Denwis La / Mbed OS mDot_Send_Data

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Dependencies:   libmDot-dev-mbed5-deprecated ISL29011

Fork of mdot-examples by 3mdeb

peer_to_peer_example.cpp@18:0185bc4b9935, 2017-12-10 (annotated)

Committer:
SDesign2018
Date:
Sun Dec 10 20:23:12 2017 +0000
Revision:
18:0185bc4b9935
Parent:
17:0a8d151af3c6
Child:
19:0799d6348449
Tried to print HELLLLOOO to terminal; Breaks the code, once it goes into the interrupt i never comes out;

Who changed what in which revision?

UserRevisionLine numberNew contents of line
SDesign2018 5:c9ab5062cfc3 1 #include <stdlib.h>
SDesign2018 6:3b41238872a8 2 #include <iostream>
SDesign2018 5:c9ab5062cfc3 3 #include <string.h>
SDesign2018 5:c9ab5062cfc3 4 #include <mbed.h>
SDesign2018 4:b0ce6385d008 5 #include "dot_util.h"
SDesign2018 4:b0ce6385d008 6 #include "RadioEvent.h"
SDesign2018 5:c9ab5062cfc3 7 #include "itoa.h"
SDesign2018 5:c9ab5062cfc3 8
SDesign2018 4:b0ce6385d008 9
SDesign2018 4:b0ce6385d008 10 /////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 11 // -------------------- DOT LIBRARY REQUIRED ------------------------------//
SDesign2018 4:b0ce6385d008 12 // * Because these example programs can be used for both mDot and xDot //
SDesign2018 4:b0ce6385d008 13 // devices, the LoRa stack is not included. The libmDot library should //
SDesign2018 4:b0ce6385d008 14 // be imported if building for mDot devices. The libxDot library //
SDesign2018 4:b0ce6385d008 15 // should be imported if building for xDot devices. //
SDesign2018 4:b0ce6385d008 16 // * https://developer.mbed.org/teams/MultiTech/code/libmDot-dev-mbed5/ //
SDesign2018 4:b0ce6385d008 17 // * https://developer.mbed.org/teams/MultiTech/code/libmDot-mbed5/ //
SDesign2018 4:b0ce6385d008 18 // * https://developer.mbed.org/teams/MultiTech/code/libxDot-dev-mbed5/ //
SDesign2018 4:b0ce6385d008 19 // * https://developer.mbed.org/teams/MultiTech/code/libxDot-mbed5/ //
SDesign2018 4:b0ce6385d008 20 /////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 21
SDesign2018 17:0a8d151af3c6 22
SDesign2018 4:b0ce6385d008 23 /////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 24 // * these options must match between the two devices in //
SDesign2018 4:b0ce6385d008 25 // order for communication to be successful
SDesign2018 4:b0ce6385d008 26 //-------------------MDOT variables------------------------//
SDesign2018 4:b0ce6385d008 27 /////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 28 static uint8_t network_address[] = { 0x00, 0x11, 0x22, 0x33 };
SDesign2018 4:b0ce6385d008 29 static uint8_t network_session_key[] = { 0x00, 0x11, 0x22, 0x33, 0x00, 0x11, 0x22, 0x33, 0x00, 0x11, 0x22, 0x33, 0x00, 0x11, 0x22, 0x33 };
SDesign2018 4:b0ce6385d008 30 static uint8_t data_session_key[] = { 0x33, 0x22, 0x11, 0x00, 0x33, 0x22, 0x11, 0x00, 0x33, 0x22, 0x11, 0x00, 0x33, 0x22, 0x11, 0x00 };
SDesign2018 4:b0ce6385d008 31
SDesign2018 4:b0ce6385d008 32 mDot* dot = NULL;
SDesign2018 4:b0ce6385d008 33 lora::ChannelPlan* plan = NULL;
SDesign2018 4:b0ce6385d008 34 //--------------End of MDOT variables-------------------//
SDesign2018 4:b0ce6385d008 35
SDesign2018 4:b0ce6385d008 36 Serial pc(USBTX, USBRX);
SDesign2018 4:b0ce6385d008 37
SDesign2018 4:b0ce6385d008 38 // ADXL372 Slave SPI
SDesign2018 4:b0ce6385d008 39 DigitalOut MOSI(D11);
SDesign2018 4:b0ce6385d008 40 DigitalIn MISO(D12);
SDesign2018 4:b0ce6385d008 41 DigitalOut SPI_CLK(D13);
SDesign2018 4:b0ce6385d008 42 DigitalOut SPI_CS(D10);
SDesign2018 4:b0ce6385d008 43 //InterruptIn INT1();
SDesign2018 4:b0ce6385d008 44 //InterruptIn INT2();
SDesign2018 11:dce6c1b255fd 45
SDesign2018 17:0a8d151af3c6 46 DigitalOut led1(LED1);
SDesign2018 4:b0ce6385d008 47
SDesign2018 4:b0ce6385d008 48 // ADXL372 Slave I2C
SDesign2018 4:b0ce6385d008 49 I2C ADXL372(I2C_SDA, I2C_SCL); // (D14,D15) (MISO, CS)
SDesign2018 4:b0ce6385d008 50
SDesign2018 4:b0ce6385d008 51 // ADT7410 Temperature
SDesign2018 4:b0ce6385d008 52 I2C ADT7410(I2C_SDA, I2C_SCL); // Attempt at making I2C connection to slaves (D14,D15)
SDesign2018 4:b0ce6385d008 53 InterruptIn ADT7410_Int(D2); // Allow this pin for ADT7410 Interrupt critical temperature notice
SDesign2018 4:b0ce6385d008 54
SDesign2018 4:b0ce6385d008 55 // DS7505s Temperature
SDesign2018 4:b0ce6385d008 56 I2C DS7505(I2C_SDA, I2C_SCL); // Attempt at making I2C connection to slaves (D14,D15)
SDesign2018 4:b0ce6385d008 57
SDesign2018 4:b0ce6385d008 58 // Create reocurring interrupt function that could be used to periodically take temperatures
SDesign2018 4:b0ce6385d008 59 // Not working right now due to some mutex initialize error
SDesign2018 4:b0ce6385d008 60 // Suspect that it is due to it having be a RTOS task thing
SDesign2018 4:b0ce6385d008 61 // Should probably go back to using an in processor timer interrupt instead of mbed
SDesign2018 4:b0ce6385d008 62 Ticker interruptEverything;
SDesign2018 4:b0ce6385d008 63
SDesign2018 4:b0ce6385d008 64 const int ADT7410_Address_7BIT = 0x49; // A0 set HIGH and A1 set LOW
SDesign2018 4:b0ce6385d008 65 const int ADT7410_Address_8BIT = ADT7410_Address_7BIT << 1; // Shift 1 bit to left for R/~W bit, and basic I2C format
SDesign2018 4:b0ce6385d008 66
SDesign2018 4:b0ce6385d008 67 const int ADXL372_Address_7bit = 0x1D; // Address for the I2C if MISO pulled low, 0x53 if pulled high
SDesign2018 4:b0ce6385d008 68 const int ADXL372_Address_8bit = ADXL372_Address_7bit << 1; // Same
SDesign2018 4:b0ce6385d008 69
SDesign2018 4:b0ce6385d008 70 const int DS7505s_Address_7bit = 0x48; // A0 set LOR, A1 set LOW, A2 set LOW
SDesign2018 4:b0ce6385d008 71 const int DS7505s_Address_8bit = DS7505s_Address_7bit << 1; // Same
SDesign2018 4:b0ce6385d008 72
SDesign2018 4:b0ce6385d008 73
SDesign2018 17:0a8d151af3c6 74 int counter = 0;
SDesign2018 17:0a8d151af3c6 75
SDesign2018 4:b0ce6385d008 76 //-------------------All prototype functions-----------------------//
SDesign2018 4:b0ce6385d008 77 void ADXL372Initialize(void);
SDesign2018 4:b0ce6385d008 78
SDesign2018 4:b0ce6385d008 79 int accelerometerI2CWrite(int hexAddress, int hexData);
SDesign2018 4:b0ce6385d008 80 char * accelerometerI2CRead(int hexAddress);
SDesign2018 4:b0ce6385d008 81 void ADXL372Reset(void);
SDesign2018 10:db20118b7d32 82 void I2CSelfTest(void);
SDesign2018 4:b0ce6385d008 83 void BitBangSPIWrite(const unsigned char regAddr, const unsigned char regData);
SDesign2018 5:c9ab5062cfc3 84 uint8_t BitBangSPIRead (const unsigned char regAddr);
SDesign2018 4:b0ce6385d008 85
SDesign2018 4:b0ce6385d008 86 int ADT7410Write(unsigned char registerAddress, unsigned char data);
SDesign2018 4:b0ce6385d008 87 char * ADT7410Read(int hex);
SDesign2018 4:b0ce6385d008 88
SDesign2018 4:b0ce6385d008 89 int DS7505sWrite(unsigned char registerAddress, unsigned char data);
SDesign2018 4:b0ce6385d008 90 char * DS7505sRead(int hex);
SDesign2018 4:b0ce6385d008 91
SDesign2018 13:e336881e0a3e 92 char twosComplementConversion(char value);
SDesign2018 6:3b41238872a8 93 void flushSerialBuffer(void);
SDesign2018 4:b0ce6385d008 94 //---------------------End of prototype functions-----------------------------//
SDesign2018 4:b0ce6385d008 95
SDesign2018 4:b0ce6385d008 96 void printMenu(){
SDesign2018 4:b0ce6385d008 97 pc.printf("Please eneter a debug option: \n\r"
SDesign2018 5:c9ab5062cfc3 98 "1: I2C Read converted values from Accelerometer ADXL372\n\r"
SDesign2018 4:b0ce6385d008 99 "2: Read converted values from Temperature ADT7410\n\r"
SDesign2018 4:b0ce6385d008 100 "3: Read raw values from Accelerometer ADXL372\n\r"
SDesign2018 4:b0ce6385d008 101 "4: Read raw values from Temperature ADT7410\n\r"
SDesign2018 9:df0c4e8a3097 102 "5: Initialize Accelerometer with I2C\n\r"
SDesign2018 10:db20118b7d32 103 "6: Reset Accelerometer with I2C\n\r"
SDesign2018 10:db20118b7d32 104 "7: Perform self test with I2C\n\r"
SDesign2018 10:db20118b7d32 105 "8: Send Temperature data\n\r"
SDesign2018 10:db20118b7d32 106 "9: SPI Read values from Accelerometer ADXL372\n\r"
SDesign2018 10:db20118b7d32 107 "a: SPI reset for ADXL372\n\r"
SDesign2018 10:db20118b7d32 108 "b: Initialize Accelerometer with SPI\n\r"
SDesign2018 10:db20118b7d32 109 "c: Check data in status register with SPI\n\r"
SDesign2018 12:bdf16bf682ec 110 "d: Perform self test with SPI\n\r"
SDesign2018 17:0a8d151af3c6 111 "e: Perform two's complement on accel data\n\r"
SDesign2018 17:0a8d151af3c6 112 "g: Set temperature critical to 24 celsius\n\r"
SDesign2018 17:0a8d151af3c6 113 "h: Print interrupt counter\n\r");
SDesign2018 4:b0ce6385d008 114 }
SDesign2018 4:b0ce6385d008 115
SDesign2018 4:b0ce6385d008 116
SDesign2018 4:b0ce6385d008 117 /*******************************************************************************
SDesign2018 4:b0ce6385d008 118 * Function to be called by the ticker interrupt
SDesign2018 4:b0ce6385d008 119 * Read temperatures and send it
SDesign2018 4:b0ce6385d008 120 *
SDesign2018 4:b0ce6385d008 121 *
SDesign2018 4:b0ce6385d008 122 ******************************************************************************/
SDesign2018 4:b0ce6385d008 123 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 124 void interruptReadTemperature(void){
SDesign2018 4:b0ce6385d008 125 std::vector<uint8_t> tx_data;
SDesign2018 4:b0ce6385d008 126 uint16_t temperatures;
SDesign2018 4:b0ce6385d008 127 char data[2] = {0, 0};
SDesign2018 4:b0ce6385d008 128 char cmd[1];
SDesign2018 4:b0ce6385d008 129 cmd[0] = 0x00;
SDesign2018 4:b0ce6385d008 130 //pc.printf("Register Addres is: %x \n\r", cmd[0]);
SDesign2018 4:b0ce6385d008 131 if(ADT7410.write(ADT7410_Address_8BIT, cmd,1) == 0){
SDesign2018 4:b0ce6385d008 132 if(ADT7410.read(ADT7410_Address_8BIT, data, 2) == 0){
SDesign2018 4:b0ce6385d008 133 temperatures = ((data[0] << 8) | data[1]) >> 3;
SDesign2018 4:b0ce6385d008 134 tx_data.push_back((temperatures >> 8) & 0xFF);
SDesign2018 4:b0ce6385d008 135 tx_data.push_back(temperatures & 0xFF);
SDesign2018 4:b0ce6385d008 136 logInfo("light: %lu [0x%04X]", temperatures, temperatures);
SDesign2018 4:b0ce6385d008 137 send_data(tx_data);
SDesign2018 4:b0ce6385d008 138 //return (data[0] >> 8 | data[1])>>3; // Explained here: https://stackoverflow.com/a/141576 SOOO GOOOOODDD
SDesign2018 4:b0ce6385d008 139
SDesign2018 4:b0ce6385d008 140 }
SDesign2018 4:b0ce6385d008 141 }
SDesign2018 4:b0ce6385d008 142 }
SDesign2018 4:b0ce6385d008 143 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 144
SDesign2018 17:0a8d151af3c6 145 void CriticalTemperatureInterrupt(void){
SDesign2018 17:0a8d151af3c6 146
SDesign2018 18:0185bc4b9935 147 pc.printf("HELLOOOO\n\r");
SDesign2018 17:0a8d151af3c6 148 counter++;
SDesign2018 17:0a8d151af3c6 149 }
SDesign2018 17:0a8d151af3c6 150
SDesign2018 11:dce6c1b255fd 151
SDesign2018 11:dce6c1b255fd 152
SDesign2018 11:dce6c1b255fd 153 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 11:dce6c1b255fd 154 /* _
SDesign2018 11:dce6c1b255fd 155 ____ ___ ____ _(_)___
SDesign2018 11:dce6c1b255fd 156 / __ `__ \/ __ `/ / __ \
SDesign2018 11:dce6c1b255fd 157 / / / / / / /_/ / / / / /
SDesign2018 11:dce6c1b255fd 158 /_/ /_/ /_/\__,_/_/_/ /_/
SDesign2018 11:dce6c1b255fd 159
SDesign2018 11:dce6c1b255fd 160 *//////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 161 int main() {
SDesign2018 4:b0ce6385d008 162 // Custom event handler for automatically displaying RX data
SDesign2018 5:c9ab5062cfc3 163 //interruptEverything.attach(&interruptReadTemperature, 7.0);
SDesign2018 4:b0ce6385d008 164 RadioEvent events;
SDesign2018 4:b0ce6385d008 165 uint32_t tx_frequency;
SDesign2018 4:b0ce6385d008 166 uint8_t tx_datarate;
SDesign2018 4:b0ce6385d008 167 uint8_t tx_power;
SDesign2018 4:b0ce6385d008 168 uint8_t frequency_band;
SDesign2018 4:b0ce6385d008 169
SDesign2018 4:b0ce6385d008 170 // Points to the returned char pointer from called functions
SDesign2018 4:b0ce6385d008 171 char * rawTempValues; // Could change to uint8_t, same for other char pointers
SDesign2018 16:12f38e4755de 172 char Xmsb;
SDesign2018 16:12f38e4755de 173 char Xlsb;
SDesign2018 16:12f38e4755de 174 char Ymsb;
SDesign2018 16:12f38e4755de 175 char Ylsb;
SDesign2018 16:12f38e4755de 176 char Zmsb;
SDesign2018 16:12f38e4755de 177 char Zlsb;
SDesign2018 4:b0ce6385d008 178
SDesign2018 4:b0ce6385d008 179 // Save converted values here
SDesign2018 4:b0ce6385d008 180 uint16_t convertedTempValue; // Data values must be uint16_t for conversion and send prep
SDesign2018 4:b0ce6385d008 181 char *accelValues;
SDesign2018 4:b0ce6385d008 182 uint16_t XData;
SDesign2018 4:b0ce6385d008 183 uint16_t YData;
SDesign2018 4:b0ce6385d008 184 uint16_t ZData;
SDesign2018 4:b0ce6385d008 185 int regAddress;
SDesign2018 4:b0ce6385d008 186
SDesign2018 4:b0ce6385d008 187 // Change baud rate in serial terminal to this value
SDesign2018 4:b0ce6385d008 188 pc.baud(115200);
SDesign2018 17:0a8d151af3c6 189 ADXL372.frequency(300000);
SDesign2018 17:0a8d151af3c6 190 ADT7410_Int.fall(&CriticalTemperatureInterrupt);
SDesign2018 4:b0ce6385d008 191
SDesign2018 4:b0ce6385d008 192
SDesign2018 4:b0ce6385d008 193 mts::MTSLog::setLogLevel(mts::MTSLog::TRACE_LEVEL);
SDesign2018 4:b0ce6385d008 194
SDesign2018 4:b0ce6385d008 195 // Sometimes when calling this, it creates error: type specifier expected
SDesign2018 4:b0ce6385d008 196 // Even with identical include files I would get this in another workspace.
SDesign2018 4:b0ce6385d008 197 plan = new lora::ChannelPlan_US915();
SDesign2018 4:b0ce6385d008 198
SDesign2018 4:b0ce6385d008 199 logInfo("Now asserting");
SDesign2018 4:b0ce6385d008 200 assert(plan);
SDesign2018 4:b0ce6385d008 201
SDesign2018 4:b0ce6385d008 202 // Careful when using this. The production ready libmdot-mbed5 has a void constructor
SDesign2018 4:b0ce6385d008 203 // Therefore, can only use the libmDot-dev-mbed5 version, for now.
SDesign2018 4:b0ce6385d008 204 dot = mDot::getInstance(plan);
SDesign2018 4:b0ce6385d008 205 assert(dot);
SDesign2018 4:b0ce6385d008 206
SDesign2018 4:b0ce6385d008 207 logInfo("mbed-os library version: %d", MBED_LIBRARY_VERSION);
SDesign2018 4:b0ce6385d008 208
SDesign2018 4:b0ce6385d008 209 // start from a well-known state
SDesign2018 4:b0ce6385d008 210 logInfo("defaulting Dot configuration");
SDesign2018 4:b0ce6385d008 211 dot->resetConfig();
SDesign2018 4:b0ce6385d008 212
SDesign2018 4:b0ce6385d008 213 // make sure library logging is turned on
SDesign2018 4:b0ce6385d008 214 dot->setLogLevel(mts::MTSLog::INFO_LEVEL);
SDesign2018 4:b0ce6385d008 215
SDesign2018 4:b0ce6385d008 216 // attach the custom events handler
SDesign2018 4:b0ce6385d008 217 dot->setEvents(&events);
SDesign2018 4:b0ce6385d008 218
SDesign2018 4:b0ce6385d008 219 // update configuration if necessary
SDesign2018 4:b0ce6385d008 220 if (dot->getJoinMode() != mDot::PEER_TO_PEER) {
SDesign2018 4:b0ce6385d008 221 logInfo("changing network join mode to PEER_TO_PEER");
SDesign2018 4:b0ce6385d008 222 if (dot->setJoinMode(mDot::PEER_TO_PEER) != mDot::MDOT_OK) {
SDesign2018 4:b0ce6385d008 223 logError("failed to set network join mode to PEER_TO_PEER");
SDesign2018 4:b0ce6385d008 224 }
SDesign2018 4:b0ce6385d008 225 }
SDesign2018 4:b0ce6385d008 226
SDesign2018 4:b0ce6385d008 227 /*
SDesign2018 4:b0ce6385d008 228 * Get the Frequency and then choose transfer frequency, datarate, and power accordingly
SDesign2018 4:b0ce6385d008 229 *
SDesign2018 4:b0ce6385d008 230 */
SDesign2018 4:b0ce6385d008 231 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 232 frequency_band = dot->getFrequencyBand();
SDesign2018 4:b0ce6385d008 233 switch (frequency_band) {
SDesign2018 4:b0ce6385d008 234 case lora::ChannelPlan::EU868_OLD:
SDesign2018 4:b0ce6385d008 235 case lora::ChannelPlan::EU868:
SDesign2018 4:b0ce6385d008 236 // 250kHz channels achieve higher throughput
SDesign2018 4:b0ce6385d008 237 // DR_6 : SF7 @ 250kHz
SDesign2018 4:b0ce6385d008 238 // DR_0 - DR_5 (125kHz channels) available but much slower
SDesign2018 4:b0ce6385d008 239 tx_frequency = 869850000;
SDesign2018 4:b0ce6385d008 240 tx_datarate = lora::DR_6;
SDesign2018 4:b0ce6385d008 241 // the 869850000 frequency is 100% duty cycle if the total power is under 7 dBm - tx power 4 + antenna gain 3 = 7
SDesign2018 4:b0ce6385d008 242 tx_power = 4;
SDesign2018 4:b0ce6385d008 243 break;
SDesign2018 4:b0ce6385d008 244
SDesign2018 4:b0ce6385d008 245 case lora::ChannelPlan::US915_OLD:
SDesign2018 4:b0ce6385d008 246 case lora::ChannelPlan::US915:
SDesign2018 4:b0ce6385d008 247 case lora::ChannelPlan::AU915_OLD:
SDesign2018 4:b0ce6385d008 248 case lora::ChannelPlan::AU915:
SDesign2018 4:b0ce6385d008 249 // 500kHz channels achieve highest throughput
SDesign2018 4:b0ce6385d008 250 // DR_8 : SF12 @ 500kHz
SDesign2018 4:b0ce6385d008 251 // DR_9 : SF11 @ 500kHz
SDesign2018 4:b0ce6385d008 252 // DR_10 : SF10 @ 500kHz
SDesign2018 4:b0ce6385d008 253 // DR_11 : SF9 @ 500kHz
SDesign2018 4:b0ce6385d008 254 // DR_12 : SF8 @ 500kHz
SDesign2018 4:b0ce6385d008 255 // DR_13 : SF7 @ 500kHz
SDesign2018 4:b0ce6385d008 256 // DR_0 - DR_3 (125kHz channels) available but much slower
SDesign2018 4:b0ce6385d008 257 tx_frequency = 915500000;
SDesign2018 4:b0ce6385d008 258 tx_datarate = lora::DR_13;
SDesign2018 4:b0ce6385d008 259 // 915 bands have no duty cycle restrictions, set tx power to max
SDesign2018 4:b0ce6385d008 260 tx_power = 20;
SDesign2018 4:b0ce6385d008 261 break;
SDesign2018 4:b0ce6385d008 262
SDesign2018 4:b0ce6385d008 263 case lora::ChannelPlan::AS923:
SDesign2018 4:b0ce6385d008 264 case lora::ChannelPlan::AS923_JAPAN:
SDesign2018 4:b0ce6385d008 265 // 250kHz channels achieve higher throughput
SDesign2018 4:b0ce6385d008 266 // DR_6 : SF7 @ 250kHz
SDesign2018 4:b0ce6385d008 267 // DR_0 - DR_5 (125kHz channels) available but much slower
SDesign2018 4:b0ce6385d008 268 tx_frequency = 924800000;
SDesign2018 4:b0ce6385d008 269 tx_datarate = lora::DR_6;
SDesign2018 4:b0ce6385d008 270 tx_power = 16;
SDesign2018 4:b0ce6385d008 271 break;
SDesign2018 4:b0ce6385d008 272
SDesign2018 4:b0ce6385d008 273 case lora::ChannelPlan::KR920:
SDesign2018 4:b0ce6385d008 274 // DR_5 : SF7 @ 125kHz
SDesign2018 4:b0ce6385d008 275 tx_frequency = 922700000;
SDesign2018 4:b0ce6385d008 276 tx_datarate = lora::DR_5;
SDesign2018 4:b0ce6385d008 277 tx_power = 14;
SDesign2018 4:b0ce6385d008 278 break;
SDesign2018 4:b0ce6385d008 279
SDesign2018 4:b0ce6385d008 280 default:
SDesign2018 4:b0ce6385d008 281 while (true) {
SDesign2018 4:b0ce6385d008 282 logFatal("no known channel plan in use - extra configuration is needed!");
SDesign2018 4:b0ce6385d008 283 wait(5);
SDesign2018 4:b0ce6385d008 284 }
SDesign2018 4:b0ce6385d008 285 break;
SDesign2018 4:b0ce6385d008 286 }
SDesign2018 4:b0ce6385d008 287
SDesign2018 4:b0ce6385d008 288 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 289
SDesign2018 4:b0ce6385d008 290 // in PEER_TO_PEER mode there is no join request/response transaction
SDesign2018 4:b0ce6385d008 291 // as long as both Dots are configured correctly, they should be able to communicate
SDesign2018 4:b0ce6385d008 292 update_peer_to_peer_config(network_address, network_session_key, data_session_key, tx_frequency, tx_datarate, tx_power);
SDesign2018 4:b0ce6385d008 293
SDesign2018 4:b0ce6385d008 294 // save changes to configuration
SDesign2018 4:b0ce6385d008 295 logInfo("saving configuration");
SDesign2018 4:b0ce6385d008 296 if (!dot->saveConfig()) {
SDesign2018 4:b0ce6385d008 297 logError("failed to save configuration");
SDesign2018 4:b0ce6385d008 298 }
SDesign2018 4:b0ce6385d008 299
SDesign2018 4:b0ce6385d008 300 // Display configuration
SDesign2018 4:b0ce6385d008 301 // It's gonna output a lot of information onto the Serial Terminal
SDesign2018 4:b0ce6385d008 302 display_config();
SDesign2018 4:b0ce6385d008 303
SDesign2018 4:b0ce6385d008 304 /*
SDesign2018 4:b0ce6385d008 305 *
SDesign2018 4:b0ce6385d008 306 * From here on is my own code
SDesign2018 4:b0ce6385d008 307 * Can add more options to choose from
SDesign2018 4:b0ce6385d008 308 *
SDesign2018 4:b0ce6385d008 309 */
SDesign2018 4:b0ce6385d008 310 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 311 printMenu();
SDesign2018 6:3b41238872a8 312 flushSerialBuffer();
SDesign2018 4:b0ce6385d008 313 pc.printf("\n\rChoose what you want to do: \n\r");
SDesign2018 4:b0ce6385d008 314
SDesign2018 4:b0ce6385d008 315 char userInput = pc.getc();
SDesign2018 4:b0ce6385d008 316 while(1){
SDesign2018 4:b0ce6385d008 317 // Create a vector of uint8_t elements to be sent later
SDesign2018 4:b0ce6385d008 318 std::vector<uint8_t> tx_data;
SDesign2018 4:b0ce6385d008 319
SDesign2018 4:b0ce6385d008 320 // Checks if a character has been pressed;
SDesign2018 4:b0ce6385d008 321 // Works right now for 1 digit numbers :(
SDesign2018 4:b0ce6385d008 322 // Change to work with larger inputs
SDesign2018 4:b0ce6385d008 323 if(pc.readable())
SDesign2018 4:b0ce6385d008 324 {
SDesign2018 4:b0ce6385d008 325 userInput = pc.getc();
SDesign2018 4:b0ce6385d008 326 switch(userInput){
SDesign2018 4:b0ce6385d008 327 case 49: // 1
SDesign2018 4:b0ce6385d008 328 pc.printf("Reading converted values from accelerometer\n\r");
SDesign2018 4:b0ce6385d008 329 for(int i = 0; i < 15; ++i){
SDesign2018 4:b0ce6385d008 330 regAddress = 0x08; // This is the register address for XData
SDesign2018 4:b0ce6385d008 331 accelValues = accelerometerI2CRead(regAddress);
SDesign2018 17:0a8d151af3c6 332 Xmsb = *(accelValues + 0);
SDesign2018 17:0a8d151af3c6 333 Xlsb = *(accelValues + 1);
SDesign2018 17:0a8d151af3c6 334 Ymsb = *(accelValues + 2);
SDesign2018 17:0a8d151af3c6 335 Ylsb = *(accelValues + 3);
SDesign2018 17:0a8d151af3c6 336 Zmsb = *(accelValues + 4);
SDesign2018 17:0a8d151af3c6 337 Zlsb = *(accelValues + 5);
SDesign2018 16:12f38e4755de 338
SDesign2018 16:12f38e4755de 339 XData = (Xmsb << 8 | Xlsb) >> 4; // Combine two bytes into short int, remove last 4 flag bits
SDesign2018 16:12f38e4755de 340 YData = (Ymsb << 8 | Ylsb) >> 4;
SDesign2018 16:12f38e4755de 341 ZData = (Zmsb << 8 | Zlsb) >> 4;
SDesign2018 17:0a8d151af3c6 342
SDesign2018 17:0a8d151af3c6 343 XData = twosComplementConversion(XData);
SDesign2018 17:0a8d151af3c6 344 YData = twosComplementConversion(YData);
SDesign2018 17:0a8d151af3c6 345 ZData = twosComplementConversion(ZData);
SDesign2018 17:0a8d151af3c6 346
SDesign2018 4:b0ce6385d008 347 pc.printf("\n %d: X: 0x%x | Y: 0x%x | Z: 0x%x \n\r", i+1, XData, YData, ZData);
SDesign2018 4:b0ce6385d008 348 wait(0.2);
SDesign2018 4:b0ce6385d008 349 }
SDesign2018 4:b0ce6385d008 350 break;
SDesign2018 4:b0ce6385d008 351 case 50: // 2
SDesign2018 4:b0ce6385d008 352 pc.printf("Reading converted values from temperature\n\r");
SDesign2018 4:b0ce6385d008 353 for(int i = 0; i < 10; ++i){
SDesign2018 4:b0ce6385d008 354 regAddress = 0x00;
SDesign2018 4:b0ce6385d008 355 rawTempValues = ADT7410Read(regAddress);
SDesign2018 4:b0ce6385d008 356 convertedTempValue = ((*(rawTempValues + 0) << 8) | *(rawTempValues + 1)) >> 3; // Combine the two bytes into
SDesign2018 5:c9ab5062cfc3 357 // a short int variable(16 bits), remove last 3 bits
SDesign2018 4:b0ce6385d008 358
SDesign2018 4:b0ce6385d008 359 pc.printf("\n %d: Temperature is: 0x%x \n\r", i+1, convertedTempValue);
SDesign2018 4:b0ce6385d008 360 }
SDesign2018 4:b0ce6385d008 361
SDesign2018 4:b0ce6385d008 362 break;
SDesign2018 4:b0ce6385d008 363 case 51: // 3
SDesign2018 4:b0ce6385d008 364 pc.printf("Reading raw values from accelerometer\n\r");
SDesign2018 4:b0ce6385d008 365 for(int i = 0; i < 15; ++i){
SDesign2018 17:0a8d151af3c6 366 regAddress = 0x08; // This is the register address for XData
SDesign2018 4:b0ce6385d008 367 accelValues = accelerometerI2CRead(regAddress);
SDesign2018 17:0a8d151af3c6 368 Xmsb = *(accelValues + 0);
SDesign2018 17:0a8d151af3c6 369 Xlsb = *(accelValues + 1);
SDesign2018 17:0a8d151af3c6 370 Ymsb = *(accelValues + 2);
SDesign2018 17:0a8d151af3c6 371 Ylsb = *(accelValues + 3);
SDesign2018 17:0a8d151af3c6 372 Zmsb = *(accelValues + 4);
SDesign2018 17:0a8d151af3c6 373 Zlsb = *(accelValues + 5);
SDesign2018 17:0a8d151af3c6 374
SDesign2018 17:0a8d151af3c6 375 XData = (Xmsb << 8 | Xlsb) >> 4; // Combine two bytes into short int, remove last 4 flag bits
SDesign2018 17:0a8d151af3c6 376 YData = (Ymsb << 8 | Ylsb) >> 4;
SDesign2018 17:0a8d151af3c6 377 ZData = (Zmsb << 8 | Zlsb) >> 4;
SDesign2018 17:0a8d151af3c6 378
SDesign2018 17:0a8d151af3c6 379 XData = twosComplementConversion(XData);
SDesign2018 17:0a8d151af3c6 380 YData = twosComplementConversion(YData);
SDesign2018 17:0a8d151af3c6 381 ZData = twosComplementConversion(ZData);
SDesign2018 17:0a8d151af3c6 382
SDesign2018 17:0a8d151af3c6 383 Xlsb = XData & 0xFF;
SDesign2018 17:0a8d151af3c6 384 Xmsb = XData >> 8;
SDesign2018 17:0a8d151af3c6 385
SDesign2018 17:0a8d151af3c6 386 Ylsb = YData & 0xFF;
SDesign2018 17:0a8d151af3c6 387 Ymsb = YData >> 8;
SDesign2018 17:0a8d151af3c6 388
SDesign2018 17:0a8d151af3c6 389 Zlsb = ZData & 0xFF;
SDesign2018 17:0a8d151af3c6 390 Zmsb = ZData >> 8;
SDesign2018 17:0a8d151af3c6 391
SDesign2018 16:12f38e4755de 392 pc.printf("\n %d: X:: H: %x | L: %x | Y:: H: %x | L: %x | Z: H: %x | L: %x \n\r", i+1, Xmsb,
SDesign2018 16:12f38e4755de 393 Xlsb,
SDesign2018 16:12f38e4755de 394 Ymsb,
SDesign2018 16:12f38e4755de 395 Ylsb,
SDesign2018 16:12f38e4755de 396 Zmsb,
SDesign2018 16:12f38e4755de 397 Zlsb);
SDesign2018 4:b0ce6385d008 398 wait(0.2);
SDesign2018 4:b0ce6385d008 399 }
SDesign2018 4:b0ce6385d008 400 break;
SDesign2018 4:b0ce6385d008 401 case 52: // 4
SDesign2018 4:b0ce6385d008 402 pc.printf("Reading raw values from temperature\n\r");
SDesign2018 4:b0ce6385d008 403 for(int i = 0; i < 10; ++i){
SDesign2018 4:b0ce6385d008 404 regAddress = 0x00;
SDesign2018 4:b0ce6385d008 405 rawTempValues = ADT7410Read(regAddress);
SDesign2018 13:e336881e0a3e 406 pc.printf("\n %d: Temperature is: HIGH BYTE: %x | LOW BYTE: %x \n\r", i+1, *(rawTempValues + 0),
SDesign2018 13:e336881e0a3e 407 *(rawTempValues + 1));
SDesign2018 4:b0ce6385d008 408 }
SDesign2018 4:b0ce6385d008 409 break;
SDesign2018 4:b0ce6385d008 410 case 53: // 5
SDesign2018 4:b0ce6385d008 411 ADXL372Initialize();
SDesign2018 4:b0ce6385d008 412 break;
SDesign2018 4:b0ce6385d008 413 case 54: // 6
SDesign2018 4:b0ce6385d008 414 ADXL372Reset();
SDesign2018 4:b0ce6385d008 415 break;
SDesign2018 4:b0ce6385d008 416
SDesign2018 10:db20118b7d32 417 case 55: // 7: perform self test with I2C
SDesign2018 10:db20118b7d32 418 I2CSelfTest();
SDesign2018 10:db20118b7d32 419 break;
SDesign2018 10:db20118b7d32 420 case 56: // 8: Read Temperature raws
SDesign2018 4:b0ce6385d008 421 regAddress = 0x00;
SDesign2018 4:b0ce6385d008 422 rawTempValues = ADT7410Read(regAddress);
SDesign2018 4:b0ce6385d008 423 convertedTempValue = ((*(rawTempValues + 0) << 8) | *(rawTempValues + 1)) >> 3; // Combine the two bytes
SDesign2018 4:b0ce6385d008 424
SDesign2018 4:b0ce6385d008 425 tx_data.push_back((convertedTempValue >> 8) & 0xFF);
SDesign2018 4:b0ce6385d008 426 tx_data.push_back(convertedTempValue & 0xFF);
SDesign2018 4:b0ce6385d008 427 logInfo("light: %lu [0x%04X]", convertedTempValue, convertedTempValue);
SDesign2018 4:b0ce6385d008 428 send_data(tx_data);
SDesign2018 5:c9ab5062cfc3 429 break;
SDesign2018 4:b0ce6385d008 430
SDesign2018 10:db20118b7d32 431 case 57: // 9: Read Accelerometer SPI
SDesign2018 5:c9ab5062cfc3 432 uint8_t MSB;
SDesign2018 5:c9ab5062cfc3 433 uint8_t LSB;
SDesign2018 5:c9ab5062cfc3 434
SDesign2018 5:c9ab5062cfc3 435
SDesign2018 5:c9ab5062cfc3 436 for(int i = 0; i < 15; ++i){
SDesign2018 5:c9ab5062cfc3 437
SDesign2018 5:c9ab5062cfc3 438 MSB = BitBangSPIRead(0x08); // XData MSB
SDesign2018 5:c9ab5062cfc3 439 LSB = BitBangSPIRead(0x09); // XData LSB
SDesign2018 5:c9ab5062cfc3 440 XData = ((MSB << 8) | LSB) >> 4;
SDesign2018 5:c9ab5062cfc3 441
SDesign2018 5:c9ab5062cfc3 442 MSB = BitBangSPIRead(0x0A); // YData MSB
SDesign2018 5:c9ab5062cfc3 443 LSB = BitBangSPIRead(0x0B); // YData LSB
SDesign2018 5:c9ab5062cfc3 444 YData = ((MSB << 8) | LSB) >> 4;
SDesign2018 5:c9ab5062cfc3 445
SDesign2018 5:c9ab5062cfc3 446 MSB = BitBangSPIRead(0x0C); // ZData MSB
SDesign2018 5:c9ab5062cfc3 447 LSB = BitBangSPIRead(0x0D); // ZData LSB
SDesign2018 5:c9ab5062cfc3 448 ZData = ((MSB << 8 ) | LSB) >> 4;
SDesign2018 5:c9ab5062cfc3 449
SDesign2018 5:c9ab5062cfc3 450 pc.printf("\n %d: X: 0x%x | Y: 0x%x | Z: 0x%x \n\r", i+1, XData, YData, ZData);
SDesign2018 5:c9ab5062cfc3 451 wait(0.2);
SDesign2018 5:c9ab5062cfc3 452 }
SDesign2018 5:c9ab5062cfc3 453 break;
SDesign2018 10:db20118b7d32 454 case 97: // a: Reset Accelerometer with SPI
SDesign2018 6:3b41238872a8 455 int intRegister;
SDesign2018 7:5f2b3d1a9b0b 456 char input[4];
SDesign2018 5:c9ab5062cfc3 457 char passRegister[1];
SDesign2018 6:3b41238872a8 458 int intData;
SDesign2018 5:c9ab5062cfc3 459 char passData[1];
SDesign2018 8:efab0e415826 460 BitBangSPIWrite(0x41, 0x52);
SDesign2018 8:efab0e415826 461 pc.printf("Done \n\r");
SDesign2018 6:3b41238872a8 462 break;
SDesign2018 10:db20118b7d32 463 case 98: // b: Initialize Accelerometer with SPI
SDesign2018 9:df0c4e8a3097 464 BitBangSPIWrite(0x24, 0x01); // Turn on X
SDesign2018 9:df0c4e8a3097 465 BitBangSPIWrite(0x26, 0x01); // Turn on Y
SDesign2018 9:df0c4e8a3097 466 BitBangSPIWrite(0x28, 0x01); // Turn on Z
SDesign2018 9:df0c4e8a3097 467 pc.printf("Done\n\r");
SDesign2018 9:df0c4e8a3097 468 break;
SDesign2018 10:db20118b7d32 469 case 99: // c: Check status with SPI
SDesign2018 9:df0c4e8a3097 470 uint8_t statusData = BitBangSPIRead(0x04);
SDesign2018 9:df0c4e8a3097 471
SDesign2018 9:df0c4e8a3097 472 pc.printf("0x%x in status\n\r", statusData);
SDesign2018 9:df0c4e8a3097 473 break;
SDesign2018 10:db20118b7d32 474 case 100: // d: Perform self-test
SDesign2018 9:df0c4e8a3097 475 uint8_t testResult;
SDesign2018 9:df0c4e8a3097 476 BitBangSPIWrite(0x3F, 0x03); // put to fullbandwidth measurement mode and lpf enaled(0)
SDesign2018 9:df0c4e8a3097 477
SDesign2018 9:df0c4e8a3097 478 BitBangSPIWrite(0x40, 0x01); // start self test
SDesign2018 9:df0c4e8a3097 479 testResult = BitBangSPIRead(0x40);
SDesign2018 9:df0c4e8a3097 480 while(!(BitBangSPIRead(0x40) & 0x02)){}
SDesign2018 9:df0c4e8a3097 481 wait(0.4);
SDesign2018 9:df0c4e8a3097 482
SDesign2018 9:df0c4e8a3097 483 testResult = BitBangSPIRead(0x40);
SDesign2018 9:df0c4e8a3097 484
SDesign2018 9:df0c4e8a3097 485 if(testResult & 0x04)
SDesign2018 9:df0c4e8a3097 486 {
SDesign2018 9:df0c4e8a3097 487 pc.printf("It passed \n\r");
SDesign2018 9:df0c4e8a3097 488 }
SDesign2018 9:df0c4e8a3097 489 pc.printf("0x%x\n\r", testResult);
SDesign2018 9:df0c4e8a3097 490 break;
SDesign2018 12:bdf16bf682ec 491 case 101: // e for two's complement of accel data
SDesign2018 12:bdf16bf682ec 492 regAddress = 0x08;
SDesign2018 12:bdf16bf682ec 493
SDesign2018 12:bdf16bf682ec 494 accelValues = accelerometerI2CRead(regAddress);
SDesign2018 13:e336881e0a3e 495
SDesign2018 13:e336881e0a3e 496 Xmsb = *(accelValues + 0);
SDesign2018 13:e336881e0a3e 497 Xlsb = *(accelValues + 1);
SDesign2018 13:e336881e0a3e 498 Ymsb = *(accelValues + 2);
SDesign2018 13:e336881e0a3e 499 Ylsb = *(accelValues + 3);
SDesign2018 13:e336881e0a3e 500 Zmsb = *(accelValues + 4);
SDesign2018 13:e336881e0a3e 501 Zlsb = *(accelValues + 5);
SDesign2018 12:bdf16bf682ec 502 pc.printf("\n X:: H: %x | L: %x | Y:: H: %x | L: %x | Z: H: %x | L: %x \n\r", *(accelValues + 0),
SDesign2018 12:bdf16bf682ec 503 *(accelValues + 1),
SDesign2018 12:bdf16bf682ec 504 *(accelValues + 2),
SDesign2018 12:bdf16bf682ec 505 *(accelValues + 3),
SDesign2018 12:bdf16bf682ec 506 *(accelValues + 4),
SDesign2018 12:bdf16bf682ec 507 *(accelValues + 5));
SDesign2018 12:bdf16bf682ec 508 pc.printf("Converted \n\r");
SDesign2018 12:bdf16bf682ec 509
SDesign2018 13:e336881e0a3e 510 pc.printf("\n X:: H: %x | L: %x | Y:: H: %x | L: %x | Z: H: %x | L: %x \n\r", twosComplementConversion(Xmsb),
SDesign2018 13:e336881e0a3e 511 twosComplementConversion(Xlsb),
SDesign2018 13:e336881e0a3e 512 twosComplementConversion(Ymsb),
SDesign2018 13:e336881e0a3e 513 twosComplementConversion(Ylsb),
SDesign2018 13:e336881e0a3e 514 twosComplementConversion(Zmsb),
SDesign2018 13:e336881e0a3e 515 twosComplementConversion(Zlsb));
SDesign2018 12:bdf16bf682ec 516 wait(0.2);
SDesign2018 12:bdf16bf682ec 517
SDesign2018 12:bdf16bf682ec 518 break;
SDesign2018 17:0a8d151af3c6 519 case 102: // f: check register 0x08 and 0x09 for critical temperature
SDesign2018 17:0a8d151af3c6 520 char * critDatapointer;
SDesign2018 17:0a8d151af3c6 521 uint8_t CritMSB;
SDesign2018 17:0a8d151af3c6 522 uint8_t CritLSB;
SDesign2018 17:0a8d151af3c6 523 uint16_t CritData;
SDesign2018 17:0a8d151af3c6 524 critDatapointer = ADT7410Read(0x08);
SDesign2018 17:0a8d151af3c6 525
SDesign2018 17:0a8d151af3c6 526 CritMSB = *(critDatapointer + 0);
SDesign2018 17:0a8d151af3c6 527 CritLSB = *(critDatapointer + 1);
SDesign2018 17:0a8d151af3c6 528
SDesign2018 17:0a8d151af3c6 529 CritData = (CritMSB << 8) | CritLSB;
SDesign2018 17:0a8d151af3c6 530
SDesign2018 17:0a8d151af3c6 531 pc.printf("H: 0x%x | L: 0x%x | Data: 0x%x CritData\n\r", CritMSB, CritLSB, CritData);
SDesign2018 17:0a8d151af3c6 532 break;
SDesign2018 17:0a8d151af3c6 533 case 103: // g: set critical temperature to 30 celsius
SDesign2018 17:0a8d151af3c6 534 ADT7410Write(0x08, 0x01);
SDesign2018 17:0a8d151af3c6 535 ADT7410Write(0x09, 0x80);
SDesign2018 17:0a8d151af3c6 536 ADT7410Write(0x03, 0x08); // Turn INT HIGH, works for the interrupt pin
SDesign2018 17:0a8d151af3c6 537 break;
SDesign2018 17:0a8d151af3c6 538 case 104: // h: get count value
SDesign2018 17:0a8d151af3c6 539 pc.printf("Count Value: %d\n\r", counter);
SDesign2018 17:0a8d151af3c6 540 break;
SDesign2018 4:b0ce6385d008 541 default:
SDesign2018 4:b0ce6385d008 542 printMenu();
SDesign2018 4:b0ce6385d008 543 break;
SDesign2018 4:b0ce6385d008 544 }
SDesign2018 4:b0ce6385d008 545 }
SDesign2018 4:b0ce6385d008 546
SDesign2018 4:b0ce6385d008 547 }
SDesign2018 4:b0ce6385d008 548
SDesign2018 4:b0ce6385d008 549 return 0;
SDesign2018 4:b0ce6385d008 550 }
SDesign2018 4:b0ce6385d008 551 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 552
SDesign2018 4:b0ce6385d008 553
SDesign2018 4:b0ce6385d008 554 /*******************************************************************************
SDesign2018 4:b0ce6385d008 555 *
SDesign2018 4:b0ce6385d008 556 * I2C function for the the ADXL372 accelerometer for a write sequence
SDesign2018 4:b0ce6385d008 557 * Param:
SDesign2018 4:b0ce6385d008 558 * hexAddress: Pass the hexadecimal value for what register you want
SDesign2018 4:b0ce6385d008 559 * hexData: Pass the hexadecimal value for what data you want to send
SDesign2018 4:b0ce6385d008 560 * i.e. hexadecimal represenatation of certain bits
SDesign2018 4:b0ce6385d008 561 * Returns:
SDesign2018 4:b0ce6385d008 562 * 1: Write was a complete success
SDesign2018 4:b0ce6385d008 563 * 2: Writing data to register failed
SDesign2018 4:b0ce6385d008 564 * 3: Writing to register Address failed
SDesign2018 4:b0ce6385d008 565 ******************************************************************************/
SDesign2018 4:b0ce6385d008 566 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 567 int accelerometerI2CWrite(int hexAddress, int hexData){
SDesign2018 4:b0ce6385d008 568 //--------- One full writing cycle for ADXL372 for X enable ------------------//
SDesign2018 4:b0ce6385d008 569 /* '0' - NAK was received
SDesign2018 4:b0ce6385d008 570 * '1' - ACK was received, <---- This good
SDesign2018 4:b0ce6385d008 571 * '2' - timeout
SDesign2018 4:b0ce6385d008 572 */
SDesign2018 4:b0ce6385d008 573 int flag;
SDesign2018 4:b0ce6385d008 574 int registerAddress = hexAddress;
SDesign2018 4:b0ce6385d008 575 int data = hexData;
SDesign2018 4:b0ce6385d008 576
SDesign2018 4:b0ce6385d008 577 ADXL372.start();
SDesign2018 4:b0ce6385d008 578 flag = ADXL372.write(ADXL372_Address_8bit);
SDesign2018 4:b0ce6385d008 579 if(flag == 1)
SDesign2018 4:b0ce6385d008 580 {
SDesign2018 11:dce6c1b255fd 581 //pc.printf("Write to I2C address success\n\r");
SDesign2018 4:b0ce6385d008 582 wait(0.1);
SDesign2018 4:b0ce6385d008 583 flag = ADXL372.write(registerAddress);
SDesign2018 4:b0ce6385d008 584 if(flag == 1)
SDesign2018 4:b0ce6385d008 585 {
SDesign2018 11:dce6c1b255fd 586 //pc.printf("Write to register 0x%x address success\n\r", registerAddress);
SDesign2018 4:b0ce6385d008 587 flag = ADXL372.write(data);
SDesign2018 4:b0ce6385d008 588 if(flag == 1)
SDesign2018 4:b0ce6385d008 589 {
SDesign2018 4:b0ce6385d008 590 pc.printf("Writing data 0x%x to register address success\n\r", data);
SDesign2018 4:b0ce6385d008 591 ADXL372.stop();
SDesign2018 4:b0ce6385d008 592 return 1;
SDesign2018 4:b0ce6385d008 593 }else {ADXL372.stop(); return 2;}
SDesign2018 4:b0ce6385d008 594 }else {ADXL372.stop(); return 3;}
SDesign2018 4:b0ce6385d008 595 }else ADXL372.stop();
SDesign2018 4:b0ce6385d008 596
SDesign2018 4:b0ce6385d008 597 return 0;
SDesign2018 4:b0ce6385d008 598 // ---------------- End of writing cycle --------------------------//
SDesign2018 4:b0ce6385d008 599 }
SDesign2018 4:b0ce6385d008 600 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 601
SDesign2018 4:b0ce6385d008 602
SDesign2018 4:b0ce6385d008 603 /*******************************************************************************
SDesign2018 4:b0ce6385d008 604 * I2C read sequence for the accelerometer
SDesign2018 4:b0ce6385d008 605 * Param:
SDesign2018 4:b0ce6385d008 606 * hexAddress: pass the hexadecimal representation of desired Register address
SDesign2018 4:b0ce6385d008 607 * Return:
SDesign2018 4:b0ce6385d008 608 * Char pointer to the array of read data.
SDesign2018 4:b0ce6385d008 609 *
SDesign2018 4:b0ce6385d008 610 * Right now it works only for the XData, YData, ZData because I wrote it to read
SDesign2018 4:b0ce6385d008 611 * 6 bytes(6 registers).
SDesign2018 4:b0ce6385d008 612 * Should change it to be 1 byte at a time
SDesign2018 4:b0ce6385d008 613 ******************************************************************************/
SDesign2018 4:b0ce6385d008 614 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 615 char * accelerometerI2CRead(int hexAddress){
SDesign2018 4:b0ce6385d008 616 char accelData[6];
SDesign2018 4:b0ce6385d008 617 char registerAddress[1];
SDesign2018 4:b0ce6385d008 618 registerAddress[0] = hexAddress;
SDesign2018 4:b0ce6385d008 619
SDesign2018 4:b0ce6385d008 620 // Perform mbed's way sending a start bit, then device address[r/~w], and then the register address
SDesign2018 4:b0ce6385d008 621 // Also if it succeeds, continue to the next operation
SDesign2018 4:b0ce6385d008 622 if(ADXL372.write(ADXL372_Address_8bit, registerAddress, 1) == 0){
SDesign2018 4:b0ce6385d008 623
SDesign2018 4:b0ce6385d008 624 // If previous sequence works, get 6 bytes into char array accelData
SDesign2018 4:b0ce6385d008 625 // Char array because it uses 1 byte(8bits)
SDesign2018 4:b0ce6385d008 626 // Should probably change it to uint8_t type
SDesign2018 4:b0ce6385d008 627 if(ADXL372.read(ADXL372_Address_8bit, accelData, 6) == 0){
SDesign2018 4:b0ce6385d008 628 return accelData;
SDesign2018 4:b0ce6385d008 629 }else pc.printf("Failed to read\n\r");
SDesign2018 4:b0ce6385d008 630 }else pc.printf("Failed to write\n\r");
SDesign2018 4:b0ce6385d008 631 return 0; // Only if it fails
SDesign2018 4:b0ce6385d008 632 }
SDesign2018 4:b0ce6385d008 633 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 634
SDesign2018 4:b0ce6385d008 635
SDesign2018 4:b0ce6385d008 636
SDesign2018 4:b0ce6385d008 637 /*******************************************************************************
SDesign2018 4:b0ce6385d008 638 * Initializes whatever settings you want for the accelerometer
SDesign2018 4:b0ce6385d008 639 * Can change it to use the previous I2C write function instead of all this mess
SDesign2018 4:b0ce6385d008 640 *
SDesign2018 4:b0ce6385d008 641 ******************************************************************************/
SDesign2018 4:b0ce6385d008 642 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 643 void ADXL372Initialize(void){
SDesign2018 14:454090793a35 644 accelerometerI2CWrite(0x3F, 0x0F); // Enable I2C highspeed,Low Pass, High pass and full bandwidth measurement mode
SDesign2018 17:0a8d151af3c6 645 accelerometerI2CWrite(0x38, 0x01); // Enable the High pass filter corner 1 at register 0x38
SDesign2018 13:e336881e0a3e 646 /* accelerometerI2CWrite(0x24, 0x01); // X used for activity threshold
SDesign2018 11:dce6c1b255fd 647 accelerometerI2CWrite(0x26, 0x01); // Y used for activity threshold
SDesign2018 13:e336881e0a3e 648 accelerometerI2CWrite(0x28, 0x01); // Z used for activity threshold */
SDesign2018 4:b0ce6385d008 649 }
SDesign2018 4:b0ce6385d008 650 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 651
SDesign2018 4:b0ce6385d008 652
SDesign2018 4:b0ce6385d008 653
SDesign2018 4:b0ce6385d008 654 /*******************************************************************************
SDesign2018 4:b0ce6385d008 655 * BitBangSPIWrite for ADXL372 if you wire it up as SPI
SDesign2018 4:b0ce6385d008 656 *
SDesign2018 4:b0ce6385d008 657 * Sends the 6-0bits of desired register with LSB of transmission bit R/!W
SDesign2018 4:b0ce6385d008 658 *
SDesign2018 4:b0ce6385d008 659 ******************************************************************************/
SDesign2018 4:b0ce6385d008 660 ///////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 661 void BitBangSPIWrite(const unsigned char regAddr, const unsigned char regData)
SDesign2018 4:b0ce6385d008 662 {
SDesign2018 4:b0ce6385d008 663 unsigned char SPICount; // Counter used to clock out the data
SDesign2018 4:b0ce6385d008 664
SDesign2018 4:b0ce6385d008 665 unsigned char SPIData; // Define a data structure for the SPI data
SDesign2018 4:b0ce6385d008 666 SPI_CS = 0; // Make sure we start with active-low CS high
SDesign2018 4:b0ce6385d008 667 SPI_CLK = 0; // and CK low
SDesign2018 4:b0ce6385d008 668
SDesign2018 4:b0ce6385d008 669 SPIData = regAddr; // Preload the data to be sent with Address
SDesign2018 4:b0ce6385d008 670 SPI_CS = 1; // Set active-low CS low to start the SPI cycle
SDesign2018 4:b0ce6385d008 671
SDesign2018 4:b0ce6385d008 672 for (SPICount = 0; SPICount < 8; SPICount++) // Prepare to clock out the Address byte
SDesign2018 4:b0ce6385d008 673 {
SDesign2018 4:b0ce6385d008 674 if (SPIData & 0x80) // Check for a 1 at MSB
SDesign2018 4:b0ce6385d008 675 MOSI = 1; // and set the MOSI line appropriately
SDesign2018 4:b0ce6385d008 676 else
SDesign2018 4:b0ce6385d008 677 MOSI = 0;
SDesign2018 4:b0ce6385d008 678 SPI_CLK = 1; // Toggle the clock line
SDesign2018 4:b0ce6385d008 679 SPI_CLK = 0;
SDesign2018 4:b0ce6385d008 680 SPIData <<= 1; // Rotate to get the next bit
SDesign2018 4:b0ce6385d008 681 } // and loop back to send the next bit
SDesign2018 4:b0ce6385d008 682
SDesign2018 4:b0ce6385d008 683 // Repeat for the Data byte
SDesign2018 4:b0ce6385d008 684 SPIData = regData; // Preload the data to be sent with Data
SDesign2018 4:b0ce6385d008 685 for (SPICount = 0; SPICount < 8; SPICount++)
SDesign2018 4:b0ce6385d008 686 {
SDesign2018 4:b0ce6385d008 687 if (SPIData & 0x80)
SDesign2018 4:b0ce6385d008 688 MOSI = 1;
SDesign2018 4:b0ce6385d008 689 else
SDesign2018 4:b0ce6385d008 690 MOSI = 0;
SDesign2018 4:b0ce6385d008 691 SPI_CLK = 1;
SDesign2018 4:b0ce6385d008 692 SPI_CLK = 0;
SDesign2018 4:b0ce6385d008 693 SPIData <<= 1; // After each bit, move next bit one to left
SDesign2018 4:b0ce6385d008 694 }
SDesign2018 4:b0ce6385d008 695 SPI_CS = 0;
SDesign2018 4:b0ce6385d008 696 MOSI = 0;
SDesign2018 4:b0ce6385d008 697 }
SDesign2018 4:b0ce6385d008 698 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 699
SDesign2018 4:b0ce6385d008 700
SDesign2018 4:b0ce6385d008 701
SDesign2018 4:b0ce6385d008 702 /*******************************************************************************
SDesign2018 4:b0ce6385d008 703 * BitBangSPIRead for ADXL372 if you wire it up as SPI
SDesign2018 4:b0ce6385d008 704 *
SDesign2018 4:b0ce6385d008 705 *
SDesign2018 4:b0ce6385d008 706 *
SDesign2018 4:b0ce6385d008 707 ******************************************************************************/
SDesign2018 4:b0ce6385d008 708 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 5:c9ab5062cfc3 709 uint8_t BitBangSPIRead (uint8_t regAddr)
SDesign2018 4:b0ce6385d008 710 {
SDesign2018 4:b0ce6385d008 711
SDesign2018 4:b0ce6385d008 712 unsigned char SPICount; // Counter used to clock out the data
SDesign2018 4:b0ce6385d008 713
SDesign2018 5:c9ab5062cfc3 714 uint8_t SPIData;
SDesign2018 4:b0ce6385d008 715
SDesign2018 4:b0ce6385d008 716 SPI_CS = 0; // Make sure we start with active-low CS high
SDesign2018 4:b0ce6385d008 717 SPI_CLK = 0; // and CK low
SDesign2018 4:b0ce6385d008 718 SPIData = regAddr; // Preload the data to be sent with Address and Data
SDesign2018 4:b0ce6385d008 719
SDesign2018 4:b0ce6385d008 720 SPI_CS = 1; // Set active-low CS low to start the SPI cycle
SDesign2018 4:b0ce6385d008 721 for (SPICount = 0; SPICount < 8; SPICount++) // Prepare to clock out the Address and Data
SDesign2018 4:b0ce6385d008 722 {
SDesign2018 4:b0ce6385d008 723 if (SPIData & 0x80)
SDesign2018 4:b0ce6385d008 724 MOSI = 1;
SDesign2018 4:b0ce6385d008 725 else
SDesign2018 4:b0ce6385d008 726 MOSI = 0;
SDesign2018 4:b0ce6385d008 727 SPI_CLK = 1;
SDesign2018 4:b0ce6385d008 728 SPI_CLK = 0;
SDesign2018 4:b0ce6385d008 729 SPIData <<= 1;
SDesign2018 4:b0ce6385d008 730 }// and loop back to send the next bit
SDesign2018 4:b0ce6385d008 731
SDesign2018 4:b0ce6385d008 732 MOSI = 0; // Reset the MOSI data line
SDesign2018 4:b0ce6385d008 733
SDesign2018 4:b0ce6385d008 734 SPIData = 0;
SDesign2018 4:b0ce6385d008 735 for (SPICount = 0; SPICount < 8; SPICount++) // Prepare to clock in the data to be read
SDesign2018 4:b0ce6385d008 736 {
SDesign2018 4:b0ce6385d008 737 SPIData <<=1; // Rotate the data, keep previous bit value
SDesign2018 4:b0ce6385d008 738 SPI_CLK = 1; // Raise the clock to clock the data out of the MAX7456
SDesign2018 4:b0ce6385d008 739 SPIData += SPI_MISO; // Read the data one bit at a time, starting from MISO MSB
SDesign2018 4:b0ce6385d008 740 SPI_CLK = 0; // Drop the clock ready for the next bit
SDesign2018 4:b0ce6385d008 741 }// and loop back for next bit
SDesign2018 4:b0ce6385d008 742 SPI_CS = 0; // Raise CS
SDesign2018 4:b0ce6385d008 743
SDesign2018 5:c9ab5062cfc3 744 return ((uint8_t)SPIData); // Finally return the read data
SDesign2018 4:b0ce6385d008 745 }
SDesign2018 4:b0ce6385d008 746
SDesign2018 4:b0ce6385d008 747 /*******************************************************************************
SDesign2018 4:b0ce6385d008 748 * Not really used at the moment
SDesign2018 4:b0ce6385d008 749 * Not really needed. But keep just in case because I don't want to rewrite it
SDesign2018 4:b0ce6385d008 750 ******************************************************************************/
SDesign2018 4:b0ce6385d008 751 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 12:bdf16bf682ec 752 char twosComplementConversion(char value)
SDesign2018 4:b0ce6385d008 753 {
SDesign2018 4:b0ce6385d008 754 /*
SDesign2018 4:b0ce6385d008 755 * Go from bit 0 to bit 7 and invert them
SDesign2018 4:b0ce6385d008 756 * Then finally add 1
SDesign2018 4:b0ce6385d008 757 */
SDesign2018 4:b0ce6385d008 758 char mask = value & 0x80;
SDesign2018 4:b0ce6385d008 759 if(mask == 0x80){ // Check for sign
SDesign2018 4:b0ce6385d008 760 value = ~value + 1;
SDesign2018 4:b0ce6385d008 761 return value;
SDesign2018 4:b0ce6385d008 762 }
SDesign2018 4:b0ce6385d008 763 return value;
SDesign2018 4:b0ce6385d008 764 }
SDesign2018 4:b0ce6385d008 765 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 766
SDesign2018 4:b0ce6385d008 767
SDesign2018 4:b0ce6385d008 768 /*******************************************************************************
SDesign2018 4:b0ce6385d008 769 * Performs one byte write I2C protocol
SDesign2018 4:b0ce6385d008 770 * PARAM:
SDesign2018 4:b0ce6385d008 771 * registerAddress: register you want access to in device, one byte char hex format
SDesign2018 4:b0ce6385d008 772 * data: one byte data that you want to write to device register
SDesign2018 4:b0ce6385d008 773 * Return:
SDesign2018 4:b0ce6385d008 774 * 0: failure at writing i2c address
SDesign2018 4:b0ce6385d008 775 * 1: successful write
SDesign2018 4:b0ce6385d008 776 * 2: failure at writing data
SDesign2018 4:b0ce6385d008 777 * 3: failure at writing register address
SDesign2018 4:b0ce6385d008 778 ******************************************************************************/
SDesign2018 4:b0ce6385d008 779 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 780 int ADT7410Write(unsigned char registerAddress, unsigned char data){
SDesign2018 4:b0ce6385d008 781 int flag;
SDesign2018 4:b0ce6385d008 782 ADT7410.start();
SDesign2018 4:b0ce6385d008 783 flag = ADT7410.write(ADT7410_Address_8BIT);
SDesign2018 4:b0ce6385d008 784 if(flag == 1)
SDesign2018 4:b0ce6385d008 785 {
SDesign2018 4:b0ce6385d008 786 pc.printf("Write to I2C address success\n\r");
SDesign2018 4:b0ce6385d008 787 wait(0.1);
SDesign2018 4:b0ce6385d008 788 flag = ADT7410.write(registerAddress);
SDesign2018 4:b0ce6385d008 789 if(flag == 1)
SDesign2018 4:b0ce6385d008 790 {
SDesign2018 4:b0ce6385d008 791 pc.printf("Write to register 0x%x address success\n\r", registerAddress);
SDesign2018 4:b0ce6385d008 792 flag = ADT7410.write(data);
SDesign2018 4:b0ce6385d008 793 if(flag == 1)
SDesign2018 4:b0ce6385d008 794 {
SDesign2018 4:b0ce6385d008 795 pc.printf("Writing data 0x%x to register address success\n\r", data);
SDesign2018 4:b0ce6385d008 796 ADT7410.stop();
SDesign2018 4:b0ce6385d008 797 return 1;
SDesign2018 4:b0ce6385d008 798 }else {ADT7410.stop(); return 2;}
SDesign2018 4:b0ce6385d008 799 }else {ADT7410.stop(); return 3;}
SDesign2018 4:b0ce6385d008 800 }else ADT7410.stop();
SDesign2018 4:b0ce6385d008 801
SDesign2018 4:b0ce6385d008 802 return 0;
SDesign2018 4:b0ce6385d008 803 }
SDesign2018 4:b0ce6385d008 804 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 805
SDesign2018 4:b0ce6385d008 806 /*******************************************************************************
SDesign2018 4:b0ce6385d008 807 * I2C Read function for ADT7410 Temperature sensor
SDesign2018 4:b0ce6385d008 808 * Param:
SDesign2018 4:b0ce6385d008 809 * hex: hexadecimal representation for desired register
SDesign2018 4:b0ce6385d008 810 * Return:
SDesign2018 4:b0ce6385d008 811 * Char pointer to the array of data values.
SDesign2018 4:b0ce6385d008 812 * Could also change from a char pointer to a uint8_t pointer.
SDesign2018 4:b0ce6385d008 813 *
SDesign2018 4:b0ce6385d008 814 ******************************************************************************/
SDesign2018 4:b0ce6385d008 815 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 816 char * ADT7410Read(int hex){
SDesign2018 4:b0ce6385d008 817 //short int convertedVal;
SDesign2018 4:b0ce6385d008 818 char data[2] = {0, 0};
SDesign2018 4:b0ce6385d008 819 char cmd[1];
SDesign2018 4:b0ce6385d008 820 cmd[0] = hex;
SDesign2018 4:b0ce6385d008 821 //pc.printf("Register Addres is: %x \n\r", cmd[0]);
SDesign2018 4:b0ce6385d008 822 if(ADT7410.write(ADT7410_Address_8BIT, cmd,1) == 0){
SDesign2018 4:b0ce6385d008 823 if(ADT7410.read(ADT7410_Address_8BIT, data, 2) == 0){
SDesign2018 4:b0ce6385d008 824
SDesign2018 4:b0ce6385d008 825 return data;
SDesign2018 4:b0ce6385d008 826 //return (data[0] << 8 | data[1])>>3; // Explained here: https://stackoverflow.com/a/141576 SOOO GREAT
SDesign2018 4:b0ce6385d008 827
SDesign2018 4:b0ce6385d008 828 }else {pc.printf("Failed to read \n\r"); return data;}
SDesign2018 4:b0ce6385d008 829 }else {pc.printf("Failed to write \n\r"); return data;}
SDesign2018 4:b0ce6385d008 830
SDesign2018 4:b0ce6385d008 831 }
SDesign2018 4:b0ce6385d008 832 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 833
SDesign2018 4:b0ce6385d008 834
SDesign2018 4:b0ce6385d008 835 /*******************************************************************************
SDesign2018 4:b0ce6385d008 836 * ADXL372 reset function
SDesign2018 4:b0ce6385d008 837 * Resets all registers and settings back to default
SDesign2018 4:b0ce6385d008 838 * Basically the same as the previous ADXL372 I2C write function
SDesign2018 4:b0ce6385d008 839 *
SDesign2018 4:b0ce6385d008 840 ******************************************************************************/
SDesign2018 4:b0ce6385d008 841 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 4:b0ce6385d008 842 void ADXL372Reset(void){
SDesign2018 4:b0ce6385d008 843 int flag;
SDesign2018 4:b0ce6385d008 844 //--------- One full writing cycle for ADXL372 for Z Enable ------------------//
SDesign2018 4:b0ce6385d008 845 /* '0' - NAK was received
SDesign2018 4:b0ce6385d008 846 * '1' - ACK was received, <---- This good
SDesign2018 4:b0ce6385d008 847 * '2' - timeout
SDesign2018 4:b0ce6385d008 848 */
SDesign2018 4:b0ce6385d008 849 ADXL372.start();
SDesign2018 4:b0ce6385d008 850 flag = ADXL372.write(ADXL372_Address_8bit | 0);
SDesign2018 4:b0ce6385d008 851 if(flag == 1)
SDesign2018 4:b0ce6385d008 852 {
SDesign2018 4:b0ce6385d008 853 //pc.printf("Write to I2C address success\n\r");
SDesign2018 4:b0ce6385d008 854
SDesign2018 4:b0ce6385d008 855 flag = ADXL372.write(0x41);
SDesign2018 4:b0ce6385d008 856 if(flag == 1)
SDesign2018 4:b0ce6385d008 857 {
SDesign2018 4:b0ce6385d008 858 //pc.printf("Write to 0x41 register address success\n\r");
SDesign2018 4:b0ce6385d008 859 flag = ADXL372.write(0x52); // Set bit 0
SDesign2018 4:b0ce6385d008 860 if(flag == 1)
SDesign2018 4:b0ce6385d008 861 {
SDesign2018 4:b0ce6385d008 862 pc.printf("Everything has been reset\n\r");
SDesign2018 4:b0ce6385d008 863 ADXL372.stop();
SDesign2018 4:b0ce6385d008 864 }
SDesign2018 4:b0ce6385d008 865 }
SDesign2018 4:b0ce6385d008 866 }
SDesign2018 4:b0ce6385d008 867 else ADXL372.stop();
SDesign2018 4:b0ce6385d008 868 // ---------------- End of writing cycle --------------------------//
SDesign2018 4:b0ce6385d008 869 }
SDesign2018 4:b0ce6385d008 870 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 6:3b41238872a8 871
SDesign2018 10:db20118b7d32 872 /*
SDesign2018 10:db20118b7d32 873 *
SDesign2018 10:db20118b7d32 874 * Self-test to see if the accelerometer is working as intended
SDesign2018 10:db20118b7d32 875 * Wait 300 ms.
SDesign2018 10:db20118b7d32 876 * Check bit 2 for a 1 for success. Bit 1 for completion of self-test.
SDesign2018 10:db20118b7d32 877 * Returns whole register
SDesign2018 10:db20118b7d32 878 */
SDesign2018 10:db20118b7d32 879 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 10:db20118b7d32 880 void I2CSelfTest(void){
SDesign2018 10:db20118b7d32 881 char *result;
SDesign2018 10:db20118b7d32 882 uint8_t check;
SDesign2018 10:db20118b7d32 883 accelerometerI2CWrite(0x3F, 0x03);
SDesign2018 10:db20118b7d32 884 accelerometerI2CWrite(0x40, 0x01);
SDesign2018 10:db20118b7d32 885 wait(0.3);
SDesign2018 10:db20118b7d32 886 result = accelerometerI2CRead(0x40);
SDesign2018 10:db20118b7d32 887 check = result[0];
SDesign2018 10:db20118b7d32 888 if(check & 0x04){
SDesign2018 10:db20118b7d32 889 pc.printf("Passed\n\r");
SDesign2018 10:db20118b7d32 890 }else {pc.printf("FAILED\n\r");}
SDesign2018 10:db20118b7d32 891 }
SDesign2018 17:0a8d151af3c6 892 ////////////////////////////////////////////////////////////////////////////////g
SDesign2018 10:db20118b7d32 893
SDesign2018 6:3b41238872a8 894 // Used to clear serial buffer in beginning
SDesign2018 6:3b41238872a8 895 ////////////////////////////////////////////////////////////////////////////////
SDesign2018 6:3b41238872a8 896 void flushSerialBuffer(void) { char char1 = 0; while (pc.readable()) { char1 = pc.getc(); } return; }