For use with the AnyLeaf pH and RTD sensors in Rust on embedded systems, and single-board computers.
Cargo.toml:
[package]
name = "anyleaf_linux_example"
version = "0.1.0"
authors = ["Anyleaf <anyleaf@anyleaf.org>"]
edition = "2018"
[dependencies]
embedded-hal = "^0.2.3"
linux-embedded-hal = "^0.3.0"
anyleaf = "^0.1.6"main.rs:
use embedded_hal::blocking::delay::DelayMs;
use linux_embedded_hal::{Delay, I2cdev};
use anyleaf::{PhSensor, CalPt, CalSlot, TempSource};
fn main() {
let i2c = I2cdev::new("/dev/i2c-1").unwrap();
let dt = 1.; // Time between measurements, in seconds
let mut ph_sensor = PhSensor::new(i2c, dt);
// 2 or 3 pt calibration both give acceptable results.
// Calibrate with known values. (voltage, pH, temp in °C).
// You can find voltage and temperature with `ph_sensor.read_voltage()` and
// `ph_sensor.read_temp()` respectively.
// For 3 pt calibration, pass a third argument to `calibrate_all`.
ph_sensor.calibrate_all(
CalPt::new(0., 7., 25.), CalPt::new(0.18, 4., 25.), None,
);
// Or, call these with the sensor in the appropriate buffer solution.
// This will automatically use voltage and temperature.
// Voltage and Temp are returned, but calibration occurs
// without using the return values.
// (V, T) = ph_sensor.calibrate(CalSlot::One, 7.);
// ph_sensor.calibrate(CalSlot::Two, 4.);
// Store the calibration parameters somewhere, so they persist
// between program runs.
let mut delay = Delay {};
loop {
let pH = ph_sensor.read(TempSource::OnBoard).unwrap();
println!("pH: {}", pH);
delay.delay_ms(dt as u16 * 1000);
}
}Cargo.toml:
[package]
name = "anyleaf_stm32_example"
version = "0.1.0"
authors = ["Anyleaf <anyleaf@anyleaf.org>"]
edition = "2018"
[dependencies]
cortex-m = "^0.6.2"
cortex-m-rt = "^0.6.12"
stm32f3xx-hal = { version = "^0.4.3", features=["stm32f303xc", "rt"] }
f3 ="0.6.1"
embedded-hal = "^0.2.3"
cortex-m-semihosting = "0.3.5"
panic-semihosting = "0.5.3"
anyleaf = "^0.1.5"
[profile.release]
codegen-units = 1
debug = true
lto = truemain.rs:
//! This program demonstrates how to use the AnyLeaf pH module
//! with an STM32F3 microcontroller. It continuously displays
//! the pH using an output handler, and demonstrates how
//! to calibrate.
#![no_main]
#![no_std]
use cortex_m::{self, iprintln};
use cortex_m_rt::entry;
use cortex_m_semihosting::hprintln;
use stm32f3xx_hal as hal;
use hal::{delay::Delay, i2c::I2c, prelude::*, stm32};
use embedded_hal::blocking::delay::DelayMs;
#[cfg(debug_assertions)]
extern crate panic_semihosting;
use anyleaf::{PhSensor, CalPt, CalSlot, TempSource};
#[entry]
fn main() -> ! {
// Set up i2C.
let mut cp = cortex_m::Peripherals::take().unwrap();
let dp = stm32::Peripherals::take().unwrap();
let stim = &mut cp.ITM.stim[0];
let mut flash = dp.FLASH.constrain();
let mut rcc = dp.RCC.constrain();
let clocks = rcc.cfgr.freeze(&mut flash.acr);
let mut delay = Delay::new(cp.SYST, clocks);
let mut gpiob = dp.GPIOB.split(&mut rcc.ahb); // PB GPIO pins
let scl = gpiob.pb6.into_af4(&mut gpiob.moder, &mut gpiob.afrl);
let sda = gpiob.pb7.into_af4(&mut gpiob.moder, &mut gpiob.afrl);
let i2c = I2c::i2c1(dp.I2C1, (scl, sda), 100.khz(), clocks, &mut rcc.apb1);
let dt = 1.; // Time between measurements, in seconds
let mut ph_sensor = PhSensor::new(i2c, dt);
ph_sensor.calibrate_all(
CalPt::new(0., 7., 25.), CalPt::new(0.17, 4., 25.), Some(CalPt::new(-0.18, 10., 25.))
);
ph_linux
loop {
let pH = ph_sensor.read(TempSource::OffBoard(20.)).unwrap();
hprintln!("pH: {}", pH).unwrap();
delay.delay_ms(dt as u16 * 1000);
}
}