- 一、模板罗列
- 1.1 iic.h
- 1.2 ds1302.h
- 1.3 onewire.h
- 1.4 main.c
- 1.5 onewire.c
- 1.4 iic.c
- 1.4 ds1302.c
- 二、一些技巧总结
- 三、心得
#ifndef __IIC_H__ #define __IIC_H__ #include1.2 ds1302.h#include "intrins.h" sbit SD = P2^1; sbit SCL = P2^0; void IIC_Start(void); void IIC_Stop(void); bit IIC_WaitAck(void); void IIC_SendAck(bit ackbit); void IIC_SendByte(unsigned char byt); unsigned char IIC_RecByte(void); void Read_DAC(unsigned char date); unsigned char Write_ADC(unsigned char add); #endif
#ifndef __DS1302_H__ #define __DS1302_H__ #include1.3 onewire.h#include sbit SCK = P1^7; sbit SDA = P2^3; sbit RST = P1^3; void Write_Ds1302(unsigned char temp); void Write_Ds1302_Byte( unsigned char address,unsigned char dat ); unsigned char Read_Ds1302_Byte( unsigned char address ); #endif
#ifndef __ONEWIRE_H__ #define __ONEWIRE_H__ #include1.4 main.csbit DQ = P1^4; unsigned char rd_temperature(void); #endif
#include1.5 onewire.c#include "onewire.h" #include "iic.h" #include "ds1302.h" #define uchar unsigned char #define uint unsigned int uchar SMG_duanma[10] = {0xC0, 0xF9, 0xA4, 0xB0, 0x99, 0x92, 0x82, 0xF8, 0x80, 0x90}; uchar yi,er,san,si,wu,liu,qi,ba; void SelectHC138(uchar channel); void initsys(); void DisplaySMG_Bit(uchar pos, uchar value); void Delay_one_ms_SMG(); void SMG_Display(); void Alone_Key(); void Delay_five_ms_Key(); void main() { yi = er = san = si = wu = liu = qi = ba = 0; initsys(); while(1) { Alone_Key(); SMG_Display(); } } // void SelectHC138(uchar channel) { switch(channel) { case 4: //LED P2 = (P2 & 0x1F) | 0x80; break; case 5: //蜂鸣器和继电器 P2 = (P2 & 0x1F) | 0xA0; break; case 6: //位码 P2 = (P2 & 0x1F) | 0xC0; break; case 7: //段码 P2 = (P2 & 0x1F) | 0xE0; break; } } void initsys() { SelectHC138(5); P0 = 0x00;//关闭蜂鸣器和继电器 SelectHC138(4); P0 = 0xFF; SelectHC138(6); P0 = 0xFF; SelectHC138(7); P0 = 0xFF; } void DisplaySMG_Bit(uchar pos, uchar value) { SelectHC138(6); P0 = 0x01 << pos; SelectHC138(7); P0 = value; } void Delay_one_ms_SMG() { uint j; for(j = 845; j > 0; j--); } void SMG_Display() { DisplaySMG_Bit(0, SMG_duanma[yi] & 0x80); Delay_one_ms_SMG(); DisplaySMG_Bit(1, SMG_duanma[er] - 0x80); Delay_one_ms_SMG(); DisplaySMG_Bit(2, SMG_duanma[san] | 0x80); Delay_one_ms_SMG(); DisplaySMG_Bit(3, SMG_duanma[si]); Delay_one_ms_SMG(); DisplaySMG_Bit(4, SMG_duanma[wu]); Delay_one_ms_SMG(); DisplaySMG_Bit(5, SMG_duanma[liu]); Delay_one_ms_SMG(); DisplaySMG_Bit(6, SMG_duanma[qi]); Delay_one_ms_SMG(); DisplaySMG_Bit(7, SMG_duanma[ba]); Delay_one_ms_SMG(); } void Delay_five_ms_Key() { uint i,j; for(i = 0;i < 5;i++) for(j = 845; j > 0;j--); } void Alone_Key() { //S7 if(P30 == 0) { Delay_five_ms_Key(); if(P30 == 0) { yi = 1; } while(!P30); } //S6 if(P31 == 0) { Delay_five_ms_Key(); if(P31 == 0) { er = 1; } while(!P31); } //S5 if(P32 == 0) { Delay_five_ms_Key(); if(P32 == 0) { san = 1; } while(!P32); } //S4 if(P33 == 0) { Delay_five_ms_Key(); if(P33 == 0) { si = 1; } while(!P33); } } void Timer0Init(void) //1毫秒@12.000MHz { AUXR |= 0x80; //定时器时钟1T模式 TMOD &= 0xF0; //设置定时器模式 TL0 = 0x20; //设置定时初值 TH0 = 0xD1; //设置定时初值 TF0 = 0; //清除TF0标志 TR0 = 1; //定时器0开始计时 } void Timer0Service() interrupt 1 { }
#include "onewire.h"
//单总线内部延时函数
void Delay_OneWire(unsigned int t)
{
t = t * 12;
while(t--);
}
//单总线写操作
void Write_DS18B20(unsigned char dat)
{
unsigned char i;
for(i=0;i<8;i++)
{
DQ = 0;
DQ = dat&0x01;
Delay_OneWire(5);
DQ = 1;
dat >>= 1;
}
Delay_OneWire(5);
}
//单总线读操作
unsigned char Read_DS18B20(void)
{
unsigned char i;
unsigned char dat;
for(i=0;i<8;i++)
{
DQ = 0;
dat >>= 1;
DQ = 1;
if(DQ)
{
dat |= 0x80;
}
Delay_OneWire(5);
}
return dat;
}
//DS18B20初始化
bit init_ds18b20(void)
{
bit initflag = 0;
DQ = 1;
Delay_OneWire(12);
DQ = 0;
Delay_OneWire(80);
DQ = 1;
Delay_OneWire(10);
initflag = DQ;
Delay_OneWire(5);
return initflag;
}
float Get_temp()
{
float temp;
unsigned char hig,low;
init_ds18b20();
Write_DS18B20(0xCC);
Write_DS18B20(0x88);
init_ds18b20();
Write_DS18B20(0xCC);
Write_DS18B20(0xEE);
low = Read_DS18B20();
hig = Read_DS18B20();
temp = (hig<<8|low)*0.0625;
return temp;
}
//temp = (int)Get_temp()
//shi = temp / 10;
1.4 iic.c
#include "iic.h"
#define DELAY_TIME 5
//I2C总线内部延时函数
void IIC_Delay(unsigned char i)
{
do{_nop_();}
while(i--);
}
//I2C总线启动信号
void IIC_Start(void)
{
SD = 1;
SCL = 1;
IIC_Delay(DELAY_TIME);
SD = 0;
IIC_Delay(DELAY_TIME);
SCL = 0;
}
//I2C总线停止信号
void IIC_Stop(void)
{
SD = 0;
SCL = 1;
IIC_Delay(DELAY_TIME);
SD = 1;
IIC_Delay(DELAY_TIME);
}
//发送应答或非应答信号
void IIC_SendAck(bit ackbit)
{
SCL = 0;
SD = ackbit;
IIC_Delay(DELAY_TIME);
SCL = 1;
IIC_Delay(DELAY_TIME);
SCL = 0;
SD = 1;
IIC_Delay(DELAY_TIME);
}
//等待应答
bit IIC_WaitAck(void)
{
bit ackbit;
SCL = 1;
IIC_Delay(DELAY_TIME);
ackbit = SD;
SCL = 0;
IIC_Delay(DELAY_TIME);
return ackbit;
}
//I2C总线发送一个字节数据
void IIC_SendByte(unsigned char byt)
{
unsigned char i;
for(i=0; i<8; i++)
{
SCL = 0;
IIC_Delay(DELAY_TIME);
if(byt & 0x80) SD = 1;
else SD = 0;
IIC_Delay(DELAY_TIME);
SCL = 1;
byt <<= 1;
IIC_Delay(DELAY_TIME);
}
SCL = 0;
}
//I2C总线接收一个字节数据
unsigned char IIC_RecByte(void)
{
unsigned char i, da;
for(i=0; i<8; i++)
{
SCL = 1;
IIC_Delay(DELAY_TIME);
da <<= 1;
if(SD) da |= 1;
SCL = 0;
IIC_Delay(DELAY_TIME);
}
return da;
}
unsigned char Write_ADC(unsigned char add)
{
unsigned char dat;
IIC_Start();
IIC_SendByte(0x90);
IIC_WaitAck();
IIC_SendByte(add);
IIC_WaitAck();
IIC_Start();
IIC_SendByte(0x91);
IIC_WaitAck();
dat = IIC_RecByte();
IIC_SendAck(1);
IIC_Stop();
return dat;
}
void Read_DAC(unsigned char date)
{
IIC_Start();
IIC_SendByte(0x90);
IIC_WaitAck();
IIC_SendByte(0x40);
IIC_WaitAck();
IIC_SendByte(date);
IIC_WaitAck();
IIC_Stop();
}
void EEPROM_write(unsigned char add,unsigned char date)
{
IIC_Start();
IIC_SendByte(0xA0);
IIC_WaitAck();
IIC_SendByte(add);
IIC_WaitAck();
IIC_SendByte(date);
IIC_WaitAck();
IIC_Stop();
IIC_Delay(5);
}
unsigned char EEPROM_read(unsigned char add)
{
unsigned char dat;
IIC_Start();
IIC_SendByte(0xA0);
IIC_WaitAck();
IIC_SendByte(add);
IIC_WaitAck();
IIC_Start();
IIC_SendByte(0xA1);
IIC_WaitAck();
dat = IIC_RecByte();
IIC_SendAck(1);
IIC_Stop();
return dat;
}
1.4 ds1302.c
#include "ds1302.h"
#define DecToBCD(dec) (dec/10*16)+(dec%10)
#define BCDToDec(BCD) (BCD/16*10)+(BCD%16)
//写字节
void Write_Ds1302(unsigned char temp)
{
unsigned char i;
for (i=0;i<8;i++)
{
SCK = 0;
SDA = temp&0x01;
temp>>=1;
SCK=1;
}
}
//向DS1302寄存器写入数据
void Write_Ds1302_Byte( unsigned char address,unsigned char dat )
{
RST=0; _nop_();
SCK=0; _nop_();
RST=1; _nop_();
Write_Ds1302(address);
Write_Ds1302(dat);
RST=0;
}
//从DS1302寄存器读出数据
unsigned char Read_Ds1302_Byte ( unsigned char address )
{
unsigned char i,temp=0x00;
RST=0; _nop_();
SCK=0; _nop_();
RST=1; _nop_();
Write_Ds1302(address);
for (i=0;i<8;i++)
{
SCK=0;
temp>>=1;
if(SDA)
temp|=0x80;
SCK=1;
}
RST=0; _nop_();
SCK=0; _nop_();
SCK=1; _nop_();
SDA=0; _nop_();
SDA=1; _nop_();
return (temp);
}
void Init_DS1302()
{
unsigned char i,add;
add = 0x80;
Write_Ds1302_Byte(0x8E, 0x00);
for(i = 0; i < 7; i++)
{
Write_Ds1302_Byte(add,DecToBCD(shijian[i]));
add = add + 2;
}
}
void Read_DS1302()
{
unsigned char i,add;
add = 0x81;
for(i = 0; i < 7; i++)
{
shijian[i] = BCDToDec(Read_Ds1302_Byte());
add = add + 2;
}
}
二、一些技巧总结
- 共阳数码管,BCD数字-0x80就是带小数点,共阴就是|0x80
- iic和ds1302同时使用时,注意SDA的重复定义
- 底层逻辑代码,一定要多练
- iic:ADC/DAC、EEPROM
- onewire:温度
- ds1302:时钟
- 注意12MHz
- 读温度和iic,的精度,可以用float接
//ds1302用 #define DecToBCD(dec) (dec/10*16)+(dec%10) //十进制转十六进制 #define BCDToDec(BCD) (BCD/16*10)+(BCD%16) //十六进制转十进制
- EEPROM有7个地址,每个地址有8位
对于蓝桥杯,回忆了好多事情,一点一点学吧,真的,只要每天学一点,就可以很厉害,博主是没有买课,各种嫖(比我同学那种买课的,我就像野路子,hhhh~),从学长那嫖的一种网课,加上B站的小蜜蜂。博主也是这样一路学过来,之后开始写省赛题,一开始有畏难心理,之后就慢慢克服了(一定要先自己独立写,一般都可以自己写出来的)。
自己的模板有了,可以用,但考试前一定要多练,多练!,一定要!还要EEPROM、DA/AD,等等小函数,考前也一定要多练!!!
对于买课呢,也挺好,是个正规路子,我同学都90-110不等,所以自己看情况吧
对于这次的比赛呢,超声波模块我是真的没想到,哈哈哈哈哈,直接放弃,别的模块都尽全力去写。
对于客观题呢,看一遍历届赛题吧,虽然感觉没多大用,但是聊胜于无吧,模电数电一定要认真学,还有官方提供的手册,博主也不知道该怎么看,哈哈哈哈,比较菜,客观题好像可以从里面找答案。
如果有时间,我说有时间的话,可以对驱动进行更深度的理解,了解原理。博主之后有时间会再看看
此次蓝桥之后,博主就准备进攻STM32了,应该再学期吧,不知道有没有时间,听说课很多。
