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7 Commits
82010fc745 ... master

Author SHA1 Message Date
Lukrecja
4295dd2aab implement a BPSK decoder for demodulated data, add hal feature for use on non-STM32 targets 2026-03-03 13:28:34 +01:00
Lukrecja
91a9b4a311 implement software framing for BPSK modulation 2026-02-28 01:28:53 +01:00
Lukrecja
085e791ec6 change example FSK settings to more sensible values, set Variable packet type as default for FSK and MSK 2026-02-27 21:30:13 +01:00
Lukrecja
757111afda update examples, add new ones 2026-02-26 19:53:24 +01:00
Lukrecja
709bff6d5d implement FSK and MSK (rx and tx for both) 2026-02-26 19:53:06 +01:00
Lukrecja
62e586a776 use the new rx gain setting in lora 2026-02-26 19:52:40 +01:00
Lukrecja
da308fe23e add configurable rx gain setting 2026-02-26 19:52:05 +01:00
15 changed files with 1285 additions and 60 deletions
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55
Cargo.toml
View File

@@ -15,36 +15,39 @@ members = ["examples/stm32wle5jc"]
# Default chip for development/CI. Downstream users should use default-features = false
# and enable their specific chip feature.
default = ["stm32wle5jc"]
# Hardware abstraction layer, which enables embedded radio driver and all hardware deps
# When it's disabled, some parts of the code, such as BPSK frame decoding, can be used
hal = ["dep:embassy-stm32", "dep:embassy-time", "dep:defmt", "dep:cortex-m", "dep:embedded-hal", "dep:embedded-hal-async"]
# Single-core variants
stm32wle4c8 = ["embassy-stm32/stm32wle4c8"]
stm32wle4cb = ["embassy-stm32/stm32wle4cb"]
stm32wle4cc = ["embassy-stm32/stm32wle4cc"]
stm32wle4j8 = ["embassy-stm32/stm32wle4j8"]
stm32wle4jb = ["embassy-stm32/stm32wle4jb"]
stm32wle4jc = ["embassy-stm32/stm32wle4jc"]
stm32wle5c8 = ["embassy-stm32/stm32wle5c8"]
stm32wle5cb = ["embassy-stm32/stm32wle5cb"]
stm32wle5cc = ["embassy-stm32/stm32wle5cc"]
stm32wle5j8 = ["embassy-stm32/stm32wle5j8"]
stm32wle5jb = ["embassy-stm32/stm32wle5jb"]
stm32wle5jc = ["embassy-stm32/stm32wle5jc"]
stm32wle4c8 = ["hal", "embassy-stm32/stm32wle4c8"]
stm32wle4cb = ["hal", "embassy-stm32/stm32wle4cb"]
stm32wle4cc = ["hal", "embassy-stm32/stm32wle4cc"]
stm32wle4j8 = ["hal", "embassy-stm32/stm32wle4j8"]
stm32wle4jb = ["hal", "embassy-stm32/stm32wle4jb"]
stm32wle4jc = ["hal", "embassy-stm32/stm32wle4jc"]
stm32wle5c8 = ["hal", "embassy-stm32/stm32wle5c8"]
stm32wle5cb = ["hal", "embassy-stm32/stm32wle5cb"]
stm32wle5cc = ["hal", "embassy-stm32/stm32wle5cc"]
stm32wle5j8 = ["hal", "embassy-stm32/stm32wle5j8"]
stm32wle5jb = ["hal", "embassy-stm32/stm32wle5jb"]
stm32wle5jc = ["hal", "embassy-stm32/stm32wle5jc"]
# Dual-core variants
stm32wl54cc-cm0p = ["embassy-stm32/stm32wl54cc-cm0p"]
stm32wl54cc-cm4 = ["embassy-stm32/stm32wl54cc-cm4"]
stm32wl54jc-cm0p = ["embassy-stm32/stm32wl54jc-cm0p"]
stm32wl54jc-cm4 = ["embassy-stm32/stm32wl54jc-cm4"]
stm32wl55cc-cm0p = ["embassy-stm32/stm32wl55cc-cm0p"]
stm32wl55cc-cm4 = ["embassy-stm32/stm32wl55cc-cm4"]
stm32wl55jc-cm0p = ["embassy-stm32/stm32wl55jc-cm0p"]
stm32wl55jc-cm4 = ["embassy-stm32/stm32wl55jc-cm4"]
stm32wl54cc-cm0p = ["hal", "embassy-stm32/stm32wl54cc-cm0p"]
stm32wl54cc-cm4 = ["hal", "embassy-stm32/stm32wl54cc-cm4"]
stm32wl54jc-cm0p = ["hal", "embassy-stm32/stm32wl54jc-cm0p"]
stm32wl54jc-cm4 = ["hal", "embassy-stm32/stm32wl54jc-cm4"]
stm32wl55cc-cm0p = ["hal", "embassy-stm32/stm32wl55cc-cm0p"]
stm32wl55cc-cm4 = ["hal", "embassy-stm32/stm32wl55cc-cm4"]
stm32wl55jc-cm0p = ["hal", "embassy-stm32/stm32wl55jc-cm0p"]
stm32wl55jc-cm4 = ["hal", "embassy-stm32/stm32wl55jc-cm4"]
[dependencies]
embassy-stm32 = { version = "0.5.0", features = ["unstable-pac"] }
embassy-time = "0.5.0"
defmt = "1.0.1"
cortex-m = { version = "0.7.6", features = ["inline-asm"] }
embedded-hal = "1.0.0"
embedded-hal-async = "1.0.0"
embassy-stm32 = { version = "0.5.0", features = ["unstable-pac"], optional = true }
embassy-time = { version = "0.5.0", optional = true }
defmt = { version = "1.0.1", optional = true }
cortex-m = { version = "0.7.6", features = ["inline-asm"], optional = true }
embedded-hal = { version = "1.0.0", optional = true }
embedded-hal-async = { version = "1.0.0", optional = true }
[profile.release]
debug = 2

13
examples/stm32wle5jc/src/bin/bpsk_tx.rs
View File

@@ -9,7 +9,6 @@ use embassy_stm32::{
rcc::{MSIRange, Sysclk, mux},
spi::Spi,
};
use embassy_time::{Duration, Timer};
use stm32wl_subghz::{
Configure, PaSelection, Radio, SubGhzSpiDevice, Transmit,
modulations::bpsk::{Bitrate, BpskConfig, BpskRadio},
@@ -39,19 +38,15 @@ async fn main(_spawner: Spawner) {
frequency: 868_100_000,
bitrate: Bitrate::Bps600,
pa: PaSelection::HighPower,
power_dbm: 17,
power_dbm: 22,
..Default::default()
})
.await
.unwrap();
info!("sending stuffs");
match bpsk.tx(b"hiiiii!").await {
Ok(_) => info!("yay :3"),
info!("sending bpsk stuffs");
match bpsk.tx(b"hiiiii hello :3 :3 :3 this is a looooooooooooooooong text! very long :> and cute! :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 ummmm urghhh awwwooooooo woof wooooof woof").await {
Ok(_) => info!("yay tx done :3"),
Err(e) => error!("tx error: {:?}", e),
}
loop {
Timer::after(Duration::from_secs(1)).await;
}
}

56
examples/stm32wle5jc/src/bin/fsk_rx.rs Normal file
View File

@@ -0,0 +1,56 @@
#![no_std]
#![no_main]
use defmt::{error, info, warn};
use embassy_executor::Spawner;
use embassy_stm32::{
Config,
gpio::{Level, Output, Speed},
rcc::{MSIRange, Sysclk, mux},
spi::Spi,
};
use stm32wl_subghz::{
Configure, PaSelection, Radio, RadioError, Receive, SubGhzSpiDevice,
modulations::fsk::{Bandwidth, Bitrate, FreqDev, FskConfig, FskRadio},
};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let mut config = Config::default();
{
config.rcc.msi = Some(MSIRange::RANGE48M);
config.rcc.sys = Sysclk::MSI;
config.rcc.mux.rngsel = mux::Rngsel::MSI;
config.enable_debug_during_sleep = true;
}
let p = embassy_stm32::init(config);
let spi = SubGhzSpiDevice(Spi::new_subghz(p.SUBGHZSPI, p.DMA1_CH1, p.DMA1_CH2));
let rf_tx = Output::new(p.PC4, Level::Low, Speed::High);
let rf_rx = Output::new(p.PC5, Level::Low, Speed::High);
let rf_en = Output::new(p.PC3, Level::Low, Speed::High);
let mut radio = Radio::new(spi, rf_tx, rf_rx, rf_en);
radio.init().await.unwrap();
let mut fsk = FskRadio::new(&mut radio);
fsk.configure(&FskConfig {
frequency: 868_100_000,
bitrate: Bitrate::Custom(600),
fdev: FreqDev::Hz(380),
bandwidth: Bandwidth::Bw4_8kHz, // >= 2 * (380 + 600/2) = 1.36kHz
pa: PaSelection::HighPower,
power_dbm: 22,
..Default::default()
})
.await
.unwrap();
info!("waiting for fsk stuffs...");
let mut buf = [0u8; 255];
match fsk.rx(&mut buf, 5_000).await {
Ok(len) => info!("yay :3 got {} bytes: {:x}", len, &buf[..len]),
Err(RadioError::Timeout) => warn!("nobody is talking to me :<"),
Err(e) => error!("rx error: {:?}", e),
}
}

53
examples/stm32wle5jc/src/bin/fsk_tx.rs Normal file
View File

@@ -0,0 +1,53 @@
#![no_std]
#![no_main]
use defmt::{error, info};
use embassy_executor::Spawner;
use embassy_stm32::{
Config,
gpio::{Level, Output, Speed},
rcc::{MSIRange, Sysclk, mux},
spi::Spi,
};
use stm32wl_subghz::{
Configure, PaSelection, Radio, SubGhzSpiDevice, Transmit,
modulations::fsk::{Bitrate, FreqDev, FskConfig, FskRadio},
};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let mut config = Config::default();
{
config.rcc.msi = Some(MSIRange::RANGE48M);
config.rcc.sys = Sysclk::MSI;
config.rcc.mux.rngsel = mux::Rngsel::MSI;
config.enable_debug_during_sleep = true;
}
let p = embassy_stm32::init(config);
let spi = SubGhzSpiDevice(Spi::new_subghz(p.SUBGHZSPI, p.DMA1_CH1, p.DMA1_CH2));
let rf_tx = Output::new(p.PC4, Level::Low, Speed::High);
let rf_rx = Output::new(p.PC5, Level::Low, Speed::High);
let rf_en = Output::new(p.PC3, Level::Low, Speed::High);
let mut radio = Radio::new(spi, rf_tx, rf_rx, rf_en);
radio.init().await.unwrap();
let mut fsk = FskRadio::new(&mut radio);
fsk.configure(&FskConfig {
frequency: 868_100_000,
bitrate: Bitrate::Custom(600),
fdev: FreqDev::Hz(380),
pa: PaSelection::HighPower,
power_dbm: 22,
..Default::default()
})
.await
.unwrap();
info!("sending fsk stuffs");
match fsk.tx(b"hiiiii hello :3 :3 :3 this is a looooooooooooooooong text! very long :> and cute! :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 ummmm urghhh awwwooooooo woof wooooof woof").await {
Ok(_) => info!("yay tx done :3"),
Err(e) => error!("tx error: {:?}", e),
}
}

8
examples/stm32wle5jc/src/bin/lora_rx.rs
View File

@@ -38,7 +38,7 @@ async fn main(_spawner: Spawner) {
lora.configure(&LoraConfig {
frequency: 868_100_000,
sf: SpreadingFactor::SF9,
bw: Bandwidth::Bw7_8kHz,
bw: Bandwidth::Bw20_83kHz,
pa: PaSelection::HighPower,
power_dbm: 22,
..Default::default()
@@ -46,11 +46,11 @@ async fn main(_spawner: Spawner) {
.await
.unwrap();
info!("waiting for packet...");
info!("waiting for lora stuffs...");
let mut buf = [0u8; 255];
match lora.rx(&mut buf, 5_000).await {
Ok(len) => info!("rx {} bytes: {:x}", len, &buf[..len]),
Err(RadioError::Timeout) => warn!("no packet received (timeout)"),
Ok(len) => info!("yay :3 got {} bytes: {:x}", len, &buf[..len]),
Err(RadioError::Timeout) => warn!("nobody is talking to me :<"),
Err(e) => error!("rx error: {:?}", e),
}

13
examples/stm32wle5jc/src/bin/lora_tx.rs
View File

@@ -9,7 +9,6 @@ use embassy_stm32::{
rcc::{MSIRange, Sysclk, mux},
spi::Spi,
};
use embassy_time::{Duration, Timer};
use stm32wl_subghz::{
Configure, PaSelection, Radio, SubGhzSpiDevice, Transmit,
modulations::lora::{Bandwidth, LoraConfig, LoraRadio, SpreadingFactor},
@@ -38,7 +37,7 @@ async fn main(_spawner: Spawner) {
lora.configure(&LoraConfig {
frequency: 868_100_000,
sf: SpreadingFactor::SF9,
bw: Bandwidth::Bw7_8kHz,
bw: Bandwidth::Bw20_83kHz,
pa: PaSelection::HighPower,
power_dbm: 22,
..Default::default()
@@ -46,13 +45,9 @@ async fn main(_spawner: Spawner) {
.await
.unwrap();
info!("sending stuffs");
match lora.tx(b"hiiiiiII!").await {
Ok(_) => info!("yay :3"),
info!("sending lora stuffs");
match lora.tx(b"hiiiii hello :3 :3 :3 this is a looooooooooooooooong text! very long :> and cute! :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 ummmm urghhh awwwooooooo woof wooooof woof").await {
Ok(_) => info!("yay tx done :3"),
Err(e) => error!("tx error: {:?}", e),
}
loop {
Timer::after(Duration::from_secs(1)).await;
}
}

55
examples/stm32wle5jc/src/bin/msk_rx.rs Normal file
View File

@@ -0,0 +1,55 @@
#![no_std]
#![no_main]
use defmt::{error, info, warn};
use embassy_executor::Spawner;
use embassy_stm32::{
Config,
gpio::{Level, Output, Speed},
rcc::{MSIRange, Sysclk, mux},
spi::Spi,
};
use stm32wl_subghz::{
Configure, PaSelection, Radio, RadioError, Receive, SubGhzSpiDevice,
modulations::msk::{Bitrate, MskConfig, MskRadio, PulseShape},
};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let mut config = Config::default();
{
config.rcc.msi = Some(MSIRange::RANGE48M);
config.rcc.sys = Sysclk::MSI;
config.rcc.mux.rngsel = mux::Rngsel::MSI;
config.enable_debug_during_sleep = true;
}
let p = embassy_stm32::init(config);
let spi = SubGhzSpiDevice(Spi::new_subghz(p.SUBGHZSPI, p.DMA1_CH1, p.DMA1_CH2));
let rf_tx = Output::new(p.PC4, Level::Low, Speed::High);
let rf_rx = Output::new(p.PC5, Level::Low, Speed::High);
let rf_en = Output::new(p.PC3, Level::Low, Speed::High);
let mut radio = Radio::new(spi, rf_tx, rf_rx, rf_en);
radio.init().await.unwrap();
let mut msk = MskRadio::new(&mut radio);
msk.configure(&MskConfig {
frequency: 868_100_000,
bitrate: Bitrate::Custom(600),
pulse_shape: PulseShape::GaussianBt05,
pa: PaSelection::HighPower,
power_dbm: 22,
..Default::default()
})
.await
.unwrap();
info!("waiting for msk stuffs...");
let mut buf = [0u8; 255];
match msk.rx(&mut buf, 5_000).await {
Ok(len) => info!("yay :3 got {} bytes: {:x}", len, &buf[..len]),
Err(RadioError::Timeout) => warn!("nobody is talking to me :<"),
Err(e) => error!("rx error: {:?}", e),
}
}

53
examples/stm32wle5jc/src/bin/msk_tx.rs Normal file
View File

@@ -0,0 +1,53 @@
#![no_std]
#![no_main]
use defmt::{error, info};
use embassy_executor::Spawner;
use embassy_stm32::{
Config,
gpio::{Level, Output, Speed},
rcc::{MSIRange, Sysclk, mux},
spi::Spi,
};
use stm32wl_subghz::{
Configure, PaSelection, Radio, SubGhzSpiDevice, Transmit,
modulations::msk::{Bitrate, MskConfig, MskRadio, PulseShape},
};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let mut config = Config::default();
{
config.rcc.msi = Some(MSIRange::RANGE48M);
config.rcc.sys = Sysclk::MSI;
config.rcc.mux.rngsel = mux::Rngsel::MSI;
config.enable_debug_during_sleep = true;
}
let p = embassy_stm32::init(config);
let spi = SubGhzSpiDevice(Spi::new_subghz(p.SUBGHZSPI, p.DMA1_CH1, p.DMA1_CH2));
let rf_tx = Output::new(p.PC4, Level::Low, Speed::High);
let rf_rx = Output::new(p.PC5, Level::Low, Speed::High);
let rf_en = Output::new(p.PC3, Level::Low, Speed::High);
let mut radio = Radio::new(spi, rf_tx, rf_rx, rf_en);
radio.init().await.unwrap();
let mut msk = MskRadio::new(&mut radio);
msk.configure(&MskConfig {
frequency: 868_100_000,
bitrate: Bitrate::Custom(600),
pulse_shape: PulseShape::GaussianBt05,
pa: PaSelection::HighPower,
power_dbm: 22,
..Default::default()
})
.await
.unwrap();
info!("sending msk stuffs");
match msk.tx(b"hiiiii hello :3 :3 :3 this is a looooooooooooooooong text! very long :> and cute! :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 :3 ummmm urghhh awwwooooooo woof wooooof woof").await {
Ok(_) => info!("yay tx done :3"),
Err(e) => error!("tx error: {:?}", e),
}
}

13
src/lib.rs
View File

@@ -1,13 +1,22 @@
#![no_std]
#![cfg_attr(feature = "hal", no_std)]
#![allow(async_fn_in_trait)]
pub mod error;
pub mod modulations;
#[cfg(feature = "hal")]
pub mod error;
#[cfg(feature = "hal")]
pub mod radio;
#[cfg(feature = "hal")]
pub mod spi;
#[cfg(feature = "hal")]
pub mod traits;
#[cfg(feature = "hal")]
pub use error::RadioError;
#[cfg(feature = "hal")]
pub use radio::{PaSelection, Radio};
#[cfg(feature = "hal")]
pub use spi::SubGhzSpiDevice;
#[cfg(feature = "hal")]
pub use traits::{Configure, Receive, Transmit};

360
src/modulations/bpsk.rs
View File

@@ -1,16 +1,24 @@
#[cfg(feature = "hal")]
use defmt::debug;
#[cfg(feature = "hal")]
use embedded_hal::digital::OutputPin;
#[cfg(feature = "hal")]
use embedded_hal_async::spi::SpiDevice;
#[cfg(feature = "hal")]
use crate::{
RadioError,
radio::{PaSelection, PacketType, Radio, RampTime, irq},
traits::{Configure, Transmit},
};
#[cfg(not(feature = "hal"))]
use std::vec::Vec;
/// BPSK bitrate
/// Formula: register = (32 * 32_000_000) / bps
#[derive(Clone, Copy, defmt::Format)]
#[derive(Clone, Copy)]
#[cfg_attr(feature = "hal", derive(defmt::Format))]
pub enum Bitrate {
/// 100 bits per second
Bps100,
@@ -22,7 +30,7 @@ pub enum Bitrate {
impl Bitrate {
/// Get the 3-byte register value for this bitrate
fn to_bytes(self) -> [u8; 3] {
pub fn to_bytes(self) -> [u8; 3] {
let val = match self {
Bitrate::Bps100 => 0x9C4000,
Bitrate::Bps600 => 0x1A0AAA,
@@ -32,6 +40,337 @@ impl Bitrate {
}
}
#[derive(Clone, Copy)]
#[cfg_attr(feature = "hal", derive(defmt::Format))]
pub enum CrcType {
None,
/// Using a common 0x07 polynomial
Crc8,
/// CRC-16 CCITT using 0x1021 polynomial
Crc16,
}
impl CrcType {
pub fn compute(self, data: &[u8]) -> (u16, usize) {
match self {
CrcType::None => (0, 0),
CrcType::Crc8 => {
let mut crc: u8 = 0x00;
for &byte in data {
crc ^= byte;
for _ in 0..8 {
if crc & 0x80 != 0 {
crc = (crc << 1) ^ 0x07;
} else {
crc <<= 1;
}
}
}
(crc as u16, 1)
}
CrcType::Crc16 => {
let mut crc: u16 = 0xFFFF;
for &byte in data {
crc ^= (byte as u16) << 8;
for _ in 0..8 {
if crc & 0x8000 != 0 {
crc = (crc << 1) ^ 0x1021;
} else {
crc <<= 1;
}
}
}
(crc, 2)
}
}
}
pub fn write(self, crc: u16, buf: &mut [u8]) {
match self {
CrcType::None => {}
CrcType::Crc8 => {
buf[0] = crc as u8;
}
CrcType::Crc16 => {
buf[0] = (crc >> 8) as u8;
buf[1] = crc as u8;
}
}
}
}
#[derive(Clone, Copy)]
#[cfg_attr(feature = "hal", derive(defmt::Format))]
pub enum Whitening {
None,
Ccitt,
}
impl Whitening {
pub fn apply(self, seed: u16, data: &mut [u8]) {
match self {
Whitening::None => return,
Whitening::Ccitt => {}
}
// Calculate CCITT whitening using x^9 + x^4 + 1 polynomial and LFSR
let mut lfsr: u16 = seed & 0x1FF;
for byte in data.iter_mut() {
let mut mask = 0u8;
for bit in 0..8 {
let feedback = ((lfsr >> 8) ^ (lfsr >> 3)) & 1;
lfsr = ((lfsr << 1) | feedback) & 0x1FF;
mask |= (feedback as u8) << (7 - bit);
}
*byte ^= mask;
}
}
}
#[cfg(not(feature = "hal"))]
pub struct DecodeResult {
/// On which bit the sync word was found
pub bit_offset: usize,
/// Signal was phase-inverted
pub inverted: bool,
/// Decoded payload
pub payload: Vec<u8>,
/// CRC matches
pub crc_valid: bool,
}
#[derive(Clone, Copy)]
#[cfg_attr(feature = "hal", derive(defmt::Format))]
pub enum BpskPacket {
/// No framing, just send raw data
Raw,
/// Use a configurable framing
Framing {
/// Length of the preamble (0xAA) in bytes
preamble_len: usize,
/// Synchronization word (max 32 bytes)
sync_word: [u8; 32],
/// Sync word length
sync_word_len: usize,
/// CRC size (0, 1 or 2 bytes)
crc_type: CrcType,
/// Whitening algorithm
whitening: Whitening,
/// Whitening LFSR seed (9-bit, 0x000..0x1FF)
whitening_seed: u16,
},
}
impl BpskPacket {
pub fn default() -> Self {
Self::Framing {
preamble_len: 32,
// Baker-13 code (2 bytes)
sync_word: [
0x1F, 0x35, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00,
],
sync_word_len: 2,
crc_type: CrcType::Crc16,
whitening: Whitening::Ccitt,
whitening_seed: 0x1FF,
}
}
#[cfg(feature = "hal")]
pub fn to_bytes(self, payload: &[u8], buf: &mut [u8]) -> Result<u8, RadioError> {
match self {
BpskPacket::Raw => {
// Simple copy operation, no modifications made
buf[..payload.len()].copy_from_slice(payload);
payload
.len()
.try_into()
.map_err(|_| RadioError::PayloadTooLarge)
}
BpskPacket::Framing {
preamble_len,
sync_word,
sync_word_len,
crc_type,
whitening,
whitening_seed,
} => {
let len_field_size = 1;
let crc_size = match crc_type {
CrcType::None => 0,
CrcType::Crc8 => 1,
CrcType::Crc16 => 2,
};
// Validate packet length
let total =
preamble_len + sync_word_len + len_field_size + payload.len() + crc_size;
if total > buf.len() {
return Err(RadioError::PayloadTooLarge);
}
// Keeps track of the current position in the buffer
let mut pos = 0;
// Write preamble which consists of 0xAA symbols
buf[pos..pos + preamble_len].fill(0xAA);
pos += preamble_len;
// Write sync word
buf[pos..pos + sync_word_len].copy_from_slice(&sync_word[..sync_word_len]);
pos += sync_word_len;
// Actual payload starts here
let data_start = pos;
// Write length info
let payload_len: u8 = payload
.len()
.try_into()
.map_err(|_| RadioError::PayloadTooLarge)?;
buf[pos] = payload_len;
pos += 1;
// Copy the original payload itself
buf[pos..pos + payload.len()].copy_from_slice(payload);
pos += payload.len();
// Compute CRC before the whitening
let (crc, crc_len) = crc_type.compute(&buf[data_start..pos]);
crc_type.write(crc, &mut buf[pos..]);
pos += crc_len;
// Apply whitening
whitening.apply(whitening_seed, &mut buf[data_start..pos]);
// Additional validation - if buffer position can't fit in u8, it's invalid
pos.try_into().map_err(|_| RadioError::PayloadTooLarge)
}
}
}
#[cfg(not(feature = "hal"))]
pub fn decode(&self, data: &[u8]) -> Vec<DecodeResult> {
match self {
// Can't do much with Raw packets so just return the same data and accept as valid
BpskPacket::Raw => vec![DecodeResult {
bit_offset: 0,
inverted: false,
payload: data.to_vec(),
crc_valid: true,
}],
BpskPacket::Framing {
preamble_len: _,
sync_word,
sync_word_len,
crc_type,
whitening,
whitening_seed,
} => {
let sync_word = &sync_word[..*sync_word_len];
let sync_bits = sync_word_len * 8;
let total_bits = data.len() * 8;
let mut results = Vec::new();
let crc_len = match crc_type {
CrcType::None => 0,
CrcType::Crc8 => 1,
CrcType::Crc16 => 2,
};
// Go through every bit, giving space to the sync word length
for i in 0..total_bits.saturating_sub(sync_bits) {
let mut matching: usize = 0;
for j in 0..sync_bits {
// Compare the sync word bit-by-bit against the data stream
let data_bit = (data[(i + j) / 8] >> (7 - ((i + j) % 8))) & 1;
let sync_bit = (sync_word[j / 8] >> (7 - (j % 8))) & 1;
if data_bit == sync_bit {
matching += 1;
}
}
// Allow up to 2 bit errors, if <= 2 bits match or unmatch, it's an accepted
// normal or phase-inverted data
let inverted = if sync_bits - matching <= 2 {
false
} else if matching <= 2 {
true
} else {
continue;
};
// Extract bytes that happen after the sync word is found at any bit offset
let bit_start = i + sync_bits;
let remaining_bytes = (total_bits - bit_start) / 8;
if remaining_bytes == 0 {
continue;
}
// Reassemble bytes from arbitrary bit positions after sync word is found at offset `i`
let mut raw = vec![0u8; remaining_bytes];
for b in 0..remaining_bytes {
let mut byte = 0u8;
for bit in 0..8 {
let idx = bit_start + b * 8 + bit;
let mut val = (data[idx / 8] >> (7 - (idx % 8))) & 1;
// Handle the 180 degree phase ambiguity
if inverted {
val ^= 1;
}
byte |= val << (7 - bit);
}
raw[b] = byte;
}
// De-whiten by applying the same whitening operation again (it's reversible)
whitening.apply(*whitening_seed, &mut raw);
// Extract payload length
let (payload_start, payload_len) = (1, raw[0] as usize);
if payload_len == 0 {
continue;
}
if payload_start + payload_len + crc_len > raw.len() {
continue;
}
// Verify CRC over len field and payload
let crc_data = &raw[..payload_start + payload_len];
let (crc_computed, _) = crc_type.compute(crc_data);
let crc_valid = match crc_type {
CrcType::None => true,
CrcType::Crc8 => raw[payload_start + payload_len] == crc_computed as u8,
CrcType::Crc16 => {
// Assemble u16 from two bytes
let received = ((raw[payload_start + payload_len] as u16) << 8)
| raw[payload_start + payload_len + 1] as u16;
received == crc_computed
}
};
results.push(DecodeResult {
bit_offset: i,
inverted,
payload: raw[payload_start..payload_start + payload_len].to_vec(),
crc_valid,
});
}
results
}
}
}
}
#[cfg(feature = "hal")]
#[derive(Clone, Copy, defmt::Format)]
pub struct BpskConfig {
pub frequency: u32,
@@ -39,8 +378,10 @@ pub struct BpskConfig {
pub pa: PaSelection,
pub power_dbm: i8,
pub ramp: RampTime,
pub packet: BpskPacket,
}
#[cfg(feature = "hal")]
impl Default for BpskConfig {
fn default() -> Self {
Self {
@@ -49,17 +390,20 @@ impl Default for BpskConfig {
pa: PaSelection::LowPower,
power_dbm: 14,
ramp: RampTime::Us40,
packet: BpskPacket::default(),
}
}
}
/// BPSK modulation - borrows a Radio, implements Configure + Transmit
#[cfg(feature = "hal")]
pub struct BpskRadio<'a, SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> {
radio: &'a mut Radio<SPI, TX, RX, EN>,
payload_len: u8,
config: BpskConfig,
}
#[cfg(feature = "hal")]
impl<'a, SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin>
BpskRadio<'a, SPI, TX, RX, EN>
{
@@ -87,6 +431,7 @@ impl<'a, SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin>
}
}
#[cfg(feature = "hal")]
impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Configure
for BpskRadio<'_, SPI, TX, RX, EN>
{
@@ -119,20 +464,21 @@ impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Configure
}
}
#[cfg(feature = "hal")]
impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Transmit
for BpskRadio<'_, SPI, TX, RX, EN>
{
async fn tx(&mut self, data: &[u8]) -> Result<(), RadioError> {
if data.len() > 255 {
return Err(RadioError::PayloadTooLarge);
}
let mut buf = [0u8; 255];
// Convert buffer to packet with chosen framing
let len = self.config.packet.to_bytes(data, &mut buf)?;
// Write payload to radio buffer
self.radio.set_buffer_base(0x00, 0x00).await?;
self.radio.write_buffer(0x00, data).await?;
self.radio.write_buffer(0x00, &buf[..len as usize]).await?;
// Update packet params with actual payload length
self.update_payload_len(data.len() as u8).await?;
self.update_payload_len(len).await?;
// Clear any stale IRQ flags before starting TX
self.radio.clear_irq(irq::ALL).await?;

380
src/modulations/fsk.rs Normal file
View File

@@ -0,0 +1,380 @@
use defmt::{debug, trace};
use embedded_hal::digital::OutputPin;
use embedded_hal_async::spi::SpiDevice;
use crate::{
RadioError,
radio::{PaSelection, PacketType, Radio, RampTime, RxGain, irq},
traits::{Configure, Receive, Transmit},
};
/// (G)FSK bitrate
/// Formula: register = 32 * 32 MHz / bitrate
#[derive(Clone, Copy, defmt::Format)]
pub enum Bitrate {
/// Arbitrary bitrate in bits per second
Custom(u32),
}
impl Bitrate {
/// Get the 3-byte BR register value (FSK formula: 32 * fxosc / bitrate)
pub fn to_bytes(self) -> [u8; 3] {
let val = (32u64 * 32_000_000) / self.bps() as u64;
[(val >> 16) as u8, (val >> 8) as u8, val as u8]
}
/// Get the raw bitrate in bps
pub fn bps(self) -> u32 {
match self {
Bitrate::Custom(bps) => bps,
}
}
}
/// Gaussian pulse shape filter
#[derive(Clone, Copy, defmt::Format)]
#[repr(u8)]
pub enum PulseShape {
/// No filter applied
None = 0x00,
/// Gaussian filter BT 0.3
GaussianBt03 = 0x08,
/// Gaussian filter BT 0.5
GaussianBt05 = 0x09,
/// Gaussian filter BT 0.7
GaussianBt07 = 0x0A,
/// Gaussian filter BT 1.0
GaussianBt10 = 0x0B,
}
/// FSK receiver bandwidth
#[derive(Clone, Copy, defmt::Format)]
#[repr(u8)]
pub enum Bandwidth {
Bw4_8kHz = 0x1F,
Bw5_8kHz = 0x17,
Bw7_3kHz = 0x0F,
Bw9_7kHz = 0x1E,
Bw11_7kHz = 0x16,
Bw14_6kHz = 0x0E,
Bw19_5kHz = 0x1D,
Bw23_4kHz = 0x15,
Bw29_3kHz = 0x0D,
Bw39kHz = 0x1C,
Bw46_9kHz = 0x14,
Bw58_6kHz = 0x0C,
Bw78_2kHz = 0x1B,
Bw93_8kHz = 0x13,
Bw117_3kHz = 0x0B,
Bw156_2kHz = 0x1A,
Bw187_2kHz = 0x12,
Bw234_3kHz = 0x0A,
Bw312kHz = 0x19,
Bw373_6kHz = 0x11,
Bw467kHz = 0x09,
}
/// CRC type for FSK packet params
#[derive(Clone, Copy, defmt::Format)]
#[repr(u8)]
pub enum CrcType {
Off = 0x01,
/// 1-byte CRC
Crc1Byte = 0x00,
/// 2-byte CRC
Crc2Byte = 0x02,
/// 1-byte CRC inverted
Crc1ByteInv = 0x04,
/// 2-byte CRC inverted
Crc2ByteInv = 0x06,
}
/// Preamble detection length
#[derive(Clone, Copy, defmt::Format)]
#[repr(u8)]
pub enum PreambleDetLength {
/// Preamble detection disabled
Off = 0x00,
/// 8-bit preamble detection
Bits8 = 0x04,
/// 16-bit preamble detection
Bits16 = 0x05,
/// 24-bit preamble detection
Bits24 = 0x06,
/// 32-bit preamble detection
Bits32 = 0x07,
}
/// Address comparison/filtering mode
#[derive(Clone, Copy, defmt::Format)]
#[repr(u8)]
pub enum AddrComp {
/// Address filtering disabled
Off = 0x00,
/// Filter on node address
Node = 0x01,
/// Filter on node and broadcast addresses
NodeBroadcast = 0x02,
}
/// Packet length type
#[derive(Clone, Copy, defmt::Format)]
#[repr(u8)]
pub enum PacketLengthType {
/// Fixed payload length, no header
Fixed = 0x00,
/// Variable payload length, header added to packet
Variable = 0x01,
}
/// Frequency deviation
/// Formula: register = deviation_hz * 2^25 / 32 MHz
#[derive(Clone, Copy, defmt::Format)]
pub enum FreqDev {
/// Deviation in Hz
Hz(u32),
}
impl FreqDev {
/// Get the 3-byte Fdev register value
pub fn to_bytes(self) -> [u8; 3] {
let FreqDev::Hz(hz) = self;
let val = ((hz as u64) * (1 << 25)) / 32_000_000;
[(val >> 16) as u8, (val >> 8) as u8, val as u8]
}
}
#[derive(Clone, Copy, defmt::Format)]
pub struct FskConfig {
pub frequency: u32,
pub bitrate: Bitrate,
pub pulse_shape: PulseShape,
pub bandwidth: Bandwidth,
pub fdev: FreqDev,
pub preamble_len: u16,
pub preamble_det: PreambleDetLength,
/// Sync word bytes (1-8) written to SUBGHZ_GSYNCR (0x06C0)
pub sync_word: [u8; 8],
pub addr_comp: AddrComp,
pub packet_type: PacketLengthType,
pub crc: CrcType,
pub whitening: bool,
pub rx_gain: RxGain,
pub pa: PaSelection,
pub power_dbm: i8,
pub ramp: RampTime,
}
impl Default for FskConfig {
fn default() -> Self {
Self {
frequency: 868_100_000,
bitrate: Bitrate::Custom(9600),
pulse_shape: PulseShape::GaussianBt05,
bandwidth: Bw46_9kHz,
fdev: FreqDev::Hz(25_000),
preamble_len: 32,
preamble_det: PreambleDetLength::Bits8,
// default values taken from RF0461 reference manual
sync_word: [0x97, 0x23, 0x52, 0x25, 0x56, 0x53, 0x65, 0x64],
addr_comp: AddrComp::Off,
packet_type: PacketLengthType::Variable,
crc: CrcType::Crc2Byte,
whitening: true,
rx_gain: RxGain::Boosted,
pa: PaSelection::LowPower,
power_dbm: 14,
ramp: RampTime::Us40,
}
}
}
// Import for default
use Bandwidth::Bw46_9kHz;
/// (G)FSK modulation - borrows a Radio, implements Configure + Transmit + Receive
pub struct FskRadio<'a, SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> {
radio: &'a mut Radio<SPI, TX, RX, EN>,
payload_len: u8,
config: FskConfig,
}
impl<'a, SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin>
FskRadio<'a, SPI, TX, RX, EN>
{
pub fn new(radio: &'a mut Radio<SPI, TX, RX, EN>) -> Self {
Self {
radio,
payload_len: 0,
config: FskConfig::default(),
}
}
/// Re-send SetPacketParams with updated payload length
async fn update_payload_len(&mut self, len: u8) -> Result<(), RadioError> {
debug!("Updating payload length to {}", len);
if len == self.payload_len {
return Ok(());
}
self.payload_len = len;
self.send_packet_params(len).await
}
/// Send FSK SetPacketParams
async fn send_packet_params(&mut self, payload_len: u8) -> Result<(), RadioError> {
let cfg = &self.config;
self.radio
.set_packet_params(&[
(cfg.preamble_len >> 8) as u8,
cfg.preamble_len as u8,
cfg.preamble_det as u8,
cfg.sync_word.len() as u8 * 8, // SyncWordLen in bits
cfg.addr_comp as u8,
cfg.packet_type as u8,
payload_len,
cfg.crc as u8,
if cfg.whitening { 0x01 } else { 0x00 },
])
.await
}
}
impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Configure
for FskRadio<'_, SPI, TX, RX, EN>
{
type Config = FskConfig;
async fn configure(&mut self, config: &Self::Config) -> Result<(), RadioError> {
self.config = *config;
self.radio.set_packet_type(PacketType::Fsk).await?;
// Write sync word to SUBGHZ_GSYNCR (0x06C0)
self.radio.write_register(0x06C0, &config.sync_word).await?;
// Set FSK packet params
self.send_packet_params(0).await?;
// RF frequency
self.radio.set_rf_frequency(config.frequency).await?;
// Modulation params
let br = config.bitrate.to_bytes();
let fdev = config.fdev.to_bytes();
self.radio
.set_modulation_params(&[
br[0],
br[1],
br[2],
config.pulse_shape as u8,
config.bandwidth as u8,
fdev[0],
fdev[1],
fdev[2],
])
.await?;
// PA config + TX power
self.radio
.set_output_power(config.pa, config.power_dbm, config.ramp)
.await?;
Ok(())
}
}
impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Transmit
for FskRadio<'_, SPI, TX, RX, EN>
{
async fn tx(&mut self, data: &[u8]) -> Result<(), RadioError> {
if data.len() > 255 {
return Err(RadioError::PayloadTooLarge);
}
// Write payload to radio buffer
self.radio.set_buffer_base(0x00, 0x00).await?;
self.radio.write_buffer(0x00, data).await?;
// Update packet params with actual payload length
self.update_payload_len(data.len() as u8).await?;
// Clear any stale IRQ flags before starting TX
self.radio.clear_irq(irq::ALL).await?;
// Enable IRQs on DIO1
self.radio.set_dio1_irq(irq::TX_DONE | irq::TIMEOUT).await?;
// Start TX
self.radio.set_tx(0).await?;
// Wait until it's done or until timeout
let status = self.radio.poll_irq(irq::TX_DONE | irq::TIMEOUT).await?;
if status & irq::TIMEOUT != 0 {
return Err(RadioError::Timeout);
}
Ok(())
}
}
impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Receive
for FskRadio<'_, SPI, TX, RX, EN>
{
async fn rx(&mut self, buf: &mut [u8], timeout_ms: u32) -> Result<usize, RadioError> {
// Set max payload length we can accept
let max_len = buf.len().min(255) as u8;
self.update_payload_len(max_len).await?;
// Set buffer base addresses
self.radio.set_buffer_base(0x00, 0x00).await?;
// Clear any stale IRQ flags before starting RX
self.radio.clear_irq(irq::ALL).await?;
// Enable RX-related IRQs on DIO1
self.radio
.set_dio1_irq(irq::RX_DONE | irq::TIMEOUT | irq::CRC_ERR | irq::SYNC_WORD_VALID)
.await?;
// Stop RX timer on preamble detection (required for proper RX behavior)
self.radio.set_stop_rx_timer_on_preamble(true).await?;
// Set RX gain
self.radio
.write_register(0x08AC, &[self.config.rx_gain as u8])
.await?;
// Convert ms to 15.625µs steps, 0 = single, 0xFFFFFF = continuous
let timeout_steps = if timeout_ms == 0 {
0
} else {
timeout_ms.saturating_mul(64).min(0xFFFFFF)
};
self.radio.set_rx(timeout_steps).await?;
// Wait for something to happen
let status = self
.radio
.poll_irq(irq::RX_DONE | irq::TIMEOUT | irq::CRC_ERR)
.await?;
// Check what happened
if status & irq::TIMEOUT != 0 {
return Err(RadioError::Timeout);
}
if status & irq::CRC_ERR != 0 {
return Err(RadioError::CrcInvalid);
}
// Read received data from the radio buffer
let (len, offset) = self.radio.get_rx_buffer_status().await?;
let read_len = len.min(buf.len() as u8);
self.radio
.read_buffer(offset, &mut buf[..read_len as usize])
.await?;
trace!("Got data {:x}", &mut buf[..read_len as usize]);
Ok(read_len as usize)
}
}

10
src/modulations/lora.rs
View File

@@ -3,7 +3,7 @@ use embedded_hal::digital::OutputPin;
use embedded_hal_async::spi::SpiDevice;
use crate::error::RadioError;
use crate::radio::{PaSelection, PacketType, Radio, RampTime, irq};
use crate::radio::{PaSelection, PacketType, Radio, RampTime, RxGain, irq};
use crate::traits::{Configure, Receive, Transmit};
#[derive(Clone, Copy, defmt::Format)]
@@ -57,6 +57,7 @@ pub struct LoraConfig {
pub crc_on: bool,
pub iq_inverted: bool,
pub sync_word: u16,
pub rx_gain: RxGain,
pub pa: PaSelection,
pub power_dbm: i8,
pub ramp: RampTime,
@@ -75,6 +76,7 @@ impl Default for LoraConfig {
crc_on: true,
iq_inverted: false,
sync_word: 0x1424, // private LoRa network
rx_gain: RxGain::PowerSaving,
pa: PaSelection::LowPower,
power_dbm: 14,
ramp: RampTime::Us40,
@@ -235,8 +237,10 @@ impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Receive
// Stop RX timer on preamble detection (required for proper RX behavior)
self.radio.set_stop_rx_timer_on_preamble(true).await?;
// Set RX gain (0x94 = normal, 0x96 = boosted)
self.radio.write_register(0x08AC, &[0x94]).await?;
// Set RX gain
self.radio
.write_register(0x08AC, &[self.config.rx_gain as u8])
.await?;
// Convert ms to 15.625µs steps (ms * 64), 0 = single mode, 0xFFFFFF = continuous
let timeout_steps = if timeout_ms == 0 {

5
src/modulations/mod.rs
View File

@@ -1,2 +1,7 @@
pub mod bpsk;
#[cfg(feature = "hal")]
pub mod fsk;
#[cfg(feature = "hal")]
pub mod lora;
#[cfg(feature = "hal")]
pub mod msk;

261
src/modulations/msk.rs Normal file
View File

@@ -0,0 +1,261 @@
use defmt::{debug, trace};
use embedded_hal::digital::OutputPin;
use embedded_hal_async::spi::SpiDevice;
use crate::{
RadioError,
radio::{PaSelection, PacketType, Radio, RampTime, RxGain, irq},
traits::{Configure, Receive, Transmit},
};
// Re-export shared FSK types
pub use super::fsk::{
AddrComp, Bandwidth, Bitrate, CrcType, PacketLengthType, PreambleDetLength, PulseShape,
};
impl Bitrate {
/// Get the 3-byte Fdev register for MSK (Fdev = bitrate / 4)
/// Register = deviation_hz * 2^25 / 32 MHz
fn fdev_bytes(self) -> [u8; 3] {
let deviation_hz = self.bps() / 4;
let val = ((deviation_hz as u64) * (1 << 25)) / 32_000_000;
[(val >> 16) as u8, (val >> 8) as u8, val as u8]
}
}
#[derive(Clone, Copy, defmt::Format)]
pub struct MskConfig {
pub frequency: u32,
pub bitrate: Bitrate,
pub pulse_shape: PulseShape,
/// Bandwidth of the rx side
/// Should be >= 1.5 * bitrate for MSK
/// (Carson's rule: BW = 2 * (Fdev + bitrate/2), with Fdev = bitrate/4)
/// So for 10kbps signal, it should be
/// 2 * (10000/4 + 10000/2) = 15000 Hz
pub bandwidth: Bandwidth,
pub preamble_len: u16,
pub preamble_det: PreambleDetLength,
/// Sync word bytes (1-8) written to SUBGHZ_GSYNCR (0x06C0)
pub sync_word: [u8; 8],
pub addr_comp: AddrComp,
pub packet_type: PacketLengthType,
pub crc: CrcType,
pub whitening: bool,
pub rx_gain: RxGain,
pub pa: PaSelection,
pub power_dbm: i8,
pub ramp: RampTime,
}
impl Default for MskConfig {
fn default() -> Self {
Self {
frequency: 868_100_000,
bitrate: Bitrate::Custom(600),
pulse_shape: PulseShape::GaussianBt05,
bandwidth: Bandwidth::Bw4_8kHz,
preamble_len: 32,
preamble_det: PreambleDetLength::Bits8,
// default values taken from RF0461 reference manual
sync_word: [0x97, 0x23, 0x52, 0x25, 0x56, 0x53, 0x65, 0x64],
addr_comp: AddrComp::Off,
packet_type: PacketLengthType::Variable,
crc: CrcType::Crc2Byte,
whitening: true,
rx_gain: RxGain::Boosted,
pa: PaSelection::LowPower,
power_dbm: 14,
ramp: RampTime::Us40,
}
}
}
/// (G)MSK modulation implemented via FSK with modulation index 0.5
/// Borrows a Radio, implements Configure + Transmit + Receive
pub struct MskRadio<'a, SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> {
radio: &'a mut Radio<SPI, TX, RX, EN>,
payload_len: u8,
config: MskConfig,
}
impl<'a, SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin>
MskRadio<'a, SPI, TX, RX, EN>
{
pub fn new(radio: &'a mut Radio<SPI, TX, RX, EN>) -> Self {
Self {
radio,
payload_len: 0,
config: MskConfig::default(),
}
}
/// Re-send SetPacketParams with updated payload length
async fn update_payload_len(&mut self, len: u8) -> Result<(), RadioError> {
debug!("Updating payload length to {}", len);
if len == self.payload_len {
return Ok(());
}
self.payload_len = len;
self.send_packet_params(len).await
}
/// Send FSK SetPacketParams with the given payload length
async fn send_packet_params(&mut self, payload_len: u8) -> Result<(), RadioError> {
let cfg = &self.config;
self.radio
.set_packet_params(&[
(cfg.preamble_len >> 8) as u8,
cfg.preamble_len as u8,
cfg.preamble_det as u8,
cfg.sync_word.len() as u8 * 8, // SyncWordLen in bits
cfg.addr_comp as u8,
cfg.packet_type as u8,
payload_len,
cfg.crc as u8,
if cfg.whitening { 0x01 } else { 0x00 },
])
.await
}
}
impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Configure
for MskRadio<'_, SPI, TX, RX, EN>
{
type Config = MskConfig;
async fn configure(&mut self, config: &Self::Config) -> Result<(), RadioError> {
self.config = *config;
// Use FSK packet type - MSK is FSK with modulation index 0.5
self.radio.set_packet_type(PacketType::Fsk).await?;
// Write sync word to SUBGHZ_GSYNCR (0x06C0)
self.radio.write_register(0x06C0, &config.sync_word).await?;
// Set FSK packet params
self.send_packet_params(0).await?;
// RF frequency
self.radio.set_rf_frequency(config.frequency).await?;
// Modulation params: FSK format with Fdev = bitrate/4 for MSK
let br = config.bitrate.to_bytes();
let fdev = config.bitrate.fdev_bytes();
self.radio
.set_modulation_params(&[
br[0],
br[1],
br[2],
config.pulse_shape as u8,
config.bandwidth as u8,
fdev[0],
fdev[1],
fdev[2],
])
.await?;
// PA config + TX power
self.radio
.set_output_power(config.pa, config.power_dbm, config.ramp)
.await?;
Ok(())
}
}
impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Transmit
for MskRadio<'_, SPI, TX, RX, EN>
{
async fn tx(&mut self, data: &[u8]) -> Result<(), RadioError> {
if data.len() > 255 {
return Err(RadioError::PayloadTooLarge);
}
// Write payload to radio buffer
self.radio.set_buffer_base(0x00, 0x00).await?;
self.radio.write_buffer(0x00, data).await?;
// Update packet params with actual payload length
self.update_payload_len(data.len() as u8).await?;
// Clear any stale IRQ flags before starting TX
self.radio.clear_irq(irq::ALL).await?;
// Enable IRQs on DIO1
self.radio.set_dio1_irq(irq::TX_DONE | irq::TIMEOUT).await?;
// Start TX
self.radio.set_tx(0).await?;
// Wait until it's done or until timeout
let status = self.radio.poll_irq(irq::TX_DONE | irq::TIMEOUT).await?;
if status & irq::TIMEOUT != 0 {
return Err(RadioError::Timeout);
}
Ok(())
}
}
impl<SPI: SpiDevice, TX: OutputPin, RX: OutputPin, EN: OutputPin> Receive
for MskRadio<'_, SPI, TX, RX, EN>
{
async fn rx(&mut self, buf: &mut [u8], timeout_ms: u32) -> Result<usize, RadioError> {
// Set max payload length we can accept
let max_len = buf.len().min(255) as u8;
self.update_payload_len(max_len).await?;
// Set buffer base addresses
self.radio.set_buffer_base(0x00, 0x00).await?;
// Clear any stale IRQ flags before starting RX
self.radio.clear_irq(irq::ALL).await?;
// Enable RX-related IRQs on DIO1
self.radio
.set_dio1_irq(irq::RX_DONE | irq::TIMEOUT | irq::CRC_ERR | irq::SYNC_WORD_VALID)
.await?;
// Stop RX timer on preamble detection (required for proper RX behavior)
self.radio.set_stop_rx_timer_on_preamble(true).await?;
// Set RX gain
self.radio
.write_register(0x08AC, &[self.config.rx_gain as u8])
.await?;
// Convert ms to 15.625µs steps, 0 = single, 0xFFFFFF = continuous
let timeout_steps = if timeout_ms == 0 {
0
} else {
timeout_ms.saturating_mul(64).min(0xFFFFFF)
};
self.radio.set_rx(timeout_steps).await?;
// Wait for something to happen
let status = self
.radio
.poll_irq(irq::RX_DONE | irq::TIMEOUT | irq::CRC_ERR)
.await?;
// Check what happened
if status & irq::TIMEOUT != 0 {
return Err(RadioError::Timeout);
}
if status & irq::CRC_ERR != 0 {
return Err(RadioError::CrcInvalid);
}
// Read received data from the radio buffer
let (len, offset) = self.radio.get_rx_buffer_status().await?;
let read_len = len.min(buf.len() as u8);
self.radio
.read_buffer(offset, &mut buf[..read_len as usize])
.await?;
trace!("Got data {:x}", &mut buf[..read_len as usize]);
Ok(read_len as usize)
}
}

10
src/radio.rs
View File

@@ -88,6 +88,16 @@ pub enum PaSelection {
HighPower,
}
/// RX gain setting (register 0x08AC)
#[derive(Clone, Copy, defmt::Format)]
#[repr(u8)]
pub enum RxGain {
/// Power saving gain
PowerSaving = 0x94,
/// Boosted gain (better sensitivity)
Boosted = 0x96,
}
/// Standby mode clock source
#[derive(Clone, Copy, defmt::Format)]
#[repr(u8)]