Host software for the MAX30001 ECG, PACE, biopotential, bioimpedance, R-to-R peak sensor. Hosted on the MAX32630FTHR.
Dependencies: SDFileSystem USBDevice max32630fthr
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MAX30001-MAX32630FTHR ECG Evaluation System
The MAX30001 EVKIT SYS-MBED Evaluation System (EV System) is used to evaluates the MAX30001 sensor, which is an ECG (electrocardiogram), biopotential and bioimpedance analog front end solution for wearable applications. The full evaluation system consists of the MAX32630FTHR board, MAX30001 EVKIT sensor board and the evaluation software. The evaluation kit features ECG, PACE, R-to-R (R-peak timing) detection; bioimpedance (BioZ) AFE; and raw data logging.
The MAX30001 EVKIT evaluation system is assembled, tested and contains the necessary circuitry and connections to evaluate the MAX30001 ECG sensor.
When evaluated as an evaluation system, the MAX32630FTHR board provides the necessary logic rails, master clock, SPI, USB-to-Serial interfaces that are needed to evaluate the MAX30001 sensor board. MAX32630FTHR can be used as an independent development platform.
Communication between the PC and the MAX32630FTHR board is facilitated by a Windows 7, Windows 8 and Windows 10 compatible software that provides a simple and intuitive graphical user interface (GUI).
For more information, visit the wiki pages by clicking the wiki tab above and MAX30001EVSYS product page.
C++ source code, library for the MAX30001 ECG drivers are in the links at the bottom of this page. The sample code includes the ability to log data to the SD card of the MAX32630FTHR.
MAX30001 EVKIT Pinout Connections
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HSP/Devices/MAX30001/MAX30001_RPC.cpp
- Committer:
- Emre.Eken@IST-LT-35101.maxim-ic.internal
- Date:
- 2018-04-05
- Revision:
- 0:8e4630a71eb1
File content as of revision 0:8e4630a71eb1:
/******************************************************************************* * Copyright (C) 2016 Maxim Integrated Products, Inc., All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL MAXIM INTEGRATED BE LIABLE FOR ANY CLAIM, DAMAGES * OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. * * Except as contained in this notice, the name of Maxim Integrated * Products, Inc. shall not be used except as stated in the Maxim Integrated * Products, Inc. Branding Policy. * * The mere transfer of this software does not imply any licenses * of trade secrets, proprietary technology, copyrights, patents, * trademarks, maskwork rights, or any other form of intellectual * property whatsoever. Maxim Integrated Products, Inc. retains all * ownership rights. ******************************************************************************* */ #include <stdio.h> #include "StringHelper.h" #include "MAX30001.h" #include "Streaming.h" #include "StringInOut.h" #include "MAX30001_helper.h" #include "RpcFifo.h" #include "RpcServer.h" #include "Peripherals.h" #include "DataLoggingService.h" int highDataRate = 0; uint32_t max30001_RegRead(MAX30001::MAX30001_REG_map_t addr) { uint32_t data; Peripherals::max30001()->max30001_reg_read(addr, &data); return data; } void max30001_RegWrite(MAX30001::MAX30001_REG_map_t addr, uint32_t data) { Peripherals::max30001()->max30001_reg_write(addr, data); } int MAX30001_WriteReg(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[2]; uint32_t reply[1]; uint32_t value; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); max30001_RegWrite((MAX30001::MAX30001_REG_map_t)args[0], args[1]); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_ReadReg(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[1]; uint32_t reply[1]; uint32_t value; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); value = max30001_RegRead((MAX30001::MAX30001_REG_map_t)args[0]); reply[0] = value; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_Rbias_FMSTR_Init(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[5]; uint32_t reply[1]; uint32_t value; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); value = Peripherals::max30001()->max30001_Rbias_FMSTR_Init(args[0], // En_rbias args[1], // Rbiasv args[2], // Rbiasp args[3], // Rbiasn args[4]); // Fmstr reply[0] = value; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_CAL_InitStart(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[6]; uint32_t reply[1]; uint32_t value; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); // Peripherals::serial()->printf("MAX30001_CAL_InitStart 0 "); value = Peripherals::max30001()->max30001_CAL_InitStart(args[0], // En_Vcal args[1], // Vmag args[2], // Fcal args[3], // Thigh args[4], // Fifty args[5]); // Vmode reply[0] = value; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_ECG_InitStart(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[11]; uint32_t reply[1]; uint32_t value; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); // Peripherals::serial()->printf("MAX30001_ECG_InitStart 0 "); value = Peripherals::max30001()->max30001_ECG_InitStart(args[0], // En_ecg args[1], // Openp args[2], // Openn args[3], // Pol args[4], // Calp_sel args[5], // Caln_sel args[6], // E_fit args[7], // Rate args[8], // Gain args[9], // Dhpf args[10]); // Dlpf // Peripherals::serial()->printf("MAX30001_ECG_InitStart 1 "); MAX30001_Helper_SetStreamingFlag(eStreaming_ECG, 1); reply[0] = value; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_ECGFast_Init(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[3]; uint32_t reply[1]; uint32_t value; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); value = Peripherals::max30001()->max30001_ECGFast_Init(args[0], // Clr_Fast args[1], // Fast args[2]); // Fast_Th reply[0] = value; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_PACE_InitStart(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[9]; uint32_t reply[1]; uint32_t value; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); value = Peripherals::max30001()->max30001_PACE_InitStart(args[0], // En_pace args[1], // Clr_pedge args[2], // Pol args[3], // Gn_diff_off args[4], // Gain args[5], // Aout_lbw args[6], // Aout args[7], // Dacp args[8]); // Dacn MAX30001_Helper_SetStreamingFlag(eStreaming_PACE, 1); reply[0] = value; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_BIOZ_InitStart(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[18]; uint32_t reply[1]; uint32_t value; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); value = Peripherals::max30001()->max30001_BIOZ_InitStart(args[0], // En_bioz args[1], // Openp args[2], // Openn args[3], // Calp_sel args[4], // Caln_sel args[5], // CG_mode args[6], // B_fit args[7], // Rate args[8], // Ahpf args[9], // Ext_rbias args[10], // Gain args[11], // Dhpf args[12], // Dlpf args[13], // Fcgen args[14], // Cgmon args[15], // Cgmag args[16], // Phoff args[17]); //INAPow_mode MAX30001_Helper_SetStreamingFlag(eStreaming_BIOZ, 1); reply[0] = value; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_RtoR_InitStart(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[9]; uint32_t reply[1]; uint32_t value; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); value = Peripherals::max30001()->max30001_RtoR_InitStart(args[0], // En_rtor args[1], // Wndw args[2], // Gain args[3], // Pavg args[4], // Ptsf args[5], // Hoff args[6], // Ravg args[7], // Rhsf args[8]); // Clr_rrint MAX30001_Helper_SetStreamingFlag(eStreaming_RtoR, 1); reply[0] = value; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_Stop_ECG(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; Peripherals::max30001()->max30001_Stop_ECG(); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_Stop_PACE(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; Peripherals::max30001()->max30001_Stop_PACE(); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_Stop_BIOZ(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; Peripherals::max30001()->max30001_Stop_BIOZ(); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_Stop_RtoR(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; Peripherals::max30001()->max30001_Stop_RtoR(); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_Stop_Cal(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; // max30001_Stop_Cal(); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } void max30001_ServiceStreaming() { char ch; uint32_t val; USBSerial *usbSerial = Peripherals::usbSerial(); fifo_clear(GetStreamOutFifo()); SetStreaming(TRUE); clearOutReadFifo(); while (IsStreaming() == TRUE) { if (fifo_empty(GetStreamOutFifo()) == 0) { fifo_get32(GetStreamOutFifo(), &val); usbSerial->printf("%02X ", val); } if (usbSerial->available()) { ch = usbSerial->_getc(); MAX30001_Helper_Stop(); SetStreaming(FALSE); fifo_clear(GetUSBIncomingFifo()); // clear USB serial incoming fifo fifo_clear(GetStreamOutFifo()); } } } int MAX30001_Start(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; uint32_t all; fifo_clear(GetUSBIncomingFifo()); Peripherals::max30001()->max30001_synch(); // max30001_ServiceStreaming(); highDataRate = 0; Peripherals::max30001()->max30001_reg_read(MAX30001::STATUS, &all); LoggingService_StartLoggingUsb(); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_Stop(char argStrs[32][32], char replyStrs[32][32]) { /* uint32_t args[1]; uint32_t reply[1]; uint32_t value; //ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); max30001_StopTest(); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs);*/ return 0; } int MAX30001_INT_assignment(char argStrs[32][32], char replyStrs[32][32]) { uint32_t args[17]; uint32_t reply[1]; ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); /* printf("MAX30001_INT_assignment "); printf("%d ",args[0]); printf("%d ",args[1]); printf("%d ",args[2]); printf("%d ",args[3]); printf("%d ",args[4]); printf("%d ",args[5]); printf("%d ",args[6]); printf("%d ",args[7]); printf("%d ",args[8]); printf("%d ",args[9]); printf("%d ",args[10]); printf("%d ",args[11]); printf("%d ",args[12]); printf("%d ",args[13]); printf("%d ",args[14]); printf("%d ",args[15]); printf("%d ",args[16]); printf("\n"); fflush(stdout); */ Peripherals::max30001()->max30001_INT_assignment( (MAX30001::max30001_intrpt_Location_t)args[0], (MAX30001::max30001_intrpt_Location_t)args[1], (MAX30001::max30001_intrpt_Location_t)args[2], (MAX30001::max30001_intrpt_Location_t)args[3], (MAX30001::max30001_intrpt_Location_t)args[4], (MAX30001::max30001_intrpt_Location_t)args[5], (MAX30001::max30001_intrpt_Location_t)args[6], (MAX30001::max30001_intrpt_Location_t)args[7], (MAX30001::max30001_intrpt_Location_t)args[8], (MAX30001::max30001_intrpt_Location_t)args[9], (MAX30001::max30001_intrpt_Location_t)args[10], (MAX30001::max30001_intrpt_Location_t)args[11], (MAX30001::max30001_intrpt_Location_t)args[12], (MAX30001::max30001_intrpt_Location_t)args[13], (MAX30001::max30001_intrpt_Location_t)args[14], (MAX30001::max30001_intrpt_type_t)args[15], (MAX30001::max30001_intrpt_type_t)args[16]); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_StartTest(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; // ProcessArgs32(argStrs, args, sizeof(args) / sizeof(uint32_t)); /*** Set FMSTR over here ****/ /*** Set and Start the VCAL input ***/ /* NOTE VCAL must be set first if VCAL is to be used */ Peripherals::max30001()->max30001_CAL_InitStart(0b1, 0b1, 0b1, 0b011, 0x7FF, 0b0); /**** ECG Initialization ****/ Peripherals::max30001()->max30001_ECG_InitStart(0b1, 0b1, 0b1, 0b0, 0b10, 0b11, 31, 0b00, 0b00, 0b0, 0b01); /***** PACE Initialization ***/ Peripherals::max30001()->max30001_PACE_InitStart(0b1, 0b0, 0b0, 0b1, 0b000, 0b0, 0b00, 0b0, 0b0); /**** BIOZ Initialization ****/ Peripherals::max30001()->max30001_BIOZ_InitStart( 0b1, 0b1, 0b1, 0b10, 0b11, 0b00, 7, 0b0, 0b111, 0b0, 0b10, 0b00, 0b00, 0b0001, 0b0, 0b111, 0b0000, 0b0000); /*** Set RtoR registers ***/ Peripherals::max30001()->max30001_RtoR_InitStart( 0b1, 0b0011, 0b1111, 0b00, 0b0011, 0b000001, 0b00, 0b000, 0b01); /*** Set Rbias & FMSTR over here ****/ Peripherals::max30001()->max30001_Rbias_FMSTR_Init(0b01, 0b10, 0b1, 0b1, 0b00); /**** Interrupt Setting ****/ /*** Set ECG Lead ON/OFF ***/ // max30001_ECG_LeadOnOff(); /*** Set BIOZ Lead ON/OFF ***/ // max30001_BIOZ_LeadOnOff(); Does not work yet... /**** Do a Synch ****/ Peripherals::max30001()->max30001_synch(); fifo_clear(GetUSBIncomingFifo()); max30001_ServiceStreaming(); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } /* static void StopAll() { if (startedEcg == 1) { max30001_Stop_ECG(); } if (startedCal == 1) { } if (startedBioz == 1) { max30001_Stop_BIOZ(); } if (startedPace == 1) { max30001_Stop_PACE(); } if (startedRtor == 1) { max30001_Stop_RtoR(); } startedEcg = 0; startedBioz = 0; startedCal = 0; startedPace = 0; startedRtor = 0; } */ /* // switch to ECG DC Lead ON max30001_Enable_LeadON(0b01); // switch to BIOZ DC Lead ON max30001_Enable_LeadON(0b10); */ int MAX30001_Enable_ECG_LeadON(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; // switch to ECG DC Lead ON Peripherals::max30001()->max30001_Enable_LeadON(0b01); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } int MAX30001_Enable_BIOZ_LeadON(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; // switch to BIOZ DC Lead ON Peripherals::max30001()->max30001_Enable_LeadON(0b10); reply[0] = 0x80; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; } // uint32_t max30001_LeadOn; // This holds the LeadOn data, BIT1 = BIOZ Lead ON, BIT0 = ECG Lead ON int MAX30001_Read_LeadON(char argStrs[32][32], char replyStrs[32][32]) { uint32_t reply[1]; // return the max30001_LeadOn var from the MAX30001 driver reply[0] = Peripherals::max30001()->max30001_LeadOn; FormatReply32(reply, sizeof(reply) / sizeof(uint32_t), replyStrs); return 0; }