Maxim Integrated / MAX17055_EZconfig

This is a library for the MAX17055 Li+ Battery Fuel Gauge.

Dependents:   Low_Power_Long_Distance_IR_Vision_Robot MAX17055_EZconfig MAX17055_EZconfig_Sample Low_Power_Long_Distance_IR_Vision_Robot

Fork of max17055 by Maxim Integrated

max17055.cpp@18:37bca022d144, 2018-10-10 (annotated)

Committer:
fneirab
Date:
Wed Oct 10 00:35:12 2018 +0000
Revision:
18:37bca022d144
Parent:
17:7447aaa9c121
Child:
19:20590e00feab
comments and clean up

Who changed what in which revision?

UserRevisionLine numberNew contents of line
fneirab 9:f29d5e49b190 1 /*******************************************************************************
fneirab 9:f29d5e49b190 2 * Copyright (C) 2018 Maxim Integrated Products, Inc., All Rights Reserved.
fneirab 4:a4d6ae2182c2 3 *
fneirab 4:a4d6ae2182c2 4 * Permission is hereby granted, free of charge, to any person obtaining a
fneirab 4:a4d6ae2182c2 5 * copy of this software and associated documentation files (the "Software"),
fneirab 4:a4d6ae2182c2 6 * to deal in the Software without restriction, including without limitation
fneirab 4:a4d6ae2182c2 7 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
fneirab 4:a4d6ae2182c2 8 * and/or sell copies of the Software, and to permit persons to whom the
fneirab 4:a4d6ae2182c2 9 * Software is furnished to do so, subject to the following conditions:
fneirab 4:a4d6ae2182c2 10 *
fneirab 4:a4d6ae2182c2 11 * The above copyright notice and this permission notice shall be included
fneirab 4:a4d6ae2182c2 12 * in all copies or substantial portions of the Software.
fneirab 4:a4d6ae2182c2 13 *
fneirab 4:a4d6ae2182c2 14 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
fneirab 4:a4d6ae2182c2 15 * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
fneirab 4:a4d6ae2182c2 16 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
fneirab 4:a4d6ae2182c2 17 * IN NO EVENT SHALL MAXIM INTEGRATED BE LIABLE FOR ANY CLAIM, DAMAGES
fneirab 4:a4d6ae2182c2 18 * OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
fneirab 4:a4d6ae2182c2 19 * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
fneirab 4:a4d6ae2182c2 20 * OTHER DEALINGS IN THE SOFTWARE.
fneirab 4:a4d6ae2182c2 21 *
fneirab 4:a4d6ae2182c2 22 * Except as contained in this notice, the name of Maxim Integrated
fneirab 4:a4d6ae2182c2 23 * Products, Inc. shall not be used except as stated in the Maxim Integrated
fneirab 4:a4d6ae2182c2 24 * Products, Inc. Branding Policy.
fneirab 4:a4d6ae2182c2 25 *
fneirab 4:a4d6ae2182c2 26 * The mere transfer of this software does not imply any licenses
fneirab 4:a4d6ae2182c2 27 * of trade secrets, proprietary technology, copyrights, patents,
fneirab 4:a4d6ae2182c2 28 * trademarks, maskwork rights, or any other form of intellectual
fneirab 4:a4d6ae2182c2 29 * property whatsoever. Maxim Integrated Products, Inc. retains all
fneirab 4:a4d6ae2182c2 30 * ownership rights.
fneirab 9:f29d5e49b190 31 *******************************************************************************
fneirab 9:f29d5e49b190 32 */
fneirab 0:80c39eb8f3ba 33
fneirab 0:80c39eb8f3ba 34 #include "mbed.h"
fneirab 0:80c39eb8f3ba 35 #include "max17055.h"
fneirab 0:80c39eb8f3ba 36
fneirab 9:f29d5e49b190 37 /* POR Mask */
fneirab 9:f29d5e49b190 38 #define MAX17055_POR_MASK (0xFFFD)
fneirab 17:7447aaa9c121 39 #define MAX17055_CYCLE_MASK (0x0002)
fneirab 17:7447aaa9c121 40
fneirab 9:f29d5e49b190 41
fneirab 5:a18a189588dc 42 /* MODELCFG register bits */
fneirab 5:a18a189588dc 43 #define MAX17055_MODELCFG_REFRESH (1 << 15)
fneirab 5:a18a189588dc 44
fneirab 5:a18a189588dc 45
fneirab 5:a18a189588dc 46 /* FSTAT register bits */
fneirab 5:a18a189588dc 47 #define MAX17055_FSTAT_DNR (1)
fneirab 5:a18a189588dc 48
fneirab 11:bdbd3104995b 49 /* LIBRARY FUNCTION SUCCESS*/
fneirab 11:bdbd3104995b 50 #define F_SUCCESS_0 0
fneirab 11:bdbd3104995b 51
fneirab 17:7447aaa9c121 52 /* LIBRARY FUNCTION ERROR CODES */
fneirab 12:519a18fc3b28 53 #define F_ERROR_1 -1 //-1 if I2C read/write errors exist
fneirab 11:bdbd3104995b 54 #define F_ERROR_2 -2 //-2 if device is not present
fneirab 11:bdbd3104995b 55 #define F_ERROR_3 -3 //-3 if function error
fneirab 11:bdbd3104995b 56 #define F_ERROR_4 -4 //-4 if other error
fneirab 11:bdbd3104995b 57 #define F_ERROR_5 -5 //-5 if POR not detected
fneirab 4:a4d6ae2182c2 58
fneirab 0:80c39eb8f3ba 59
fneirab 5:a18a189588dc 60
fneirab 11:bdbd3104995b 61 /**
fneirab 11:bdbd3104995b 62 * @brief max17055 Constructor
fneirab 11:bdbd3104995b 63 * @details max17055 Constructor with battery and i2c as parameters
fneirab 11:bdbd3104995b 64 */
fneirab 5:a18a189588dc 65 MAX17055::MAX17055(I2C &i2c):
fneirab 5:a18a189588dc 66 m_i2cBus(i2c)
fneirab 0:80c39eb8f3ba 67 {
fneirab 5:a18a189588dc 68 //empty block
fneirab 0:80c39eb8f3ba 69 }
fneirab 0:80c39eb8f3ba 70
fneirab 11:bdbd3104995b 71 /**
fneirab 11:bdbd3104995b 72 * @brief Fuel Gauge Destructor
fneirab 11:bdbd3104995b 73 */
fneirab 0:80c39eb8f3ba 74 MAX17055::~MAX17055()
fneirab 0:80c39eb8f3ba 75 {
fneirab 0:80c39eb8f3ba 76 //empty block
fneirab 0:80c39eb8f3ba 77 }
fneirab 5:a18a189588dc 78
fneirab 0:80c39eb8f3ba 79 /**
fneirab 11:bdbd3104995b 80 * @brief Writes a register.
fneirab 11:bdbd3104995b 81 *
fneirab 11:bdbd3104995b 82 * @param[in] reg_addr The register address
fneirab 11:bdbd3104995b 83 * @param[in] reg_data The register data
fneirab 11:bdbd3104995b 84 *
fneirab 11:bdbd3104995b 85 * @retval 0 on success
fneirab 11:bdbd3104995b 86 * @retval non-0 for errors
fneirab 11:bdbd3104995b 87 */
fneirab 0:80c39eb8f3ba 88 int MAX17055::writeReg(Registers_e reg_addr, uint16_t reg_data)
fneirab 0:80c39eb8f3ba 89 {
fneirab 0:80c39eb8f3ba 90
fneirab 7:479a36909ced 91 uint16_t mask = 0x00FF;
fneirab 1:a031f0c6a71e 92 uint8_t dataLSB;
fneirab 1:a031f0c6a71e 93 uint8_t dataMSB;
fneirab 5:a18a189588dc 94
fneirab 7:479a36909ced 95 dataLSB = reg_data & mask;
fneirab 7:479a36909ced 96 dataMSB = (reg_data >> 8) & mask;
fneirab 5:a18a189588dc 97
fneirab 7:479a36909ced 98 char addr_plus_data[3] = {reg_addr, dataLSB, dataMSB};
fneirab 5:a18a189588dc 99
fneirab 11:bdbd3104995b 100 if ( m_i2cBus.write(I2C_W_ADRS, addr_plus_data, 3, false) == F_SUCCESS_0)
fneirab 11:bdbd3104995b 101 return F_SUCCESS_0;
fneirab 0:80c39eb8f3ba 102 else
fneirab 11:bdbd3104995b 103 return F_ERROR_1;
fneirab 11:bdbd3104995b 104 }
fneirab 0:80c39eb8f3ba 105
fneirab 0:80c39eb8f3ba 106 /**
fneirab 11:bdbd3104995b 107 * @brief Reads from MAX17055 register.
fneirab 11:bdbd3104995b 108 *
fneirab 11:bdbd3104995b 109 * @param[in] reg_addr The register address
fneirab 11:bdbd3104995b 110 * @param value The value
fneirab 11:bdbd3104995b 111 *
fneirab 11:bdbd3104995b 112 * @retval 0 on success
fneirab 11:bdbd3104995b 113 * @retval non-0 for errors
fneirab 11:bdbd3104995b 114 */
fneirab 1:a031f0c6a71e 115 int32_t MAX17055::readReg(Registers_e reg_addr, uint16_t &value)
fneirab 0:80c39eb8f3ba 116 {
fneirab 0:80c39eb8f3ba 117 int32_t result;
fneirab 7:479a36909ced 118 uint16_t mask = 0x00FF;
fneirab 1:a031f0c6a71e 119 char local_data[1];
fneirab 0:80c39eb8f3ba 120 local_data[0] = reg_addr;
fneirab 1:a031f0c6a71e 121 char read_data[2];
fneirab 5:a18a189588dc 122
fneirab 0:80c39eb8f3ba 123 result = m_i2cBus.write(I2C_W_ADRS, local_data, 1);
fneirab 11:bdbd3104995b 124 if(result == F_SUCCESS_0) {
fneirab 1:a031f0c6a71e 125 result = m_i2cBus.read(I2C_R_ADRS, read_data , 2, false);
fneirab 11:bdbd3104995b 126 if (result == F_SUCCESS_0) {
fneirab 7:479a36909ced 127 value = ( ((read_data[1] & mask) << 8) + (read_data[0]));
fneirab 11:bdbd3104995b 128 result = F_SUCCESS_0;
fneirab 5:a18a189588dc 129 }
fneirab 0:80c39eb8f3ba 130 }
fneirab 0:80c39eb8f3ba 131 return result;
fneirab 0:80c39eb8f3ba 132 }
fneirab 0:80c39eb8f3ba 133
fneirab 1:a031f0c6a71e 134 /**
fneirab 17:7447aaa9c121 135 * @brief Reads an specified register from the MAX17055 register.
fneirab 17:7447aaa9c121 136 *
fneirab 17:7447aaa9c121 137 * @param[in] reg_addr The register address
fneirab 17:7447aaa9c121 138 * @param value The value
fneirab 17:7447aaa9c121 139 *
fneirab 17:7447aaa9c121 140 * @retval reg_data register data
fneirab 17:7447aaa9c121 141 * @retval statusRead non-0 for errors
fneirab 17:7447aaa9c121 142 */
fneirab 17:7447aaa9c121 143
fneirab 17:7447aaa9c121 144 int16_t MAX17055::get_regInfo(Registers_e reg_addr)
fneirab 17:7447aaa9c121 145 {
fneirab 17:7447aaa9c121 146 uint16_t read_data;
fneirab 17:7447aaa9c121 147 int statusRead;
fneirab 17:7447aaa9c121 148
fneirab 17:7447aaa9c121 149 statusRead = readReg(reg_addr, read_data);
fneirab 17:7447aaa9c121 150 if (statusRead != F_SUCCESS_0)
fneirab 17:7447aaa9c121 151 return statusRead;
fneirab 17:7447aaa9c121 152 else
fneirab 17:7447aaa9c121 153 return read_data;
fneirab 17:7447aaa9c121 154
fneirab 17:7447aaa9c121 155 }
fneirab 17:7447aaa9c121 156
fneirab 17:7447aaa9c121 157 /**
fneirab 11:bdbd3104995b 158 * @brief Write and Verify a MAX17055 register
fneirab 11:bdbd3104995b 159 * @par Details
fneirab 12:519a18fc3b28 160 * This function writes and verifies if the writing process was successful
fneirab 17:7447aaa9c121 161 *
fneirab 11:bdbd3104995b 162 * @param[in] reg_addr - register address
fneirab 11:bdbd3104995b 163 * @param[out] reg_data - the variable that contains the data to write
fneirab 11:bdbd3104995b 164 * to the register address
fneirab 11:bdbd3104995b 165 *
fneirab 11:bdbd3104995b 166 * @retval 0 on success
fneirab 12:519a18fc3b28 167 * @retval non-0 for errors
fneirab 11:bdbd3104995b 168 */
fneirab 5:a18a189588dc 169 int MAX17055::write_and_verify_reg(Registers_e reg_addr, uint16_t reg_data)
fneirab 5:a18a189588dc 170 {
fneirab 1:a031f0c6a71e 171 int retries = 8;
fneirab 1:a031f0c6a71e 172 int ret;
fneirab 1:a031f0c6a71e 173 int statusRead;
fneirab 1:a031f0c6a71e 174 int statusWrite;
fneirab 1:a031f0c6a71e 175 uint16_t read_data;
fneirab 5:a18a189588dc 176
fneirab 1:a031f0c6a71e 177 do {
fneirab 1:a031f0c6a71e 178 statusWrite = writeReg(reg_addr, reg_data);
fneirab 11:bdbd3104995b 179 if (statusWrite != F_SUCCESS_0)
fneirab 17:7447aaa9c121 180 ret = F_ERROR_1;
fneirab 1:a031f0c6a71e 181 wait_ms(3);
fneirab 5:a18a189588dc 182 statusRead = readReg(reg_addr, read_data);
fneirab 11:bdbd3104995b 183 if (statusRead != F_SUCCESS_0)
fneirab 17:7447aaa9c121 184 ret = F_ERROR_1;
fneirab 5:a18a189588dc 185 if (read_data != reg_data) {
fneirab 17:7447aaa9c121 186 ret = F_ERROR_3;
fneirab 1:a031f0c6a71e 187 retries--;
fneirab 1:a031f0c6a71e 188 }
fneirab 5:a18a189588dc 189 } while (retries && read_data != reg_data);
fneirab 5:a18a189588dc 190
fneirab 11:bdbd3104995b 191 if (ret!=F_SUCCESS_0)
fneirab 1:a031f0c6a71e 192 return ret;
fneirab 7:479a36909ced 193 else
fneirab 11:bdbd3104995b 194 return F_SUCCESS_0;
fneirab 1:a031f0c6a71e 195 }
fneirab 2:ff7db397b70f 196
fneirab 2:ff7db397b70f 197 /**
fneirab 11:bdbd3104995b 198 * @brief Initialization Function for MAX17055.
fneirab 11:bdbd3104995b 199 * @par Details
fneirab 12:519a18fc3b28 200 * This function initializes the MAX17055 for the implementation of the EZconfig model.\n
fneirab 17:7447aaa9c121 201 * The library needs to be customized for the implementation of customize model.\n
fneirab 17:7447aaa9c121 202 *
fneirab 17:7447aaa9c121 203 * @retval 0 on success
fneirab 11:bdbd3104995b 204 * @retval non-0 for errors
fneirab 11:bdbd3104995b 205 */
fneirab 7:479a36909ced 206 int MAX17055::init(platform_data des_data)
fneirab 2:ff7db397b70f 207 {
fneirab 6:5ced10109ebf 208
fneirab 17:7447aaa9c121 209 int ret;
fneirab 9:f29d5e49b190 210 int time_out = 10;
fneirab 17:7447aaa9c121 211 uint16_t hibcfg_value;
fneirab 5:a18a189588dc 212
fneirab 5:a18a189588dc 213
fneirab 17:7447aaa9c121 214 // status = readReg(VERSION_REG, read_data);
fneirab 17:7447aaa9c121 215 // if (status != F_SUCCESS_0)
fneirab 17:7447aaa9c121 216 // return status;
fneirab 5:a18a189588dc 217
fneirab 12:519a18fc3b28 218 ///STEP 0. Check for POR (Skip load model if POR bit is cleared)
fneirab 5:a18a189588dc 219
fneirab 11:bdbd3104995b 220 if (check_POR_func() == F_ERROR_5)
fneirab 11:bdbd3104995b 221 return F_ERROR_5; //POR not detected. Skip Initialization.
fneirab 2:ff7db397b70f 222
fneirab 12:519a18fc3b28 223 ///STEP 1. Check if FStat.DNR == 0 (Do not continue until FSTAT.DNR == 0)
fneirab 7:479a36909ced 224 ret = poll_flag_clear(FSTAT_REG, MAX17055_FSTAT_DNR, time_out);
fneirab 11:bdbd3104995b 225 if (ret < F_SUCCESS_0) {
fneirab 6:5ced10109ebf 226 return ret;
fneirab 3:f77a8345b0e3 227 }
fneirab 5:a18a189588dc 228
fneirab 12:519a18fc3b28 229 ///STEP 1.2. Force exit from hibernate
fneirab 12:519a18fc3b28 230 hibcfg_value = forcedExitHiberMode();
fneirab 7:479a36909ced 231
fneirab 5:a18a189588dc 232
fneirab 12:519a18fc3b28 233 ///STEP 2. Initialize configuration
fneirab 17:7447aaa9c121 234 ///STEP 2.1. Load EZ Config
fneirab 17:7447aaa9c121 235 EZconfig(des_data);
fneirab 5:a18a189588dc 236
fneirab 17:7447aaa9c121 237 ///STEP 2.2. Poll ModelCFG.ModelRefresh bit for clear
fneirab 17:7447aaa9c121 238 ret = poll_flag_clear(MODELCFG_REG, MAX17055_MODELCFG_REFRESH, time_out);
fneirab 17:7447aaa9c121 239 if(ret < F_SUCCESS_0) {
fneirab 17:7447aaa9c121 240 return ret;
fneirab 5:a18a189588dc 241 }
fneirab 12:519a18fc3b28 242 ///STEP3. Restore original HibCfg
fneirab 7:479a36909ced 243 writeReg(HIBCFG_REG, hibcfg_value);
fneirab 5:a18a189588dc 244
fneirab 5:a18a189588dc 245 /* Clear Status.POR */
fneirab 9:f29d5e49b190 246 ret = clear_POR_bit();
fneirab 11:bdbd3104995b 247 if (ret < F_SUCCESS_0)
fneirab 17:7447aaa9c121 248 return ret; //See errors
fneirab 11:bdbd3104995b 249 return F_SUCCESS_0;
fneirab 5:a18a189588dc 250 }
fneirab 5:a18a189588dc 251
fneirab 9:f29d5e49b190 252 /**
fneirab 11:bdbd3104995b 253 * @brief Check POR function
fneirab 11:bdbd3104995b 254 * @par Details
fneirab 11:bdbd3104995b 255 * This function check is there was a power on reset event for the
fneirab 11:bdbd3104995b 256 * MAX17055
fneirab 11:bdbd3104995b 257 *
fneirab 11:bdbd3104995b 258 * @retval 0 on success (POR detected)
fneirab 11:bdbd3104995b 259 * @retval non-0 for errors (POR not detected)
fneirab 17:7447aaa9c121 260 *
fneirab 11:bdbd3104995b 261 */
fneirab 9:f29d5e49b190 262 int MAX17055::check_POR_func()
fneirab 9:f29d5e49b190 263 {
fneirab 9:f29d5e49b190 264 uint16_t read_data;
fneirab 17:7447aaa9c121 265
fneirab 9:f29d5e49b190 266 readReg(STATUS_REG, read_data);
fneirab 17:7447aaa9c121 267 printf("STATUS REF = %X \r\n", read_data);
fneirab 17:7447aaa9c121 268 if (!(read_data & MAX17055_STATUS_POR ) ) {
fneirab 11:bdbd3104995b 269 return F_ERROR_5; //POR not detected.
fneirab 17:7447aaa9c121 270 } else
fneirab 11:bdbd3104995b 271 return F_SUCCESS_0;
fneirab 9:f29d5e49b190 272 }
fneirab 9:f29d5e49b190 273
fneirab 9:f29d5e49b190 274 /**
fneirab 11:bdbd3104995b 275 * @brief clear POR bit function
fneirab 11:bdbd3104995b 276 * @par Details
fneirab 12:519a18fc3b28 277 * This function clear the indicating bit for POR - MAX17055
fneirab 11:bdbd3104995b 278 *
fneirab 11:bdbd3104995b 279 * @retval 0 for Success
fneirab 11:bdbd3104995b 280 * @retval non-0 for errors
fneirab 11:bdbd3104995b 281 */
fneirab 9:f29d5e49b190 282 int MAX17055::clear_POR_bit()
fneirab 9:f29d5e49b190 283 {
fneirab 17:7447aaa9c121 284 int status;
fneirab 17:7447aaa9c121 285 uint16_t read_data;
fneirab 9:f29d5e49b190 286
fneirab 9:f29d5e49b190 287
fneirab 9:f29d5e49b190 288 status = readReg(STATUS_REG, read_data);
fneirab 11:bdbd3104995b 289 if (status != F_SUCCESS_0)
fneirab 11:bdbd3104995b 290 return F_ERROR_2; //Device is not present in the i2c Bus
fneirab 9:f29d5e49b190 291 status = write_and_verify_reg(STATUS_REG, (read_data & MAX17055_POR_MASK));
fneirab 11:bdbd3104995b 292 if (status != F_SUCCESS_0)
fneirab 11:bdbd3104995b 293 return F_ERROR_1; //read or write error
fneirab 17:7447aaa9c121 294 else
fneirab 11:bdbd3104995b 295 return F_SUCCESS_0;
fneirab 9:f29d5e49b190 296 }
fneirab 5:a18a189588dc 297
fneirab 5:a18a189588dc 298 /**
fneirab 17:7447aaa9c121 299 * @brief Poll Flag clear Function.
fneirab 11:bdbd3104995b 300 * @par Details
fneirab 11:bdbd3104995b 301 * This function clears status flags for the MAX17055
fneirab 11:bdbd3104995b 302 *
fneirab 11:bdbd3104995b 303 * @param[in] reg_addr - register address
fneirab 11:bdbd3104995b 304 * @param[in] mask - register address
fneirab 11:bdbd3104995b 305 * @param[in] timeout - register data
fneirab 11:bdbd3104995b 306 *
fneirab 17:7447aaa9c121 307 * @retval 0 on success
fneirab 11:bdbd3104995b 308 * @retval non-0 negative for errors
fneirab 11:bdbd3104995b 309 */
fneirab 7:479a36909ced 310 int MAX17055::poll_flag_clear (Registers_e reg_addr, int mask, int timeout)
fneirab 5:a18a189588dc 311 {
fneirab 5:a18a189588dc 312 uint16_t data;
fneirab 5:a18a189588dc 313 int ret;
fneirab 5:a18a189588dc 314
fneirab 5:a18a189588dc 315 do {
fneirab 9:f29d5e49b190 316 wait_ms(1);
fneirab 6:5ced10109ebf 317 ret = readReg(reg_addr, data);
fneirab 11:bdbd3104995b 318 if(ret < F_SUCCESS_0)
fneirab 11:bdbd3104995b 319 return F_ERROR_1;
fneirab 5:a18a189588dc 320
fneirab 5:a18a189588dc 321 if(!(data & mask))
fneirab 11:bdbd3104995b 322 return F_SUCCESS_0;
fneirab 5:a18a189588dc 323
fneirab 9:f29d5e49b190 324 timeout -= 1;
fneirab 5:a18a189588dc 325 } while(timeout > 0);
fneirab 5:a18a189588dc 326
fneirab 11:bdbd3104995b 327 return F_ERROR_4;
fneirab 5:a18a189588dc 328 }
fneirab 5:a18a189588dc 329
fneirab 2:ff7db397b70f 330 /**
fneirab 11:bdbd3104995b 331 * @brief Get Temperature Function from the MAX17055 TEMP register.
fneirab 11:bdbd3104995b 332 * @par Details
fneirab 11:bdbd3104995b 333 * This function sends a request to access the TEMP register
fneirab 17:7447aaa9c121 334 * of the MAX17055, which reflects the temperature measured for the fuel gauge.
fneirab 11:bdbd3104995b 335 * The temperature values will reflect the Config Register (0x1D) selections for Tsel bit (D15).
fneirab 11:bdbd3104995b 336 * For this library the setting are for die temperature.
fneirab 11:bdbd3104995b 337 * The MAX32620FTHR thermistor bias pin is not connected. The biasing of the thermistor is
fneirab 17:7447aaa9c121 338 * done by the MAX77650. See MAX77650 library for how to enable the thermistor biasing.
fneirab 11:bdbd3104995b 339 *
fneirab 17:7447aaa9c121 340 *
fneirab 11:bdbd3104995b 341 * @retval temp - Temperature value from TEMP register in &deg;C
fneirab 11:bdbd3104995b 342 * @retval non-0 negative values check for errors
fneirab 11:bdbd3104995b 343 */
fneirab 7:479a36909ced 344 int MAX17055::get_temperature()
fneirab 2:ff7db397b70f 345 {
fneirab 5:a18a189588dc 346
fneirab 2:ff7db397b70f 347 int ret;
fneirab 11:bdbd3104995b 348 uint16_t temp;
fneirab 5:a18a189588dc 349
fneirab 11:bdbd3104995b 350 ret = readReg(TEMP_REG, temp);
fneirab 11:bdbd3104995b 351 if (ret < F_SUCCESS_0)
fneirab 2:ff7db397b70f 352 return ret;
fneirab 2:ff7db397b70f 353
fneirab 2:ff7db397b70f 354 /* The value is signed. */
fneirab 11:bdbd3104995b 355 if (temp & 0x8000)
fneirab 11:bdbd3104995b 356 temp |= 0xFFFF0000;
fneirab 2:ff7db397b70f 357
fneirab 2:ff7db397b70f 358 /* The value is converted into centigrade scale */
fneirab 2:ff7db397b70f 359 /* Units of LSB = 1 / 256 degree Celsius */
fneirab 11:bdbd3104995b 360 temp >>= 8;
fneirab 2:ff7db397b70f 361
fneirab 11:bdbd3104995b 362 return temp;
fneirab 5:a18a189588dc 363 }
fneirab 3:f77a8345b0e3 364
fneirab 3:f77a8345b0e3 365 /**
fneirab 11:bdbd3104995b 366 * @brief Forced Exit Hibernate Mode Function for MAX17055
fneirab 11:bdbd3104995b 367 * @par Details
fneirab 11:bdbd3104995b 368 * This function executes a force exit from hibernate mode.
fneirab 11:bdbd3104995b 369 *
fneirab 12:519a18fc3b28 370 * @retval HibCFG original value before forced Exit Hibernate mode *
fneirab 11:bdbd3104995b 371 */
fneirab 12:519a18fc3b28 372 uint16_t MAX17055::forcedExitHiberMode()
fneirab 3:f77a8345b0e3 373 {
fneirab 3:f77a8345b0e3 374 uint16_t hibcfg;
fneirab 5:a18a189588dc 375
fneirab 5:a18a189588dc 376 /* Force exit from hibernate */
fneirab 3:f77a8345b0e3 377 //STEP 0: Store original HibCFG value
fneirab 7:479a36909ced 378 readReg(HIBCFG_REG, hibcfg);
fneirab 3:f77a8345b0e3 379
fneirab 12:519a18fc3b28 380 //STEP 1: Write to Soft-Wakeup Command Register
fneirab 12:519a18fc3b28 381 writeReg(VFSOC0_QH0_LOCK_REG, 0x90); //Soft-Wakeup from hibernate
fneirab 5:a18a189588dc 382
fneirab 3:f77a8345b0e3 383 //STEP 2: Write to Hibernate Configuration register
fneirab 7:479a36909ced 384 writeReg(HIBCFG_REG, 0x0); //disable hibernate mode
fneirab 5:a18a189588dc 385
fneirab 12:519a18fc3b28 386 //STEP 3:Write to Soft-Wakeup Command Register
fneirab 12:519a18fc3b28 387 writeReg(VFSOC0_QH0_LOCK_REG, 0x0); //Clear All commands
fneirab 5:a18a189588dc 388
fneirab 3:f77a8345b0e3 389 return hibcfg;
fneirab 5:a18a189588dc 390 }
fneirab 7:479a36909ced 391
fneirab 7:479a36909ced 392 /**
fneirab 14:519754351400 393 * @brief EZ Config function
fneirab 11:bdbd3104995b 394 * @par Details
fneirab 12:519a18fc3b28 395 * This function implements the steps for the EZ config m5 FuelGauge
fneirab 12:519a18fc3b28 396 * @param[in] des_data - Plataform_data struct with information about the design.
fneirab 11:bdbd3104995b 397 * @retval 0 on success
fneirab 11:bdbd3104995b 398 * @retval non-zero for errors
fneirab 11:bdbd3104995b 399 */
fneirab 13:fc91b283e689 400 uint16_t MAX17055::EZconfig(platform_data des_data)
fneirab 7:479a36909ced 401 {
fneirab 12:519a18fc3b28 402 ///STEP 2.1.1 EZ config values suggested by manufacturer.
fneirab 7:479a36909ced 403 const int charger_th = 4275;
fneirab 12:519a18fc3b28 404 const int chg_V_high = 51200; // scaling factor high voltage charger
fneirab 7:479a36909ced 405 const int chg_V_low = 44138;
fneirab 12:519a18fc3b28 406 const int param_EZ_FG1 = 0x8400; // Sets config bit for the charge voltage for the m5
fneirab 7:479a36909ced 407 const int param_EZ_FG2 = 0x8000;
fneirab 8:ca8765c30ed2 408 uint16_t dpacc, ret;
fneirab 7:479a36909ced 409
fneirab 17:7447aaa9c121 410 ///STEP 2.1.2 Store the EZ Config values into the appropriate registers.
fneirab 9:f29d5e49b190 411 ret = writeReg(DESIGNCAP_REG, des_data.designcap);
fneirab 12:519a18fc3b28 412 ret = writeReg(DQACC_REG, des_data.designcap >> 5); //DesignCap divide by 32
fneirab 9:f29d5e49b190 413 ret = writeReg(ICHGTERM_REG, des_data.ichgterm);
fneirab 9:f29d5e49b190 414 ret = writeReg(VEMPTY_REG, des_data.vempty);
fneirab 7:479a36909ced 415
fneirab 7:479a36909ced 416 if (des_data.vcharge > charger_th) {
fneirab 7:479a36909ced 417 dpacc = (des_data.designcap >> 5) * chg_V_high / des_data.designcap;
fneirab 9:f29d5e49b190 418 ret = writeReg(DPACC_REG, dpacc);
fneirab 17:7447aaa9c121 419 ret = writeReg(MODELCFG_REG, param_EZ_FG1); //
fneirab 7:479a36909ced 420 } else {
fneirab 7:479a36909ced 421 dpacc = (des_data.designcap >> 5) * chg_V_low / des_data.designcap;
fneirab 9:f29d5e49b190 422 ret = writeReg(DPACC_REG, dpacc);
fneirab 9:f29d5e49b190 423 ret = writeReg(MODELCFG_REG, param_EZ_FG2);
fneirab 7:479a36909ced 424 }
fneirab 7:479a36909ced 425 return ret;
fneirab 7:479a36909ced 426 }
fneirab 7:479a36909ced 427
fneirab 17:7447aaa9c121 428
fneirab 17:7447aaa9c121 429 /**
fneirab 17:7447aaa9c121 430 * @brief Get reported Battery Capacity Function from MAX17055 Fuel Gauge
fneirab 17:7447aaa9c121 431 * @par Details
fneirab 17:7447aaa9c121 432 * This function sends a request to access the RepCAP register
fneirab 17:7447aaa9c121 433 * of the MAX17055. RepCAP is the reported Battery Capacity in mAh of the battery based on the calulation by the Fuel Gauge algorithm.
fneirab 17:7447aaa9c121 434 *
fneirab 17:7447aaa9c121 435 * @retval repcap_data - Reported SOC data from the RepSOC register in % value.
fneirab 17:7447aaa9c121 436 * @retval non-0 negative values check for errors
fneirab 17:7447aaa9c121 437 */
fneirab 17:7447aaa9c121 438
fneirab 17:7447aaa9c121 439 int MAX17055::get_battCAP(platform_data des_data)
fneirab 17:7447aaa9c121 440 {
fneirab 17:7447aaa9c121 441 int ret, design_rsense;
fneirab 17:7447aaa9c121 442 uint16_t repcap_data;
fneirab 17:7447aaa9c121 443
fneirab 17:7447aaa9c121 444 ret = readReg(REPCAP_REG, repcap_data);
fneirab 17:7447aaa9c121 445 if (ret < F_SUCCESS_0)
fneirab 17:7447aaa9c121 446 return ret;
fneirab 17:7447aaa9c121 447 else
fneirab 17:7447aaa9c121 448 design_rsense = des_data.rsense;
fneirab 17:7447aaa9c121 449 ret = raw_cap_to_uAh((uint32_t)repcap_data, design_rsense);
fneirab 17:7447aaa9c121 450 if (ret < F_SUCCESS_0)
fneirab 17:7447aaa9c121 451 return ret;
fneirab 17:7447aaa9c121 452 else
fneirab 17:7447aaa9c121 453 return ret;
fneirab 17:7447aaa9c121 454 }
fneirab 17:7447aaa9c121 455
fneirab 7:479a36909ced 456 /**
fneirab 11:bdbd3104995b 457 * @brief Get reported State Of Charge(SOC) Function from MAX17055 Fuel Gauge.
fneirab 11:bdbd3104995b 458 * @par Details
fneirab 11:bdbd3104995b 459 * This function sends a request to access the RepSOC register
fneirab 17:7447aaa9c121 460 * of the MAX17055. RepSOC is the reported state-of-charge percentage output of the fuel gauge.
fneirab 11:bdbd3104995b 461 *
fneirab 11:bdbd3104995b 462 * @retval soc_data - Reported SOC data from the RepSOC register in % value.
fneirab 17:7447aaa9c121 463 * @retval non-0 negative values check for errors
fneirab 11:bdbd3104995b 464 */
fneirab 7:479a36909ced 465 int MAX17055::get_SOC()
fneirab 7:479a36909ced 466 {
fneirab 7:479a36909ced 467
fneirab 7:479a36909ced 468 int ret;
fneirab 11:bdbd3104995b 469 uint16_t soc_data;
fneirab 7:479a36909ced 470
fneirab 11:bdbd3104995b 471 ret = readReg(REPSOC_REG, soc_data);
fneirab 11:bdbd3104995b 472 if (ret < F_SUCCESS_0)
fneirab 7:479a36909ced 473 return ret;
fneirab 7:479a36909ced 474
fneirab 11:bdbd3104995b 475 soc_data = soc_data >> 8; /* RepSOC LSB: 1/256 % */
fneirab 7:479a36909ced 476
fneirab 11:bdbd3104995b 477 return soc_data;
fneirab 7:479a36909ced 478 }
fneirab 7:479a36909ced 479
fneirab 8:ca8765c30ed2 480 /**
fneirab 12:519a18fc3b28 481 * @brief Get at rate Average State Of Charge(SOC) Function from MAX17055 Fuel Gauge.
fneirab 11:bdbd3104995b 482 * @par Details
fneirab 12:519a18fc3b28 483 * This function sends a request to access the atAvSOC register of the MAX17055.
fneirab 11:bdbd3104995b 484 * The AvSOC registers hold the calculated available capacity and percentage of the
fneirab 17:7447aaa9c121 485 * battery based on all inputs from the ModelGauge m5 algorithm including empty
fneirab 17:7447aaa9c121 486 * compensation. These registers provide unfiltered results. Jumps in the reported
fneirab 11:bdbd3104995b 487 * values can be caused by abrupt changes in load current or temperature.
fneirab 11:bdbd3104995b 488 *
fneirab 17:7447aaa9c121 489 * @retval atAvSOC_data - Average SOC data from the atAVSOC register in % value.
fneirab 17:7447aaa9c121 490 * @retval non-0 negative values check for errors
fneirab 11:bdbd3104995b 491 */
fneirab 12:519a18fc3b28 492 int MAX17055::get_atAvSOC()
fneirab 8:ca8765c30ed2 493 {
fneirab 8:ca8765c30ed2 494 int ret;
fneirab 12:519a18fc3b28 495 uint16_t atAvSOC_data;
fneirab 8:ca8765c30ed2 496
fneirab 12:519a18fc3b28 497 ret = readReg(AVSOC_REG, atAvSOC_data);
fneirab 11:bdbd3104995b 498 if (ret < F_SUCCESS_0)
fneirab 11:bdbd3104995b 499 return ret; //Check errors if data is not correct
fneirab 8:ca8765c30ed2 500
fneirab 12:519a18fc3b28 501 atAvSOC_data = atAvSOC_data >> 8; /* avSOC LSB: 1/256 % */
fneirab 11:bdbd3104995b 502
fneirab 12:519a18fc3b28 503 return atAvSOC_data;
fneirab 8:ca8765c30ed2 504 }
fneirab 7:479a36909ced 505
fneirab 9:f29d5e49b190 506 /**
fneirab 11:bdbd3104995b 507 * @brief Get mix State Of Charge(SOC) Function for MAX17055 Fuel Gauge.
fneirab 11:bdbd3104995b 508 * @par Details
fneirab 11:bdbd3104995b 509 * This function sends a request to access mixSOC register
fneirab 11:bdbd3104995b 510 * of the MAX17055. The MixSOC registers holds the calculated
fneirab 11:bdbd3104995b 511 * remaining capacity and percentage of the cell before any empty compensation
fneirab 11:bdbd3104995b 512 * adjustments are performed.
fneirab 17:7447aaa9c121 513 *
fneirab 17:7447aaa9c121 514 * @retval mixSOC_data - Mixed SOC register values from the mixSOC register in % value.
fneirab 11:bdbd3104995b 515 * @retval non-0 for errors
fneirab 11:bdbd3104995b 516 */
fneirab 11:bdbd3104995b 517 int MAX17055::get_mixSOC()
fneirab 11:bdbd3104995b 518 {
fneirab 11:bdbd3104995b 519 int ret;
fneirab 11:bdbd3104995b 520 uint16_t mixSOC_data;
fneirab 11:bdbd3104995b 521
fneirab 11:bdbd3104995b 522 ret = readReg(MIXSOC_REG, mixSOC_data);
fneirab 11:bdbd3104995b 523 if (ret < F_SUCCESS_0)
fneirab 11:bdbd3104995b 524 return ret;
fneirab 9:f29d5e49b190 525
fneirab 11:bdbd3104995b 526 mixSOC_data = mixSOC_data >> 8; /* RepSOC LSB: 1/256 % */
fneirab 9:f29d5e49b190 527
fneirab 11:bdbd3104995b 528 return mixSOC_data;
fneirab 11:bdbd3104995b 529 }
fneirab 11:bdbd3104995b 530
fneirab 11:bdbd3104995b 531 /**
fneirab 11:bdbd3104995b 532 * @brief Get the Time to Empty(TTE) Function form MAX17055 Fuel Gauge.
fneirab 11:bdbd3104995b 533 * @par Details
fneirab 11:bdbd3104995b 534 * This function sends a request to access the TTE register
fneirab 11:bdbd3104995b 535 * of the MAX17055
fneirab 17:7447aaa9c121 536 * The TTE register holds the estimated time to empty for the
fneirab 17:7447aaa9c121 537 * application under present temperature and load conditions. The TTE value is
fneirab 17:7447aaa9c121 538 * determined by relating AvCap with AvgCurrent. The corresponding AvgCurrent
fneirab 11:bdbd3104995b 539 * filtering gives a delay in TTE, but provides more stable results.
fneirab 11:bdbd3104995b 540 *
fneirab 11:bdbd3104995b 541 * @retval tte_data - Time to Empty data from the TTE register in seconds.
fneirab 11:bdbd3104995b 542 * @retval non-0 negative values check for errors
fneirab 11:bdbd3104995b 543 */
fneirab 12:519a18fc3b28 544 float MAX17055::get_TTE()
fneirab 9:f29d5e49b190 545 {
fneirab 9:f29d5e49b190 546
fneirab 9:f29d5e49b190 547 int ret;
fneirab 11:bdbd3104995b 548 uint16_t tte_data;
fneirab 12:519a18fc3b28 549 float f_tte_data;
fneirab 9:f29d5e49b190 550
fneirab 11:bdbd3104995b 551 ret = readReg(TTE_REG, tte_data);
fneirab 11:bdbd3104995b 552 if (ret < F_SUCCESS_0)
fneirab 11:bdbd3104995b 553 return ret;
fneirab 11:bdbd3104995b 554 else
fneirab 12:519a18fc3b28 555 f_tte_data = ((float)tte_data * 5.625); /* TTE LSB: 5.625 sec */
fneirab 9:f29d5e49b190 556
fneirab 12:519a18fc3b28 557 return f_tte_data;
fneirab 9:f29d5e49b190 558 }
fneirab 7:479a36909ced 559
fneirab 7:479a36909ced 560 /**
fneirab 11:bdbd3104995b 561 * @brief Get the at Time to Empty(atTTE) value Function for MAX17055 Fuel Gauge.
fneirab 11:bdbd3104995b 562 * @par Details
fneirab 11:bdbd3104995b 563 * This function sends a request to access the internal register
fneirab 11:bdbd3104995b 564 * of the MAX17055
fneirab 11:bdbd3104995b 565 *
fneirab 17:7447aaa9c121 566 * @retval atTTE_data - Time to Empty data from the atTTE register in seconds.
fneirab 11:bdbd3104995b 567 * @retval non-0 negative values check for errors
fneirab 11:bdbd3104995b 568 */
fneirab 12:519a18fc3b28 569 float MAX17055::get_atTTE()
fneirab 7:479a36909ced 570 {
fneirab 7:479a36909ced 571
fneirab 7:479a36909ced 572 int ret;
fneirab 11:bdbd3104995b 573 uint16_t atTTE_data;
fneirab 12:519a18fc3b28 574 float f_atTTE_data;
fneirab 7:479a36909ced 575
fneirab 11:bdbd3104995b 576 ret = readReg(ATTTE_REG, atTTE_data);
fneirab 11:bdbd3104995b 577 if (ret < F_SUCCESS_0)
fneirab 11:bdbd3104995b 578 return ret; //Check for errors
fneirab 7:479a36909ced 579 else
fneirab 12:519a18fc3b28 580 f_atTTE_data = ((float)atTTE_data * 5.625); /* TTE LSB: 5.625 sec */
fneirab 7:479a36909ced 581
fneirab 12:519a18fc3b28 582 return f_atTTE_data;
fneirab 7:479a36909ced 583 }
fneirab 7:479a36909ced 584
fneirab 8:ca8765c30ed2 585 /**
fneirab 11:bdbd3104995b 586 * @brief Get the Time to Full(TTE) values Function for MAX17055 Fuel Gauge.
fneirab 11:bdbd3104995b 587 * @par Details
fneirab 11:bdbd3104995b 588 * This function sends a request to access the internal register of the MAX17055
fneirab 11:bdbd3104995b 589 * The TTF register holds the estimated time to full for the application
fneirab 11:bdbd3104995b 590 * under present conditions. The TTF value is determined by learning the
fneirab 11:bdbd3104995b 591 * constant current and constant voltage portions of the charge cycle based
fneirab 17:7447aaa9c121 592 * on experience of prior charge cycles. Time to full is then estimate
fneirab 17:7447aaa9c121 593 * by comparing present charge current to the charge termination current.
fneirab 11:bdbd3104995b 594 * Operation of the TTF register assumes all charge profiles are consistent in the application.
fneirab 11:bdbd3104995b 595 *
fneirab 17:7447aaa9c121 596 * @retval ttf_data - Time to Full data from the TTF register in seconds.
fneirab 11:bdbd3104995b 597 * @retval non-0 negative values check for errors
fneirab 11:bdbd3104995b 598 */
fneirab 12:519a18fc3b28 599 float MAX17055::get_TTF()
fneirab 8:ca8765c30ed2 600 {
fneirab 8:ca8765c30ed2 601
fneirab 8:ca8765c30ed2 602 int ret;
fneirab 8:ca8765c30ed2 603 uint16_t ttf_data;
fneirab 12:519a18fc3b28 604 float f_ttf_data;
fneirab 8:ca8765c30ed2 605
fneirab 8:ca8765c30ed2 606 ret = readReg(TTF_REG, ttf_data);
fneirab 11:bdbd3104995b 607 if (ret < F_SUCCESS_0)
fneirab 8:ca8765c30ed2 608 return ret;
fneirab 8:ca8765c30ed2 609 else
fneirab 12:519a18fc3b28 610 f_ttf_data = ((float)ttf_data * 5.625); /* TTE LSB: 5.625 sec */
fneirab 8:ca8765c30ed2 611
fneirab 12:519a18fc3b28 612 return f_ttf_data;
fneirab 8:ca8765c30ed2 613 }
fneirab 7:479a36909ced 614
fneirab 7:479a36909ced 615 /**
fneirab 11:bdbd3104995b 616 * @brief Get voltage of the cell Function for MAX17055 Fuel Gauge.
fneirab 11:bdbd3104995b 617 * @par Details
fneirab 11:bdbd3104995b 618 * This function sends a request to access the VCell Register
fneirab 17:7447aaa9c121 619 * of the MAX17055 to read the measured voltage from the cell.
fneirab 17:7447aaa9c121 620 *
fneirab 11:bdbd3104995b 621 * @retval vcell_data - vcell data from the VCELL_REG register in uVolts.
fneirab 11:bdbd3104995b 622 * @retval non-0 negative values check for errors
fneirab 11:bdbd3104995b 623 */
fneirab 7:479a36909ced 624 int MAX17055::get_Vcell()
fneirab 7:479a36909ced 625 {
fneirab 7:479a36909ced 626
fneirab 7:479a36909ced 627 int ret;
fneirab 7:479a36909ced 628 uint16_t vcell_data;
fneirab 7:479a36909ced 629
fneirab 7:479a36909ced 630 ret = readReg(VCELL_REG, vcell_data);
fneirab 11:bdbd3104995b 631 if (ret < F_SUCCESS_0)
fneirab 7:479a36909ced 632 return ret;
fneirab 7:479a36909ced 633 else
fneirab 7:479a36909ced 634 ret = lsb_to_uvolts(vcell_data);
fneirab 7:479a36909ced 635 return ret;
fneirab 7:479a36909ced 636 }
fneirab 7:479a36909ced 637
fneirab 7:479a36909ced 638 /**
fneirab 17:7447aaa9c121 639 * @brief Gets Average voltage of the cell Function for MAX17055 Fuel Gauge.
fneirab 17:7447aaa9c121 640 * @par Details
fneirab 17:7447aaa9c121 641 * This function sends a request to access the AvgVCell Register
fneirab 17:7447aaa9c121 642 * of the MAX17055 to read the measured voltage from the cell.
fneirab 17:7447aaa9c121 643 *
fneirab 17:7447aaa9c121 644 * @retval avgVcell_data - avgvcell data from the AVGVCELL_REG register in uVolts.
fneirab 17:7447aaa9c121 645 * @retval non-0 negative values check for errors
fneirab 17:7447aaa9c121 646 */
fneirab 17:7447aaa9c121 647 int MAX17055::get_avgVcell()
fneirab 17:7447aaa9c121 648 {
fneirab 17:7447aaa9c121 649
fneirab 17:7447aaa9c121 650 int ret;
fneirab 17:7447aaa9c121 651 uint16_t avgVcell_data;
fneirab 17:7447aaa9c121 652
fneirab 17:7447aaa9c121 653 ret = readReg(AVGVCELL_REG, avgVcell_data);
fneirab 17:7447aaa9c121 654 if (ret < F_SUCCESS_0)
fneirab 17:7447aaa9c121 655 return ret;
fneirab 17:7447aaa9c121 656 else
fneirab 17:7447aaa9c121 657 ret = lsb_to_uvolts(avgVcell_data);
fneirab 17:7447aaa9c121 658 return ret;
fneirab 17:7447aaa9c121 659 }
fneirab 17:7447aaa9c121 660
fneirab 17:7447aaa9c121 661 /**
fneirab 11:bdbd3104995b 662 * @brief Get current Function for MAX17055 Fuel Gauge.
fneirab 11:bdbd3104995b 663 * @par Details
fneirab 11:bdbd3104995b 664 * This function sends a request to access the CURRENT register
fneirab 17:7447aaa9c121 665 * of the MAX17055 to read the current readings.
fneirab 11:bdbd3104995b 666 *
fneirab 12:519a18fc3b28 667 * @param[in] des_data - Plataform_data struct with information about the design.
fneirab 17:7447aaa9c121 668 *
fneirab 17:7447aaa9c121 669 * @retval curr_data - current data from the CURRENT register in uAmps.
fneirab 11:bdbd3104995b 670 * @retval non-0 negative values check for errors.
fneirab 11:bdbd3104995b 671 */
fneirab 17:7447aaa9c121 672 float MAX17055::get_Current( platform_data des_data )
fneirab 7:479a36909ced 673 {
fneirab 7:479a36909ced 674
fneirab 7:479a36909ced 675 int ret,design_rsense;
fneirab 11:bdbd3104995b 676 uint16_t curr_data;
fneirab 17:7447aaa9c121 677 float f_ret;
fneirab 7:479a36909ced 678
fneirab 11:bdbd3104995b 679 ret = readReg(CURRENT_REG, curr_data);
fneirab 11:bdbd3104995b 680 if (ret < F_SUCCESS_0)
fneirab 7:479a36909ced 681 return ret;
fneirab 7:479a36909ced 682 else
fneirab 17:7447aaa9c121 683 design_rsense = des_data.rsense;
fneirab 17:7447aaa9c121 684 f_ret = raw_current_to_uamps((uint32_t)curr_data, design_rsense);
fneirab 17:7447aaa9c121 685 return f_ret;
fneirab 7:479a36909ced 686 }
fneirab 7:479a36909ced 687
fneirab 7:479a36909ced 688 /**
fneirab 11:bdbd3104995b 689 * @brief Get average current Function for MAX17055 Fuel Gauge.
fneirab 11:bdbd3104995b 690 * @par Details
fneirab 11:bdbd3104995b 691 * This function sends a request to access the aveCURRENT register
fneirab 17:7447aaa9c121 692 * of the MAX17055 to read the average current readings.
fneirab 11:bdbd3104995b 693 *
fneirab 12:519a18fc3b28 694 * @param[in] des_data - Plataform_data struct with information about the design.
fneirab 17:7447aaa9c121 695 *
fneirab 17:7447aaa9c121 696 * @retval aveCurr_data - current data from the AVGCURRENT register in uAmps.
fneirab 11:bdbd3104995b 697 * @retval non-0 negative values check for errors.
fneirab 11:bdbd3104995b 698 */
fneirab 17:7447aaa9c121 699 float MAX17055::get_AvgCurrent( platform_data des_data )
fneirab 7:479a36909ced 700 {
fneirab 7:479a36909ced 701 int ret, design_rsense;
fneirab 7:479a36909ced 702 uint16_t data;
fneirab 17:7447aaa9c121 703 float avgCurr_data;
fneirab 7:479a36909ced 704
fneirab 7:479a36909ced 705 ret = readReg(AVGCURRENT_REG, data);
fneirab 11:bdbd3104995b 706 if (ret < F_SUCCESS_0)
fneirab 7:479a36909ced 707 return ret;
fneirab 7:479a36909ced 708 else
fneirab 17:7447aaa9c121 709 avgCurr_data = data;
fneirab 7:479a36909ced 710 design_rsense = des_data.rsense;
fneirab 17:7447aaa9c121 711 avgCurr_data = raw_current_to_uamps((uint32_t)data, design_rsense);
fneirab 17:7447aaa9c121 712 return avgCurr_data;
fneirab 7:479a36909ced 713 }
fneirab 7:479a36909ced 714
fneirab 7:479a36909ced 715 /**
fneirab 17:7447aaa9c121 716 * @brief lsb_to_uvolts Conversion Function
fneirab 11:bdbd3104995b 717 * @par Details
fneirab 11:bdbd3104995b 718 * This function takes the lsb value of the register and convert it
fneirab 11:bdbd3104995b 719 * to uvolts
fneirab 11:bdbd3104995b 720 *
fneirab 11:bdbd3104995b 721 * @param[in] lsb - value of register lsb
fneirab 17:7447aaa9c121 722 * @retval conv_2_uvolts - value converted lsb to uvolts
fneirab 11:bdbd3104995b 723 */
fneirab 7:479a36909ced 724 int MAX17055:: lsb_to_uvolts(uint16_t lsb)
fneirab 7:479a36909ced 725 {
fneirab 11:bdbd3104995b 726 int conv_2_uvolts;
fneirab 11:bdbd3104995b 727 conv_2_uvolts = (lsb * 625) / 8; /* 78.125uV per bit */
fneirab 11:bdbd3104995b 728 return conv_2_uvolts;
fneirab 7:479a36909ced 729 }
fneirab 7:479a36909ced 730
fneirab 7:479a36909ced 731 /**
fneirab 17:7447aaa9c121 732 * @brief raw_current_to_uamp Conversion Function
fneirab 11:bdbd3104995b 733 * @par Details
fneirab 17:7447aaa9c121 734 * This function takes the raw current value of the register and
fneirab 11:bdbd3104995b 735 * converts it to uamps
fneirab 11:bdbd3104995b 736 *
fneirab 17:7447aaa9c121 737 * @param[in] curr - raw current value of register
fneirab 17:7447aaa9c121 738 * @retval res - converted raw current to uamps (Signed 2's complement)
fneirab 11:bdbd3104995b 739 */
fneirab 17:7447aaa9c121 740 float MAX17055::raw_current_to_uamps(uint32_t curr, int rsense_value)
fneirab 7:479a36909ced 741 {
fneirab 7:479a36909ced 742 int res = curr;
fneirab 17:7447aaa9c121 743 float final_res;
fneirab 17:7447aaa9c121 744 /* Negative Check*/
fneirab 17:7447aaa9c121 745 if (res & 0x8000){
fneirab 7:479a36909ced 746 res |= 0xFFFF0000;
fneirab 7:479a36909ced 747 }
fneirab 17:7447aaa9c121 748 final_res = (float)res;
fneirab 17:7447aaa9c121 749 final_res *= 1562500 /(float)(rsense_value*1000000);
fneirab 17:7447aaa9c121 750
fneirab 17:7447aaa9c121 751 return final_res;
fneirab 17:7447aaa9c121 752 }
fneirab 17:7447aaa9c121 753
fneirab 17:7447aaa9c121 754 /**
fneirab 17:7447aaa9c121 755 * @brief raw_cap_to_uAh Conversion Function
fneirab 17:7447aaa9c121 756 * @par Details
fneirab 17:7447aaa9c121 757 * This function takes the raw battery capacity value of the register and
fneirab 17:7447aaa9c121 758 * converts it to uAh
fneirab 17:7447aaa9c121 759 *
fneirab 17:7447aaa9c121 760 * @param[in] raw_cap - raw capacity value of register
fneirab 17:7447aaa9c121 761 * @retval res - converted raw capacity to uAh
fneirab 17:7447aaa9c121 762 */
fneirab 17:7447aaa9c121 763 int MAX17055::raw_cap_to_uAh(uint32_t raw_cap, int rsense_value)
fneirab 17:7447aaa9c121 764 {
fneirab 17:7447aaa9c121 765 int res = raw_cap ;
fneirab 17:7447aaa9c121 766 res *= 5000000/(rsense_value * 1000000);
fneirab 7:479a36909ced 767 return res;
fneirab 9:f29d5e49b190 768 }
fneirab 9:f29d5e49b190 769
fneirab 9:f29d5e49b190 770 /**
fneirab 17:7447aaa9c121 771 * @brief Save Learned Parameters Function for battery Fuel Gauge model.
fneirab 11:bdbd3104995b 772 * @par Details
fneirab 11:bdbd3104995b 773 * It is recommended to save the learned capacity parameters every
fneirab 11:bdbd3104995b 774 * time bit 2 of the Cycles register toggles
fneirab 17:7447aaa9c121 775 * (so that it is saved every 64% change in the battery)
fneirab 15:291446b008df 776 * so that if power is lost the values can easily be restored. Make sure
fneirab 17:7447aaa9c121 777 * the data is saved on a non-volatile memory. Call this functinton after first initialization for reference in future function calls.
fneirab 17:7447aaa9c121 778 * Max muber of cycles is 655.35 cycles with a LSB of 1% for the cycles register.
fneirab 11:bdbd3104995b 779 *
fneirab 17:7447aaa9c121 780 * @param[in] FG_params Fuel Gauge Parameters based on design details.
fneirab 17:7447aaa9c121 781 *
fneirab 11:bdbd3104995b 782 * @retval 0 for success
fneirab 11:bdbd3104995b 783 * @retval non-0 negative for errors
fneirab 11:bdbd3104995b 784 */
fneirab 9:f29d5e49b190 785 int MAX17055::save_Params(saved_FG_params_t FG_params)
fneirab 9:f29d5e49b190 786 {
fneirab 17:7447aaa9c121 787 int ret;
fneirab 17:7447aaa9c121 788 uint16_t data[5], value;
fneirab 11:bdbd3104995b 789 ///STEP 1. Checks if the cycel register bit 2 has changed.
fneirab 11:bdbd3104995b 790 ret = readReg(CYCLES_REG, data[3]);
fneirab 17:7447aaa9c121 791 value = data[3];
fneirab 11:bdbd3104995b 792 if (ret < F_SUCCESS_0)
fneirab 9:f29d5e49b190 793 return ret;
fneirab 17:7447aaa9c121 794 //Check if the stored cycles value is different from the read Cycles_reg value
fneirab 17:7447aaa9c121 795 else if (FG_params.cycles == value)
fneirab 17:7447aaa9c121 796 return ret; //exits the function without saving, when initializing or value did not change (calculate when the function is called in you application).
fneirab 17:7447aaa9c121 797 else {
fneirab 17:7447aaa9c121 798 value = FG_params.cycles^value;
fneirab 17:7447aaa9c121 799 //check with mask
fneirab 17:7447aaa9c121 800 value = (value & MAX17055_POR_MASK);
fneirab 17:7447aaa9c121 801
fneirab 17:7447aaa9c121 802 if (value == 0)
fneirab 17:7447aaa9c121 803 return ret;
fneirab 17:7447aaa9c121 804
fneirab 17:7447aaa9c121 805 ///STEP 2. Save the capacity parameters for the specific battery.
fneirab 17:7447aaa9c121 806 ret = readReg(RCOMP0_REG, data[0]);
fneirab 17:7447aaa9c121 807 if (ret < F_SUCCESS_0)
fneirab 17:7447aaa9c121 808 return ret;
fneirab 17:7447aaa9c121 809 else
fneirab 17:7447aaa9c121 810 FG_params.rcomp0 = data[0];
fneirab 9:f29d5e49b190 811
fneirab 17:7447aaa9c121 812 ret = readReg(TEMPCO_REG, data[1]);
fneirab 17:7447aaa9c121 813 if (ret < F_SUCCESS_0)
fneirab 17:7447aaa9c121 814 return ret;
fneirab 17:7447aaa9c121 815 else
fneirab 17:7447aaa9c121 816 FG_params.temp_co = data[1];
fneirab 9:f29d5e49b190 817
fneirab 17:7447aaa9c121 818 ret = readReg(FULLCAPREP_REG, data[2]);
fneirab 17:7447aaa9c121 819 if (ret < F_SUCCESS_0)
fneirab 17:7447aaa9c121 820 return ret;
fneirab 17:7447aaa9c121 821 else
fneirab 17:7447aaa9c121 822 FG_params.full_cap_rep = data[2];
fneirab 17:7447aaa9c121 823
fneirab 17:7447aaa9c121 824 FG_params.cycles = data[3];
fneirab 17:7447aaa9c121 825
fneirab 17:7447aaa9c121 826 ret = readReg(FULLCAPNOM_REG, data[4]);
fneirab 17:7447aaa9c121 827 if (ret < F_SUCCESS_0)
fneirab 17:7447aaa9c121 828 return ret;
fneirab 17:7447aaa9c121 829 else
fneirab 17:7447aaa9c121 830 FG_params.full_cap_nom = data[4];
fneirab 9:f29d5e49b190 831 return ret;
fneirab 17:7447aaa9c121 832 }
fneirab 17:7447aaa9c121 833 }
fneirab 9:f29d5e49b190 834
fneirab 17:7447aaa9c121 835
fneirab 9:f29d5e49b190 836
fneirab 9:f29d5e49b190 837 /**
fneirab 12:519a18fc3b28 838 * @brief Restore Parameters Function for battery Fuel Gauge model.
fneirab 11:bdbd3104995b 839 * @par Details
fneirab 17:7447aaa9c121 840 * If power is lost, then the capacity information
fneirab 17:7447aaa9c121 841 * can be easily restored with this function.
fneirab 11:bdbd3104995b 842 *
fneirab 17:7447aaa9c121 843 * @param[in] FG_params Struct for Fuel Gauge Parameters
fneirab 11:bdbd3104995b 844 * @retval 0 for success
fneirab 11:bdbd3104995b 845 * @retval non-0 negative for errors
fneirab 11:bdbd3104995b 846 */
fneirab 9:f29d5e49b190 847 int MAX17055::restore_Params(saved_FG_params_t FG_params)
fneirab 9:f29d5e49b190 848 {
fneirab 9:f29d5e49b190 849 int ret;
fneirab 9:f29d5e49b190 850 uint16_t temp_data, fullcapnom_data, mixCap_calc, dQacc_calc;
fneirab 12:519a18fc3b28 851 uint16_t dPacc_value = 0x0C80;//Set it to 200%
fneirab 9:f29d5e49b190 852
fneirab 17:7447aaa9c121 853 ///STEP 1. Restoring capacity parameters
fneirab 9:f29d5e49b190 854 write_and_verify_reg(RCOMP0_REG, FG_params.rcomp0);
fneirab 9:f29d5e49b190 855 write_and_verify_reg(TEMPCO_REG, FG_params.temp_co);
fneirab 9:f29d5e49b190 856 write_and_verify_reg(FULLCAPNOM_REG, FG_params.full_cap_nom);
fneirab 17:7447aaa9c121 857
fneirab 11:bdbd3104995b 858 wait_ms(350);//check the type of wait
fneirab 17:7447aaa9c121 859
fneirab 11:bdbd3104995b 860 ///STEP 2. Restore FullCap
fneirab 9:f29d5e49b190 861 ret = readReg(FULLCAPNOM_REG, fullcapnom_data);
fneirab 11:bdbd3104995b 862 if (ret < F_SUCCESS_0)
fneirab 9:f29d5e49b190 863 return ret;
fneirab 9:f29d5e49b190 864
fneirab 18:37bca022d144 865 ret = readReg(MIXSOC_REG, temp_data);
fneirab 11:bdbd3104995b 866 if (ret < F_SUCCESS_0)
fneirab 9:f29d5e49b190 867 return ret;
fneirab 17:7447aaa9c121 868
fneirab 9:f29d5e49b190 869 mixCap_calc = (temp_data*fullcapnom_data)/25600;
fneirab 9:f29d5e49b190 870
fneirab 9:f29d5e49b190 871 write_and_verify_reg(MIXCAP_REG, mixCap_calc);
fneirab 9:f29d5e49b190 872 write_and_verify_reg(FULLCAPREP_REG, FG_params.full_cap_rep);
fneirab 17:7447aaa9c121 873
fneirab 11:bdbd3104995b 874 ///STEP 3. Write DQACC to 200% of Capacity and DPACC to 200%
fneirab 9:f29d5e49b190 875 dQacc_calc = (FG_params.full_cap_nom/ 16) ;
fneirab 9:f29d5e49b190 876
fneirab 9:f29d5e49b190 877 write_and_verify_reg(DPACC_REG, dPacc_value);
fneirab 9:f29d5e49b190 878 write_and_verify_reg(DQACC_REG, dQacc_calc);
fneirab 9:f29d5e49b190 879
fneirab 9:f29d5e49b190 880 wait_ms(350);
fneirab 9:f29d5e49b190 881
fneirab 11:bdbd3104995b 882 ///STEP 4. Restore Cycles register
fneirab 9:f29d5e49b190 883 ret = write_and_verify_reg(CYCLES_REG, FG_params.cycles);
fneirab 11:bdbd3104995b 884 if (ret < F_SUCCESS_0)
fneirab 9:f29d5e49b190 885 return ret;
fneirab 11:bdbd3104995b 886 return ret;
fneirab 11:bdbd3104995b 887 }
fneirab 11:bdbd3104995b 888
fneirab 11:bdbd3104995b 889 /**
fneirab 11:bdbd3104995b 890 * @brief Function to Save Average Current to At Rate register.
fneirab 11:bdbd3104995b 891 * @par Details
fneirab 12:519a18fc3b28 892 * For User friendliness display of atTTE, atAvSOC, atAvCAP
fneirab 17:7447aaa9c121 893 * write the average current to At Rate registers every 10sec
fneirab 11:bdbd3104995b 894 * when the battery is in use.
fneirab 17:7447aaa9c121 895 * NOTE: do not use this function when the Battery is charging.
fneirab 11:bdbd3104995b 896 *
fneirab 11:bdbd3104995b 897 * @retval 0 for success
fneirab 11:bdbd3104995b 898 * @retval non-0 negative for errors
fneirab 11:bdbd3104995b 899 */
fneirab 11:bdbd3104995b 900 int MAX17055::avCurr_2_atRate()
fneirab 11:bdbd3104995b 901 {
fneirab 11:bdbd3104995b 902 int ret;
fneirab 11:bdbd3104995b 903 uint16_t avCurr_data;
fneirab 11:bdbd3104995b 904
fneirab 11:bdbd3104995b 905 ret = readReg(AVGCURRENT_REG, avCurr_data);
fneirab 17:7447aaa9c121 906 if (ret < F_SUCCESS_0) {
fneirab 12:519a18fc3b28 907 return ret = -3;
fneirab 17:7447aaa9c121 908 }
fneirab 11:bdbd3104995b 909
fneirab 11:bdbd3104995b 910 //Write avCurrent to atRate Register
fneirab 12:519a18fc3b28 911 ret = writeReg(ATRATE_REG, avCurr_data);
fneirab 17:7447aaa9c121 912 if (ret < F_SUCCESS_0) {
fneirab 11:bdbd3104995b 913 return ret;
fneirab 12:519a18fc3b28 914 }
fneirab 12:519a18fc3b28 915 return F_SUCCESS_0;
fneirab 7:479a36909ced 916 }