#include #include "battery.h" #include "regs/regs.h" /* To measure the battery voltage, we're using the internal ADC. The ADC works * by comparing the input voltage to a reference voltage. The only fixed voltage * we have around is 2.8V, so that's the one we're using as a refrence. However, * and ADC can only measure voltage that is lower than the reference voltage. So * we need to use a voltage divider before sampling Vbat. * To avoid draining the battery, we're using an high-impedence voltage divider, * so we need to be careful when sampling the ADC. See AN2834 for more info. */ namespace Ion { namespace Battery { bool isCharging() { return !Device::ChargingGPIO.IDR()->get(Device::ChargingPin); } Charge level() { if (voltage() < 3.2f) { return Charge::EMPTY; } if (voltage() < 3.5f) { return Charge::LOW; } if (voltage() < 3.8f) { return Charge::SOMEWHERE_INBETWEEN; } return Charge::FULL; } float voltage() { ADC.CR2()->setSWSTART(true); while (ADC.SR()->getEOC() != true) { } uint16_t value = ADC.DR()->get(); // The ADC is 12 bits by default return Device::ADCDividerBridgeRatio*(Device::ADCReferenceVoltage * value)/0xFFF; } } } namespace Ion { namespace Battery { namespace Device { void init() { initGPIO(); /* The BAT_SNS pin is connected to Vbat through a divider bridge. It therefore * has a voltage of Vbat/2. We'll measure this using ADC channel 0. */ ADCGPIO.MODER()->setMode(ADCPin, GPIO::MODER::Mode::Analog); // Step 2 - Enable the ADC RCC.APB2ENR()->setADC1EN(true); ADC.CR2()->setADON(true); // Configure the ADC channel ADC.SQR1()->setL(0); // Always sample the same channel ADC.SQR3()->setSQ1(ADCChannel); ADC.SMPR()->setSamplingTime(ADCChannel, ADC::SMPR::SamplingTime::Cycles480); // Use the max sampling time } void initGPIO() { /* Step 1 - Configure the GPIOs * The BAT_CHRG pin is connected to the Li-Po charging IC. That pin uses an * open-drain output. Open-drain output are either connected to ground or left * floating. To interact with such an output, our input must therefore be * pulled up. */ ChargingGPIO.MODER()->setMode(ChargingPin, GPIO::MODER::Mode::Input); ChargingGPIO.PUPDR()->setPull(ChargingPin, GPIO::PUPDR::Pull::Up); } void shutdown() { ChargingGPIO.MODER()->setMode(ChargingPin, GPIO::MODER::Mode::Analog); ChargingGPIO.PUPDR()->setPull(ChargingPin, GPIO::PUPDR::Pull::None); // Disable the ADC ADC.CR2()->setADON(false); RCC.APB2ENR()->setADC1EN(false); } } } }