使用stm32f103rct6控制adf4351实现30M~~4G的正弦波

刚开始接触adf4351的时候,发现不知道如何去下手去编写程序,
怎么通过按键去实现控制产生不同的正弦波,
同时通过OLED显示。代码如下:
#include “delay.h”
#include “sys.h”
#include “lcd.h”
#include “touch.h”
#include “gui.h”
#include “test.h”
#include “MS5611.h”
#include “24l01.h”
#include “spi.h”
#include “string.h”
#include “usart.h”
#include “key.h”
#include “ADF4351.h”
void KEY_Init(void);
u8 KEY_Scan(void);
u8 keycount=1;
int sweeptime=0;
int timebai=9;
int timeshi=0;
int timege=0;
int timeyi=0;
extern uint32_t Pressure;
extern uint64_t dT,TEMP;
void LCD_MS5611_DataShow(void);
u8 T[9],P[13];
int key1_flag,key0_flg,keyup_flag;
void ADF4351Init(void);
void ReadToADF4351(u8 count, u8 *buf);
void WriteToADF4351(u8 count, u8 *buf);
void WriteOneRegToADF4351(u32 Regster);
void ADF4351_Init_some(void);
void ADF4351WriteFreq(float Fre);
uint8_t data_buf[9]={0};
u8 tmp_buf[33];
float fre=80;
float frequence=80;
int main(void)
{
SystemInit();
key1_flag=0;key0_flg=0;keyup_flag=0;
delay_init(72);
//delay_ms(1000);
IIC_Init();
delay_ms(100);
KEY_Init();
delay_ms(100);
LCD_Init();
LCD_Clear(WHITE);
LCD_Clear(WHITE);
ADF4351Init();
ADF4351_Init_some();
ADF4351WriteFreq(fre) ;
while(1){
keycount=KEY_Scan();
switch(keycount)
{
case KEY0_PRES:{
LCD_Clear(WHITE);
Gui_StrCenter(0,40,BLUE,YELLOW,“sweep frequence”,16,1);

			key0_flg=key0_flg+1;
		if(key0_flg==2)
		{
			LCD_Clear(WHITE);	
			Gui_StrCenter(0,40,BLUE,YELLOW,"start sweep",16,1);
			while(key0_flg==2)
			{
				frequence=frequence+0.1;
				keycount=KEY_Scan();  
				delay_us(sweeptime);
				if(keycount==1)
				{
					
					key0_flg=key0_flg+1;
					
				}
				if(frequence>110)
				{
					frequence=80;
				}
				ADF4351WriteFreq(frequence)	;
					
			}
			
		key0_flg=0;	
			
		}
		
		
		
		break;}

		case  KEY1_PRES:{
	    LCD_Clear(WHITE);		
			Gui_StrCenter(0,60,BLUE,YELLOW,"dop frequence",16,1);
		  key1_flag=key1_flag+1;
		if(key1_flag==2){
			LCD_Clear(WHITE);	
    Gui_StrCenter(0,60,BLUE,YELLOW,"dop dop",16,1);				
			while((key1_flag==2))
			{
				
				//Gui_StrCenter(0,60,BLUE,YELLOW,"dop dop",16,1);
				keycount=KEY_Scan();  
				if(keycount==1)
				{
					LCD_Clear(WHITE);
					fre=fre+1;
					
					ADF4351WriteFreq(fre)	;
					Gui_StrCenter(0,20,BLUE,YELLOW,"frequence",16,1);			
					LCD_ShowNum(30,50,fre,5,16) ;
				}
				else if(keycount==2)
				{
					 key1_flag=key1_flag+1;
						LCD_Clear(WHITE);	
					
				}
				else if(keycount==3)
				{
					 LCD_Clear(WHITE);
					fre=fre-1;
					if(fre<35){
						fre=35;
						ADF4351WriteFreq(fre)	;
					Gui_StrCenter(0,20,BLUE,YELLOW,"frequence",16,1);			
					LCD_ShowNum(30,50,fre,5,16) ;
					}
					ADF4351WriteFreq(fre)	;
					Gui_StrCenter(0,20,BLUE,YELLOW,"frequence",16,1);			
					LCD_ShowNum(30,50,fre,5,16) ;
				}
				
			}
			key1_flag=0;
		}
		
		break;}
		
		case  WKUP_PRES:{
			LCD_Clear(WHITE);		
			Gui_StrCenter(0,60,BLUE,YELLOW,"step in",16,1);
		  keyup_flag=keyup_flag+1;
			if(keyup_flag==2)
			{
				LCD_Clear(WHITE);		
			Gui_StrCenter(0,60,BLUE,YELLOW,"step step",16,1);
				while(keyup_flag==2)
				{
					
					keycount=KEY_Scan();  
					if(keycount==2)
					{
						LCD_Clear(WHITE);
													timeyi=timeyi+1;
						if(timeyi>2)
						{
						timeyi=0;
						LCD_Clear(WHITE);		
							Gui_StrCenter(0,20,BLUE,YELLOW,"bai wei",16,1);			
							LCD_ShowNum(30,50,timebai,5,16) ;	
						}
						
						else if(timeyi==0)
						{
							LCD_Clear(WHITE);		
							Gui_StrCenter(0,20,BLUE,YELLOW,"bai wei",16,1);			
							LCD_ShowNum(30,50,timebai,5,16) ;
						}
						else if(timeyi==1)
						{
							LCD_Clear(WHITE);		
							Gui_StrCenter(0,20,BLUE,YELLOW,"shi wei",16,1);			
							LCD_ShowNum(30,50,timeshi,5,16) ;
						}
						else if(timeyi==2)
						{
							LCD_Clear(WHITE);		
							Gui_StrCenter(0,20,BLUE,YELLOW,"ge wei",16,1);			
							LCD_ShowNum(30,50,timege,5,16) ;
						}
						sweeptime=sweeptime+timebai*100+timeshi*10+timege;
					}
				else if(keycount==1)
				{
					LCD_Clear(WHITE);
					if(timeyi==0){
						
						timebai=timebai+1;
						if(timebai>9)
						{
							timebai=0;
						}
														LCD_Clear(WHITE);		
							Gui_StrCenter(0,20,BLUE,YELLOW,"bai wei",16,1);			
							LCD_ShowNum(30,50,timebai,5,16) ;	
					}
						else if(timeyi==1){
							
					timeshi=timeshi+1;
							if(timeshi>9)
							{
								timeshi=0;
							}
							LCD_Clear(WHITE);		
							Gui_StrCenter(0,20,BLUE,YELLOW,"shi wei",16,1);			
							LCD_ShowNum(30,50,timeshi,5,16) ;
						}
						
						else if(timeyi==2)
						{
							timege=timege+1;
							if(timege>9)
							{
								timege=0;
								
							}
															LCD_Clear(WHITE);		
							Gui_StrCenter(0,20,BLUE,YELLOW,"ge wei",16,1);			
							LCD_ShowNum(30,50,timege,5,16) ;
						}
					
					sweeptime=sweeptime+timebai*100+timeshi*10+timege;
				}
				else if(keycount==3)
				{
					keyup_flag=keyup_flag+1;
				}
			}
			keyup_flag=0;	
			}
		break;	
		}	  	
	}
 }
}

void LCD_MS5611_DataShow(void)
{
//unsigned char T[9],P[13];

  T[0] = 'T';
  T[1] = ':';
	T[2] = TEMP/1000 + 0x30;
	T[3] = TEMP%1000/100 + 0x30;
	T[4] = '.';
	T[5] = TEMP%100/10 + 0x30;
	T[6] = TEMP%10 + 0x30;
  T[7]='C';
	T[8] = '\0';

	
  P[0] = 'P';
P[1] = ':';
	P[2] = Pressure/100000 + 0x30;
	P[3] = Pressure%100000/10000 + 0x30;
	P[4] = Pressure%10000/1000 + 0x30;
	P[5] = Pressure%1000/100 + 0x30;
	P[6] = '.';
	P[7] = Pressure%100/10 + 0x30;
	P[8] = Pressure%10 + 0x30;
	P[10] = 'p';
	P[11] = 'a';
	P[12] = '\0';
 
	//LCD_ShowString(100,190,200,16,16, P);	

  delay_ms(500);
	LCD_Clear(WHITE);
	Gui_StrCenter(0,28,BLUE,YELLOW,P,16,1);
	Gui_StrCenter(0,60,BLUE,YELLOW,T,16,1);
	

	//printf("	Pressure : %u\r\n\r\n\r\n",Pressure); //´®¿ÚÊä³öԭʼÊý¾Ý

}
u8 KEY_Scan(void)
{
if((KEY00||KEY10||WK_UP1))
{
delay_ms(10);//È¥¶¶¶¯
if(KEY0
0){
delay_ms(100);
while(!KEY0){;}
return KEY0_PRES;
}
else if(KEY1==0){

		if(KEY1==0){
		delay_ms(100);
		while(!KEY1){;}
		
		return KEY1_PRES;
	
}	}
		
	else if(WK_UP==1){
		
		if(WK_UP==1){
		delay_ms(100);
		while(WK_UP){;}
		
		return WKUP_PRES; 
	
}	     
//return 0;// ÎÞ°´¼ü°´ÏÂ

}
}
}
void KEY_Init(void)
{

GPIO_InitTypeDef GPIO_InitStructure;

RCC_APB2PeriphClockCmd(RCC_APB2Periph_GPIOA|RCC_APB2Periph_GPIOC,ENABLE);

GPIO_PinRemapConfig(GPIO_Remap_SWJ_JTAGDisable, ENABLE);
GPIO_InitStructure.GPIO_Pin  = GPIO_Pin_1;//PA15
GPIO_InitStructure.GPIO_Mode = GPIO_Mode_IPU; 
GPIO_Init(GPIOC, &GPIO_InitStructure);
GPIO_InitStructure.GPIO_Pin  = GPIO_Pin_13;//PC5
GPIO_InitStructure.GPIO_Mode = GPIO_Mode_IPU; 
GPIO_Init(GPIOC, &GPIO_InitStructure);
GPIO_InitStructure.GPIO_Pin  = GPIO_Pin_0;//PA0
GPIO_InitStructure.GPIO_Mode = GPIO_Mode_IPD;  
GPIO_Init(GPIOA, &GPIO_InitStructure);

}
主要adf4351初始化代码如下:
void ADF4351Init(void)
{
u8 buf[4] = {0,0,0,0};

ADF_Output_GPIOInit();

buf[3] = 0x00;
buf[2] = 0x58;
buf[1] = 0x00;				//write communication register 0x00580005 to control the progress 
buf[0] = 0x05;				//to write Register 5 to set digital lock detector
WriteToADF4351(4,buf);		

buf[3] = 0x00;
buf[2] = 0xec;				//(DB23=1)The signal is taken from the VCO directly;(DB22-20:4H)the RF divider is 16;(DB19-12:50H)R is 80
buf[1] = 0x80;				//(DB11=0)VCO powerd up;
buf[0] = 0x3C;				//(DB5=1)RF output is enabled;(DB4-3=3H)Output power level is 5
WriteToADF4351(4,buf);		

buf[3] = 0x00;
buf[2] = 0x00;
buf[1] = 0x04;				//(DB14-3:96H)clock divider value is 150.
buf[0] = 0xB3;
WriteToADF4351(4,buf);	

buf[3] = 0x00;
buf[2] = 0x01;				//(DB6=1)set PD polarity is positive;(DB7=1)LDP is 6nS;
buf[1] = 0x0E;				//(DB8=0)enable fractional-N digital lock detect;
buf[0] = 0x42;				//(DB12-9:7H)set Icp 2.50 mA;
WriteToADF4351(4,buf);		//(DB23-14:1H)R counter is 1

buf[3] = 0x00;
buf[2] = 0x00;
buf[1] = 0x80;			   //(DB14-3:6H)MOD counter is 6;
buf[0] = 0x29;			   //(DB26-15:6H)PHASE word is 1,neither the phase resync 
WriteToADF4351(4,buf);	   //nor the spurious optimization functions are being used
						   //(DB27=1)prescaler value is 8/9

buf[3] = 0x00;
buf[2] = 0x2c;
buf[1] = 0x80;
buf[0] = 0x18;				//(DB14-3:0H)FRAC value is 0;
WriteToADF4351(4,buf);		//(DB30-15:140H)INT value is 320;	

}
void ADF4351_Init_some(void)
{
WriteOneRegToADF4351(ADF4351_R2);
WriteOneRegToADF4351(ADF4351_R3);
WriteOneRegToADF4351(ADF4351_R5);
}
adf4351写入频率函数:
void ADF4351WriteFreq(float Fre) // (xx.x) M Hz
{
u16 Fre_temp, N_Mul = 1, Mul_Core = 0;
u16 INT_Fre, Frac_temp, Mod_temp, i;
u32 W_ADF4351_R0 = 0, W_ADF4351_R1 = 0, W_ADF4351_R4 = 0;
float multiple;

if(Fre < 35.0)
	Fre = 35.0;
if(Fre > 4400.0)
	Fre = 4400.0;
Mod_temp = 1000;
Fre = ((float)((u32)(Fre*10)))/10;

Fre_temp = Fre;
for(i = 0; i < 10; i++)
{
	if(((Fre_temp*N_Mul) >= 2199.9) && ((Fre_temp*N_Mul) <= 4400.1))
		break;
	Mul_Core++;
	N_Mul = N_Mul*2;
}

multiple = (Fre*N_Mul)/25;		
INT_Fre = (u16)multiple;
Frac_temp = ((u32)(multiple*1000))%1000;
while(((Frac_temp%5) == 0) && ((Mod_temp%5) == 0))
{
	Frac_temp = Frac_temp/5;
	Mod_temp = Mod_temp/5;
}
while(((Frac_temp%2) == 0)&&((Mod_temp%2) == 0))
{
	Frac_temp = Frac_temp/2;
	Mod_temp = Mod_temp/2;
}
Mul_Core %= 7;
W_ADF4351_R0 = (INT_Fre<<15)+(Frac_temp<<3);
W_ADF4351_R1 = ADF4351_R1_Base + (Mod_temp<<3);
W_ADF4351_R4 = ADF4351_R4_ON + (Mul_Core<<20);
WriteOneRegToADF4351(ADF4351_RF_OFF);
WriteOneRegToADF4351(W_ADF4351_R1);
WriteOneRegToADF4351(W_ADF4351_R0);
WriteOneRegToADF4351(W_ADF4351_R4);

// WriteOneRegToADF4351((u32)(ADF4351_R4_ON + (Mul_Core<<20)));
}

keil工程和代码在如下网址:https://download.csdn.net/download/lsh11111/11926230

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