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| sbit IR_Tx at RA3_bit;
sbit DD0_Set at RA2_bit;
sbit DD1_Set at RA1_bit;
sbit DD2_Set at RA0_bit;
sbit start at RB7_bit;
unsigned short j, DD0, DD1, DD2, DD3;
unsigned short pulserate, pulsecount;
unsigned int i;
//-------------- Function to Return mask for common anode 7-seg. display
unsigned short mask(unsigned short num) {
switch (num) {
case 0 : return 0xC0;
case 1 : return 0xF9;
case 2 : return 0xA4;
case 3 : return 0xB0;
case 4 : return 0x99;
case 5 : return 0x92;
case 6 : return 0x82;
case 7 : return 0xF8;
case 8 : return 0x80;
case 9 : return 0x90;
} //case end
}
void delay_debounce(){
Delay_ms(300);
}
void delay_refresh(){
Delay_ms(5);
}
void countpulse(){
IR_Tx = 1;
delay_debounce();
delay_debounce();
TMR0=0;
Delay_ms(15000); // Delay 1 Sec
IR_Tx = 0;
pulsecount = TMR0;
pulserate = pulsecount*4;
}
void display(){
DD0 = pulserate%10;
DD0 = mask(DD0);
DD1 = (pulserate/10)%10;
DD1 = mask(DD1);
DD2 = pulserate/100;
DD2 = mask(DD2);
for (i = 0; i<=180*j; i++) {
DD0_Set = 0;
DD1_Set = 1;
DD2_Set = 1;
PORTB = DD0;
delay_refresh();
DD0_Set = 1;
DD1_Set = 0;
DD2_Set = 1;
PORTB = DD1;
delay_refresh();
DD0_Set = 1;
DD1_Set = 1;
DD2_Set = 0;
PORTB = DD2;
delay_refresh();
}
DD2_Set = 1;
}
void main() {
CMCON = 0x07; // Disable Comparators
TRISA = 0b00110000; // RA4/T0CKI input, RA5 is I/P only
TRISB = 0b10000000; // RB7 input(start), rest output
OPTION_REG = 0b00101000; // Prescaler (1:1), TOCS =1 for countermode(EBPD)
pulserate = 0;
j = 1;
display();
do {
if(!start){//penyongsang
delay_debounce();
countpulse();
j= 3;
display();
}
} while(1); // Infinite loop
}
LCD:
sbit IR_Tx at RA3_bit;
sbit start at RB0_bit;
unsigned short pulserate, pulsecount;
sbit LCD_RS at RB2_bit;
sbit LCD_EN at RB3_bit;
sbit LCD_D4 at RB4_bit;
sbit LCD_D5 at RB5_bit;
sbit LCD_D6 at RB6_bit;
sbit LCD_D7 at RB7_bit;
sbit LCD_RS_Direction at TRISB2_bit;
sbit LCD_EN_Direction at TRISB3_bit;
sbit LCD_D4_Direction at TRISB4_bit;
sbit LCD_D5_Direction at TRISB5_bit;
sbit LCD_D6_Direction at TRISB6_bit;
sbit LCD_D7_Direction at TRISB7_bit;
void delay_debounce(){
Delay_ms(300);
}
void delay_refresh(){
Delay_ms(5);
}
void countpulse(){
IR_Tx = 1;
delay_debounce();
delay_debounce();
TMR0=0; //0 to 1 transition
Delay_ms(15000); // Delay 1 Sec
IR_Tx = 0;
pulsecount = TMR0;
pulserate = pulsecount*4;
}
char message1[] = "Frequency= Hz";
char *freq = "000";
void Display_Freq() {
freq[0] = (pulserate/100)%10+ 48; // Extract hundreds digit
freq[1] = (pulserate/10)%10 + 48; // Extract tens digit
freq[2] = pulserate%10 + 48; // Extract ones digit
Lcd_Out(1, 11, freq);
}
void main() {
CMCON = 0x07; // Disable Comparators
TRISA = 0b00110000; // RA4/T0CKI input, RA5 is I/P(clear) only
TRISB = 0b00000001; // RB0 input(start),rest output,direction
OPTION_REG = 0b00101000; // Prescaler (1:1), TOCS =1 counter mode
pulserate=0;
Display_Freq();
Lcd_Init(); // Initialize LCD
Lcd_Cmd(_LCD_CLEAR); // CLEAR display
Lcd_Cmd(_LCD_CURSOR_OFF); // Cursor off
Lcd_Out(1,1,message1); // Write message1 in 1st row
do {
if(!start){
delay_debounce();
countpulse();
Delay_ms(1000); // Delay 1 Sec
Display_Freq();//TMR0@countpulse@pulsecount@pulserate,value
}
} while(1); // Infinite loop
} |