pll: refine gains
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1425608647
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469c89ea70
@ -10,12 +10,14 @@ use serde::{Deserialize, Serialize};
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/// stable for any gain (1 <= shift <= 30). It has a single parameter that determines the loop
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/// stable for any gain (1 <= shift <= 30). It has a single parameter that determines the loop
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/// bandwidth in octave steps. The gain can be changed freely between updates.
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/// bandwidth in octave steps. The gain can be changed freely between updates.
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///
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///
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/// The frequency and phase settling time constants for an (any) frequency jump are `1 << shift`
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/// The frequency and phase settling time constants for a frequency/phase jump are `1 << shift`
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/// update cycles. The loop bandwidth is about `1/(2*pi*(1 << shift))` in units of the sample rate.
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/// update cycles. The loop bandwidth is about `1/(2*pi*(1 << shift))` in units of the sample rate.
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/// While the phase is being settled within one turn, there is a typically very small frequency
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/// overshoot.
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///
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///
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/// All math is naturally wrapping 32 bit integer. Phase and frequency are understood modulo that
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/// All math is naturally wrapping 32 bit integer. Phase and frequency are understood modulo that
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/// overflow in the first Nyquist zone. Expressing the IIR equations in other ways (e.g. single
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/// overflow in the first Nyquist zone. Expressing the IIR equations in other ways (e.g. single
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/// (T)-DF-{I,II} biquad/IIR) would break on overflow.
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/// (T)-DF-{I,II} biquad/IIR) would break on overflow (i.e. every cycle).
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///
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///
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/// There are no floating point rounding errors here. But there is integer quantization/truncation
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/// There are no floating point rounding errors here. But there is integer quantization/truncation
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/// error of the `shift` lowest bits leading to a phase offset for very low gains. Truncation
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/// error of the `shift` lowest bits leading to a phase offset for very low gains. Truncation
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@ -23,8 +25,8 @@ use serde::{Deserialize, Serialize};
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/// efficiently by dithering.
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/// efficiently by dithering.
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///
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///
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/// This PLL does not unwrap phase slips during lock acquisition. This can and should be
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/// This PLL does not unwrap phase slips during lock acquisition. This can and should be
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/// implemented elsewhere by (down) scaling and then unwrapping the input phase and (up) scaling
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/// implemented elsewhere by unwrapping and scaling the input phase and un-scaling
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/// and wrapping output phase and frequency. This affects dynamic range accordingly.
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/// and wrapping output phase and frequency. This affects dynamic range, gain, and noise accordingly.
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///
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///
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/// The extension to I^3,I^2,I behavior to track chirps phase-accurately or to i64 data to
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/// The extension to I^3,I^2,I behavior to track chirps phase-accurately or to i64 data to
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/// increase resolution for extremely narrowband applications is obvious.
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/// increase resolution for extremely narrowband applications is obvious.
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@ -39,25 +41,39 @@ pub struct PLL {
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}
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}
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impl PLL {
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impl PLL {
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/// Update the PLL with a new phase sample.
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/// Update the PLL with a new phase sample. This needs to be called (sampled) periodically.
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/// The signal's phase/frequency is reconstructed relative to the sampling period.
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///
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///
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/// Args:
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/// Args:
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/// * `input`: New input phase sample.
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/// * `input`: New input phase sample.
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/// * `shift`: Error scaling. The frequency gain per update is `1/(1 << shift)`. The phase gain
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/// * `shift_frequency`: Frequency error scaling. The frequency gain per update is
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/// is always twice the frequency gain.
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/// `1/(1 << shift_frequency)`.
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/// * `shift_phase`: Phase error scaling. The phase gain is `1/(1 << shift_phase)`
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/// per update. A good value is typically `shift_frequency - 1`.
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///
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///
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/// Returns:
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/// Returns:
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/// A tuple of instantaneous phase and frequency (the current phase increment).
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/// A tuple of instantaneous phase and frequency (the current phase increment).
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pub fn update(&mut self, x: i32, shift: u8) -> (i32, i32) {
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pub fn update(
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debug_assert!((1..=30).contains(&shift));
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&mut self,
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let bias = 1i32 << shift;
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x: i32,
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shift_frequency: u8,
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shift_phase: u8,
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) -> (i32, i32) {
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debug_assert!((1..=30).contains(&shift_frequency));
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debug_assert!((1..=30).contains(&shift_phase));
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let e = x.wrapping_sub(self.f);
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let e = x.wrapping_sub(self.f);
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self.f = self.f.wrapping_add(
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self.f = self.f.wrapping_add(
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(bias >> 1).wrapping_add(e).wrapping_sub(self.x) >> shift,
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(1i32 << (shift_frequency - 1))
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.wrapping_add(e)
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.wrapping_sub(self.x)
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>> shift_frequency,
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);
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);
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self.x = x;
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self.x = x;
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let f = self.f.wrapping_add(
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let f = self.f.wrapping_add(
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bias.wrapping_add(e).wrapping_sub(self.y) >> (shift - 1),
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(1i32 << (shift_phase - 1))
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.wrapping_add(e)
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.wrapping_sub(self.y)
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>> shift_phase,
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);
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);
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self.y = self.y.wrapping_add(f);
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self.y = self.y.wrapping_add(f);
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(self.y, f)
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(self.y, f)
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@ -70,8 +86,8 @@ mod tests {
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#[test]
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#[test]
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fn mini() {
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fn mini() {
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let mut p = PLL::default();
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let mut p = PLL::default();
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let (y, f) = p.update(0x10000, 10);
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let (y, f) = p.update(0x10000, 8, 4);
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assert_eq!(y, 0xc2);
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assert_eq!(y, 0x1100);
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assert_eq!(f, y);
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assert_eq!(f, y);
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}
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}
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@ -79,17 +95,17 @@ mod tests {
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fn converge() {
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fn converge() {
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let mut p = PLL::default();
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let mut p = PLL::default();
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let f0 = 0x71f63049_i32;
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let f0 = 0x71f63049_i32;
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let shift = 10;
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let shift = (10, 9);
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let n = 31 << shift + 2;
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let n = 31 << shift.0 + 2;
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let mut x = 0i32;
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let mut x = 0i32;
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for i in 0..n {
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for i in 0..n {
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x = x.wrapping_add(f0);
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x = x.wrapping_add(f0);
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let (y, f) = p.update(x, shift);
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let (y, f) = p.update(x, shift.0, shift.1);
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if i > n / 4 {
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if i > n / 4 {
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assert_eq!(f.wrapping_sub(f0).abs() <= 1, true);
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assert_eq!(f.wrapping_sub(f0).abs() <= 1, true);
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}
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}
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if i > n / 2 {
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if i > n / 2 {
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// The remaining error is removed by dithering.
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// The remaining error would be removed by dithering.
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assert_eq!(y.wrapping_sub(x).abs() < 1 << 18, true);
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assert_eq!(y.wrapping_sub(x).abs() < 1 << 18, true);
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}
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}
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}
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}
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