nut-debian/drivers/microsol-apc.c

/* microsol-apc.c - APC Back-UPS BR series UPS driver

   Copyright (C) 2004  Silvino B. Magalhães    <sbm2yk@gmail.com>
                 2019  Roberto Panerai Velloso <rvelloso@gmail.com>
                 2021  Ygor A. S. Regados      <ygorre@tutanota.com>

   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 2 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, write to the Free Software
   Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA

   2021/03/19 - Version 0.70 - Initial release, based on solis driver

*/

#include "config.h" /* must be first */

#include <ctype.h>
#include <stdio.h>
#include "main.h"
#include "serial.h"
#include "nut_float.h"
#include "timehead.h"

#include "microsol-common.h"
#include "microsol-apc.h"

#define DRIVER_NAME	"APC Back-UPS BR series UPS driver"
#define DRIVER_VERSION	"0.69"

/* driver description structure */
upsdrv_info_t upsdrv_info = {
	DRIVER_NAME,
	DRIVER_VERSION,
	"Silvino B. Magalhães <sbm2yk@gmail.com>"
	"Roberto Panerai Velloso <rvelloso@gmail.com>"
	"Ygor A. S. Regados <ygorre@tutanota.com>",
	DRV_STABLE,
	{ NULL }
};

#define false 0
#define true 1
#define RESP_END    0xFE
#define ENDCHAR     13		/* replies end with CR */
/* solis commands */
#define CMD_UPSCONT 0xCC
#define CMD_SHUT    0xDD
#define CMD_SHUTRET 0xDE
#define CMD_EVENT   0xCE
#define CMD_DUMP    0xCD

/** Check if UPS model is available here. */
bool_t ups_model_defined(void)
{
	unsigned int model_index;

	for (model_index = 0; MODELS[model_index] != ups_model; model_index++);
	if (model_index == MODEL_COUNT) {
		return 0;
	} else {
		return 1;
	}
}

/** Set UPS model name. */
void set_ups_model(void)
{
	switch (ups_model) {
	case 183:
		model_name = "BZ2200I-BR";
		break;
	case 190:
		model_name = "BZ1500-BR";
		break;
	case 191:
		model_name = "BZ2200BI-BR";
		break;
	default:
		model_name = "Unknown UPS";
	}
}

/**
 * Parse received packet with UPS instantaneous data.
 * This function parses model-specific values, such as voltage and battery times.
 */
void scan_received_pack_model_specific(void)
{
	unsigned int relay_state;
	unsigned int model_index;
	float real_power_curve_1, real_power_curve_2, real_power_curve_3;
	float power_difference_1, power_difference_2, power_difference_3;
	bool_t recharging;

	/* Extract unprocessed data from packet */
	input_voltage = received_packet[2];
	output_voltage = received_packet[1];
	output_current = received_packet[5];
	battery_voltage = received_packet[3];

	relay_state = (received_packet[6] & 0x28) >> 3;

	/* Find array indexes for detected UPS model */
	for (model_index = 0; MODELS[model_index] != ups_model && model_index < MODEL_COUNT - 1; model_index++);
	if (MODELS[model_index] != ups_model) {
		upslogx(LOG_NOTICE, "UPS model not found, using fallback option.");
	}

	/* Start processing according to model */
	nominal_power = NOMINAL_POWER[model_index];

	input_voltage = INPUT_VOLTAGE_MULTIPLIER_A[model_index][output_220v] * input_voltage + INPUT_VOLTAGE_MULTIPLIER_B[model_index][output_220v];

	battery_voltage = BATTERY_VOLTAGE_MULTIPLIER_A[model_index] * battery_voltage + BATTERY_VOLTAGE_MULTIPLIER_B[model_index];

	output_current = OUTPUT_CURRENT_MULTIPLIER_A[model_index][line_unpowered] * output_current + OUTPUT_CURRENT_MULTIPLIER_B[model_index][line_unpowered];

	if (ups_model == 190 && line_unpowered) {
		/* Special calculation for BZ1500 on battery */
		output_voltage = battery_voltage * sqrt(output_voltage / 64.0) * OUTPUT_VOLTAGE_MULTIPLIER_A[model_index][line_unpowered][relay_state]
		    - output_current * OUTPUT_VOLTAGE_MULTIPLIER_B[model_index][line_unpowered][relay_state];
		output_voltage = 1.5091 * output_voltage + 1.5823;

		if (output_current > 4.0)
			output_voltage += output_current * 4.0;

		if (output_current > 3.0)
			output_voltage += output_current * 2.0;
		else if (output_voltage > 0.9)
			output_voltage += output_current / 3.0;
		else
			output_voltage -= 5.0;

		if (output_voltage < 100.0)
			output_voltage = 100;
	} else {
		output_voltage = OUTPUT_VOLTAGE_MULTIPLIER_A[model_index][line_unpowered][relay_state] * output_voltage + OUTPUT_VOLTAGE_MULTIPLIER_B[model_index][line_unpowered][relay_state];
	}

	if (line_unpowered) {
		input_frequency = 0;
		output_frequency = 60;
	} else {
		input_frequency = 0.37 * (257 - ((received_packet[21] + received_packet[22] * 256) >> 8));
		output_frequency = input_frequency;
	}

	apparent_power = output_current * output_voltage;

	real_power = received_packet[7] + 256 * received_packet[8];
	real_power_curve_1 = REAL_POWER_CURVE_SELECTOR_A1[model_index][relay_state] * real_power + REAL_POWER_CURVE_SELECTOR_B1[model_index][relay_state];
	real_power_curve_2 = REAL_POWER_CURVE_SELECTOR_A2[model_index][relay_state] * real_power + REAL_POWER_CURVE_SELECTOR_B2[model_index][relay_state];
	real_power_curve_3 = REAL_POWER_CURVE_SELECTOR_A3[model_index][relay_state] * real_power + REAL_POWER_CURVE_SELECTOR_B3[model_index][relay_state];

	power_difference_1 = fabs(real_power_curve_1 - apparent_power);
	power_difference_2 = fabs(real_power_curve_2 - apparent_power);
	power_difference_3 = fabs(real_power_curve_3 - apparent_power);

	if (power_difference_1 < power_difference_2 && power_difference_1 < power_difference_3) {
		real_power = REAL_POWER_MULTIPLIER_A1[model_index][relay_state] * real_power + REAL_POWER_MULTIPLIER_B1[model_index][relay_state];
	} else if (power_difference_2 < power_difference_3) {
		real_power = REAL_POWER_MULTIPLIER_A2[model_index][relay_state] * real_power + REAL_POWER_MULTIPLIER_B2[model_index][relay_state];
	} else {
		real_power = REAL_POWER_MULTIPLIER_A3[model_index][relay_state] * real_power + REAL_POWER_MULTIPLIER_B3[model_index][relay_state];
	}

	/* If real power is greater than apparent power, invert values */
	if (apparent_power < real_power) {
		apparent_power = apparent_power + real_power;
		real_power = apparent_power - real_power;
		apparent_power = apparent_power - real_power;
	}

	input_current = 1.1 * apparent_power / input_voltage;

	recharging = (0x02 & received_packet[20]) == 0x02;
	battery_charge = (100.0 * (battery_voltage - MIN_BATTERY_VOLTAGE[model_index])) / (MAX_BATTERY_VOLTAGE[model_index][recharging] - MIN_BATTERY_VOLTAGE[model_index]);
}
New upstream version 2.8.0 2022-07-10 10:23:45 +03:00			`/* microsol-apc.c - APC Back-UPS BR series UPS driver`

			`Copyright (C) 2004 Silvino B. Magalhães <sbm2yk@gmail.com>`
			`2019 Roberto Panerai Velloso <rvelloso@gmail.com>`
			`2021 Ygor A. S. Regados <ygorre@tutanota.com>`

			`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 2 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, write to the Free Software`
			`Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA`

			`2021/03/19 - Version 0.70 - Initial release, based on solis driver`

			`*/`

			`#include "config.h" /* must be first */`

			`#include <ctype.h>`
			`#include <stdio.h>`
			`#include "main.h"`
			`#include "serial.h"`
			`#include "nut_float.h"`
			`#include "timehead.h"`

			`#include "microsol-common.h"`
			`#include "microsol-apc.h"`

			`#define DRIVER_NAME "APC Back-UPS BR series UPS driver"`
			`#define DRIVER_VERSION "0.69"`

			`/* driver description structure */`
			`upsdrv_info_t upsdrv_info = {`
			`DRIVER_NAME,`
			`DRIVER_VERSION,`
			`"Silvino B. Magalhães <sbm2yk@gmail.com>"`
			`"Roberto Panerai Velloso <rvelloso@gmail.com>"`
			`"Ygor A. S. Regados <ygorre@tutanota.com>",`
			`DRV_STABLE,`
			`{ NULL }`
			`};`

			`#define false 0`
			`#define true 1`
			`#define RESP_END 0xFE`
			`#define ENDCHAR 13 /* replies end with CR */`
			`/* solis commands */`
			`#define CMD_UPSCONT 0xCC`
			`#define CMD_SHUT 0xDD`
			`#define CMD_SHUTRET 0xDE`
			`#define CMD_EVENT 0xCE`
			`#define CMD_DUMP 0xCD`

			`/** Check if UPS model is available here. */`
			`bool_t ups_model_defined(void)`
			`{`
			`unsigned int model_index;`

			`for (model_index = 0; MODELS[model_index] != ups_model; model_index++);`
			`if (model_index == MODEL_COUNT) {`
			`return 0;`
			`} else {`
			`return 1;`
			`}`
			`}`

			`/** Set UPS model name. */`
			`void set_ups_model(void)`
			`{`
			`switch (ups_model) {`
			`case 183:`
			`model_name = "BZ2200I-BR";`
			`break;`
			`case 190:`
			`model_name = "BZ1500-BR";`
			`break;`
			`case 191:`
			`model_name = "BZ2200BI-BR";`
			`break;`
			`default:`
			`model_name = "Unknown UPS";`
			`}`
			`}`

			`/**`
			`* Parse received packet with UPS instantaneous data.`
			`* This function parses model-specific values, such as voltage and battery times.`
			`*/`
			`void scan_received_pack_model_specific(void)`
			`{`
			`unsigned int relay_state;`
			`unsigned int model_index;`
			`float real_power_curve_1, real_power_curve_2, real_power_curve_3;`
			`float power_difference_1, power_difference_2, power_difference_3;`
			`bool_t recharging;`

			`/* Extract unprocessed data from packet */`
			`input_voltage = received_packet[2];`
			`output_voltage = received_packet[1];`
			`output_current = received_packet[5];`
			`battery_voltage = received_packet[3];`

			`relay_state = (received_packet[6] & 0x28) >> 3;`

			`/* Find array indexes for detected UPS model */`
			`for (model_index = 0; MODELS[model_index] != ups_model && model_index < MODEL_COUNT - 1; model_index++);`
			`if (MODELS[model_index] != ups_model) {`
			`upslogx(LOG_NOTICE, "UPS model not found, using fallback option.");`
			`}`

			`/* Start processing according to model */`
			`nominal_power = NOMINAL_POWER[model_index];`

			`input_voltage = INPUT_VOLTAGE_MULTIPLIER_A[model_index][output_220v] * input_voltage + INPUT_VOLTAGE_MULTIPLIER_B[model_index][output_220v];`

			`battery_voltage = BATTERY_VOLTAGE_MULTIPLIER_A[model_index] * battery_voltage + BATTERY_VOLTAGE_MULTIPLIER_B[model_index];`

			`output_current = OUTPUT_CURRENT_MULTIPLIER_A[model_index][line_unpowered] * output_current + OUTPUT_CURRENT_MULTIPLIER_B[model_index][line_unpowered];`

			`if (ups_model == 190 && line_unpowered) {`
			`/* Special calculation for BZ1500 on battery */`
			`output_voltage = battery_voltage * sqrt(output_voltage / 64.0) * OUTPUT_VOLTAGE_MULTIPLIER_A[model_index][line_unpowered][relay_state]`
			`- output_current * OUTPUT_VOLTAGE_MULTIPLIER_B[model_index][line_unpowered][relay_state];`
			`output_voltage = 1.5091 * output_voltage + 1.5823;`

			`if (output_current > 4.0)`
			`output_voltage += output_current * 4.0;`

			`if (output_current > 3.0)`
			`output_voltage += output_current * 2.0;`
			`else if (output_voltage > 0.9)`
			`output_voltage += output_current / 3.0;`
			`else`
			`output_voltage -= 5.0;`

			`if (output_voltage < 100.0)`
			`output_voltage = 100;`
			`} else {`
			`output_voltage = OUTPUT_VOLTAGE_MULTIPLIER_A[model_index][line_unpowered][relay_state] * output_voltage + OUTPUT_VOLTAGE_MULTIPLIER_B[model_index][line_unpowered][relay_state];`
			`}`

			`if (line_unpowered) {`
			`input_frequency = 0;`
			`output_frequency = 60;`
			`} else {`
			`input_frequency = 0.37 * (257 - ((received_packet[21] + received_packet[22] * 256) >> 8));`
			`output_frequency = input_frequency;`
			`}`

			`apparent_power = output_current * output_voltage;`

			`real_power = received_packet[7] + 256 * received_packet[8];`
			`real_power_curve_1 = REAL_POWER_CURVE_SELECTOR_A1[model_index][relay_state] * real_power + REAL_POWER_CURVE_SELECTOR_B1[model_index][relay_state];`
			`real_power_curve_2 = REAL_POWER_CURVE_SELECTOR_A2[model_index][relay_state] * real_power + REAL_POWER_CURVE_SELECTOR_B2[model_index][relay_state];`
			`real_power_curve_3 = REAL_POWER_CURVE_SELECTOR_A3[model_index][relay_state] * real_power + REAL_POWER_CURVE_SELECTOR_B3[model_index][relay_state];`

			`power_difference_1 = fabs(real_power_curve_1 - apparent_power);`
			`power_difference_2 = fabs(real_power_curve_2 - apparent_power);`
			`power_difference_3 = fabs(real_power_curve_3 - apparent_power);`

			`if (power_difference_1 < power_difference_2 && power_difference_1 < power_difference_3) {`
			`real_power = REAL_POWER_MULTIPLIER_A1[model_index][relay_state] * real_power + REAL_POWER_MULTIPLIER_B1[model_index][relay_state];`
			`} else if (power_difference_2 < power_difference_3) {`
			`real_power = REAL_POWER_MULTIPLIER_A2[model_index][relay_state] * real_power + REAL_POWER_MULTIPLIER_B2[model_index][relay_state];`
			`} else {`
			`real_power = REAL_POWER_MULTIPLIER_A3[model_index][relay_state] * real_power + REAL_POWER_MULTIPLIER_B3[model_index][relay_state];`
			`}`

			`/* If real power is greater than apparent power, invert values */`
			`if (apparent_power < real_power) {`
			`apparent_power = apparent_power + real_power;`
			`real_power = apparent_power - real_power;`
			`apparent_power = apparent_power - real_power;`
			`}`

			`input_current = 1.1 * apparent_power / input_voltage;`

			`recharging = (0x02 & received_packet[20]) == 0x02;`
			`battery_charge = (100.0 * (battery_voltage - MIN_BATTERY_VOLTAGE[model_index])) / (MAX_BATTERY_VOLTAGE[model_index][recharging] - MIN_BATTERY_VOLTAGE[model_index]);`
			`}`