This library provides a simple interface to IDT HS3001 and HS3002 temperature/humidity sensors. Although we tested this on the MCCI Catena 4617, there are no dependencies on MCCI hardware; this should work equally well with IDT breakout boards, etc.
Clients interact with IDT HS300x sensors via the following sequence.
-
Initially, the client creates an instance object for the sensor. When creating the object, the client passes a
Wireobject (representing the I2C bus used for communication). Since the address of the HS300x is fixed at 0x44, there is no need to provide the address. -
When the client wants to take a measurement, the client calls either the
cHS300x::getTemperatureHumidity()method (which returns temperature and humidity scaled in engineering units), orcHS300x::getTemperatureHumidityRaw()(which returns temperature and humidity asuint16_tunscaled values). Generally, the former is used if data is to be processed locally on the Arduino, and the latter is used if data is to be transmitted via a LPWAN network. -
If the client needs to overlap measurements with computation, the client first calls
cHS300x::startMeasurement()to start measurement. The result of this call is the number of milliseconds to delay before the measurement is likely to be active.To collect results, the client occasionaly calls
cHS300x::getMeasurementResults()orcHS300x::getMeasurementResultsRaw(). If a measurement is available, it will be returned, and the method returnstrue; otherwise, the method returnsfalse. To save power, the client should delay the appropriate number of milliseconds between calls (as indicated by the result ofcHS300x::startMeasurement()).
Measurements are returned in structures (cHS300x::Measurements or cHS300x::MeasurementsRaw, respectively.) These structures have some utility methods:
cHS300x::Measurments::set(const cHS300x::MeasurementsRaw &mRaw)sets the targetMeasurementto the engineering-units equivalent ofmRaw.cHS300x::Measurments::extract(float &t, float &rh) constsetstto the temperature (in Celsius), andrhto the relative humidity (in percent).cHS300x::MeasurmentsRaw::extract(std::uint16_t &t, std::uint16_t &rh) constsetstandrhto the raw measurement from the device.
Utility methods allow the client to manage the sensor.
cHS300x::end()idles the device, and is typically used prior to sleeping the system.- For convenience, static methods are provided to convert between raw (
uint16_t) data and engineering units.cHS300x::rawToCelsius()andcHS300x::rawRHtoPercent()convert raw data to engineering units.cHS300x::celsiusToRawT()andcHS300x::percentRHtoRaw()convert engineering units to raw data. (This may be useful for precalculating alarms, to save on floating point calculations at run time.) cHS300x::isDebug()returnstrueif this is a debug build,falseotherwise. It's aconstexpr, so using this in anif()statement is equivalent to a#if-- the compiler will optimize away the code if this is not a debug build.
"Raw data", in the case of HS300x sensors, is only 14 bits (for both temperature and humidity). For consistency with other sensors, we arrange them in a 16-bit word as follows.
15 14 13 12 11 10 9 8 7 6 5 4 3 2 |
1 0 |
|---|---|
| data from sensor, justified with MSB at bit 15 | zero |
This matches temperature from the sensor, but humidity is left-shifted two bits relative to values fetched from the sensor.
#include <Catena-HS300x.h>None, beyond the normal Arduino library <Wire.h>. It can be used with Catena-Arduino-Platform, but it doesn't require it.
See hs300x-simple. Hs300x-simple reads and displays the temperature and humidity once a second, using the simple APIs.
All definitions are wrapped in a namespace. Normally, after incluing the header file, you'll want to say:
using namespace McciCatenaHs300x;An instance object must be created for each HS300x sensor to be managed. The constructor must specify:
- The
Wireobject to be used to communicate with the sensor.
A typical initialization will look like this:
using namespace McciCatenaSht3x;
cHS300x myHS300x(Wire);