pounder_test/src/bin/lockin-internal-demo.rs

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#![deny(warnings)]
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#![no_std]
#![no_main]
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#![cfg_attr(feature = "nightly", feature(core_intrinsics))]
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// A constant sinusoid to send on the DAC output.
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const DAC_SEQUENCE: [f32; 8] =
[0.0, 0.707, 1.0, 0.707, 0.0, -0.707, -1.0, -0.707];
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use dsp::{iir, iir_int, lockin::Lockin};
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use hardware::{Adc1Input, Dac0Output, Dac1Output, AFE0, AFE1};
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use stabilizer::hardware;
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const SCALE: f32 = ((1 << 15) - 1) as f32;
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#[rtic::app(device = stm32h7xx_hal::stm32, peripherals = true, monotonic = rtic::cyccnt::CYCCNT)]
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const APP: () = {
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struct Resources {
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afes: (AFE0, AFE1),
adc1: Adc1Input,
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dacs: (Dac0Output, Dac1Output),
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#[init([0.; 5])]
iir_state: iir::IIRState,
#[init(iir::IIR { ba: [1., 0., 0., 0., 0.], y_offset: 0., y_min: -SCALE - 1., y_max: SCALE })]
iir: iir::IIR,
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lockin: Lockin,
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}
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#[init]
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fn init(c: init::Context) -> init::LateResources {
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// Configure the microcontroller
let (mut stabilizer, _pounder) = hardware::setup(c.core, c.device);
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let lockin = Lockin::new(
&iir_int::IIRState::lowpass(1e-3, 0.707, 2.), // TODO: expose
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);
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// Enable ADC/DAC events
stabilizer.adcs.1.start();
stabilizer.dacs.0.start();
stabilizer.dacs.1.start();
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// Start sampling ADCs.
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stabilizer.adc_dac_timer.start();
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init::LateResources {
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lockin,
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afes: stabilizer.afes,
adc1: stabilizer.adcs.1,
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dacs: stabilizer.dacs,
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}
}
/// Main DSP processing routine for Stabilizer.
///
/// # Note
/// Processing time for the DSP application code is bounded by the following constraints:
///
/// DSP application code starts after the ADC has generated a batch of samples and must be
/// completed by the time the next batch of ADC samples has been acquired (plus the FIFO buffer
/// time). If this constraint is not met, firmware will panic due to an ADC input overrun.
///
/// The DSP application code must also fill out the next DAC output buffer in time such that the
/// DAC can switch to it when it has completed the current buffer. If this constraint is not met
/// it's possible that old DAC codes will be generated on the output and the output samples will
/// be delayed by 1 batch.
///
/// Because the ADC and DAC operate at the same rate, these two constraints actually implement
/// the same time bounds, meeting one also means the other is also met.
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///
/// TODO: Document
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#[task(binds=DMA1_STR4, resources=[adc1, dacs, iir_state, iir, lockin], priority=2)]
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fn process(mut c: process::Context) {
let adc_samples = c.resources.adc1.acquire_buffer();
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let dac_samples = [
c.resources.dacs.0.acquire_buffer(),
c.resources.dacs.1.acquire_buffer(),
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];
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// DAC0 always generates a fixed sinusoidal output.
for (i, value) in DAC_SEQUENCE.iter().enumerate() {
let y = value * i16::MAX as f32;
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// Note(unsafe): The DAC_SEQUENCE values are guaranteed to be normalized.
let y = unsafe { y.to_int_unchecked::<i16>() };
// Convert to DAC code
dac_samples[0][i] = y as u16 ^ 0x8000;
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}
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// TODO: Verify that the DAC code is always generated at T=0
let pll_phase = 0i32;
let pll_frequency = 1i32 << (32 - 3); // 1/8 of the sample rate
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// Harmonic index of the LO: -1 to _de_modulate the fundamental
let harmonic: i32 = -1;
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// Demodulation LO phase offset
let phase_offset: i32 = 0;
let sample_frequency = (pll_frequency as i32).wrapping_mul(harmonic);
let mut sample_phase = phase_offset
.wrapping_add((pll_phase as i32).wrapping_mul(harmonic));
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let mut phase = 0f32;
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for sample in adc_samples.iter() {
// Convert to signed, MSB align the ADC sample.
let input = (*sample as i16 as i32) << 16;
// Obtain demodulated, filtered IQ sample.
let output = c.resources.lockin.update(input, sample_phase);
// Advance the sample phase.
sample_phase = sample_phase.wrapping_add(sample_frequency);
// Convert from IQ to phase.
phase = output.phase() as _;
}
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// Filter phase through an IIR.
phase = c.resources.iir.update(&mut c.resources.iir_state, phase);
for value in dac_samples[1].iter_mut() {
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*value = phase as u16 ^ 0x8000
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}
}
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#[idle(resources=[iir_state, iir, afes])]
fn idle(_: idle::Context) -> ! {
loop {
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// TODO: Implement network interface.
cortex_m::asm::wfi();
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}
}
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#[task(binds = ETH, priority = 1)]
fn eth(_: eth::Context) {
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unsafe { stm32h7xx_hal::ethernet::interrupt_handler() }
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}
#[task(binds = SPI2, priority = 3)]
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fn spi2(_: spi2::Context) {
panic!("ADC0 input overrun");
}
#[task(binds = SPI3, priority = 3)]
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fn spi3(_: spi3::Context) {
panic!("ADC1 input overrun");
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}
#[task(binds = SPI4, priority = 3)]
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fn spi4(_: spi4::Context) {
panic!("DAC0 output error");
}
#[task(binds = SPI5, priority = 3)]
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fn spi5(_: spi5::Context) {
panic!("DAC1 output error");
}
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extern "C" {
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// hw interrupt handlers for RTIC to use for scheduling tasks
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// one per priority
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fn DCMI();
fn JPEG();
fn SDMMC();
}
};