Keil51单片机解决数字显示不稳的问题

Keil51单片机解决数字显示不稳的问题

数字显示不稳，就是我们人眼的特点决定的，0.1秒的残留现象，低于这个值人眼发现不了其中变化，大于这个值就会出现同一个数字闪烁的现象。解决的方法就是所有数字，第一个的显示到最后一个的显示刷新总值低于0.1秒，即100ms。这里包括程序本身的运行时间。所以比较稳妥的办法是，计算与显示分开；显示用中断来做，如下：

#include <reg52.h>  

sbit ADDR0 = P1^0;
sbit ADDR1 = P1^1;
sbit ADDR2 = P1^2;
sbit ADDR3 = P1^3;

sbit ENLED = P1^4;
sbit ENLCD = P1^5;

sbit LED0 = P0^0;
sbit LED1 = P0^1;
sbit LED2 = P0^2;
sbit LED3 = P0^3;
sbit LED4 = P0^4;
sbit LED5 = P0^5;
sbit LED6 = P0^6;
sbit LED7 = P0^7;

unsigned char code LedChar[] = {0xC0,0xF9,0xA4,0xB0,0x99,0x92,0x82,0xF8,0x80,0x90,0x88,0x83,0xC6,0xA1,0x86,0x8E};
unsigned char LedBuff[7] = { 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF };
unsigned int cnt = 0; //中断计时器
 

//数字计算部分
void main()
{ 

unsigned char j=0 ;
unsigned long Sec =0;

ENLCD = 1;
ENLED = 0; //使能 U3

EA = 1; //打开中断总开关
ADDR3 = 1; //设置固定位，即数码管处于开放状态

TMOD = 0x01; //计时器运行在模式1下

TH0 = 0xFC; //FC67  1ms时长 
TL0 = 0x67;

ET0 = 1; //使能T0中断
TR0 = 1; //开始T0计时器

while(1)
{
if (cnt >= 100)
{
cnt = 0; //time length control
Sec++;  //1x1000ms=1 second

switch (j)
{
case 0:
{
if (Sec>9)
{
j++;
 
}
else
{
LedBuff[0] = LedChar[Sec%10];
LedBuff[1] = 0xFF;
LedBuff[2] = 0xFF;
LedBuff[3] = 0xFF;
LedBuff[4] = 0xFF;
LedBuff[5] = 0xFF;
};
};break;
case 1:
{
if (Sec>99)
{
j++;
}
else
{
LedBuff[0] = LedChar[Sec%10];
LedBuff[1] = LedChar[Sec/10%10];
LedBuff[2] = 0xFF;
LedBuff[3] = 0xFF;
LedBuff[4] = 0xFF;
LedBuff[5] = 0xFF;
};
};break;
case 2:
{
if (Sec>999)
{
j++;
}
else
{
LedBuff[0] = LedChar[Sec%10];
LedBuff[1] = LedChar[Sec/10%10];
LedBuff[2] = LedChar[Sec/100%10];
LedBuff[3] = 0xFF;
LedBuff[4] = 0xFF;
LedBuff[5] = 0xFF;
};
};break;
case 3:
{
if (Sec>9999)
{
j++;
}
else
{
LedBuff[0] = LedChar[Sec%10];
LedBuff[1] = LedChar[Sec/10%10];
LedBuff[2] = LedChar[Sec/100%10];
LedBuff[3] = LedChar[Sec/1000%10];
LedBuff[4] = 0xFF;
LedBuff[5] = 0xFF;
};
};break;
case 4:
{
if (Sec>99999)
{
j++;
}
else
{
LedBuff[0] = LedChar[Sec%10];
LedBuff[1] = LedChar[Sec/10%10];
LedBuff[2] = LedChar[Sec/100%10];
LedBuff[3] = LedChar[Sec/1000%10];
LedBuff[4] = LedChar[Sec/10000%10];
LedBuff[5] = 0xFF;
};
};break;
case 5:
{
if (Sec>999999)
{
j=0;
Sec = 0;
}
else
{
LedBuff[0] = LedChar[Sec%10];
LedBuff[1] = LedChar[Sec/10%10];
LedBuff[2] = LedChar[Sec/100%10];
LedBuff[3] = LedChar[Sec/1000%10];
LedBuff[4] = LedChar[Sec/10000%10];
LedBuff[5] = LedChar[Sec/100000%10];
};
};break;
default: break;

};

};

};

 

}  

 

//中断程序，用于显示部分，这样运算不会影响显示，保持显示的稳定性

//Timer 0 interrupt 1

void InterruptTimer0() interrupt 3
{
static unsigned char i = 0;   //这个放第一行
TH0 = 0xFC; //reload initiation setting
TL0 = 0x67;
cnt++; // 加1，这个全局变量很重要，因为它是与主程序运算部分关联

ENLED = 1;  //关闭LED显示，后面赋值，再开放显示

switch (i)

{
case 0: {ADDR2 = 0; ADDR1 = 0; ADDR0 = 0; i++; P0 = LedBuff[0]; }; break;  //LedBuff[0]这个也是全局数组变量，用于传递运算与显示之间的值
case 1: {ADDR2 = 0; ADDR1 = 0; ADDR0 = 1; i++; P0 = LedBuff[1]; }; break;
case 2: {ADDR2 = 0; ADDR1 = 1; ADDR0 = 0; i++; P0 = LedBuff[2]; }; break;
case 3: {ADDR2 = 0; ADDR1 = 1; ADDR0 = 1; i++; P0 = LedBuff[3]; }; break;
case 4: {ADDR2 = 1; ADDR1 = 0; ADDR0 = 0; i++; P0 = LedBuff[4]; }; break;
case 5: {ADDR2 = 1; ADDR1 = 0; ADDR0 = 1; i=0; P0 = LedBuff[5]; }; break;
default: break;
};

ENLED = 0; //瞬间打开LED显示

}