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ADC_Module.cpp
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ADC_Module.cpp
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/* Teensy 4.x, 3.x, LC ADC library
* https://github.com/pedvide/ADC
* Copyright (c) 2020 Pedro Villanueva
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
/* ADC_Module.cpp: Implements the fuctions of a Teensy 3.x, LC ADC module
*
*/
#include "ADC_Module.h"
// include the internal reference
#ifdef ADC_USE_INTERNAL_VREF
#include <VREF.h>
#endif
/* Constructor
* Point the registers to the correct ADC module
* Copy the correct channel2sc1a
* Call init
*/
ADC_Module::ADC_Module(uint8_t ADC_number,
const uint8_t *const a_channel2sc1a,
#if ADC_DIFF_PAIRS > 0
const ADC_NLIST *const a_diff_table,
#endif
ADC_REGS_t &a_adc_regs) : ADC_num(ADC_number), channel2sc1a(a_channel2sc1a)
#if ADC_DIFF_PAIRS > 0
,
diff_table(a_diff_table)
#endif
,
adc_regs(a_adc_regs)
#ifdef ADC_USE_PDB
,
PDB0_CHnC1(ADC_num ? PDB0_CH1C1 : PDB0_CH0C1)
#endif
#if defined(ADC_TEENSY_4)
,
XBAR_IN(ADC_num ? XBARA1_IN_QTIMER4_TIMER3 : XBARA1_IN_QTIMER4_TIMER0), XBAR_OUT(ADC_num ? XBARA1_OUT_ADC_ETC_TRIG10 : XBARA1_OUT_ADC_ETC_TRIG00), QTIMER4_INDEX(ADC_num ? 3 : 0), ADC_ETC_TRIGGER_INDEX(ADC_num ? 4 : 0), IRQ_ADC(ADC_num ? IRQ_NUMBER_t::IRQ_ADC2 : IRQ_NUMBER_t::IRQ_ADC1)
#elif defined(ADC_DUAL_ADCS)
// IRQ_ADC0 and IRQ_ADC1 aren't consecutive in Teensy 3.6
// fix by SB, https://github.com/pedvide/ADC/issues/19
,
IRQ_ADC(ADC_num ? IRQ_NUMBER_t::IRQ_ADC1 : IRQ_NUMBER_t::IRQ_ADC0)
#else
,
IRQ_ADC(IRQ_NUMBER_t::IRQ_ADC0)
#endif
{
// call our init
analog_init();
}
/* Initialize stuff:
* - Switch on clock
* - Clear all fail flags
* - Internal reference (default: external vcc)
* - Mux between a and b channels (b channels)
* - Calibrate with 32 averages and low speed
* - When first calibration is done it sets:
* - Resolution (default: 10 bits)
* - Conversion speed and sampling time (both set to medium speed)
* - Averaging (set to 4)
*/
void ADC_Module::analog_init()
{
startClock();
// default settings:
/*
- 10 bits resolution
- 4 averages
- vcc reference
- no interrupts
- pga gain=1
- conversion speed = medium
- sampling speed = medium
initiate to 0 (or 1) so the corresponding functions change it to the correct value
*/
analog_res_bits = 0;
analog_max_val = 0;
analog_num_average = 0;
analog_reference_internal = ADC_REF_SOURCE::REF_NONE;
#ifdef ADC_USE_PGA
pga_value = 1;
#endif
interrupts_enabled = false;
#ifdef ADC_TEENSY_4
// overwrite old values if a new conversion ends
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_OVWREN);
// this is the only option for Teensy 3.x and LC
#endif
conversion_speed = ADC_CONVERSION_SPEED::HIGH_SPEED; // set to something different from line 139 so it gets changed there
sampling_speed = ADC_SAMPLING_SPEED::VERY_HIGH_SPEED;
calibrating = 0;
fail_flag = ADC_ERROR::CLEAR; // clear all errors
num_measurements = 0;
// select b channels
#ifdef ADC_TEENSY_4
// T4 has no a or b channels
#else
// ADC_CFG2_muxsel = 1;
atomic::setBitFlag(adc_regs.CFG2, ADC_CFG2_MUXSEL);
#endif
// set reference to vcc
setReference(ADC_REFERENCE::REF_3V3);
// set resolution to 10
setResolution(10);
// the first calibration will use 32 averages and lowest speed,
// when this calibration is over the averages and speed will be set to default by wait_for_cal and init_calib will be cleared.
init_calib = 1;
setAveraging(32);
setConversionSpeed(ADC_CONVERSION_SPEED::LOW_SPEED);
setSamplingSpeed(ADC_SAMPLING_SPEED::LOW_SPEED);
// begin init calibration
calibrate();
}
// starts calibration
void ADC_Module::calibrate()
{
__disable_irq();
calibrating = 1;
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.GC, ADC_GC_CAL);
atomic::setBitFlag(adc_regs.GS, ADC_GS_CALF);
atomic::setBitFlag(adc_regs.GC, ADC_GC_CAL);
#else
// ADC_SC3_cal = 0; // stop possible previous calibration
atomic::clearBitFlag(adc_regs.SC3, ADC_SC3_CAL);
// ADC_SC3_calf = 1; // clear possible previous error
atomic::setBitFlag(adc_regs.SC3, ADC_SC3_CALF);
// ADC_SC3_cal = 1; // start calibration
atomic::setBitFlag(adc_regs.SC3, ADC_SC3_CAL);
#endif
__enable_irq();
}
/* Waits until calibration is finished and writes the corresponding registers
*
*/
void ADC_Module::wait_for_cal(void)
{
// wait for calibration to finish
#ifdef ADC_TEENSY_4
while (atomic::getBitFlag(adc_regs.GC, ADC_GC_CAL))
{ // Bit ADC_GC_CAL in register GC cleared when calib. finishes.
yield();
}
if (atomic::getBitFlag(adc_regs.GS, ADC_GS_CALF))
{ // calibration failed
fail_flag |= ADC_ERROR::CALIB; // the user should know and recalibrate manually
}
#else
while (atomic::getBitFlag(adc_regs.SC3, ADC_SC3_CAL))
{ // Bit ADC_SC3_CAL in register ADC0_SC3 cleared when calib. finishes.
yield();
}
if (atomic::getBitFlag(adc_regs.SC3, ADC_SC3_CALF))
{ // calibration failed
fail_flag |= ADC_ERROR::CALIB; // the user should know and recalibrate manually
}
#endif
// set calibrated values to registers
#ifdef ADC_TEENSY_4
// T4 does not require anything else for calibration
#else
__disable_irq();
uint16_t sum;
if (calibrating)
{
sum = adc_regs.CLPS + adc_regs.CLP4 + adc_regs.CLP3 + adc_regs.CLP2 + adc_regs.CLP1 + adc_regs.CLP0;
sum = (sum / 2) | 0x8000;
adc_regs.PG = sum;
sum = adc_regs.CLMS + adc_regs.CLM4 + adc_regs.CLM3 + adc_regs.CLM2 + adc_regs.CLM1 + adc_regs.CLM0;
sum = (sum / 2) | 0x8000;
adc_regs.MG = sum;
}
__enable_irq();
#endif
calibrating = 0;
// the first calibration uses 32 averages and lowest speed,
// when this calibration is over, set the averages and speed to default.
if (init_calib)
{
// set conversion speed to medium
setConversionSpeed(ADC_CONVERSION_SPEED::MED_SPEED);
// set sampling speed to medium
setSamplingSpeed(ADC_SAMPLING_SPEED::MED_SPEED);
// number of averages to 4
setAveraging(4);
init_calib = 0; // clear
}
}
//! Starts the calibration sequence, waits until it's done and writes the results
/** Usually it's not necessary to call this function directly, but do it if the "environment" changed
* significantly since the program was started.
*/
void ADC_Module::recalibrate()
{
calibrate();
wait_for_cal();
}
/////////////// METHODS TO SET/GET SETTINGS OF THE ADC ////////////////////
/* Set the voltage reference you prefer, default is 3.3V
* It needs to recalibrate
* Use ADC_REF_3V3, ADC_REF_1V2 (not for Teensy LC) or ADC_REF_EXT
*/
void ADC_Module::setReference(ADC_REFERENCE type)
{
ADC_REF_SOURCE ref_type = static_cast<ADC_REF_SOURCE>(type); // cast to source type, that is, either internal or default
if (analog_reference_internal == ref_type)
{ // don't need to change anything
return;
}
if (ref_type == ADC_REF_SOURCE::REF_ALT)
{ // 1.2V ref for Teensy 3.x, 3.3 VDD for Teensy LC
// internal reference requested
#ifdef ADC_USE_INTERNAL_VREF
VREF::start(); // enable VREF if Teensy 3.x
#endif
analog_reference_internal = ADC_REF_SOURCE::REF_ALT;
#ifdef ADC_TEENSY_4
// No REF_ALT for T4
#else
// *ADC_SC2_ref = 1; // uses bitband: atomic
atomic::setBitFlag(adc_regs.SC2, ADC_SC2_REFSEL(1));
#endif
}
else if (ref_type == ADC_REF_SOURCE::REF_DEFAULT)
{ // ext ref for all Teensys, vcc also for Teensy 3.x
// vcc or external reference requested
#ifdef ADC_USE_INTERNAL_VREF
VREF::stop(); // disable 1.2V reference source when using the external ref (p. 102, 3.7.1.7)
#endif
analog_reference_internal = ADC_REF_SOURCE::REF_DEFAULT;
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_REFSEL(3));
#else
// *ADC_SC2_ref = 0; // uses bitband: atomic
atomic::clearBitFlag(adc_regs.SC2, ADC_SC2_REFSEL(1));
#endif
}
calibrate();
}
/* Change the resolution of the measurement
* For single-ended measurements: 8, 10, 12 or 16 bits.
* For differential measurements: 9, 11, 13 or 16 bits.
* If you want something in between (11 bits single-ended for example) select the inmediate higher
* and shift the result one to the right.
*
* It doesn't recalibrate
*/
void ADC_Module::setResolution(uint8_t bits)
{
if (analog_res_bits == bits)
{
return;
}
uint8_t config;
if (calibrating)
wait_for_cal();
if (bits <= 9)
{
config = 8;
}
else if (bits <= 11)
{
config = 10;
#ifdef ADC_TEENSY_4
}
else if (bits > 11)
{
config = 12;
#else
}
else if (bits <= 13)
{
config = 12;
}
else if (bits > 13)
{
config = 16;
#endif
}
else
{
config = 8; // default to 8 bits
}
// conversion resolution
// single-ended 8 bits is the same as differential 9 bits, etc.
if ((config == 8) || (config == 9))
{
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_MODE(3));
#else
// *ADC_CFG1_mode1 = 0;
// *ADC_CFG1_mode0 = 0;
atomic::clearBitFlag(adc_regs.CFG1, ADC_CFG1_MODE(3));
#endif
analog_max_val = 255; // diff mode 9 bits has 1 bit for sign, so max value is the same as single 8 bits
}
else if ((config == 10) || (config == 11))
{
#ifdef ADC_TEENSY_4
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_MODE(3), ADC_CFG_MODE(1));
#else
// *ADC_CFG1_mode1 = 1;
// *ADC_CFG1_mode0 = 0;
atomic::changeBitFlag(adc_regs.CFG1, ADC_CFG1_MODE(3), ADC_CFG1_MODE(2));
#endif
analog_max_val = 1023;
}
else if ((config == 12) || (config == 13))
{
#ifdef ADC_TEENSY_4
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_MODE(3), ADC_CFG_MODE(2));
#else
// *ADC_CFG1_mode1 = 0;
// *ADC_CFG1_mode0 = 1;
atomic::changeBitFlag(adc_regs.CFG1, ADC_CFG1_MODE(3), ADC_CFG1_MODE(1));
#endif
analog_max_val = 4095;
}
else
{
#ifdef ADC_TEENSY_4
// Impossible for T4
#else
// *ADC_CFG1_mode1 = 1;
// *ADC_CFG1_mode0 = 1;
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_MODE(3));
#endif
analog_max_val = 65535;
}
analog_res_bits = config;
// no recalibration is needed when changing the resolution, p. 619
}
/* Returns the resolution of the ADC
*
*/
uint8_t ADC_Module::getResolution()
{
return analog_res_bits;
}
/* Returns the maximum value for a measurement, that is: 2^resolution-1
*
*/
uint32_t ADC_Module::getMaxValue()
{
return analog_max_val;
}
// Sets the conversion speed
/* Increase the sampling speed for low impedance sources, decrease it for higher impedance ones.
* \param speed can be any of the ADC_SAMPLING_SPEED enum: VERY_LOW_SPEED, LOW_SPEED, MED_SPEED, HIGH_SPEED or VERY_HIGH_SPEED.
*
* VERY_LOW_SPEED is the lowest possible sampling speed (+24 ADCK).
* LOW_SPEED adds +16 ADCK.
* MED_SPEED adds +10 ADCK.
* HIGH_SPEED adds +6 ADCK.
* VERY_HIGH_SPEED is the highest possible sampling speed (0 ADCK added).
*/
void ADC_Module::setConversionSpeed(ADC_CONVERSION_SPEED speed)
{
if (speed == conversion_speed)
{ // no change
return;
}
//if (calibrating) wait_for_cal();
bool is_adack = false;
uint32_t ADC_CFG1_speed = 0; // store the clock and divisor (set to 0 to avoid warnings)
switch (speed)
{
// normal bus clock
#ifndef ADC_TEENSY_4
case ADC_CONVERSION_SPEED::VERY_LOW_SPEED:
atomic::clearBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
// ADC_CFG1_speed = ADC_CFG1_VERY_LOW_SPEED;
ADC_CFG1_speed = get_CFG_VERY_LOW_SPEED(ADC_F_BUS);
break;
#endif
case ADC_CONVERSION_SPEED::LOW_SPEED:
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADHSC);
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_ADLPC);
#else
atomic::clearBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
#endif
// ADC_CFG1_speed = ADC_CFG1_LOW_SPEED;
ADC_CFG1_speed = get_CFG_LOW_SPEED(ADC_F_BUS);
break;
case ADC_CONVERSION_SPEED::MED_SPEED:
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADHSC);
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADLPC);
#else
atomic::clearBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::clearBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
#endif
ADC_CFG1_speed = get_CFG_MEDIUM_SPEED(ADC_F_BUS);
break;
#ifndef ADC_TEENSY_4
case ADC_CONVERSION_SPEED::HIGH_SPEED_16BITS:
atomic::setBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::clearBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
// ADC_CFG1_speed = ADC_CFG1_HI_SPEED_16_BITS;
ADC_CFG1_speed = get_CFG_HI_SPEED_16_BITS(ADC_F_BUS);
break;
#endif
case ADC_CONVERSION_SPEED::HIGH_SPEED:
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_ADHSC);
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADLPC);
#else
atomic::setBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::clearBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
#endif
ADC_CFG1_speed = get_CFG_HIGH_SPEED(ADC_F_BUS);
break;
#ifndef ADC_TEENSY_4
case ADC_CONVERSION_SPEED::VERY_HIGH_SPEED:
atomic::setBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::clearBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
// ADC_CFG1_speed = ADC_CFG1_VERY_HIGH_SPEED;
ADC_CFG1_speed = get_CFG_VERY_HIGH_SPEED(ADC_F_BUS);
break;
#endif
// adack - async clock source, independent of the bus clock
#ifdef ADC_TEENSY_4 // fADK = 10 or 20 MHz
case ADC_CONVERSION_SPEED::ADACK_10:
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADHSC);
is_adack = true;
break;
case ADC_CONVERSION_SPEED::ADACK_20:
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_ADHSC);
is_adack = true;
break;
#else // fADK = 2.4, 4.0, 5.2 or 6.2 MHz
case ADC_CONVERSION_SPEED::ADACK_2_4:
atomic::clearBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
is_adack = true;
break;
case ADC_CONVERSION_SPEED::ADACK_4_0:
atomic::setBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
is_adack = true;
break;
case ADC_CONVERSION_SPEED::ADACK_5_2:
atomic::clearBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::clearBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
is_adack = true;
break;
case ADC_CONVERSION_SPEED::ADACK_6_2:
atomic::setBitFlag(adc_regs.CFG2, ADC_CFG2_ADHSC);
atomic::clearBitFlag(adc_regs.CFG1, ADC_CFG1_ADLPC);
is_adack = true;
break;
#endif
default:
fail_flag |= ADC_ERROR::OTHER;
return;
}
if (is_adack)
{
// async clock source, independent of the bus clock
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.GC, ADC_GC_ADACKEN); // enable ADACK (takes max 5us to be ready)
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_ADICLK(3)); // select ADACK as clock source
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADIV(3)); // select no dividers
#else
atomic::setBitFlag(adc_regs.CFG2, ADC_CFG2_ADACKEN);
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_ADICLK(3));
atomic::clearBitFlag(adc_regs.CFG1, ADC_CFG1_ADIV(3));
#endif
}
else
{
// normal bus clock used - disable the internal asynchronous clock
// total speed can be: bus, bus/2, bus/4, bus/8 or bus/16.
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.GC, ADC_GC_ADACKEN); // disable async
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADICLK(3), ADC_CFG1_speed & ADC_CFG_ADICLK(3)); // bus or bus/2
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADIV(3), ADC_CFG1_speed & ADC_CFG_ADIV(3)); // divisor for the clock source
#else
atomic::clearBitFlag(adc_regs.CFG2, ADC_CFG2_ADACKEN);
atomic::changeBitFlag(adc_regs.CFG1, ADC_CFG1_ADICLK(3), ADC_CFG1_speed & ADC_CFG1_ADICLK(3));
atomic::changeBitFlag(adc_regs.CFG1, ADC_CFG1_ADIV(3), ADC_CFG1_speed & ADC_CFG1_ADIV(3));
#endif
}
conversion_speed = speed;
calibrate();
}
// Sets the sampling speed
/* Increase the sampling speed for low impedance sources, decrease it for higher impedance ones.
* \param speed can be any of the ADC_SAMPLING_SPEED enum: VERY_LOW_SPEED, LOW_SPEED, MED_SPEED, HIGH_SPEED or VERY_HIGH_SPEED.
*
* VERY_LOW_SPEED is the lowest possible sampling speed (+24 ADCK).
* LOW_SPEED adds +16 ADCK.
* MED_SPEED adds +10 ADCK.
* HIGH_SPEED adds +6 ADCK.
* VERY_HIGH_SPEED is the highest possible sampling speed (0 ADCK added).
*/
void ADC_Module::setSamplingSpeed(ADC_SAMPLING_SPEED speed)
{
if (calibrating)
wait_for_cal();
switch (speed)
{
#ifdef ADC_TEENSY_4
case ADC_SAMPLING_SPEED::VERY_LOW_SPEED:
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_ADLSMP); // long sampling time enable
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADSTS(3), ADC_CFG_ADSTS(3));
break;
case ADC_SAMPLING_SPEED::LOW_SPEED:
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_ADLSMP); // long sampling time enable
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADSTS(3), ADC_CFG_ADSTS(2));
break;
case ADC_SAMPLING_SPEED::LOW_MED_SPEED:
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_ADLSMP); // long sampling time enable
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADSTS(3), ADC_CFG_ADSTS(1));
break;
case ADC_SAMPLING_SPEED::MED_SPEED:
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_ADLSMP); // long sampling time enable
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADSTS(3), ADC_CFG_ADSTS(0));
break;
case ADC_SAMPLING_SPEED::MED_HIGH_SPEED:
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADLSMP); // long sampling time disabled
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADSTS(3), ADC_CFG_ADSTS(3));
break;
case ADC_SAMPLING_SPEED::HIGH_SPEED:
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADLSMP); // long sampling time disabled
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADSTS(3), ADC_CFG_ADSTS(2));
break;
case ADC_SAMPLING_SPEED::HIGH_VERY_HIGH_SPEED:
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADLSMP); // long sampling time disabled
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADSTS(3), ADC_CFG_ADSTS(1));
break;
case ADC_SAMPLING_SPEED::VERY_HIGH_SPEED:
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_ADLSMP); // long sampling time disabled
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_ADSTS(3), ADC_CFG_ADSTS(0));
break;
#else
case ADC_SAMPLING_SPEED::VERY_LOW_SPEED:
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_ADLSMP); // long sampling time enable
atomic::clearBitFlag(adc_regs.CFG2, ADC_CFG2_ADLSTS(3)); // maximum sampling time (+24 ADCK)
break;
case ADC_SAMPLING_SPEED::LOW_SPEED:
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_ADLSMP); // long sampling time enable
atomic::changeBitFlag(adc_regs.CFG2, ADC_CFG2_ADLSTS(3), ADC_CFG2_ADLSTS(1)); // high sampling time (+16 ADCK)
break;
case ADC_SAMPLING_SPEED::MED_SPEED:
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_ADLSMP); // long sampling time enable
atomic::changeBitFlag(adc_regs.CFG2, ADC_CFG2_ADLSTS(3), ADC_CFG2_ADLSTS(2)); // medium sampling time (+10 ADCK)
break;
case ADC_SAMPLING_SPEED::HIGH_SPEED:
atomic::setBitFlag(adc_regs.CFG1, ADC_CFG1_ADLSMP); // long sampling time enable
atomic::setBitFlag(adc_regs.CFG2, ADC_CFG2_ADLSTS(3)); // low sampling time (+6 ADCK)
break;
case ADC_SAMPLING_SPEED::VERY_HIGH_SPEED:
atomic::clearBitFlag(adc_regs.CFG1, ADC_CFG1_ADLSMP); // shortest sampling time
break;
#endif
}
sampling_speed = speed;
}
/* Set the number of averages: 0, 4, 8, 16 or 32.
*
*/
void ADC_Module::setAveraging(uint8_t num)
{
if (calibrating)
wait_for_cal();
if (num <= 1)
{
num = 0;
// ADC_SC3_avge = 0;
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.GC, ADC_GC_AVGE);
#else
atomic::clearBitFlag(adc_regs.SC3, ADC_SC3_AVGE);
#endif
}
else
{
// ADC_SC3_avge = 1;
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.GC, ADC_GC_AVGE);
#else
atomic::setBitFlag(adc_regs.SC3, ADC_SC3_AVGE);
#endif
if (num <= 4)
{
num = 4;
// ADC_SC3_avgs0 = 0;
// ADC_SC3_avgs1 = 0;
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.CFG, ADC_CFG_AVGS(3));
#else
atomic::clearBitFlag(adc_regs.SC3, ADC_SC3_AVGS(3));
#endif
}
else if (num <= 8)
{
num = 8;
// ADC_SC3_avgs0 = 1;
// ADC_SC3_avgs1 = 0;
#ifdef ADC_TEENSY_4
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_AVGS(3), ADC_CFG_AVGS(1));
#else
atomic::changeBitFlag(adc_regs.SC3, ADC_SC3_AVGS(3), ADC_SC3_AVGS(1));
#endif
}
else if (num <= 16)
{
num = 16;
// ADC_SC3_avgs0 = 0;
// ADC_SC3_avgs1 = 1;
#ifdef ADC_TEENSY_4
atomic::changeBitFlag(adc_regs.CFG, ADC_CFG_AVGS(3), ADC_CFG_AVGS(2));
#else
atomic::changeBitFlag(adc_regs.SC3, ADC_SC3_AVGS(3), ADC_SC3_AVGS(2));
#endif
}
else
{
num = 32;
// ADC_SC3_avgs0 = 1;
// ADC_SC3_avgs1 = 1;
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.CFG, ADC_CFG_AVGS(3));
#else
atomic::setBitFlag(adc_regs.SC3, ADC_SC3_AVGS(3));
#endif
}
}
analog_num_average = num;
}
/* Enable interrupts: An ADC Interrupt will be raised when the conversion is completed
* (including hardware averages and if the comparison (if any) is true).
*/
void ADC_Module::enableInterrupts(void (*isr)(void), uint8_t priority)
{
if (calibrating)
wait_for_cal();
// ADC_SC1A_aien = 1;
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.HC0, ADC_HC_AIEN);
interrupts_enabled = true;
#else
atomic::setBitFlag(adc_regs.SC1A, ADC_SC1_AIEN);
#endif
attachInterruptVector(IRQ_ADC, isr);
NVIC_SET_PRIORITY(IRQ_ADC, priority);
NVIC_ENABLE_IRQ(IRQ_ADC);
}
/* Disable interrupts
*
*/
void ADC_Module::disableInterrupts()
{
// ADC_SC1A_aien = 0;
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.HC0, ADC_HC_AIEN);
interrupts_enabled = false;
#else
atomic::clearBitFlag(adc_regs.SC1A, ADC_SC1_AIEN);
#endif
NVIC_DISABLE_IRQ(IRQ_ADC);
}
#ifdef ADC_USE_DMA
/* Enable DMA request: An ADC DMA request will be raised when the conversion is completed
* (including hardware averages and if the comparison (if any) is true).
*/
void ADC_Module::enableDMA()
{
if (calibrating)
wait_for_cal();
// ADC_SC2_dma = 1;
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.GC, ADC_GC_DMAEN);
#else
atomic::setBitFlag(adc_regs.SC2, ADC_SC2_DMAEN);
#endif
}
/* Disable ADC DMA request
*
*/
void ADC_Module::disableDMA()
{
// ADC_SC2_dma = 0;
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.GC, ADC_GC_DMAEN);
#else
atomic::clearBitFlag(adc_regs.SC2, ADC_SC2_DMAEN);
#endif
}
#endif
/* Enable the compare function: A conversion will be completed only when the ADC value
* is >= compValue (greaterThan=1) or < compValue (greaterThan=0)
* Call it after changing the resolution
* Use with interrupts or poll conversion completion with isADC_Complete()
*/
void ADC_Module::enableCompare(int16_t compValue, bool greaterThan)
{
if (calibrating)
wait_for_cal(); // if we modify the adc's registers when calibrating, it will fail
// ADC_SC2_cfe = 1; // enable compare
// ADC_SC2_cfgt = (int32_t)greaterThan; // greater or less than?
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.GC, ADC_GC_ACFE);
atomic::changeBitFlag(adc_regs.GC, ADC_GC_ACFGT, ADC_GC_ACFGT * greaterThan);
adc_regs.CV = ADC_CV_CV1(compValue);
#else
atomic::setBitFlag(adc_regs.SC2, ADC_SC2_ACFE);
atomic::changeBitFlag(adc_regs.SC2, ADC_SC2_ACFGT, ADC_SC2_ACFGT * greaterThan);
adc_regs.CV1 = (int16_t)compValue; // comp value
#endif
}
/* Enable the compare function: A conversion will be completed only when the ADC value
* is inside (insideRange=1) or outside (=0) the range given by (lowerLimit, upperLimit),
* including (inclusive=1) the limits or not (inclusive=0).
* See Table 31-78, p. 617 of the freescale manual.
* Call it after changing the resolution
*/
void ADC_Module::enableCompareRange(int16_t lowerLimit, int16_t upperLimit, bool insideRange, bool inclusive)
{
if (calibrating)
wait_for_cal(); // if we modify the adc's registers when calibrating, it will fail
// ADC_SC2_cfe = 1; // enable compare
// ADC_SC2_cren = 1; // enable compare range
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.GC, ADC_GC_ACFE);
atomic::setBitFlag(adc_regs.GC, ADC_GC_ACREN);
#else
atomic::setBitFlag(adc_regs.SC2, ADC_SC2_ACFE);
atomic::setBitFlag(adc_regs.SC2, ADC_SC2_ACREN);
#endif
if (insideRange && inclusive)
{ // True if value is inside the range, including the limits. CV1 <= CV2 and ACFGT=1
// ADC_SC2_cfgt = 1;
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.GC, ADC_GC_ACFGT);
adc_regs.CV = ADC_CV_CV1(lowerLimit) | ADC_CV_CV2(upperLimit);
#else
atomic::setBitFlag(adc_regs.SC2, ADC_SC2_ACFGT);
adc_regs.CV1 = (int16_t)lowerLimit;
adc_regs.CV2 = (int16_t)upperLimit;
#endif
}
else if (insideRange && !inclusive)
{ // True if value is inside the range, excluding the limits. CV1 > CV2 and ACFGT=0
// ADC_SC2_cfgt = 0;
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.GC, ADC_GC_ACFGT);
adc_regs.CV = ADC_CV_CV2(lowerLimit) | ADC_CV_CV1(upperLimit);
#else
atomic::clearBitFlag(adc_regs.SC2, ADC_SC2_ACFGT);
adc_regs.CV2 = (int16_t)lowerLimit;
adc_regs.CV1 = (int16_t)upperLimit;
#endif
}
else if (!insideRange && inclusive)
{ // True if value is outside of range or is equal to either limit. CV1 > CV2 and ACFGT=1
// ADC_SC2_cfgt = 1;
#ifdef ADC_TEENSY_4
atomic::setBitFlag(adc_regs.GC, ADC_GC_ACFGT);
adc_regs.CV = ADC_CV_CV2(lowerLimit) | ADC_CV_CV1(upperLimit);
#else
atomic::setBitFlag(adc_regs.SC2, ADC_SC2_ACFGT);
adc_regs.CV2 = (int16_t)lowerLimit;
adc_regs.CV1 = (int16_t)upperLimit;
#endif
}
else if (!insideRange && !inclusive)
{ // True if value is outside of range and not equal to either limit. CV1 > CV2 and ACFGT=0
// ADC_SC2_cfgt = 0;
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.GC, ADC_GC_ACFGT);
adc_regs.CV = ADC_CV_CV1(lowerLimit) | ADC_CV_CV2(upperLimit);
#else
atomic::clearBitFlag(adc_regs.SC2, ADC_SC2_ACFGT);
adc_regs.CV1 = (int16_t)lowerLimit;
adc_regs.CV2 = (int16_t)upperLimit;
#endif
}
}
/* Disable the compare function
*
*/
void ADC_Module::disableCompare()
{
// ADC_SC2_cfe = 0;
#ifdef ADC_TEENSY_4
atomic::clearBitFlag(adc_regs.GC, ADC_GC_ACFE);
#else
atomic::clearBitFlag(adc_regs.SC2, ADC_SC2_ACFE);
#endif
}
#ifdef ADC_USE_PGA
/* Enables the PGA and sets the gain
* Use only for signals lower than 1.2 V
* \param gain can be 1, 2, 4, 8, 16 32 or 64
*
*/
void ADC_Module::enablePGA(uint8_t gain)
{
if (calibrating)
wait_for_cal();
uint8_t setting;
if (gain <= 1)
{
setting = 0;
}
else if (gain <= 2)
{
setting = 1;
}
else if (gain <= 4)
{
setting = 2;
}
else if (gain <= 8)
{
setting = 3;
}
else if (gain <= 16)
{
setting = 4;
}
else if (gain <= 32)
{
setting = 5;
}
else
{ // 64
setting = 6;
}
adc_regs.PGA = ADC_PGA_PGAEN | ADC_PGA_PGAG(setting);
pga_value = 1 << setting;
}
/* Returns the PGA level
* PGA level = from 0 to 64
*/
uint8_t ADC_Module::getPGA()
{
return pga_value;
}
//! Disable PGA
void ADC_Module::disablePGA()
{
// ADC_PGA_pgaen = 0;
atomic::clearBitFlag(adc_regs.PGA, ADC_PGA_PGAEN);
pga_value = 1;
}
#endif
//////////////// INFORMATION ABOUT VALID PINS //////////////////
// check whether the pin is a valid analog pin
bool ADC_Module::checkPin(uint8_t pin)
{
if (pin > ADC_MAX_PIN)
{
return false; // all others are invalid
}
// translate pin number to SC1A number, that also contains MUX a or b info.
const uint8_t sc1a_pin = channel2sc1a[pin];
// check for valid pin
if ((sc1a_pin & ADC_SC1A_CHANNELS) == ADC_SC1A_PIN_INVALID)
{
return false; // all others are invalid
}
return true;
}
#if ADC_DIFF_PAIRS > 0
// check whether the pins are a valid analog differential pins (including PGA if enabled)
bool ADC_Module::checkDifferentialPins(uint8_t pinP, uint8_t pinN)
{
if (pinP > ADC_MAX_PIN)
{
return false; // all others are invalid
}
// translate pinP number to SC1A number, to make sure it's differential
uint8_t sc1a_pin = channel2sc1a[pinP];