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view Discovery/Src/bonex_mini.c @ 93:3d6ccfb0190b kittz
a bit of
| author | Dmitry Romanov <kitt@bk.ru> |
|---|---|
| date | Mon, 26 Nov 2018 11:38:06 +0300 |
| parents | 5f11787b4f42 |
| children |
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/////////////////////////////////////////////////////////////////////////////// /// -*- coding: UTF-8 -*- /// /// \file Discovery/Src/bonex_mini.c /// \brief voltage to battery percentage based on bonex.c for BIS PCB /// \author Heinrichs Weikamp gmbh /// \date 26-March-2017 /// /// \details /// /// $Id$ /////////////////////////////////////////////////////////////////////////////// /// \par Copyright (c) 2014-2018 Heinrichs Weikamp gmbh /// /// This program is free software: you can redistribute it and/or modify /// it under the terms of the GNU General Public License as published by /// the Free Software Foundation, either version 3 of the License, or /// (at your option) any later version. /// /// This program is distributed in the hope that it will be useful, /// but WITHOUT ANY WARRANTY; without even the implied warranty of /// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the /// GNU General Public License for more details. /// /// You should have received a copy of the GNU General Public License /// along with this program. If not, see <http://www.gnu.org/licenses/>. ////////////////////////////////////////////////////////////////////////////// /* ============================================================================== ##### CAN data ##### ============================================================================== [..] is stored static in BONEX_CAN_Config see example CAN_Networking for STM32303C_EVAL */ /* Includes ------------------------------------------------------------------*/ #include "bonex_mini.h" /* Private variables ---------------------------------------------------------*/ enum { TYPE_ECOS = 0, TYPE_RS = 1, TYPE_MAX }; const uint16_t loadVoltageInverted[TYPE_MAX][21] = { { // ECOS 0 }, { // RS 38000, // 0% >= index *5 ist Ergebnis Kapazit�t 38875, // 5% 39750, // 10% 40625, 41500, 42050, 42600, 43150, 43700, 44250, 44800, 45350, 45900, 46450, 47000, // 70% 47550, // 75% 48100, 48450, // 85% 48800, 49150, 49500, //100% , index = 20 } }; uint8_t BONEX_mini_ResidualCapacityVoltageBased(float voltage_V, uint16_t ageInMilliSecondsSinceLast) { static uint8_t capacityStorage = 0; static uint32_t voltage_mV_storage_32bit = 0; static uint16_t storageCounter = 0; uint16_t voltage_mV = (uint16_t)(1000 * voltage_V); uint8_t calcNow = 0; if(ageInMilliSecondsSinceLast < 2000) { voltage_mV_storage_32bit += voltage_mV; storageCounter++; } else { storageCounter = 0; voltage_mV_storage_32bit = 0; } if(storageCounter >= 600) { voltage_mV_storage_32bit /= storageCounter; voltage_mV = (uint16_t)voltage_mV_storage_32bit; storageCounter = 1; voltage_mV_storage_32bit = voltage_mV; calcNow = 1; } else if(storageCounter == 1) // value immediately but not called after 600 counter ;-) { voltage_mV = (uint16_t)voltage_mV_storage_32bit; calcNow = 1; } if(calcNow) { for(int i = 20; i>=0; i--) { if(voltage_mV >= loadVoltageInverted[1][i]) { capacityStorage = i*5; break; } } } return capacityStorage; } /* uint8_t BONEX_mini_ResidualCapacityVoltageBased(float voltage_V, uint16_t ageInMilliSecondsSinceLast) { static uint8_t capacityStorage = 0; static uint16_t voltage_mV_storage[5] = {0,0,0,0,0}; // number six is used directly from voltage_mV uint32_t voltage_mV = (uint32_t)(1000 * voltage_V); // if necessary reset container and return actual voltage_V as capacity if(ageInMilliSecondsSinceLast > 2000) { capacityStorage = 0; for(int i = 0; i<5; i++) { voltage_mV_storage[i] = 0; } } // find storage container or, if full, use it as number six and recalc voltage_mV based on those six values int ptr = -1; do { ptr++; } while ((ptr < 5) && voltage_mV_storage[ptr] != 0); if(ptr == 5) { for(int i = 0; i<5; i++) { voltage_mV += voltage_mV_storage[i]; voltage_mV_storage[i] = 0; } voltage_mV += 3; voltage_mV /= 6; capacityStorage = 0; } else { voltage_mV_storage[ptr] = voltage_mV; } // calc result if update necessary if(capacityStorage == 0) { for(int i = 20; i>=0; i--) { if(voltage_mV >= loadVoltageInverted[1][i]) { capacityStorage = i*5; break; } } } return capacityStorage; } #define ECOS_VMAX 290 #define ECOS_VMIN 195 #define ECOS_STEP 5 #define RS_VMAX 500 #define RS_VMIN 360 #define RS_STEP 5 #define ECOS_LENGTH (((ECOS_VMAX - ECOS_VMIN) / ECOS_STEP) + 1) #define RS_LENGTH (((RS_VMAX - RS_VMIN) / RS_STEP) + 1) #define MAX_LENGTH (ECOS_LENGTH>RS_LENGTH? ECOS_LENGTH:RS_LENGTH) typedef struct { uint8_t load[3]; } load; const int32_t currentMaxLoad[TYPE_MAX] = { 17000,14000}; const int32_t currentPartialLoad[TYPE_MAX] = { 1000, 1000}; const uint16_t voltageCharged[TYPE_MAX] = { 280, 480}; const uint16_t voltageMax[TYPE_MAX] = { ECOS_VMAX, RS_VMAX}; const uint16_t voltageMin[TYPE_MAX] = { ECOS_VMIN, RS_VMIN}; const uint8_t voltageSteps[TYPE_MAX] = { ECOS_STEP, RS_STEP}; const uint8_t length[TYPE_MAX] = { ECOS_LENGTH, RS_LENGTH}; const uint8_t loadVoltage[TYPE_MAX][MAX_LENGTH][3] = { { // ECOS // no,teil,voll { 0, 5, 0}, // voltageMin 19.5 { 0, 5, 0}, // voltageMin + 0.5V { 0, 5, 0}, // 20.5 { 5, 5, 5}, // 21 { 5, 5, 5}, // 21.5 { 5, 10, 10}, // 22 { 5, 10, 15}, // 22.5 { 10, 15, 30}, // 23 { 20, 30, 45}, // 23.5 { 30, 40, 60}, // 24 { 40, 50, 65}, // 24.5 { 50, 60, 75}, // 25 { 60, 70, 80}, // 25.5 { 70, 80, 85}, // 26 { 80, 90, 85}, // 26.5 { 85, 90, 90}, // 27 { 90, 95, 90}, // 27.5 { 95, 95, 95}, // 28 {100,100,100}, // 28.5 {100,100,100}, // voltageMax 29 }, { // RS // no,teil,voll { 0, 0, 0}, // voltageMin 36 V { 2, 0, 2}, // voltageMin + 0.5V { 5, 0, 5}, // 37 { 5, 2, 5}, // { 5, 5, 5}, // 38 { 5, 5, 10}, // { 5, 5, 15}, // 39 { 7, 7, 17}, // { 10, 10, 20}, // 40 { 15, 12, 27}, // { 20, 15, 35}, // 41 { 27, 22, 42}, // { 35, 30, 50}, // 42 { 42, 37, 55}, // { 50, 45, 60}, // 43 { 55, 50, 67}, // { 60, 55, 75}, // 44 { 67, 57, 80}, // { 75, 60, 85}, // 45 { 77, 65, 87}, // { 80, 70, 90}, // 46 { 85, 75, 90}, // { 90, 80, 90}, // 47 { 92, 85, 92}, // { 95, 90, 95}, // 48 { 95, 92, 97}, // { 95, 95,100}, // 49 { 97, 97,100}, // {100,100,100} // 50 } }; void BONEX_calc_new_ResidualCapacity(uint8_t *residualC, uint32_t voltage_mV, int32_t current_mA, uint8_t scooterType) // as in BIS { uint8_t actualLoad = 0; uint8_t remainder = 0; uint32_t voltagePointer = 0; if(voltage_mV == 0) return; if(scooterType >= TYPE_MAX) return; if(voltage_mV < (voltageMin[scooterType] * 100)) { *residualC = 0; return; } else if(voltage_mV >= (voltageMax[scooterType] * 100)) { *residualC = 100; return; } else // check if charged and reset residualC for further calculation if(voltage_mV >= (voltageCharged[scooterType] * 100)) { *residualC = 100; return; } // define the line we are working if(current_mA >= currentMaxLoad[scooterType]) actualLoad = 2; else if(current_mA >= currentPartialLoad[scooterType]) actualLoad = 1; else actualLoad = 0; voltagePointer = (voltage_mV - ((uint32_t)(voltageMin[scooterType])) * 100) / (voltageSteps[scooterType] * 100); // should be checked with if(... >= voltageMax) but for safety if(voltagePointer >= length[scooterType]) { *residualC = 100; return; } if(loadVoltage[scooterType][voltagePointer][actualLoad] < *residualC) *residualC = loadVoltage[scooterType][voltagePointer][actualLoad]; else if(loadVoltage[scooterType][voltagePointer][actualLoad] >= (*residualC + 20)) *residualC = loadVoltage[scooterType][voltagePointer][actualLoad]; // steps of 5 remainder = (*residualC)%5; if(remainder) *residualC += (5 - remainder); // safety if(*residualC > 100) *residualC = 100; return; } */