Merge branch 'master' into feature/unwrap
This commit is contained in:
commit
47806a155d
|
@ -77,6 +77,25 @@ jobs:
|
||||||
command: build
|
command: build
|
||||||
args: --release --features semihosting
|
args: --release --features semihosting
|
||||||
|
|
||||||
|
test:
|
||||||
|
runs-on: ubuntu-latest
|
||||||
|
strategy:
|
||||||
|
matrix:
|
||||||
|
toolchain:
|
||||||
|
- stable
|
||||||
|
- beta
|
||||||
|
steps:
|
||||||
|
- uses: actions/checkout@v2
|
||||||
|
- name: Install Rust ${{ matrix.toolchain }}
|
||||||
|
uses: actions-rs/toolchain@v1
|
||||||
|
with:
|
||||||
|
toolchain: ${{ matrix.toolchain }}
|
||||||
|
- name: cargo test
|
||||||
|
uses: actions-rs/cargo@v1
|
||||||
|
with:
|
||||||
|
command: test
|
||||||
|
args: --package dsp --target=x86_64-unknown-linux-gnu
|
||||||
|
|
||||||
# Tell bors about it
|
# Tell bors about it
|
||||||
# https://github.com/rtic-rs/cortex-m-rtic/blob/8a4f9c6b8ae91bebeea0791680f89375a78bffc6/.github/workflows/build.yml#L566-L603
|
# https://github.com/rtic-rs/cortex-m-rtic/blob/8a4f9c6b8ae91bebeea0791680f89375a78bffc6/.github/workflows/build.yml#L566-L603
|
||||||
ci-success:
|
ci-success:
|
||||||
|
|
|
@ -1,2 +1,3 @@
|
||||||
/target
|
/target
|
||||||
|
/dsp/target
|
||||||
.gdb_history
|
.gdb_history
|
||||||
|
|
|
@ -189,6 +189,7 @@ dependencies = [
|
||||||
name = "dsp"
|
name = "dsp"
|
||||||
version = "0.1.0"
|
version = "0.1.0"
|
||||||
dependencies = [
|
dependencies = [
|
||||||
|
"libm",
|
||||||
"serde",
|
"serde",
|
||||||
]
|
]
|
||||||
|
|
||||||
|
@ -297,6 +298,12 @@ dependencies = [
|
||||||
"hashbrown",
|
"hashbrown",
|
||||||
]
|
]
|
||||||
|
|
||||||
|
[[package]]
|
||||||
|
name = "libm"
|
||||||
|
version = "0.2.1"
|
||||||
|
source = "registry+https://github.com/rust-lang/crates.io-index"
|
||||||
|
checksum = "c7d73b3f436185384286bd8098d17ec07c9a7d2388a6599f824d8502b529702a"
|
||||||
|
|
||||||
[[package]]
|
[[package]]
|
||||||
name = "log"
|
name = "log"
|
||||||
version = "0.4.11"
|
version = "0.4.11"
|
||||||
|
|
|
@ -4,9 +4,16 @@
|
||||||
name = "dsp"
|
name = "dsp"
|
||||||
version = "0.1.0"
|
version = "0.1.0"
|
||||||
dependencies = [
|
dependencies = [
|
||||||
|
"libm",
|
||||||
"serde",
|
"serde",
|
||||||
]
|
]
|
||||||
|
|
||||||
|
[[package]]
|
||||||
|
name = "libm"
|
||||||
|
version = "0.2.1"
|
||||||
|
source = "registry+https://github.com/rust-lang/crates.io-index"
|
||||||
|
checksum = "c7d73b3f436185384286bd8098d17ec07c9a7d2388a6599f824d8502b529702a"
|
||||||
|
|
||||||
[[package]]
|
[[package]]
|
||||||
name = "proc-macro2"
|
name = "proc-macro2"
|
||||||
version = "1.0.24"
|
version = "1.0.24"
|
||||||
|
|
|
@ -5,6 +5,7 @@ authors = ["Robert Jördens <rj@quartiq.de>"]
|
||||||
edition = "2018"
|
edition = "2018"
|
||||||
|
|
||||||
[dependencies]
|
[dependencies]
|
||||||
|
libm = "0.2.1"
|
||||||
serde = { version = "1.0", features = ["derive"], default-features = false }
|
serde = { version = "1.0", features = ["derive"], default-features = false }
|
||||||
|
|
||||||
[features]
|
[features]
|
||||||
|
|
|
@ -1,6 +1,11 @@
|
||||||
#![cfg_attr(not(test), no_std)]
|
#![cfg_attr(not(test), no_std)]
|
||||||
#![cfg_attr(feature = "nightly", feature(asm, core_intrinsics))]
|
#![cfg_attr(feature = "nightly", feature(asm, core_intrinsics))]
|
||||||
|
|
||||||
|
pub type Complex<T> = (T, T);
|
||||||
pub mod iir;
|
pub mod iir;
|
||||||
|
pub mod lockin;
|
||||||
pub mod pll;
|
pub mod pll;
|
||||||
pub mod unwrap;
|
pub mod unwrap;
|
||||||
|
|
||||||
|
#[cfg(test)]
|
||||||
|
mod testing;
|
|
@ -0,0 +1,518 @@
|
||||||
|
//! Lock-in amplifier.
|
||||||
|
//!
|
||||||
|
//! Lock-in processing is performed through a combination of the
|
||||||
|
//! following modular processing blocks: demodulation, filtering,
|
||||||
|
//! decimation and computing the magnitude and phase from a complex
|
||||||
|
//! signal. These processing blocks are mutually independent.
|
||||||
|
//!
|
||||||
|
//! # Terminology
|
||||||
|
//!
|
||||||
|
//! * _demodulation signal_ - A copy of the reference signal that is
|
||||||
|
//! optionally frequency scaled and phase shifted. This is a complex
|
||||||
|
//! signal. The demodulation signals are used to demodulate the ADC
|
||||||
|
//! sampled signal.
|
||||||
|
//! * _internal clock_ - A fast internal clock used to increment a
|
||||||
|
//! counter for determining the 0-phase points of a reference signal.
|
||||||
|
//! * _reference signal_ - A constant-frequency signal used to derive
|
||||||
|
//! the demodulation signal.
|
||||||
|
//! * _timestamp_ - Timestamps record the timing of the reference
|
||||||
|
//! signal's 0-phase points. For instance, if a reference signal is
|
||||||
|
//! provided externally, a fast internal clock increments a
|
||||||
|
//! counter. When the external reference reaches the 0-phase point
|
||||||
|
//! (e.g., a positive edge), the value of the counter is recorded as a
|
||||||
|
//! timestamp. These timestamps are used to determine the frequency
|
||||||
|
//! and phase of the reference signal.
|
||||||
|
//!
|
||||||
|
//! # Usage
|
||||||
|
//!
|
||||||
|
//! The first step is to initialize a `Lockin` instance with
|
||||||
|
//! `Lockin::new()`. This provides the lock-in algorithms with
|
||||||
|
//! necessary information about the demodulation and filtering steps,
|
||||||
|
//! such as whether to demodulate with a harmonic of the reference
|
||||||
|
//! signal and the IIR biquad filter to use. There are then 4
|
||||||
|
//! different processing steps that can be used:
|
||||||
|
//!
|
||||||
|
//! * `demodulate` - Computes the phase of the demodulation signal
|
||||||
|
//! corresponding to each ADC sample, uses this phase to compute the
|
||||||
|
//! demodulation signal, and multiplies this demodulation signal by
|
||||||
|
//! the ADC-sampled signal. This is a method of `Lockin` since it
|
||||||
|
//! requires information about how to modify the reference signal for
|
||||||
|
//! demodulation.
|
||||||
|
//! * `filter` - Performs IIR biquad filtering of a complex
|
||||||
|
//! signals. This is commonly performed on the signal provided by the
|
||||||
|
//! demodulation step, but can be performed at any other point in the
|
||||||
|
//! processing chain or omitted entirely. `filter` is a method of
|
||||||
|
//! `Lockin` since it must hold onto the filter configuration and
|
||||||
|
//! state.
|
||||||
|
//! * `decimate` - This decimates a signal to reduce the load on the
|
||||||
|
//! DAC output. It does not require any state information and is
|
||||||
|
//! therefore a normal function.
|
||||||
|
//! * `magnitude_phase` - Computes the magnitude and phase of the
|
||||||
|
//! component of the ADC-sampled signal whose frequency is equal to
|
||||||
|
//! the demodulation frequency. This does not require any state
|
||||||
|
//! information and is therefore a normal function.
|
||||||
|
|
||||||
|
use super::iir::{IIRState, IIR};
|
||||||
|
use super::Complex;
|
||||||
|
use core::f32::consts::PI;
|
||||||
|
|
||||||
|
/// The number of ADC samples in one batch.
|
||||||
|
pub const ADC_SAMPLE_BUFFER_SIZE: usize = 16;
|
||||||
|
/// The number of outputs sent to the DAC for each ADC batch.
|
||||||
|
pub const DECIMATED_BUFFER_SIZE: usize = 1;
|
||||||
|
|
||||||
|
/// Treat the 2-element array as a FIFO. This allows new elements to
|
||||||
|
/// be pushed into the array, existing elements to shift back in the
|
||||||
|
/// array, and the last element to fall off the array.
|
||||||
|
trait Fifo2<T> {
|
||||||
|
fn push(&mut self, new_element: Option<T>);
|
||||||
|
}
|
||||||
|
|
||||||
|
impl<T: Copy> Fifo2<T> for [Option<T>; 2] {
|
||||||
|
/// Push a new element into the array. The existing elements move
|
||||||
|
/// backward in the array by one location, and the current last
|
||||||
|
/// element is discarded.
|
||||||
|
///
|
||||||
|
/// # Arguments
|
||||||
|
///
|
||||||
|
/// * `new_element` - New element pushed into the front of the
|
||||||
|
/// array.
|
||||||
|
fn push(&mut self, new_element: Option<T>) {
|
||||||
|
// For array sizes greater than 2 it would be preferable to
|
||||||
|
// use a rotating index to avoid unnecessary data
|
||||||
|
// copying. However, this would somewhat complicate the use of
|
||||||
|
// iterators and for 2 elements, shifting is inexpensive.
|
||||||
|
self[1] = self[0];
|
||||||
|
self[0] = new_element;
|
||||||
|
}
|
||||||
|
}
|
||||||
|
|
||||||
|
/// Performs lock-in amplifier processing of a signal.
|
||||||
|
pub struct Lockin {
|
||||||
|
phase_offset: f32,
|
||||||
|
sample_period: u32,
|
||||||
|
harmonic: u32,
|
||||||
|
timestamps: [Option<i32>; 2],
|
||||||
|
iir: IIR,
|
||||||
|
iirstate: [IIRState; 2],
|
||||||
|
}
|
||||||
|
|
||||||
|
impl Lockin {
|
||||||
|
/// Initialize a new `Lockin` instance.
|
||||||
|
///
|
||||||
|
/// # Arguments
|
||||||
|
///
|
||||||
|
/// * `phase_offset` - Phase offset (in radians) applied to the
|
||||||
|
/// demodulation signal.
|
||||||
|
/// * `sample_period` - ADC sampling period in terms of the
|
||||||
|
/// internal clock period.
|
||||||
|
/// * `harmonic` - Integer scaling factor used to adjust the
|
||||||
|
/// demodulation frequency. E.g., 2 would demodulate with the
|
||||||
|
/// first harmonic.
|
||||||
|
/// * `iir` - IIR biquad filter.
|
||||||
|
///
|
||||||
|
/// # Returns
|
||||||
|
///
|
||||||
|
/// New `Lockin` instance.
|
||||||
|
pub fn new(
|
||||||
|
phase_offset: f32,
|
||||||
|
sample_period: u32,
|
||||||
|
harmonic: u32,
|
||||||
|
iir: IIR,
|
||||||
|
) -> Self {
|
||||||
|
Lockin {
|
||||||
|
phase_offset: phase_offset,
|
||||||
|
sample_period: sample_period,
|
||||||
|
harmonic: harmonic,
|
||||||
|
timestamps: [None, None],
|
||||||
|
iir: iir,
|
||||||
|
iirstate: [[0.; 5]; 2],
|
||||||
|
}
|
||||||
|
}
|
||||||
|
|
||||||
|
/// Demodulate an input signal with the complex reference signal.
|
||||||
|
///
|
||||||
|
/// # Arguments
|
||||||
|
///
|
||||||
|
/// * `adc_samples` - One batch of ADC samples.
|
||||||
|
/// * `timestamps` - Counter values corresponding to the edges of
|
||||||
|
/// an external reference signal. The counter is incremented by a
|
||||||
|
/// fast internal clock.
|
||||||
|
///
|
||||||
|
/// # Returns
|
||||||
|
///
|
||||||
|
/// The demodulated complex signal as a `Result`. When there are
|
||||||
|
/// an insufficient number of timestamps to perform processing,
|
||||||
|
/// `Err` is returned.
|
||||||
|
///
|
||||||
|
/// # Assumptions
|
||||||
|
///
|
||||||
|
/// `demodulate` expects that the timestamp counter value is equal
|
||||||
|
/// to 0 when the ADC samples its first input in a batch. This can
|
||||||
|
/// be achieved by configuring the timestamp counter to overflow
|
||||||
|
/// at the end of the ADC batch sampling period.
|
||||||
|
pub fn demodulate(
|
||||||
|
&mut self,
|
||||||
|
adc_samples: &[i16],
|
||||||
|
timestamps: &[u16],
|
||||||
|
) -> Result<[Complex<f32>; ADC_SAMPLE_BUFFER_SIZE], &str> {
|
||||||
|
let sample_period = self.sample_period as i32;
|
||||||
|
// update old timestamps for new ADC batch
|
||||||
|
self.timestamps.iter_mut().for_each(|t| match *t {
|
||||||
|
Some(timestamp) => {
|
||||||
|
// Existing timestamps have aged by one ADC batch
|
||||||
|
// period since the last ADC batch.
|
||||||
|
*t = Some(
|
||||||
|
timestamp - ADC_SAMPLE_BUFFER_SIZE as i32 * sample_period,
|
||||||
|
);
|
||||||
|
}
|
||||||
|
None => (),
|
||||||
|
});
|
||||||
|
|
||||||
|
// return prematurely if there aren't enough timestamps for
|
||||||
|
// processing
|
||||||
|
let old_timestamp_count =
|
||||||
|
self.timestamps.iter().filter(|t| t.is_some()).count();
|
||||||
|
if old_timestamp_count + timestamps.len() < 2 {
|
||||||
|
return Err("insufficient timestamps");
|
||||||
|
}
|
||||||
|
|
||||||
|
let mut signal = [(0., 0.); ADC_SAMPLE_BUFFER_SIZE];
|
||||||
|
// if we have not yet recorded any timestamps, the first
|
||||||
|
// reference period must be computed from the first and
|
||||||
|
// second timestamps in the array
|
||||||
|
let mut timestamp_index: usize =
|
||||||
|
if old_timestamp_count == 0 { 1 } else { 0 };
|
||||||
|
|
||||||
|
// compute ADC sample phases, sines/cosines and demodulate
|
||||||
|
signal
|
||||||
|
.iter_mut()
|
||||||
|
.zip(adc_samples.iter())
|
||||||
|
.enumerate()
|
||||||
|
.for_each(|(i, (s, sample))| {
|
||||||
|
let adc_sample_count = i as i32 * sample_period;
|
||||||
|
// index of the closest timestamp that occurred after
|
||||||
|
// the current ADC sample
|
||||||
|
let closest_timestamp_after_index: i32 = if timestamps.len() > 0
|
||||||
|
{
|
||||||
|
// Linear search is fast because both the timestamps
|
||||||
|
// and ADC sample counts are sorted. Because of this,
|
||||||
|
// we only need to check timestamps that were also
|
||||||
|
// greater than the last ADC sample count.
|
||||||
|
while timestamp_index < timestamps.len() - 1
|
||||||
|
&& (timestamps[timestamp_index] as i32)
|
||||||
|
< adc_sample_count
|
||||||
|
{
|
||||||
|
timestamp_index += 1;
|
||||||
|
}
|
||||||
|
timestamp_index as i32
|
||||||
|
} else {
|
||||||
|
-1
|
||||||
|
};
|
||||||
|
|
||||||
|
// closest timestamp that occurred before the current
|
||||||
|
// ADC sample
|
||||||
|
let closest_timestamp_before: i32;
|
||||||
|
let reference_period = if closest_timestamp_after_index < 0 {
|
||||||
|
closest_timestamp_before = self.timestamps[0].unwrap();
|
||||||
|
closest_timestamp_before - self.timestamps[1].unwrap()
|
||||||
|
} else if closest_timestamp_after_index == 0 {
|
||||||
|
closest_timestamp_before = self.timestamps[0].unwrap();
|
||||||
|
timestamps[0] as i32 - closest_timestamp_before
|
||||||
|
} else {
|
||||||
|
closest_timestamp_before = timestamps
|
||||||
|
[(closest_timestamp_after_index - 1) as usize]
|
||||||
|
as i32;
|
||||||
|
timestamps[closest_timestamp_after_index as usize] as i32
|
||||||
|
- closest_timestamp_before
|
||||||
|
};
|
||||||
|
|
||||||
|
let integer_phase: i32 = (adc_sample_count
|
||||||
|
- closest_timestamp_before)
|
||||||
|
* self.harmonic as i32;
|
||||||
|
let phase = self.phase_offset
|
||||||
|
+ 2. * PI * integer_phase as f32 / reference_period as f32;
|
||||||
|
let (sine, cosine) = libm::sincosf(phase);
|
||||||
|
let sample = *sample as f32;
|
||||||
|
s.0 = sine * sample;
|
||||||
|
s.1 = cosine * sample;
|
||||||
|
});
|
||||||
|
|
||||||
|
// record new timestamps
|
||||||
|
let start_index: usize = if timestamps.len() < 2 {
|
||||||
|
0
|
||||||
|
} else {
|
||||||
|
timestamps.len() - 2
|
||||||
|
};
|
||||||
|
timestamps[start_index..]
|
||||||
|
.iter()
|
||||||
|
.for_each(|t| self.timestamps.push(Some(*t as i32)));
|
||||||
|
|
||||||
|
Ok(signal)
|
||||||
|
}
|
||||||
|
|
||||||
|
/// Filter the complex signal using the supplied biquad IIR. The
|
||||||
|
/// signal array is modified in place.
|
||||||
|
///
|
||||||
|
/// # Arguments
|
||||||
|
///
|
||||||
|
/// * `signal` - Complex signal to filter.
|
||||||
|
pub fn filter(&mut self, signal: &mut [Complex<f32>]) {
|
||||||
|
signal.iter_mut().for_each(|s| {
|
||||||
|
s.0 = self.iir.update(&mut self.iirstate[0], s.0);
|
||||||
|
s.1 = self.iir.update(&mut self.iirstate[1], s.1);
|
||||||
|
});
|
||||||
|
}
|
||||||
|
}
|
||||||
|
|
||||||
|
/// Decimate the complex signal to `DECIMATED_BUFFER_SIZE`. The ratio
|
||||||
|
/// of `ADC_SAMPLE_BUFFER_SIZE` to `DECIMATED_BUFFER_SIZE` must be a
|
||||||
|
/// power of 2.
|
||||||
|
///
|
||||||
|
/// # Arguments
|
||||||
|
///
|
||||||
|
/// * `signal` - Complex signal to decimate.
|
||||||
|
///
|
||||||
|
/// # Returns
|
||||||
|
///
|
||||||
|
/// The decimated signal.
|
||||||
|
pub fn decimate(
|
||||||
|
signal: [Complex<f32>; ADC_SAMPLE_BUFFER_SIZE],
|
||||||
|
) -> [Complex<f32>; DECIMATED_BUFFER_SIZE] {
|
||||||
|
let n_k = ADC_SAMPLE_BUFFER_SIZE / DECIMATED_BUFFER_SIZE;
|
||||||
|
debug_assert!(
|
||||||
|
ADC_SAMPLE_BUFFER_SIZE == DECIMATED_BUFFER_SIZE || n_k % 2 == 0
|
||||||
|
);
|
||||||
|
|
||||||
|
let mut signal_decimated = [(0_f32, 0_f32); DECIMATED_BUFFER_SIZE];
|
||||||
|
|
||||||
|
signal_decimated
|
||||||
|
.iter_mut()
|
||||||
|
.zip(signal.iter().step_by(n_k))
|
||||||
|
.for_each(|(s_d, s)| {
|
||||||
|
s_d.0 = s.0;
|
||||||
|
s_d.1 = s.1;
|
||||||
|
});
|
||||||
|
|
||||||
|
signal_decimated
|
||||||
|
}
|
||||||
|
|
||||||
|
/// Compute the magnitude and phase from the complex signal. The
|
||||||
|
/// signal array is modified in place.
|
||||||
|
///
|
||||||
|
/// # Arguments
|
||||||
|
///
|
||||||
|
/// * `signal` - Complex signal to decimate.
|
||||||
|
pub fn magnitude_phase(signal: &mut [Complex<f32>]) {
|
||||||
|
signal.iter_mut().for_each(|s| {
|
||||||
|
let new_i = libm::sqrtf([s.0, s.1].iter().map(|i| i * i).sum());
|
||||||
|
let new_q = libm::atan2f(s.1, s.0);
|
||||||
|
s.0 = new_i;
|
||||||
|
s.1 = new_q;
|
||||||
|
});
|
||||||
|
}
|
||||||
|
|
||||||
|
#[cfg(test)]
|
||||||
|
mod tests {
|
||||||
|
use super::*;
|
||||||
|
use crate::testing::complex_allclose;
|
||||||
|
|
||||||
|
#[test]
|
||||||
|
fn array_push() {
|
||||||
|
let mut arr: [Option<u32>; 2] = [None, None];
|
||||||
|
arr.push(Some(1));
|
||||||
|
assert_eq!(arr, [Some(1), None]);
|
||||||
|
arr.push(Some(2));
|
||||||
|
assert_eq!(arr, [Some(2), Some(1)]);
|
||||||
|
arr.push(Some(10));
|
||||||
|
assert_eq!(arr, [Some(10), Some(2)]);
|
||||||
|
}
|
||||||
|
|
||||||
|
#[test]
|
||||||
|
fn magnitude_phase_length_1_quadrant_1() {
|
||||||
|
let mut signal: [Complex<f32>; 1] = [(1., 1.)];
|
||||||
|
magnitude_phase(&mut signal);
|
||||||
|
assert!(complex_allclose(
|
||||||
|
&signal,
|
||||||
|
&[(2_f32.sqrt(), PI / 4.)],
|
||||||
|
f32::EPSILON,
|
||||||
|
0.
|
||||||
|
));
|
||||||
|
|
||||||
|
signal = [(3_f32.sqrt() / 2., 1. / 2.)];
|
||||||
|
magnitude_phase(&mut signal);
|
||||||
|
assert!(complex_allclose(
|
||||||
|
&signal,
|
||||||
|
&[(1., PI / 6.)],
|
||||||
|
f32::EPSILON,
|
||||||
|
0.
|
||||||
|
));
|
||||||
|
}
|
||||||
|
|
||||||
|
#[test]
|
||||||
|
fn magnitude_phase_length_1_quadrant_2() {
|
||||||
|
let mut signal = [(-1., 1.)];
|
||||||
|
magnitude_phase(&mut signal);
|
||||||
|
assert!(complex_allclose(
|
||||||
|
&signal,
|
||||||
|
&[(2_f32.sqrt(), 3. * PI / 4.)],
|
||||||
|
f32::EPSILON,
|
||||||
|
0.
|
||||||
|
));
|
||||||
|
|
||||||
|
signal = [(-1. / 2., 3_f32.sqrt() / 2.)];
|
||||||
|
magnitude_phase(&mut signal);
|
||||||
|
assert!(complex_allclose(
|
||||||
|
&signal,
|
||||||
|
&[(1_f32, 2. * PI / 3.)],
|
||||||
|
f32::EPSILON,
|
||||||
|
0.
|
||||||
|
));
|
||||||
|
}
|
||||||
|
|
||||||
|
#[test]
|
||||||
|
fn magnitude_phase_length_1_quadrant_3() {
|
||||||
|
let mut signal = [(-1. / 2_f32.sqrt(), -1. / 2_f32.sqrt())];
|
||||||
|
magnitude_phase(&mut signal);
|
||||||
|
assert!(complex_allclose(
|
||||||
|
&signal,
|
||||||
|
&[(1_f32.sqrt(), -3. * PI / 4.)],
|
||||||
|
f32::EPSILON,
|
||||||
|
0.
|
||||||
|
));
|
||||||
|
|
||||||
|
signal = [(-1. / 2., -2_f32.sqrt())];
|
||||||
|
magnitude_phase(&mut signal);
|
||||||
|
assert!(complex_allclose(
|
||||||
|
&signal,
|
||||||
|
&[((3. / 2.) as f32, -1.91063323625 as f32)],
|
||||||
|
f32::EPSILON,
|
||||||
|
0.
|
||||||
|
));
|
||||||
|
}
|
||||||
|
|
||||||
|
#[test]
|
||||||
|
fn magnitude_phase_length_1_quadrant_4() {
|
||||||
|
let mut signal = [(1. / 2_f32.sqrt(), -1. / 2_f32.sqrt())];
|
||||||
|
magnitude_phase(&mut signal);
|
||||||
|
assert!(complex_allclose(
|
||||||
|
&signal,
|
||||||
|
&[(1_f32.sqrt(), -1. * PI / 4.)],
|
||||||
|
f32::EPSILON,
|
||||||
|
0.
|
||||||
|
));
|
||||||
|
|
||||||
|
signal = [(3_f32.sqrt() / 2., -1. / 2.)];
|
||||||
|
magnitude_phase(&mut signal);
|
||||||
|
assert!(complex_allclose(
|
||||||
|
&signal,
|
||||||
|
&[(1_f32, -PI / 6.)],
|
||||||
|
f32::EPSILON,
|
||||||
|
0.
|
||||||
|
));
|
||||||
|
}
|
||||||
|
|
||||||
|
#[test]
|
||||||
|
fn decimate_sample_16_decimated_1() {
|
||||||
|
let signal: [Complex<f32>; ADC_SAMPLE_BUFFER_SIZE] = [
|
||||||
|
(0.0, 1.6),
|
||||||
|
(0.1, 1.7),
|
||||||
|
(0.2, 1.8),
|
||||||
|
(0.3, 1.9),
|
||||||
|
(0.4, 2.0),
|
||||||
|
(0.5, 2.1),
|
||||||
|
(0.6, 2.2),
|
||||||
|
(0.7, 2.3),
|
||||||
|
(0.8, 2.4),
|
||||||
|
(0.9, 2.5),
|
||||||
|
(1.0, 2.6),
|
||||||
|
(1.1, 2.7),
|
||||||
|
(1.2, 2.8),
|
||||||
|
(1.3, 2.9),
|
||||||
|
(1.4, 3.0),
|
||||||
|
(1.5, 3.1),
|
||||||
|
];
|
||||||
|
assert_eq!(decimate(signal), [(0.0, 1.6)]);
|
||||||
|
}
|
||||||
|
|
||||||
|
#[test]
|
||||||
|
fn lockin_demodulate_valid_0() {
|
||||||
|
let mut lockin = Lockin::new(
|
||||||
|
0.,
|
||||||
|
200,
|
||||||
|
1,
|
||||||
|
IIR {
|
||||||
|
ba: [0_f32; 5],
|
||||||
|
y_offset: 0.,
|
||||||
|
y_min: -(1 << 15) as f32,
|
||||||
|
y_max: (1 << 15) as f32 - 1.,
|
||||||
|
},
|
||||||
|
);
|
||||||
|
assert_eq!(
|
||||||
|
lockin.demodulate(&[0; ADC_SAMPLE_BUFFER_SIZE], &[]),
|
||||||
|
Err("insufficient timestamps")
|
||||||
|
);
|
||||||
|
}
|
||||||
|
|
||||||
|
#[test]
|
||||||
|
fn lockin_demodulate_valid_1() {
|
||||||
|
let mut lockin = Lockin::new(
|
||||||
|
0.,
|
||||||
|
200,
|
||||||
|
1,
|
||||||
|
IIR {
|
||||||
|
ba: [0_f32; 5],
|
||||||
|
y_offset: 0.,
|
||||||
|
y_min: -(1 << 15) as f32,
|
||||||
|
y_max: (1 << 15) as f32 - 1.,
|
||||||
|
},
|
||||||
|
);
|
||||||
|
assert_eq!(
|
||||||
|
lockin.demodulate(&[0; ADC_SAMPLE_BUFFER_SIZE], &[0],),
|
||||||
|
Err("insufficient timestamps")
|
||||||
|
);
|
||||||
|
}
|
||||||
|
|
||||||
|
#[test]
|
||||||
|
fn lockin_demodulate_valid_2() {
|
||||||
|
let adc_period: u32 = 200;
|
||||||
|
let mut lockin = Lockin::new(
|
||||||
|
0.,
|
||||||
|
adc_period,
|
||||||
|
1,
|
||||||
|
IIR {
|
||||||
|
ba: [0_f32; 5],
|
||||||
|
y_offset: 0.,
|
||||||
|
y_min: -(1 << 15) as f32,
|
||||||
|
y_max: (1 << 15) as f32 - 1.,
|
||||||
|
},
|
||||||
|
);
|
||||||
|
let adc_samples: [i16; ADC_SAMPLE_BUFFER_SIZE] =
|
||||||
|
[-8, 7, -7, 6, -6, 5, -5, 4, -4, 3, -3, 2, -2, -1, 1, 0];
|
||||||
|
let reference_period: u16 = 2800;
|
||||||
|
let initial_phase_integer: u16 = 200;
|
||||||
|
let timestamps: &[u16] = &[
|
||||||
|
initial_phase_integer,
|
||||||
|
initial_phase_integer + reference_period,
|
||||||
|
];
|
||||||
|
let initial_phase: f32 =
|
||||||
|
-(initial_phase_integer as f32) / reference_period as f32 * 2. * PI;
|
||||||
|
let phase_increment: f32 =
|
||||||
|
adc_period as f32 / reference_period as f32 * 2. * PI;
|
||||||
|
let mut signal = [(0., 0.); ADC_SAMPLE_BUFFER_SIZE];
|
||||||
|
for (n, s) in signal.iter_mut().enumerate() {
|
||||||
|
let adc_phase = initial_phase + n as f32 * phase_increment;
|
||||||
|
let sine = adc_phase.sin();
|
||||||
|
let cosine = adc_phase.cos();
|
||||||
|
s.0 = sine * adc_samples[n] as f32;
|
||||||
|
s.1 = cosine * adc_samples[n] as f32;
|
||||||
|
}
|
||||||
|
let result = lockin.demodulate(&adc_samples, timestamps).unwrap();
|
||||||
|
assert!(
|
||||||
|
complex_allclose(&result, &signal, 0., 1e-5),
|
||||||
|
"\nsignal computed: {:?},\nsignal expected: {:?}",
|
||||||
|
result,
|
||||||
|
signal
|
||||||
|
);
|
||||||
|
}
|
||||||
|
}
|
|
@ -0,0 +1,27 @@
|
||||||
|
use super::Complex;
|
||||||
|
|
||||||
|
pub fn isclose(a: f32, b: f32, rtol: f32, atol: f32) -> bool {
|
||||||
|
(a - b).abs() <= a.abs().max(b.abs()) * rtol + atol
|
||||||
|
}
|
||||||
|
|
||||||
|
pub fn complex_isclose(
|
||||||
|
a: Complex<f32>,
|
||||||
|
b: Complex<f32>,
|
||||||
|
rtol: f32,
|
||||||
|
atol: f32,
|
||||||
|
) -> bool {
|
||||||
|
isclose(a.0, b.0, rtol, atol) && isclose(a.1, b.1, rtol, atol)
|
||||||
|
}
|
||||||
|
|
||||||
|
pub fn complex_allclose(
|
||||||
|
a: &[Complex<f32>],
|
||||||
|
b: &[Complex<f32>],
|
||||||
|
rtol: f32,
|
||||||
|
atol: f32,
|
||||||
|
) -> bool {
|
||||||
|
let mut result: bool = true;
|
||||||
|
a.iter().zip(b.iter()).for_each(|(i, j)| {
|
||||||
|
result &= complex_isclose(*i, *j, rtol, atol);
|
||||||
|
});
|
||||||
|
result
|
||||||
|
}
|
File diff suppressed because it is too large
Load Diff
Loading…
Reference in New Issue