Maxim Integrated
Maxim Integrated's IoT development kit.
Dependencies: MAX30101 MAX30003 MAX113XX_Pixi MAX30205 max32630fthr USBDevice
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max30003_app.cpp
00001 /* 00002 * max30003_app.c 00003 * 00004 * Created on: Jun 20, 2018 00005 * Author: Mahir.Ozturk 00006 */ 00007 #include <mbed.h> 00008 #include "max30003_app.h" 00009 #include "MAX30003.h" 00010 00011 #define MAX30003_IRQ_ASSERTED_SIGNAL_ID 1 00012 00013 static Thread *thread = 0; 00014 00015 /* ECG FIFO nearly full callback */ 00016 void ecgFIFO_callback() { 00017 if (thread != 0) { 00018 thread->signal_set(MAX30003_IRQ_ASSERTED_SIGNAL_ID); 00019 } 00020 } 00021 00022 void ecg_config(MAX30003& ecgAFE) 00023 { 00024 // Reset ECG to clear registers 00025 ecgAFE.writeRegister( MAX30003::SW_RST , 0); 00026 00027 // General config register setting 00028 MAX30003::GeneralConfiguration_u CNFG_GEN_r; 00029 CNFG_GEN_r.bits.en_ecg = 1; // Enable ECG channel 00030 CNFG_GEN_r.bits.rbiasn = 1; // Enable resistive bias on negative input 00031 CNFG_GEN_r.bits.rbiasp = 1; // Enable resistive bias on positive input 00032 CNFG_GEN_r.bits.en_rbias = 1; // Enable resistive bias 00033 CNFG_GEN_r.bits.imag = 2; // Current magnitude = 10nA 00034 CNFG_GEN_r.bits.en_dcloff = 1; // Enable DC lead-off detection 00035 ecgAFE.writeRegister( MAX30003::CNFG_GEN , CNFG_GEN_r.all); 00036 00037 00038 // ECG Config register setting 00039 MAX30003::ECGConfiguration_u CNFG_ECG_r; 00040 CNFG_ECG_r.bits.dlpf = 1; // Digital LPF cutoff = 40Hz 00041 CNFG_ECG_r.bits.dhpf = 1; // Digital HPF cutoff = 0.5Hz 00042 CNFG_ECG_r.bits.gain = 3; // ECG gain = 160V/V 00043 CNFG_ECG_r.bits.rate = 2; // Sample rate = 128 sps 00044 ecgAFE.writeRegister( MAX30003::CNFG_ECG , CNFG_ECG_r.all); 00045 00046 00047 //R-to-R configuration 00048 MAX30003::RtoR1Configuration_u CNFG_RTOR_r; 00049 CNFG_RTOR_r.bits.wndw = 0b0011; // WNDW = 96ms 00050 CNFG_RTOR_r.bits.rgain = 0b1111; // Auto-scale gain 00051 CNFG_RTOR_r.bits.pavg = 0b11; // 16-average 00052 CNFG_RTOR_r.bits.ptsf = 0b0011; // PTSF = 4/16 00053 CNFG_RTOR_r.bits.en_rtor = 1; // Enable R-to-R detection 00054 ecgAFE.writeRegister( MAX30003::CNFG_RTOR1 , CNFG_RTOR_r.all); 00055 00056 00057 //Manage interrupts register setting 00058 MAX30003::ManageInterrupts_u MNG_INT_r; 00059 MNG_INT_r.bits.efit = 0b00011; // Assert EINT w/ 4 unread samples 00060 MNG_INT_r.bits.clr_rrint = 0b01; // Clear R-to-R on RTOR reg. read back 00061 ecgAFE.writeRegister( MAX30003::MNGR_INT , MNG_INT_r.all); 00062 00063 00064 //Enable interrupts register setting 00065 MAX30003::EnableInterrupts_u EN_INT_r; 00066 EN_INT_r.bits.en_eint = 1; // Enable EINT interrupt 00067 EN_INT_r.bits.en_rrint = 1; // Enable R-to-R interrupt 00068 EN_INT_r.bits.intb_type = 3; // Open-drain NMOS with internal pullup 00069 ecgAFE.writeRegister( MAX30003::EN_INT , EN_INT_r.all); 00070 00071 00072 //Dyanmic modes config 00073 MAX30003::ManageDynamicModes_u MNG_DYN_r; 00074 MNG_DYN_r.bits.fast = 0; // Fast recovery mode disabled 00075 ecgAFE.writeRegister( MAX30003::MNGR_DYN , MNG_DYN_r.all); 00076 00077 // MUX Config 00078 MAX30003::MuxConfiguration_u CNFG_MUX_r; 00079 CNFG_MUX_r.bits.openn = 0; // Connect ECGN to AFE channel 00080 CNFG_MUX_r.bits.openp = 0; // Connect ECGP to AFE channel 00081 ecgAFE.writeRegister( MAX30003::CNFG_EMUX , CNFG_MUX_r.all); 00082 00083 return; 00084 } 00085 00086 void max30003_reader_task(struct max30003_reader_task_args *args) 00087 { 00088 // Constants 00089 const int EINT_STATUS = 1 << 23; 00090 const int RTOR_STATUS = 1 << 10; 00091 const int RTOR_REG_OFFSET = 10; 00092 const float RTOR_LSB_RES = 0.0078125f; 00093 const int FIFO_OVF = 0x7; 00094 const int FIFO_VALID_SAMPLE = 0x0; 00095 const int FIFO_FAST_SAMPLE = 0x1; 00096 const int ETAG_BITS = 0x7; 00097 00098 uint32_t ecgFIFO, RtoR, readECGSamples, ETAG[32], status; 00099 float BPM; 00100 Timer bleNotifyTimer; 00101 00102 thread = args->self; 00103 00104 MAX30003 max30003(args->spiBus, args->spiCS); /* MAX30003WING board */ 00105 00106 InterruptIn ecgFIFO_int(P5_4); // Config P5_4 as int. in for the 00107 ecgFIFO_int.fall(&ecgFIFO_callback); // ecg FIFO almost full interrupt 00108 00109 ecg_config(max30003); // Config ECG 00110 00111 max30003.writeRegister( MAX30003::SYNCH , 0); 00112 00113 bleNotifyTimer.start(); 00114 while (1) { 00115 // Read back ECG samples from the FIFO 00116 thread->signal_wait(MAX30003_IRQ_ASSERTED_SIGNAL_ID); 00117 00118 while (1) { 00119 /* Read back ECG samples from the FIFO */ 00120 status = max30003.readRegister( MAX30003::STATUS ); // Read the STATUS register 00121 00122 if ((status & (RTOR_STATUS | EINT_STATUS)) == 0) { 00123 break; 00124 } 00125 00126 // Check if R-to-R interrupt asserted 00127 if ((status & RTOR_STATUS) == RTOR_STATUS) { 00128 00129 // printf("R-to-R Interrupt \r\n"); 00130 00131 // Read RtoR register 00132 RtoR = max30003.readRegister(MAX30003::RTOR) >> RTOR_REG_OFFSET; 00133 00134 // Convert to BPM 00135 BPM = 1.0f / ( RtoR * RTOR_LSB_RES / 60.0f ); 00136 00137 if (bleNotifyTimer.read_ms() >= (args->notify_period_sec * 1000)) { 00138 printf("BPM: %.2f\r\n", BPM); 00139 bleGattAttrWrite(args->gatt, (uint8_t *)&BPM, sizeof(BPM)); 00140 bleNotifyTimer.reset(); 00141 } 00142 } 00143 00144 // Check if EINT interrupt asserted 00145 if ((status & EINT_STATUS) == EINT_STATUS) { 00146 readECGSamples = 0; // Reset sample counter 00147 00148 do { 00149 ecgFIFO = max30003.readRegister( MAX30003::ECG_FIFO ); // Read FIFO 00150 ETAG[readECGSamples] = ( ecgFIFO >> 3 ) & ETAG_BITS; // Isolate ETAG 00151 readECGSamples++; // Increment sample counter 00152 00153 // Check that sample is not last sample in FIFO 00154 } while (ETAG[readECGSamples-1] == FIFO_VALID_SAMPLE || 00155 ETAG[readECGSamples-1] == FIFO_FAST_SAMPLE); 00156 00157 // Check if FIFO has overflowed 00158 if (ETAG[readECGSamples - 1] == FIFO_OVF){ 00159 max30003.writeRegister( MAX30003::FIFO_RST , 0); // Reset FIFO 00160 } 00161 } 00162 } 00163 } 00164 } 00165 00166
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