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**This report contains libraries for AVR ATmega 16 & similar micro-controllers. It contains function names same as that used in Arduino IDE io.h is the main library containing all the basic functions for ATmega16 microcontroller

Index:

1]analogWrite() 2]pulseIn() 3]attachinterrupt() 4]softwareInterrupt 5]LCD 6]analogrRead() 7] 8] 9] 10]

analogWrite():

PARAMETERS:

The parameters for this function are the pin and duty cycle.The value of duty cycle ranges between 0 to 255.The pins for this function are PD4 and PD5 on Atmega .For simplicity,pin parameter has only two values.These are 1 and 2.**If 1 is given as parameter for pin,the duty cycle will be given to PD4(OCRA) and if it is 2 the duty cycle will be given to PD5(OCRB).

SYNTAX:

**analogWrite(pin,duty cycle);

pulseIn():

######FUNCTIONS:

  1. unsigned long pulseIn(); This function reads a pulse (either HIGH or LOW) on a pin. For example,if value is HIGH, pulse_In() waits for the pin to go from LOW to HIGH, starts timing, then waits for the pin to go LOW and stops timing. Returns the length of the pulse in microseconds or gives up and returns 0 if no complete pulse was received within the timeout. SYNTAX: unsigned long pulseIn (volatile uint8_t bitno, uint8_t stateMask); PARAMETERS: • pInno: The pin number on which you want to read the pulse. (int) • vAlue: type of pulse to read: either 1(for high) or 0(for low). (int)

unsigned long microsecondsToInches();

•	There are 73.746 microseconds per inch (i.e. sound travels at 1130 feet per second).This gives the distance travelled by the     	 ping, outbound and return, so we divide by 2 to get the distance of the obstacle.
FORMULA:    
    mIcroseconds*0.00669/ 2
SYNTAX:    
    unsigned long microsecondsToInches(unsigned long mIcroseconds1)

unsigned long microsecondsToCentimeters();

•	The speed of sound is 340 m/s or 29 microseconds per centimetre. The ping travels out and back, so to find the distance of the           object we take half of the distance travelled.
FORMULA:
    mIcroseconds*0.17/ 2
SYNTAX:
    unsigned long microsecondsToCentimeters(unsigned long mIcroseconds)

EXAMPLE CODE: #include <avr/io.h> #include <util/delay.h> #include <pulseIn.h> const Pin = PIND0 const PingPin = PINC0 int main() { DDRC=0b11111111; DDRD=0b00000000; while(1) { // establish variables for duration of the ping, and the distance result // in inches and centimeters: unsigned long duration, inches, cm; // The PING is triggered by a HIGH pulse of 2 or more microseconds. // Give a short LOW pulse beforehand to ensure a clean HIGH pulse: // trig 10 PORTC=(1<<pingPin); _delay_us(2); PORTC=(1<<pingPin); _delay_us(5); PORTC=(1<<pingPin);

// Pin is used to read the signal from the PING : a HIGH pulse // whose duration is the time (in microseconds) from the sending of the ping // to the reception of its echo off of an object. //echo11 duration = pulseIn(Pin,1);

// convert the time into a distance

inches = microsecondsToInches(duration); cm = microsecondsToCentimeters(duration); PORTB=0; if(cm<10) { PORTB=0b00000001;
} if(cm>=10||cm<20) { PORTB=0b00000010;
} if(cm>=20||cm<30) { PORTB=0b00000100;
} else if(cm>=30) { PORTB=0b00001000;
} } }

3]attachinterrupt():

FUNCTIONS:

1.void attachInterrupt (): External interrupt enabling function SYNTAX: void attachInterrupt (digitalpintoInterrupt, *ISR (), mode) PARAMETERS: • digitalpintoInterrupt : The external interrupt request enable pin available are INT0, INT1, INT2. It takes an integer value. • 0 for INT0 • 1 for INT1 • 2 for INT2

• *ISR (): This function is called if the external interrupt occurs. • No parameter • Returns nothing

• mode: The mode at which the interrupt is enabled. Predefined constants are used for the different modes:
• RISING=2: interrupt enables on rising edge • FALLING=3: interrupt enables on falling edge • CHANGE=4: interrupt enables on any change of the edge

EXAMPLE CODE: #include<avr/io.h> #include<attachInterrupt.h> #include<avr/interrupt.h> void fun(void) { while (PIND&&(1<<PD2)){ // while PD2(INT0) is HIGH PORTB|=(1<<PB7);} PORTB|=(1<<PB6); // glowing a led
} Int main() { DDRB=0XFF; // setting leds as output DDRD= 0X00; PORTB|=0X00; PORTD|=0XFF;// pull-up the interrupts attachInterrupt (0, *fun, 2); // INT0 is enabled on a RISING edge and fun() is called } while(1) {
}

4]softwareinterrupt LIBRARY:

FUNCTIONS: 1.void softwareInterrupt(): It enables internal interrupt.

SYNTAX: void softwareInterrupt (*Isr ())

PARAMETERS:

  • isr(): ISR is called if internal interrupt is enabled.  No parameter  Returns nothing Ex: #define F_CPU 1000000UL void func(void) { PORTD=0b11111111; _delay_ms(500);
    PORTD=0b00000000; _delay_ms(500); // blinking a led }

int main() { DDRD=0X00; PORTD=0XFF; sei(); softwareInterrupt(*func); while (1) { } }

LCD:

FUNCTIONS:
1.	Lcd8_Init () & Lcd4_Init (): These functions will initialize the 16×2 LCD module connected to the microcontroller
        pins defined by the following constants.
2.	Lcd8_Clear() & Lcd4_Clear() : Calling these functions will clear the 16×2 LCD display screen when interfaced with
        8 bit and 4 bit mode respectively.
3.	Lcd8_SetCursor() & Lcd4_SetCursor() : These function will set the cursor position on the LCD screen by specifying 
        its row and column. By using these functions we can change the position of character and string displayed by the
	following functions.
4.	Lcd8_WriteChar() & Lcd4_WriteChar() : These functions will write a single character to the LCD screen and the cursor
        position will be incremented by one.
5.	Lcd8_WriteString() & Lcd8_WriteString() : These function will write string or text to the LCD screen and the cursor
        positon will be incremented by length of the string plus one.
6.	Lcd8_ShiftLeft() & Lcd4_ShiftLeft() : This function will shift data in the LCD display without changing data in the
        display RAM.
7.	Lcd8_ShiftRight() & Lcd8_ShiftRight() : This function will shift data in the LCD display without changing data in 
        the display RAM.
8.	For Pin change:
	•	Change Lcd4_Port(data) and Lcd8_Port(data) to PORTD = data
	•	Change pinChange(EN,1) to  PORTC |= (1<<PC7)
	•	Change pinChange(EN,0) to PORTC &= ~(1<<PC7)
	•	Change pinChange(RS,1) to PORTB |= (1<<PB6)
	•	Change pinChange(RS,0) to PORTC &= ~(1<<PC6)

EXAMPLE CODE: // Defining pins for LCD #define D4 eS_PORTD4 #define D5 eS_PORTD5 #define D6 eS_PORTD6 #define D7 eS_PORTD7 #define RS eS_PORTC6 #define EN eS_PORTC7 //Including standard libs #include <avr/io.h> #define F_CPU 8000000UL #include <util/delay.h> #include <avr/interrupt.h> #include <stdlib.h> #include "lcd.h" // Defining pins #define trig PB0 //Output pin for sending trigger pulse #define echo 2 //Input pin for receiving distance proportional pulse

int time=0;

void set_interrupt() { GICR |= (1<<INT0); //Enable external interrupts MCUCR |= (1<<ISC00); //Trigger interrupt on logical change MCUCR &= ~(1<<ISC01); sei(); //Enable global interrupts or SREG |= (1<<I) }

void init_timer() { TCCR1B = (1<<CS11); // Initialize timer1 with prescaler of 8 TCNT1 = 0; }

void trigger() { PORTB &= ~(1<<trig); _delay_us(2); PORTB |= (1<<trig); _delay_us(12); PORTB &= ~(1<<trig); _delay_us(2); }

ISR(INT0_vect) { if(TCNT1 == 0) { init_timer(); } else { time = TCNT1; TCNT1 = 0; TCCR1B = 0x00; } }

int main(void) { DDRB |= (1<<trig); //Setting trigger pin as output DDRC |= (0b11100000); //Setting enable and RS pin as output DDRD &= ~(1<<echo); //Setting echo pin as input DDRD |= (0b11110000); //Setting LCD data pins as output set_interrupt(); Lcd4_Init(); int dist = 0; char a[10]; while (1) { trigger(); dist = time/58; itoa(dist, a, 10); if(dist>400) { Lcd4_Set_Cursor(1,1); Lcd4_Write_String("No object found"); } else { Lcd4_Set_Cursor(1,1); Lcd4_Write_String("Distance : "); Lcd4_Write_String(a); } _delay_ms(1000); Lcd4_Clear(); } }

analogread()

this function acts as a comparision between between supply applied to analog pins and to the supply offered at vcc .for multiple adc pins to be used we can use this function for more than one time returining data type of 16 bit .which means the value will be of 1023 at max value.and 0 as the lowest and its value is mapped to voltage value which is supplied at vcc supply to take an example suppose if vcc supply is given of 5v which means that when analog value supplied to pin respective from 0 to 7 .one at time of declaration.5v will be maximum i.e 1023 and if suppose a is applied of 2.5 v which means that return value will be of 512 or 511 .... warining the value ranges from 0 to 1024. ex uint16_t analogRead(uint8_t cHannel) {ADMUX=(1<<REFS0); //Aref=AVcc ADCSRA=(1<<ADEN)|(1<<ADPS2)|(1<<ADPS1);

ADMUX=(1<<REFS0)|(0<<REFS1); ADCSRA|=(1<<ADEN); ADMUX|=cHannel;//chose value from 0 to 7 to chose adc pin accordingly ADCSRA|=(1<<ADEN); ADCSRA|=(1<<ADSC); while(ADCSRA&(1<<ADSC)); return (ADC); cHannel++;

}

int main(void) {int x; int y; DDRB=0b1111111;

while(1)
{x=analogRead(0);
	if (x<514)
	{
		PORTB=0b11100000;
    //TODO:: Please write your application code 
}
y=analogRead(1);
if(y==1023)
{
	PORTB|=1;	
	}
}	

} .. thats it ..

serial library/UART

serial library/UART is used for serial communication in which serial is a class in which it start function ubrr value should be put.which will initialize serail communication at give baud rate. then serial send as the name suggest it transfers data upto 8 bits so preferably a character is send.moving on we have serial.get which is used to receive data.into some variable again preferably of 8 bit. and flush is used to empty data buffer.serial.end is used to end serial communication . FOR EX: #define FOSC 1000000 // Clock Speed #define BAUD 4800 //baud rate #define MYUBRR FOSC/16/BAUD-1 //formula for calculating ubrr rate int main(void) { serial j; //serial type declaration j.start(MYUBRR); //ubrr rate input while(1) { j.send('w'); //data transmit } } similarly j.recieve is used for recieving end.

millis()

this function **returns value of miilisecond occured until the program has started with float data type. .

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