SHT35 Sensor Project With Arduino

November 23, 2024

SHT35 Sensor Project With Arduino

متن سربرگ خود را وارد کنید

November 23, 2024

SHT35 Sensor Project With Arduino

What's the purpose of this project?

The purpose of this project is to interface the SHT35 temperature and humidity sensor with an Arduino to measure and monitor environmental conditions with high precision. The SHT35 provides accurate readings of temperature and relative humidity, making it ideal for applications such as climate monitoring, indoor air quality control, and agricultural systems. By reading real-time data, users can design systems that dynamically respond to changes in temperature and humidity, enhancing functionality and reliability in various environmental and industrial applications.

What are we going to learn in this tutorial?

In this tutorial, you’ll learn how to:

Connect the SHT35 sensor to Arduino and establish I2C communication.
Utilize an existing library to simplify sensor integration, enhancing your understanding of I2C data handling.
Read accurate temperature and humidity data from the sensor, interpreting it for real-world applications.
Implement sensor-based projects for environmental monitoring and climate control, gaining practical skills for creating responsive systems based on environmental conditions.

This hands-on guide provides valuable insights into sensor integration and real-time environmental data monitoring with Arduino.

What do we need to start this project?

As you probably know, we need some hardware and software to do this project. The titles of these hardware and software are provided to you in the table below and you can prepare/download by clicking on each of them and get ready to start.

Required hardware	Required software
GebraBit SHT35 module	Arduino IDE
Arduino UNO

First as shown in the image below, we connect the GebraBit SHT35 module to the Arduino UNO as follows:

Then download and add the GebraBit SHT35 library to your Arduino IDE.

Required Library
GebraBit SHT35 Arduino Library

If you don’t know how to add GebraBit libraries to Arduino IDE, refer to the tutorial link below.

How to add GebraBit libraries to Arduino

SHT35 library and driver

In addition to the modular design of various sensors and ICs, GebraBit tries to provide variety of structured and hardware-independent libraries in C language for the ease of users in setting up and developing software.

For this purpose, after preparing each GebraBit module, the users can refer to the “tutorial” section of the desired module and download the dedicated library, which contains the “ .h” and “ .c” file (Header and Source) and a sample training program under “GebraBit STM32F303”, “GebraBit ATMEGA32A” or “Arduino” development boards.

All the defined functions and structures in the library are commented in full detail and all the received parameters in the arguments of the functions and their return values, are briefly explained. Since the libraries are hardware independed, the user can easily add the library in any of their favorite compilers and develop it by desired microcontroller and development board.

GebraBit_SHT35.h header file

In this file, based on the datasheet of the sensor or IC, all address registers, the values of each register are defined in the form of “Enumeration”. Also, the casing of the SHT35 sensor and the configurations related to each of the SHT35 sensor internal blocks are defined in the form of a “STRUCT” with the name GebraBit_SHT35. Finally, in the Debug Session environment, all the configurations related to each block can be seen in real time.

USER REGISTER MAP

The registry map or sensor commands are defined in this section:

				
					/************************************************
 *              USER REGISTER MAP               *
 ************************************************/ 
#define SHT35_SOFT_RESET_TIME                         5
#define SHT35_ADDRESS                                0x44
#define SHT35_READOUT_PERIODIC_MEASUREMENT_RESULT   0xE000
#define SHT35_ART                                   0x2B32
#define SHT35_BREAK_STOP                            0x3093
#define SHT35_SOFT_RESET                            0x30A2
#define SHT35_HEATER_ON                             0x306D
#define SHT35_HEATER_OFF                            0x3066
#define SHT35_READOUT_STATUS_REGISTER               0xF32D
#define SHT35_CLEAR_STATUS_REGISTER                 0x3041
/*----------------------------------------------*
 *           USER REGISTER MAP End              *
 *----------------------------------------------*/

SHT35_Ability Enum

The ability to activate or deactivate different parts of the sensor is defined in this enum:

				
					typedef enum Ability
{
	Disable = 0 ,
	Enable
}SHT35_Ability;

SHT35_Single_Shot_Mode Enum

The values of this enum are used to select different sensor measurement modes in Single Shot mode:

				
					1. typedef enum Single_Shot_Mode
 2. {
 3.  SHT35_HIGH_REPEATABILITY_CLOCK_STRETCHING      =  0x2C06 ,
 4.  SHT35_MEDIUM_REPEATABILITY_CLOCK_STRETCHING    =  0x2C0D ,
 5.  SHT35_LOW_REPEATABILITY_CLOCK_STRETCHING       =  0x2C10 ,
 6.  SHT35_HIGH_REPEATABILITY_NO_CLOCK_STRETCHING   =  0x2400 ,
 7.  SHT35_MEDIUM_REPEATABILITY_NO_CLOCK_STRETCHING =  0x240B ,
 8.  SHT35_LOW_REPEATABILITY_NO_CLOCK_STRETCHING    =  0x2416
 9. }SHT35_Single_Shot_Mode;
10.

SHT35_Periodic_Data_Acquisition_Mode Enum

The values of this enum are used to select different sensor data acquisition modes in periodic mode:

				
					1. typedef enum Periodic_Data_Acquisition_Mode
 2. {
 3.  SHT35_HIGH_REPEATABILITY_0P5_MPS_FREQUENCY      =  0x2032 ,
 4.  SHT35_MEDIUM_REPEATABILITY_0P5_MPS_FREQUENCY    =  0x2024 ,
 5.  SHT35_LOW_REPEATABILITY_0P5_MPS_FREQUENCY       =  0x202F ,
 6.  SHT35_HIGH_REPEATABILITY_1_MPS_FREQUENCY   	 =  0x2130 ,
 7.  SHT35_MEDIUM_REPEATABILITY_1_MPS_FREQUENCY 	 =  0x2126 ,
 8.  SHT35_LOW_REPEATABILITY_1_MPS_FREQUENCY    	 =  0x212D ,
 9.  SHT35_HIGH_REPEATABILITY_2_MPS_FREQUENCY        =  0x2236 ,
10.  SHT35_MEDIUM_REPEATABILITY_2_MPS_FREQUENCY      =  0x2220 ,
11.  SHT35_LOW_REPEATABILITY_2_MPS_FREQUENCY         =  0x222B ,
12.  SHT35_HIGH_REPEATABILITY_4_MPS_FREQUENCY   	 =  0x2334 ,
13.  SHT35_MEDIUM_REPEATABILITY_4_MPS_FREQUENCY 	 =  0x2322 ,
14.  SHT35_LOW_REPEATABILITY_4_MPS_FREQUENCY    	 =  0x2329 ,
15.  SHT35_HIGH_REPEATABILITY_10_MPS_FREQUENCY   	 =  0x2737 ,
16.  SHT35_MEDIUM_REPEATABILITY_10_MPS_FREQUENCY 	 =  0x2721 ,
17.  SHT35_LOW_REPEATABILITY_10_MPS_FREQUENCY    	 =  0x272A
18. }SHT35_Periodic_Mode;
19.

SHT35_ Command_Status Enum

To know the status of commands sent to the sensor, the values of this enum are used:

				
					1. typedef enum Command_Status
2. {
3. 	LAST_COMMAND_PROCESSED       = 0 ,
4. 	LAST_COMMAND_NOT_PROCESSED   = 1
5. }SHT35_Command_Status;
6.

SHT35_ Checksum_Status Enum

This enum is used to know the checksum status:

				
					1. typedef enum Checksum_Status
2. {
3. ECKSUM_CORRECT               = 0 ,
4. 	LAST_WRITE_CHECKSUM_FAILED  = 1
5. }SHT35_Checksum_Status;
6.

SHT35_Measurement_Time Enum

This enum is used to choose when to convert data values:

				
					1. typedef enum Measurement_Time
2. {
3.   HIGH_REPEATABILITY_15_mS      =  15 ,
4.   MEDIUM_REPEATABILITY_6_mS     =  6  ,
5.   LOW_REPEATABILITY_4_mS        =  4  ,
6. }SHT35_Measurement_Time;
7.

SHT35_ Heater Enum

Using this enum, the sensor internal heater is turned off or on:

				
					1. typedef enum Heater
2. {
3. 	HEATER_ENABLE  = SHT35_HEATER_ON ,
4. 	HEATER_DISABLE = SHT35_HEATER_OFF
5. }SHT35_Heater;
6.

SHT35_Alert_Pending_Status Enum

Using this enum, the status of sensor notifications and warnings is checked:

				
					1. typedef enum Alert_Pending_Status
2. {
3.   NO_PENDING_ALERT   		  = 0,
4.   AT_LEAST_ONE_PENDING_ALERT   = 1
5. } SHT35_Alert_Pending_Status;
6.

SHT35_CRC_Status Enum

Using this enum, the status of the CRC check is specified:

				
					1. typedef enum CRC_Status
2. {
3. 	CRC_ERROR = 0 ,
4. 	CRC_OK
5. }SHT35_CRC_Status;
6.

SHT35_Reset_Status Enum

By using this enum, the sensor reset status is specified:

				
					1. typedef enum
2. {
3. 	NOT_DETECTED = 0 ,
4. 	DETECTED
5. }SHT35_Reset_Status;
6.

SHT35 struct

All sensor properties, calibration coefficients and sensor data are defined in this “struct” and All the information and configuration implemented on the sensor are stored in this “structure” and you can see the changes in each part of the sensor in the “Debug Session” environment

				
					1. typedef	struct SHT35
 2. {
 3. 	  uint8_t                       	   Register_Cache;
 4. 	  SHT35_Reset				           RESET;
 5. 	  uint16_t							   COMMAND;
 6. 	  SHT35_Single_Shot_Mode               SINGLE_SHOT_MODE;
 7. 	  SHT35_Periodic_Mode                  PERIODIC_MODE;
 8. 	  SHT35_Measurement_Time               MEASUREMENT_TIME;
 9. 	  HTU31D_Ability                       ART;
10. 	  uint16_t							   STATUS_REGISTER;
11. 	  SHT35_Alert_Pending_Status           ALERT_PENDING;
12. 	  SHT35_Heater			               ON_CHIP_HEATER;
13. 	  SHT35_Alert						   HUMIDITY_ALERT;
14. 	  SHT35_Alert						   TEMPERATURE_ALERT;
15. 	  SHT35_Command_Status                 COMMAND_STATUS;
16. 	  SHT35_Checksum_Status 	           CHECKSUM;
17. 	  uint8_t 							   SHT35_CRC;
18. 	  SHT35_CRC_Status			           CRC_CHECK;
19. 	  uint8_t                              ADC_RAW_DATA[ADC_RAW_DATA_BUFFER_SIZE];
20. 	  uint16_t                             RAW_TEMPERATURE;
21. 	  uint16_t							   RAW_HUMIDITY;
22.       float 							   TEMPERATURE;
23. 	  float 							   HUMIDITY;
24. //	  double							   PARTIAL_PRESSURE;
25. //	  double 							   DEW_POINT;
26. }GebraBit_SHT35;
27.

Declaration of functions

At the end of this file, all the functions for reading and writing in SHT35 registers, sensor configuration and receiving data from the sensor are declared:

				
					1. /********************************************************
 2.  *  Declare Read&Write SHT35 Register Values Functions *
 3.  ********************************************************/
 4. extern void GB_SHT35_Write_Command(GebraBit_SHT35 * SHT35 , uint16_t cmd);
 5. /********************************************************
 6.  *       Declare MS5611 Configuration Functions         *
 7.  ********************************************************/
 8. extern void GB_SHT35_Soft_Reset ( GebraBit_SHT35 * SHT35 )  ;
 9. extern void GB_SHT35_CRC_Check( GebraBit_SHT35 * SHT35 , uint16_t value, uint8_t crc) ;
10. extern void GB_SHT35_On_Chip_Heater ( GebraBit_SHT35 * SHT35 , SHT35_Heater heater )   ;
11. extern void GB_SHT35_Read_Serial_Number ( GebraBit_SHT35 * SHT35  )    ;
12. extern void GB_SHT35_Read_Diagnostic ( GebraBit_SHT35 * SHT35  )   ;
13. extern void GB_SHT35_Configuration(GebraBit_SHT35 * SHT35)  ;
14. extern void GB_SHT35_Start_Conversion ( GebraBit_SHT35 * SHT35   )   ;
15. extern void GB_SHT35_Read_Raw_Temperature_Humidity( GebraBit_SHT35 * SHT35 )  ;
16. extern void GB_SHT35_Temperature ( GebraBit_SHT35 * SHT35 )  ;
17. extern void GB_SHT35_Humidity ( GebraBit_SHT35 * SHT35 )   ;
18. extern void GB_SHT35_Dew_Point( GebraBit_SHT35 * SHT35  ) ;
19. extern void GB_SHT35_initialize( GebraBit_SHT35 * SHT35 )  ;
20. extern void GB_SHT35_Get_Data(GebraBit_SHT35 * SHT35);
21.

GebraBit_SHT35.c source file

In this file, which is written in C language, all the functions are commented in full detail, and all the parameters received in the arguments of the functions and their return values are clearly explained so we confine to these explanations and invite users to check this file directly for more information.

Sample program in Arduino

After connecting the module to Arduino and adding the library to the IDE, go to the following path: File > Examples > GebraBit_SHT35 > Temp-Humid

Description of Sample file

Enums and functions required by GebraBit SHT35 module have been added to the structures. In the next part, a variable named SHT35_Module of the GebraBit_SHT35 structure type (this structure is in the GebraBit_SHT35 header and is explained in the GebraBit_SHT35 library description section) is defined for the configuration of the GebraBit SHT35 module:

				
					GebraBit_SHT35 SHT35;

In the next part of the written code, using the GB_SHT35_initialize (&SHT35_Module) and GB_SHT35_Configuration (&SHT35_Module) functions, we set the GebraBit SHT35 module and finally, in the while part of the program, the data is read from the sensor and the humidity and temperature values are continuously received:

				
					void setup() {
    Wire.begin();           // Initialize the I2C bus
    Serial.begin(9600);     // Initialize serial communication for debugging

    GB_SHT35_initialize(&SHT35); // Initialize the SHT35 sensor
    GB_SHT35_Configuration(&SHT35); // Configure the SHT35 sensor
}

void loop() {
    GB_SHT35_Get_Data(&SHT35); // Read data from the sensor

    Serial.print("Temperature: ");
    Serial.print(SHT35.TEMPERATURE);
    Serial.println(" °C");

    Serial.print("Humidity: ");
    Serial.print(SHT35.HUMIDITY);
    Serial.println(" %");

    delay(2000); // Delay between readings
}

The Sample file code text:

				
					#include "GebraBit_SHT35.h"

GebraBit_SHT35 SHT35;

void setup() {
    Wire.begin();           // Initialize the I2C bus
    Serial.begin(9600);     // Initialize serial communication for debugging

    GB_SHT35_initialize(&SHT35); // Initialize the SHT35 sensor
    GB_SHT35_Configuration(&SHT35); // Configure the SHT35 sensor
}

void loop() {
    GB_SHT35_Get_Data(&SHT35); // Read data from the sensor

    Serial.print("Temperature: ");
    Serial.print(SHT35.TEMPERATURE);
    Serial.println(" °C");

    Serial.print("Humidity: ");
    Serial.print(SHT35.HUMIDITY);
    Serial.println(" %");

    delay(2000); // Delay between readings
}

Connect your arduino to computer and select your Arduino Board