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/* Copyright 2018 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*
* Battery pack vendor provided charging profile
*/
#include "battery.h"
#include "charge_state.h"
#include "charger_mt6370.h"
#include "console.h"
#include "driver/battery/max17055.h"
#include "ec_commands.h"
#include "util.h"
#define TEMP_OUT_OF_RANGE TEMP_ZONE_COUNT
#ifdef BOARD_KAKADU
#define BATT_ID 1
#else
#define BATT_ID 0
#endif
#define BATTERY_SIMPLO_CHARGE_MIN_TEMP 0
#define BATTERY_SIMPLO_CHARGE_MAX_TEMP 60
#define BATTERY_ATL_CHARGE_MIN_TEMP -20
#define BATTERY_ATL_CHARGE_MAX_TEMP 60
#define CPRINTS(format, args...) cprints(CC_CHARGER, format, ## args)
enum battery_type {
BATTERY_SIMPLO = 0,
BATTERY_ATL,
BATTERY_COUNT
};
static const struct battery_info info[] = {
[BATTERY_SIMPLO] = {
.voltage_max = 4400,
.voltage_normal = 3860,
.voltage_min = 3000,
.precharge_current = 256,
.start_charging_min_c = 0,
.start_charging_max_c = 45,
.charging_min_c = 0,
.charging_max_c = 60,
.discharging_min_c = -20,
.discharging_max_c = 60,
},
[BATTERY_ATL] = {
.voltage_max = 4370,
.voltage_normal = 3860,
.voltage_min = 3150,
.precharge_current = 256,
.start_charging_min_c = 0,
.start_charging_max_c = 45,
.charging_min_c = 0,
.charging_max_c = 60,
.discharging_min_c = -20,
.discharging_max_c = 60,
},
};
static const struct max17055_batt_profile batt_profile[] = {
[BATTERY_SIMPLO] = {
.is_ez_config = 1,
.design_cap = MAX17055_DESIGNCAP_REG(6910),
.ichg_term = MAX17055_ICHGTERM_REG(235),
.v_empty_detect = MAX17055_VEMPTY_REG(3000, 3600),
},
[BATTERY_ATL] = {
.is_ez_config = 1,
.design_cap = MAX17055_DESIGNCAP_REG(7270),
.ichg_term = MAX17055_ICHGTERM_REG(500),
.v_empty_detect = MAX17055_VEMPTY_REG(3000, 3600),
},
};
static const struct max17055_alert_profile alert_profile[] = {
[BATTERY_SIMPLO] = {
.v_alert_mxmn = VALRT_DISABLE,
.t_alert_mxmn = MAX17055_TALRTTH_REG(
BATTERY_SIMPLO_CHARGE_MAX_TEMP,
BATTERY_SIMPLO_CHARGE_MIN_TEMP),
.s_alert_mxmn = SALRT_DISABLE,
.i_alert_mxmn = IALRT_DISABLE,
},
[BATTERY_ATL] = {
.v_alert_mxmn = VALRT_DISABLE,
.t_alert_mxmn = MAX17055_TALRTTH_REG(
BATTERY_ATL_CHARGE_MAX_TEMP,
BATTERY_ATL_CHARGE_MIN_TEMP),
.s_alert_mxmn = SALRT_DISABLE,
.i_alert_mxmn = IALRT_DISABLE,
},
};
const struct max17055_batt_profile *max17055_get_batt_profile(void)
{
return &batt_profile[BATT_ID];
}
const struct max17055_alert_profile *max17055_get_alert_profile(void)
{
return &alert_profile[BATT_ID];
}
const struct battery_info *battery_get_info(void)
{
return &info[BATT_ID];
}
enum battery_disconnect_state battery_get_disconnect_state(void)
{
if (battery_is_present() == BP_YES)
return BATTERY_NOT_DISCONNECTED;
return BATTERY_DISCONNECTED;
}
int charger_profile_override(struct charge_state_data *curr)
{
#ifdef BOARD_KAKADU
static timestamp_t deadline_48;
static timestamp_t deadline_2;
int cycle_count = 0, rv, val;
#endif
/* battery temp in 0.1 deg C */
int bat_temp_c = curr->batt.temperature - 2731;
/*
* Keep track of battery temperature range:
*
* ZONE_0 ZONE_1 ZONE_2
* -----+--------+--------+------------+----- Temperature (C)
* t0 t1 t2 t3
*/
enum {
TEMP_ZONE_0, /* t0 < bat_temp_c <= t1 */
TEMP_ZONE_1, /* t1 < bat_temp_c <= t2 */
TEMP_ZONE_2, /* t2 < bat_temp_c <= t3 */
TEMP_ZONE_3, /* t3 < bat_temp_c <= t4 */
TEMP_ZONE_COUNT
} temp_zone;
static struct {
int temp_min; /* 0.1 deg C */
int temp_max; /* 0.1 deg C */
int desired_current; /* mA */
int desired_voltage; /* mV */
} temp_zones[BATTERY_COUNT][TEMP_ZONE_COUNT] = {
[BATTERY_SIMPLO] = {
/* Add a empty range here to avoid TEMP_ZONE_COUNT mismatch. */
/* TEMP_ZONE_0 */
{BATTERY_SIMPLO_CHARGE_MIN_TEMP * 10,
BATTERY_SIMPLO_CHARGE_MIN_TEMP * 10, 1772, 4376},
/* TEMP_ZONE_1 */
{BATTERY_SIMPLO_CHARGE_MIN_TEMP * 10, 150, 1772, 4376},
/* TEMP_ZONE_2 */
{150, 450, 4020, 4376},
/* TEMP_ZONE_3 */
{450, BATTERY_SIMPLO_CHARGE_MAX_TEMP * 10, 3350, 4300},
},
[BATTERY_ATL] = {
/* TEMP_ZONE_0 */
{BATTERY_ATL_CHARGE_MIN_TEMP * 10, 50, 719, 4370},
/* TEMP_ZONE_1 */
{50, 100, 2157, 4370},
/* TEMP_ZONE_2 */
{100, 450, 3595, 4370},
/* TEMP_ZONE_3 */
{450, BATTERY_ATL_CHARGE_MAX_TEMP * 10, 2516, 4100},
},
};
BUILD_ASSERT(ARRAY_SIZE(temp_zones[BATT_ID]) == TEMP_ZONE_COUNT);
BUILD_ASSERT(ARRAY_SIZE(temp_zones) == BATTERY_COUNT);
if ((curr->batt.flags & BATT_FLAG_BAD_TEMPERATURE) ||
(bat_temp_c < temp_zones[BATT_ID][0].temp_min) ||
(bat_temp_c >= temp_zones[BATT_ID][TEMP_ZONE_COUNT - 1].temp_max))
temp_zone = TEMP_OUT_OF_RANGE;
else {
for (temp_zone = 0; temp_zone < TEMP_ZONE_COUNT; temp_zone++) {
if (bat_temp_c <
temp_zones[BATT_ID][temp_zone].temp_max)
break;
}
}
if (curr->state != ST_CHARGE)
return 0;
switch (temp_zone) {
case TEMP_ZONE_0:
case TEMP_ZONE_1:
case TEMP_ZONE_2:
case TEMP_ZONE_3:
curr->requested_current =
temp_zones[BATT_ID][temp_zone].desired_current;
curr->requested_voltage =
temp_zones[BATT_ID][temp_zone].desired_voltage;
break;
case TEMP_OUT_OF_RANGE:
curr->requested_current = curr->requested_voltage = 0;
curr->batt.flags &= ~BATT_FLAG_WANT_CHARGE;
curr->state = ST_IDLE;
break;
}
#ifdef BOARD_KAKADU
/* Check cycle count to decrease charging voltage. */
rv = battery_cycle_count(&val);
if (!rv)
cycle_count = val;
if (cycle_count > 300 && cycle_count <= 600)
curr->requested_voltage = 4320;
else if (cycle_count > 600 && cycle_count <= 1000)
curr->requested_voltage = 4300;
else if (cycle_count > 1000)
curr->requested_voltage = 4250;
/* Should not keep charging voltage > 4250mV for 48hrs. */
if ((curr->state == ST_DISCHARGE) ||
curr->chg.voltage < 4250) {
deadline_48.val = 0;
/* Starting count 48hours */
} else if (curr->state == ST_CHARGE ||
curr->state == ST_PRECHARGE) {
if (deadline_48.val == 0)
deadline_48.val = get_time().val +
CHARGER_LIMIT_TIMEOUT_HOURS * HOUR;
/* If charging voltage keep > 4250 for 48hrs,
set charging voltage = 4250 */
else if (timestamp_expired(deadline_48, NULL))
curr->requested_voltage = 4250;
}
/* Should not keeep battery voltage > 4100mV and
battery temperature > 45C for two hour */
if (curr->state == ST_DISCHARGE ||
curr->batt.voltage < 4100 ||
bat_temp_c < 450) {
deadline_2.val = 0;
} else if (curr->state == ST_CHARGE ||
curr->state == ST_PRECHARGE) {
if (deadline_2.val == 0)
deadline_2.val = get_time().val +
CHARGER_LIMIT_TIMEOUT_HOURS_TEMP * HOUR;
else if (timestamp_expired(deadline_2, NULL)) {
/* Set discharge and charging voltage = 4100mV */
if (curr->batt.voltage >= 4100) {
curr->requested_current = 0;
curr->requested_voltage = 4100;
}
}
}
#endif
#ifdef VARIANT_KUKUI_CHARGER_MT6370
mt6370_charger_profile_override(curr);
#endif /* CONFIG_CHARGER_MT6370 */
return 0;
}
enum ec_status charger_profile_override_get_param(uint32_t param,
uint32_t *value)
{
return EC_RES_INVALID_PARAM;
}
enum ec_status charger_profile_override_set_param(uint32_t param,
uint32_t value)
{
return EC_RES_INVALID_PARAM;
}
int get_battery_manufacturer_name(char *dest, int size)
{
static const char * const name[] = {
[BATTERY_SIMPLO] = "SIMPLO",
[BATTERY_ATL] = "Celxpert",
};
ASSERT(dest);
strzcpy(dest, name[BATT_ID], size);
return EC_SUCCESS;
}
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