//***************************************************************************** // // am_hal_adc.h //! @file //! //! @brief Functions for interfacing with the Analog to Digital Converter //! //! @addtogroup adc2 Analog-to-Digital Converter (ADC) //! @ingroup apollo2hal //! @{ // //***************************************************************************** //***************************************************************************** // // Copyright (c) 2017, Ambiq Micro // All rights reserved. // // 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 the copyright holder 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. // // This is part of revision 1.2.9 of the AmbiqSuite Development Package. // //***************************************************************************** #ifndef AM_HAL_ADC_H #define AM_HAL_ADC_H #ifdef __cplusplus extern "C" { #endif //***************************************************************************** // //! @name Clock Selection //! @brief These macros may be used to set the ADC module's clock source. //! @{ // //***************************************************************************** #define AM_HAL_ADC_CLOCK_OFF AM_REG_ADC_CFG_CLKSEL_OFF #define AM_HAL_ADC_CLOCK_HFRC AM_REG_ADC_CFG_CLKSEL_HFRC #define AM_HAL_ADC_CLOCK_DIV2 AM_REG_ADC_CFG_CLKSEL_HFRC_DIV2 //! @} //***************************************************************************** // //! @name Trigger Settings //! @brief ADC trigger setting macros. //! //! These macros alter the ADC's trigger source and trigger polarity. Note that //! the external trigger setting needs to be ORed with a POS or NEG option to //! define the desired trigger polarity. //! @{ // //***************************************************************************** #define AM_HAL_ADC_TRIGGER_SOFT AM_REG_ADC_CFG_TRIGSEL_SWT #define AM_HAL_ADC_TRIGGER_VCOMP AM_REG_ADC_CFG_TRIGSEL_VCOMP #define AM_HAL_ADC_TRIGGER_EXT0 AM_REG_ADC_CFG_TRIGSEL_EXT0 #define AM_HAL_ADC_TRIGGER_EXT1 AM_REG_ADC_CFG_TRIGSEL_EXT1 #define AM_HAL_ADC_TRIGGER_EXT2 AM_REG_ADC_CFG_TRIGSEL_EXT2 #define AM_HAL_ADC_TRIGGER_EXT3 AM_REG_ADC_CFG_TRIGSEL_EXT3 #define AM_HAL_ADC_TRIGGER_FALL AM_REG_ADC_CFG_TRIGPOL_FALLING_EDGE #define AM_HAL_ADC_TRIGGER_RISE AM_REG_ADC_CFG_TRIGPOL_RISING_EDGE //! @} //***************************************************************************** // //! @name Reference Settings //! @brief ADC reference voltage setting macros. //! //! These macros control the ADC reference voltage source. //! @{ // //***************************************************************************** #define AM_HAL_ADC_REF_EXT_2P0 AM_REG_ADC_CFG_REFSEL_EXT2P0 #define AM_HAL_ADC_REF_EXT_1P5 AM_REG_ADC_CFG_REFSEL_EXT1P5 #define AM_HAL_ADC_REF_INT_2P0 AM_REG_ADC_CFG_REFSEL_INT2P0 #define AM_HAL_ADC_REF_INT_1P5 AM_REG_ADC_CFG_REFSEL_INT1P5 //! @} //***************************************************************************** // //! @name Clock Mode //! @brief ADC clock mode settings //! //! These macros determine whether the ADC shuts down its clock between //! samples. Shutting down the clock will reduce power consumption, but //! increase latency. This setting is only valid for LPMODE 0. For other modes, //! it will be ignored. //! //! @{ // //***************************************************************************** #define AM_HAL_ADC_CK_LOW_POWER AM_REG_ADC_CFG_CKMODE_LPCKMODE #define AM_HAL_ADC_CK_LOW_LATENCY AM_REG_ADC_CFG_CKMODE_LLCKMODE //! @} //***************************************************************************** // //! @name Low Power Mode //! @brief ADC power conservation settings. //! //! These macros select the power state to enter between active scans. Each low //! power mode has its own set of timing constraints. Please see the datasheet //! for additional timing information on each power mode. //! @{ // //***************************************************************************** #define AM_HAL_ADC_LPMODE_0 AM_REG_ADC_CFG_LPMODE_MODE0 #define AM_HAL_ADC_LPMODE_1 AM_REG_ADC_CFG_LPMODE_MODE1 //! @} //***************************************************************************** // //! @name Repeat Mode //! @brief Enable repeating scan mode. //! //! Use this macro to enable repeating scans using timer 3. //! //! @{ // //***************************************************************************** #define AM_HAL_ADC_REPEAT AM_REG_ADC_CFG_RPTEN(1) #define AM_HAL_ADC_NO_REPEAT AM_REG_ADC_CFG_RPTEN(0) //! @} //***************************************************************************** // //! @name Slot configuration //! @brief Slot configuration macros //! //! These macros may be used to configure an individual ADC slot. //! @{ // //***************************************************************************** // Set number of samples to average. #define AM_HAL_ADC_SLOT_AVG_1 AM_REG_ADC_SL0CFG_ADSEL0(0) #define AM_HAL_ADC_SLOT_AVG_2 AM_REG_ADC_SL0CFG_ADSEL0(1) #define AM_HAL_ADC_SLOT_AVG_4 AM_REG_ADC_SL0CFG_ADSEL0(2) #define AM_HAL_ADC_SLOT_AVG_8 AM_REG_ADC_SL0CFG_ADSEL0(3) #define AM_HAL_ADC_SLOT_AVG_16 AM_REG_ADC_SL0CFG_ADSEL0(4) #define AM_HAL_ADC_SLOT_AVG_32 AM_REG_ADC_SL0CFG_ADSEL0(5) #define AM_HAL_ADC_SLOT_AVG_64 AM_REG_ADC_SL0CFG_ADSEL0(6) #define AM_HAL_ADC_SLOT_AVG_128 AM_REG_ADC_SL0CFG_ADSEL0(7) // Set slot precision mode. #define AM_HAL_ADC_SLOT_14BIT AM_REG_ADC_SL0CFG_PRMODE0_P14B #define AM_HAL_ADC_SLOT_12BIT AM_REG_ADC_SL0CFG_PRMODE0_P14B #define AM_HAL_ADC_SLOT_10BIT AM_REG_ADC_SL0CFG_PRMODE0_P14B #define AM_HAL_ADC_SLOT_8BIT AM_REG_ADC_SL0CFG_PRMODE0_P14B // Select a channel by number. #define AM_HAL_ADC_SLOT_CHANNEL(n) AM_REG_ADC_SL0CFG_CHSEL0(n) // Single-ended channels #define AM_HAL_ADC_SLOT_CHSEL_SE0 AM_REG_ADC_SL0CFG_CHSEL0_SE0 #define AM_HAL_ADC_SLOT_CHSEL_SE1 AM_REG_ADC_SL0CFG_CHSEL0_SE1 #define AM_HAL_ADC_SLOT_CHSEL_SE2 AM_REG_ADC_SL0CFG_CHSEL0_SE2 #define AM_HAL_ADC_SLOT_CHSEL_SE3 AM_REG_ADC_SL0CFG_CHSEL0_SE3 #define AM_HAL_ADC_SLOT_CHSEL_SE4 AM_REG_ADC_SL0CFG_CHSEL0_SE4 #define AM_HAL_ADC_SLOT_CHSEL_SE5 AM_REG_ADC_SL0CFG_CHSEL0_SE5 #define AM_HAL_ADC_SLOT_CHSEL_SE6 AM_REG_ADC_SL0CFG_CHSEL0_SE6 #define AM_HAL_ADC_SLOT_CHSEL_SE7 AM_REG_ADC_SL0CFG_CHSEL0_SE7 #define AM_HAL_ADC_SLOT_CHSEL_SE8 AM_REG_ADC_SL0CFG_CHSEL0_SE8 #define AM_HAL_ADC_SLOT_CHSEL_SE9 AM_REG_ADC_SL0CFG_CHSEL0_SE9 // Differential channels. #define AM_HAL_ADC_SLOT_CHSEL_DF0 AM_REG_ADC_SL0CFG_CHSEL0_DF0 #define AM_HAL_ADC_SLOT_CHSEL_DF1 AM_REG_ADC_SL0CFG_CHSEL0_DF1 // Miscellaneous other signals. #define AM_HAL_ADC_SLOT_CHSEL_TEMP AM_REG_ADC_SL0CFG_CHSEL0_TEMP #define AM_HAL_ADC_SLOT_CHSEL_VSS AM_REG_ADC_SL0CFG_CHSEL0_VSS #define AM_HAL_ADC_SLOT_CHSEL_VBATT AM_REG_ADC_SL0CFG_CHSEL0_BATT // Window enable. #define AM_HAL_ADC_SLOT_WINDOW_EN AM_REG_ADC_SL0CFG_WCEN0(1) // Enable the slot. #define AM_HAL_ADC_SLOT_ENABLE AM_REG_ADC_SL0CFG_SLEN0(1) //! @} //***************************************************************************** // //! @name Interrupt Status Bits //! @brief Interrupt Status Bits for enable/disble use //! //! These macros may be used to enable an individual ADC interrupt cause. //! @{ // //***************************************************************************** #define AM_HAL_ADC_INT_WCINC AM_REG_ADC_INTEN_WCINC(1) #define AM_HAL_ADC_INT_WCEXC AM_REG_ADC_INTEN_WCEXC(1) #define AM_HAL_ADC_INT_FIFOOVR2 AM_REG_ADC_INTEN_FIFOOVR2(1) #define AM_HAL_ADC_INT_FIFOOVR1 AM_REG_ADC_INTEN_FIFOOVR1(1) #define AM_HAL_ADC_INT_SCNCMP AM_REG_ADC_INTEN_SCNCMP(1) #define AM_HAL_ADC_INT_CNVCMP AM_REG_ADC_INTEN_CNVCMP(1) //! @} //***************************************************************************** // //! @name Temperature Trim Value Locations //! @brief Temperature calibration cofficients are stored in readable space. //! //! These macros are used to access the temperature trim values in readable //! space. //! @{ // //***************************************************************************** #define AM_HAL_ADC_CALIB_TEMP_ADDR (0x50023010) #define AM_HAL_ADC_CALIB_AMBIENT_ADDR (0x50023014) #define AM_HAL_ADC_CALIB_ADC_OFFSET_ADDR (0x50023018) // // Default coefficients (used when trims not provided): // TEMP_DEFAULT = Temperature in deg K (e.g. 299.5 - 273.15 = 26.35) // AMBIENT_DEFAULT = Voltage measurement at default temperature. // OFFSET_DEFAULT = Default ADC offset at 1v. // #define AM_HAL_ADC_CALIB_TEMP_DEFAULT (299.5F) #define AM_HAL_ADC_CALIB_AMBIENT_DEFAULT (1.02809F) #define AM_HAL_ADC_CALIB_ADC_OFFSET_DEFAULT (-0.004281F) //! @} //***************************************************************************** // //! @brief Configuration structure for the ADC. // //***************************************************************************** typedef struct { //! Select the ADC Clock source using one of the clock source macros. uint32_t ui32Clock; //! Select the ADC trigger source using a trigger source macro. uint32_t ui32TriggerConfig; //! Use a macro to select the ADC reference voltage. uint32_t ui32Reference; //! Use a macro to decide whether to disable clocks between samples. uint32_t ui32ClockMode; //! Use a macro to select the ADC power mode. uint32_t ui32PowerMode; //! Select whether the ADC will re-trigger based on a signal from timer 3. uint32_t ui32Repeat; } am_hal_adc_config_t; //***************************************************************************** // //! @brief ADC Fifo Read macros //! //! These are helper macros for interpreting FIFO data. Each ADC FIFO entry //! contains information about the slot number and the FIFO depth alongside the //! current sample. These macros perform the correct masking and shifting to //! read those values. //! //! The SAMPLE and FULL_SAMPLE options refer to the fractional part of averaged //! samples. If you are not using hardware averaging or don't need the //! fractional part of the ADC sample, you should just use //! AM_HAL_ADC_FIFO_SAMPLE. //! //! If you do need the fractional part, use AM_HAL_ADC_FIFO_FULL_SAMPLE. This //! macro will keep six bits of precision past the decimal point. Depending on //! the number of averaged samples, anywhere between 1 and 6 of these bits will //! be valid. Please consult the datasheet to find out how many bits of data //! are valid for your chosen averaging settings. //! //! @{ // //***************************************************************************** #define AM_HAL_ADC_FIFO_SAMPLE(value) \ ((((value) & AM_REG_ADC_FIFO_DATA_M) >> AM_REG_ADC_FIFO_DATA_S) >> 6) #define AM_HAL_ADC_FIFO_FULL_SAMPLE(value) \ (((value) & AM_REG_ADC_FIFO_DATA_M) >> AM_REG_ADC_FIFO_DATA_S ) #define AM_HAL_ADC_FIFO_SLOT(value) \ (((value) & AM_REG_ADC_FIFO_SLOTNUM_M) >> AM_REG_ADC_FIFO_SLOTNUM_S) #define AM_HAL_ADC_FIFO_COUNT(value) \ (((value) & AM_REG_ADC_FIFO_COUNT_M) >> AM_REG_ADC_FIFO_COUNT_S) //! @} //***************************************************************************** // // External function definitions // //***************************************************************************** extern void am_hal_adc_config(am_hal_adc_config_t *psConfig); extern void am_hal_adc_window_set(uint32_t ui32Upper, uint32_t ui32Lower); extern void am_hal_adc_slot_config(uint32_t ui32SlotNumber, uint32_t ui32SlotConfig); extern uint32_t am_hal_adc_fifo_peek(void); extern uint32_t am_hal_adc_fifo_pop(void); extern void am_hal_adc_trigger(void); extern void am_hal_adc_enable(void); extern void am_hal_adc_disable(void); extern void am_hal_adc_int_enable(uint32_t ui32Interrupt); extern uint32_t am_hal_adc_int_enable_get(void); extern void am_hal_adc_int_disable(uint32_t ui32Interrupt); extern void am_hal_adc_int_clear(uint32_t ui32Interrupt); extern void am_hal_adc_int_set(uint32_t ui32Interrupt); extern uint32_t am_hal_adc_int_status_get(bool bEnabledOnly); extern float am_hal_adc_volts_to_celsius(float fVoltage); extern void am_hal_adc_temp_trims_get(float * pfTemp, float * pfVoltage, float * pfOffsetV); #ifdef __cplusplus } #endif #endif // AM_HAL_ADC_H //***************************************************************************** // // End Doxygen group. //! @} // //*****************************************************************************