电子模块|心率血氧传感器模块MAX30102及其驱动代码

电子模块|心率血氧传感器模块MAX30102及其驱动代码

• 实物照片
• 模块简介
• 工作原理
• 原理图及引脚说明
• STM32软件驱动
• • IIC通信代码
  • 数值转换代码
  • main函数
  • 结果

    实物照片

    

    

    模块简介

    MAX30102是一个集成的脉搏血氧仪和心率监测仪生物传感器的模块。

    它集成了一个红光LED和一个红外光LED、光电检测器、光器件，以及带环境光抑制的低噪声电子电路。

    MAX30102采用一个1.8V电源和一个独立的5.0V用于内部LED的电源，应用于可穿戴设备进行心率和血氧采集检测，佩戴于手指点耳垂和手腕处。

    标准的I2C兼容的通信接口可以将采集到的数值传输给Arduino、KL25Z、STM32、STC51等单片机进行心率和血氧计算。

    此外，该芯片还可以通过软件关断模块，待机电流接近为零，实现电源始终维持供电状态。

    主要参数:

    产品名称	MAX30102 心率模块
    LED峰值波长器	660nm/880nm
    LED供电电压	3.3 ~ 5V
    检测信号类型	光反射信号（PPG）
    输出信号接口	I2C接口
    通信接口电压	1.8 ~ 3.3V ~ 5V（可选）

    产品尺寸：

    

    工作原理

    光溶积法：利用人体组织在血管搏动时造成透光率不同来进行脉搏和血氧饱和度测量

    光源：采用对动脉血中痒合血红蛋白（HbO2）和血红蛋白（Hb）有选择性的特定波长的发光二极管

    透光率转化为电信号：动脉搏动充血容积变化导致这束光的透光率发送改变，此时由光电变换接收经人体组织反射光线，转变为电信号并将其放大输出。

    

    原理图及引脚说明

    

    

    引脚说明

    名称	管教定义
    VIN	电源输入 1.6V-5.5V
    3位焊盘	选择总线的上拉电平，取决于引脚主控电压可选1.8v或者3.3v
    SDA	IIC-SDA
    SCL	IIC-SCL
    GND	地
    INT	INT 低电平有效中断（漏极开路）MAX30102 的中断引脚
    IRD	IR_DRV IR LED阴极和LED驱动器连接点 一般不接
    RD	R_DRV 红色LED阴极和LED驱动器连接点 一般不接

    STM32软件驱动

    使用STM32F103C8T6最小系统开发板验证。

    接线如下：

    MAX30102模块接口：PB9-SDA,PB8-SCL,PB7-INT

    PA2/PA3为串口传输口TX和RX，波特率设置为115200

    PC13为显示LED

    IIC通信代码

    #include "mbed.h"
    #include "MAX30102.h"
    I2C i2c(I2C_SDA, I2C_SCL);//SDA-PB9,SCL-PB8
    bool maxim_max30102_write_reg(uint8_t uch_addr, uint8_t uch_data)
    /**
    * \brief        Write a value to a MAX30102 register
    * \par          Details
    *               This function writes a value to a MAX30102 register
    *
    * \param[in]    uch_addr    - register address
    * \param[in]    uch_data    - register data
    *
    * \retval       true on success
    */
    {
      char ach_i2c_data[2];
      ach_i2c_data[0]=uch_addr;
      ach_i2c_data[1]=uch_data;
      
      if(i2c.write(I2C_WRITE_ADDR, ach_i2c_data, 2, false)==0)
        return true;
      else
        return false;
    }
    bool maxim_max30102_read_reg(uint8_t uch_addr, uint8_t *puch_data)
    /**
    * \brief        Read a MAX30102 register
    * \par          Details
    *               This function reads a MAX30102 register
    *
    * \param[in]    uch_addr    - register address
    * \param[out]   puch_data    - pointer that stores the register data
    *
    * \retval       true on success
    */
    {
      char ch_i2c_data;
      ch_i2c_data=uch_addr;
      if(i2c.write(I2C_WRITE_ADDR, &ch_i2c_data, 1, true)!=0)
        return false;
      if(i2c.read(I2C_READ_ADDR, &ch_i2c_data, 1, false)==0)
      {
        *puch_data=(uint8_t) ch_i2c_data;
        return true;
      }
      else
        return false;
    }
    bool maxim_max30102_init()
    /**
    * \brief        Initialize the MAX30102
    * \par          Details
    *               This function initializes the MAX30102
    *
    * \param        None
    *
    * \retval       true on success
    */
    {
      if(!maxim_max30102_write_reg(REG_INTR_ENABLE_1,0xc0)) // INTR setting
        return false;
      if(!maxim_max30102_write_reg(REG_INTR_ENABLE_2,0x00))
        return false;
      if(!maxim_max30102_write_reg(REG_FIFO_WR_PTR,0x00))  //FIFO_WR_PTR[4:0]
        return false;
      if(!maxim_max30102_write_reg(REG_OVF_COUNTER,0x00))  //OVF_COUNTER[4:0]
        return false;
      if(!maxim_max30102_write_reg(REG_FIFO_RD_PTR,0x00))  //FIFO_RD_PTR[4:0]
        return false;
      if(!maxim_max30102_write_reg(REG_FIFO_CONFIG,0x0f))  //sample avg = 1, fifo rollover=false, fifo almost full = 17
        return false;
      if(!maxim_max30102_write_reg(REG_MODE_CONFIG,0x03))   //0x02 for Red only, 0x03 for SpO2 mode 0x07 multimode LED
        return false;
      if(!maxim_max30102_write_reg(REG_SPO2_CONFIG,0x27))  // SPO2_ADC range = 4096nA, SPO2 sample rate (100 Hz), LED pulseWidth (400uS)
        return false;
      
      if(!maxim_max30102_write_reg(REG_LED1_PA,0x24))   //Choose value for ~ 7mA for LED1
        return false;
      if(!maxim_max30102_write_reg(REG_LED2_PA,0x24))   // Choose value for ~ 7mA for LED2
        return false;
      if(!maxim_max30102_write_reg(REG_PILOT_PA,0x7f))   // Choose value for ~ 25mA for Pilot LED
        return false;
      return true;  
    }
    bool maxim_max30102_read_fifo(uint32_t *pun_red_led, uint32_t *pun_ir_led)
    /**
    * \brief        Read a set of samples from the MAX30102 FIFO register
    * \par          Details
    *               This function reads a set of samples from the MAX30102 FIFO register
    *
    * \param[out]   *pun_red_led   - pointer that stores the red LED reading data
    * \param[out]   *pun_ir_led    - pointer that stores the IR LED reading data
    *
    * \retval       true on success
    */
    {
      uint32_t un_temp;
      unsigned char uch_temp;
      *pun_red_led=0;
      *pun_ir_led=0;
      char ach_i2c_data[6];
      
      //read and clear status register
      maxim_max30102_read_reg(REG_INTR_STATUS_1, &uch_temp);
      maxim_max30102_read_reg(REG_INTR_STATUS_2, &uch_temp);
      
      ach_i2c_data[0]=REG_FIFO_DATA;
      if(i2c.write(I2C_WRITE_ADDR, ach_i2c_data, 1, true)!=0)
        return false;
      if(i2c.read(I2C_READ_ADDR, ach_i2c_data, 6, false)!=0)
      {
        return false;
      }
      un_temp=(unsigned char) ach_i2c_data[0];
      un_temp<<=16;
      *pun_red_led+=un_temp;
      un_temp=(unsigned char) ach_i2c_data[1];
      un_temp<<=8;
      *pun_red_led+=un_temp;
      un_temp=(unsigned char) ach_i2c_data[2];
      *pun_red_led+=un_temp;
      
      un_temp=(unsigned char) ach_i2c_data[3];
      un_temp<<=16;
      *pun_ir_led+=un_temp;
      un_temp=(unsigned char) ach_i2c_data[4];
      un_temp<<=8;
      *pun_ir_led+=un_temp;
      un_temp=(unsigned char) ach_i2c_data[5];
      *pun_ir_led+=un_temp;
      *pun_red_led&=0x03FFFF;  //Mask MSB [23:18]
      *pun_ir_led&=0x03FFFF;  //Mask MSB [23:18]
      
      
      return true;
    }
    bool maxim_max30102_reset()
    /**
    * \brief        Reset the MAX30102
    * \par          Details
    *               This function resets the MAX30102
    *
    * \param        None
    *
    * \retval       true on success
    */
    {
        if(!maxim_max30102_write_reg(REG_MODE_CONFIG,0x40))
            return false;
        else
            return true;    
    }
    

    数值转换代码

    #include "algorithm.h"
    #include "mbed.h"
    void maxim_heart_rate_and_oxygen_saturation(uint32_t *pun_ir_buffer,  int32_t n_ir_buffer_length, uint32_t *pun_red_buffer, int32_t *pn_spo2, int8_t *pch_spo2_valid, 
                                  int32_t *pn_heart_rate, int8_t  *pch_hr_valid)
    /**
    * \brief        Calculate the heart rate and SpO2 level
    * \par          Details
    *               By detecting  peaks of PPG cycle and corresponding AC/DC of red/infra-red signal, the ratio for the SPO2 is computed.
    *               Since this algorithm is aiming for Arm M0/M3. formaula for SPO2 did not achieve the accuracy due to register overflow.
    *               Thus, accurate SPO2 is precalculated and save longo uch_spo2_table[] per each ratio.
    *
    * \param[in]    *pun_ir_buffer           - IR sensor data buffer
    * \param[in]    n_ir_buffer_length      - IR sensor data buffer length
    * \param[in]    *pun_red_buffer          - Red sensor data buffer
    * \param[out]    *pn_spo2                - Calculated SpO2 value
    * \param[out]    *pch_spo2_valid         - 1 if the calculated SpO2 value is valid
    * \param[out]    *pn_heart_rate          - Calculated heart rate value
    * \param[out]    *pch_hr_valid           - 1 if the calculated heart rate value is valid
    *
    * \retval       None
    */
    {
        uint32_t un_ir_mean ,un_only_once ;
        int32_t k ,n_i_ratio_count;
        int32_t i, s, m, n_exact_ir_valley_locs_count ,n_middle_idx;
        int32_t n_th1, n_npks,n_c_min;      
        int32_t an_ir_valley_locs[15] ;
        int32_t an_exact_ir_valley_locs[15] ;
        int32_t an_dx_peak_locs[15] ;
        int32_t n_peak_interval_sum;
        
        int32_t n_y_ac, n_x_ac;
        int32_t n_spo2_calc; 
        int32_t n_y_dc_max, n_x_dc_max; 
        int32_t n_y_dc_max_idx, n_x_dc_max_idx; 
        int32_t an_ratio[5],n_ratio_average; 
        int32_t n_nume,  n_denom ;
        // remove DC of ir signal    
        un_ir_mean =0; 
        for (k=0 ; k
            n_denom= ( an_x[k]+an_x[k+1]+ an_x[k+2]+ an_x[k+3]);
            an_x[k]=  n_denom/(int32_t)4; 
        }
        // get difference of smoothed IR signal
        
        for( k=0; k
            an_dx[k] =  ( an_dx[k]+an_dx[k+1])/2 ;
        }
        
        // hamming window
        // flip wave form so that we can detect valley with peak detector
        for ( i=0 ; i
            s= 0;
            for( k=i; k
                s -= an_dx[k] *auw_hamm[k-i] ; 
                         }
            an_dx[i]= s/ (int32_t)1146; // divide by sum of auw_hamm 
        }
     
        n_th1=0; // threshold calculation
        for ( k=0 ; k
            n_th1 += ((an_dx[k]>0)? an_dx[k] : ((int32_t)0-an_dx[k])) ;
        }
        n_th1= n_th1/ ( BUFFER_SIZE-HAMMING_SIZE);
        // peak location is acutally index for sharpest location of raw signal since we flipped the signal         
        maxim_find_peaks( an_dx_peak_locs, &n_npks, an_dx, BUFFER_SIZE-HAMMING_SIZE, n_th1, 8, 5 );//peak_height, peak_distance, max_num_peaks 
        n_peak_interval_sum =0;
        if (n_npks>=2){
            for (k=1; k
            *pn_heart_rate = -999;
            *pch_hr_valid  = 0;
        }
                
        for ( k=0 ; k
            an_x[k] =  pun_ir_buffer[k] ; 
            an_y[k] =  pun_red_buffer[k] ; 
        }
        // find precise min near an_ir_valley_locs
        n_exact_ir_valley_locs_count =0; 
        for(k=0 ; k
            un_only_once =1;
            m=an_ir_valley_locs[k];
            n_c_min= 16777216;//2^24;
            if (m+5 <  BUFFER_SIZE-HAMMING_SIZE  && m-5 >0){
                for(i= m-5;i
                        if (un_only_once >0){
                           un_only_once =0;
                       } 
                       n_c_min= an_x[i] ;
                       an_exact_ir_valley_locs[k]=i;
                    }
                if (un_only_once ==0)
                    n_exact_ir_valley_locs_count ++ ;
            }
        }
        if (n_exact_ir_valley_locs_count <2 ){
           *pn_spo2 =  -999 ; // do not use SPO2 since signal ratio is out of range
           *pch_spo2_valid  = 0; 
           return;
        }
        // 4 pt MA
        for(k=0; k< BUFFER_SIZE-MA4_SIZE; k++){
            an_x[k]=( an_x[k]+an_x[k+1]+ an_x[k+2]+ an_x[k+3])/(int32_t)4;
            an_y[k]=( an_y[k]+an_y[k+1]+ an_y[k+2]+ an_y[k+3])/(int32_t)4;
        }
        //using an_exact_ir_valley_locs , find ir-red DC andir-red AC for SPO2 calibration ratio
        //finding AC/DC maximum of raw ir * red between two valley locations
        n_ratio_average =0; 
        n_i_ratio_count =0; 
        
        for(k=0; k< 5; k++) an_ratio[k]=0;
        for (k=0; k< n_exact_ir_valley_locs_count; k++){
            if (an_exact_ir_valley_locs[k] > BUFFER_SIZE ){             
                *pn_spo2 =  -999 ; // do not use SPO2 since valley loc is out of range
                *pch_spo2_valid  = 0; 
                return;
            }
        }
        // find max between two valley locations 
        // and use ratio betwen AC compoent of Ir & Red and DC compoent of Ir & Red for SPO2 
        for (k=0; k< n_exact_ir_valley_locs_count-1; k++){
            n_y_dc_max= -16777216 ; 
            n_x_dc_max= - 16777216; 
            if (an_exact_ir_valley_locs[k+1]-an_exact_ir_valley_locs[k] >10){
                for (i=an_exact_ir_valley_locs[k]; i< an_exact_ir_valley_locs[k+1]; i++){
                    if (an_x[i]> n_x_dc_max) {n_x_dc_max =an_x[i];n_x_dc_max_idx =i; }
                    if (an_y[i]> n_y_dc_max) {n_y_dc_max =an_y[i];n_y_dc_max_idx=i;}
                }
                n_y_ac= (an_y[an_exact_ir_valley_locs[k+1]] - an_y[an_exact_ir_valley_locs[k] ] )*(n_y_dc_max_idx -an_exact_ir_valley_locs[k]); //red
                n_y_ac=  an_y[an_exact_ir_valley_locs[k]] + n_y_ac/ (an_exact_ir_valley_locs[k+1] - an_exact_ir_valley_locs[k])  ; 
            
            
                n_y_ac=  an_y[n_y_dc_max_idx] - n_y_ac;    // subracting linear DC compoenents from raw 
                n_x_ac= (an_x[an_exact_ir_valley_locs[k+1]] - an_x[an_exact_ir_valley_locs[k] ] )*(n_x_dc_max_idx -an_exact_ir_valley_locs[k]); // ir
                n_x_ac=  an_x[an_exact_ir_valley_locs[k]] + n_x_ac/ (an_exact_ir_valley_locs[k+1] - an_exact_ir_valley_locs[k]); 
                n_x_ac=  an_x[n_y_dc_max_idx] - n_x_ac;      // subracting linear DC compoenents from raw 
                n_nume=( n_y_ac *n_x_dc_max)>>7 ; //prepare X100 to preserve floating value
                n_denom= ( n_x_ac *n_y_dc_max)>>7;
                if (n_denom>0  && n_i_ratio_count <5 &&  n_nume != 0)
                {   
                    an_ratio[n_i_ratio_count]= (n_nume*100)/n_denom ; //formular is ( n_y_ac *n_x_dc_max) / ( n_x_ac *n_y_dc_max) ;
                    n_i_ratio_count++;
                }
            }
        }
        maxim_sort_ascend(an_ratio, n_i_ratio_count);
        n_middle_idx= n_i_ratio_count/2;
        if (n_middle_idx >1)
            n_ratio_average =( an_ratio[n_middle_idx-1] +an_ratio[n_middle_idx])/2; // use median
        else
            n_ratio_average = an_ratio[n_middle_idx ];
        if( n_ratio_average>2 && n_ratio_average <184){
            n_spo2_calc= uch_spo2_table[n_ratio_average] ;
            *pn_spo2 = n_spo2_calc ;
            *pch_spo2_valid  = 1;//  float_SPO2 =  -45.060*n_ratio_average* n_ratio_average/10000 + 30.354 *n_ratio_average/100 + 94.845 ;  // for comparison with table
        }
        else{
            *pn_spo2 =  -999 ; // do not use SPO2 since signal ratio is out of range
            *pch_spo2_valid  = 0; 
        }
    }
    void maxim_find_peaks(int32_t *pn_locs, int32_t *pn_npks, int32_t *pn_x, int32_t n_size, int32_t n_min_height, int32_t n_min_distance, int32_t n_max_num)
    /**
    * \brief        Find peaks
    * \par          Details
    *               Find at most MAX_NUM peaks above MIN_HEIGHT separated by at least MIN_DISTANCE
    *
    * \retval       None
    */
    {
        maxim_peaks_above_min_height( pn_locs, pn_npks, pn_x, n_size, n_min_height );
        maxim_remove_close_peaks( pn_locs, pn_npks, pn_x, n_min_distance );
        *pn_npks = min( *pn_npks, n_max_num );
    }
    void maxim_peaks_above_min_height(int32_t *pn_locs, int32_t *pn_npks, int32_t  *pn_x, int32_t n_size, int32_t n_min_height)
    /**
    * \brief        Find peaks above n_min_height
    * \par          Details
    *               Find all peaks above MIN_HEIGHT
    *
    * \retval       None
    */
    {
        int32_t i = 1, n_width;
        *pn_npks = 0;
        
        while (i < n_size-1){
            if (pn_x[i] > n_min_height && pn_x[i] > pn_x[i-1]){            // find left edge of potential peaks
                n_width = 1;
                while (i+n_width < n_size && pn_x[i] == pn_x[i+n_width])    // find flat peaks
                    n_width++;
                if (pn_x[i] > pn_x[i+n_width] && (*pn_npks) < 15 ){                            // find right edge of peaks
                    pn_locs[(*pn_npks)++] = i;        
                    // for flat peaks, peak location is left edge
                    i += n_width+1;
                }
                else
                    i += n_width;
            }
            else
                i++;
        }
    }
    void maxim_remove_close_peaks(int32_t *pn_locs, int32_t *pn_npks, int32_t *pn_x, int32_t n_min_distance)
    /**
    * \brief        Remove peaks
    * \par          Details
    *               Remove peaks separated by less than MIN_DISTANCE
    *
    * \retval       None
    */
    {
        
        int32_t i, j, n_old_npks, n_dist;
        
        /* Order peaks from large to small */
        maxim_sort_indices_descend( pn_x, pn_locs, *pn_npks );
        for ( i = -1; i < *pn_npks; i++ ){
            n_old_npks = *pn_npks;
            *pn_npks = i+1;
            for ( j = i+1; j < n_old_npks; j++ ){
                n_dist =  pn_locs[j] - ( i == -1 ? -1 : pn_locs[i] ); // lag-zero peak of autocorr is at index -1
                if ( n_dist > n_min_distance || n_dist < -n_min_distance )
                    pn_locs[(*pn_npks)++] = pn_locs[j];
            }
        }
        // Resort indices longo ascending order
        maxim_sort_ascend( pn_locs, *pn_npks );
    }
    void maxim_sort_ascend(int32_t *pn_x,int32_t n_size) 
    /**
    * \brief        Sort array
    * \par          Details
    *               Sort array in ascending order (insertion sort algorithm)
    *
    * \retval       None
    */
    {
        int32_t i, j, n_temp;
        for (i = 1; i < n_size; i++) {
            n_temp = pn_x[i];
            for (j = i; j > 0 && n_temp < pn_x[j-1]; j--)
                pn_x[j] = pn_x[j-1];
            pn_x[j] = n_temp;
        }
    }
    void maxim_sort_indices_descend(int32_t *pn_x, int32_t *pn_indx, int32_t n_size)
    /**
    * \brief        Sort indices
    * \par          Details
    *               Sort indices according to descending order (insertion sort algorithm)
    *
    * \retval       None
    */ 
    {
        int32_t i, j, n_temp;
        for (i = 1; i < n_size; i++) {
            n_temp = pn_indx[i];
            for (j = i; j > 0 && pn_x[n_temp] > pn_x[pn_indx[j-1]]; j--)
                pn_indx[j] = pn_indx[j-1];
            pn_indx[j] = n_temp;
        }
    }
    

    main函数

    #include "stm32f103c8t6.h"
    #include "mbed.h"
    #include "algorithm.h"
    #include "MAX30102.h"
    #define MAX_BRIGHTNESS 255
    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;
    Serial pc(SERIAL_TX, SERIAL_RX);    //initializes the serial port, TX-PA2, RX-PA3
    PwmOut pwmled(PB_3);  //initializes the pwm output PB3 that connects to the LED
    DigitalIn INT(PB_7);  //pin PB7 connects to the interrupt output pin of the MAX30102
    DigitalOut led(PC_13); //PC13 connects to the on board user LED
    // the setup routine runs once when you press reset:
    int main() { 
        uint32_t un_min, un_max, un_prev_data;  //variables to calculate the on-board LED brightness that reflects the heartbeats
        int i;
        int32_t n_brightness;
        float f_temp;
        
        maxim_max30102_reset(); //resets the MAX30102
        // initialize serial communication at 115200 bits per second:
        pc.baud(115200);
        pc.format(8,SerialBase::None,1);
        wait(1);
        
        //read and clear status register
        maxim_max30102_read_reg(0,&uch_dummy);
        
        //wait until the user presses a key
    //    while(pc.readable()==0)
    //    {
    //        pc.printf("\x1B[2J");  //clear terminal program screen
    //        pc.printf("Press any key to start conversion\n\r");
    //        wait(1);
    //    }
    //    uch_dummy=getchar();
        
        maxim_max30102_init();  //initializes the MAX30102
            
            
        n_brightness=0;
        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
            while(INT.read()==1);   //wait until the interrupt pin asserts
            
            maxim_max30102_read_fifo((aun_red_buffer+i), (aun_ir_buffer+i));  //read from MAX30102 FIFO
                
            if(un_min>aun_red_buffer[i])
                un_min=aun_red_buffer[i];    //update signal min
            if(un_max
            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
                un_prev_data=aun_red_buffer[i-1];
                while(INT.read()==1);
                maxim_max30102_read_fifo((aun_red_buffer+i), (aun_ir_buffer+i));
            
                if(aun_red_buffer[i]>un_prev_data)//just to determine the brightness of LED according to the deviation of adjacent two AD 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;
                }
                pwmled.write(1-(float)n_brightness/256);//pwm control led brightness
    						if(n_brightness<120)
    							led=1;
    						else
    							led=0;
                //send samples and calculation result to terminal program through UART
                pc.printf("red=");
                pc.printf("%i", aun_red_buffer[i]);
                pc.printf(", ir=");
                pc.printf("%i", aun_ir_buffer[i]);
                pc.printf(", HR=%i, ", n_heart_rate); 
                pc.printf("HRvalid=%i, ", ch_hr_valid);
                pc.printf("SpO2=%i, ", n_sp02);
                pc.printf("SPO2Valid=%i\n\r", 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); 
        }
    }
    

    结果

    将输出数据转成曲线