STM32驱动MAX30102心率血氧传感器(OLED显示)
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2025年12月25日 09:52
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简介

MAX30102是一个集成的脉搏血氧仪和心率监测仪模块。它包括内部led,光电探测器,光学元件,和低噪声电子与环境光排斥。MAX30102提供了一个完整的系统解决方案,以简化移动和可穿戴设备的设计过程。MAX30102运行在一个1.8V电源和一个单独的3.3V电源上。通信是通过一个标准的i2c兼容的接口。该模块可以通过零备用电流的软件关闭,允许电源轨道始终保持供电。

电气参数

系统框图

MAX30102是一个完整的脉搏血氧仪和心率传感器系统解决方案模块,为可穿戴设备的苛刻要求而设计。该设备保持了一个非常小的解决方案尺寸,而不牺牲光学或电气性能。集成到可穿戴系统中需要最小的外部硬件组件。MAX30102可以通过软件寄存器进行完全可调,并且数字输出数据可以存储在IC内的一个32深的FIFO中。FIFO允许MAX30102连接到共享总线上的微控制器或处理器,在其中,数据不会从MAX30102的寄存器中连续读取。MAX30102有一个片上的温度传感器,用于校准SpO2子系统的温度依赖性。该温度传感器的固有分辨率0.0625°C。器件输出数据对红外LED的波长相对不敏感,其中红色LED的波长对正确解释数据至关重要。与MAX30102输出信号一起使用的SpO2算法可以补偿环境温度变化时的相关SpO2误差。

接线

代码

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#include "led.h"

#include "delay.h"

#include "sys.h"

#include "usart.h"

#include "max30102.h" 

#include "myiic.h"

#include "algorithm.h"

#include "oled.h"



uint32_t aun_ir_buffer[500]; //IR LED sensor data

int32_t n_ir_buffer_length;    //data length

uint32_t aun_red_buffer[500];    //Red LED sensor data

int32_t n_sp02; //SPO2 value

int8_t ch_spo2_valid;   //indicator to show if the SP02 calculation is valid

int32_t n_heart_rate;   //heart rate value

int8_t  ch_hr_valid;    //indicator to show if the heart rate calculation is valid

uint8_t uch_dummy;



#define MAX_BRIGHTNESS 255



void dis_DrawCurve(u32* data,u8 x);



int main(void)

{ 

//variables to calculate the on-board LED brightness that reflects the heartbeats

uint32_t un_min, un_max, un_prev_data;  

int i;

int32_t n_brightness;

float f_temp;

u8 temp_num=0;

u8 temp[6];

u8 str[100];

u8 dis_hr=0,dis_spo2=0;



NVIC_Configuration();

delay_init();     //延时函数初始化   

uart_init(115200); //串口初始化为115200

LED_Init();



//OLED

OLED_Init();

OLED_ShowString(0,0,"  initializing  ",16);

OLED_Refresh_Gram();//更新显示到OLED  



max30102_init();



printf("\r\n MAX30102  init  \r\n");



un_min=0x3FFFF;

un_max=0;



n_ir_buffer_length=500; //buffer length of 100 stores 5 seconds of samples running at 100sps

//read the first 500 samples, and determine the signal range

    for(i=0;i<n_ir_buffer_length;i++)

    {

        while(MAX30102_INT==1);   //wait until the interrupt pin asserts

        

max30102_FIFO_ReadBytes(REG_FIFO_DATA,temp);

aun_red_buffer[i] =  (long)((long)((long)temp[0]&0x03)<<16) | (long)temp[1]<<8 | (long)temp[2];    // Combine values to get the actual number

aun_ir_buffer[i] = (long)((long)((long)temp[3] & 0x03)<<16) |(long)temp[4]<<8 | (long)temp[5];   // Combine values to get the actual number

            

        if(un_min>aun_red_buffer[i])

            un_min=aun_red_buffer[i];    //update signal min

        if(un_max<aun_red_buffer[i])

            un_max=aun_red_buffer[i];    //update signal max

    }

un_prev_data=aun_red_buffer[i];

//calculate heart rate and SpO2 after first 500 samples (first 5 seconds of samples)

    maxim_heart_rate_and_oxygen_saturation(aun_ir_buffer, n_ir_buffer_length, aun_red_buffer, &n_sp02, &ch_spo2_valid, &n_heart_rate, &ch_hr_valid); 



while(1)

{

i=0;

        un_min=0x3FFFF;

        un_max=0;



//dumping the first 100 sets of samples in the memory and shift the last 400 sets of samples to the top

        for(i=100;i<500;i++)

        {

            aun_red_buffer[i-100]=aun_red_buffer[i];

            aun_ir_buffer[i-100]=aun_ir_buffer[i];

            

            //update the signal min and max

            if(un_min>aun_red_buffer[i])

            un_min=aun_red_buffer[i];

            if(un_max<aun_red_buffer[i])

            un_max=aun_red_buffer[i];

        }

//take 100 sets of samples before calculating the heart rate.

        for(i=400;i<500;i++)

        {

            un_prev_data=aun_red_buffer[i-1];

            while(MAX30102_INT==1);

            max30102_FIFO_ReadBytes(REG_FIFO_DATA,temp);

aun_red_buffer[i] =  (long)((long)((long)temp[0]&0x03)<<16) | (long)temp[1]<<8 | (long)temp[2];    // Combine values to get the actual number

aun_ir_buffer[i] = (long)((long)((long)temp[3] & 0x03)<<16) |(long)temp[4]<<8 | (long)temp[5];   // Combine values to get the actual number

        

            if(aun_red_buffer[i]>un_prev_data)

            {

                f_temp=aun_red_buffer[i]-un_prev_data;

                f_temp/=(un_max-un_min);

                f_temp*=MAX_BRIGHTNESS;

                n_brightness-=(int)f_temp;

                if(n_brightness<0)

                    n_brightness=0;

            }

            else

            {

                f_temp=un_prev_data-aun_red_buffer[i];

                f_temp/=(un_max-un_min);

                f_temp*=MAX_BRIGHTNESS;

                n_brightness+=(int)f_temp;

                if(n_brightness>MAX_BRIGHTNESS)

                    n_brightness=MAX_BRIGHTNESS;

            }

//send samples and calculation result to terminal program through UART

if(ch_hr_valid == 1 && n_heart_rate<120)//**/ ch_hr_valid == 1 && ch_spo2_valid ==1 && n_heart_rate<120 && n_sp02<101

{

dis_hr = n_heart_rate;

dis_spo2 = n_sp02;

}

else

{

dis_hr = 0;

dis_spo2 = 0;

}

printf("HR=%i, ", n_heart_rate); 

printf("HRvalid=%i, ", ch_hr_valid);

printf("SpO2=%i, ", n_sp02);

printf("SPO2Valid=%i\r\n", ch_spo2_valid);

}

        maxim_heart_rate_and_oxygen_saturation(aun_ir_buffer, n_ir_buffer_length, aun_red_buffer, &n_sp02, &ch_spo2_valid, &n_heart_rate, &ch_hr_valid);



//显示刷新

LED0=0;

if(dis_hr == 0 && dis_spo2 == 0)  //**dis_hr == 0 && dis_spo2 == 0

{

sprintf((char *)str,"HR:--- SpO2:--- ");//**HR:--- SpO2:--- 

}

else{

sprintf((char *)str,"HR:%3d SpO2:%3d ",dis_hr,dis_spo2);//**HR:%3d SpO2:%3d 

}

OLED_ShowString(0,0,str,16);

OLED_Fill(0,23,127,63,0);

//红光在上,红外在下

dis_DrawCurve(aun_red_buffer,20);

dis_DrawCurve(aun_ir_buffer,0);

OLED_Refresh_Gram();//更新显示到OLED  

}

}



void dis_DrawCurve(u32* data,u8 x)

{

u16 i;

u32 max=0,min=262144;

u32 temp;

u32 compress;



for(i=0;i<128*2;i++)

{

if(data[i]>max)

{

max = data[i];

}

if(data[i]<min)

{

min = data[i];

}

}



compress = (max-min)/20;



for(i=0;i<128;i++)

{

temp = data[i*2] + data[i*2+1];

temp/=2;

temp -= min;

temp/=compress;

if(temp>20)temp=20;

OLED_DrawPoint(i,63-x-temp,1);

}

} 
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结果

总结

手指放置红色LED上,OLED上会显示心率、血氧值,并且还有波形显示,刚开始数值和波形会有些波动,静置几秒后,数值和波形方可稳定。