Add linear approximation and use it for improving battery percentage
Add linear approximation class and use it to better model the non-linear discharge curve of the battery. Changed the minimum voltage level to 3.5V and the maximum to 4.18V. For reference the maximum observed voltage is 4.21V during charging.
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@ -1,4 +1,5 @@
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#include "components/battery/BatteryController.h"
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#include "components/utility/LinearApproximation.h"
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#include "drivers/PinMap.h"
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#include <hal/nrf_gpio.h>
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#include <nrfx_saadc.h>
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@ -60,6 +61,14 @@ void Battery::SaadcInit() {
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}
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void Battery::SaadcEventHandler(nrfx_saadc_evt_t const* p_event) {
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static const Utility::LinearApproximation<uint16_t, uint8_t, 6> aprox {{{
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{3500, 0}, // Minimum voltage before shutdown (depends on the battery)
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{3600, 10}, // Keen point that corresponds to 10%
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{3700, 25},
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{3750, 50},
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{3900, 75},
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{4180, 100} // Maximum voltage during charging is 4.21V
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}}};
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if (p_event->type == NRFX_SAADC_EVT_DONE) {
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@ -76,7 +85,7 @@ void Battery::SaadcEventHandler(nrfx_saadc_evt_t const* p_event) {
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if (isFull) {
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newPercent = 100;
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} else {
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newPercent = std::min(GetBatteryPercentageFromVoltage(voltage), static_cast<uint8_t>(isCharging ? 99 : 100));
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newPercent = std::min(aprox.GetValue(voltage), isCharging ? uint8_t {99} : uint8_t {100});
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}
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if ((isPowerPresent && newPercent > percentRemaining) || (!isPowerPresent && newPercent < percentRemaining) || firstMeasurement) {
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@ -93,37 +102,3 @@ void Battery::SaadcEventHandler(nrfx_saadc_evt_t const* p_event) {
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void Battery::Register(Pinetime::System::SystemTask* systemTask) {
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this->systemTask = systemTask;
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}
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uint8_t Battery::GetBatteryPercentageFromVoltage(uint16_t voltage) {
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// The number of line segments used to approximate the battery discharge curve.
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static const uint8_t LINE_SEGMENT_COUNT = 7;
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// The voltages (mV) at the endpoints of the line segments. Any two consecutive
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// values represent the start and end voltage of a line segment.
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static const uint16_t voltageOffsets[LINE_SEGMENT_COUNT + 1] {4157, 4063, 3882, 3747, 3716, 3678, 3583, 3500};
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// The battery percentages at the endpoints of the line segments. Note that last
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// value is omitted: It is not needed because we only need the percentages at
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// the start of each line segment.
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static const float percentageOffsets[LINE_SEGMENT_COUNT] {100.000, 95.197, 70.429, 48.947, 35.158, 18.971, 5.801};
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// The pre-calculated slopes (in battery percentage points per millivolt) of the
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// line segments.
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static const float percentageSlopes[LINE_SEGMENT_COUNT] {0.05109, 0.13684, 0.15913, 0.44481, 0.42595, 0.13863, 0.06989};
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if (voltage >= voltageOffsets[0]) {
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return 100;
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}
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if (voltage <= voltageOffsets[7]) {
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return 0;
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}
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for (uint8_t i = 0; i < LINE_SEGMENT_COUNT; i++) {
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if (voltage > voltageOffsets[i + 1]) {
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return static_cast<uint8_t>(roundf(percentageOffsets[i] + percentageSlopes[i] * (voltage - voltageOffsets[i])));
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}
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}
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return 0;
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}
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@ -49,7 +49,6 @@ namespace Pinetime {
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void SaadcEventHandler(nrfx_saadc_evt_t const* p_event);
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static void AdcCallbackStatic(nrfx_saadc_evt_t const* event);
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static uint8_t GetBatteryPercentageFromVoltage(uint16_t voltage);
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bool isReading = false;
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41
src/components/utility/LinearApproximation.h
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41
src/components/utility/LinearApproximation.h
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#pragma once
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#include <cstddef>
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#include <array>
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namespace Pinetime {
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namespace Utility {
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// based on: https://github.com/SHristov92/LinearApproximation/blob/main/Linear.h
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template <typename Key, typename Value, std::size_t Size> class LinearApproximation {
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using Point = struct {
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Key key;
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Value value;
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};
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public:
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LinearApproximation(const std::array<Point, Size>&& sorted_points) : points {sorted_points} {
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}
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Value GetValue(Key key) const {
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if (key <= points[0].key) {
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return points[0].value;
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}
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for (std::size_t i = 1; i < Size; i++) {
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const auto& p = points[i];
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const auto& p_prev = points[i - 1];
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if (key < p.key) {
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return p_prev.value + (key - p_prev.key) * (p.value - p_prev.value) / (p.key - p_prev.key);
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}
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}
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return points[Size - 1].value;
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}
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private:
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std::array<Point, Size> points;
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};
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}
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}
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