/*! \file ********************************************************************* * * \brief API for SAM3 Analog-to-Digital Converter (ADC/ADC12B) controller. * * ---------------------------------------------------------------------------- * SAM Software Package License * ---------------------------------------------------------------------------- * Copyright (c) 2011, Atmel Corporation * * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * - Redistributions of source code must retain the above copyright notice, * this list of conditions and the disclaimer below. * * Atmel's name may not be used to endorse or promote products derived from * this software without specific prior written permission. * * DISCLAIMER: THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE * DISCLAIMED. IN NO EVENT SHALL ATMEL 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. * * - Compiler: IAR EWARM and CodeSourcery GCC for ARM * - Supported devices: All SAM devices with a Analog-to-Digital Converter can be used. * - AppNote: * * \author Atmel Corporation: http://www.atmel.com \n * Support and FAQ: http://support.atmel.com/ * *******************************************************************************/ #include "../chip.h" /// @cond 0 /**INDENT-OFF**/ #ifdef __cplusplus extern "C" { #endif /* __cplusplus */ /**INDENT-ON**/ /// @endcond #if SAM3U /** * \brief Initializes the given ADC with the specified ADC clock and startup time. * * \param p_adc Pointer to an ADC instance. * \param dw_mck Main clock of the device (value in Hz). * \param dw_adc_clock Analog-to-Digital conversion clock (value in Hz). * \param ul_startuptime ADC start up time value(value in us). Please refer to the product datasheet for details. * \param ul_offmode_startuptime ADC off mode startup Time value(value in us). Please refer to the product datasheet for details. * * \retval 0 The initialization operation succeeds. * \retval others The initialization operation fails. */ uint32_t adc12_init(Adc12b *p_adc, uint32_t ul_mck, uint32_t ul_adc_clock, uint32_t ul_startuptime, uint32_t ul_offmode_startuptime) { p_adc->ADC12B_CR = ADC12B_CR_SWRST; /* Reset Mode Register */ p_adc->ADC12B_MR = 0; /* Reset PDC transfer */ p_adc->ADC12B_PTCR = (ADC12B_PTCR_RXTDIS | ADC12B_PTCR_TXTDIS); p_adc->ADC12B_RCR = 0; p_adc->ADC12B_RNCR = 0; p_adc->ADC12B_TCR = 0; p_adc->ADC12B_TNCR = 0; uint32_t prescal = ul_mck/(2 * ul_adc_clock) - 1; // check for rounding errors if ( (ul_mck/((prescal+1)*2)) > ul_adc_clock ) { prescal++; ul_adc_clock = ul_mck/((prescal+1)*2); } uint32_t startup = ((ul_adc_clock/1000000) * ul_startuptime / 8) - 1; p_adc->ADC12B_MR |= ADC12B_MR_PRESCAL(prescal) | ADC12B_MR_STARTUP(startup); uint32_t offmode = ((ul_adc_clock/1000000) * ul_offmode_startuptime / 8) - 1; p_adc->ADC12B_EMR |= ADC12B_EMR_OFF_MODE_STARTUP_TIME(offmode); return 0; } /** * \brief Configures conversion resolution. * * \param p_adc Pointer to an ADC instance. * \param resolution ADC resolution. */ void adc12_set_resolution(Adc12b *p_adc, adc_resolution_t resolution) { p_adc->ADC12B_MR |= (resolution<<4) & ADC12B_MR_LOWRES; } /** * \brief Configures conversion trigger and free run mode. * * \param p_adc Pointer to an ADC instance. * \param trigger Conversion trigger. */ void adc12_configure_trigger(Adc12b *p_adc, adc_trigger_t trigger) { p_adc->ADC12B_MR |= trigger; } /** * \brief Configures ADC power saving mode. * * \param p_adc Pointer to an ADC instance. * \param uc_sleep ADC_MR_SLEEP_NORMAL keeps the ADC Core and reference voltage circuitry ON between conversions * ADC_MR_SLEEP_SLEEP keeps the ADC Core and reference voltage circuitry OFF between conversions * \param uc_offmode 0 Standby Mode (if Sleep Bit = 1) * 1 Off Mode */ void adc12_configure_power_save(Adc12b *p_adc, uint8_t uc_sleep, uint8_t uc_offmode) { p_adc->ADC12B_MR |= ((uc_sleep<<5) & ADC12B_MR_SLEEP) ; p_adc->ADC12B_EMR |= uc_offmode; } /** * \brief Configures ADC timing. * * \param p_adc Pointer to an ADC instance. * \param ul_sh ADC sample and hold time = uc_sh / ADC clock. * */ void adc12_configure_timing(Adc12b *p_adc, uint32_t ul_sh) { p_adc->ADC12B_MR |= ADC12B_MR_SHTIM( ul_sh ) ; } /** * \brief Starts analog-to-digital conversion. * * \note If one of the hardware event is selected as ADC trigger, this function can NOT start analog to digital conversion. * * \param p_adc Pointer to an ADC instance. */ void adc12_start(Adc12b *p_adc) { p_adc->ADC12B_CR = ADC12B_CR_START; } /** * \brief Stop analog-to-digital conversion. * \param p_adc Pointer to an ADC instance. */ void adc12_stop(Adc12b *p_adc) { p_adc->ADC12B_CR = ADC12B_CR_SWRST; } /** * \brief Enables the specified ADC channel. * * \param p_adc Pointer to an ADC instance. * \param adc_ch ADC channel number. */ void adc12_enable_channel(Adc12b *p_adc, adc_channel_num_t adc_ch) { p_adc->ADC12B_CHER = 1 << adc_ch; } /** * \brief Disables the specified ADC channel. * * \param p_adc Pointer to an ADC instance. * \param adc_ch ADC channel number. */ void adc12_disable_channel(Adc12b *p_adc, adc_channel_num_t adc_ch) { p_adc->ADC12B_CHDR = 1 << adc_ch; } /** * \brief Reads the ADC channel status. * * \param p_adc Pointer to an ADC instance. * \param adc_ch ADC channel number. * * \retval 1 means the specified channel is enabled. * 0 means the specified channel is disabled. */ uint32_t adc12_get_channel_status(Adc12b *p_adc, adc_channel_num_t adc_ch) { return p_adc->ADC12B_CHSR & (1 << adc_ch); } /** * \brief Reads the ADC status. * * \param p_adc Pointer to an ADC instance. * * \retval ADC status register content. */ uint32_t adc12_get_status(Adc12b *p_adc) { return p_adc->ADC12B_SR; } /** * \brief Reads the ADC result data of the specified channel. * * \param p_adc Pointer to an ADC instance. * \param adc_ch ADC channel number. * * \retval ADC data of the specified channel. */ uint32_t adc12_get_value(Adc12b *p_adc, adc_channel_num_t adc_ch) { uint32_t dwData = 0; if ( 15 >= adc_ch ) { dwData=*(p_adc->ADC12B_CDR+adc_ch) ; } return dwData ; } /** * \brief Reads the last ADC result data. * * \param p_adc Pointer to an ADC instance. * * \retval ADC data. */ uint32_t adc12_get_latest_value(Adc12b *p_adc) { return p_adc->ADC12B_LCDR; } /** * \brief Enables differential input for all channels. * * \param p_adc Pointer to an ADC instance. */ void adc12_enable_differential_input(Adc12b *p_adc) { p_adc->ADC12B_ACR |= (0x01u << 16); } /** * \brief Disables differential input for the specified channel. * * \param p_adc Pointer to an ADC instance. */ void adc12_disable_differential_input(Adc12b*p_adc) { p_adc->ADC12B_ACR &= (0x01u << 16); } /** * \brief Enables analog signal offset for the specified channel. * * \param p_adc Pointer to an ADC instance. */ void adc12_enable_input_offset(Adc12b *p_adc) { p_adc->ADC12B_ACR |= (0x01u << 17); } /** * \brief Disables analog signal offset for the specified channel. * * \param p_adc Pointer to an ADC instance. */ void adc12_disable_input_offset(Adc12b *p_adc) { p_adc->ADC12B_ACR &= (0x01u << 17); } /** * \brief Configures input gain for the specified channel. * * \param p_adc Pointer to an ADC instance. * \param gain Gain value for the input. */ void adc12_set_input_gain(Adc12b *p_adc, adc_gainvalue_t gain) { p_adc->ADC12B_ACR |= (0x03u & gain); } uint32_t adc12_get_actual_adc_clock(Adc12b *p_adc, uint32_t ul_mck) { uint32_t ul_adcfreq; uint32_t ul_prescal; /* ADCClock = MCK / ( (PRESCAL+1) * 2 ) */ ul_prescal = (( p_adc->ADC12B_MR & ADC12B_MR_PRESCAL_Msk) >> ADC12B_MR_PRESCAL_Pos); ul_adcfreq = ul_mck / ((ul_prescal+1)*2); return ul_adcfreq; } /** * \brief Enables ADC interrupt(s). * * \param p_adc Pointer to an ADC instance. * \param dw_source Interrupt(s) to be enabled. */ void adc12_enable_interrupt(Adc12b *p_adc, uint32_t ul_source) { p_adc->ADC12B_IER = ul_source; } /** * \brief Disables ADC interrupt(s). * * \param p_adc Pointer to an ADC instance. * \param dw_source Interrupt(s) to be disabled. */ void adc12_disable_interrupt(Adc12b *p_adc, uint32_t ul_source) { p_adc->ADC12B_IDR = ul_source; } /** \brief Read ADC interrupt mask. * * \param p_uart pointer to a UART instance. * * \return The interrupt mask value. */ uint32_t adc12_get_interrupt_mask(Adc12b *p_adc) { return p_adc->ADC12B_IMR; } /** * \brief Reads ADC interrupt status. * * \param p_adc Pointer to an ADC instance. * * \retval ADC interrupt status. */ uint32_t adc12_get_interrupt_status(Adc12b *p_adc) { return p_adc->ADC12B_SR ; } /** * \brief Reads overrun status. * * \param p_adc Pointer to an ADC instance. * * \retval ADC overrun status. */ uint32_t adc12_check_ovr(Adc12b *p_adc,adc_channel_num_t adc_ch) { return p_adc->ADC12B_SR & (0x01u << (adc_ch+8)); } /** * \brief Adapts performance versus power consumption. * * \note Please refer to ADC Characteristics in the product datasheet for the details. * * \param p_adc Pointer to an ADC instance. * \param ibctl ADC Bias current control. */ void adc12_set_bias_current(Adc12b *p_adc, uint8_t uc_ibctl) { p_adc->ADC12B_ACR |= ADC12B_ACR_IBCTL(uc_ibctl); } /** * \brief Gets PDC registers base address. * * \param p_adc Pointer to an ADC instance. * * \retval PDC registers base for PDC driver to access. */ Pdc *adc12_get_pdc_base(Adc12b *p_adc) { return PDC_ADC12B; } /// @cond 0 /**INDENT-OFF**/ #ifdef __cplusplus } #endif /* __cplusplus */ /**INDENT-ON**/ /// @endcond #endif /* SAM3U */