osd-contiki/cpu/stm32w108/hal/micro/adc.h
2011-03-22 19:35:49 +01:00

296 lines
10 KiB
C

/** @file /hal/micro/adc.h
* @brief Header for A/D converter.
*
* <!--(C) COPYRIGHT 2010 STMicroelectronics. All rights reserved. -->
*/
/** @addtogroup adc
* Sample A/D converter driver.
*
* See adc.h for source code.
*
* @note Stm32w108xx ADC driver support is preliminary and essentailly untested -
* please do not attempt to use this ADC driver on this platform.
*
* @note Except for the Stm32w108xx, the StZNet stack does use these functions.
*
* To use the ADC system, include this file and ensure that
* ::halInternalInitAdc() is called whenever the microcontroller is
* started.
*
* A "user" is a separate thread of execution and usage. That is,
* internal St code is one user and clients are a different user.
* But a client that is calling the ADC in two different functions
* constitutes only one user, as long as the ADC access is not
* interleaved.
*
* @note This code does not allow access to the continuous reading mode of
* the ADC, which some clients may require.
*
* Many functions in this file return an ::StStatus value. See
* error-def.h for definitions of all ::StStatus return values.
*
*@{
*/
#ifndef __ADC_H__
#define __ADC_H__
// A type for the ADC User enumeration.
typedef int8u ADCUser;
enum
{
/** LQI User ID. */
ADC_USER_LQI = 0,
/** Application User ID */
ADC_USER_APP = 1,
/** Application User ID */
ADC_USER_APP2 = 2
};
/** @brief Be sure to update ::NUM_ADC_USERS if additional users are added
* to the ::ADCUser list.
*/
#define NUM_ADC_USERS 3 // make sure to update if the above is adjusted
// A type for the reference enumeration.
typedef int8u ADCReferenceType;
enum
{
/** AREF pin reference. */
ADC_REF_AREF = 0x00,
/** AVCC pin reference. */
ADC_REF_AVCC = 0x40,
/** Internal reference. */
ADC_REF_INT = 0xC0
};
// A type for the rate enumeration.
typedef int8u ADCRateType;
enum
{
/** Rate 32 us, 5 effective bits in ADC_DATA[15:11] */
ADC_CONVERSION_TIME_US_32 = 0x0,
/** Rate 64 us, 6 effective bits in ADC_DATA[15:10] */
ADC_CONVERSION_TIME_US_64 = 0x1,
/** Rate 128 us, 7 effective bits in ADC_DATA[15:9] */
ADC_CONVERSION_TIME_US_128 = 0x2,
/** Rate 256 us, 8 effective bits in ADC_DATA[15:8] */
ADC_CONVERSION_TIME_US_256 = 0x3,
/** Rate 512 us, 9 effective bits in ADC_DATA[15:7] */
ADC_CONVERSION_TIME_US_512 = 0x4,
/** Rate 1024 us, 10 effective bits in ADC_DATA[15:6] */
ADC_CONVERSION_TIME_US_1024 = 0x5,
/** Rate 2048 us, 11 effective bits in ADC_DATA[15:5] */
ADC_CONVERSION_TIME_US_2048 = 0x6,
/** Rate 4096 us, 12 effective bits in ADC_DATA[15:4] */
ADC_CONVERSION_TIME_US_4096 = 0x7,
};
#if defined (CORTEXM3)
/** Channel 0 : ADC0 on PB5 */
#define ADC_MUX_ADC0 0x0
/** Channel 1 : ADC0 on PB6 */
#define ADC_MUX_ADC1 0x1
/** Channel 2 : ADC0 on PB7 */
#define ADC_MUX_ADC2 0x2
/** Channel 3 : ADC0 on PC1 */
#define ADC_MUX_ADC3 0x3
/** Channel 4 : ADC0 on PA4 */
#define ADC_MUX_ADC4 0x4
/** Channel 5 : ADC0 on PA5 */
#define ADC_MUX_ADC5 0x5
/** Channel 8 : VSS (0V) - not for high voltage range */
#define ADC_MUX_GND 0x8
/** Channel 9 : VREF/2 (0.6V) */
#define ADC_MUX_VREF2 0x9
/** Channel A : VREF (1.2V)*/
#define ADC_MUX_VREF 0xA
/** Channel B : Regulator/2 (0.9V) - not for high voltage range */
#define ADC_MUX_VREG2 0xB
// ADC_SOURCE_<pos>_<neg> selects <pos> as the positive input and <neg> as
// the negative input.
enum
{
ADC_SOURCE_ADC0_VREF2 = ((ADC_MUX_ADC0 <<ADC_MUXN_BITS) + ADC_MUX_VREF2),
ADC_SOURCE_ADC0_GND = ((ADC_MUX_ADC0 <<ADC_MUXN_BITS) + ADC_MUX_GND),
ADC_SOURCE_ADC1_VREF2 = ((ADC_MUX_ADC1 <<ADC_MUXN_BITS) + ADC_MUX_VREF2),
ADC_SOURCE_ADC1_GND = ((ADC_MUX_ADC1 <<ADC_MUXN_BITS) + ADC_MUX_GND),
ADC_SOURCE_ADC2_VREF2 = ((ADC_MUX_ADC2 <<ADC_MUXN_BITS) + ADC_MUX_VREF2),
ADC_SOURCE_ADC2_GND = ((ADC_MUX_ADC2 <<ADC_MUXN_BITS) + ADC_MUX_GND),
ADC_SOURCE_ADC3_VREF2 = ((ADC_MUX_ADC3 <<ADC_MUXN_BITS) + ADC_MUX_VREF2),
ADC_SOURCE_ADC3_GND = ((ADC_MUX_ADC3 <<ADC_MUXN_BITS) + ADC_MUX_GND),
ADC_SOURCE_ADC4_VREF2 = ((ADC_MUX_ADC4 <<ADC_MUXN_BITS) + ADC_MUX_GND),
ADC_SOURCE_ADC5_VREF2 = ((ADC_MUX_ADC5 <<ADC_MUXN_BITS) + ADC_MUX_GND),
ADC_SOURCE_ADC1_ADC0 = ((ADC_MUX_ADC1 <<ADC_MUXN_BITS) + ADC_MUX_ADC0),
ADC_SOURCE_ADC0_ADC1 = ((ADC_MUX_ADC1 <<ADC_MUXN_BITS) + ADC_MUX_ADC0),
ADC_SOURCE_ADC3_ADC2 = ((ADC_MUX_ADC3 <<ADC_MUXN_BITS) + ADC_MUX_ADC2),
ADC_SOURCE_ADC2_ADC3 = ((ADC_MUX_ADC3 <<ADC_MUXN_BITS) + ADC_MUX_ADC2),
ADC_SOURCE_ADC5_ADC4 = ((ADC_MUX_ADC5 <<ADC_MUXN_BITS) + ADC_MUX_ADC4),
ADC_SOURCE_GND_VREF2 = ((ADC_MUX_GND <<ADC_MUXN_BITS) + ADC_MUX_VREF2),
ADC_SOURCE_VGND = ((ADC_MUX_GND <<ADC_MUXN_BITS) + ADC_MUX_GND),
ADC_SOURCE_VREF_VREF2 = ((ADC_MUX_VREF <<ADC_MUXN_BITS) + ADC_MUX_VREF2),
ADC_SOURCE_VREF = ((ADC_MUX_VREF <<ADC_MUXN_BITS) + ADC_MUX_GND),
/* Modified the original ADC driver for enabling the ADC extended range mode required for
supporting the STLM20 temperature sensor.
NOTE:
The ADC extended range is inaccurate due to the high voltage mode bug of the general purpose ADC
(see STM32W108 errata). As consequence, it is not reccomended to use this ADC driver for getting
the temperature values
*/
#ifdef ENABLE_ADC_EXTENDED_RANGE_BROKEN
ADC_SOURCE_VREF2_VREF2 = ((ADC_MUX_VREF2 <<ADC_MUXN_BITS) + ADC_MUX_VREF2),
ADC_SOURCE_VREF2 = ((ADC_MUX_VREF2 <<ADC_MUXN_BITS) + ADC_MUX_GND),
#endif /* ENABLE_ADC_EXTENDED_RANGE_BROKEN */
ADC_SOURCE_VREG2_VREF2 = ((ADC_MUX_VREG2 <<ADC_MUXN_BITS) + ADC_MUX_VREF2),
ADC_SOURCE_VDD_GND = ((ADC_MUX_VREG2 <<ADC_MUXN_BITS) + ADC_MUX_GND)
};
#endif // defined (CORTEXM3)
/** @brief A type for the channel enumeration
* (such as ::ADC_SOURCE_ADC0_GND)
*/
typedef int8u ADCChannelType;
/** @brief Initializes and powers-up the ADC.
*/
void halInternalInitAdc(void);
/** @brief Starts an ADC conversion for the user specified by \c id.
*
* @appusage The application must set \c reference to the voltage
* reference desired (see the ADC references enum),
* set \c channel to the channel number
* required (see the ADC channel enum), and set \c rate to reflect the
* number of bits of accuracy desired (see the ADC rates enum)
*
* @param id An ADC user.
*
* @param reference Voltage reference to use, chosen from enum
*
* @param channel Microprocessor channel number.
*
* @param rate rate number (see the ADC rate enum).
*
* @return One of the following:
* - ADC_CONVERSION_DEFERRED if the conversion is still waiting
* to start.
* - ADC_CONVERSION_BUSY if the conversion is currently taking
* place.
* - ST_ERR_FATAL if a passed parameter is invalid.
*/
StStatus halStartAdcConversion(ADCUser id,
ADCReferenceType reference,
ADCChannelType channel,
ADCRateType rate);
/** @brief Returns the status of a pending conversion
* previously started by ::halStartAdcConversion(). If the conversion
* is complete, writes the raw register value of the conversion (the unaltered
* value taken directly from the ADC's data register) into \c value.
*
* @param id An ADC user.
*
* @param value Pointer to an int16u to be loaded with the new value.
*
* @return One of the following:
* - ::ST_ADC_CONVERSION_DONE if the conversion is complete.
* - ::ST_ADC_CONVERSION_DEFERRED if the conversion is still waiting
* to start.
* - ::ST_ADC_CONVERSION_BUSY if the conversion is currently taking
* place.
* - ::ST_ADC_NO_CONVERSION_PENDING if \c id does not have a pending
* conversion.
*/
StStatus halRequestAdcData(ADCUser id, int16u *value);
/** @brief Waits for the user's request to complete and then,
* if a conversion was done, writes the raw register value of the conversion
* (the unaltered value taken directly from the ADC's data register) into
* \c value and returns ::ADC_CONVERSION_DONE, or immediately
* returns ::ADC_NO_CONVERSION_PENDING.
*
* @param id An ADC user.
*
* @param value Pointer to an int16u to be loaded with the new value.
*
* @return One of the following:
* - ::ST_ADC_CONVERSION_DONE if the conversion is complete.
* - ::ST_ADC_NO_CONVERSION_PENDING if \c id does not have a pending
* conversion.
*/
StStatus halReadAdcBlocking(ADCUser id, int16u *value);
/** @brief Calibrates or recalibrates the ADC system.
*
* @appusage Use this function to (re)calibrate as needed. This function is
* intended for the microcontroller, which requires proper calibration to calculate
* a human readible value (a value in volts). If the app does not call this
* function, the first time (and only the first time) the function
* ::halConvertValueToVolts() is called, this function is invoked. To
* maintain accurate volt calculations, the application should call this
* whenever it expects the temperature of the micro to change.
*
* @param id An ADC user.
*
* @return One of the following:
* - ::ST_ADC_CONVERSION_DONE if the calibration is complete.
* - ::ST_ERR_FATAL if the calibration failed.
*/
StStatus halAdcCalibrate(ADCUser id);
/** @brief Convert the raw register value (the unaltered value taken
* directly from the ADC's data register) into a signed fixed point value with
* units 10^-4 Volts. The returned value will be in the range -12000 to
* +12000 (-1.2000 volts to +1.2000 volts).
*
* @appusage Use this function to get a human useful value.
*
* @param value An int16u to be converted.
*
* @return Volts as signed fixed point with units 10^-4 Volts.
*/
int16s halConvertValueToVolts(int16u value);
/** @brief Calibrates Vref to be 1.2V +/-10mV.
*
* @appusage This function must be called from halInternalInitAdc() before
* making ADC readings. This function is not intended to be called from any
* function other than halInternalInitAdc(). This function ensures that the
* master cell voltage and current bias values are calibrated before
* calibrating Vref.
*/
void stCalibrateVref(void);
#ifdef CORTEXM3
void halAdcSetClock(boolean fast);
void halAdcSetRange(boolean high);
boolean halAdcGetClock(void);
boolean halAdcGetRange(void);
#endif
#endif // __ADC_H__
/** @} // END addtogroup
*/