LCD12864液晶显示电子钟设计

12864时钟显示程序/*用LCD12864液晶显示器进行设置时钟，有独立键盘调节时间程序*/个人觉得在学习编写LCD12864显示程序时可以多结合1602一起来学习，很多东西是相通的，我这个程序就是，还有对于初学者来说，最好是理解程序每个模块的作用，掌握后对于以后的编程学习进度会更快，再补充说明一句，对于显示模块程序，着重需要对地址些函数部分理解，废话不多说，看程序吧：#include#define uchar unsigned char#define uint unsigned intsbit RS= P2^6;//数据/命令选择端(H/L)sbit RW= P2^5;//读写/选择端(H/L)sbit EP= P2^7;//使能信号sbit K1=P3^0; //开关定义sbit K2=P3^1;sbit K3=P3^2;uchar num,t;uchar K1num;char s,f,m; //可取负数uchar code table[]= " 2013-8-12 MON ";//日期显示uchar code table1[]=" 00: 00: 00 AM "; //时间显示uchar code table2[]="长沙今日多云"; //天气显示uchar code table3[]=" 南风39-30℃"; //气温显示void init1(); //中断子函数void delay(uint k) //延时函数{uint i,j;for(i=k;i>0;i--)for(j=110;j>0;j--);}void write(uchar com) //命令指令函数{ //根据时序图来设置RS=0; //选择指令寄存器RW=0; //选择写P0=com; //将8位数据通过P0口传给12864delay(5); //延时一会，让12864准备接收数据EP=1; //使能线电平变化，数据送入1602的八位数据口delay(5);EP=0;}void read(uchar date) //写入指令函数{ //根据时序图来设置RS=1; //选择寄存器RW=0; //选择写P0=date; //将8位数据通过P0口传给12864delay(5);EP=1;delay(5);EP=0;}void init() //初始化函数{RS=0;EP=0;RW=0;write(0x38); //显示设置模式write(0x0c); //显示开关控制write(0x06); //光标设置write(0x01); //清屏设置write(0x80); //数据地址初始位for(num=0;num<16;num++) //查table表数据{read(table[num]); //读取表中内容delay(20);}write(0x90);//重新设置数据指针for(num=0;num<16;num++) //查table2表数据{read(table2[num]); //读取表中内容delay(20);}write(0x98);//重新设置数据指针for(num=0;num<16;num++) //查table3表数据{read(table3[num]); //读取表中内容delay(20);}write(0x88);//重新设置数据指针for(num=0;num<16;num++){read(table1[num]); //读取table1表中内容delay(20);}}void write_sfm(uchar add,uchar date) // 时分秒函数设置{ uchar shi ,ge;shi=date/10; // 取商ge=date%10; //取余write(0x83+add); //设置add位地置read(0x30+shi); //设置十位地置read(0x30+ge); //设置个位地址}void key() //独立开关控制{if(K1==0){delay(5);if(K1==0){K1num++;while(!K1); //判断按键是否按下if(K1num==1) //按一下调节秒{TR0=0; //关定时器write(0x83+10); //找到秒位置write(0x0f); //光标闪烁}}if(K1num==2){write(0x83+8);//再按一下调节分地址}if(K1num==3) //第三次按下调节时{write(0x83+6);}if(K1num==4) //按四次回到正常计时{K1num=0;write(0x0c);//光标不闪TR0=1;}}if(K1num!=0) //有按下{if(K2==0) //K2开关控制时分秒加{delay(5);if(K2==0) //消抖{while(!K2);//松手if(K1num==1) //秒调节{m++;if(m==60)m=0;write_sfm(10,m);write(0x83+10);//秒钟地址}if(K1num==2) //分钟调节{f++;if(f==60)f=0;write_sfm(8,f);write(0x83+8); //分钟地址}if(K1num==3) //小时调节{s++;if(s==23)s=0;write_sfm(6,s);write(0x83+6);//时地址}}}if(K3==0){delay(5);if(K3==0){while(!K3);if(K1num==1) //K3控制时分秒减{m--;if(m==-1)m=59;write_sfm(10,m);write(0x83+10);}if(K1num==2)f--;if(f==-1)f=59;write_sfm(8,f);write(0x83+8);}if(K1num==3){s--;if(s==-1)m=23;write_sfm(6,s);write(0x83+6);}}}}}void main() //主函数{init(); //调用子函数init1(); //调用定时子函数while(1){key();}}void init1() //定时子函数{TMOD=0x01;EA=1; //开总中断ET0=1; //开定时器中断TR0=1;TH0=(65536-50000)/256; //设置时间50ms TL0=(65536-50000)%256;}void e() interrupt 1 //定时器T0方式1中断{ TH0=(65536-50000)/256;TL0=(65536-50000)%256;t++;if(t==18) //一秒钟定时{m++;if(m==60) //秒设置{m=0;f++;if(f==60) //分设置{f=0;s++;if(s==24) //小时设置{s=0;}write_sfm(6,s); //时位数据读取}write_sfm(8,f); //分位数据读取}write_sfm(10,m); //秒位数据读取}}。

学士学位毕业论文(设计)题目：基于单片机的12864时钟显示摘要电子时钟是一种非常广泛日常计时工具，给人们的带来了很大的方便，在社会上越来越流行。

它可以对年、月、日、星期、时、分、秒进行计时，采用直观的数字显示，可以同时显示年月日时分秒等信息，还有时间校准等功能。

该电子时钟主要采用STC89C52单片机作为主控核心，用DS1302时钟芯片作为时钟、液晶12864显示屏显示。

STC89C52单片机是由深圳宏晶科技公司推出的，功耗小，电压可选用4～6V电压供电；DS1302时钟芯片是美国DALLAS公司推出的具有细电流充电功能的低功耗实时时钟芯片，它可以对年、月、日、星期、时、分、秒进行计时，还具有闰年补偿等多种功能，而且DS1302的使用寿命长，误差小；数字显示是采用的12864液晶显示屏来显示，可以同时显示年、月、日、星期、时、分、秒等信息。

此外，该电子时钟还具有时间校准等功能。

关键词：STC89C51单片机，DS1302时钟芯片，液晶12864AbstractElectronic clock is a very extensive daily timing tool, to the people has brought great convenience, more and more popular in the community. It can be the year, month, date, day, hour, minute, second for a time, using intuitive digital display, can display information such as year, month, day, hour, and time alignment functions. The electronic clock is used mainly as a master STC89C52 microcontroller core, with theDS1302 clock chip as a clock, LCD display12864. STC89C52 SCM is a Shenzhen Hong Crystal Technology has introduced, power consumption, voltage can be selected 4 ~ 6V voltage power supply; DS1302 clock chip is American DALLAS company launched with a fine current charging low-power real-time clock chip, it can year, month, date, day, hour, minute, second for a time, also has a leap year compensation and other functions, DS1302 and long life, small error; 12864 LCD digital display isused to display that can display year, month, date, day, hour, minute, second and so on. In addition, the electronic clock also has a time calibration function.Key Words:STC89C51 microcontroller, DS1302 clock chip, LCD 12864目录1绪论 (3)1.1时钟发展史 (3)1.2 目前的研究现状 (4)1.3研究目的及意义 (4)2 总体方案设计 (5)2.1 方案的选择 (5)2．1.1设计要求 (5)2．1.2方案的选择 (5)2.2总体方案组成框图 (6)3系统硬件设计 (6)3. 1主芯片模块 (6)3.1.1 中断系统 (8)3.1.2常用寄存器 (8)3.2晶振和复位电路 (10)3.2.1晶振电路 (10)3.2.2复位电路 (11)3.3 DS1302时钟芯片电路 (11)3.3.1 DS1302引脚图 (11)3.3.2 DS1302寄存器 (12)3.3.3 DS1302外围电路 (13)3.4 LCD12864显示模块 (13)3.4.1 LCD12864引脚功能 (13)3.4.2 LCD12864指令说明 (14)3.4.3 LCD12864电路接线 (15)3.5 红外遥控模块 (16)4 系统软件设计 (17)4．1 主程序设计 (17)4.2 LCD12864驱动程序 (19)4.3 DS1302驱动程序 (21)4.4 红外遥控程序 (24)5 调试结果 (25)5.1 正常显示日期时间画面 (26)5.2 进入调整时间日期画面 (26)5.3图片显示画面 (26)6总结 (27)致谢 (28)参考文献 (29)附录一 (31)附录二 (32)1绪论1.1时钟发展史很早以前,人类主要是利用天文现象和流动物质的连续运动来计时。

毕业设计题目用PG12864LCD设计的指针式电子钟物理与电信工程学院所在院(系) 专业班级电子信息科学与技术指导教师完成地点目录引言 .................................................. 1 1 1 设计任务及方案论证设计任务及方案论证 ..................................1 1.1设计任务与要求设计任务与要求 ..................................... ..................................... 1 1 1.2 1.2 总体方案论证与设计总体方案论证与设计总体方案论证与设计 ................................. (11)2系统硬件设置 (1)2.1 STC89C51单片机简介单片机简介 ................................ ................................ 1 2.2显示模块设计显示模块设计 ....................................... ....................................... 4 42.2.1 PG12864LCD 的特性介绍的特性介绍 ......................... ......................... 4 2.2.2 LCD12864引脚介绍引脚介绍 ............................. ............................. 4 2.2.3 12864内部功能器件及相关功能内部功能器件及相关功能 .................. .................. 5 2.2.4 12864液晶与单片机接口电路液晶与单片机接口电路 .................... .................... 7 2.3设置模块设置模块 ........................................... ........................................... 8 8 2.4 2.4 振荡电路振荡电路振荡电路 ........................................... .......................................... 9 92.5 2.5 复位电路复位电路复位电路 .......................................... (99)3系统软件设计 (9)3.1总体软件设计总体软件设计 ....................................... ....................................... 9 9 3.2 3.2 时钟函数模块时钟函数模块时钟函数模块 ...................................... ...................................... 10 10 3.3 3.3 指针时钟设计指针时钟设计指针时钟设计 ...................................... ...................................... 11 113.3.1 实现功能实现功能 ..................................... 11 113.3.2实现算法实现算法 ..................................... ..................................... 11 11 3.3.3 3.3.3 函数设计函数设计函数设计 ..................................... ..................................... 13 13 3.4 3.4 显示函数模块显示函数模块显示函数模块 ...................................... ...................................... 15 153.4.1实现功能实现功能 ..................................... ..................................... 17 17 3.4.2 3.4.2 函数设计函数设计函数设计 ..................................... ..................................... 17 17 3.5.1 3.5.1 功能功能功能 ......................................... ........................................ 18 18 3.5.2 3.5.2 函数函数函数 ......................................... ........................................ 18 18 3.6主函数模块主函数模块 ........................................ . (1919)4.4.设计结果设计结果........................................... 19 5.5.使用方法使用方法........................................... 20 6.6.设计进度设计进度........................................... 20 7.7.教学单位可以提供的条件教学单位可以提供的条件 ............................. 20 致谢 ................................................. 21 参考文献 (21)用PG12864LCD设计的指针式电子钟[摘要]本设计采用的是STC89C51单片机，通过单片机内部定时器定时实现时钟定时计数功能，并以模拟时钟的形式显示在LCD_12864上。

DS1302是美国DALLAS公司推出的一种高性能、低功耗的实时时钟芯片，附加31字节静态RAM，采用SPI三线接口与CPU进行同步通信，并可采用突发方式一次传送多个字节的时钟信号和RAM数据。

实时时钟可提供秒、分、时、日、星期、月和年，一个月小与31天时可以自动调整，且具有闰年补偿功能。

下面是一段12864液晶显示实时时钟的程序：/****************************************************************************** *********时间：2012.11.30晶振：11.0592MHz芯片：STC89C52RC功能描述：在12864上显示年、月、日、星期、时、分和秒等时间信息******************************************************************************* ********/#include<reg52.h>#define uchar unsigned charsbit CLK=P1^4; //DS1302引脚定义sbit IO=P1^5;sbit CE=P1^6;sbit ACC0=ACC^0;sbit ACC7=ACC^7;sbit RS=P2^4; //12864引脚定义数据口为P0sbit RW=P2^5;sbit EN=P2^6;sbit PSB=P2^1;sbit RET=P2^3;void Input_1byte(uchar TD) //DS1302输入一字节数据{uchar i;ACC=TD;for(i=8;i>0;i--){IO=ACC0;CLK=1;CLK=0;ACC=ACC>>1;}}uchar Output_1byte(void) //DS1302输出一字节数据{uchar i;for(i=8;i>0;i--){ACC=ACC>>1;ACC7=IO;CLK=1;CLK=0;}return(ACC);}void Write_DS1302(uchar add,uchar dat)//向DS1302写{CE=0;CLK=0;CE=1;Input_1byte(add);Input_1byte(dat);CE=0;}uchar Read_DS1302(uchar add) //从DS1302读{uchar inf; //信息临时存储变量CE=0;CLK=0;CE=1;Input_1byte(add);inf=Output_1byte();CE=0;return(inf);}/**********************DS1302初始化*****************************/void init_1302(){if(Read_DS1302(0xd1)==0x55) //判断内存单元的内容，是否进行初始化 {return;}else{Write_DS1302(0x8e,0x00); //关闭写保护Write_DS1302(0x90,0x00); //电池充电设置Write_DS1302(0x80,0x00); //秒Write_DS1302(0x82,0x54); //分Write_DS1302(0x84,0x20); //时Write_DS1302(0x86,0x30); //日Write_DS1302(0x88,0x11); //月Write_DS1302(0x8a,0x05); //星期Write_DS1302(0x8c,0x12); //年Write_DS1302(0xd0,0x55); //写RAMWrite_DS1302(0x8e,0x80); //打开写保护}}/**********************延时函数*****************************/ void DelayUs2x(unsigned char t){while(--t);}void DelayMs(unsigned char t){while(t--){//大致延时1mSDelayUs2x(245);DelayUs2x(245);}}/**********************12864判忙*****************************/ void check_busy(){RS=0;RW=1;EN=1;while((P0&0x80)==0x80);EN=0;}/**********************12864写指令*****************************/ void write_com(uchar com){check_busy();RS=0;RW=0;EN=1;P0=com;DelayUs2x(250);EN=0;DelayUs2x(250);}/**********************12864写数据*****************************/void write_data(uchar dat){check_busy();RS=1;RW=0;EN=1;P0=dat;DelayUs2x(250);EN=0;DelayUs2x(250);}/**********************12864初始化函数*****************************/void init(){DelayMs(40); //大于40MS的延时程序PSB=1; //设置为8BIT并口工作模式DelayMs(1); //延时RET=0; //复位DelayMs(1); //延时RET=1; //复位置高DelayMs(200);write_com(0x30); //选择基本指令集DelayUs2x(250); //延时大于100uswrite_com(0x30); //选择8bit数据流DelayUs2x(200); //延时大于37uswrite_com(0x0c); //开显示(无游标、不反白)DelayUs2x(250); //延时大于100uswrite_com(0x01); //清除显示，并且设定地址指针为00HDelayMs(200); //延时大于10mswrite_com(0x06); //指定在资料的读取及写入时，设定游标的移动方向及指定显示的移位，光标从右向左加1位移动DelayUs2x(250); //延时大于100us}/**********************清屏*****************************/void clrscreen(){write_com(0x01);DelayMs(15);}/*********************************************************主函数********************************************************/void main(){uchar sec,sec1,sec2;uchar min,min1,min2;uchar hour,hour1,hour2;uchar date,date1,date2;uchar mon,mon1,mon2;uchar day;uchar year,year1,year2;uchar table1[]="年月日时分秒星期温度摄氏"; //长度24uchar table2[]={0XD2,0XBB, 0XB6,0XFE, 0XC8,0XFD, 0XCB,0XC4, 0XCE,0XE5, 0XCE,0XF9, 0XC8,0XD5}; //长度14 uchar table3[]="0123456789"; //长度10init(); //液晶初始化clrscreen();DelayMs(200);init_1302(); //1302初始化只初始化一下就可以需要下载两次DelayMs(50);write_com(0x80); //显示20write_data('2');write_data('0');write_com(0x82); //显示年write_data(table1[0]);write_data(table1[1]);write_com(0x84); //显示月write_data(table1[2]);write_data(table1[3]);write_com(0x86); //显示日write_data(table1[4]);write_data(table1[5]);write_com(0x91); //显示时write_data(table1[6]);write_data(table1[7]);write_com(0x93); //显示分write_data(table1[8]);write_data(table1[9]);write_com(0x95); //显示秒write_data(table1[10]);write_data(table1[11]);write_com(0x88); //显示星期write_data(table1[12]);write_data(table1[13]);write_data(table1[14]);write_data(table1[15]);while(1){sec=Read_DS1302(0x81); ////读秒sec1=sec&0x0f; //个位sec2=sec>>4; //十位min=Read_DS1302(0x83); ////读分min1=min&0x0f; //个位min2=min>>4; //十位hour=Read_DS1302(0x85); ////读时hour1=hour&0x0f; //个位hour2=hour>>4; //十位date=Read_DS1302(0x87); ////读日date1=date&0x0f; //个位date2=date>>4; //十位mon=Read_DS1302(0x89); ////读月mon1=mon&0x0f; //个位mon2=mon>>4; //十位year=Read_DS1302(0x8d); ////读年year1=year&0x0f; //个位year2=year>>4; //十位day=Read_DS1302(0x8b); ////读星期write_com(0x94); //送显示内容write_data(table3[sec2]); //秒write_data(table3[sec1]);write_com(0x92);write_data(table3[min2]); //分write_data(table3[min1]);write_com(0x90);write_data(table3[hour2]); //时write_data(table3[hour1]);write_com(0x85);write_data(table3[date2]); //日write_data(table3[date1]);write_com(0x83);write_data(table3[mon2]); //月write_data(table3[mon1]);write_com(0x81);write_data(table3[year2]); //年write_data(table3[year1]);write_com(0x8a);write_data(table2[2*day-2]); //星期write_data(table2[2*day-1]);}}。

fpga设计电子时钟（12864显示）设计心得：1，进行分块设计，类似调用函数，脉冲使能2，充分了解fpga的并行特性（c程序的串行特性，不能并行处理，线性：只有完成了当前任务，才能进行下一个任务）设计问题：1，似乎读有问题，在char_LR=1时，写的数据为汉字（程序中时间没有更改，主要为了调试看波形）实际板子验证时，将LCD_clk模块中的分频调为50到100kHz左右整体架构功能模块液晶初始化时序parameter Idle =8'b0000_0001,Basic_com =8'b0000_0010, //basic instruction:0x30Disp_set =8'b0000_0100, //set show curse blingDDRAM_clear =8'b0000_1000, //colunm address XWait_clear =8'b0001_0000,Point_set =8'b0010_0000,Show_on =8'b0100_0000,Stop=8'b1000_0000;写字符的时序由于字符属于半宽字形，且DDRAM形式下，每行只有8个地址，而字符可以写16个，因此用下面三个来表示写的地址：i nput [1:0] Y, //row 0-3i nput [2:0] X, //clunm 0-7i nput LR, //0/1因此当LR=0时，直接写地址，然后写一个字符编码即可LR=1时，先写地址，读出高位数据，然后写入两个字节（读出的数据，要写的数据）parameter Idle =8'b0000_0001,DDRAM =8'b0000_0010, //drawing modeW_addr =8'b0000_0100, //row address YDummy =8'b0000_1000, // not really readingR_data =8'b0001_0000, //reading high byte dataW0_data =8'b0010_0000,W1_data =8'b0100_0000,Stop =8'b1000_0000;# t1: 0 t2: 2305, T: 10,n_init: 38 # t1: 2305 t2: 2665, T: 10,n_char: 6 # t1: 2665 t2: 3265, T: 10,n_char: 10完成了上述工作，就可以设计一个简单的电子时钟，其要求如下：在屏幕上显示时间00：00：00要动态走（主要就是控制脉冲信号的产生）设计思路：100：00：0023LCD更新数据显示00:00:0100:01:591代码/*sign.v//creat the control signclock h:m:s*/module sign(//module LED(input lcd_clk, //100kHzinput sys_rst,output reg lcd_char_en,output reg lcd_init_en,output reg [7:0]char_data,output reg [2:0]char_X,output reg [1:0]char_Y,output reg char_LR);parameter T_w_char = 5,T_lcd_init = 40;reg [47:0] time_out;/* 1s */reg [16:0] cnt_s;reg [5:0] cnt0_clk;reg [3:0] cnt1_clk;reg [2:0] cnt_char;reg [5:0] sec,min;reg [4:0] hour;reg flag_s,flag_init;always @ (posedge lcd_clk or negedge sys_rst) begin //100kHz if(!sys_rst)begincnt_s <=0;cnt0_clk<=0;cnt1_clk<=0;cnt_char<=0;sec <=0;min <=0;hour <=0;flag_s <=0;flag_init <=1'b1;char_Y <= 2'b10;endelsebeginif(cnt_s == (40-1))begincnt_s <=0;flag_s<=1'b1;data_deal; //taskendelsecnt_s <=cnt_s+1'b1;if(flag_init)begincnt0_clk <= cnt0_clk +1'b1;case(cnt0_clk)1 : begin lcd_init_en <=1'b0; end2 : begin lcd_init_en <=1'b1; end3 : begin lcd_init_en <=1'b1; end4 : begin lcd_init_en <=1'b0; endT_lcd_init: beginflag_init <=0;cnt0_clk <=0;enddefault: lcd_init_en <=0;endcaseendelseif(flag_s)begincnt1_clk <= cnt1_clk +1'b1;case(cnt1_clk)1 : begin lcd_char_en <=1'b0; e nd2 : begin lcd_char_en <=1'b1; e nd3 : begin lcd_char_en <=1'b1; e nd4 : begin lcd_char_en <=1'b0; e ndT_w_char: beginif(cnt_char == 3'b111)begin cnt_char<=0; flag_s <=0; endelsecnt_char <=cnt_char+1'b1;cnt1_clk <=0;enddefault: lcd_char_en <=0;endcasecase(cnt_char)//2 3 4 50 : begin char_X <=3'b000; char_LR <=0; char_data <=time_out[47:40]; end //x0:00:001 : begin char_X <=3'b001; char_LR <=0; char_data <=time_out[39:32]; end //0x:00:002 : begin char_X <=3'b010; char_LR <=0; char_data <=8'h3a; end //: ascii 0583 : begin char_X <=3'b011; char_LR <=0; char_data <=time_out[31:24]; end //00:x0:004 : begin char_X <=3'b100; char_LR <=0; char_data <=time_out[23:16]; end //00:0x:005 : begin char_X <=3'b101; char_LR <=0; char_data <=8'h3a; end //: ascii 0586 : begin char_X <=3'b110; char_LR <=0; char_data <=time_out[15: 8]; end//00:00:x07 : begin char_X <=3'b111; char_LR <=0; char_data <=time_out[7 : 0]; endendcaseendendendtask data_deal;beginif(sec == 59)if(min ==59)if(hour == 23)begin hour<=0;min <=0;sec <=0; endelsebegin hour<=hour + 1'b1; min <=0; sec<=0; endelsebegin min <= min+1'b1; sec <=0; endelsesec <= sec +1'b1;time_out[47:40] <= 8'h30+(hour/10);time_out[39:32] <= 8'h30+(hour%10);time_out[31:24] <= 8'h30+(min /10);time_out[23:16] <= 8'h30+(min %10);time_out[15: 8] <= 8'h30+(sec /10);time_out[ 7: 0] <= 8'h30+(sec %10);endendtaskendmodule2代码module LCD_init(//module LED(input lcd_clk,input sys_clk,input lcd_en, //1 is activedoutput reg LCD_RS,output reg LCD_RW,output reg LCD_EN,inout [7:0] LCD_DATA,output reg ACK);reg flag;reg [7:0] lcd_data;reg [7:0] State;reg link_rs;reg link_data;parameter Idle =8'b0000_0001,Basic_com =8'b0000_0010, //basic instruction:0x30Disp_set =8'b0000_0100, //set show curse blingDDRAM_clear =8'b0000_1000, //colunm address XWait_clear =8'b0001_0000,Point_set =8'b0010_0000,Show_on =8'b0100_0000,Stop =8'b1000_0000;reg [9:0] cnt; //16*2*32=2^10 byte(8bits)/* LCD_RW LCD_DATA*/assign LCD_DATA = link_data ? lcd_data: 8'hzz;/* LCD_RW LCD_EN */always @ (posedge sys_clk) beginif(flag)beginLCD_RW =0;LCD_EN = lcd_clk;endelsebeginLCD_RW =1'bz;LCD_EN =1'bz;endend/* LCD_RS */always @ (posedge lcd_clk) beginif(link_rs)LCD_RS <=1'b0;elseLCD_RS <=1'bz;end/*-Main state transter-*/always @ (posedge lcd_clk) begincase (State)Idle : beginif(lcd_en)begin link_rs=1; State <= Basic_com; endelseState <= Idle;ACK =0;flag <=1'b0;lcd_data <= 8'hzz;cnt <= 0;endBasic_com : beginflag <=1'b1;link_data =1'b1;cnt <= cnt +1'b1;if(cnt == 1)State <= Disp_set;elseState <= Basic_com;lcd_data <= 8'h30;endDisp_set : beginState <= DDRAM_clear;lcd_data <= 8'h0c; //show curse blink is offendDDRAM_clear : beginState <= Wait_clear;lcd_data <= 8'h01;endWait_clear : begincnt <=cnt +1'b1;link_data = 1'b0;flag <=0;lcd_data <= 8'hzz;if(cnt == 30)State <= Point_set;elseState <= Wait_clear;endPoint_set : beginflag <=1'b1;link_data =1'b1;State <= Show_on;lcd_data <= 8'h06; //point +1 automatically,screen move off endShow_on : beginState <= Stop;lcd_data <= 8'h0c;endStop : beginState <= Idle;flag <=1'b0;link_data =1'b0;ACK <=1'b1;lcd_data <= 8'hzz;cnt <= 0;link_rs =0;enddefault: begin ACK =0;State <= Idle;end endcaseendendmodule3代码//module LCD_top(module LED(input sys_clk,input sys_rst,output LCD_RS,output LCD_RW,output LCD_EN,inout [7:0] LCD_DATA,output BUSY);wire [7:0] char_data;wire [2:0] char_X;wire [1:0] char_Y;sign singb(.lcd_clk (lcd_clk), //100kHz.sys_rst (sys_rst),.lcd_char_en(lcd_char_en),.lcd_init_en(lcd_init_en),.char_data (char_data),.char_X (char_X),.char_Y (char_Y),.char_LR (char_LR));LCD_init lcd_init(.lcd_clk (lcd_clk),.sys_clk (sys_clk),.lcd_en (lcd_init_en), //1 is actived .LCD_RS (LCD_RS),.LCD_RW (LCD_RW),.LCD_EN (LCD_EN),.LCD_DATA (LCD_DATA),.ACK (init_ack));LCD_charac a(.lcd_clk (lcd_clk),.sys_clk (sys_clk),.lcd_en (lcd_char_en), //1 is actived .Y (char_Y), //row 0-3.X (char_X), //clunm 0-7.LR (char_LR), //0/1.data_disp (char_data),.LCD_RS (LCD_RS),.LCD_RW (LCD_RW),.LCD_EN (LCD_EN),.LCD_DATA (LCD_DATA),.ACK (init_ack));LCD_clk clk1(.sys_clk (sys_clk),.lcd_clk (lcd_clk));endmodule4代码module LCD_clk(//module LED(input sys_clk,output reg lcd_clk);/*-creat the 25kHz clock-*/reg [11:0] lcd_cnt;always @ (posedge sys_clk) beginif(lcd_cnt == 2) //100kHzbeginlcd_cnt =0;lcd_clk <= ~ lcd_clk;endelselcd_cnt = lcd_cnt +1'b1;endinitial begin lcd_clk =0; lcd_cnt =0; endendmodule5代码/* to display character */module LCD_charac(//module LED(input lcd_clk,input sys_clk,input lcd_en, //1 is activedinput [1:0] Y, //row 0-3input [2:0] X, //clunm 0-7input LR, //0/1input [7:0] data_disp,output reg LCD_RS,output reg LCD_RW,output reg LCD_EN,inout [7:0] LCD_DATA,output reg ACK);reg [7:0] lcd_data;reg [7:0] R_buff;reg [7:0] State;parameter Idle =8'b0000_0001,DDRAM =8'b0000_0010, //drawing modeW_addr =8'b0000_0100, //row address YDummy =8'b0000_1000, // not really readingR_data =8'b0001_0000, //reading high byte dataW0_data =8'b0010_0000,W1_data =8'b0100_0000,Stop =8'b1000_0000;reg flag,cnt;reg link_data;reg flag0;/* LCD_DATA */assign LCD_DATA = link_data ? lcd_data :8'hzz;/* LCD_EN */always @ (posedge sys_clk) beginif(flag == 1'b1)LCD_EN <= lcd_clk;elseLCD_EN <=1'bz;end/* LCD_RW */always @ (posedge lcd_clk) beginif(flag0)if(State == Dummy || State == R_data)LCD_RW <=1'b1;elseLCD_RW <=1'b0;elseLCD_RW <=1'bz;end/* LCD_RS */always @ (posedge lcd_clk) beginif(flag0)if(State == W0_data || State == W1_data || State == Dummy || State == R_data) LCD_RS <=1'b1;elseLCD_RS <=1'b0;elseLCD_RS <=1'bz;end/*-Main state transter-*/always @ (posedge lcd_clk) begincase (State)Idle : beginif(lcd_en)begin State <= DDRAM; link_data =1; flag0=1'b1; endelsebegin State <= Idle; flag0= 1'b0;endflag <= 1'b0;lcd_data <= 8'hzz;ACK <=0;endDDRAM : begin //here flag is changed,not Idle, cause sys_clk flag <= 1'b1;State <= W_addr;link_data =1;lcd_data <= 8'h30;endW_addr : beginif(!cnt)beginif(LR)State <= Dummy;elseState <= W0_data;cnt =1'b1;endelseState <= W0_data;case (Y)2'b00: lcd_data <= 8'h80 + X;2'b01: lcd_data <= 8'h90 + X;2'b10: lcd_data <= 8'h88 + X;2'b11: lcd_data <= 8'h98 + X;endcaselink_data =1'b1;endDummy : beginState <= R_data;R_buff <= LCD_DATA;link_data =0;endR_data : beginState <=W_addr;R_buff <= LCD_DATA;endW0_data : beginif( !LR)beginlcd_data <= data_disp;State <= Stop;endelsebeginlcd_data <= R_buff;State <= W1_data;endendW1_data : beginlcd_data <= data_disp;State <=Stop;flag0=0;endStop : beginState <= Idle;flag <= 1'b0;lcd_data <= 8'hzz;cnt <= 0;ACK <= 1;enddefault: begin ACK =0;State <= Idle; link_data=0 ;end endcaseendendmodule。

DS1302是美国DALLAS公司推出的一种高性能、低功耗的实时时钟芯片，附加31字节静态RAM，采用SPI三线接口与CPU进行同步通信，并可采用突发方式一次传送多个字节的时钟信号和RAM数据。

实时时钟可提供秒、分、时、日、星期、月和年，一个月小与31天时可以自动调整，且具有闰年补偿功能。

下面是一段12864液晶显示实时时钟的程序：/****************************************************************************** *********时间：2012.11.30晶振：11.0592MHz芯片：STC89C52RC功能描述：在12864上显示年、月、日、星期、时、分和秒等时间信息******************************************************************************* ********/#include<reg52.h>#define uchar unsigned charsbit CLK=P1^4; //DS1302引脚定义sbit IO=P1^5;sbit CE=P1^6;sbit ACC0=ACC^0;sbit ACC7=ACC^7;sbit RS=P2^4; //12864引脚定义数据口为P0sbit RW=P2^5;sbit EN=P2^6;sbit PSB=P2^1;sbit RET=P2^3;void Input_1byte(uchar TD) //DS1302输入一字节数据{uchar i;ACC=TD;for(i=8;i>0;i--){IO=ACC0;CLK=1;CLK=0;ACC=ACC>>1;}}uchar Output_1byte(void) //DS1302输出一字节数据{uchar i;for(i=8;i>0;i--){ACC=ACC>>1;ACC7=IO;CLK=1;CLK=0;}return(ACC);}void Write_DS1302(uchar add,uchar dat)//向DS1302写{CE=0;CLK=0;CE=1;Input_1byte(add);Input_1byte(dat);CE=0;}uchar Read_DS1302(uchar add) //从DS1302读{uchar inf; //信息临时存储变量CE=0;CLK=0;CE=1;Input_1byte(add);inf=Output_1byte();CE=0;return(inf);}/**********************DS1302初始化*****************************/void init_1302(){if(Read_DS1302(0xd1)==0x55) //判断内存单元的内容，是否进行初始化 {return;}else{Write_DS1302(0x8e,0x00); //关闭写保护Write_DS1302(0x90,0x00); //电池充电设置Write_DS1302(0x80,0x00); //秒Write_DS1302(0x82,0x54); //分Write_DS1302(0x84,0x20); //时Write_DS1302(0x86,0x30); //日Write_DS1302(0x88,0x11); //月Write_DS1302(0x8a,0x05); //星期Write_DS1302(0x8c,0x12); //年Write_DS1302(0xd0,0x55); //写RAMWrite_DS1302(0x8e,0x80); //打开写保护}}/**********************延时函数*****************************/ void DelayUs2x(unsigned char t){while(--t);}void DelayMs(unsigned char t){while(t--){//大致延时1mSDelayUs2x(245);DelayUs2x(245);}}/**********************12864判忙*****************************/ void check_busy(){RS=0;RW=1;EN=1;while((P0&0x80)==0x80);EN=0;}/**********************12864写指令*****************************/ void write_com(uchar com){check_busy();RS=0;RW=0;EN=1;P0=com;DelayUs2x(250);EN=0;DelayUs2x(250);}/**********************12864写数据*****************************/void write_data(uchar dat){check_busy();RS=1;RW=0;EN=1;P0=dat;DelayUs2x(250);EN=0;DelayUs2x(250);}/**********************12864初始化函数*****************************/void init(){DelayMs(40); //大于40MS的延时程序PSB=1; //设置为8BIT并口工作模式DelayMs(1); //延时RET=0; //复位DelayMs(1); //延时RET=1; //复位置高DelayMs(200);write_com(0x30); //选择基本指令集DelayUs2x(250); //延时大于100uswrite_com(0x30); //选择8bit数据流DelayUs2x(200); //延时大于37uswrite_com(0x0c); //开显示(无游标、不反白)DelayUs2x(250); //延时大于100uswrite_com(0x01); //清除显示，并且设定地址指针为00HDelayMs(200); //延时大于10mswrite_com(0x06); //指定在资料的读取及写入时，设定游标的移动方向及指定显示的移位，光标从右向左加1位移动DelayUs2x(250); //延时大于100us}/**********************清屏*****************************/void clrscreen(){write_com(0x01);DelayMs(15);}/*********************************************************主函数********************************************************/void main(){uchar sec,sec1,sec2;uchar min,min1,min2;uchar hour,hour1,hour2;uchar date,date1,date2;uchar mon,mon1,mon2;uchar day;uchar year,year1,year2;uchar table1[]="年月日时分秒星期温度摄氏"; //长度24uchar table2[]={0XD2,0XBB, 0XB6,0XFE, 0XC8,0XFD, 0XCB,0XC4, 0XCE,0XE5, 0XCE,0XF9, 0XC8,0XD5}; //长度14 uchar table3[]="0123456789"; //长度10init(); //液晶初始化clrscreen();DelayMs(200);init_1302(); //1302初始化只初始化一下就可以需要下载两次DelayMs(50);write_com(0x80); //显示20write_data('2');write_data('0');write_com(0x82); //显示年write_data(table1[0]);write_data(table1[1]);write_com(0x84); //显示月write_data(table1[2]);write_data(table1[3]);write_com(0x86); //显示日write_data(table1[4]);write_data(table1[5]);write_com(0x91); //显示时write_data(table1[6]);write_data(table1[7]);write_com(0x93); //显示分write_data(table1[8]);write_data(table1[9]);write_com(0x95); //显示秒write_data(table1[10]);write_data(table1[11]);write_com(0x88); //显示星期write_data(table1[12]);write_data(table1[13]);write_data(table1[14]);write_data(table1[15]);while(1){sec=Read_DS1302(0x81); ////读秒sec1=sec&0x0f; //个位sec2=sec>>4; //十位min=Read_DS1302(0x83); ////读分min1=min&0x0f; //个位min2=min>>4; //十位hour=Read_DS1302(0x85); ////读时hour1=hour&0x0f; //个位hour2=hour>>4; //十位date=Read_DS1302(0x87); ////读日date1=date&0x0f; //个位date2=date>>4; //十位mon=Read_DS1302(0x89); ////读月mon1=mon&0x0f; //个位mon2=mon>>4; //十位year=Read_DS1302(0x8d); ////读年year1=year&0x0f; //个位year2=year>>4; //十位day=Read_DS1302(0x8b); ////读星期write_com(0x94); //送显示内容write_data(table3[sec2]); //秒write_data(table3[sec1]);write_com(0x92);write_data(table3[min2]); //分write_data(table3[min1]);write_com(0x90);write_data(table3[hour2]); //时write_data(table3[hour1]);write_com(0x85);write_data(table3[date2]); //日write_data(table3[date1]);write_com(0x83);write_data(table3[mon2]); //月write_data(table3[mon1]);write_com(0x81);write_data(table3[year2]); //年write_data(table3[year1]);write_com(0x8a);write_data(table2[2*day-2]); //星期write_data(table2[2*day-1]);}}。

学士学位毕业论文(设计)题目：基于单片机的12864时钟显示摘要电子时钟是一种非常广泛日常计时工具，给人们的带来了很大的方便，在社会上越来越流行。

它可以对年、月、日、星期、时、分、秒进行计时，采用直观的数字显示，可以同时显示年月日时分秒等信息，还有时间校准等功能。

该电子时钟主要采用STC89C52单片机作为主控核心，用DS1302时钟芯片作为时钟、液晶12864显示屏显示。

STC89C52单片机是由深圳宏晶科技公司推出的，功耗小，电压可选用4～6V电压供电；DS1302时钟芯片是美国DALLAS公司推出的具有细电流充电功能的低功耗实时时钟芯片，它可以对年、月、日、星期、时、分、秒进行计时，还具有闰年补偿等多种功能，而且DS1302的使用寿命长，误差小；数字显示是采用的12864液晶显示屏来显示，可以同时显示年、月、日、星期、时、分、秒等信息。

此外，该电子时钟还具有时间校准等功能。

关键词：STC89C51单片机，DS1302时钟芯片，液晶12864AbstractElectronic clock is a very extensive daily timing tool, to the people has brought great convenience, more and more popular in the community. It can be the year, month, date, day, hour, minute, second for a time, using intuitive digital display, can display information such as year, month, day, hour, and time alignment functions. The electronic clock is used mainly as a master STC89C52 microcontroller core, with theDS1302 clock chip as a clock, LCD display12864. STC89C52 SCM is a Shenzhen Hong Crystal Technology has introduced, power consumption, voltage can be selected 4 ~ 6V voltage power supply; DS1302 clock chip is American DALLAS company launched with a fine current charging low-power real-time clock chip, it can year, month, date, day, hour, minute, second for a time, also has a leap year compensation and other functions, DS1302 and long life, small error; 12864 LCD digital display isused to display that can display year, month, date, day, hour, minute, second and so on. In addition, the electronic clock also has a time calibration function.Key Words:STC89C51 microcontroller, DS1302 clock chip, LCD 12864目录1绪论 (3)1.1时钟发展史 (3)1.2 目前的研究现状 (4)1.3研究目的及意义 (4)2 总体方案设计 (5)2.1 方案的选择 (5)2．1.1设计要求 (5)2．1.2方案的选择 (5)2.2总体方案组成框图 (6)3系统硬件设计 (6)3. 1主芯片模块 (6)3.1.1 中断系统 (8)3.1.2常用寄存器 (8)3.2晶振和复位电路 (10)3.2.1晶振电路 (10)3.2.2复位电路 (11)3.3 DS1302时钟芯片电路 (11)3.3.1 DS1302引脚图 (11)3.3.2 DS1302寄存器 (12)3.3.3 DS1302外围电路 (13)3.4 LCD12864显示模块 (13)3.4.1 LCD12864引脚功能 (13)3.4.2 LCD12864指令说明 (14)3.4.3 LCD12864电路接线 (15)3.5 红外遥控模块 (16)4 系统软件设计 (17)4．1 主程序设计 (17)4.2 LCD12864驱动程序 (19)4.3 DS1302驱动程序 (21)4.4 红外遥控程序 (24)5 调试结果 (25)5.1 正常显示日期时间画面 (26)5.2 进入调整时间日期画面 (26)5.3图片显示画面 (26)6总结 (27)致谢 (28)参考文献 (29)附录一 (31)附录二 (32)1绪论1.1时钟发展史很早以前,人类主要是利用天文现象和流动物质的连续运动来计时。