Vergil Cola
Fork of my original MQTTGateway
Diff: easy-connect/stm-spirit1-rf-driver/source/libs/spirit1/SPIRIT1_Library/Src/SPIRIT_Radio.c
- Revision:
- 0:a1734fe1ec4b
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/easy-connect/stm-spirit1-rf-driver/source/libs/spirit1/SPIRIT1_Library/Src/SPIRIT_Radio.c Sat Apr 08 14:43:14 2017 +0000
@@ -0,0 +1,3144 @@
+/**
+ ******************************************************************************
+ * @file SPIRIT_Radio.c
+ * @author VMA division - AMS
+ * @version 3.2.2
+ * @date 08-July-2015
+ * @brief This file provides all the low level API to manage Analog and Digital
+ * radio part of SPIRIT.
+ * @details
+ *
+ * @attention
+ *
+ * <h2><center>© 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_Radio.h"
+#include "MCU_Interface.h"
+#include <math.h>
+
+/** @addtogroup SPIRIT_Libraries
+* @{
+*/
+
+
+/** @addtogroup SPIRIT_Radio
+* @{
+*/
+
+
+/** @defgroup Radio_Private_TypesDefinitions Radio Private Types Definitions
+* @{
+*/
+
+
+/**
+* @}
+*/
+
+
+/** @defgroup Radio_Private_Defines Radio Private Defines
+* @{
+*/
+
+
+
+
+/**
+* @}
+*/
+
+
+/** @defgroup Radio_Private_Macros Radio Private Macros
+* @{
+*/
+#define XTAL_FLAG(xtalFrequency) (xtalFrequency>=25e6) ? XTAL_FLAG_26_MHz:XTAL_FLAG_24_MHz
+
+#define ROUND(A) (((A-(uint32_t)A)> 0.5)? (uint32_t)A+1:(uint32_t)A)
+/**
+* @}
+*/
+
+
+/** @defgroup Radio_Private_Variables Radio Private Variables
+* @{
+*/
+/**
+* @brief The Xtal frequency. To be set by the user (see SetXtalFreq() function)
+*/
+static uint32_t s_lXtalFrequency;
+
+/**
+* @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)};
+
+/**
+* @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};
+
+
+/**
+* @brief It represents the available channel bandwidth times 10 for 26 Mhz xtal.
+* @note The channel bandwidth for others xtal frequencies can be computed since this table
+* multiplying the current table by a factor xtal_frequency/26e6.
+*/
+static const uint16_t s_vectnBandwidth26M[90]=
+{
+ 8001, 7951, 7684, 7368, 7051, 6709, 6423, 5867, 5414, \
+ 4509, 4259, 4032, 3808, 3621, 3417, 3254, 2945, 2703, \
+ 2247, 2124, 2015, 1900, 1807, 1706, 1624, 1471, 1350, \
+ 1123, 1062, 1005, 950, 903, 853, 812, 735, 675, \
+ 561, 530, 502, 474, 451, 426, 406, 367, 337, \
+ 280, 265, 251, 237, 226, 213, 203, 184, 169, \
+ 140, 133, 126, 119, 113, 106, 101, 92, 84, \
+ 70, 66, 63, 59, 56, 53, 51, 46, 42, \
+ 35, 33, 31, 30, 28, 27, 25, 23, 21, \
+ 18, 17, 16, 15, 14, 13, 13, 12, 11
+};
+
+/**
+* @brief It represents the available VCO frequencies
+*/
+static const uint16_t s_vectnVCOFreq[16]=
+{
+ 4644, 4708, 4772, 4836, 4902, 4966, 5030, 5095, \
+ 5161, 5232, 5303, 5375, 5448, 5519, 5592, 5663
+};
+
+/**
+* @brief This variable is used to enable or disable
+* the VCO calibration WA called at the end of the SpiritRadioSetFrequencyBase fcn.
+* Default is enabled.
+*/
+static SpiritFunctionalState xDoVcoCalibrationWA=S_ENABLE;
+
+
+/**
+* @brief These values are used to interpolate the power curves.
+* Interpolation curves are linear in the following 3 regions:
+* - reg value: 1 to 13 (up region)
+* - reg value: 13 to 40 (mid region)
+* - reg value: 41 to 90 (low region)
+* power_reg = m*power_dBm + q
+* For each band the order is: {m-up, q-up, m-mid, q-mid, m-low, q-low}.
+* @note The power interpolation curves have been extracted
+* by measurements done on the divisional evaluation boards.
+*/
+static const float fPowerFactors[5][6]={
+ {-2.11,25.66,-2.11,25.66,-2.00,31.28}, /* 915 */
+ {-2.04,23.45,-2.04,23.45,-1.95,27.66}, /* 868 */
+ {-3.48,38.45,-1.89,27.66,-1.92,30.23}, /* 433 */
+ {-3.27,35.43,-1.80,26.31,-1.89,29.61}, /* 315 */
+ {-4.18,50.66,-1.80,30.04,-1.86,32.22}, /* 169 */
+};
+
+/**
+* @}
+*/
+
+
+/** @defgroup Radio_Private_FunctionPrototypes Radio Private Function Prototypes
+* @{
+*/
+
+
+/**
+* @}
+*/
+
+
+/** @defgroup Radio_Private_Functions Radio Private Functions
+* @{
+*/
+
+/**
+* @brief Initializes the SPIRIT analog and digital radio part according to the specified
+* parameters in the pxSRadioInitStruct.
+* @param pxSRadioInitStruct pointer to a SRadioInit structure that
+* contains the configuration information for the analog radio part of SPIRIT.
+* @retval Error code: 0=no error, 1=error during calibration of VCO.
+*/
+uint8_t SpiritRadioInit(SRadioInit* pxSRadioInitStruct)
+{
+ int32_t FOffsetTmp;
+ uint8_t anaRadioRegArray[8], digRadioRegArray[4];
+ int16_t xtalOffsetFactor;
+ uint8_t drM, drE, FdevM, FdevE, bwM, bwE;
+
+ /* Workaround for Vtune */
+ uint8_t value = 0xA0; SpiritSpiWriteRegisters(0x9F, 1, &value);
+
+ /* Calculates the offset respect to RF frequency and according to xtal_ppm parameter: (xtal_ppm*FBase)/10^6 */
+ FOffsetTmp = (int32_t)(((float)pxSRadioInitStruct->nXtalOffsetPpm*pxSRadioInitStruct->lFrequencyBase)/PPM_FACTOR);
+
+ /* Check the parameters */
+ s_assert_param(IS_FREQUENCY_BAND(pxSRadioInitStruct->lFrequencyBase));
+ s_assert_param(IS_MODULATION_SELECTED(pxSRadioInitStruct->xModulationSelect));
+ s_assert_param(IS_DATARATE(pxSRadioInitStruct->lDatarate));
+ s_assert_param(IS_FREQUENCY_OFFSET(FOffsetTmp,s_lXtalFrequency));
+ s_assert_param(IS_CHANNEL_SPACE(pxSRadioInitStruct->nChannelSpace,s_lXtalFrequency));
+ s_assert_param(IS_F_DEV(pxSRadioInitStruct->lFreqDev,s_lXtalFrequency));
+
+ /* Disable the digital, ADC, SMPS reference clock divider if fXO>24MHz or fXO<26MHz */
+ SpiritSpiCommandStrobes(COMMAND_STANDBY);
+ do{
+ /* Delay for state transition */
+ for(volatile uint8_t i=0; i!=0xFF; i++);
+
+ /* Reads the MC_STATUS register */
+ SpiritRefreshStatus();
+ }while(g_xStatus.MC_STATE!=MC_STATE_STANDBY);
+
+ if(s_lXtalFrequency<DOUBLE_XTAL_THR)
+ {
+ SpiritRadioSetDigDiv(S_DISABLE);
+ s_assert_param(IS_CH_BW(pxSRadioInitStruct->lBandwidth,s_lXtalFrequency));
+ }
+ else
+ {
+ SpiritRadioSetDigDiv(S_ENABLE);
+ s_assert_param(IS_CH_BW(pxSRadioInitStruct->lBandwidth,(s_lXtalFrequency>>1)));
+ }
+
+ /* Goes in READY state */
+ SpiritSpiCommandStrobes(COMMAND_READY);
+ do{
+ /* Delay for state transition */
+ for(volatile uint8_t i=0; i!=0xFF; i++);
+
+ /* Reads the MC_STATUS register */
+ SpiritRefreshStatus();
+ }while(g_xStatus.MC_STATE!=MC_STATE_READY);
+
+ /* Calculates the FC_OFFSET parameter and cast as signed int: FOffsetTmp = (Fxtal/2^18)*FC_OFFSET */
+ xtalOffsetFactor = (int16_t)(((float)FOffsetTmp*FBASE_DIVIDER)/s_lXtalFrequency);
+ anaRadioRegArray[2] = (uint8_t)((((uint16_t)xtalOffsetFactor)>>8)&0x0F);
+ anaRadioRegArray[3] = (uint8_t)(xtalOffsetFactor);
+
+ /* Calculates the channel space factor */
+ anaRadioRegArray[0] =((uint32_t)pxSRadioInitStruct->nChannelSpace<<9)/(s_lXtalFrequency>>6)+1;
+
+ SpiritManagementWaTRxFcMem(pxSRadioInitStruct->lFrequencyBase);
+
+ /* 2nd order DEM algorithm enabling */
+ uint8_t tmpreg; SpiritSpiReadRegisters(0xA3, 1, &tmpreg);
+ tmpreg &= ~0x02; SpiritSpiWriteRegisters(0xA3, 1, &tmpreg);
+
+ /* Check the channel center frequency is in one of the possible range */
+ s_assert_param(IS_FREQUENCY_BAND((pxSRadioInitStruct->lFrequencyBase + ((xtalOffsetFactor*s_lXtalFrequency)/FBASE_DIVIDER) + pxSRadioInitStruct->nChannelSpace * pxSRadioInitStruct->cChannelNumber)));
+
+ /* Calculates the datarate mantissa and exponent */
+ SpiritRadioSearchDatarateME(pxSRadioInitStruct->lDatarate, &drM, &drE);
+ digRadioRegArray[0] = (uint8_t)(drM);
+ digRadioRegArray[1] = (uint8_t)(0x00 | pxSRadioInitStruct->xModulationSelect |drE);
+
+ /* Read the fdev register to preserve the clock recovery algo bit */
+ SpiritSpiReadRegisters(0x1C, 1, &tmpreg);
+
+ /* Calculates the frequency deviation mantissa and exponent */
+ SpiritRadioSearchFreqDevME(pxSRadioInitStruct->lFreqDev, &FdevM, &FdevE);
+ digRadioRegArray[2] = (uint8_t)((FdevE<<4) | (tmpreg&0x08) | FdevM);
+
+ /* Calculates the channel filter mantissa and exponent */
+ SpiritRadioSearchChannelBwME(pxSRadioInitStruct->lBandwidth, &bwM, &bwE);
+
+ digRadioRegArray[3] = (uint8_t)((bwM<<4) | bwE);
+
+ float if_off=(3.0*480140)/(s_lXtalFrequency>>12)-64;
+
+ uint8_t ifOffsetAna = ROUND(if_off);
+
+ if(s_lXtalFrequency<DOUBLE_XTAL_THR)
+ {
+ /* if offset digital is the same in case of single xtal */
+ anaRadioRegArray[1] = ifOffsetAna;
+ }
+ else
+ {
+ if_off=(3.0*480140)/(s_lXtalFrequency>>13)-64;
+
+ /* ... otherwise recompute it */
+ anaRadioRegArray[1] = ROUND(if_off);
+ }
+// if(s_lXtalFrequency==24000000) {
+// ifOffsetAna = 0xB6;
+// anaRadioRegArray[1] = 0xB6;
+// }
+// if(s_lXtalFrequency==25000000) {
+// ifOffsetAna = 0xAC;
+// anaRadioRegArray[1] = 0xAC;
+// }
+// if(s_lXtalFrequency==26000000) {
+// ifOffsetAna = 0xA3;
+// anaRadioRegArray[1] = 0xA3;
+// }
+// if(s_lXtalFrequency==48000000) {
+// ifOffsetAna = 0x3B;
+// anaRadioRegArray[1] = 0xB6;
+// }
+// if(s_lXtalFrequency==50000000) {
+// ifOffsetAna = 0x36;
+// anaRadioRegArray[1] = 0xAC;
+// }
+// if(s_lXtalFrequency==52000000) {
+// ifOffsetAna = 0x31;
+// anaRadioRegArray[1] = 0xA3;
+// }
+
+ g_xStatus = SpiritSpiWriteRegisters(IF_OFFSET_ANA_BASE, 1, &ifOffsetAna);
+
+
+ /* Sets Xtal configuration */
+ if(s_lXtalFrequency>DOUBLE_XTAL_THR)
+ {
+ SpiritRadioSetXtalFlag(XTAL_FLAG((s_lXtalFrequency/2)));
+ }
+ else
+ {
+ SpiritRadioSetXtalFlag(XTAL_FLAG(s_lXtalFrequency));
+ }
+
+ /* Sets the channel number in the corresponding register */
+ SpiritSpiWriteRegisters(CHNUM_BASE, 1, &pxSRadioInitStruct->cChannelNumber);
+
+ /* Configures the Analog Radio registers */
+ SpiritSpiWriteRegisters(CHSPACE_BASE, 4, anaRadioRegArray);
+
+ /* Configures the Digital Radio registers */
+ g_xStatus = SpiritSpiWriteRegisters(MOD1_BASE, 4, digRadioRegArray);
+
+ /* Enable the freeze option of the AFC on the SYNC word */
+ SpiritRadioAFCFreezeOnSync(S_ENABLE);
+
+ /* Set the IQC correction optimal value */
+ anaRadioRegArray[0]=0x80;
+ anaRadioRegArray[1]=0xE3;
+ g_xStatus = SpiritSpiWriteRegisters(0x99, 2, anaRadioRegArray);
+
+ return SpiritRadioSetFrequencyBase(pxSRadioInitStruct->lFrequencyBase);
+
+}
+
+
+/**
+* @brief Returns the SPIRIT analog and digital radio structure according to the registers value.
+* @param pxSRadioInitStruct pointer to a SRadioInit structure that
+* contains the configuration information for the analog radio part of SPIRIT.
+* @retval None.
+*/
+void SpiritRadioGetInfo(SRadioInit* pxSRadioInitStruct)
+{
+ uint8_t anaRadioRegArray[8], digRadioRegArray[4];
+ BandSelect band;
+ int16_t xtalOffsetFactor;
+
+ /* Get the RF board version */
+ //SpiritVersion xSpiritVersion = SpiritGeneralGetSpiritVersion();
+
+ /* Reads the Analog Radio registers */
+ SpiritSpiReadRegisters(SYNT3_BASE, 8, anaRadioRegArray);
+
+ /* Reads the Digital Radio registers */
+ g_xStatus = SpiritSpiReadRegisters(MOD1_BASE, 4, digRadioRegArray);
+
+ /* Reads the operating band masking the Band selected field */
+ if((anaRadioRegArray[3] & 0x07) == SYNT0_BS_6)
+ {
+ band = HIGH_BAND;
+ }
+ else if ((anaRadioRegArray[3] & 0x07) == SYNT0_BS_12)
+ {
+ band = MIDDLE_BAND;
+ }
+ else if ((anaRadioRegArray[3] & 0x07) == SYNT0_BS_16)
+ {
+ band = LOW_BAND;
+ }
+ else if ((anaRadioRegArray[3] & 0x07) == SYNT0_BS_32)
+ {
+ band = VERY_LOW_BAND;
+ }
+ else
+ {
+ /* if it is another value, set it to a valid one in order to avoid access violation */
+ uint8_t tmp=(anaRadioRegArray[3]&0xF8)|SYNT0_BS_6;
+ SpiritSpiWriteRegisters(SYNT0_BASE,1,&tmp);
+ band = HIGH_BAND;
+ }
+
+ /* Computes the synth word */
+ uint32_t synthWord = (uint32_t)((((uint32_t)(anaRadioRegArray[0]&0x1F))<<21)+(((uint32_t)(anaRadioRegArray[1]))<<13)+\
+ (((uint32_t)(anaRadioRegArray[2]))<<5)+(((uint32_t)(anaRadioRegArray[3]))>>3));
+
+ /* Calculates the frequency base */
+ uint8_t cRefDiv = (uint8_t)SpiritRadioGetRefDiv()+1;
+ pxSRadioInitStruct->lFrequencyBase = (uint32_t)round(synthWord*(((double)s_lXtalFrequency)/(FBASE_DIVIDER*cRefDiv*s_vectcBHalfFactor[band])));
+
+ /* Calculates the Offset Factor */
+ uint16_t xtalOffTemp = ((((uint16_t)anaRadioRegArray[6])<<8)+((uint16_t)anaRadioRegArray[7]));
+
+ /* If a negative number then convert the 12 bit 2-complement in a 16 bit number */
+ if(xtalOffTemp & 0x0800)
+ {
+ xtalOffTemp = xtalOffTemp | 0xF000;
+ }
+ else
+ {
+ xtalOffTemp = xtalOffTemp & 0x0FFF;
+ }
+
+ xtalOffsetFactor = *((int16_t*)(&xtalOffTemp));
+
+ /* Calculates the frequency offset in ppm */
+ pxSRadioInitStruct->nXtalOffsetPpm =(int16_t)((uint32_t)xtalOffsetFactor*s_lXtalFrequency*PPM_FACTOR)/((uint32_t)FBASE_DIVIDER*pxSRadioInitStruct->lFrequencyBase);
+
+ /* Channel space */
+ pxSRadioInitStruct->nChannelSpace = anaRadioRegArray[4]*(s_lXtalFrequency>>15);
+
+ /* Channel number */
+ pxSRadioInitStruct->cChannelNumber = SpiritRadioGetChannel();
+
+ /* Modulation select */
+ pxSRadioInitStruct->xModulationSelect = (ModulationSelect)(digRadioRegArray[1] & 0x70);
+
+ /* Reads the frequency deviation for mantissa and exponent */
+ uint8_t FDevM = digRadioRegArray[2]&0x07;
+ uint8_t FDevE = (digRadioRegArray[2]&0xF0)>>4;
+
+ /* Reads the channel filter register for mantissa and exponent */
+ uint8_t bwM = (digRadioRegArray[3]&0xF0)>>4;
+ uint8_t bwE = digRadioRegArray[3]&0x0F;
+
+ uint8_t cDivider = 0;
+ cDivider = SpiritRadioGetDigDiv();
+
+ /* Calculates the datarate */
+ pxSRadioInitStruct->lDatarate = ((s_lXtalFrequency>>(5+cDivider))*(256+digRadioRegArray[0]))>>(23-(digRadioRegArray[1]&0x0F));
+
+ /* Calculates the frequency deviation */
+ // (((s_lXtalFrequency>>6)*(8+FDevM))>>(12-FDevE+cCorrection));
+ pxSRadioInitStruct->lFreqDev =(uint32_t)((float)s_lXtalFrequency/(((uint32_t)1)<<18)*(uint32_t)((8.0+FDevM)/2*(1<<FDevE)));
+
+ /* Reads the channel filter bandwidth from the look-up table and return it */
+ pxSRadioInitStruct->lBandwidth = (uint32_t)(100.0*s_vectnBandwidth26M[bwM+(bwE*9)]*((s_lXtalFrequency>>cDivider)/26e6));
+
+}
+
+
+/**
+* @brief Sets the Xtal configuration in the ANA_FUNC_CONF0 register.
+* @param xXtal one of the possible value of the enum type XtalFrequency.
+* @arg XTAL_FLAG_24_MHz: in case of 24 MHz crystal
+* @arg XTAL_FLAG_26_MHz: in case of 26 MHz crystal
+* @retval None.
+*/
+void SpiritRadioSetXtalFlag(XtalFlag xXtal)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_XTAL_FLAG(xXtal));
+
+ /* Reads the ANA_FUNC_CONF_0 register */
+ g_xStatus = SpiritSpiReadRegisters(ANA_FUNC_CONF0_BASE, 1, &tempRegValue);
+ if(xXtal == XTAL_FLAG_26_MHz)
+ {
+ tempRegValue|=SELECT_24_26_MHZ_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~SELECT_24_26_MHZ_MASK);
+ }
+
+ /* Sets the 24_26MHz_SELECT field in the ANA_FUNC_CONF_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(ANA_FUNC_CONF0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the Xtal configuration in the ANA_FUNC_CONF0 register.
+* @param None.
+* @retval XtalFrequency Settled Xtal configuration.
+*/
+XtalFlag SpiritRadioGetXtalFlag(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the Xtal configuration in the ANA_FUNC_CONF_0 register and return the value */
+ g_xStatus = SpiritSpiReadRegisters(ANA_FUNC_CONF0_BASE, 1, &tempRegValue);
+
+ return (XtalFlag)((tempRegValue & 0x40)>>6);
+
+}
+
+
+/**
+* @brief Returns the charge pump word for a given VCO frequency.
+* @param lFc channel center frequency expressed in Hz.
+* This parameter can be a value in one of the following ranges:<ul>
+* <li> High_Band: from 779 MHz to 915 MHz </li>
+* <li> Middle Band: from 387 MHz to 470 MHz </li>
+* <li> Low Band: from 300 MHz to 348 MHz </li>
+* <li> Very low Band: from 150 MHz to 174 MHz </li> </ul>
+* @retval uint8_t Charge pump word.
+*/
+uint8_t SpiritRadioSearchWCP(uint32_t lFc)
+{
+ int8_t i;
+ uint32_t vcofreq;
+ uint8_t BFactor;
+
+ /* Check the channel center frequency is in one of the possible range */
+ s_assert_param(IS_FREQUENCY_BAND(lFc));
+
+ /* Search the operating band */
+ if(IS_FREQUENCY_BAND_HIGH(lFc))
+ {
+ BFactor = HIGH_BAND_FACTOR;
+ }
+ else if(IS_FREQUENCY_BAND_MIDDLE(lFc))
+ {
+ BFactor = MIDDLE_BAND_FACTOR;
+ }
+ else if(IS_FREQUENCY_BAND_LOW(lFc))
+ {
+ BFactor = LOW_BAND_FACTOR;
+ }
+ else
+ {
+ BFactor = VERY_LOW_BAND_FACTOR;
+ }
+
+ /* Calculates the VCO frequency VCOFreq = lFc*B */
+ vcofreq = (lFc/1000000)*BFactor;
+
+ /* Search in the vco frequency array the charge pump word */
+ if(vcofreq>=s_vectnVCOFreq[15])
+ {
+ i=15;
+ }
+ else
+ {
+ /* Search the value */
+ for(i=0 ; i<15 && vcofreq>s_vectnVCOFreq[i] ; i++);
+
+ /* Be sure that it is the best approssimation */
+ if (i!=0 && s_vectnVCOFreq[i]-vcofreq>vcofreq-s_vectnVCOFreq[i-1])
+ i--;
+ }
+
+ /* Return index */
+ return (i%8);
+
+}
+
+/**
+* @brief Returns the synth word.
+* @param None.
+* @retval uint32_t Synth word.
+*/
+uint32_t SpiritRadioGetSynthWord(void)
+{
+ uint8_t regArray[4];
+
+ /* Reads the SYNTH registers, build the synth word and return it */
+ g_xStatus = SpiritSpiReadRegisters(SYNT3_BASE, 4, regArray);
+ return ((((uint32_t)(regArray[0]&0x1F))<<21)+(((uint32_t)(regArray[1]))<<13)+\
+ (((uint32_t)(regArray[2]))<<5)+(((uint32_t)(regArray[3]))>>3));
+
+}
+
+
+/**
+* @brief Sets the SYNTH registers.
+* @param lSynthWord the synth word to write in the SYNTH[3:0] registers.
+* @retval None.
+*/
+void SpiritRadioSetSynthWord(uint32_t lSynthWord)
+{
+ uint8_t tempArray[4];
+ uint8_t tempRegValue;
+
+ /* Reads the SYNT0 register */
+ g_xStatus = SpiritSpiReadRegisters(SYNT0_BASE, 1, &tempRegValue);
+
+ /* Mask the Band selected field */
+ tempRegValue &= 0x07;
+
+ /* Build the array for SYNTH registers */
+ tempArray[0] = (uint8_t)((lSynthWord>>21)&(0x0000001F));
+ tempArray[1] = (uint8_t)((lSynthWord>>13)&(0x000000FF));
+ tempArray[2] = (uint8_t)((lSynthWord>>5)&(0x000000FF));
+ tempArray[3] = (uint8_t)(((lSynthWord&0x0000001F)<<3)| tempRegValue);
+
+ /* Writes the synth word in the SYNTH registers */
+ g_xStatus = SpiritSpiWriteRegisters(SYNT3_BASE, 4, tempArray);
+
+}
+
+
+/**
+* @brief Sets the operating band.
+* @param xBand the band to set.
+* This parameter can be one of following parameters:
+* @arg HIGH_BAND High_Band selected: from 779 MHz to 915 MHz
+* @arg MIDDLE_BAND: Middle Band selected: from 387 MHz to 470 MHz
+* @arg LOW_BAND: Low Band selected: from 300 MHz to 348 MHz
+* @arg VERY_LOW_BAND: Very low Band selected: from 150 MHz to 174 MHz
+* @retval None.
+*/
+void SpiritRadioSetBand(BandSelect xBand)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_BAND_SELECTED(xBand));
+
+ /* Reads the SYNT0 register*/
+ g_xStatus = SpiritSpiReadRegisters(SYNT0_BASE, 1, &tempRegValue);
+
+ /* Mask the SYNTH[4;0] field and write the BS value */
+ tempRegValue &= 0xF8;
+ tempRegValue |= s_vectcBandRegValue[xBand];
+
+ /* Configures the SYNT0 register setting the operating band */
+ g_xStatus = SpiritSpiWriteRegisters(SYNT0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the operating band.
+* @param None.
+* @retval BandSelect Settled band.
+* This returned value can be one of the following parameters:
+* @arg HIGH_BAND High_Band selected: from 779 MHz to 915 MHz
+* @arg MIDDLE_BAND: Middle Band selected: from 387 MHz to 470 MHz
+* @arg LOW_BAND: Low Band selected: from 300 MHz to 348 MHz
+* @arg VERY_LOW_BAND: Very low Band selected: from 150 MHz to 174 MHz
+*/
+BandSelect SpiritRadioGetBand(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the SYNT0 register */
+ g_xStatus = SpiritSpiReadRegisters(SYNT0_BASE, 1, &tempRegValue);
+
+ /* Mask the Band selected field */
+ if((tempRegValue & 0x07) == SYNT0_BS_6)
+ {
+ return HIGH_BAND;
+ }
+ else if ((tempRegValue & 0x07) == SYNT0_BS_12)
+ {
+ return MIDDLE_BAND;
+ }
+ else if ((tempRegValue & 0x07) == SYNT0_BS_16)
+ {
+ return LOW_BAND;
+ }
+ else
+ {
+ return VERY_LOW_BAND;
+ }
+
+}
+
+
+/**
+* @brief Sets the channel number.
+* @param cChannel the channel number.
+* @retval None.
+*/
+void SpiritRadioSetChannel(uint8_t cChannel)
+{
+ /* Writes the CHNUM register */
+ g_xStatus = SpiritSpiWriteRegisters(CHNUM_BASE, 1, &cChannel);
+
+}
+
+
+/**
+* @brief Returns the actual channel number.
+* @param None.
+* @retval uint8_t Actual channel number.
+*/
+uint8_t SpiritRadioGetChannel(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the CHNUM register and return the value */
+ g_xStatus = SpiritSpiReadRegisters(CHNUM_BASE, 1, &tempRegValue);
+
+ return tempRegValue;
+
+}
+
+
+/**
+* @brief Sets the channel space factor in channel space register.
+* The channel spacing step is computed as F_Xo/32768.
+* @param fChannelSpace the channel space expressed in Hz.
+* @retval None.
+*/
+void SpiritRadioSetChannelSpace(uint32_t fChannelSpace)
+{
+ uint8_t cChannelSpaceFactor;
+
+ /* Round to the nearest integer */
+ cChannelSpaceFactor = ((uint32_t)fChannelSpace*CHSPACE_DIVIDER)/s_lXtalFrequency;
+
+ /* Write value into the register */
+ g_xStatus = SpiritSpiWriteRegisters(CHSPACE_BASE, 1, &cChannelSpaceFactor);
+
+}
+
+
+/**
+* @brief Returns the channel space register.
+* @param None.
+* @retval uint32_t Channel space. The channel space is: CS = channel_space_factor x XtalFrequency/2^15
+* where channel_space_factor is the CHSPACE register value.
+*/
+uint32_t SpiritRadioGetChannelSpace(void)
+{
+ uint8_t channelSpaceFactor;
+
+ /* Reads the CHSPACE register, calculate the channel space and return it */
+ g_xStatus = SpiritSpiReadRegisters(CHSPACE_BASE, 1, &channelSpaceFactor);
+
+ /* Compute the Hertz value and return it */
+ return ((channelSpaceFactor*s_lXtalFrequency)/CHSPACE_DIVIDER);
+
+}
+
+
+/**
+* @brief Sets the FC OFFSET register starting from xtal ppm value.
+* @param nXtalPpm the xtal offset expressed in ppm.
+* @retval None.
+*/
+void SpiritRadioSetFrequencyOffsetPpm(int16_t nXtalPpm)
+{
+ uint8_t tempArray[2];
+ int16_t xtalOffsetFactor;
+ uint32_t synthWord, fBase;
+ int32_t FOffsetTmp;
+ BandSelect band;
+
+ /* Reads the synth word */
+ synthWord = SpiritRadioGetSynthWord();
+
+ /* Reads the operating band */
+ band = SpiritRadioGetBand();
+
+ /* Calculates the frequency base */
+ uint8_t cRefDiv = (uint8_t)SpiritRadioGetRefDiv()+1;
+ fBase = synthWord*(s_lXtalFrequency/(s_vectcBHalfFactor[band]*cRefDiv)/FBASE_DIVIDER);
+
+ /* Calculates the offset respect to RF frequency and according to xtal_ppm parameter */
+ FOffsetTmp = (int32_t)(((float)nXtalPpm*fBase)/PPM_FACTOR);
+
+ /* Check the Offset is in the correct range */
+ s_assert_param(IS_FREQUENCY_OFFSET(FOffsetTmp,s_lXtalFrequency));
+
+ /* Calculates the FC_OFFSET value to write in the corresponding register */
+ xtalOffsetFactor = (int16_t)(((float)FOffsetTmp*FBASE_DIVIDER)/s_lXtalFrequency);
+
+ /* Build the array related to the FC_OFFSET_1 and FC_OFFSET_0 register */
+ tempArray[0]=(uint8_t)((((uint16_t)xtalOffsetFactor)>>8)&0x0F);
+ tempArray[1]=(uint8_t)(xtalOffsetFactor);
+
+ /* Writes the FC_OFFSET registers */
+ g_xStatus = SpiritSpiWriteRegisters(FC_OFFSET1_BASE, 2, tempArray);
+
+}
+
+
+/**
+* @brief Sets the FC OFFSET register starting from frequency offset expressed in Hz.
+* @param lFOffset frequency offset expressed in Hz as signed word.
+* @retval None.
+*/
+void SpiritRadioSetFrequencyOffset(int32_t lFOffset)
+{
+ uint8_t tempArray[2];
+ int16_t offset;
+
+ /* Check that the Offset is in the correct range */
+ s_assert_param(IS_FREQUENCY_OFFSET(lFOffset,s_lXtalFrequency));
+
+ /* Calculates the offset value to write in the FC_OFFSET register */
+ offset = (int16_t)(((float)lFOffset*FBASE_DIVIDER)/s_lXtalFrequency);
+
+ /* Build the array related to the FC_OFFSET_1 and FC_OFFSET_0 register */
+ tempArray[0]=(uint8_t)((((uint16_t)offset)>>8)&0x0F);
+ tempArray[1]=(uint8_t)(offset);
+
+ /* Writes the FC_OFFSET registers */
+ g_xStatus = SpiritSpiWriteRegisters(FC_OFFSET1_BASE, 2, tempArray);
+
+}
+
+
+/**
+* @brief Returns the actual frequency offset.
+* @param None.
+* @retval int32_t Frequency offset expressed in Hz as signed word.
+*/
+int32_t SpiritRadioGetFrequencyOffset(void)
+{
+ uint8_t tempArray[2];
+ int16_t xtalOffsetFactor;
+
+ /* Reads the FC_OFFSET registers */
+ g_xStatus = SpiritSpiReadRegisters(FC_OFFSET1_BASE, 2, tempArray);
+
+ /* Calculates the Offset Factor */
+ uint16_t xtalOffTemp = ((((uint16_t)tempArray[0])<<8)+((uint16_t)tempArray[1]));
+
+ if(xtalOffTemp & 0x0800)
+ {
+ xtalOffTemp = xtalOffTemp | 0xF000;
+ }
+ else
+ {
+ xtalOffTemp = xtalOffTemp & 0x0FFF;
+ }
+
+ xtalOffsetFactor = *((int16_t*)(&xtalOffTemp));
+
+ /* Calculates the frequency offset and return it */
+ return ((int32_t)(xtalOffsetFactor*s_lXtalFrequency)/FBASE_DIVIDER);
+
+}
+
+
+
+/**
+* @brief Sets the Synth word and the Band Select register according to desired base carrier frequency.
+* In this API the Xtal configuration is read out from
+* the corresponding register. The user shall fix it before call this API.
+* @param lFBase the base carrier frequency expressed in Hz as unsigned word.
+* @retval Error code: 0=no error, 1=error during calibration of VCO.
+*/
+uint8_t SpiritRadioSetFrequencyBase(uint32_t lFBase)
+{
+ uint32_t synthWord, Fc;
+ uint8_t band, anaRadioRegArray[4], wcp;
+
+ /* Check the parameter */
+ s_assert_param(IS_FREQUENCY_BAND(lFBase));
+
+ /* 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
+ {
+ 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;
+
+ /* Reads the reference divider */
+ uint8_t cRefDiv = (uint8_t)SpiritRadioGetRefDiv()+1;
+
+ /* Selects the VCO */
+ 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*s_vectcBHalfFactor[band]*(((double)(FBASE_DIVIDER*cRefDiv))/s_lXtalFrequency));
+
+ /* 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);
+
+ if(xDoVcoCalibrationWA==S_ENABLE)
+ return SpiritManagementWaVcoCalibration();
+
+ return 0;
+}
+
+/**
+* @brief To say to the set frequency base if do or not the VCO calibration WA.
+* @param S_ENABLE or S_DISABLE the WA procedure.
+* @retval None.
+*/
+void SpiritRadioVcoCalibrationWAFB(SpiritFunctionalState xNewstate)
+{
+ xDoVcoCalibrationWA=xNewstate;
+}
+
+/**
+* @brief Returns the base carrier frequency.
+* @param None.
+* @retval uint32_t Base carrier frequency expressed in Hz as unsigned word.
+*/
+uint32_t SpiritRadioGetFrequencyBase(void)
+{
+ uint32_t synthWord;
+ BandSelect band;
+
+ /* Reads the synth word */
+ synthWord = SpiritRadioGetSynthWord();
+
+ /* Reads the operating band */
+ band = SpiritRadioGetBand();
+
+ uint8_t cRefDiv = (uint8_t)SpiritRadioGetRefDiv() + 1;
+
+ /* Calculates the frequency base and return it */
+ return (uint32_t)round(synthWord*(((double)s_lXtalFrequency)/(FBASE_DIVIDER*cRefDiv*s_vectcBHalfFactor[band])));
+}
+
+
+/**
+* @brief Returns the actual channel center frequency.
+* @param None.
+* @retval uint32_t Actual channel center frequency expressed in Hz.
+*/
+uint32_t SpiritRadioGetCenterFrequency(void)
+{
+ int32_t offset;
+ uint8_t channel;
+ uint32_t fBase;
+ uint32_t channelSpace;
+
+ /* Reads the frequency base */
+ fBase = SpiritRadioGetFrequencyBase();
+
+ /* Reads the frequency offset */
+ offset = SpiritRadioGetFrequencyOffset();
+
+ /* Reads the channel space */
+ channelSpace = SpiritRadioGetChannelSpace();
+
+ /* Reads the channel number */
+ channel = SpiritRadioGetChannel();
+
+ /* Calculates the channel center frequency and return it */
+ return (uint32_t)(fBase + offset + (uint32_t)(channelSpace*channel));
+
+}
+
+
+/**
+* @brief Returns the mantissa and exponent, whose value used in the datarate formula
+* will give the datarate value closer to the given datarate.
+* @param fDatarate datarate expressed in bps. This parameter ranging between 100 and 500000.
+* @param pcM pointer to the returned mantissa value.
+* @param pcE pointer to the returned exponent value.
+* @retval None.
+*/
+void SpiritRadioSearchDatarateME(uint32_t lDatarate, uint8_t* pcM, uint8_t* pcE)
+{
+ volatile SpiritBool find = S_FALSE;
+ int8_t i=15;
+ uint8_t cMantissaTmp;
+ uint8_t cDivider = 0;
+
+ /* Check the parameters */
+ s_assert_param(IS_DATARATE(lDatarate));
+
+ cDivider = (uint8_t)SpiritRadioGetDigDiv();
+
+ /* Search in the datarate array the exponent value */
+ while(!find && i>=0)
+ {
+ if(lDatarate>=(s_lXtalFrequency>>(20-i+cDivider)))
+ {
+ find = S_TRUE;
+ }
+ else
+ {
+ i--;
+ }
+ }
+ i<0 ? i=0 : i;
+ *pcE = i;
+
+ /* Calculates the mantissa value according to the datarate formula */
+ cMantissaTmp = (lDatarate*((uint32_t)1<<(23-i)))/(s_lXtalFrequency>>(5+cDivider))-256;
+
+ /* Finds the mantissa value with less approximation */
+ int16_t mantissaCalculation[3];
+ for(uint8_t j=0;j<3;j++)
+ {
+ if((cMantissaTmp+j-1))
+ {
+ mantissaCalculation[j]=lDatarate-(((256+cMantissaTmp+j-1)*(s_lXtalFrequency>>(5+cDivider)))>>(23-i));
+ }
+ else
+ {
+ mantissaCalculation[j]=0x7FFF;
+ }
+ }
+ uint16_t mantissaCalculationDelta = 0xFFFF;
+ for(uint8_t j=0;j<3;j++)
+ {
+ if(S_ABS(mantissaCalculation[j])<mantissaCalculationDelta)
+ {
+ mantissaCalculationDelta = S_ABS(mantissaCalculation[j]);
+ *pcM = cMantissaTmp+j-1;
+ }
+ }
+
+}
+
+
+/**
+* @brief Returns the mantissa and exponent for a given bandwidth.
+* Even if it is possible to pass as parameter any value in the below mentioned range,
+* the API will search the closer value according to a fixed table of channel
+* bandwidth values (@ref s_vectnBandwidth), as defined in the datasheet, returning the corresponding mantissa
+* and exponent value.
+* @param lBandwidth bandwidth expressed in Hz. This parameter ranging between 1100 and 800100.
+* @param pcM pointer to the returned mantissa value.
+* @param pcE pointer to the returned exponent value.
+* @retval None.
+*/
+void SpiritRadioSearchChannelBwME(uint32_t lBandwidth, uint8_t* pcM, uint8_t* pcE)
+{
+ int8_t i, i_tmp;
+ uint8_t cDivider = 1;
+
+ /* Search in the channel filter bandwidth table the exponent value */
+ if(SpiritRadioGetDigDiv())
+ {
+ cDivider = 2;
+ }
+ else
+ {
+ cDivider = 1;
+ }
+
+ s_assert_param(IS_CH_BW(lBandwidth,s_lXtalFrequency/cDivider));
+
+ uint32_t lChfltFactor = (s_lXtalFrequency/cDivider)/100;
+
+ for(i=0;i<90 && (lBandwidth<(uint32_t)((s_vectnBandwidth26M[i]*lChfltFactor)/2600));i++);
+
+ if(i!=0)
+ {
+ /* Finds the mantissa value with less approximation */
+ i_tmp=i;
+ int16_t chfltCalculation[3];
+ for(uint8_t j=0;j<3;j++)
+ {
+ if(((i_tmp+j-1)>=0) || ((i_tmp+j-1)<=89))
+ {
+ chfltCalculation[j] = lBandwidth - (uint32_t)((s_vectnBandwidth26M[i_tmp+j-1]*lChfltFactor)/2600);
+ }
+ else
+ {
+ chfltCalculation[j] = 0x7FFF;
+ }
+ }
+ uint16_t chfltDelta = 0xFFFF;
+
+ for(uint8_t j=0;j<3;j++)
+ {
+ if(S_ABS(chfltCalculation[j])<chfltDelta)
+ {
+ chfltDelta = S_ABS(chfltCalculation[j]);
+ i=i_tmp+j-1;
+ }
+ }
+ }
+ (*pcE) = (uint8_t)(i/9);
+ (*pcM) = (uint8_t)(i%9);
+
+}
+
+/**
+* @brief Returns the mantissa and exponent, whose value used in the frequency deviation formula
+* will give a frequency deviation value most closer to the given frequency deviation.
+* @param fFDev frequency deviation expressed in Hz. This parameter can be a value in the range [F_Xo*8/2^18, F_Xo*7680/2^18].
+* @param pcM pointer to the returned mantissa value.
+* @param pcE pointer to the returned exponent value.
+* @retval None.
+*/
+void SpiritRadioSearchFreqDevME(uint32_t lFDev, uint8_t* pcM, uint8_t* pcE)
+{
+ uint8_t i;
+ uint32_t a,bp,b=0;
+ float xtalDivtmp=(float)s_lXtalFrequency/(((uint32_t)1)<<18);
+
+ /* Check the parameters */
+ s_assert_param(IS_F_DEV(lFDev,s_lXtalFrequency));
+
+ for(i=0;i<10;i++)
+ {
+ a=(uint32_t)(xtalDivtmp*(uint32_t)(7.5*(1<<i)));
+ if(lFDev<a)
+ break;
+ }
+ (*pcE) = i;
+
+ for(i=0;i<8;i++)
+ {
+ bp=b;
+ b=(uint32_t)(xtalDivtmp*(uint32_t)((8.0+i)/2*(1<<(*pcE))));
+ if(lFDev<b)
+ break;
+ }
+
+ (*pcM)=i;
+ if((lFDev-bp)<(b-lFDev))
+ (*pcM)--;
+
+}
+
+
+/**
+* @brief Sets the datarate.
+* @param fDatarate datarate expressed in bps. This value shall be in the range
+* [100 500000].
+* @retval None.
+*/
+void SpiritRadioSetDatarate(uint32_t lDatarate)
+{
+ uint8_t drE, tempRegValue[2];
+
+ /* Check the parameters */
+ s_assert_param(IS_DATARATE(lDatarate));
+
+ /* Calculates the datarate mantissa and exponent */
+ SpiritRadioSearchDatarateME(lDatarate, &tempRegValue[0], &drE);
+
+ /* Reads the MOD_O register*/
+ SpiritSpiReadRegisters(MOD0_BASE, 1, &tempRegValue[1]);
+
+ /* Mask the other fields and set the datarate exponent */
+ tempRegValue[1] &= 0xF0;
+ tempRegValue[1] |= drE;
+
+ /* Writes the Datarate registers */
+ g_xStatus = SpiritSpiWriteRegisters(MOD1_BASE, 2, tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the datarate.
+* @param None.
+* @retval uint32_t Settled datarate expressed in bps.
+*/
+uint32_t SpiritRadioGetDatarate(void)
+{
+ uint8_t tempRegValue[2];
+ uint8_t cDivider=0;
+
+ /* Reads the datarate registers for mantissa and exponent */
+ g_xStatus = SpiritSpiReadRegisters(MOD1_BASE, 2, tempRegValue);
+
+ /* Calculates the datarate */
+ cDivider = (uint8_t)SpiritRadioGetDigDiv();
+
+ return (((s_lXtalFrequency>>(5+cDivider))*(256+tempRegValue[0]))>>(23-(tempRegValue[1]&0x0F)));
+}
+
+
+/**
+* @brief Sets the frequency deviation.
+* @param fFDev frequency deviation expressed in Hz. Be sure that this value
+* is in the correct range [F_Xo*8/2^18, F_Xo*7680/2^18] Hz.
+* @retval None.
+*/
+void SpiritRadioSetFrequencyDev(uint32_t lFDev)
+{
+ uint8_t FDevM, FDevE, tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_F_DEV(lFDev, s_lXtalFrequency));
+
+ /* Calculates the frequency deviation mantissa and exponent */
+ SpiritRadioSearchFreqDevME(lFDev, &FDevM, &FDevE);
+
+ /* Reads the FDEV0 register */
+ SpiritSpiReadRegisters(FDEV0_BASE, 1, &tempRegValue);
+
+ /* Mask the other fields and set the frequency deviation mantissa and exponent */
+ tempRegValue &= 0x08;
+ tempRegValue |= ((FDevE<<4)|(FDevM));
+
+ /* Writes the Frequency deviation register */
+ g_xStatus = SpiritSpiWriteRegisters(FDEV0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the frequency deviation.
+* @param None.
+* @retval uint32_t Frequency deviation value expressed in Hz.
+* This value will be in the range [F_Xo*8/2^18, F_Xo*7680/2^18] Hz.
+*/
+uint32_t SpiritRadioGetFrequencyDev(void)
+{
+ uint8_t tempRegValue, FDevM, FDevE;
+
+
+ /* Reads the frequency deviation register for mantissa and exponent */
+ g_xStatus = SpiritSpiReadRegisters(FDEV0_BASE, 1, &tempRegValue);
+ FDevM = tempRegValue&0x07;
+ FDevE = (tempRegValue&0xF0)>>4;
+
+ /* Calculates the frequency deviation and return it */
+ //return (((s_lXtalFrequency>>6)*(8+FDevM))>>(13-FDevE));
+
+ return (uint32_t)((float)s_lXtalFrequency/(((uint32_t)1)<<18)*(uint32_t)((8.0+FDevM)/2*(1<<FDevE)));
+
+}
+
+
+/**
+* @brief Sets the channel filter bandwidth.
+* @param lBandwidth channel filter bandwidth expressed in Hz. This parameter shall be in the range [1100 800100]
+* Even if it is possible to pass as parameter any value in the above mentioned range,
+* the API will search the most closer value according to a fixed table of channel
+* bandwidth values (@ref s_vectnBandwidth), as defined in the datasheet. To verify the settled channel bandwidth
+* it is possible to use the SpiritRadioGetChannelBW() API.
+* @retval None.
+*/
+void SpiritRadioSetChannelBW(uint32_t lBandwidth)
+{
+ uint8_t bwM, bwE, tempRegValue;
+
+ /* Search in the channel filter bandwidth table the exponent value */
+ if(SpiritRadioGetDigDiv())
+ {
+ s_assert_param(IS_CH_BW(lBandwidth,(s_lXtalFrequency/2)));
+ }
+ else
+ {
+ s_assert_param(IS_CH_BW(lBandwidth,(s_lXtalFrequency)));
+ }
+
+ /* Calculates the channel bandwidth mantissa and exponent */
+ SpiritRadioSearchChannelBwME(lBandwidth, &bwM, &bwE);
+ tempRegValue = (bwM<<4)|(bwE);
+
+ /* Writes the Channel filter register */
+ g_xStatus = SpiritSpiWriteRegisters(CHFLT_BASE, 1, &tempRegValue);
+
+}
+
+/**
+* @brief Returns the channel filter bandwidth.
+* @param None.
+* @retval uint32_t Channel filter bandwidth expressed in Hz.
+*/
+uint32_t SpiritRadioGetChannelBW(void)
+{
+ uint8_t tempRegValue, bwM, bwE;
+
+ /* Reads the channel filter register for mantissa and exponent */
+ g_xStatus = SpiritSpiReadRegisters(CHFLT_BASE, 1, &tempRegValue);
+ bwM = (tempRegValue&0xF0)>>4;
+ bwE = tempRegValue&0x0F;
+
+ /* Reads the channel filter bandwidth from the look-up table and return it */
+ return (uint32_t)(100.0*s_vectnBandwidth26M[bwM+(bwE*9)]*s_lXtalFrequency/26e6);
+
+}
+
+
+/**
+* @brief Sets the modulation type.
+* @param xModulation modulation to set.
+* This parameter shall be of type @ref ModulationSelect .
+* @retval None.
+*/
+void SpiritRadioSetModulation(ModulationSelect xModulation)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_MODULATION_SELECTED(xModulation));
+
+ /* Reads the modulation register */
+ SpiritSpiReadRegisters(MOD0_BASE, 1, &tempRegValue);
+
+ /* Mask the other fields and set the modulation type */
+ tempRegValue &=0x8F;
+ tempRegValue |= xModulation;
+
+ /* Writes the modulation register */
+ g_xStatus = SpiritSpiWriteRegisters(MOD0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the modulation type used.
+* @param None.
+* @retval ModulationSelect Settled modulation type.
+*/
+ModulationSelect SpiritRadioGetModulation(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the modulation register MOD0*/
+ g_xStatus = SpiritSpiReadRegisters(MOD0_BASE, 1, &tempRegValue);
+
+ /* Return the modulation type */
+ return (ModulationSelect)(tempRegValue&0x70);
+
+}
+
+
+/**
+* @brief Enables or Disables the Continuous Wave transmit mode.
+* @param xNewState new state for power ramping.
+* This parameter can be: S_ENABLE or S_DISABLE .
+* @retval None.
+*/
+void SpiritRadioCWTransmitMode(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the modulation register MOD0 and mask the CW field */
+ SpiritSpiReadRegisters(MOD0_BASE, 1, &tempRegValue);
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |=MOD0_CW;
+ }
+ else
+ {
+ tempRegValue &= (~MOD0_CW);
+ }
+
+ /* Writes the new value in the MOD0 register */
+ g_xStatus = SpiritSpiWriteRegisters(MOD0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Sets the OOK Peak Decay.
+* @param xOokDecay Peak decay control for OOK.
+* This parameter shall be of type @ref OokPeakDecay .
+* @retval None.
+*/
+void SpiritRadioSetOokPeakDecay(OokPeakDecay xOokDecay)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_OOK_PEAK_DECAY(xOokDecay));
+
+ /* Reads the RSSI_FLT register */
+ SpiritSpiReadRegisters(RSSI_FLT_BASE, 1, &tempRegValue);
+
+ /* Mask the other fields and set OOK Peak Decay */
+ tempRegValue &= 0xFC;
+ tempRegValue |= xOokDecay;
+
+ /* Writes the RSSI_FLT register to set the new OOK peak dacay value */
+ g_xStatus = SpiritSpiWriteRegisters(RSSI_FLT_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the OOK Peak Decay.
+* @param None
+* @retval OokPeakDecay Ook peak decay value.
+*/
+OokPeakDecay SpiritRadioGetOokPeakDecay(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the OOK peak decay register RSSI_FLT_BASE*/
+ g_xStatus = SpiritSpiReadRegisters(RSSI_FLT_BASE, 1, &tempRegValue);
+
+ /* Returns the OOK peak decay */
+ return (OokPeakDecay) (tempRegValue & 0x03);
+
+}
+
+/**
+* @brief Returns the PA register value that corresponds to the passed dBm power.
+* @param lFbase Frequency base expressed in Hz.
+* @param fPowerdBm Desired power in dBm.
+* @retval Register value as byte.
+* @note The power interpolation curves used by this function have been extracted
+* by measurements done on the divisional evaluation boards.
+*/
+uint8_t SpiritRadioGetdBm2Reg(uint32_t lFBase, float fPowerdBm)
+{
+ uint8_t i=0;
+ uint8_t j=0;
+ float fReg;
+
+ if(IS_FREQUENCY_BAND_HIGH(lFBase))
+ {
+ i=0;
+ if(lFBase<900000000) i=1;// 868
+ }
+ else if(IS_FREQUENCY_BAND_MIDDLE(lFBase))
+ {
+ i=2;
+ }
+ else if(IS_FREQUENCY_BAND_LOW(lFBase))
+ {
+ i=3;
+ }
+ else if(IS_FREQUENCY_BAND_VERY_LOW(lFBase))
+ {
+ i=4;
+ }
+
+ j=1;
+ if(fPowerdBm>0 && 13.0/fPowerFactors[i][2]-fPowerFactors[i][3]/fPowerFactors[i][2]<fPowerdBm)
+ j=0;
+ else if(fPowerdBm<=0 && 40.0/fPowerFactors[i][2]-fPowerFactors[i][3]/fPowerFactors[i][2]>fPowerdBm)
+ j=2;
+
+ fReg=fPowerFactors[i][2*j]*fPowerdBm+fPowerFactors[i][2*j+1];
+
+ if(fReg<1)
+ fReg=1;
+ else if(fReg>90)
+ fReg=90;
+
+ return ((uint8_t)fReg);
+}
+
+
+/**
+* @brief Returns the dBm power that corresponds to the value of PA register.
+* @param lFbase Frequency base expressed in Hz.
+* @param cPowerReg Register value of the PA.
+* @retval Power in dBm as float.
+* @note The power interpolation curves used by this function have been extracted
+* by measurements done on the divisional evaluation boards.
+*/
+float SpiritRadioGetReg2dBm(uint32_t lFBase, uint8_t cPowerReg)
+{
+ uint8_t i=0;
+ uint8_t j=0;
+ float fPower;
+
+ if(cPowerReg==0 || cPowerReg>90)
+ return (-130.0);
+
+ if(IS_FREQUENCY_BAND_HIGH(lFBase))
+ {
+ i=0;
+ if(lFBase<900000000) i=1;// 868
+ }
+ else if(IS_FREQUENCY_BAND_MIDDLE(lFBase))
+ {
+ i=2;
+ }
+ else if(IS_FREQUENCY_BAND_LOW(lFBase))
+ {
+ i=3;
+ }
+ else if(IS_FREQUENCY_BAND_VERY_LOW(lFBase))
+ {
+ i=4;
+ }
+
+ j=1;
+ if(cPowerReg<13) j=0;
+ else if(cPowerReg>40) j=2;
+
+ fPower=(((float)cPowerReg)/fPowerFactors[i][2*j]-fPowerFactors[i][2*j+1]/fPowerFactors[i][2*j]);
+
+ return fPower;
+}
+
+/**
+* @brief Configures the Power Amplifier Table and registers with value expressed in dBm.
+* @param cPALevelMaxIndex number of levels to set. This parameter shall be in the range [0:7].
+* @param cWidth step width expressed in terms of bit period units Tb/8.
+* This parameter shall be in the range [1:4].
+* @param xCLoad one of the possible value of the enum type PALoadCapacitor.
+* @arg LOAD_0_PF No additional PA load capacitor
+* @arg LOAD_1_2_PF 1.2pF additional PA load capacitor
+* @arg LOAD_2_4_PF 2.4pF additional PA load capacitor
+* @arg LOAD_3_6_PF 3.6pF additional PA load capacitor
+* @param pfPAtabledBm pointer to an array of PA values in dbm between [-PA_LOWER_LIMIT: PA_UPPER_LIMIT] dbm.
+* The first element shall be the lower level (PA_LEVEL[0]) value and the last element
+* the higher level one (PA_LEVEL[paLevelMaxIndex]).
+* @retval None.
+*/
+void SpiritRadioSetPATabledBm(uint8_t cPALevelMaxIndex, uint8_t cWidth, PALoadCapacitor xCLoad, float* pfPAtabledBm)
+{
+ uint8_t palevel[9], address, paLevelValue;
+ uint32_t lFBase=SpiritRadioGetFrequencyBase();
+
+ /* Check the parameters */
+ s_assert_param(IS_PA_MAX_INDEX(cPALevelMaxIndex));
+ s_assert_param(IS_PA_STEP_WIDTH(cWidth));
+ s_assert_param(IS_PA_LOAD_CAP(xCLoad));
+
+ /* Check the PA level in dBm is in the range and calculate the PA_LEVEL value
+ to write in the corresponding register using the linearization formula */
+ for(int i=0; i<=cPALevelMaxIndex; i++)
+ {
+ s_assert_param(IS_PAPOWER_DBM(*pfPAtabledBm));
+ paLevelValue=SpiritRadioGetdBm2Reg(lFBase,(*pfPAtabledBm));
+ palevel[cPALevelMaxIndex-i]=paLevelValue;
+ pfPAtabledBm++;
+ }
+
+ /* Sets the PA_POWER[0] register */
+ palevel[cPALevelMaxIndex+1]=xCLoad|(cWidth-1)<<3|cPALevelMaxIndex;
+
+ /* Sets the base address */
+ address=PA_POWER8_BASE+7-cPALevelMaxIndex;
+
+ /* Configures the PA_POWER registers */
+ g_xStatus = SpiritSpiWriteRegisters(address, cPALevelMaxIndex+2, palevel);
+
+}
+
+
+/**
+* @brief Returns the Power Amplifier Table and registers, returning values in dBm.
+* @param pcPALevelMaxIndex pointer to the number of levels settled.
+* This parameter will be in the range [0:7].
+* @param pfPAtabledBm pointer to an array of 8 elements containing the PA value in dbm.
+* The first element will be the PA_LEVEL_0 and the last element
+* will be PA_LEVEL_7. Any value higher than PA_UPPER_LIMIT implies no output
+* power (output stage is in high impedance).
+* @retval None.
+*/
+void SpiritRadioGetPATabledBm(uint8_t* pcPALevelMaxIndex, float* pfPAtabledBm)
+{
+ uint8_t palevelvect[9];
+ uint32_t lFBase=SpiritRadioGetFrequencyBase();
+
+ /* Reads the PA_LEVEL_x registers and the PA_POWER_0 register */
+ g_xStatus = SpiritSpiReadRegisters(PA_POWER8_BASE, 9, palevelvect);
+
+ /* Fill the PAtable */
+ for(int i=7; i>=0; i--)
+ {
+ (*pfPAtabledBm)=SpiritRadioGetReg2dBm(lFBase,palevelvect[i]);
+ pfPAtabledBm++;
+ }
+
+ /* Return the settled index */
+ *pcPALevelMaxIndex = palevelvect[8]&0x07;
+
+}
+
+
+
+
+
+
+/**
+* @brief Sets a specific PA_LEVEL register, with a value given in dBm.
+* @param cIndex PA_LEVEL to set. This parameter shall be in the range [0:7].
+* @param fPowerdBm PA value to write expressed in dBm . Be sure that this values is in the
+* correct range [-PA_LOWER_LIMIT: PA_UPPER_LIMIT] dBm.
+* @retval None.
+* @note This function makes use of the @ref SpiritRadioGetdBm2Reg fcn to interpolate the
+* power value.
+*/
+void SpiritRadioSetPALeveldBm(uint8_t cIndex, float fPowerdBm)
+{
+ uint8_t address, paLevelValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_PA_MAX_INDEX(cIndex));
+ s_assert_param(IS_PAPOWER_DBM(fPowerdBm));
+
+ /* interpolate the power level */
+ paLevelValue=SpiritRadioGetdBm2Reg(SpiritRadioGetFrequencyBase(),fPowerdBm);
+
+ /* Sets the base address */
+ address=PA_POWER8_BASE+7-cIndex;
+
+ /* Configures the PA_LEVEL register */
+ g_xStatus = SpiritSpiWriteRegisters(address, 1, &paLevelValue);
+
+}
+
+
+/**
+* @brief Returns a specific PA_LEVEL register, returning a value in dBm.
+* @param cIndex PA_LEVEL to read. This parameter shall be in the range [0:7]
+* @retval float Settled power level expressed in dBm. A value
+* higher than PA_UPPER_LIMIT dBm implies no output power
+* (output stage is in high impedance).
+* @note This function makes use of the @ref SpiritRadioGetReg2dBm fcn to interpolate the
+* power value.
+*/
+float SpiritRadioGetPALeveldBm(uint8_t cIndex)
+{
+ uint8_t address, paLevelValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_PA_MAX_INDEX(cIndex));
+
+ /* Sets the base address */
+ address=PA_POWER8_BASE+7-cIndex;
+
+ /* Reads the PA_LEVEL[cIndex] register */
+ g_xStatus = SpiritSpiReadRegisters(address, 1, &paLevelValue);
+
+ return SpiritRadioGetReg2dBm(SpiritRadioGetFrequencyBase(),paLevelValue);
+}
+
+
+/**
+* @brief Configures the Power Amplifier Table and registers.
+* @param cPALevelMaxIndex number of levels to set. This parameter shall be in the range [0:7].
+* @param cWidth step width expressed in terms of bit period units Tb/8.
+* This parameter shall be in the range [1:4].
+* @param xCLoad one of the possible value of the enum type PALoadCapacitor.
+* @arg LOAD_0_PF No additional PA load capacitor
+* @arg LOAD_1_2_PF 1.2pF additional PA load capacitor
+* @arg LOAD_2_4_PF 2.4pF additional PA load capacitor
+* @arg LOAD_3_6_PF 3.6pF additional PA load capacitor
+* @param pcPAtable pointer to an array of PA values in the range [0: 90], where 0 implies no
+* output power, 1 will be the maximum level and 90 the minimum one
+* The first element shall be the lower level (PA_LEVEL[0]) value and the last element
+* the higher level one (PA_LEVEL[paLevelMaxIndex]).
+* @retval None.
+*/
+void SpiritRadioSetPATable(uint8_t cPALevelMaxIndex, uint8_t cWidth, PALoadCapacitor xCLoad, uint8_t* pcPAtable)
+{
+ uint8_t palevel[9], address;
+
+ /* Check the parameters */
+ s_assert_param(IS_PA_MAX_INDEX(cPALevelMaxIndex));
+ s_assert_param(IS_PA_STEP_WIDTH(cWidth));
+ s_assert_param(IS_PA_LOAD_CAP(xCLoad));
+
+ /* Check the PA levels are in the range */
+ for(int i=0; i<=cPALevelMaxIndex; i++)
+ {
+ s_assert_param(IS_PAPOWER(*pcPAtable));
+ palevel[cPALevelMaxIndex-i]=*pcPAtable;
+ pcPAtable++;
+ }
+
+ /* Sets the PA_POWER[0] register */
+ palevel[cPALevelMaxIndex+1]=xCLoad|((cWidth-1)<<3)|cPALevelMaxIndex;
+
+ /* Sets the base address */
+ address=PA_POWER8_BASE+7-cPALevelMaxIndex;
+
+ /* Configures the PA_POWER registers */
+ g_xStatus = SpiritSpiWriteRegisters(address, cPALevelMaxIndex+2, palevel);
+
+}
+
+
+/**
+* @brief Returns the Power Amplifier Table and registers.
+* @param pcPALevelMaxIndex pointer to the number of levels settled.
+* This parameter shall be in the range [0:7].
+* @param pcPAtable pointer to an array of 8 elements containing the PA value.
+* The first element will be the PA_LEVEL_0 and the last element
+* will be PA_LEVEL_7. Any value equals to 0 implies that level has
+* no output power (output stage is in high impedance).
+* @retval None
+*/
+void SpiritRadioGetPATable(uint8_t* pcPALevelMaxIndex, uint8_t* pcPAtable)
+{
+ uint8_t palevelvect[9];
+
+ /* Reads the PA_LEVEL_x registers and the PA_POWER_0 register */
+ g_xStatus = SpiritSpiReadRegisters(PA_POWER8_BASE, 9, palevelvect);
+
+ /* Fill the PAtable */
+ for(int i=7; i>=0; i--)
+ {
+ *pcPAtable = palevelvect[i];
+ pcPAtable++;
+ }
+
+ /* Return the settled index */
+ *pcPALevelMaxIndex = palevelvect[8]&0x07;
+
+}
+
+
+/**
+* @brief Sets a specific PA_LEVEL register.
+* @param cIndex PA_LEVEL to set. This parameter shall be in the range [0:7].
+* @param cPower PA value to write in the register. Be sure that this values is in the
+* correct range [0 : 90].
+* @retval None.
+*/
+void SpiritRadioSetPALevel(uint8_t cIndex, uint8_t cPower)
+{
+ uint8_t address;
+
+ /* Check the parameters */
+ s_assert_param(IS_PA_MAX_INDEX(cIndex));
+ s_assert_param(IS_PAPOWER(cPower));
+
+ /* Sets the base address */
+ address=PA_POWER8_BASE+7-cIndex;
+
+ /* Configures the PA_LEVEL register */
+ g_xStatus = SpiritSpiWriteRegisters(address, 1, &cPower);
+
+}
+
+
+/**
+* @brief Returns a specific PA_LEVEL register.
+* @param cIndex PA_LEVEL to read. This parameter shall be in the range [0:7].
+* @retval uint8_t PA_LEVEL value. A value equal to zero
+* implies no output power (output stage is in high impedance).
+*/
+uint8_t SpiritRadioGetPALevel(uint8_t cIndex)
+{
+ uint8_t address, tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_PA_MAX_INDEX(cIndex));
+
+ /* Sets the base address */
+ address=PA_POWER8_BASE+7-cIndex;
+
+ /* Reads the PA_LEVEL[cIndex] register and return the value */
+ g_xStatus = SpiritSpiReadRegisters(address, 1, &tempRegValue);
+ return tempRegValue;
+
+}
+
+
+/**
+* @brief Sets the output stage additional load capacitor bank.
+* @param xCLoad one of the possible value of the enum type PALoadCapacitor.
+* @arg LOAD_0_PF No additional PA load capacitor
+* @arg LOAD_1_2_PF 1.2pF additional PA load capacitor
+* @arg LOAD_2_4_PF 2.4pF additional PA load capacitor
+* @arg LOAD_3_6_PF 3.6pF additional PA load capacitor
+* @retval None.
+*/
+void SpiritRadioSetPACwc(PALoadCapacitor xCLoad)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_PA_LOAD_CAP(xCLoad));
+
+ /* Reads the PA_POWER_0 register */
+ SpiritSpiReadRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+ /* Mask the CWC[1:0] field and write the new value */
+ tempRegValue &= 0x3F;
+ tempRegValue |= xCLoad;
+
+ /* Configures the PA_POWER_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the output stage additional load capacitor bank.
+* @param None.
+* @retval PALoadCapacitor Output stage additional load capacitor bank.
+* This parameter can be:
+* @arg LOAD_0_PF No additional PA load capacitor
+* @arg LOAD_1_2_PF 1.2pF additional PA load capacitor
+* @arg LOAD_2_4_PF 2.4pF additional PA load capacitor
+* @arg LOAD_3_6_PF 3.6pF additional PA load capacitor
+*/
+PALoadCapacitor SpiritRadioGetPACwc(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the PA_POWER_0 register */
+ g_xStatus = SpiritSpiReadRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+ /* Mask the CWC[1:0] field and return the value*/
+ return (PALoadCapacitor)(tempRegValue & 0xC0);
+
+}
+
+
+/**
+* @brief Sets a specific PA_LEVEL_MAX_INDEX.
+* @param cIndex PA_LEVEL_MAX_INDEX to set. This parameter shall be in the range [0:7].
+* @retval None
+*/
+void SpiritRadioSetPALevelMaxIndex(uint8_t cIndex)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_PA_MAX_INDEX(cIndex));
+
+ /* Reads the PA_POWER_0 register */
+ SpiritSpiReadRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+ /* Mask the PA_LEVEL_MAX_INDEX[1:0] field and write the new value */
+ tempRegValue &= 0xF8;
+ tempRegValue |= cIndex;
+
+ /* Configures the PA_POWER_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the actual PA_LEVEL_MAX_INDEX.
+* @param None.
+* @retval uint8_t Actual PA_LEVEL_MAX_INDEX. This parameter will be in the range [0:7].
+*/
+uint8_t SpiritRadioGetPALevelMaxIndex(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the PA_POWER_0 register */
+ g_xStatus = SpiritSpiReadRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+ /* Mask the PA_LEVEL_MAX_INDEX[1:0] field and return the value */
+ return (tempRegValue & 0x07);
+
+}
+
+
+/**
+* @brief Sets a specific PA_RAMP_STEP_WIDTH.
+* @param cWidth step width expressed in terms of bit period units Tb/8.
+* This parameter shall be in the range [1:4].
+* @retval None.
+*/
+void SpiritRadioSetPAStepWidth(uint8_t cWidth)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_PA_STEP_WIDTH(cWidth));
+
+ /* Reads the PA_POWER_0 register */
+ SpiritSpiReadRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+ /* Mask the PA_RAMP_STEP_WIDTH[1:0] field and write the new value */
+ tempRegValue &= 0xE7;
+ tempRegValue |= (cWidth-1)<<3;
+
+ /* Configures the PA_POWER_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the actual PA_RAMP_STEP_WIDTH.
+* @param None.
+* @retval uint8_t Step width value expressed in terms of bit period units Tb/8.
+* This parameter will be in the range [1:4].
+*/
+uint8_t SpiritRadioGetPAStepWidth(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the PA_POWER_0 register */
+ g_xStatus = SpiritSpiReadRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+ /* Mask the PA_RAMP_STEP_WIDTH[1:0] field and return the value */
+ tempRegValue &= 0x18;
+ return ((tempRegValue>>3)+1);
+
+}
+
+
+/**
+* @brief Enables or Disables the Power Ramping.
+* @param xNewState new state for power ramping.
+* This parameter can be: S_ENABLE or S_DISABLE.
+* @retval None.
+*/
+void SpiritRadioPARamping(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the PA_POWER_0 register and configure the PA_RAMP_ENABLE field */
+ SpiritSpiReadRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= PA_POWER0_PA_RAMP_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~PA_POWER0_PA_RAMP_MASK);
+ }
+
+ /* Sets the PA_POWER_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+}
+
+/**
+* @brief Returns the Power Ramping enable bit.
+* @param xNewState new state for power ramping.
+* This parameter can be: S_ENABLE or S_DISABLE.
+* @retval None.
+*/
+SpiritFunctionalState SpiritRadioGetPARamping(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the PA_POWER_0 register and configure the PA_RAMP_ENABLE field */
+ g_xStatus = SpiritSpiReadRegisters(PA_POWER0_BASE, 1, &tempRegValue);
+
+ /* Mask and return data */
+ return (SpiritFunctionalState)((tempRegValue>>5) & 0x01);
+
+}
+
+
+/**
+* @brief Enables or Disables the AFC.
+* @param xNewState new state for AFC.
+* This parameter can be: S_ENABLE or S_DISABLE.
+* @retval None.
+*/
+void SpiritRadioAFC(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the AFC_2 register and configure the AFC Enabled field */
+ SpiritSpiReadRegisters(AFC2_BASE, 1, &tempRegValue);
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= AFC2_AFC_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~AFC2_AFC_MASK);
+ }
+
+ /* Sets the AFC_2 register */
+ g_xStatus = SpiritSpiWriteRegisters(AFC2_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Enables or Disables the AFC freeze on sync word detection.
+* @param xNewState new state for AFC freeze on sync word detection.
+* This parameter can be: S_ENABLE or S_DISABLE.
+* @retval None.
+*/
+void SpiritRadioAFCFreezeOnSync(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the AFC_2 register and configure the AFC Freeze on Sync field */
+ SpiritSpiReadRegisters(AFC2_BASE, 1, &tempRegValue);
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= AFC2_AFC_FREEZE_ON_SYNC_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~AFC2_AFC_FREEZE_ON_SYNC_MASK);
+ }
+
+ /* Sets the AFC_2 register */
+ g_xStatus = SpiritSpiWriteRegisters(AFC2_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Sets the AFC working mode.
+* @param xMode the AFC mode. This parameter can be one of the values defined in @ref AFCMode :
+* @arg AFC_SLICER_CORRECTION AFC loop closed on slicer
+* @arg AFC_2ND_IF_CORRECTION AFC loop closed on 2nd conversion stage
+* @retval None.
+*/
+void SpiritRadioSetAFCMode(AFCMode xMode)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_AFC_MODE(xMode));
+
+ /* Reads the AFC_2 register and configure the AFC Mode field */
+ SpiritSpiReadRegisters(AFC2_BASE, 1, &tempRegValue);
+ if(xMode == AFC_2ND_IF_CORRECTION)
+ {
+ tempRegValue |= AFC_2ND_IF_CORRECTION;
+ }
+ else
+ {
+ tempRegValue &= (~AFC_2ND_IF_CORRECTION);
+ }
+
+ /* Sets the AFC_2 register */
+ g_xStatus = SpiritSpiWriteRegisters(AFC2_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AFC working mode.
+* @param None.
+* @retval AFCMode Settled AFC mode. This parameter will be one of the values defined in @ref AFCMode :
+* @arg AFC_SLICER_CORRECTION AFC loop closed on slicer
+* @arg AFC_2ND_IF_CORRECTION AFC loop closed on 2nd conversion stage
+*/
+AFCMode SpiritRadioGetAFCMode(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AFC_2 register */
+ g_xStatus = SpiritSpiReadRegisters(AFC2_BASE, 1, &tempRegValue);
+
+ /* Mask the AFC Mode field and returns the value */
+ return (AFCMode)(tempRegValue & 0x20);
+
+}
+
+
+/**
+* @brief Sets the AFC peak detector leakage.
+* @param cLeakage the peak detector leakage. This parameter shall be in the range:
+* [0:31].
+* @retval None.
+*/
+void SpiritRadioSetAFCPDLeakage(uint8_t cLeakage)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_AFC_PD_LEAKAGE(cLeakage));
+
+ /* Reads the AFC_2 register and configure the AFC PD leakage field */
+ SpiritSpiReadRegisters(AFC2_BASE, 1, &tempRegValue);
+ tempRegValue &= 0xE0;
+ tempRegValue |= cLeakage;
+
+ /* Sets the AFC_2 register */
+ g_xStatus = SpiritSpiWriteRegisters(AFC2_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AFC peak detector leakage.
+* @param None.
+* @retval uint8_t Peak detector leakage value. This parameter will be in the range:
+* [0:31].
+*/
+uint8_t SpiritRadioGetAFCPDLeakage(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AFC_2 register */
+ g_xStatus = SpiritSpiReadRegisters(AFC2_BASE, 1, &tempRegValue);
+
+ /* Mask the AFC PD leakage field and return the value */
+ return (tempRegValue & 0x1F);
+
+}
+
+
+/**
+* @brief Sets the length of the AFC fast period expressed as number of samples.
+* @param cLength length of the fast period in number of samples.
+* @retval None.
+*/
+void SpiritRadioSetAFCFastPeriod(uint8_t cLength)
+{
+ /* Sets the AFC_1 register */
+ g_xStatus = SpiritSpiWriteRegisters(AFC1_BASE, 1, &cLength);
+
+}
+
+
+/**
+* @brief Returns the AFC fast period expressed as number of samples.
+* @param None.
+* @retval uint8_t Length of the fast period in number of samples.
+*/
+uint8_t SpiritRadioGetAFCFastPeriod(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AFC 1 register and return the value */
+ g_xStatus = SpiritSpiReadRegisters(AFC1_BASE, 1, &tempRegValue);
+
+ return tempRegValue;
+
+}
+
+
+/**
+* @brief Sets the AFC loop gain in fast mode.
+* @param cGain AFC loop gain in fast mode. This parameter shall be in the range:
+* [0:15].
+* @retval None.
+*/
+void SpiritRadioSetAFCFastGain(uint8_t cGain)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_AFC_FAST_GAIN(cGain));
+
+ /* Reads the AFC_0 register and configure the AFC Fast Gain field */
+ SpiritSpiReadRegisters(AFC0_BASE, 1, &tempRegValue);
+ tempRegValue &= 0x0F;
+ tempRegValue |= cGain<<4;
+
+ /* Sets the AFC_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(AFC0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AFC loop gain in fast mode.
+* @param None.
+* @retval uint8_t AFC loop gain in fast mode. This parameter will be in the range:
+* [0:15].
+*/
+uint8_t SpiritRadioGetAFCFastGain(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AFC_0 register, mask the AFC Fast Gain field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(AFC0_BASE, 1, &tempRegValue);
+
+ return ((tempRegValue & 0xF0)>>4);
+
+}
+
+
+/**
+* @brief Sets the AFC loop gain in slow mode.
+* @param cGain AFC loop gain in slow mode. This parameter shall be in the range:
+* [0:15].
+* @retval None.
+*/
+void SpiritRadioSetAFCSlowGain(uint8_t cGain)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_AFC_SLOW_GAIN(cGain));
+
+ /* Reads the AFC_0 register and configure the AFC Slow Gain field */
+ SpiritSpiReadRegisters(AFC0_BASE, 1, &tempRegValue);
+ tempRegValue &= 0xF0;
+ tempRegValue |= cGain;
+
+ /* Sets the AFC_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(AFC0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AFC loop gain in slow mode.
+* @param None.
+* @retval uint8_t AFC loop gain in slow mode. This parameter will be in the range:
+* [0:15].
+*/
+uint8_t SpiritRadioGetAFCSlowGain(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AFC_0 register, mask the AFC Slow Gain field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(AFC0_BASE, 1, &tempRegValue);
+
+ return (tempRegValue & 0x0F);
+
+}
+
+
+/**
+* @brief Returns the AFC correction from the corresponding register.
+* @param None.
+* @retval int8_t AFC correction, read from the corresponding register.
+* This parameter will be in the range [-128:127].
+*/
+int8_t SpiritRadioGetAFCCorrectionReg(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AFC_CORR register, cast the read value as signed char and return it */
+ g_xStatus = SpiritSpiReadRegisters(AFC_CORR_BASE, 1, &tempRegValue);
+
+ return (int8_t)tempRegValue;
+
+}
+
+
+/**
+* @brief Returns the AFC correction expressed in Hz.
+* @param None.
+* @retval int32_t AFC correction expressed in Hz
+* according to the following formula:<ul>
+* <li> Fafc[Hz]= (Fdig/(12*2^10))*AFC_CORR where </li>
+* <li> AFC_CORR is the value read in the AFC_CORR register </li> </ul>
+*/
+int32_t SpiritRadioGetAFCCorrectionHz(void)
+{
+ int8_t correction;
+ uint32_t xtal = s_lXtalFrequency;
+
+ /* Reads the AFC correction register */
+ correction = SpiritRadioGetAFCCorrectionReg();
+
+ if(xtal>DOUBLE_XTAL_THR)
+ {
+ xtal /= 2;
+ }
+
+ /* Calculates and return the Frequency Correction */
+ return (int32_t)(xtal/(12*pow(2,10))*correction);
+
+}
+
+
+/**
+* @brief Enables or Disables the AGC.
+* @param xNewState new state for AGC.
+* This parameter can be: S_ENABLE or S_DISABLE
+* @retval None.
+*/
+void SpiritRadioAGC(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the AGCCTRL_0 register and configure the AGC Enabled field */
+ SpiritSpiReadRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= AGCCTRL0_AGC_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~AGCCTRL0_AGC_MASK);
+ }
+
+ /* Sets the AGCCTRL_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Sets the AGC working mode.
+* @param xMode the AGC mode. This parameter can be one of the values defined in @ref AGCMode :
+* @arg AGC_LINEAR_MODE AGC works in linear mode
+* @arg AGC_BINARY_MODE AGC works in binary mode
+* @retval None.
+*/
+void SpiritRadioSetAGCMode(AGCMode xMode)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_AGC_MODE(xMode));
+
+ /* Reads the AGCCTRL_0 register and configure the AGC Mode field */
+ SpiritSpiReadRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+ if(xMode == AGC_BINARY_MODE)
+ {
+ tempRegValue |= AGC_BINARY_MODE;
+ }
+ else
+ {
+ tempRegValue &= (~AGC_BINARY_MODE);
+ }
+
+ /* Sets the AGCCTRL_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AGC working mode.
+* @param None.
+* @retval AGCMode Settled AGC mode. This parameter can be one of the values defined in @ref AGCMode :
+* @arg AGC_LINEAR_MODE AGC works in linear mode
+* @arg AGC_BINARY_MODE AGC works in binary mode
+*/
+AGCMode SpiritRadioGetAGCMode(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AGCCTRL_0 register, mask the AGC Mode field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+
+ return (AGCMode)(tempRegValue & 0x40);
+
+}
+
+
+/**
+* @brief Enables or Disables the AGC freeze on steady state.
+* @param xNewState new state for AGC freeze on steady state.
+* This parameter can be: S_ENABLE or S_DISABLE.
+* @retval None.
+*/
+void SpiritRadioAGCFreezeOnSteady(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the AGCCTRL_2 register and configure the AGC Freeze On Steady field */
+ SpiritSpiReadRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= AGCCTRL2_FREEZE_ON_STEADY_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~AGCCTRL2_FREEZE_ON_STEADY_MASK);
+ }
+
+ /* Sets the AGCCTRL_2 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Enable or Disable the AGC freeze on sync detection.
+* @param xNewState new state for AGC freeze on sync detection.
+* This parameter can be: S_ENABLE or S_DISABLE.
+* @retval None.
+*/
+void SpiritRadioAGCFreezeOnSync(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the AGCCTRL_2 register and configure the AGC Freeze On Sync field */
+ SpiritSpiReadRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= AGCCTRL2_FREEZE_ON_SYNC_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~AGCCTRL2_FREEZE_ON_SYNC_MASK);
+ }
+
+ /* Sets the AGCCTRL_2 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Enable or Disable the AGC to start with max attenuation.
+* @param xNewState new state for AGC start with max attenuation mode.
+* This parameter can be: S_ENABLE or S_DISABLE.
+* @retval None.
+*/
+void SpiritRadioAGCStartMaxAttenuation(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue = 0x00;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the AGCCTRL_2 register and configure the AGC Start Max Attenuation field */
+ SpiritSpiReadRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= AGCCTRL2_START_MAX_ATTENUATION_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~AGCCTRL2_START_MAX_ATTENUATION_MASK);
+ }
+
+ /* Sets the AGCCTRL_2 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Sets the AGC measure time.
+* @param nTime AGC measure time expressed in us. This parameter shall be in the range [0, 393216/F_Xo].
+* @retval None.
+*/
+void SpiritRadioSetAGCMeasureTimeUs(uint16_t nTime)
+{
+ uint8_t tempRegValue, measure;
+
+ /* Check the parameter */
+ s_assert_param(IS_AGC_MEASURE_TIME_US(nTime,s_lXtalFrequency));
+
+ /* Reads the AGCCTRL_2 register */
+ SpiritSpiReadRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+
+ /* Calculates the measure time value to write in the register */
+ measure = (uint8_t)lroundf(log2((float)nTime/1e6 * s_lXtalFrequency/12));
+ (measure>15) ? (measure=15):(measure);
+
+ /* Mask the MEAS_TIME field and write the new value */
+ tempRegValue &= 0xF0;
+ tempRegValue |= measure;
+
+ /* Sets the AGCCTRL_2 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AGC measure time.
+* @param None.
+* @retval uint16_t AGC measure time expressed in us. This parameter will be in the range [0, 393216/F_Xo].
+*/
+uint16_t SpiritRadioGetAGCMeasureTimeUs(void)
+{
+ uint8_t measure;
+
+ /* Reads the AGCCTRL_2 register */
+ g_xStatus = SpiritSpiReadRegisters(AGCCTRL2_BASE, 1, &measure);
+
+ /* Mask the MEAS_TIME field */
+ measure &= 0x0F;
+
+ /* Calculates the measure time value to write in the register */
+ return (uint16_t)((12.0/s_lXtalFrequency)*(float)pow(2,measure)*1e6);
+
+}
+
+
+/**
+* @brief Sets the AGC measure time.
+* @param cTime AGC measure time to write in the MEAS_TIME field of AGCCTRL_2 register.
+* This parameter shall be in the range [0:15].
+* @retval None.
+*/
+void SpiritRadioSetAGCMeasureTime(uint8_t cTime)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameter */
+ s_assert_param(IS_AGC_MEASURE_TIME(cTime));
+
+ /* Reads the AGCCTRL_2 register */
+ SpiritSpiReadRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+
+ /* Mask the MEAS_TIME field and write the new value */
+ tempRegValue &= 0xF0;
+ tempRegValue |= cTime;
+
+ /* Sets the AGCCTRL_2 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AGC measure time.
+* @param None.
+* @retval uint8_t AGC measure time read from the MEAS_TIME field of AGCCTRL_2 register.
+* This parameter will be in the range [0:15].
+*/
+uint8_t SpiritRadioGetAGCMeasureTime(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AGCCTRL_2 register, mask the MEAS_TIME field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(AGCCTRL2_BASE, 1, &tempRegValue);
+
+ return (tempRegValue & 0x0F);
+
+}
+
+
+/**
+* @brief Sets the AGC hold time.
+* @param cTime AGC hold time expressed in us. This parameter shall be in the range[0, 756/F_Xo].
+* @retval None.
+*/
+void SpiritRadioSetAGCHoldTimeUs(uint8_t cTime)
+{
+ uint8_t tempRegValue, hold;
+
+ /* Check the parameter */
+ s_assert_param(IS_AGC_HOLD_TIME_US(cTime,s_lXtalFrequency));
+
+ /* Reads the AGCCTRL_0 register */
+ SpiritSpiReadRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+
+ /* Calculates the hold time value to write in the register */
+ hold = (uint8_t)lroundf(((float)cTime/1e6 * s_lXtalFrequency)/12);
+ (hold>63) ? (hold=63):(hold);
+
+ /* Mask the HOLD_TIME field and write the new value */
+ tempRegValue &= 0xC0;
+ tempRegValue |= hold;
+
+ /* Sets the AGCCTRL_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AGC hold time.
+* @param None.
+* @retval uint8_t AGC hold time expressed in us. This parameter will be in the range:
+* [0, 756/F_Xo].
+*/
+uint8_t SpiritRadioGetAGCHoldTimeUs(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AGCCTRL_0 register */
+ g_xStatus = SpiritSpiReadRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+
+ /* Mask the HOLD_TIME field */
+ tempRegValue &= 0x3F;
+
+ /* Calculates the hold time value and return it */
+ return (uint8_t)lroundf ((12.0/s_lXtalFrequency)*(tempRegValue*1e6));
+
+}
+
+
+/**
+* @brief Sets the AGC hold time.
+* @param cTime AGC hold time to write in the HOLD_TIME field of AGCCTRL_0 register.
+* This parameter shall be in the range [0:63].
+* @retval None.
+*/
+void SpiritRadioSetAGCHoldTime(uint8_t cTime)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameter */
+ s_assert_param(IS_AGC_HOLD_TIME(cTime));
+
+ /* Reads the AGCCTRL_0 register */
+ SpiritSpiReadRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+
+ /* Mask the HOLD_TIME field and write the new value */
+ tempRegValue &= 0xC0;
+ tempRegValue |= cTime;
+
+ /* Sets the AGCCTRL_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AGC hold time.
+* @param None.
+* @retval uint8_t AGC hold time read from the HOLD_TIME field of AGCCTRL_0 register.
+* This parameter will be in the range [0:63].
+*/
+uint8_t SpiritRadioGetAGCHoldTime(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AGCCTRL_0 register, mask the MEAS_TIME field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(AGCCTRL0_BASE, 1, &tempRegValue);
+
+ return (tempRegValue & 0x3F);
+
+}
+
+
+/**
+* @brief Sets the AGC high threshold.
+* @param cHighThreshold AGC high threshold to write in the THRESHOLD_HIGH field of AGCCTRL_1 register.
+* This parameter shall be in the range [0:15].
+* @retval None.
+*/
+void SpiritRadioSetAGCHighThreshold(uint8_t cHighThreshold)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameter */
+ s_assert_param(IS_AGC_THRESHOLD(cHighThreshold));
+
+ /* Reads the AGCCTRL_1 register */
+ SpiritSpiReadRegisters(AGCCTRL1_BASE, 1, &tempRegValue);
+
+ /* Mask the THRESHOLD_HIGH field and write the new value */
+ tempRegValue &= 0x0F;
+ tempRegValue |= cHighThreshold<<4;
+
+ /* Sets the AGCCTRL_1 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL1_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AGC high threshold.
+* @param None.
+* @retval uint8_t AGC high threshold read from the THRESHOLD_HIGH field of AGCCTRL_1 register.
+* This parameter will be in the range [0:15].
+*/
+uint8_t SpiritRadioGetAGCHighThreshold(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AGCCTRL_1 register, mask the THRESHOLD_HIGH field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(AGCCTRL1_BASE, 1, &tempRegValue);
+
+ return ((tempRegValue & 0xF0)>>4);
+
+}
+
+
+/**
+* @brief Sets the AGC low threshold.
+* @param cLowThreshold AGC low threshold to write in the THRESHOLD_LOW field of AGCCTRL_1 register.
+* This parameter shall be in the range [0:15].
+* @retval None.
+*/
+void SpiritRadioSetAGCLowThreshold(uint8_t cLowThreshold)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameter */
+ s_assert_param(IS_AGC_THRESHOLD(cLowThreshold));
+
+ /* Reads the AGCCTRL_1 register */
+ SpiritSpiReadRegisters(AGCCTRL1_BASE, 1, &tempRegValue);
+
+ /* Mask the THRESHOLD_LOW field and write the new value */
+ tempRegValue &= 0xF0;
+ tempRegValue |= cLowThreshold;
+
+ /* Sets the AGCCTRL_1 register */
+ g_xStatus = SpiritSpiWriteRegisters(AGCCTRL1_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the AGC low threshold.
+* @param None.
+* @retval uint8_t AGC low threshold read from the THRESHOLD_LOW field of AGCCTRL_1 register.
+* This parameter will be in the range [0:15].
+*/
+uint8_t SpiritRadioGetAGCLowThreshold(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the AGCCTRL_1 register, mask the THRESHOLD_LOW field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(AGCCTRL1_BASE, 1, &tempRegValue);
+
+ return (tempRegValue & 0x0F);
+
+}
+
+
+/**
+* @brief Sets the clock recovery algorithm.
+* @param xMode the Clock Recovery mode. This parameter can be one of the values defined in @ref ClkRecMode :
+* @arg CLK_REC_PLL PLL alogrithm for clock recovery
+* @arg CLK_REC_DLL DLL alogrithm for clock recovery
+* @retval None.
+*/
+void SpiritRadioSetClkRecMode(ClkRecMode xMode)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameter */
+ s_assert_param(IS_CLK_REC_MODE(xMode));
+
+ /* Reads the FDEV_0 register */
+ SpiritSpiReadRegisters(FDEV0_BASE, 1, &tempRegValue);
+
+ /* Mask the CLOCK_REC_ALGO_SEL field and write the new value */
+ tempRegValue &= 0xF7;
+ tempRegValue |= (uint8_t)xMode;
+
+ /* Sets the FDEV_0 register */
+ g_xStatus = SpiritSpiWriteRegisters(FDEV0_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the Clock Recovery working mode.
+* @param None.
+* @retval ClkRecMode Clock Recovery mode. This parameter can be one of the values defined in @ref ClkRecMode :
+* @arg CLK_REC_PLL PLL alogrithm for clock recovery
+* @arg CLK_REC_DLL DLL alogrithm for clock recovery
+*/
+ClkRecMode SpiritRadioGetClkRecMode(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the FDEV_0 register, mask the CLOCK_REC_ALGO_SEL field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(FDEV0_BASE, 1, &tempRegValue);
+
+ return (ClkRecMode)(tempRegValue & 0x08);
+
+}
+
+
+/**
+* @brief Sets the clock recovery proportional gain.
+* @param cPGain the Clock Recovery proportional gain to write in the CLK_REC_P_GAIN field of CLOCKREC register.
+* It represents is log2 value of the clock recovery proportional gain.
+* This parameter shall be in the range [0:7].
+* @retval None.
+*/
+void SpiritRadioSetClkRecPGain(uint8_t cPGain)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameter */
+ s_assert_param(IS_CLK_REC_P_GAIN(cPGain));
+
+ /* Reads the CLOCKREC register */
+ SpiritSpiReadRegisters(CLOCKREC_BASE, 1, &tempRegValue);
+
+ /* Mask the CLK_REC_P_GAIN field and write the new value */
+ tempRegValue &= 0x1F;
+ tempRegValue |= (cPGain<<5);
+
+ /* Sets the CLOCKREC register */
+ g_xStatus = SpiritSpiWriteRegisters(CLOCKREC_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the log2 of the clock recovery proportional gain.
+* @param None.
+* @retval uint8_t Clock Recovery proportional gain read from the CLK_REC_P_GAIN field of CLOCKREC register.
+* This parameter will be in the range [0:7].
+*/
+uint8_t SpiritRadioGetClkRecPGain(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the CLOCKREC register, mask the CLK_REC_P_GAIN field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(CLOCKREC_BASE, 1, &tempRegValue);
+
+ return ((tempRegValue & 0xEF)>>5);
+
+}
+
+
+/**
+* @brief Sets the clock recovery integral gain.
+* @param cIGain the Clock Recovery integral gain to write in the CLK_REC_I_GAIN field of CLOCKREC register.
+* This parameter shall be in the range [0:15].
+* @retval None.
+*/
+void SpiritRadioSetClkRecIGain(uint8_t cIGain)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameter */
+ s_assert_param(IS_CLK_REC_I_GAIN(cIGain));
+
+ /* Reads the CLOCKREC register */
+ SpiritSpiReadRegisters(CLOCKREC_BASE, 1, &tempRegValue);
+
+ /* Mask the CLK_REC_P_GAIN field and write the new value */
+ tempRegValue &= 0xF0;
+ tempRegValue |= cIGain;
+
+ /* Sets the CLOCKREC register */
+ g_xStatus = SpiritSpiWriteRegisters(CLOCKREC_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the clock recovery integral gain.
+* @param None.
+* @retval uint8_t Clock Recovery integral gain read from the
+* CLK_REC_I_GAIN field of CLOCKREC register.
+* This parameter will be in the range [0:15].
+*/
+uint8_t SpiritRadioGetClkRecIGain(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the CLOCKREC register, mask the CLK_REC_I_GAIN field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(CLOCKREC_BASE, 1, &tempRegValue);
+
+ return (tempRegValue & 0x0F);
+
+}
+
+
+/**
+* @brief Sets the postfilter length for clock recovery algorithm.
+* @param xLength the postfilter length in symbols. This parameter can be one of the values defined in @ref PstFltLength :
+* @arg PSTFLT_LENGTH_8 Postfilter length is 8 symbols
+* @arg PSTFLT_LENGTH_16 Postfilter length is 16 symbols
+* @retval None.
+*/
+void SpiritRadioSetClkRecPstFltLength(PstFltLength xLength)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameter */
+ s_assert_param(IS_PST_FLT_LENGTH(xLength));
+
+ /* Reads the CLOCKREC register */
+ SpiritSpiReadRegisters(CLOCKREC_BASE, 1, &tempRegValue);
+
+ /* Mask the PSTFLT_LEN field and write the new value */
+ tempRegValue &= 0xEF;
+ tempRegValue |= (uint8_t)xLength;
+
+ /* Sets the CLOCKREC register */
+ g_xStatus = SpiritSpiWriteRegisters(CLOCKREC_BASE, 1, &tempRegValue);
+
+}
+
+
+/**
+* @brief Returns the postfilter length for clock recovery algorithm.
+* @param None.
+* @retval PstFltLength Postfilter length in symbols. This parameter can be one of the values defined in @ref PstFltLength :
+* @arg PSTFLT_LENGTH_8 Postfilter length is 8 symbols
+* @arg PSTFLT_LENGTH_16 Postfilter length is 16 symbols
+*/
+PstFltLength SpiritRadioGetClkRecPstFltLength(void)
+{
+ uint8_t tempRegValue;
+
+ /* Reads the CLOCKREC register, mask the PSTFLT_LEN field and return the value */
+ g_xStatus = SpiritSpiReadRegisters(CLOCKREC_BASE, 1, &tempRegValue);
+
+ return (PstFltLength)(tempRegValue & 0x10);
+
+}
+
+
+/**
+* @brief Enables or Disables the received data blanking when the CS is under the threshold.
+* @param xNewState new state of this mode.
+* This parameter can be: S_ENABLE or S_DISABLE .
+* @retval None.
+*/
+void SpiritRadioCsBlanking(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the ANT_SELECT_CONF_BASE and mask the CS_BLANKING BIT field */
+ SpiritSpiReadRegisters(ANT_SELECT_CONF_BASE, 1, &tempRegValue);
+
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= ANT_SELECT_CS_BLANKING_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~ANT_SELECT_CS_BLANKING_MASK);
+ }
+
+ /* Writes the new value in the ANT_SELECT_CONF register */
+ g_xStatus = SpiritSpiWriteRegisters(ANT_SELECT_CONF_BASE, 1, &tempRegValue);
+
+
+}
+
+/**
+* @brief Enables or Disables the persistent RX mode.
+* @param xNewState new state of this mode.
+* This parameter can be: S_ENABLE or S_DISABLE .
+* @retval None.
+*/
+void SpiritRadioPersistenRx(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the PROTOCOL0_BASE and mask the PROTOCOL0_PERS_RX_MASK bitfield */
+ SpiritSpiReadRegisters(PROTOCOL0_BASE, 1, &tempRegValue);
+
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= PROTOCOL0_PERS_RX_MASK;
+ }
+ else
+ {
+ tempRegValue &= (~PROTOCOL0_PERS_RX_MASK);
+ }
+
+ /* Writes the new value in the PROTOCOL0_BASE register */
+ g_xStatus = SpiritSpiWriteRegisters(PROTOCOL0_BASE, 1, &tempRegValue);
+
+}
+
+/**
+* @brief Enables or Disables the synthesizer reference divider.
+* @param xNewState new state for synthesizer reference divider.
+* This parameter can be: S_ENABLE or S_DISABLE .
+* @retval None.
+*/
+void SpiritRadioSetRefDiv(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the SYNTH_CONFIG1_BASE and mask the REFDIV bit field */
+ SpiritSpiReadRegisters(SYNTH_CONFIG1_BASE, 1, &tempRegValue);
+
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue |= 0x80;
+ }
+ else
+ {
+ tempRegValue &= 0x7F;
+ }
+
+ /* Writes the new value in the SYNTH_CONFIG1_BASE register */
+ g_xStatus = SpiritSpiWriteRegisters(SYNTH_CONFIG1_BASE, 1, &tempRegValue);
+
+}
+
+/**
+* @brief Get the the synthesizer reference divider state.
+* @param void.
+* @retval None.
+*/
+SpiritFunctionalState SpiritRadioGetRefDiv(void)
+{
+ uint8_t tempRegValue;
+
+ g_xStatus = SpiritSpiReadRegisters(SYNTH_CONFIG1_BASE, 1, &tempRegValue);
+
+ if(((tempRegValue>>7)&0x1))
+ {
+ return S_ENABLE;
+ }
+ else
+ {
+ return S_DISABLE;
+ }
+
+}
+
+/**
+* @brief Enables or Disables the synthesizer reference divider.
+* @param xNewState new state for synthesizer reference divider.
+* This parameter can be: S_ENABLE or S_DISABLE .
+* @retval None.
+*/
+void SpiritRadioSetDigDiv(SpiritFunctionalState xNewState)
+{
+ uint8_t tempRegValue;
+
+ /* Check the parameters */
+ s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));
+
+ /* Reads the XO_RCO_TEST_BASE and mask the PD_CLKDIV bit field */
+ SpiritSpiReadRegisters(XO_RCO_TEST_BASE, 1, &tempRegValue);
+
+ if(xNewState == S_ENABLE)
+ {
+ tempRegValue &= 0xf7;
+ }
+ else
+ {
+
+ tempRegValue |= 0x08;
+ }
+
+ /* Writes the new value in the XO_RCO_TEST_BASE register */
+ g_xStatus = SpiritSpiWriteRegisters(XO_RCO_TEST_BASE, 1, &tempRegValue);
+
+}
+
+/**
+* @brief Get the the synthesizer reference divider state.
+* @param void.
+* @retval None.
+*/
+SpiritFunctionalState SpiritRadioGetDigDiv(void)
+{
+ uint8_t tempRegValue;
+
+ g_xStatus = SpiritSpiReadRegisters(XO_RCO_TEST_BASE, 1, &tempRegValue);
+
+ if(((tempRegValue>>3)&0x1))
+ {
+ return S_DISABLE;
+ }
+ else
+ {
+ return S_ENABLE;
+ }
+
+}
+
+/**
+* @brief Returns the XTAL frequency.
+* @param void.
+* @retval uint32_t XTAL frequency.
+*/
+uint32_t SpiritRadioGetXtalFrequency(void)
+{
+ return s_lXtalFrequency;
+}
+
+/**
+* @brief Sets the XTAL frequency.
+* @param uint32_t XTAL frequency.
+* @retval void.
+*/
+void SpiritRadioSetXtalFrequency(uint32_t lXtalFrequency)
+{
+ s_lXtalFrequency = lXtalFrequency;
+}
+
+/**
+* @}
+*/
+
+
+/**
+* @}
+*/
+
+
+/**
+* @}
+*/
+
+
+
+/******************* (C) COPYRIGHT 2015 STMicroelectronics *****END OF FILE****/
+