7seginpic.cpp

1.  
2. // PIC16F18877 Configuration Bit Settings
3.  
4. // 'C' source line config statements
5.  
6. // CONFIG1
7. #pragma config FEXTOSC = OFF    // External Oscillator mode selection bits (Oscillator not enabled)
8. #pragma config RSTOSC = HFINT1  // Power-up default value for COSC bits (HFINTOSC (1MHz))
9. #pragma config CLKOUTEN = OFF   // Clock Out Enable bit (CLKOUT function is disabled; i/o or oscillator function on OSC2)
10. #pragma config CSWEN = ON       // Clock Switch Enable bit (Writing to NOSC and NDIV is allowed)
11. #pragma config FCMEN = ON       // Fail-Safe Clock Monitor Enable bit (FSCM timer enabled)
12.  
13. // CONFIG2
14. #pragma config MCLRE = ON       // Master Clear Enable bit (MCLR pin is Master Clear function)
15. #pragma config PWRTE = OFF      // Power-up Timer Enable bit (PWRT disabled)
16. #pragma config LPBOREN = OFF    // Low-Power BOR enable bit (ULPBOR disabled)
17. #pragma config BOREN = ON       // Brown-out reset enable bits (Brown-out Reset Enabled, SBOREN bit is ignored)
18. #pragma config BORV = LO        // Brown-out Reset Voltage Selection (Brown-out Reset Voltage (VBOR) set to 1.9V on LF, and 2.45V on F Devices)
19. #pragma config ZCD = OFF        // Zero-cross detect disable (Zero-cross detect circuit is disabled at POR.)
20. #pragma config PPS1WAY = ON     // Peripheral Pin Select one-way control (The PPSLOCK bit can be cleared and set only once in software)
21. #pragma config STVREN = ON      // Stack Overflow/Underflow Reset Enable bit (Stack Overflow or Underflow will cause a reset)
22.  
23. // CONFIG3
24. #pragma config WDTCPS = WDTCPS_31// WDT Period Select bits (Divider ratio 1:65536; software control of WDTPS)
25. #pragma config WDTE = OFF       // WDT operating mode (WDT Disabled, SWDTEN is ignored)
26. #pragma config WDTCWS = WDTCWS_7// WDT Window Select bits (window always open (100%); software control; keyed access not required)
27. #pragma config WDTCCS = SC      // WDT input clock selector (Software Control)
28.  
29. // CONFIG4
30. #pragma config WRT = OFF        // UserNVM self-write protection bits (Write protection off)
31. #pragma config SCANE = available// Scanner Enable bit (Scanner module is available for use)
32. #pragma config LVP = ON         // Low Voltage Programming Enable bit (Low Voltage programming enabled. MCLR/Vpp pin function is MCLR.)
33.  
34. // CONFIG5
35. #pragma config CP = OFF         // UserNVM Program memory code protection bit (Program Memory code protection disabled)
36. #pragma config CPD = OFF        // DataNVM code protection bit (Data EEPROM code protection disabled)
37.  
38. // #pragma config statements should precede project file includes.
39. // Use project enums instead of #define for ON and OFF.
40.  
41.  
42. #include <xc.h>
43. #include <stdint.h>
44. #include <stdio.h>
45.  
46. // LCD module connections
47. #define LCD_RS PORTCbits.RC0  //
48. #define LCD_EN PORTCbits.RC3
49. #define LCD_D4 PORTCbits.RC4
50. #define LCD_D5 PORTCbits.RC5
51. #define LCD_D6 PORTCbits.RC6
52. #define LCD_D7 PORTCbits.RC7
53. #define LCD_DATA_PORT PORTC
54. #define _XTAL_FREQ  4000000
55.  
56. #define DIGIT1  LATE0
57. #define DIGIT2  LATE2
58.  
59. // Define 7-segment display pins
60. #define SEG_A   PORTD0
61. #define SEG_B   PORTD1
62. #define SEG_C   PORTD2
63. #define SEG_D   PORTD3
64. #define SEG_E   PORTD4
65. #define SEG_F   PORTD5
66. #define SEG_G   PORTD6
67. #define SEG_DP  PORTD7
68.  
69. // Function prototypes
70. void LCD_Init();
71. void LCD_Cmd(unsigned char);
72. void LCD_Char(unsigned char);
73. void LCD_String(const char*);
74. void LCD_Clear();
75. void LCD_Send(int RS,unsigned char data);
76. void lcd_set_cursor(char col,char line);
77. void ADC_Init();
78. void Timer0_Init();
79. unsigned int ADC_Read(uint8_t channel);
80. void timer(void);
81.  
82. void init7Segment(void);
83. //void displayDigit(unsigned char display, unsigned char digit);
84. char hexvalue[10]= {0x3F,0x06,0x5B,0x4F,0x66,0x6D,0x7D,0x07,0x7F,0x6F};
85.  void seven_seg_Show(int i);
86.  
87. //O2 Lvl = 3543 %
88. //PH lvl = 3432 %
89.  
90. void main(void) {
91.     TRISB = 0b00000000;
92.     char name[16] = "Aung Win Htut";
93.     char buffer[16];
94.     int i = 32;
95.     Timer0_Init();
96.     ADC_Init();
97.     init7Segment();
98.     LCD_Init();
99.     LCD_Clear();
100.     unsigned int motor_status=0;
101.     __delay_ms(300);
102.    
103.    
104.    
105.    
106.     while (1) {
107.         unsigned int O2_level = ADC_Read(0);
108.         O2_level = O2_level * 100 / 1023;
109.         sprintf(buffer, "O2 lvl = %3u%%", O2_level);
110.         // Display the formatted string on the 2-digit 7-segment display
111.         for(int j=0;j<10;j++)
112.             seven_seg_Show(O2_level);
113.         if(O2_level<=20)
114.         {
115.             //start motor
116.             motor_status=1;
117.             LATBbits.LATB0 = 1;
118.             LCD_Clear();
119.             lcd_set_cursor(1,1);
120.             LCD_String("O2 is in danger!");
121.             timer();
122.             __delay_ms(30);
123.            
124.            
125.         }
126.        
127.        
128.                  
129.         //LCD_Cmd(0x00);
130.          LCD_Clear();
131.         lcd_set_cursor(1,1);
132.         LCD_String(buffer);
133.         //__delay_ms(100);
134.        
135.         unsigned int PH_level = ADC_Read(1);
136.         PH_level = PH_level * 14 / 1023;
137.         sprintf(buffer, "PH lvl = %3u%%", PH_level);
138.         lcd_set_cursor(1,2);
139.         LCD_String(buffer);
140.         __delay_ms(100);        
141.     }
142.     return;
143. }
144. void Timer0_Init() {
145.     // Set Timer0 to 16-bit mode and use the internal clock (Fosc/4)
146.     T0CON0 = 0b10000000; // 16-bit mode, Fosc/4    
147.     // Set the prescaler to 1:256, so each Timer0 tick is 256 instruction cycles
148.     T0CON1 = 0b00000110; // 1:256 prescaler    
149.     // Load Timer0 with the initial value to achieve a 1-minute delay
150.     TMR0H = 0x85; // High byte
151.     TMR0L = 0xEE; // Low byte
152. }
153. void __interrupt()isr(void)
154. {
155.     if(PIR0bits.TMR0IF==1)
156.     {
157.         PIR0bits.TMR0IF=0;
158.         PORTBbits.RB0=0;
159.         LCD_Clear();
160.         lcd_set_cursor(1,1);
161.         LCD_String("O2 is OK again!");
162.         __delay_ms(300);
163.          LCD_Clear();
164.        // __delay_ms(2000);
165.     }
166.    
167. }
168.  
169. void timer(void)
170. {
171.     INTCONbits.GIE = 0;
172.     T0CON0 = 0b10000100;
173.     T0CON1 = 0b01001011;
174.     TMR0H = 200;
175.     PIR0bits.TMR0IF = 0;
176.     PIE0bits.TMR0IE = 1;
177.     INTCONbits.GIE = 1;
178.  
179.  
180. }
181.  
182. void ADC_Init() {
183.     // Configure ADC module settings
184.     // Set the ADC channel to ANA3 (RA3)
185.     ANSELA = 0b00000011; //RA0 and RA1
186.     TRISA =  0b11111111; //all inputs (including digital inputs)
187.     ADREF =  0b00000000; // VREF to VDD and VSS
188.     ADCLK =  0b00000011; // Set TAD = 2 us
189.     ADACQ =  0b00000000;
190.     ADCON0 = 0b10000100;  
191.     // Optional: Allow the ADC to stabilize before reading the first value
192.     __delay_us(20);
193. }
194. unsigned int ADC_Read(uint8_t channel) {    
195.     unsigned int result;
196.      ADPCH = channel; //0b00000011; //RA3 = 3
197.     __delay_us(2);
198.    
199.     ADCON0bits.GO = 1; //Start  
200.     // Wait for the conversion to complete
201.     while (ADCON0bits.GO); //while (ADCON0bits.ADGO==1);
202.     result = ((unsigned int)ADRESH << 8) | ADRESL; // ADRESH * 256 + ADRESL;
203.     // Return the ADC result (combine ADRESH and ADRESL)
204.     return(result);
205. }
206.  
207. void LCD_Init() {
208.  
209.     TRISC = 0x00; //all C port pins are output
210.     __delay_ms(15);
211.  
212.     LCD_Cmd(0x02);  // Return home
213.     LCD_Cmd(0x28);  // 4-bit mode - 2 line display - 5x7 font
214.     LCD_Cmd(0x0C);  // Display ON - Cursor OFF - Blink OFF
215.     LCD_Cmd(0x06);  // Increment cursor - No shift
216.     LCD_Cmd(0x80);  // Address DDRAM with 0 offset 80h
217. }
218.  
219. void LCD_Cmd(unsigned char command) {
220.     LCD_Send(0,command);
221. }
222.  
223. void LCD_Char(unsigned char data) {
224.     LCD_Send(1,data);
225. }
226.  
227. void LCD_Send(int RS,unsigned char data)
228. {
229.    
230.     LCD_RS = RS;     // Data mode data = 1101, 1001
231.     LCD_DATA_PORT = (LCD_DATA_PORT & 0x0F) | (data & 0xF0);   // Send higher nibble 1101,0000
232.    
233.     LCD_EN = 1;     // Enable pulse
234.     __delay_us(1);
235.     LCD_EN = 0;
236.     __delay_us(200);
237.     LCD_DATA_PORT = (LCD_DATA_PORT & 0x0F) | ((data << 4) & 0xF0);   // Send lower nibble 1001,0000
238.    
239.     LCD_EN = 1;     // Enable pulse
240.     __delay_us(1);
241.     LCD_EN = 0;
242.     __delay_ms(2);
243.  
244. }
245.  
246. void LCD_String(const char* text) {
247.     while (*text != '\0') {
248.         LCD_Char(*text++);
249.     }
250. }
251.  
252. void LCD_Clear() {
253.     LCD_Cmd(0x01);  // Clear display
254.     __delay_ms(2);
255. }
256.  
257. void lcd_set_cursor(char col,char line)
258. {
259.     if(line==1){
260.         LCD_Cmd(0b10000000 | col);        
261.     }
262.     else if(line==2){
263.         LCD_Cmd(0b11000000 | col);        
264.     }
265. }
266. void init7Segment(void) {
267.     // Initialize digit pins
268.     TRISE &= 0b11110010;    
269.     TRISD=0;
270.     PORTD =0;
271.     DIGIT1 = 0;
272.     DIGIT2 = 0;
273. }
274.  
275.  
276.  
277.  void seven_seg_Show(int i){
278.      
279.     unsigned char tens_digit = (i / 10) % 10;
280.     unsigned char ones_digit = i % 10;
281.    
282.     // Display tens digit on first digit
283.     PORTEbits.RE0 = 0;  // Set first digit high
284.     PORTD = hexvalue[tens_digit];
285.     PORTEbits.RE2 = 1;  // Set second digit low
286.     __delay_ms(30);
287.    
288.      // Display ones digit on second digit
289.     PORTEbits.RE2 = 0;  // Set second digit high
290.     PORTD = hexvalue[ones_digit];
291.     PORTEbits.RE0 = 1;  // Set first digit low
292.     __delay_ms(30);
293.      
294.    
295. }
296.