Interfacing PIC18F4550 with DHT22(AM2302-RHT03) digital humidity and temperature sensor

Interfacing PIC18F4550 microcontroller with DHT22 sensor using CCS PIC C compiler

This topic shows how to interface PIC18F4550 microcontroller with DHT22 sensor with hardware circuit.
Related topic:
The following topic shows PIC18F4550 microcontroller and DHT22 Proteus simulation with some details about this sensor.
PIC18F4550 microcontroller and DHT22(AM2302) sensor circuit + Proteus simulation
Interfacing PIC18F4550 with DHT22(AM2302 - RHT03) sensor circuit:
The following circuit schematic shows complete project circuit.

The circuit is simple, there is the microcontroller PIC18F4550, DHT22 sensor and 1602 LCD to display humidity and temperature results.
PIC18F4550 uses its internal oscillator @ 8MHz and mclr pin function is disabled.
Interfacing PIC18F4550 with DH22(AM2302-RHT03) sensor CCS C code:
The interfacing code is written with CCS PIC C compiler PCWHD version 5.051.
If you want to understand the code please read the DHT22 datasheet.
Variables Time_out and k are used to test reading time to avoid wrong data reception or microcontroller hanging.

// Interfacing PIC18F4550 with DHT22(AM2302 - RHT03) sensor CCS C code
// http://ccspicc.blogspot.com/
// electronnote@gmail.com

//LCD module connections
#define LCD_RS_PIN PIN_D0
#define LCD_RW_PIN PIN_D1
#define LCD_ENABLE_PIN PIN_D2
#define LCD_DATA4 PIN_D3
#define LCD_DATA5 PIN_D4
#define LCD_DATA6 PIN_D5
#define LCD_DATA7 PIN_D6
//End LCD module connections

#include <18F4550.h>
#fuses NOMCLR INTRC_IO
#use delay(clock = 8000000)
#include <lcd.c>
#use fast_io(B)
// Connection pin between PIC18F4550 and DHT22 sensor
#BIT Data_Pin = 0xF81.0                       // Pin mapped to PORTB.0
#BIT Data_Pin_Direction = 0xF93.0             // Pin direction mapped to TRISB.0

char message1[] = "Temp = 00.0 C";
char message2[] = "RH   = 00.0 %";
short Time_out ;
unsigned int8 T_byte1, T_byte2, RH_byte1, RH_byte2, CheckSum ;
unsigned int16 Temp, RH;
void start_signal(){
  Data_Pin_Direction = 0;              // Configure connection pin as output
  Data_Pin = 0;                        // Connection pin output low
  delay_ms(25);
  Data_Pin = 1;                        // Connection pin output high
  delay_us(30);
  Data_Pin_Direction = 1;              // Configure connection pin as input
}
short check_response(){
  delay_us(40);
  if(!Data_Pin){                     // Read and test if connection pin is low
    delay_us(80);
    if(Data_Pin){                    // Read and test if connection pin is high
      delay_us(50);
      return 1;}
    }
}
unsigned int8 Read_Data(){
  unsigned int8 i, k, _data = 0;     // k is used to count 1 bit reading duration
  if(Time_out)
    break;
  for(i = 0; i < 8; i++){
    k = 0;
    while(!Data_Pin){                          // Wait until pin goes high
      k++;
      if (k > 100) {Time_out = 1; break;}
      delay_us(1);}
    delay_us(30);
    if(!Data_Pin)
      bit_clear(_data, (7 - i));               // Clear bit (7 - i)
    else{
      bit_set(_data, (7 - i));                 // Set bit (7 - i)
      while(Data_Pin){                         // Wait until pin goes low
      k++;
      if (k > 100) {Time_out = 1; break;}
      delay_us(1);}
    }
  }
  return _data;
}
void main(){
  setup_oscillator(OSC_8MHZ);                // Set internal oscillator to 8MHz
  setup_adc_ports(NO_ANALOGS);                // Configure AN pins as digital
  lcd_init();                                 // Initialize LCD module
  lcd_putc('\f');                             // LCD clear 
  while(TRUE){
    delay_ms(1000);
    Time_out = 0;
    Start_signal();
    if(check_response()){                    // If there is response from sensor
      RH_byte1 = Read_Data();                 // read RH byte1
      RH_byte2 = Read_Data();                 // read RH byte2
      T_byte1 = Read_Data();                  // read T byte1
      T_byte2 = Read_Data();                  // read T byte2
      Checksum = Read_Data();                 // read checksum
      if(Time_out){                           // If reading takes long time
        lcd_putc('\f');                       // LCD clear
        lcd_gotoxy(5, 1);                     // Go to column 5 row 1
        lcd_putc("Time out!");
      }
      else{
       if(CheckSum == ((RH_Byte1 + RH_Byte2 + T_Byte1 + T_Byte2) & 0xFF)){
        RH = RH_byte1;
        RH = (RH << 8) | RH_byte2;
        Temp = T_byte1;
        Temp = (Temp << 8) | T_byte2;
        if (Temp > 0X8000){
         message1[6] = '-';
         Temp = Temp & 0X7FFF; }
        else
         message1[6] = ' ';
        message1[7]  = (Temp / 100) % 10  + 48;
        message1[8]  = (Temp / 10) % 10  + 48;
        message1[10] = Temp % 10  + 48;
        message2[7]  = (RH / 100) % 10 + 48;
        message2[8]  = (RH / 10) % 10 + 48;
        message2[10] = RH % 10 + 48;
        message1[11] = 223;                   // Degree symbol
        lcd_putc('\f');                       // LCD clear    
        lcd_gotoxy(1, 1);                     // Go to column 1 row 1
        printf(lcd_putc, message1);           // Display message1
        lcd_gotoxy(1, 2);                     // Go to column 1 row 2
        printf(lcd_putc, message2);           // Display message2
       }
        else {
          lcd_putc('\f');                     // LCD clear
          lcd_gotoxy(1, 1);                   // Go to column 1 row 1
          lcd_putc("Checksum Error!");
        }
      }
    }
    else {
      lcd_putc('\f');             // LCD clear
      lcd_gotoxy(3, 1);           // Go to column 3 row 1
      lcd_putc("No response");
      lcd_gotoxy(1, 2);           // Go to column 1 row 2
      lcd_putc("from the sensor");
    }
  }
}

Interfacing PIC18F4550 with DHT22 sensor video:
The following video shows hardware circuit of this project.