GY-63_MS5611/libraries/DHT20
2023-07-27 16:35:55 +02:00
..
.github 0.2.2 DHT20 2023-02-10 16:22:51 +01:00
documents 0.1.0 DHT20 2022-01-11 20:48:39 +01:00
examples 0.2.2 DHT20 2023-02-10 16:22:51 +01:00
test 0.2.2 DHT20 2023-02-10 16:22:51 +01:00
.arduino-ci.yml 0.2.0 DHT20 2022-11-01 21:05:41 +01:00
CHANGELOG.md 0.2.3 DHT20 2023-07-27 16:35:55 +02:00
DHT20.cpp 0.2.3 DHT20 2023-07-27 16:35:55 +02:00
DHT20.h 0.2.3 DHT20 2023-07-27 16:35:55 +02:00
keywords.txt 0.2.2 DHT20 2023-02-10 16:22:51 +01:00
library.json 0.2.3 DHT20 2023-07-27 16:35:55 +02:00
library.properties 0.2.3 DHT20 2023-07-27 16:35:55 +02:00
LICENSE 0.2.2 DHT20 2023-02-10 16:22:51 +01:00
README.md 0.2.2 DHT20 2023-02-10 16:22:51 +01:00

Arduino CI Arduino-lint JSON check License: MIT GitHub release

DHT20

Arduino library for I2C DHT20 temperature and humidity sensor.

Description

The DHT20 is a humidity and temperature sensor.

The sensor has a fixed address of 0x38. It is not known if the address can be changed.

The library must be initiated by calling the begin() function, or begin(dataPin, clockPin) for ESP32 and similar platforms.

Thereafter one has to call the read() function to do the actual reading, and call getTemperature() and getHumidity() to get the measured values. Calling these latter again will return the same values until a new read() is done.

The read() call of this sensor is blocking for 80+ milliseconds (datasheet 7.4) so the library also has a asynchronous interface. See below.

Since 0.1.3 and 0.1.4 the performance of read() has been optimized, still blocking but less long for about 45 milliseconds.

0.2.0

In #8 a bug is described that the sensor "freezes". Cause is not well understood.

Two solutions / workarounds are found:

  • call resetSensor() before EVERY read(). This is the preferred solution.
  • use Wire.setClock(200000) 100 K and lower speeds freezes the sensor. With clock set to 200 K and above the sensor seems to work for longer periods. Tested several speeds on UNO, no pull ups, < 10 cm wire.

Note: setting the I2C clock possibly interferes with other devices on the I2C bus, so it is not a solution in the end.

The 0.2.0 version embeds the resetSensor() into requestData() to reset the sensor if needed in both synchronous and asynchronous calls. This keeps the API simple. The reads are 1-2 ms slower than 0.1.4. (< 50 ms). Still far below the 80 ms mentioned in the datasheet.

Tested

Verified to work with Arduino UNO and ESP32 and ESP8266 (see #8) Please let me know if other platforms work (or not).

I2C

Address

The sensor has a fixed address of 0x38. It is not known if the address can be changed.

Connection

Always check datasheet!

Front view

          +--------------+
  VDD ----| 1            |
  SDA ----| 2    DHT20   |
  GND ----| 3            |
  SCL ----| 4            |
          +--------------+

Performance

The datasheet states 400 KHz as the maximum speed. Below the results of a small test that works well up to 800 KHz.

  • Arduino UNO + 10 cm wires + no pull up + DHT20_I2C_speed.ino

Speed in KHz, Time in microseconds.

read()

Speed Time notes
100 44588 default I2C speed
200 43988
400 44040 datasheet maximum
600 43224
800 43988

ASYNC: requestData()

Speed Time notes
100 1676 default I2C speed
200 1384
400 1240 datasheet maximum
600 1188
800 1168

ASYNC: readData()

Speed Time notes
100 832 default I2C speed
200 464
400 284 datasheet maximum
600 212
800 188

The numbers indicate that the conversion takes > 40 milliseconds. Requesting the measurement and fetching the data < 2.5 milliseconds.

Using the asynchronous interface frees up a lot of clock cycles. Going beyond 400 KHz (datasheet max) does not save much extra time, and should only be used if you are in a need for speed.

Interface

#include "DHT20.h"

Constructor

  • DHT20(TwoWire *wire = &Wire) constructor, using a specific Wire (I2C bus).
  • bool begin(uint8_t dataPin, uint8_t clockPin) begin for ESP32 et al, to set I2C bus pins.
  • bool begin() initializer for non ESP32. Returns true if connected.
  • bool isConnected() returns true if the address of the DHT20 can be seen on the I2C bus.
  • uint8_t getAddress() returns the (fixed) address - convenience.

Core

  • int8_t read() read the sensor and store the values internally. Returns the status of the read which should be 0 == DHT20_OK.
  • float getHumidity() returns last Humidity read. Multiple calls will return same value until a new read() is made.
  • float getTemperature() returns last Temperature read. Multiple calls will return same value until a new read() is made.

Offset

  • void setHumOffset(float offset = 0) set an offset to calibrate the sensor (1st order). Default offset is 0.
  • float getHumOffset() return current humidity offset, default 0.
  • void setTempOffset(float offset = 0) set an offset to calibrate the sensor (1st order). Default offset is 0.
  • float getTempOffset() return current temperature offset, default 0.

Asynchronous interface

There are two timings that need to be considered (from datasheet):

  • time between requests = 1000 ms.
  • time between request and data ready = 80 ms.

The async interface allows one to continue processing after a requestData() has been made. Note there should be at least 1000 milliseconds between subsequent requests.

With bool isMeasuring() one can check if a new measurement is ready. Alternative is to delay for up to 80 ms. If so the sensor can be read with readData().

To interpret the read bits to temperature, humidity and status one needs to call convert() as last step.

  • int requestData() signals the sensor to make a new measurement. Note there must be at least 1000 milliseconds between requests!
  • int readData() does the actual reading of the data.
  • int convert() converts the read bits to temperature and humidity.

See the example DHT20_async.ino

Status

  • uint8_t readStatus() forced read of the status only. This function blocks a few milliseconds to optimize communication.
  • bool isCalibrated() idem, wrapper around readStatus()
  • bool isMeasuring() idem, wrapper around readStatus()
  • bool isIdle() idem, wrapper around readStatus()
  • int internalStatus() returns the internal status of the sensor. (for debug).
status bit meaning
7 1 = measurement, 0 = idle
6 - 4 unknown
3 1 = calibrated, 0 = not
2 - 0 unknown

Experimental 0.1.4 resetSensor

Use with care!

  • uint8_t resetSensor() if at startup the sensor does not return a status of 0x18, three registers 0x1B, 0x1C and 0x1E need to be reset. See datasheet 7.4 Sensor Reading Process, point 1. There is no documentation about the meaning of these registers. The code is based upon example code for the AHT20 (from manufacturer).

The call is needed to get the read() working well so it has been embedded into the read calls. (0.2.0)

Timing

  • uint32_t lastRead() last time the sensor is read in milliseconds since start.
  • uint32_t lastRequest() last time a request is made to make a measurement.

Return codes

name value notes
DHT20_OK 00 OK
DHT20_ERROR_CHECKSUM -10 values might be OK if they are like recent previous ones.
DHT20_ERROR_CONNECT -11 check connection
DHT20_MISSING_BYTES -12 check connection
DHT20_ERROR_BYTES_ALL_ZERO -13 check connection
DHT20_ERROR_READ_TIMEOUT -14
DHT20_ERROR_LASTREAD -15 wait 1 second between reads

Future

Must

  • improve documentation.
  • investigate the bug from #8 further (is done in 0.2.1 see issue #8)

Should

Could

  • improve unit tests.
  • investigate
    • sensor calibration (website aosong?)
    • can sensor address be changed?
  • investigate optimizing timing in readStatus()
    • delay(1) ==> microSeconds(???).
  • connected flag?
  • keep in sync DHT12 ?

Wont

  • void setIgnoreChecksum(bool = false) ignore checksum flag speeds up communication a bit
  • bool getIgnoreChecksum() get checksum flag. for completeness.