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Buelmann: new implementation for ceiling Since my first functional fix in the ceiling computation in commit ceecabfddb57, I noticed that the computation used a linear search, that became rather computational expensive after that commit. The simple question is: why not a binary search? So, this commit implements the binary search. But there is a long story attached to this. Comparing ceiling results from hwOS and this OSTC4 code were very different. Basically, the original OSTC4 algorithm computed the ceiling using the same GFlow to GFhigh slope, in such a way, that the ceiling was in sync with the presented deco stops, where the hwOS code presents a GFhigh based ceiling. This said, it is more logical when the OSTC4 and hwOS code give similar results. This new recursive algorithm gives very similar results for the ceiling compared to hwOS. To be complete here, the Buelmann ceiling is the depth to which you can ascend, so that the leading tissue reaches GFhigh. This also explains why the deepest deco stop is normally deeper than the ceiling (unless one dives with GF like 80/80). The code implemented here is rather straightforward recursion. Signed-off-by: Jan Mulder <jlmulder@xs4all.nl>
author Jan Mulder <jlmulder@xs4all.nl>
date Thu, 11 Apr 2019 17:48:48 +0200
parents b23de15e2861
children 2defc8cd93ce
line wrap: on
line source

/**
  ******************************************************************************
  * @file    batteryGasGauge.c 
  * @author  heinrichs weikamp gmbh
  * @version V0.0.1
  * @date    09-Dec-2014
  * @brief   LTC2942 Battery Gas Gauge
  *           
  @verbatim                 
  ============================================================================== 
                ##### stm32f4xx_hal_i2c.c modification #####
  ============================================================================== 
	The LTC2942 requires an repeated start condition without stop condition
	for data reception.
	
  @endverbatim
  ******************************************************************************
  * @attention
  *
  * <h2><center>&copy; COPYRIGHT(c) 2014 heinrichs weikamp</center></h2>
  *
  ******************************************************************************
  */ 
/* Includes ------------------------------------------------------------------*/
#include "batteryGasGauge.h"
#include "baseCPU2.h"
#include "stm32f4xx_hal.h"
#include "i2c.h"

static float battery_f_voltage = 0;
static float battery_f_charge_percent = 0;

#define BGG_BATTERY_OFFSET          (26123)  //; 65536-(3,35Ah/0,085mAh)
#define BGG_BATTERY_DIVIDER         (394)    //; 3,35Ah/0,085mAh/100 [%]

float get_voltage(void)
{
#ifdef OSTC_ON_DISCOVERY_HARDWARE
	return 3.0f;
#endif

	return battery_f_voltage;
}


float get_charge(void)
{
	#ifdef OSTC_ON_DISCOVERY_HARDWARE
		return 100.0f;
	#endif
	
	return battery_f_charge_percent;
}


void init_battery_gas_gauge(void)
{
	#ifdef OSTC_ON_DISCOVERY_HARDWARE
		return;
	#endif
	
	uint8_t buffer[2];
	buffer[0] = 0x01;

	// F8 = 11111000:
	// Vbat 3.0V (11)
	// Prescale M = 128 (111)
	// AL/CC pin disable (0)
	// Shutdown (0)
	buffer[1] = 0xF8;
	I2C_Master_Transmit(DEVICE_BATTERYGAUGE, buffer, 2);
}

static void disable_adc(void)
{
	uint8_t buffer[2];
	buffer[0] = 0x01;

	// according to the datasheet of the LTC2942, the adc shall
	// be disabled when writing to the gauge registers

	// 0xF9 = 11111001:
	// see init_battery_gas_gauge()
	// Shutdown (1)
	buffer[1] = 0xF9;
	I2C_Master_Transmit(DEVICE_BATTERYGAUGE, buffer, 2);
}


void battery_gas_gauge_get_data(void)
{
	#ifdef OSTC_ON_DISCOVERY_HARDWARE
		return;
	#endif
	
	float battery_f_voltage_local;
	float battery_f_charge_percent_local;
	
	uint8_t bufferReceive[10];
	I2C_Master_Receive(		DEVICE_BATTERYGAUGE, bufferReceive, 10);

	battery_f_voltage_local =  (float)(bufferReceive[8] * 256);
	battery_f_voltage_local += (float)(bufferReceive[9]);
	battery_f_voltage_local *= (float)6 / (float)0xFFFF;

	// max/full: 0.085 mAh * 1 * 65535 = 5570 mAh
	battery_f_charge_percent_local =  (float)(bufferReceive[2] * 256);
	battery_f_charge_percent_local += (float)(bufferReceive[3]);
	battery_f_charge_percent_local -= BGG_BATTERY_OFFSET;
	battery_f_charge_percent_local /= BGG_BATTERY_DIVIDER;
	
	if(battery_f_charge_percent_local < 0)
		battery_f_charge_percent_local = 0;
	
	battery_f_voltage = battery_f_voltage_local;
	battery_f_charge_percent = battery_f_charge_percent_local;
}


void battery_gas_gauge_set_charge_full(void)
{
	disable_adc();
	#ifdef OSTC_ON_DISCOVERY_HARDWARE
		return;
	#endif
	
	uint8_t bufferSend[3];
	bufferSend[0] = 0x02;
	bufferSend[1] = 0xFF;
	bufferSend[2] = 0xFF;
	I2C_Master_Transmit(  DEVICE_BATTERYGAUGE, bufferSend, 3);
	init_battery_gas_gauge();
}


void battery_gas_gauge_set(float percentage)
{

	disable_adc();
	#ifdef OSTC_ON_DISCOVERY_HARDWARE
		return;
	#endif

	uint16_t mAhSend;
	
	if(percentage >= 100)
		mAhSend = 0xFFFF;
	else {
		mAhSend = (percentage * BGG_BATTERY_DIVIDER) + BGG_BATTERY_OFFSET;
	}
	
	uint8_t bufferSend[3];
	bufferSend[0] = 0x02;
	bufferSend[1] = (uint8_t)(mAhSend / 256);
	bufferSend[2] = (uint8_t)(mAhSend & 0xFF);
	I2C_Master_Transmit(  DEVICE_BATTERYGAUGE, bufferSend, 3);
	init_battery_gas_gauge();
}


/************************ (C) COPYRIGHT heinrichs weikamp *****END OF FILE****/