/* MIT License Copyright (c) 2022 lewis he Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /* ! WARN: Please do not run the example without knowing the external load voltage of the PMU, it may burn your external load, please check the voltage setting before running the example, if there is any loss, please bear it by yourself */ #ifndef XPOWERS_NO_ERROR #error "Running this example is known to not damage the device! Please go and uncomment this!" #endif // Defined using AXP2102 #define XPOWERS_CHIP_AXP2101 #include #include #include "XPowersLib.h" #ifndef CONFIG_PMU_SDA #define CONFIG_PMU_SDA 21 #endif #ifndef CONFIG_PMU_SCL #define CONFIG_PMU_SCL 22 #endif #ifndef CONFIG_PMU_IRQ #define CONFIG_PMU_IRQ 35 #endif bool pmu_flag = 0; XPowersPMU power; const uint8_t i2c_sda = CONFIG_PMU_SDA; const uint8_t i2c_scl = CONFIG_PMU_SCL; const uint8_t pmu_irq_pin = CONFIG_PMU_IRQ; void setFlag(void) { pmu_flag = true; } void setup() { Serial.begin(115200); bool result = power.begin(Wire, AXP2101_SLAVE_ADDRESS, i2c_sda, i2c_scl); if (result == false) { Serial.println("power is not online..."); while (1)delay(50); } Serial.printf("getID:0x%x\n", power.getChipID()); // Set the minimum common working voltage of the PMU VBUS input, // below this value will turn off the PMU power.setVbusVoltageLimit(XPOWERS_AXP2101_VBUS_VOL_LIM_4V36); // Set the maximum current of the PMU VBUS input, // higher than this value will turn off the PMU power.setVbusCurrentLimit(XPOWERS_AXP2101_VBUS_CUR_LIM_1500MA); // Get the VSYS shutdown voltage uint16_t vol = power.getSysPowerDownVoltage(); Serial.printf("-> getSysPowerDownVoltage:%u\n", vol); // Set VSY off voltage as 2600mV , Adjustment range 2600mV ~ 3300mV power.setSysPowerDownVoltage(2600); vol = power.getSysPowerDownVoltage(); Serial.printf("-> getSysPowerDownVoltage:%u\n", vol); // DC1 IMAX=2A // 1500~3400mV,100mV/step,20steps power.setDC1Voltage(3300); Serial.printf("DC1 : %s Voltage:%u mV \n", power.isEnableDC1() ? "+" : "-", power.getDC1Voltage()); // DC2 IMAX=2A // 500~1200mV 10mV/step,71steps // 1220~1540mV 20mV/step,17steps power.setDC2Voltage(1000); Serial.printf("DC2 : %s Voltage:%u mV \n", power.isEnableDC2() ? "+" : "-", power.getDC2Voltage()); // DC3 IMAX = 2A // 500~1200mV,10mV/step,71steps // 1220~1540mV,20mV/step,17steps // 1600~3400mV,100mV/step,19steps power.setDC3Voltage(3300); Serial.printf("DC3 : %s Voltage:%u mV \n", power.isEnableDC3() ? "+" : "-", power.getDC3Voltage()); // DCDC4 IMAX=1.5A // 500~1200mV,10mV/step,71steps // 1220~1840mV,20mV/step,32steps power.setDC4Voltage(1000); Serial.printf("DC4 : %s Voltage:%u mV \n", power.isEnableDC4() ? "+" : "-", power.getDC4Voltage()); // DC5 IMAX=2A // 1200mV // 1400~3700mV,100mV/step,24steps power.setDC5Voltage(3300); Serial.printf("DC5 : %s Voltage:%u mV \n", power.isEnableDC5() ? "+" : "-", power.getDC5Voltage()); //ALDO1 IMAX=300mA //500~3500mV, 100mV/step,31steps power.setALDO1Voltage(3300); //ALDO2 IMAX=300mA //500~3500mV, 100mV/step,31steps power.setALDO2Voltage(3300); //ALDO3 IMAX=300mA //500~3500mV, 100mV/step,31steps power.setALDO3Voltage(3300); //ALDO4 IMAX=300mA //500~3500mV, 100mV/step,31steps power.setALDO4Voltage(3300); //BLDO1 IMAX=300mA //500~3500mV, 100mV/step,31steps power.setBLDO1Voltage(3300); //BLDO2 IMAX=300mA //500~3500mV, 100mV/step,31steps power.setBLDO2Voltage(3300); //CPUSLDO IMAX=30mA //500~1400mV,50mV/step,19steps power.setCPUSLDOVoltage(1000); //DLDO1 IMAX=300mA //500~3400mV, 100mV/step,29steps power.setDLDO1Voltage(3300); //DLDO2 IMAX=300mA //500~1400mV, 50mV/step,2steps power.setDLDO2Voltage(3300); // power.enableDC1(); power.enableDC2(); power.enableDC3(); power.enableDC4(); power.enableDC5(); power.enableALDO1(); power.enableALDO2(); power.enableALDO3(); power.enableALDO4(); power.enableBLDO1(); power.enableBLDO2(); power.enableCPUSLDO(); power.enableDLDO1(); power.enableDLDO2(); Serial.println("DCDC======================================================================="); Serial.printf("DC1 : %s Voltage:%u mV \n", power.isEnableDC1() ? "+" : "-", power.getDC1Voltage()); Serial.printf("DC2 : %s Voltage:%u mV \n", power.isEnableDC2() ? "+" : "-", power.getDC2Voltage()); Serial.printf("DC3 : %s Voltage:%u mV \n", power.isEnableDC3() ? "+" : "-", power.getDC3Voltage()); Serial.printf("DC4 : %s Voltage:%u mV \n", power.isEnableDC4() ? "+" : "-", power.getDC4Voltage()); Serial.printf("DC5 : %s Voltage:%u mV \n", power.isEnableDC5() ? "+" : "-", power.getDC5Voltage()); Serial.println("ALDO======================================================================="); Serial.printf("ALDO1: %s Voltage:%u mV\n", power.isEnableALDO1() ? "+" : "-", power.getALDO1Voltage()); Serial.printf("ALDO2: %s Voltage:%u mV\n", power.isEnableALDO2() ? "+" : "-", power.getALDO2Voltage()); Serial.printf("ALDO3: %s Voltage:%u mV\n", power.isEnableALDO3() ? "+" : "-", power.getALDO3Voltage()); Serial.printf("ALDO4: %s Voltage:%u mV\n", power.isEnableALDO4() ? "+" : "-", power.getALDO4Voltage()); Serial.println("BLDO======================================================================="); Serial.printf("BLDO1: %s Voltage:%u mV\n", power.isEnableBLDO1() ? "+" : "-", power.getBLDO1Voltage()); Serial.printf("BLDO2: %s Voltage:%u mV\n", power.isEnableBLDO2() ? "+" : "-", power.getBLDO2Voltage()); Serial.println("CPUSLDO===================================================================="); Serial.printf("CPUSLDO: %s Voltage:%u mV\n", power.isEnableCPUSLDO() ? "+" : "-", power.getCPUSLDOVoltage()); Serial.println("DLDO======================================================================="); Serial.printf("DLDO1: %s Voltage:%u mV\n", power.isEnableDLDO1() ? "+" : "-", power.getDLDO1Voltage()); Serial.printf("DLDO2: %s Voltage:%u mV\n", power.isEnableDLDO2() ? "+" : "-", power.getDLDO2Voltage()); Serial.println("==========================================================================="); // Set the time of pressing the button to turn off power.setPowerKeyPressOffTime(XPOWERS_POWEROFF_4S); uint8_t opt = power.getPowerKeyPressOffTime(); Serial.print("PowerKeyPressOffTime:"); switch (opt) { case XPOWERS_POWEROFF_4S: Serial.println("4 Second"); break; case XPOWERS_POWEROFF_6S: Serial.println("6 Second"); break; case XPOWERS_POWEROFF_8S: Serial.println("8 Second"); break; case XPOWERS_POWEROFF_10S: Serial.println("10 Second"); break; default: break; } // Set the button power-on press time power.setPowerKeyPressOnTime(XPOWERS_POWERON_128MS); opt = power.getPowerKeyPressOnTime(); Serial.print("PowerKeyPressOnTime:"); switch (opt) { case XPOWERS_POWERON_128MS: Serial.println("128 Ms"); break; case XPOWERS_POWERON_512MS: Serial.println("512 Ms"); break; case XPOWERS_POWERON_1S: Serial.println("1 Second"); break; case XPOWERS_POWERON_2S: Serial.println("2 Second"); break; default: break; } Serial.println("==========================================================================="); bool en; // DCDC 120%(130%) high voltage turn off PMIC function en = power.getDCHighVoltagePowerDownEn(); Serial.print("getDCHighVoltagePowerDownEn:"); Serial.println(en ? "ENABLE" : "DISABLE"); // DCDC1 85% low voltage turn off PMIC function en = power.getDC1LowVoltagePowerDownEn(); Serial.print("getDC1LowVoltagePowerDownEn:"); Serial.println(en ? "ENABLE" : "DISABLE"); // DCDC2 85% low voltage turn off PMIC function en = power.getDC2LowVoltagePowerDownEn(); Serial.print("getDC2LowVoltagePowerDownEn:"); Serial.println(en ? "ENABLE" : "DISABLE"); // DCDC3 85% low voltage turn off PMIC function en = power.getDC3LowVoltagePowerDownEn(); Serial.print("getDC3LowVoltagePowerDownEn:"); Serial.println(en ? "ENABLE" : "DISABLE"); // DCDC4 85% low voltage turn off PMIC function en = power.getDC4LowVoltagePowerDownEn(); Serial.print("getDC4LowVoltagePowerDownEn:"); Serial.println(en ? "ENABLE" : "DISABLE"); // DCDC5 85% low voltage turn off PMIC function en = power.getDC5LowVoltagePowerDownEn(); Serial.print("getDC5LowVoltagePowerDownEn:"); Serial.println(en ? "ENABLE" : "DISABLE"); // power.setDCHighVoltagePowerDown(true); // power.setDC1LowVoltagePowerDown(true); // power.setDC2LowVoltagePowerDown(true); // power.setDC3LowVoltagePowerDown(true); // power.setDC4LowVoltagePowerDown(true); // power.setDC5LowVoltagePowerDown(true); // It is necessary to disable the detection function of the TS pin on the board // without the battery temperature detection function, otherwise it will cause abnormal charging power.disableTSPinMeasure(); // power.enableTemperatureMeasure(); // Enable internal ADC detection power.enableBattDetection(); power.enableVbusVoltageMeasure(); power.enableBattVoltageMeasure(); power.enableSystemVoltageMeasure(); /* The default setting is CHGLED is automatically controlled by the PMU. - XPOWERS_CHG_LED_OFF, - XPOWERS_CHG_LED_BLINK_1HZ, - XPOWERS_CHG_LED_BLINK_4HZ, - XPOWERS_CHG_LED_ON, - XPOWERS_CHG_LED_CTRL_CHG, * */ power.setChargingLedMode(XPOWERS_CHG_LED_OFF); // Force add pull-up pinMode(pmu_irq_pin, INPUT_PULLUP); attachInterrupt(pmu_irq_pin, setFlag, FALLING); // Disable all interrupts power.disableIRQ(XPOWERS_AXP2101_ALL_IRQ); // Clear all interrupt flags power.clearIrqStatus(); // Enable the required interrupt function power.enableIRQ( XPOWERS_AXP2101_BAT_INSERT_IRQ | XPOWERS_AXP2101_BAT_REMOVE_IRQ | //BATTERY XPOWERS_AXP2101_VBUS_INSERT_IRQ | XPOWERS_AXP2101_VBUS_REMOVE_IRQ | //VBUS XPOWERS_AXP2101_PKEY_SHORT_IRQ | XPOWERS_AXP2101_PKEY_LONG_IRQ | //POWER KEY XPOWERS_AXP2101_BAT_CHG_DONE_IRQ | XPOWERS_AXP2101_BAT_CHG_START_IRQ //CHARGE // XPOWERS_AXP2101_PKEY_NEGATIVE_IRQ | XPOWERS_AXP2101_PKEY_POSITIVE_IRQ | //POWER KEY ); // Set the precharge charging current power.setPrechargeCurr(XPOWERS_AXP2101_PRECHARGE_50MA); // Set constant current charge current limit power.setChargerConstantCurr(XPOWERS_AXP2101_CHG_CUR_200MA); // Set stop charging termination current power.setChargerTerminationCurr(XPOWERS_AXP2101_CHG_ITERM_25MA); // Set charge cut-off voltage power.setChargeTargetVoltage(XPOWERS_AXP2101_CHG_VOL_4V1); // Set the watchdog trigger event type power.setWatchdogConfig(XPOWERS_AXP2101_WDT_IRQ_TO_PIN); // Set watchdog timeout power.setWatchdogTimeout(XPOWERS_AXP2101_WDT_TIMEOUT_4S); // Enable watchdog to trigger interrupt event power.enableWatchdog(); // power.disableWatchdog(); // Enable Button Battery charge power.enableButtonBatteryCharge(); // Set Button Battery charge voltage power.setButtonBatteryChargeVoltage(3300); } void printPMU() { Serial.print("isCharging:"); Serial.println(power.isCharging() ? "YES" : "NO"); Serial.print("isDischarge:"); Serial.println(power.isDischarge() ? "YES" : "NO"); Serial.print("isStandby:"); Serial.println(power.isStandby() ? "YES" : "NO"); Serial.print("isVbusIn:"); Serial.println(power.isVbusIn() ? "YES" : "NO"); Serial.print("isVbusGood:"); Serial.println(power.isVbusGood() ? "YES" : "NO"); Serial.print("getChargerStatus:"); uint8_t charge_status = power.getChargerStatus(); if (charge_status == XPOWERS_AXP2101_CHG_TRI_STATE) { Serial.println("tri_charge"); } else if (charge_status == XPOWERS_AXP2101_CHG_PRE_STATE) { Serial.println("pre_charge"); } else if (charge_status == XPOWERS_AXP2101_CHG_CC_STATE) { Serial.println("constant charge"); } else if (charge_status == XPOWERS_AXP2101_CHG_CV_STATE) { Serial.println("constant voltage"); } else if (charge_status == XPOWERS_AXP2101_CHG_DONE_STATE) { Serial.println("charge done"); } else if (charge_status == XPOWERS_AXP2101_CHG_STOP_STATE) { Serial.println("not charge"); } Serial.print("getBattVoltage:"); Serial.print(power.getBattVoltage()); Serial.println("mV"); Serial.print("getVbusVoltage:"); Serial.print(power.getVbusVoltage()); Serial.println("mV"); Serial.print("getSystemVoltage:"); Serial.print(power.getSystemVoltage()); Serial.println("mV"); // The battery percentage may be inaccurate at first use, the PMU will automatically // learn the battery curve and will automatically calibrate the battery percentage // after a charge and discharge cycle if (power.isBatteryConnect()) { Serial.print("getBatteryPercent:"); Serial.print(power.getBatteryPercent()); Serial.println("%"); } Serial.println(); } void enterPmuSleep(void) { // Set the wake-up source to PWRKEY power.wakeupControl(XPOWERS_AXP2101_WAKEUP_IRQ_PIN_TO_LOW, true); // Set sleep flag power.enableSleep(); power.disableDC2(); power.disableDC3(); power.disableDC4(); power.disableDC5(); power.disableALDO1(); power.disableALDO2(); power.disableALDO3(); power.disableALDO4(); power.disableBLDO1(); power.disableBLDO2(); power.disableCPUSLDO(); power.disableDLDO1(); power.disableDLDO2(); // Finally, turn off the power of the control chip power.disableDC1(); } void loop() { if (pmu_flag) { pmu_flag = false; // Get PMU Interrupt Status Register uint32_t status = power.getIrqStatus(); Serial.print("STATUS => HEX:"); Serial.print(status, HEX); Serial.print(" BIN:"); Serial.println(status, BIN); if (power.isDropWarningLevel2Irq()) { Serial.println("isDropWarningLevel2"); } if (power.isDropWarningLevel1Irq()) { Serial.println("isDropWarningLevel1"); } if (power.isGaugeWdtTimeoutIrq()) { Serial.println("isWdtTimeout"); } if (power.isBatChargerOverTemperatureIrq()) { Serial.println("isBatChargeOverTemperature"); } if (power.isBatWorkOverTemperatureIrq()) { Serial.println("isBatWorkOverTemperature"); } if (power.isBatWorkUnderTemperatureIrq()) { Serial.println("isBatWorkUnderTemperature"); } if (power.isVbusInsertIrq()) { Serial.println("isVbusInsert"); } if (power.isVbusRemoveIrq()) { Serial.println("isVbusRemove"); } if (power.isBatInsertIrq()) { Serial.println("isBatInsert"); } if (power.isBatRemoveIrq()) { Serial.println("isBatRemove"); } if (power.isPekeyShortPressIrq()) { Serial.println("isPekeyShortPress"); // enterPmuSleep(); Serial.print("Read pmu data buffer ."); uint8_t data[4] = {0}; power.readDataBuffer(data, XPOWERS_AXP2101_DATA_BUFFER_SIZE); for (int i = 0; i < 4; ++i) { Serial.print(data[i]); Serial.print(","); } Serial.println(); } if (power.isPekeyLongPressIrq()) { Serial.println("isPekeyLongPress"); Serial.println("write pmu data buffer ."); uint8_t data[4] = {1, 2, 3, 4}; power.writeDataBuffer(data, XPOWERS_AXP2101_DATA_BUFFER_SIZE); } if (power.isPekeyNegativeIrq()) { Serial.println("isPekeyNegative"); } if (power.isPekeyPositiveIrq()) { Serial.println("isPekeyPositive"); } if (power.isWdtExpireIrq()) { Serial.println("isWdtExpire"); printPMU(); } if (power.isLdoOverCurrentIrq()) { Serial.println("isLdoOverCurrentIrq"); } if (power.isBatfetOverCurrentIrq()) { Serial.println("isBatfetOverCurrentIrq"); } if (power.isBatChargeDoneIrq()) { Serial.println("isBatChargeDone"); } if (power.isBatChargeStartIrq()) { Serial.println("isBatChargeStart"); } if (power.isBatDieOverTemperatureIrq()) { Serial.println("isBatDieOverTemperature"); } if (power.isChargeOverTimeoutIrq()) { Serial.println("isChargeOverTimeout"); } if (power.isBatOverVoltageIrq()) { Serial.println("isBatOverVoltage"); } // Clear PMU Interrupt Status Register power.clearIrqStatus(); } delay(10); }