = SpiritCalibrationGetVcoCalData();
  
  SpiritCmdStrobeReady();
  
  do
  {
    SpiritRefreshStatus();
    if(g_xStatus.MC_STATE == 0x13)
    {
      return 1;
    }
    
    ++iSpiritManagementErrorCounting;    
    if (iSpiritManagementErrorCounting >= MAX_ERROR_COUNTING)
    {
        iSpiritManagementErrorCounting = 0;
        return RETURN_ERROR_NUMBER;
    }
    
  }while(g_xStatus.MC_STATE != MC_STATE_READY);
  iSpiritManagementErrorCounting = 0;
  
  
  if(cStandby == 1)
  {
    SpiritCmdStrobeStandby();    
  }
  SpiritCalibrationVco(S_DISABLE);
  
  /* Disable the reference divider if the XTAL is between 48 and 52 MHz */
  if(cRestore)
  {
    SpiritRadioSetRefDiv(S_DISABLE);    
    //180621 HJM : 여기(아래) 수정함    
    iRet = SpiritManagementSetFrequencyBase(nFreq);
      if (RETURN_ERROR_NUMBER == iRet)
      {
          return RETURN_ERROR_NUMBER;
        }
  }
  
  /* Restore the VCO current */
  tmp = 0x11; SpiritSpiWriteRegisters(0xA1,1,&tmp);
  
  SpiritCalibrationSetVcoCalDataTx(s_cVcoWordTx);
  SpiritCalibrationSetVcoCalDataRx(s_cVcoWordRx);
  
  return 0;
}


void SpiritManagementWaCmdStrobeTx(void)
{
  if(s_cCommunicationState != COMMUNICATION_STATE_TX)
  {
    //uint32_t xtal_frequency = SpiritRadioGetXtalFrequency();
    
    /* To achive the max output power */
    if(s_nDesiredFrequency>=150000000 && s_nDesiredFrequency<=470000000)
    {
      /* Optimal setting for Tx mode only */
      SpiritRadioSetPACwc(LOAD_3_6_PF);
    }
    else
    {
      /* Optimal setting for Tx mode only */
      SpiritRadioSetPACwc(LOAD_0_PF);
    }
    
    uint8_t tmp = 0x11; SpiritSpiWriteRegisters(0xa9, 1, &tmp); /* Enable VCO_L buffer */
    tmp = 0x20; SpiritSpiWriteRegisters(PM_CONFIG1_BASE, 1, &tmp); /* Set SMPS switching frequency */
    
    s_cCommunicationState = COMMUNICATION_STATE_TX;
  }
}


void SpiritManagementWaCmdStrobeRx(void)
{
  if(s_cCommunicationState != COMMUNICATION_STATE_RX)
  {    
    uint8_t tmp = 0x98; SpiritSpiWriteRegisters(PM_CONFIG1_BASE, 1, &tmp); /* Set SMPS switching frequency */    
    SpiritRadioSetPACwc(LOAD_0_PF); /* Set the correct CWC parameter */
    
    s_cCommunicationState = COMMUNICATION_STATE_RX;
  }
}

void SpiritManagementWaTRxFcMem(uint32_t nDesiredFreq)
{
  s_cCommunicationState = COMMUNICATION_STATE_NONE;
  s_nDesiredFrequency = nDesiredFreq;
}


void SpiritManagementWaExtraCurrent(void)
{          
  uint8_t tmp= 0xCA;SpiritSpiWriteRegisters(0xB2, 1, &tmp); 
  tmp= 0x04;SpiritSpiWriteRegisters(0xA8, 1, &tmp); 
  /* just a read to loose some microsecs more */
  SpiritSpiReadRegisters(0xA8, 1, &tmp);
  tmp= 0x00;SpiritSpiWriteRegisters(0xA8, 1, &tmp); 
}

/**
* @}
*/



/**
* @}
*/


/**
* @}
*/

/**
* @}
*/


/******************* (C) COPYRIGHT 2015 STMicroelectronics *****END OF FILE****/