Merge #1024
1024: stm32/adc: Remove voltage and temperature conversions r=Dirbaio a=GrantM11235 The current conversion utilities are confusing and a bit of a footgun. (Two out of the three examples got it wrong! They didn't measure vref at all, so all the conversions are completely wrong if vcca isn't 3.3v) I think we should eventually have some sort of conversion utilities in the HAL, but for now I think it is best to just remove it and let the users do their own math. cc `@chemicstry` Co-authored-by: Grant Miller <GrantM11235@gmail.com>
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commit
7f499f3edc
7 changed files with 50 additions and 104 deletions
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@ -86,7 +86,6 @@ pub use sample_time::SampleTime;
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pub struct Adc<'d, T: Instance> {
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sample_time: SampleTime,
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calibrated_vdda: u32,
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phantom: PhantomData<&'d mut T>,
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}
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@ -122,7 +121,6 @@ impl<'d, T: Instance> Adc<'d, T> {
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Self {
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sample_time: Default::default(),
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calibrated_vdda: VDDA_CALIB_MV,
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phantom: PhantomData,
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}
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}
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@ -162,29 +160,10 @@ impl<'d, T: Instance> Adc<'d, T> {
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Temperature {}
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}
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/// Calculates the system VDDA by sampling the internal VREF channel and comparing
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/// to the expected value. If the chip's VDDA is not stable, run this before each ADC
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/// conversion.
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pub fn calibrate(&mut self, vref: &mut Vref) -> u32 {
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let old_sample_time = self.sample_time;
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self.sample_time = SampleTime::Cycles239_5;
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let vref_samp = self.read(vref);
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self.sample_time = old_sample_time;
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self.calibrated_vdda = (ADC_MAX * VREF_INT) / u32::from(vref_samp);
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self.calibrated_vdda
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}
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pub fn set_sample_time(&mut self, sample_time: SampleTime) {
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self.sample_time = sample_time;
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}
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/// Convert a measurement to millivolts
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pub fn to_millivolts(&self, sample: u16) -> u16 {
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((u32::from(sample) * self.calibrated_vdda) / ADC_MAX) as u16
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}
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/// Perform a single conversion.
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fn convert(&mut self) -> u16 {
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unsafe {
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@ -80,15 +80,6 @@ impl super::sealed::InternalChannel<ADC1> for Temperature {
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}
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impl Temperature {
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/// Converts temperature sensor reading in millivolts to degrees celcius
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pub fn to_celcius(sample_mv: u16) -> f32 {
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// From 6.3.22 Temperature sensor characteristics
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const V25: i32 = 760; // mV
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const AVG_SLOPE: f32 = 2.5; // mV/C
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(sample_mv as i32 - V25) as f32 / AVG_SLOPE + 25.0
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}
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/// Time needed for temperature sensor readings to stabilize
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pub fn start_time_us() -> u32 {
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10
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@ -172,7 +163,6 @@ impl Prescaler {
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pub struct Adc<'d, T: Instance> {
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sample_time: SampleTime,
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vref_mv: u32,
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resolution: Resolution,
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phantom: PhantomData<&'d mut T>,
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}
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@ -200,7 +190,6 @@ where
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Self {
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sample_time: Default::default(),
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resolution: Resolution::default(),
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vref_mv: VREF_DEFAULT_MV,
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phantom: PhantomData,
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}
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}
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@ -213,18 +202,6 @@ where
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self.resolution = resolution;
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}
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/// Set VREF value in millivolts. This value is used for [to_millivolts()] sample conversion.
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///
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/// Use this if you have a known precise VREF (VDDA) pin reference voltage.
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pub fn set_vref_mv(&mut self, vref_mv: u32) {
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self.vref_mv = vref_mv;
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}
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/// Convert a measurement to millivolts
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pub fn to_millivolts(&self, sample: u16) -> u16 {
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((u32::from(sample) * self.vref_mv) / self.resolution.to_max_count()) as u16
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}
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/// Enables internal voltage reference and returns [VrefInt], which can be used in
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/// [Adc::read_internal()] to perform conversion.
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pub fn enable_vrefint(&self) -> VrefInt {
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@ -205,7 +205,6 @@ pub use sample_time::SampleTime;
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pub struct Adc<'d, T: Instance> {
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sample_time: SampleTime,
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vref_mv: u32,
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resolution: Resolution,
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phantom: PhantomData<&'d mut T>,
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}
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@ -244,7 +243,6 @@ impl<'d, T: Instance> Adc<'d, T> {
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Self {
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sample_time: Default::default(),
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resolution: Resolution::default(),
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vref_mv: VREF_DEFAULT_MV,
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phantom: PhantomData,
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}
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}
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@ -285,31 +283,6 @@ impl<'d, T: Instance> Adc<'d, T> {
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Vbat {}
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}
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/// Calculates the system VDDA by sampling the internal VREFINT channel and comparing
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/// the result with the value stored at the factory. If the chip's VDDA is not stable, run
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/// this before each ADC conversion.
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#[cfg(not(stm32g0))] // TODO is this supposed to be public?
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#[allow(unused)] // TODO is this supposed to be public?
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fn calibrate(&mut self, vrefint: &mut VrefInt) {
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#[cfg(stm32l5)]
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let vrefint_cal: u32 = todo!();
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#[cfg(not(stm32l5))]
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let vrefint_cal = unsafe { crate::pac::VREFINTCAL.data().read().value() };
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let old_sample_time = self.sample_time;
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// "Table 24. Embedded internal voltage reference" states that the sample time needs to be
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// at a minimum 4 us. With 640.5 ADC cycles we have a minimum of 8 us at 80 MHz, leaving
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// some headroom.
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self.sample_time = SampleTime::Cycles640_5;
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// This can't actually fail, it's just in a result to satisfy hal trait
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let vrefint_samp = self.read(vrefint);
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self.sample_time = old_sample_time;
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self.vref_mv = (VREF_CALIB_MV * u32::from(vrefint_cal)) / u32::from(vrefint_samp);
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}
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pub fn set_sample_time(&mut self, sample_time: SampleTime) {
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self.sample_time = sample_time;
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}
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@ -318,18 +291,6 @@ impl<'d, T: Instance> Adc<'d, T> {
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self.resolution = resolution;
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}
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/// Set VREF value in millivolts. This value is used for [to_millivolts()] sample conversion.
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///
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/// Use this if you have a known precise VREF (VDDA) pin reference voltage.
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pub fn set_vref_mv(&mut self, vref_mv: u32) {
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self.vref_mv = vref_mv;
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}
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/// Convert a measurement to millivolts
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pub fn to_millivolts(&self, sample: u16) -> u16 {
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((u32::from(sample) * self.vref_mv) / self.resolution.to_max_count()) as u16
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}
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/*
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/// Convert a raw sample from the `Temperature` to deg C
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pub fn to_degrees_centigrade(sample: u16) -> f32 {
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@ -314,7 +314,6 @@ impl Prescaler {
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pub struct Adc<'d, T: Instance> {
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sample_time: SampleTime,
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vref_mv: u32,
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resolution: Resolution,
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phantom: PhantomData<&'d mut T>,
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}
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@ -352,7 +351,6 @@ impl<'d, T: Instance + crate::rcc::RccPeripheral> Adc<'d, T> {
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let mut s = Self {
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sample_time: Default::default(),
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vref_mv: VREF_DEFAULT_MV,
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resolution: Resolution::default(),
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phantom: PhantomData,
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};
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@ -459,18 +457,6 @@ impl<'d, T: Instance + crate::rcc::RccPeripheral> Adc<'d, T> {
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self.resolution = resolution;
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}
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/// Set VREF value in millivolts. This value is used for [to_millivolts()] sample conversion.
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///
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/// Use this if you have a known precise VREF (VDDA) pin reference voltage.
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pub fn set_vref_mv(&mut self, vref_mv: u32) {
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self.vref_mv = vref_mv;
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}
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/// Convert a measurement to millivolts
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pub fn to_millivolts(&self, sample: u16) -> u16 {
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((u32::from(sample) * self.vref_mv) / self.resolution.to_max_count()) as u16
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}
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/// Perform a single conversion.
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fn convert(&mut self) -> u16 {
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unsafe {
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@ -16,11 +16,19 @@ async fn main(_spawner: Spawner) {
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let mut adc = Adc::new(p.ADC1, &mut Delay);
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let mut pin = p.PB1;
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let mut vref = adc.enable_vref(&mut Delay);
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adc.calibrate(&mut vref);
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let mut vrefint = adc.enable_vref(&mut Delay);
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let vrefint_sample = adc.read(&mut vrefint);
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let convert_to_millivolts = |sample| {
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// From http://www.st.com/resource/en/datasheet/CD00161566.pdf
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// 5.3.4 Embedded reference voltage
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const VREFINT_MV: u32 = 1200; // mV
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(u32::from(sample) * VREFINT_MV / u32::from(vrefint_sample)) as u16
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};
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loop {
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let v = adc.read(&mut pin);
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info!("--> {} - {} mV", v, adc.to_millivolts(v));
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info!("--> {} - {} mV", v, convert_to_millivolts(v));
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Timer::after(Duration::from_millis(100)).await;
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}
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}
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@ -24,19 +24,44 @@ async fn main(_spawner: Spawner) {
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// Startup delay can be combined to the maximum of either
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delay.delay_us(Temperature::start_time_us().max(VrefInt::start_time_us()));
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let vrefint_sample = adc.read_internal(&mut vrefint);
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let convert_to_millivolts = |sample| {
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// From http://www.st.com/resource/en/datasheet/DM00071990.pdf
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// 6.3.24 Reference voltage
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const VREFINT_MV: u32 = 1210; // mV
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(u32::from(sample) * VREFINT_MV / u32::from(vrefint_sample)) as u16
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};
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let convert_to_celcius = |sample| {
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// From http://www.st.com/resource/en/datasheet/DM00071990.pdf
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// 6.3.22 Temperature sensor characteristics
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const V25: i32 = 760; // mV
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const AVG_SLOPE: f32 = 2.5; // mV/C
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let sample_mv = convert_to_millivolts(sample) as i32;
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(sample_mv - V25) as f32 / AVG_SLOPE + 25.0
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};
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info!("VrefInt: {}", vrefint_sample);
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const MAX_ADC_SAMPLE: u16 = (1 << 12) - 1;
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info!("VCCA: {} mV", convert_to_millivolts(MAX_ADC_SAMPLE));
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loop {
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// Read pin
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let v = adc.read(&mut pin);
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info!("PC1: {} ({} mV)", v, adc.to_millivolts(v));
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info!("PC1: {} ({} mV)", v, convert_to_millivolts(v));
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// Read internal temperature
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let v = adc.read_internal(&mut temp);
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let celcius = Temperature::to_celcius(adc.to_millivolts(v));
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let celcius = convert_to_celcius(v);
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info!("Internal temp: {} ({} C)", v, celcius);
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// Read internal voltage reference
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let v = adc.read_internal(&mut vrefint);
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info!("VrefInt: {} ({} mV)", v, adc.to_millivolts(v));
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info!("VrefInt: {}", v);
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Timer::after(Duration::from_millis(100)).await;
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}
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@ -16,9 +16,19 @@ async fn main(_spawner: Spawner) {
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let mut adc = Adc::new(p.ADC1, &mut Delay);
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let mut pin = p.PA3;
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let mut vrefint = adc.enable_vrefint();
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let vrefint_sample = adc.read_internal(&mut vrefint);
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let convert_to_millivolts = |sample| {
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// From http://www.st.com/resource/en/datasheet/DM00273119.pdf
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// 6.3.27 Reference voltage
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const VREFINT_MV: u32 = 1210; // mV
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(u32::from(sample) * VREFINT_MV / u32::from(vrefint_sample)) as u16
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};
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loop {
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let v = adc.read(&mut pin);
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info!("--> {} - {} mV", v, adc.to_millivolts(v));
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info!("--> {} - {} mV", v, convert_to_millivolts(v));
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Timer::after(Duration::from_millis(100)).await;
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}
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}
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