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基于51单片机智能家居家电继电器开关插座定时WiFi无线proteus仿真原理图PCB
功能:
0.本系统采用STC89C52作为单片机
1.手机通过wifi控制4路继电器的开和关以及定时:
手机发送OA,继电器全部打开,
手机发送CA,继电器全部关闭,
手机发送O14,继电器14打开,
手机发送C14,继电器14闭合,
就是手机发送U14,继电器14,10s后打开,
就是手机发送D14,继电器14,10s后关闭。
2.系统具备四路继电器可以控制四种家电
3.采用DC002作为电源接口可直接输入5V给整个系统供电原理图:
PCB :
主程序:
#include#include #include #include "delay.h" /************************* 宏定义 *************************/ #define FALSE 0x01 #define OPEN 0x22 #define CLOSE 0x33 #define ON 0 #define OFF 1 /************************* 管脚定义 *************************/ sbit RELAY1 = P3^5; //继电器控制 sbit RELAY2 = P3^4; sbit RELAY3 = P3^3; sbit RELAY4 = P3^2; /************************* 变量定义 *************************/ unsigned char relay1Flag = CLOSE; //状态标志 unsigned char relay2Flag = CLOSE; unsigned char relay3Flag = CLOSE; unsigned char relay4Flag = CLOSE; unsigned char CountLater1 = 0; //延时计数 unsigned char CountLater2 = 0; unsigned char CountLater3 = 0; unsigned char CountLater4 = 0; unsigned char Rxd_Busy = 0; //串口判忙 unsigned char record = 0; //记录串口结束数据长度 unsigned char Tmepbuf[3] = {0,0,0}; //暂存串口接收数据 unsigned char i; /************************* 函数声明 *************************/ void Timer0_Init(void); //定时器0初始化 void UART_Init(void); //串口初始化 void UART_SendByte(unsigned char dat); //串口发送字节数据 void SendStr(unsigned char *s, unsigned char length); //串口发送字符串 void main(void) { Timer0_Init(); //定时器0初始化 UART_Init(); //串口初始化 波特率115200 DelayMs(100); SendStr("AT+CIPMUX=1\r\n", 13); //打开多连接 DelayMs(250); SendStr("AT+CIPSERVER=1,8080\r\n", 21); //建立服务 端口号为8080 DelayMs(250); while (1); //主循环 } void Timer0_Init(void) { TMOD &= 0xF0; TMOD |= 0x01; // 使用模式1,16位定时器,使用"|"符号可以在使用多个定时器时不受影响 TL0 = 0x00; // 设置定时初始值 TH0 = 0x4C; // 设置定时初始值 50ms EA = 1; // 总中断打开 ET0 = 1; // 定时器中断打开 TR0 = 1; // 定时器开关打开 } void Timer0_isr(void) interrupt 1 { static unsigned char times50ms = 0; // 系统 定时器计数 TL0 = 0x00; // 设置定时初始值 TH0 = 0x4C; // 设置定时初始值 50ms times50ms++; if (times50ms > 20) //延时 约1s { times50ms = 0; if (CountLater1 > 0) //延时数据大于0时递减 { CountLater1--; } //-- else { if (relay1Flag == OPEN) //延时数据为0时操作 { RELAY1 = ON; } else if (relay1Flag == CLOSE) { RELAY1 = OFF; } } if (CountLater2 > 0) { CountLater2--; } else { if (relay2Flag == OPEN) { RELAY2 = ON; } else if (relay2Flag == CLOSE) { RELAY2 = OFF; } } if (CountLater3 > 0) { CountLater3--; } else { if (relay3Flag == OPEN) { RELAY3 = ON; } else if (relay3Flag == CLOSE) { RELAY3 = OFF; } } if (CountLater4 > 0) { CountLater4--; } else { if (relay4Flag == OPEN) { RELAY4 = ON; } else if (relay4Flag == CLOSE) { RELAY4 = OFF; } } } // Rxd_Busy++; // if (Rxd_Busy >= 20) //判忙判断 防止串口接收出现紊乱 // { // record = 0; // for (i = 0; i < 15; i++) // { // Tmepbuf[i] = 0x00; //清空接收到的数据 // } // } } void UART_Init(void) { SCON = 0x50; TH2 = 0xFF; TL2 = 0xFD; RCAP2H = 0xFF; //(65536-(FOSC/32/BAUD)) BAUD = 115200 FOSC = 11059200 RCAP2L = 0xFD; /*****************/ TCLK = 1; RCLK = 1; C_T2 = 0; EXEN2 = 0; /*****************/ TR2 = 1; ES = 1; //打开串口中断 EA = 1; //打开总中断 } void SendByte(unsigned char dat) //串口发送单字节数据 { unsigned char time_out; time_out = 0x00; SBUF = dat; //将数据放入SBUF中 while ((!TI) && (time_out < 100)) //检测是否发送出去 { time_out++; DelayUs10x(2); } //未发送出去 进行短暂延时 TI = 0; //清除ti标志 } void SendStr(unsigned char *s, unsigned char length) //发送定长度字符串 { unsigned char NUM; NUM = 0x00; while (NUM < length) //发送长度对比 { SendByte(*s); //放松单字节数据 s++; //指针++ NUM++; //下一个++ } } void UART_SER(void) interrupt 4 //串行中断服务程序 { unsigned char R_buf; static unsigned char firstBit = 0; // Rxd_Busy = 0; if (RI) //判断是接收中断产生 { RI = 0; //标志位清零 R_buf = SBUF; if (R_buf == '*') { firstBit = 1; record = 0; Tmepbuf[0] = 0; Tmepbuf[1] = 0; Tmepbuf[2] = 0; //清空数据 record++; } else if (firstBit == 1) { Tmepbuf[record] = R_buf; //存储接收 record++; if (record >= 3) { firstBit = 0; } if (Tmepbuf[2] == '1') { if (Tmepbuf[1] == 'O') { relay1Flag = OPEN; //状态记录 CountLater1 = 0; //获取延时时间 } else if (Tmepbuf[1] == 'C') { relay1Flag = CLOSE; //获取状态 CountLater1 = 0; //获取延时时间 } else if (Tmepbuf[1] == 'U') { relay1Flag = OPEN; //状态记录 CountLater1 = 10; //获取延时时间 } else if (Tmepbuf[1] == 'D') { relay1Flag = CLOSE; //状态记录 CountLater1 = 10; //获取延时时间 } } else if (Tmepbuf[2] == '2') { if (Tmepbuf[1] == 'O') { relay2Flag = OPEN; //状态记录 CountLater2 = 0; //获取延时时间 } else if (Tmepbuf[1] == 'C') { relay2Flag = CLOSE; //获取状态 CountLater2 = 0; //获取延时时间 } else if (Tmepbuf[1] == 'U') { relay2Flag = OPEN; //状态记录 CountLater2 = 10; //获取延时时间 } else if (Tmepbuf[1] == 'D') { relay2Flag = CLOSE; //状态记录 CountLater2 = 10; //获取延时时间 } } else if (Tmepbuf[2] == '3') { if (Tmepbuf[1] == 'O') { relay3Flag = OPEN; //状态记录 CountLater3 = 0; //获取延时时间 } else if (Tmepbuf[1] == 'C') { relay3Flag = CLOSE; //获取状态 CountLater3 = 0; //获取延时时间 } else if (Tmepbuf[1] == 'U') { relay3Flag = OPEN; //状态记录 CountLater3 = 10; //获取延时时间 } else if (Tmepbuf[1] == 'D') { relay3Flag = CLOSE; //状态记录 CountLater3 = 10; //获取延时时间 } } else if (Tmepbuf[2] == '4') { if (Tmepbuf[1] == 'O') { relay4Flag = OPEN; //状态记录 CountLater4 = 0; //获取延时时间 } else if (Tmepbuf[1] == 'C') { relay4Flag = CLOSE; //获取状态 CountLater4 = 0; //获取延时时间 } else if (Tmepbuf[1] == 'U') { relay4Flag = OPEN; //状态记录 CountLater4 = 10; //获取延时时间 } else if (Tmepbuf[1] == 'D') { relay4Flag = CLOSE; //状态记录 CountLater4 = 10; //获取延时时间 } } else if (Tmepbuf[2] == 'A') { if (Tmepbuf[1] == 'O') { relay1Flag = OPEN; //状态记录 relay2Flag = OPEN; relay3Flag = OPEN; relay4Flag = OPEN; CountLater1 = 0; //获取延时时间 CountLater2 = 0; CountLater3 = 0; CountLater4 = 0; } else if (Tmepbuf[1] == 'C') { relay1Flag = CLOSE; //获取状态 relay2Flag = CLOSE; relay3Flag = CLOSE; relay4Flag = CLOSE; CountLater1 = 0; //获取延时时间 CountLater2 = 0; CountLater3 = 0; CountLater4 = 0; } else if (Tmepbuf[1] == 'U') { relay1Flag = OPEN; //状态记录 relay2Flag = OPEN; relay3Flag = OPEN; relay4Flag = OPEN; CountLater1 = 10; //获取延时时间 CountLater2 = 10; CountLater3 = 10; CountLater4 = 10; } else if (Tmepbuf[1] == 'D') { relay1Flag = CLOSE; //状态记录 relay2Flag = CLOSE; relay3Flag = CLOSE; relay4Flag = CLOSE; CountLater1 = 10; //获取延时时间 CountLater2 = 10; CountLater3 = 10; CountLater4 = 10; } } } } // if (TI) //如果是发送标志位,清零 // TI = 0; } - 1
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- 原文地址:https://blog.csdn.net/jimo167913/article/details/127964924
