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base: jeka:1.4.0-rc.22
Branches Tags
jeka:master jeka:otc_fix jeka:new-equitherm jeka:hyst jeka:passive_ble jeka:async jeka:platformio_dependabot/NimBLE-Arduino/2.3.6 jeka:arduino_framework_and_idf jeka:platformio_dependabot/NimBLE-Arduino/2.1.0 jeka:1.5.0-dev
jeka:1.5.6 jeka:1.5.5 jeka:1.5.4 jeka:1.5.3 jeka:1.5.2 jeka:1.5.1 jeka:1.5.0 jeka:1.4.6 jeka:1.4.5 jeka:1.4.4 jeka:1.4.3 jeka:1.4.2 jeka:1.4.1 jeka:1.4.0 jeka:1.4.0-rc.24 jeka:1.4.0-rc.23 jeka:1.4.0-rc.22 jeka:1.4.0-rc.21 jeka:1.4.0-rc.20 jeka:1.4.0-rc.19 jeka:1.4.0-rc.18 jeka:1.4.0-rc.17 jeka:1.4.0-rc.16 jeka:1.4.0-rc.15 jeka:1.4.0-rc.14 jeka:1.4.0-rc.13 jeka:1.3.3 jeka:1.3.2 jeka:1.3.1 jeka:1.3.0 jeka:1.2.1
...
compare: jeka:1.4.0
Branches Tags
jeka:otc_fix jeka:master jeka:new-equitherm jeka:hyst jeka:passive_ble jeka:async jeka:platformio_dependabot/NimBLE-Arduino/2.3.6 jeka:arduino_framework_and_idf jeka:platformio_dependabot/NimBLE-Arduino/2.1.0 jeka:1.5.0-dev
jeka:1.5.6 jeka:1.5.5 jeka:1.5.4 jeka:1.5.3 jeka:1.5.2 jeka:1.5.1 jeka:1.5.0 jeka:1.4.6 jeka:1.4.5 jeka:1.4.4 jeka:1.4.3 jeka:1.4.2 jeka:1.4.1 jeka:1.4.0 jeka:1.4.0-rc.24 jeka:1.4.0-rc.23 jeka:1.4.0-rc.22 jeka:1.4.0-rc.21 jeka:1.4.0-rc.20 jeka:1.4.0-rc.19 jeka:1.4.0-rc.18 jeka:1.4.0-rc.17 jeka:1.4.0-rc.16 jeka:1.4.0-rc.15 jeka:1.4.0-rc.14 jeka:1.4.0-rc.13 jeka:1.3.3 jeka:1.3.2 jeka:1.3.1 jeka:1.3.0 jeka:1.2.1

15 Commits
1.4.0-rc.2 ... 1.4.0

Author SHA1 Message Date
Yurii
f245f37dfd chore: bump version 2024-05-26 17:41:12 +03:00
Yurii
a825412f37 feat: added fault state GPIO setting 2024-05-25 02:51:10 +03:00
Yurii
935f8bd0a8 fix: outdoor sensor GPIO validation fixed 2024-05-25 00:17:55 +03:00
Yurii
f78d2f38b8 fix: equitherm with BLE indoor sensor in emergency mode fixed 2024-04-25 13:38:03 +03:00
Yurii
ef083991e3 feat: added board info on portal 2024-04-23 10:30:42 +03:00
Yurii
3c0f846335 fix: added set target indoor temp to CH2 for native heating control #58 2024-04-23 08:13:03 +03:00
Yurii
85011ce4ea chore: bump version 2024-04-22 08:19:41 +03:00
Yurii
8687e122ca feat: added native heating control by boiler; refactoring; emergency settings removed from HA 2024-04-22 08:18:59 +03:00
Yurii
d35ea81080 fix: PID optimization, correction of default PID settings 2024-04-18 00:04:23 +03:00
Yurii
cca8ec58b4 fix: fix radio on settings page (portal) 2024-04-16 18:58:28 +03:00
Yurii
301b14bbd4 chore: bump version 2024-04-15 15:07:28 +03:00
Yurii
41ce9b268e fix: fix set heating temp on ITALTHERM TIME MAX 30F 2024-04-15 15:00:41 +03:00
Yurii
646939179e fix: serial on s2, s3 fixed 2024-04-15 05:49:46 +03:00
Yurii
73dddd18f0 fix: scan networks on s3 fixed 2024-04-15 02:47:42 +03:00
Yurii
f069de0415 chore: fix typo 2024-04-12 21:47:09 +03:00
17 changed files with 915 additions and 745 deletions
Expand all files Collapse all files

1
README.md
View File

@@ -31,7 +31,6 @@
- The current temperature of the heat carrier (usually the return heat carrier)
- Set heat carrier temperature (depending on the selected mode)
- Current hot water temperature
- Auto tuning of PID and Equitherm parameters *(in development)*
- [Home Assistant](https://www.home-assistant.io/) integration via MQTT. The ability to create any automation for the boiler!
![logo](/assets/ha.png)

30
lib/CustomOpenTherm/CustomOpenTherm.h
View File

@@ -126,6 +126,36 @@ public:
return isValidResponse(response);
}
bool setRoomSetpoint(float temperature) {
unsigned long response = this->sendRequest(buildRequest(
OpenThermMessageType::WRITE_DATA,
OpenThermMessageID::TrSet,
temperatureToData(temperature)
));
return isValidResponse(response);
}
bool setRoomSetpointCh2(float temperature) {
unsigned long response = this->sendRequest(buildRequest(
OpenThermMessageType::WRITE_DATA,
OpenThermMessageID::TrSetCH2,
temperatureToData(temperature)
));
return isValidResponse(response);
}
bool setRoomTemp(float temperature) {
unsigned long response = this->sendRequest(buildRequest(
OpenThermMessageType::WRITE_DATA,
OpenThermMessageID::Tr,
temperatureToData(temperature)
));
return isValidResponse(response);
}
bool sendBoilerReset() {
unsigned int data = 1;
data <<= 8;

19
platformio.ini
View File

@@ -27,6 +27,7 @@ lib_deps =
laxilef/TinyLogger@^1.1.0
build_flags =
-D PIO_FRAMEWORK_ARDUINO_LWIP2_LOW_MEMORY
;-D PIO_FRAMEWORK_ARDUINO_LWIP2_HIGHER_BANDWIDTH_LOW_FLASH
-D PIO_FRAMEWORK_ARDUINO_ESPRESSIF_SDK305
-mtext-section-literals
-D MQTT_CLIENT_STD_FUNCTION_CALLBACK=1
@@ -51,7 +52,7 @@ monitor_speed = 115200
monitor_filters = direct
board_build.flash_mode = dio
board_build.filesystem = littlefs
version = 1.4.0-rc.22
version = 1.4.0
; Defaults
[esp8266_defaults]
@@ -67,6 +68,8 @@ board_build.ldscript = eagle.flash.4m1m.ld
[esp32_defaults]
platform = espressif32@^6.6
platform_packages =
platformio/framework-arduinoespressif32 @ https://github.com/espressif/arduino-esp32/archive/refs/tags/2.0.15.zip
board_build.partitions = esp32_partitions.csv
lib_deps =
${env.lib_deps}
@@ -131,13 +134,18 @@ build_flags =
[env:s2_mini]
platform = ${esp32_defaults.platform}
platform_packages = ${esp32_defaults.platform_packages}
board = lolin_s2_mini
board_build.partitions = ${esp32_defaults.board_build.partitions}
lib_deps = ${esp32_defaults.lib_deps}
lib_ignore = ${esp32_defaults.lib_ignore}
extra_scripts = ${esp32_defaults.extra_scripts}
build_unflags =
-DARDUINO_USB_MODE=1
build_flags =
${esp32_defaults.build_flags}
-D ARDUINO_USB_MODE=0
-D ARDUINO_USB_CDC_ON_BOOT=1
-D DEFAULT_OT_IN_GPIO=33
-D DEFAULT_OT_OUT_GPIO=35
-D DEFAULT_SENSOR_OUTDOOR_GPIO=9
@@ -147,6 +155,7 @@ build_flags =
[env:s3_mini]
platform = ${esp32_defaults.platform}
platform_packages = ${esp32_defaults.platform_packages}
board = lolin_s3_mini
board_build.partitions = ${esp32_defaults.board_build.partitions}
lib_deps =
@@ -154,8 +163,12 @@ lib_deps =
h2zero/NimBLE-Arduino@^1.4.1
lib_ignore = ${esp32_defaults.lib_ignore}
extra_scripts = ${esp32_defaults.extra_scripts}
build_unflags =
-DARDUINO_USB_MODE=1
build_flags =
${esp32_defaults.build_flags}
-D ARDUINO_USB_MODE=0
-D ARDUINO_USB_CDC_ON_BOOT=1
-D USE_BLE=1
-D DEFAULT_OT_IN_GPIO=35
-D DEFAULT_OT_OUT_GPIO=36
@@ -166,6 +179,8 @@ build_flags =
[env:c3_mini]
platform = ${esp32_defaults.platform}
platform_packages =
platformio/framework-arduinoespressif32 @ https://github.com/espressif/arduino-esp32/archive/refs/tags/2.0.15.zip
board = lolin_c3_mini
board_build.partitions = ${esp32_defaults.board_build.partitions}
lib_deps =
@@ -187,6 +202,7 @@ build_flags =
[env:nodemcu_32s]
platform = ${esp32_defaults.platform}
platform_packages = ${esp32_defaults.platform_packages}
board = nodemcu-32s
board_build.partitions = ${esp32_defaults.board_build.partitions}
lib_deps =
@@ -207,6 +223,7 @@ build_flags =
[env:d1_mini32]
platform = ${esp32_defaults.platform}
platform_packages = ${esp32_defaults.platform_packages}
board = wemos_d1_mini32
board_build.partitions = ${esp32_defaults.board_build.partitions}
lib_deps =

175
src/HaHelper.h
View File

@@ -6,107 +6,6 @@ public:
static const byte TEMP_SOURCE_HEATING = 0;
static const byte TEMP_SOURCE_INDOOR = 1;
bool publishSwitchEmergency(bool enabledByDefault = true) {
JsonDocument doc;
doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectId(F("emergency"));
doc[FPSTR(HA_OBJECT_ID)] = this->getObjectId(F("emergency"));
doc[FPSTR(HA_ENTITY_CATEGORY)] = F("config");
doc[FPSTR(HA_NAME)] = F("Use emergency");
doc[FPSTR(HA_ICON)] = F("mdi:sun-snowflake-variant");
doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(F("settings"));
doc[FPSTR(HA_STATE_ON)] = true;
doc[FPSTR(HA_STATE_OFF)] = false;
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.emergency.enable }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("settings/set"));
doc[FPSTR(HA_PAYLOAD_ON)] = F("{\"emergency\": {\"enable\" : true}}");
doc[FPSTR(HA_PAYLOAD_OFF)] = F("{\"emergency\": {\"enable\" : false}}");
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
return this->publish(this->getTopic(FPSTR(HA_ENTITY_SWITCH), F("emergency")).c_str(), doc);
}
bool publishNumberEmergencyTarget(UnitSystem unit = UnitSystem::METRIC, bool enabledByDefault = true) {
JsonDocument doc;
doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectId(F("emergency_target"));
doc[FPSTR(HA_OBJECT_ID)] = this->getObjectId(F("emergency_target"));
doc[FPSTR(HA_ENTITY_CATEGORY)] = F("config");
doc[FPSTR(HA_DEVICE_CLASS)] = F("temperature");
if (unit == UnitSystem::METRIC) {
doc[FPSTR(HA_UNIT_OF_MEASUREMENT)] = FPSTR(HA_UNIT_OF_MEASUREMENT_C);
doc[FPSTR(HA_MIN)] = 5;
doc[FPSTR(HA_MAX)] = 50;
} else if (unit == UnitSystem::IMPERIAL) {
doc[FPSTR(HA_UNIT_OF_MEASUREMENT)] = FPSTR(HA_UNIT_OF_MEASUREMENT_F);
doc[FPSTR(HA_MIN)] = 41;
doc[FPSTR(HA_MAX)] = 122;
}
doc[FPSTR(HA_NAME)] = F("Emergency target temp");
doc[FPSTR(HA_ICON)] = F("mdi:thermometer-alert");
doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(F("settings"));
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.emergency.target|float(0)|round(1) }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("settings/set"));
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"emergency\": {\"target\" : {{ value }}}}");
doc[FPSTR(HA_STEP)] = 0.5;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
return this->publish(this->getTopic(FPSTR(HA_ENTITY_NUMBER), F("emergency_target")).c_str(), doc);
}
bool publishSwitchEmergencyUseEquitherm(bool enabledByDefault = true) {
JsonDocument doc;
doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->getDeviceTopic(F("settings"));
doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_VALUE_TEMPLATE)] = F("{{ iif(value_json.sensors.outdoor.type != 1, 'online', 'offline') }}");
doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectId(F("emergency_use_equitherm"));
doc[FPSTR(HA_OBJECT_ID)] = this->getObjectId(F("emergency_use_equitherm"));
doc[FPSTR(HA_ENTITY_CATEGORY)] = F("config");
doc[FPSTR(HA_NAME)] = F("Use equitherm in emergency");
doc[FPSTR(HA_ICON)] = F("mdi:snowflake-alert");
doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(F("settings"));
doc[FPSTR(HA_STATE_ON)] = true;
doc[FPSTR(HA_STATE_OFF)] = false;
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.emergency.useEquitherm }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("settings/set"));
doc[FPSTR(HA_PAYLOAD_ON)] = F("{\"emergency\": {\"useEquitherm\" : true}}");
doc[FPSTR(HA_PAYLOAD_OFF)] = F("{\"emergency\": {\"useEquitherm\" : false}}");
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
return this->publish(this->getTopic(FPSTR(HA_ENTITY_SWITCH), F("emergency_use_equitherm")).c_str(), doc);
}
bool publishSwitchEmergencyUsePid(bool enabledByDefault = true) {
JsonDocument doc;
doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->getDeviceTopic(F("settings"));
doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_VALUE_TEMPLATE)] = F("{{ iif(value_json.sensors.indoor.type != 1, 'online', 'offline') }}");
doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectId(F("emergency_use_pid"));
doc[FPSTR(HA_OBJECT_ID)] = this->getObjectId(F("emergency_use_pid"));
doc[FPSTR(HA_ENTITY_CATEGORY)] = F("config");
doc[FPSTR(HA_NAME)] = F("Use PID in emergency");
doc[FPSTR(HA_ICON)] = F("mdi:snowflake-alert");
doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(F("settings"));
doc[FPSTR(HA_STATE_ON)] = true;
doc[FPSTR(HA_STATE_OFF)] = false;
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.emergency.usePid }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("settings/set"));
doc[FPSTR(HA_PAYLOAD_ON)] = F("{\"emergency\": {\"usePid\" : true}}");
doc[FPSTR(HA_PAYLOAD_OFF)] = F("{\"emergency\": {\"usePid\" : false}}");
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
return this->publish(this->getTopic(FPSTR(HA_ENTITY_SWITCH), F("emergency_use_pid")).c_str(), doc);
}
bool publishSwitchHeating(bool enabledByDefault = true) {
JsonDocument doc;
doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->getDeviceTopic(F("status"));
@@ -175,7 +74,7 @@ public:
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"heating\": {\"target\" : {{ value }}}}");
doc[FPSTR(HA_MIN)] = minTemp;
doc[FPSTR(HA_MAX)] = maxTemp;
doc[FPSTR(HA_STEP)] = 0.5;
doc[FPSTR(HA_STEP)] = 0.5f;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -206,7 +105,7 @@ public:
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"heating\": {\"hysteresis\" : {{ value }}}}");
doc[FPSTR(HA_MIN)] = 0;
doc[FPSTR(HA_MAX)] = 5;
doc[FPSTR(HA_STEP)] = 0.1;
doc[FPSTR(HA_STEP)] = 0.1f;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -234,7 +133,7 @@ public:
doc[FPSTR(HA_NAME)] = F("Heating setpoint");
doc[FPSTR(HA_ICON)] = F("mdi:coolant-temperature");
doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(F("state"));
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.parameters.heatingSetpoint|int(0) }}");
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.parameters.heatingSetpoint|float(0)|round(1) }}");
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -433,7 +332,7 @@ public:
doc[FPSTR(HA_NAME)] = F("DHW target");
doc[FPSTR(HA_ICON)] = F("mdi:water-pump");
doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(F("settings"));
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.dhw.target|int(0) }}");
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.dhw.target|float(0)|round(1) }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("settings/set"));
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"dhw\": {\"target\" : {{ value|int(0) }}}}");
doc[FPSTR(HA_MIN)] = minTemp;
@@ -605,9 +504,9 @@ public:
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.pid.p_factor|float(0)|round(3) }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("settings/set"));
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"pid\": {\"p_factor\" : {{ value }}}}");
doc[FPSTR(HA_MIN)] = 0.1;
doc[FPSTR(HA_MIN)] = 0.1f;
doc[FPSTR(HA_MAX)] = 1000;
doc[FPSTR(HA_STEP)] = 0.1;
doc[FPSTR(HA_STEP)] = 0.1f;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -623,12 +522,12 @@ public:
doc[FPSTR(HA_NAME)] = F("PID factor I");
doc[FPSTR(HA_ICON)] = F("mdi:alpha-i-circle-outline");
doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(F("settings"));
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.pid.i_factor|float(0)|round(3) }}");
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.pid.i_factor|float(0)|round(4) }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("settings/set"));
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"pid\": {\"i_factor\" : {{ value }}}}");
doc[FPSTR(HA_MIN)] = 0;
doc[FPSTR(HA_MAX)] = 100;
doc[FPSTR(HA_STEP)] = 0.001;
doc[FPSTR(HA_STEP)] = 0.001f;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -779,9 +678,9 @@ public:
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.equitherm.n_factor|float(0)|round(3) }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("settings/set"));
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"equitherm\": {\"n_factor\" : {{ value }}}}");
doc[FPSTR(HA_MIN)] = 0.001;
doc[FPSTR(HA_MIN)] = 0.001f;
doc[FPSTR(HA_MAX)] = 10;
doc[FPSTR(HA_STEP)] = 0.001;
doc[FPSTR(HA_STEP)] = 0.001f;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -802,7 +701,7 @@ public:
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"equitherm\": {\"k_factor\" : {{ value }}}}");
doc[FPSTR(HA_MIN)] = 0;
doc[FPSTR(HA_MAX)] = 10;
doc[FPSTR(HA_STEP)] = 0.01;
doc[FPSTR(HA_STEP)] = 0.01f;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -825,7 +724,7 @@ public:
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"equitherm\": {\"t_factor\" : {{ value }}}}");
doc[FPSTR(HA_MIN)] = 0;
doc[FPSTR(HA_MAX)] = 10;
doc[FPSTR(HA_STEP)] = 0.01;
doc[FPSTR(HA_STEP)] = 0.01f;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -834,48 +733,6 @@ public:
}
bool publishSwitchTuning(bool enabledByDefault = true) {
JsonDocument doc;
doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectId(F("tuning"));
doc[FPSTR(HA_OBJECT_ID)] = this->getObjectId(F("tuning"));
doc[FPSTR(HA_ENTITY_CATEGORY)] = F("config");
doc[FPSTR(HA_NAME)] = F("Tuning");
doc[FPSTR(HA_ICON)] = F("mdi:tune-vertical");
doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(F("state"));
doc[FPSTR(HA_STATE_ON)] = true;
doc[FPSTR(HA_STATE_OFF)] = false;
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.tuning.enable }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("state/set"));
doc[FPSTR(HA_PAYLOAD_ON)] = F("{\"tuning\": {\"enable\" : true}}");
doc[FPSTR(HA_PAYLOAD_OFF)] = F("{\"tuning\": {\"enable\" : false}}");
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
return this->publish(this->getTopic(FPSTR(HA_ENTITY_SWITCH), F("tuning")).c_str(), doc);
}
bool publishSelectTuningRegulator(bool enabledByDefault = true) {
JsonDocument doc;
doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->getDeviceTopic(F("status"));
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("state/set"));
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"tuning\": {\"regulator\": {% if value == 'Equitherm' %}0{% elif value == 'PID' %}1{% endif %}}}");
doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectId(F("tuning_regulator"));
doc[FPSTR(HA_OBJECT_ID)] = this->getObjectId(F("tuning_regulator"));
doc[FPSTR(HA_ENTITY_CATEGORY)] = F("config");
doc[FPSTR(HA_NAME)] = F("Tuning regulator");
doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(F("state"));
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{% if value_json.tuning.regulator == 0 %}Equitherm{% elif value_json.tuning.regulator == 1 %}PID{% endif %}");
doc[FPSTR(HA_OPTIONS)][0] = F("Equitherm");
doc[FPSTR(HA_OPTIONS)][1] = F("PID");
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
return this->publish(this->getTopic(FPSTR(HA_ENTITY_SELECT), F("tuning_regulator")).c_str(), doc);
}
bool publishBinSensorStatus(bool enabledByDefault = true) {
JsonDocument doc;
doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
@@ -1184,7 +1041,7 @@ public:
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.temperatures.indoor|float(0)|round(1) }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("state/set"));
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"temperatures\": {\"indoor\":{{ value }}}}");
doc[FPSTR(HA_STEP)] = 0.01;
doc[FPSTR(HA_STEP)] = 0.01f;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -1243,7 +1100,7 @@ public:
doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.temperatures.outdoor|float(0)|round(1) }}");
doc[FPSTR(HA_COMMAND_TOPIC)] = this->getDeviceTopic(F("state/set"));
doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"temperatures\": {\"outdoor\":{{ value }}}}");
doc[FPSTR(HA_STEP)] = 0.01;
doc[FPSTR(HA_STEP)] = 0.01f;
doc[FPSTR(HA_MODE)] = "box";
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -1452,7 +1309,7 @@ public:
doc[FPSTR(HA_MIN_TEMP)] = minTemp;
doc[FPSTR(HA_MAX_TEMP)] = maxTemp;
doc[FPSTR(HA_TEMP_STEP)] = 0.5;
doc[FPSTR(HA_TEMP_STEP)] = 0.5f;
doc[FPSTR(HA_EXPIRE_AFTER)] = 120;
doc.shrinkToFit();
@@ -1475,7 +1332,7 @@ public:
doc[FPSTR(HA_TEMPERATURE_COMMAND_TEMPLATE)] = F("{\"dhw\": {\"target\" : {{ value|int(0) }}}}");
doc[FPSTR(HA_TEMPERATURE_STATE_TOPIC)] = this->getDeviceTopic(F("settings"));
doc[FPSTR(HA_TEMPERATURE_STATE_TEMPLATE)] = F("{{ value_json.dhw.target|int(0) }}");
doc[FPSTR(HA_TEMPERATURE_STATE_TEMPLATE)] = F("{{ value_json.dhw.target|float(0)|round(1) }}");
if (unit == UnitSystem::METRIC) {
doc[FPSTR(HA_TEMPERATURE_UNIT)] = "C";

107
src/MqttTask.h
View File

@@ -53,16 +53,25 @@ public:
Log.sinfoln(FPSTR(L_MQTT), F("Enabled"));
}
bool isConnected() {
inline bool isConnected() {
return this->connected;
}
inline void resetPublishedSettingsTime() {
this->prevPubSettingsTime = 0;
}
inline void resetPublishedVarsTime() {
this->prevPubVarsTime = 0;
}
protected:
MqttWiFiClient* wifiClient = nullptr;
MqttClient* client = nullptr;
HaHelper* haHelper = nullptr;
MqttWriter* writer = nullptr;
UnitSystem currentUnitSystem = UnitSystem::METRIC;
bool currentHomeAssistantDiscovery = false;
unsigned short readyForSendTime = 15000;
unsigned long lastReconnectTime = 0;
unsigned long connectedTime = 0;
@@ -84,7 +93,7 @@ protected:
return 2;
}
bool isReadyForSend() {
inline bool isReadyForSend() {
return millis() - this->connectedTime > this->readyForSendTime;
}
@@ -227,16 +236,25 @@ protected:
}
// publish ha entities if not published
if (this->newConnection || this->currentUnitSystem != settings.system.unitSystem) {
if (settings.mqtt.homeAssistantDiscovery) {
if (this->newConnection || !this->currentHomeAssistantDiscovery || this->currentUnitSystem != settings.system.unitSystem) {
this->publishHaEntities();
this->publishNonStaticHaEntities(true);
this->newConnection = false;
this->currentHomeAssistantDiscovery = true;
this->currentUnitSystem = settings.system.unitSystem;
} else {
// publish non static ha entities
this->publishNonStaticHaEntities();
}
} else if (this->currentHomeAssistantDiscovery) {
this->currentHomeAssistantDiscovery = false;
}
if (this->newConnection) {
this->newConnection = false;
}
}
void onConnect() {
@@ -291,52 +309,26 @@ protected:
Log.swarningln(FPSTR(L_MQTT_MSG), F("Not valid json"));
return;
}
doc.shrinkToFit();
if (this->haHelper->getDeviceTopic("state/set").equals(topic)) {
this->writer->publish(this->haHelper->getDeviceTopic("state/set").c_str(), nullptr, 0, true);
this->updateVariables(doc);
if (jsonToVars(doc, vars)) {
this->resetPublishedVarsTime();
}
} else if (this->haHelper->getDeviceTopic("settings/set").equals(topic)) {
this->writer->publish(this->haHelper->getDeviceTopic("settings/set").c_str(), nullptr, 0, true);
this->updateSettings(doc);
}
}
bool updateSettings(JsonDocument& doc) {
bool changed = safeJsonToSettings(doc, settings);
doc.clear();
doc.shrinkToFit();
if (changed) {
this->prevPubSettingsTime = 0;
if (safeJsonToSettings(doc, settings)) {
this->resetPublishedSettingsTime();
fsSettings.update();
return true;
}
return false;
}
bool updateVariables(JsonDocument& doc) {
bool changed = jsonToVars(doc, vars);
doc.clear();
doc.shrinkToFit();
if (changed) {
this->prevPubVarsTime = 0;
return true;
}
return false;
}
void publishHaEntities() {
// emergency
this->haHelper->publishSwitchEmergency();
this->haHelper->publishNumberEmergencyTarget(settings.system.unitSystem);
this->haHelper->publishSwitchEmergencyUseEquitherm();
this->haHelper->publishSwitchEmergencyUsePid();
// heating
this->haHelper->publishSwitchHeating(false);
this->haHelper->publishSwitchHeatingTurbo();
@@ -363,10 +355,6 @@ protected:
this->haHelper->publishNumberEquithermFactorK();
this->haHelper->publishNumberEquithermFactorT();
// tuning
this->haHelper->publishSwitchTuning();
this->haHelper->publishSelectTuningRegulator();
// states
this->haHelper->publishBinSensorStatus();
this->haHelper->publishBinSensorOtStatus();
@@ -396,26 +384,22 @@ protected:
bool publishNonStaticHaEntities(bool force = false) {
static byte _heatingMinTemp, _heatingMaxTemp, _dhwMinTemp, _dhwMaxTemp = 0;
static bool _isStupidMode, _editableOutdoorTemp, _editableIndoorTemp, _dhwPresent = false;
static bool _noRegulators, _editableOutdoorTemp, _editableIndoorTemp, _dhwPresent = false;
bool published = false;
bool isStupidMode = !settings.pid.enable && !settings.equitherm.enable;
bool noRegulators = !settings.opentherm.nativeHeatingControl && !settings.pid.enable && !settings.equitherm.enable;
byte heatingMinTemp = 0;
byte heatingMaxTemp = 0;
bool editableOutdoorTemp = settings.sensors.outdoor.type == SensorType::MANUAL;
bool editableIndoorTemp = settings.sensors.indoor.type == SensorType::MANUAL;
if (isStupidMode) {
if (noRegulators) {
heatingMinTemp = settings.heating.minTemp;
heatingMaxTemp = settings.heating.maxTemp;
} else if (settings.system.unitSystem == UnitSystem::METRIC) {
heatingMinTemp = 5;
heatingMaxTemp = 30;
} else if (settings.system.unitSystem == UnitSystem::IMPERIAL) {
heatingMinTemp = 41;
heatingMaxTemp = 86;
} else {
heatingMinTemp = convertTemp(THERMOSTAT_INDOOR_MIN_TEMP, UnitSystem::METRIC, settings.system.unitSystem);
heatingMaxTemp = convertTemp(THERMOSTAT_INDOOR_MAX_TEMP, UnitSystem::METRIC, settings.system.unitSystem);
}
if (force || _dhwPresent != settings.opentherm.dhwPresent) {
@@ -447,32 +431,17 @@ protected:
published = true;
}
if (force || _heatingMinTemp != heatingMinTemp || _heatingMaxTemp != heatingMaxTemp) {
if (settings.heating.target < heatingMinTemp || settings.heating.target > heatingMaxTemp) {
settings.heating.target = constrain(settings.heating.target, heatingMinTemp, heatingMaxTemp);
}
if (force || _noRegulators != noRegulators || _heatingMinTemp != heatingMinTemp || _heatingMaxTemp != heatingMaxTemp) {
_heatingMinTemp = heatingMinTemp;
_heatingMaxTemp = heatingMaxTemp;
_isStupidMode = isStupidMode;
_noRegulators = noRegulators;
this->haHelper->publishNumberHeatingTarget(settings.system.unitSystem, heatingMinTemp, heatingMaxTemp, false);
this->haHelper->publishClimateHeating(
settings.system.unitSystem,
heatingMinTemp,
heatingMaxTemp,
isStupidMode ? HaHelper::TEMP_SOURCE_HEATING : HaHelper::TEMP_SOURCE_INDOOR
);
published = true;
} else if (_isStupidMode != isStupidMode) {
_isStupidMode = isStupidMode;
this->haHelper->publishClimateHeating(
settings.system.unitSystem,
heatingMinTemp,
heatingMaxTemp,
isStupidMode ? HaHelper::TEMP_SOURCE_HEATING : HaHelper::TEMP_SOURCE_INDOOR
noRegulators ? HaHelper::TEMP_SOURCE_HEATING : HaHelper::TEMP_SOURCE_INDOOR
);
published = true;

140
src/OpenThermTask.h
View File

@@ -30,6 +30,8 @@ protected:
unsigned long dhwSetTempTime = 0;
unsigned long heatingSetTempTime = 0;
byte configuredRxLedGpio = GPIO_IS_NOT_CONFIGURED;
byte configuredFaultStateGpio = GPIO_IS_NOT_CONFIGURED;
bool faultState = false;
const char* getTaskName() {
@@ -101,7 +103,8 @@ protected:
}
void loop() {
static byte currentHeatingTemp, currentDhwTemp = 0;
static float currentHeatingTemp = 0.0f;
static float currentDhwTemp = 0.0f;
if (this->instanceInGpio != settings.opentherm.inGpio || this->instanceOutGpio != settings.opentherm.outGpio) {
this->setup();
@@ -115,6 +118,7 @@ protected:
return;
}
// RX LED GPIO setup
if (settings.opentherm.rxLedGpio != this->configuredRxLedGpio) {
if (this->configuredRxLedGpio != GPIO_IS_NOT_CONFIGURED) {
digitalWrite(this->configuredRxLedGpio, LOW);
@@ -130,6 +134,27 @@ protected:
}
}
// Fault state setup
if (settings.opentherm.faultStateGpio != this->configuredFaultStateGpio) {
if (this->configuredFaultStateGpio != GPIO_IS_NOT_CONFIGURED) {
digitalWrite(this->configuredFaultStateGpio, LOW);
}
if (GPIO_IS_VALID(settings.opentherm.faultStateGpio)) {
this->configuredFaultStateGpio = settings.opentherm.faultStateGpio;
this->faultState = false ^ settings.opentherm.invertFaultState ? HIGH : LOW;
pinMode(this->configuredFaultStateGpio, OUTPUT);
digitalWrite(
this->configuredFaultStateGpio,
this->faultState
);
} else if (this->configuredFaultStateGpio != GPIO_IS_NOT_CONFIGURED) {
this->configuredFaultStateGpio = GPIO_IS_NOT_CONFIGURED;
}
}
bool heatingEnabled = (vars.states.emergency || settings.heating.enable) && this->pump && this->isReady();
bool heatingCh2Enabled = settings.opentherm.heatingCh2Enabled;
if (settings.opentherm.heatingCh1ToCh2) {
@@ -143,7 +168,7 @@ protected:
heatingEnabled,
settings.opentherm.dhwPresent && settings.dhw.enable,
false,
false,
settings.opentherm.nativeHeatingControl,
heatingCh2Enabled,
settings.opentherm.summerWinterMode,
settings.opentherm.dhwBlocking
@@ -173,6 +198,16 @@ protected:
vars.states.fault = false;
vars.states.diagnostic = false;
// Force fault state = on
if (this->configuredFaultStateGpio != GPIO_IS_NOT_CONFIGURED) {
bool fState = true ^ settings.opentherm.invertFaultState ? HIGH : LOW;
if (fState != this->faultState) {
this->faultState = fState;
digitalWrite(this->configuredFaultStateGpio, this->faultState);
}
}
return;
}
@@ -198,6 +233,16 @@ protected:
vars.states.fault = CustomOpenTherm::isFault(response);
vars.states.diagnostic = CustomOpenTherm::isDiagnostic(response);
// Fault state
if (this->configuredFaultStateGpio != GPIO_IS_NOT_CONFIGURED) {
bool fState = vars.states.fault ^ settings.opentherm.invertFaultState ? HIGH : LOW;
if (fState != this->faultState) {
this->faultState = fState;
digitalWrite(this->configuredFaultStateGpio, this->faultState);
}
}
// These parameters will be updated every minute
if (millis() - this->prevUpdateNonEssentialVars > 60000) {
if (!heatingEnabled && settings.opentherm.modulationSyncWithHeating) {
@@ -285,6 +330,9 @@ protected:
// Get fault code (if necessary)
if (vars.states.fault) {
updateFaultCode();
} else if (vars.sensors.faultCode != 0) {
vars.sensors.faultCode = 0;
}
updatePressure();
@@ -351,18 +399,13 @@ protected:
// Update DHW temp
byte newDhwTemp = settings.dhw.target;
if (settings.opentherm.dhwPresent && settings.dhw.enable && (this->needSetDhwTemp() || newDhwTemp != currentDhwTemp)) {
if (newDhwTemp < settings.dhw.minTemp || newDhwTemp > settings.dhw.maxTemp) {
newDhwTemp = constrain(newDhwTemp, settings.dhw.minTemp, settings.dhw.maxTemp);
}
float convertedTemp = convertTemp(newDhwTemp, settings.system.unitSystem, settings.opentherm.unitSystem);
Log.sinfoln(FPSTR(L_OT_DHW), F("Set temp: %u (converted: %.2f)"), newDhwTemp, convertedTemp);
if (settings.opentherm.dhwPresent && settings.dhw.enable && (this->needSetDhwTemp() || fabs(settings.dhw.target - currentDhwTemp) > 0.0001f)) {
float convertedTemp = convertTemp(settings.dhw.target, settings.system.unitSystem, settings.opentherm.unitSystem);
Log.sinfoln(FPSTR(L_OT_DHW), F("Set temp: %.2f (converted: %.2f)"), settings.dhw.target, convertedTemp);
// Set DHW temp
if (this->instance->setDhwTemp(convertedTemp)) {
currentDhwTemp = newDhwTemp;
currentDhwTemp = settings.dhw.target;
this->dhwSetTempTime = millis();
} else {
@@ -372,30 +415,82 @@ protected:
// Set DHW temp to CH2
if (settings.opentherm.dhwToCh2) {
if (!this->instance->setHeatingCh2Temp(convertedTemp)) {
Log.swarningln(FPSTR(L_OT_DHW), F("Failed set ch2 temp"));
Log.swarningln(FPSTR(L_OT_DHW), F("Failed set CH2 temp"));
}
}
}
// Update heating temp
if (heatingEnabled && (this->needSetHeatingTemp() || fabs(vars.parameters.heatingSetpoint - currentHeatingTemp) > 0.0001)) {
float convertedTemp = convertTemp(vars.parameters.heatingSetpoint, settings.system.unitSystem, settings.opentherm.unitSystem);
Log.sinfoln(FPSTR(L_OT_HEATING), F("Set temp: %u (converted: %.2f)"), vars.parameters.heatingSetpoint, convertedTemp);
// Native heating control
if (settings.opentherm.nativeHeatingControl) {
// Set current indoor temp
float indoorTemp = 0.0f;
float convertedTemp = 0.0f;
// Set heating temp
if (this->instance->setHeatingCh1Temp(convertedTemp) || this->setMaxHeatingTemp(convertedTemp)) {
if (!vars.states.emergency || settings.sensors.indoor.type != SensorType::MANUAL) {
indoorTemp = vars.temperatures.indoor;
convertedTemp = convertTemp(indoorTemp, settings.system.unitSystem, settings.opentherm.unitSystem);
}
Log.sinfoln(FPSTR(L_OT_HEATING), F("Set current indoor temp: %.2f (converted: %.2f)"), indoorTemp, convertedTemp);
if (!this->instance->setRoomTemp(convertedTemp)) {
Log.swarningln(FPSTR(L_OT_HEATING), F("Failed set current indoor temp"));
}
// Set target indoor temp
if (this->needSetHeatingTemp() || fabs(vars.parameters.heatingSetpoint - currentHeatingTemp) > 0.0001f) {
convertedTemp = convertTemp(vars.parameters.heatingSetpoint, settings.system.unitSystem, settings.opentherm.unitSystem);
Log.sinfoln(FPSTR(L_OT_HEATING), F("Set target indoor temp: %.2f (converted: %.2f)"), vars.parameters.heatingSetpoint, convertedTemp);
if (this->instance->setRoomSetpoint(convertedTemp)) {
currentHeatingTemp = vars.parameters.heatingSetpoint;
this->heatingSetTempTime = millis();
} else {
Log.swarningln(FPSTR(L_OT_HEATING), F("Failed set temp"));
Log.swarningln(FPSTR(L_OT_HEATING), F("Failed set target indoor temp"));
}
// Set target temp to CH2
if (settings.opentherm.heatingCh1ToCh2) {
if (!this->instance->setRoomSetpointCh2(convertedTemp)) {
Log.swarningln(FPSTR(L_OT_HEATING), F("Failed set target indoor temp to CH2"));
}
}
}
// force enable pump
if (!this->pump) {
this->pump = true;
}
} else {
// Update heating temp
if (heatingEnabled && (this->needSetHeatingTemp() || fabs(vars.parameters.heatingSetpoint - currentHeatingTemp) > 0.0001f)) {
float convertedTemp = convertTemp(vars.parameters.heatingSetpoint, settings.system.unitSystem, settings.opentherm.unitSystem);
Log.sinfoln(FPSTR(L_OT_HEATING), F("Set temp: %.2f (converted: %.2f)"), vars.parameters.heatingSetpoint, convertedTemp);
// Set max heating temp
if (this->setMaxHeatingTemp(convertedTemp)) {
currentHeatingTemp = vars.parameters.heatingSetpoint;
this->heatingSetTempTime = millis();
} else {
Log.swarningln(FPSTR(L_OT_HEATING), F("Failed set max heating temp"));
}
// Set heating temp
if (this->instance->setHeatingCh1Temp(convertedTemp)) {
currentHeatingTemp = vars.parameters.heatingSetpoint;
this->heatingSetTempTime = millis();
} else {
Log.swarningln(FPSTR(L_OT_HEATING), F("Failed set CH1 temp"));
}
// Set heating temp to CH2
if (settings.opentherm.heatingCh1ToCh2) {
if (!this->instance->setHeatingCh2Temp(convertedTemp)) {
Log.swarningln(FPSTR(L_OT_HEATING), F("Failed set ch2 temp"));
Log.swarningln(FPSTR(L_OT_HEATING), F("Failed set CH2 temp"));
}
}
}
@@ -405,10 +500,10 @@ protected:
// Only if enabled PID or/and Equitherm
if (settings.heating.hysteresis > 0 && (!vars.states.emergency || settings.emergency.usePid) && (settings.equitherm.enable || settings.pid.enable)) {
float halfHyst = settings.heating.hysteresis / 2;
if (this->pump && vars.temperatures.indoor - settings.heating.target + 0.0001 >= halfHyst) {
if (this->pump && vars.temperatures.indoor - settings.heating.target + 0.0001f >= halfHyst) {
this->pump = false;
} else if (!this->pump && vars.temperatures.indoor - settings.heating.target - 0.0001 <= -(halfHyst)) {
} else if (!this->pump && vars.temperatures.indoor - settings.heating.target - 0.0001f <= -(halfHyst)) {
this->pump = true;
}
@@ -416,6 +511,7 @@ protected:
this->pump = true;
}
}
}
void initialize() {
// Not all boilers support these, only try once when the boiler becomes connected

41
src/PortalTask.h
View File

@@ -344,7 +344,11 @@ protected:
auto apCount = WiFi.scanComplete();
if (apCount <= 0) {
if (apCount != WIFI_SCAN_RUNNING) {
#ifdef ARDUINO_ARCH_ESP8266
WiFi.scanNetworks(true, true);
#else
WiFi.scanNetworks(true, true, true);
#endif
}
this->webServer->send(404);
@@ -423,7 +427,9 @@ protected:
if (changed) {
doc.clear();
doc.shrinkToFit();
fsSettings.update();
tMqtt->resetPublishedSettingsTime();
}
});
@@ -473,6 +479,13 @@ protected:
doc.shrinkToFit();
this->bufferedWebServer->send(changed ? 201 : 200, "application/json", doc);
if (changed) {
doc.clear();
doc.shrinkToFit();
tMqtt->resetPublishedVarsTime();
}
});
this->webServer->on("/api/info", HTTP_GET, [this]() {
@@ -499,6 +512,34 @@ protected:
doc["system"]["maxFreeBlockHeap"] = getMaxFreeBlockHeap();
doc["system"]["minMaxFreeBlockHeap"] = getMaxFreeBlockHeap(true);
doc["system"]["resetReason"] = getResetReason();
#ifdef ARDUINO_ARCH_ESP8266
doc["system"]["chipModel"] = esp_is_8285() ? "ESP8285" : "ESP8266";
doc["system"]["chipRevision"] = 0;
doc["system"]["chipCores"] = 1;
doc["system"]["cpuFreq"] = ESP.getCpuFreqMHz();
doc["system"]["coreVersion"] = ESP.getCoreVersion();
doc["system"]["flashSize"] = ESP.getFlashChipSize();
doc["system"]["flashRealSize"] = ESP.getFlashChipRealSize();
#elif ARDUINO_ARCH_ESP32
doc["system"]["chipModel"] = ESP.getChipModel();
doc["system"]["chipRevision"] = ESP.getChipRevision();
doc["system"]["chipCores"] = ESP.getChipCores();
doc["system"]["cpuFreq"] = ESP.getCpuFreqMHz();
doc["system"]["coreVersion"] = ESP.getSdkVersion();
doc["system"]["flashSize"] = ESP.getFlashChipSize();
doc["system"]["flashRealSize"] = doc["system"]["flashSize"];
#else
doc["system"]["chipModel"] = 0;
doc["system"]["chipRevision"] = 0;
doc["system"]["chipCores"] = 0;
doc["system"]["cpuFreq"] = 0;
doc["system"]["coreVersion"] = 0;
doc["system"]["flashSize"] = 0;
doc["system"]["flashRealSize"] = 0;
#endif
doc.shrinkToFit();
this->bufferedWebServer->send(200, "application/json", doc);

209
src/RegulatorTask.h
View File

@@ -1,10 +1,8 @@
#include <Equitherm.h>
#include <GyverPID.h>
#include <PIDtuner.h>
Equitherm etRegulator;
GyverPID pidRegulator(0, 0, 0);
PIDtuner pidTuner;
class RegulatorTask : public LeanTask {
@@ -12,9 +10,6 @@ public:
RegulatorTask(bool _enabled = false, unsigned long _interval = 0) : LeanTask(_enabled, _interval) {}
protected:
bool tunerInit = false;
byte tunerState = 0;
byte tunerRegulator = 0;
float prevHeatingTarget = 0;
float prevEtResult = 0;
float prevPidResult = 0;
@@ -32,7 +27,7 @@ protected:
}
void loop() {
byte newTemp = vars.parameters.heatingSetpoint;
float newTemp = vars.parameters.heatingSetpoint;
if (vars.states.emergency) {
if (settings.heating.turbo) {
@@ -41,74 +36,60 @@ protected:
Log.sinfoln(FPSTR(L_REGULATOR), F("Turbo mode auto disabled"));
}
newTemp = getEmergencyModeTemp();
newTemp = this->getEmergencyModeTemp();
} else {
if (vars.tuning.enable || tunerInit) {
if (settings.heating.turbo) {
settings.heating.turbo = false;
Log.sinfoln(FPSTR(L_REGULATOR), F("Turbo mode auto disabled"));
}
newTemp = getTuningModeTemp();
if (newTemp == 0) {
vars.tuning.enable = false;
}
}
if (!vars.tuning.enable) {
if (settings.heating.turbo && (fabs(settings.heating.target - vars.temperatures.indoor) < 1 || !settings.heating.enable || (settings.equitherm.enable && settings.pid.enable))) {
settings.heating.turbo = false;
Log.sinfoln(FPSTR(L_REGULATOR), F("Turbo mode auto disabled"));
}
newTemp = getNormalModeTemp();
}
newTemp = this->getNormalModeTemp();
}
// Limits
if (newTemp < settings.heating.minTemp || newTemp > settings.heating.maxTemp) {
newTemp = constrain(newTemp, settings.heating.minTemp, settings.heating.maxTemp);
}
newTemp = constrain(
newTemp,
!settings.opentherm.nativeHeatingControl ? settings.heating.minTemp : THERMOSTAT_INDOOR_MIN_TEMP,
!settings.opentherm.nativeHeatingControl ? settings.heating.maxTemp : THERMOSTAT_INDOOR_MAX_TEMP
);
if (abs(vars.parameters.heatingSetpoint - newTemp) + 0.0001 >= 1) {
if (fabs(vars.parameters.heatingSetpoint - newTemp) > 0.4999f) {
vars.parameters.heatingSetpoint = newTemp;
}
}
byte getEmergencyModeTemp() {
float getEmergencyModeTemp() {
float newTemp = 0;
// if use equitherm
if (settings.emergency.useEquitherm && settings.sensors.outdoor.type != SensorType::MANUAL) {
if (settings.emergency.useEquitherm) {
float etResult = getEquithermTemp(settings.heating.minTemp, settings.heating.maxTemp);
if (fabs(prevEtResult - etResult) + 0.0001 >= 0.5) {
if (fabs(prevEtResult - etResult) > 0.4999f) {
prevEtResult = etResult;
newTemp += etResult;
Log.sinfoln(FPSTR(L_REGULATOR_EQUITHERM), F("New emergency result: %hhu (%.2f)"), (uint8_t) round(etResult), etResult);
Log.sinfoln(FPSTR(L_REGULATOR_EQUITHERM), F("New emergency result: %.2f"), etResult);
} else {
newTemp += prevEtResult;
}
} else if(settings.emergency.usePid && settings.sensors.indoor.type != SensorType::MANUAL) {
} else if(settings.emergency.usePid) {
if (vars.parameters.heatingEnabled) {
float pidResult = getPidTemp(
settings.heating.minTemp,
settings.heating.maxTemp
);
if (fabs(prevPidResult - pidResult) + 0.0001 >= 0.5) {
if (fabs(prevPidResult - pidResult) > 0.4999f) {
prevPidResult = pidResult;
newTemp += pidResult;
Log.sinfoln(FPSTR(L_REGULATOR_PID), F("New emergency result: %hhu (%.2f)"), (uint8_t) round(pidResult), pidResult);
Log.sinfoln(FPSTR(L_REGULATOR_PID), F("New emergency result: %.2f"), pidResult);
} else {
newTemp += prevPidResult;
@@ -123,17 +104,17 @@ protected:
newTemp = settings.emergency.target;
}
return round(newTemp);
return newTemp;
}
byte getNormalModeTemp() {
float getNormalModeTemp() {
float newTemp = 0;
if (fabs(prevHeatingTarget - settings.heating.target) > 0.0001) {
if (fabs(prevHeatingTarget - settings.heating.target) > 0.0001f) {
prevHeatingTarget = settings.heating.target;
Log.sinfoln(FPSTR(L_REGULATOR), F("New target: %.2f"), settings.heating.target);
if (settings.equitherm.enable && settings.pid.enable) {
if (/*settings.equitherm.enable && */settings.pid.enable) {
pidRegulator.integral = 0;
Log.sinfoln(FPSTR(L_REGULATOR_PID), F("Integral sum has been reset"));
}
@@ -143,11 +124,11 @@ protected:
if (settings.equitherm.enable) {
float etResult = getEquithermTemp(settings.heating.minTemp, settings.heating.maxTemp);
if (fabs(prevEtResult - etResult) + 0.0001 >= 0.5) {
if (fabs(prevEtResult - etResult) > 0.4999f) {
prevEtResult = etResult;
newTemp += etResult;
Log.sinfoln(FPSTR(L_REGULATOR_EQUITHERM), F("New result: %hhu (%.2f)"), (uint8_t) round(etResult), etResult);
Log.sinfoln(FPSTR(L_REGULATOR_EQUITHERM), F("New result: %.2f"), etResult);
} else {
newTemp += prevEtResult;
@@ -162,11 +143,12 @@ protected:
settings.pid.maxTemp
);
if (fabs(prevPidResult - pidResult) + 0.0001 >= 0.5) {
if (fabs(prevPidResult - pidResult) > 0.4999f) {
prevPidResult = pidResult;
newTemp += pidResult;
Log.sinfoln(FPSTR(L_REGULATOR_PID), F("New result: %hhd (%.2f)"), (int8_t) round(pidResult), pidResult);
Log.sinfoln(FPSTR(L_REGULATOR_PID), F("New result: %.2f"), pidResult);
Log.straceln(FPSTR(L_REGULATOR_PID), F("Integral: %.2f"), pidRegulator.integral);
} else {
newTemp += prevPidResult;
@@ -174,6 +156,10 @@ protected:
} else {
newTemp += prevPidResult;
}
} else if (fabs(pidRegulator.integral) > 0.0001f) {
pidRegulator.integral = 0;
Log.sinfoln(FPSTR(L_REGULATOR_PID), F("Integral sum has been reset"));
}
// default temp, manual mode
@@ -181,97 +167,9 @@ protected:
newTemp = settings.heating.target;
}
newTemp = round(newTemp);
return newTemp;
}
byte getTuningModeTemp() {
if (tunerInit && (!vars.tuning.enable || vars.tuning.regulator != tunerRegulator)) {
if (tunerRegulator == 0) {
pidTuner.reset();
}
tunerInit = false;
tunerRegulator = 0;
tunerState = 0;
Log.sinfoln("REGULATOR.TUNING", F("Stopped"));
}
if (!vars.tuning.enable) {
return 0;
}
if (vars.tuning.regulator == 0) {
// @TODO дописать
Log.sinfoln("REGULATOR.TUNING.EQUITHERM", F("Not implemented"));
return 0;
} else if (vars.tuning.regulator == 1) {
// PID tuner
float defaultTemp = settings.equitherm.enable
? getEquithermTemp(settings.heating.minTemp, settings.heating.maxTemp)
: settings.heating.target;
if (tunerInit && pidTuner.getState() == 3) {
Log.sinfoln("REGULATOR.TUNING.PID", F("Finished"));
for (Stream* stream : Log.getStreams()) {
pidTuner.debugText(stream);
}
pidTuner.reset();
tunerInit = false;
tunerRegulator = 0;
tunerState = 0;
if (pidTuner.getAccuracy() < 90) {
Log.swarningln("REGULATOR.TUNING.PID", F("Bad result, try again..."));
} else {
settings.pid.p_factor = pidTuner.getPID_p();
settings.pid.i_factor = pidTuner.getPID_i();
settings.pid.d_factor = pidTuner.getPID_d();
return 0;
}
}
if (!tunerInit) {
Log.sinfoln("REGULATOR.TUNING.PID", F("Start..."));
float step;
if (vars.temperatures.indoor - vars.temperatures.outdoor > 10) {
step = ceil(vars.parameters.heatingSetpoint / vars.temperatures.indoor * 2);
} else {
step = 5.0f;
}
float startTemp = step;
Log.sinfoln("REGULATOR.TUNING.PID", F("Started. Start value: %f, step: %f"), startTemp, step);
pidTuner.setParameters(NORMAL, startTemp, step, 20 * 60 * 1000, 0.15, 60 * 1000, 10000);
tunerInit = true;
tunerRegulator = 1;
}
pidTuner.setInput(vars.temperatures.indoor);
pidTuner.compute();
if (tunerState > 0 && pidTuner.getState() != tunerState) {
Log.sinfoln("REGULATOR.TUNING.PID", F("Log:"));
for (Stream* stream : Log.getStreams()) {
pidTuner.debugText(stream);
}
tunerState = pidTuner.getState();
}
return round(defaultTemp + pidTuner.getOutput());
} else {
return 0;
}
}
/**
* @brief Get the Equitherm Temp
* Calculations in degrees C, conversion occurs when using F
@@ -294,8 +192,15 @@ protected:
}
if (vars.states.emergency) {
if (settings.sensors.indoor.type == SensorType::MANUAL) {
etRegulator.Kt = 0;
etRegulator.indoorTemp = 0;
} else {
etRegulator.Kt = settings.equitherm.t_factor;
etRegulator.indoorTemp = indoorTemp;
}
etRegulator.outdoorTemp = outdoorTemp;
} else if (settings.pid.enable) {
@@ -327,9 +232,23 @@ protected:
}
float getPidTemp(int minTemp, int maxTemp) {
if (fabs(pidRegulator.Kp - settings.pid.p_factor) >= 0.0001f) {
pidRegulator.Kp = settings.pid.p_factor;
pidRegulator.integral = 0;
Log.sinfoln(FPSTR(L_REGULATOR_PID), F("Integral sum has been reset"));
}
if (fabs(pidRegulator.Ki - settings.pid.i_factor) >= 0.0001f) {
pidRegulator.Ki = settings.pid.i_factor;
pidRegulator.integral = 0;
Log.sinfoln(FPSTR(L_REGULATOR_PID), F("Integral sum has been reset"));
}
if (fabs(pidRegulator.Kd - settings.pid.d_factor) >= 0.0001f) {
pidRegulator.Kd = settings.pid.d_factor;
pidRegulator.integral = 0;
Log.sinfoln(FPSTR(L_REGULATOR_PID), F("Integral sum has been reset"));
}
pidRegulator.setLimits(minTemp, maxTemp);
pidRegulator.setDt(settings.pid.dt * 1000u);
@@ -338,32 +257,4 @@ protected:
return pidRegulator.getResultTimer();
}
float tuneEquithermN(float ratio, float currentTemp, float setTemp, unsigned int dirtyInterval = 60, unsigned int accurateInterval = 1800, float accurateStep = 0.01, float accurateStepAfter = 1) {
static uint32_t _prevIteration = millis();
if (abs(currentTemp - setTemp) < accurateStepAfter) {
if (millis() - _prevIteration < (accurateInterval * 1000)) {
return ratio;
}
if (currentTemp - setTemp > 0.1f) {
ratio -= accurateStep;
} else if (currentTemp - setTemp < -0.1f) {
ratio += accurateStep;
}
} else {
if (millis() - _prevIteration < (dirtyInterval * 1000)) {
return ratio;
}
ratio = ratio * (setTemp / currentTemp);
}
_prevIteration = millis();
return ratio;
}
};

12
src/SensorsTask.h
View File

@@ -65,7 +65,7 @@ protected:
bool indoorTempUpdated = false;
bool outdoorTempUpdated = false;
if (settings.sensors.outdoor.type == SensorType::DS18B20 && GPIO_IS_VALID(settings.sensors.indoor.gpio)) {
if (settings.sensors.outdoor.type == SensorType::DS18B20 && GPIO_IS_VALID(settings.sensors.outdoor.gpio)) {
outdoorTemperatureSensor();
outdoorTempUpdated = true;
}
@@ -90,7 +90,7 @@ protected:
newTemp += c2f(this->filteredOutdoorTemp);
}
if (fabs(vars.temperatures.outdoor - newTemp) > 0.099) {
if (fabs(vars.temperatures.outdoor - newTemp) > 0.099f) {
vars.temperatures.outdoor = newTemp;
Log.sinfoln(FPSTR(L_SENSORS_OUTDOOR), F("New temp: %f"), vars.temperatures.outdoor);
}
@@ -105,7 +105,7 @@ protected:
newTemp += c2f(this->filteredIndoorTemp);
}
if (fabs(vars.temperatures.indoor - newTemp) > 0.099) {
if (fabs(vars.temperatures.indoor - newTemp) > 0.099f) {
vars.temperatures.indoor = newTemp;
Log.sinfoln(FPSTR(L_SENSORS_INDOOR), F("New temp: %f"), vars.temperatures.indoor);
}
@@ -163,7 +163,7 @@ protected:
return;
}
float rawTemp = ((pData[0] | (pData[1] << 8)) * 0.01);
float rawTemp = ((pData[0] | (pData[1] << 8)) * 0.01f);
Log.straceln(FPSTR(L_SENSORS_INDOOR), F("Raw temp: %f"), rawTemp);
if (this->emptyIndoorTemp) {
@@ -235,7 +235,7 @@ protected:
return;
}
Log.sinfoln(FPSTR(L_SENSORS_OUTDOOR), F("Starting on gpio %hhu..."), settings.sensors.outdoor.gpio);
Log.sinfoln(FPSTR(L_SENSORS_OUTDOOR), F("Starting on GPIO %hhu..."), settings.sensors.outdoor.gpio);
this->oneWireOutdoorSensor->begin(settings.sensors.outdoor.gpio);
this->oneWireOutdoorSensor->reset();
@@ -307,7 +307,7 @@ protected:
return;
}
Log.sinfoln(FPSTR(L_SENSORS_INDOOR), F("Starting on gpio %hhu..."), settings.sensors.indoor.gpio);
Log.sinfoln(FPSTR(L_SENSORS_INDOOR), F("Starting on GPIO %hhu..."), settings.sensors.indoor.gpio);
this->oneWireIndoorSensor->begin(settings.sensors.indoor.gpio);
this->oneWireIndoorSensor->reset();

23
src/Settings.h
View File

@@ -51,6 +51,8 @@ struct Settings {
byte inGpio = DEFAULT_OT_IN_GPIO;
byte outGpio = DEFAULT_OT_OUT_GPIO;
byte rxLedGpio = DEFAULT_OT_RX_LED_GPIO;
byte faultStateGpio = DEFAULT_OT_FAULT_STATE_GPIO;
byte invertFaultState = false;
unsigned int memberIdCode = 0;
bool dhwPresent = true;
bool summerWinterMode = false;
@@ -60,6 +62,7 @@ struct Settings {
bool dhwBlocking = false;
bool modulationSyncWithHeating = false;
bool getMinMaxTemp = true;
bool nativeHeatingControl = false;
} opentherm;
struct {
@@ -70,11 +73,12 @@ struct Settings {
char password[33] = DEFAULT_MQTT_PASSWORD;
char prefix[33] = DEFAULT_MQTT_PREFIX;
unsigned short interval = 5;
bool homeAssistantDiscovery = true;
} mqtt;
struct {
bool enable = true;
float target = 40.0f;
float target = DEFAULT_HEATING_TARGET_TEMP;
unsigned short tresholdTime = 120;
bool useEquitherm = false;
bool usePid = false;
@@ -85,7 +89,7 @@ struct Settings {
struct {
bool enable = true;
bool turbo = false;
float target = 40.0f;
float target = DEFAULT_HEATING_TARGET_TEMP;
float hysteresis = 0.5f;
byte minTemp = DEFAULT_HEATING_MIN_TEMP;
byte maxTemp = DEFAULT_HEATING_MAX_TEMP;
@@ -94,16 +98,16 @@ struct Settings {
struct {
bool enable = true;
byte target = 40;
float target = DEFAULT_DHW_TARGET_TEMP;
byte minTemp = DEFAULT_DHW_MIN_TEMP;
byte maxTemp = DEFAULT_DHW_MAX_TEMP;
} dhw;
struct {
bool enable = false;
float p_factor = 50;
float i_factor = 0.006f;
float d_factor = 10000;
float p_factor = 2;
float i_factor = 0.0055f;
float d_factor = 0;
unsigned short dt = 180;
byte minTemp = 0;
byte maxTemp = DEFAULT_HEATING_MAX_TEMP;
@@ -143,11 +147,6 @@ struct Settings {
} settings;
struct Variables {
struct {
bool enable = false;
byte regulator = 0;
} tuning;
struct {
bool otStatus = false;
bool emergency = false;
@@ -181,7 +180,7 @@ struct Variables {
bool heatingEnabled = false;
byte heatingMinTemp = DEFAULT_HEATING_MIN_TEMP;
byte heatingMaxTemp = DEFAULT_HEATING_MAX_TEMP;
byte heatingSetpoint = 0;
float heatingSetpoint = 0;
unsigned long extPumpLastEnableTime = 0;
byte dhwMinTemp = DEFAULT_DHW_MIN_TEMP;
byte dhwMaxTemp = DEFAULT_DHW_MAX_TEMP;

15
src/defines.h
View File

@@ -1,5 +1,5 @@
#define PROJECT_NAME "OpenTherm Gateway"
#define PROJECT_VERSION "1.4.0-rc.22"
#define PROJECT_VERSION "1.4.0"
#define PROJECT_REPO "https://github.com/Laxilef/OTGateway"
#define MQTT_RECONNECT_INTERVAL 15000
@@ -9,13 +9,20 @@
#define CONFIG_URL "http://%s/"
#define SETTINGS_VALID_VALUE "stvalid" // only 8 chars!
#define GPIO_IS_NOT_CONFIGURED 0xff
#define DEFAULT_HEATING_TARGET_TEMP 40
#define DEFAULT_HEATING_MIN_TEMP 20
#define DEFAULT_HEATING_MAX_TEMP 90
#define DEFAULT_DHW_TARGET_TEMP 40
#define DEFAULT_DHW_MIN_TEMP 30
#define DEFAULT_DHW_MAX_TEMP 60
#define THERMOSTAT_INDOOR_DEFAULT_TEMP 20
#define THERMOSTAT_INDOOR_MIN_TEMP 5
#define THERMOSTAT_INDOOR_MAX_TEMP 30
#ifndef USE_SERIAL
#define USE_SERIAL true
#endif
@@ -96,6 +103,10 @@
#define DEFAULT_OT_RX_LED_GPIO GPIO_IS_NOT_CONFIGURED
#endif
#ifndef DEFAULT_OT_FAULT_STATE_GPIO
#define DEFAULT_OT_FAULT_STATE_GPIO GPIO_IS_NOT_CONFIGURED
#endif
#ifndef DEFAULT_SENSOR_OUTDOOR_GPIO
#define DEFAULT_SENSOR_OUTDOOR_GPIO GPIO_IS_NOT_CONFIGURED
#endif

11
src/main.cpp
View File

@@ -59,7 +59,7 @@ void setup() {
return tm{sec, min, hour};
});
Serial.begin(settings.system.serial.baudrate);
Serial.begin(115200);
Log.addStream(&Serial);
Log.print("\n\n\r");
@@ -110,8 +110,15 @@ void setup() {
// logs
if (!settings.system.serial.enable) {
Log.clearStreams();
Serial.end();
Log.clearStreams();
} else if (settings.system.serial.baudrate != 115200) {
Serial.end();
Log.clearStreams();
Serial.begin(settings.system.serial.baudrate);
Log.addStream(&Serial);
}
if (settings.system.telnet.enable) {

520
src/utils.h
View File

File diff suppressed because it is too large Load Diff

8
src_data/dashboard.html
View File

@@ -250,7 +250,7 @@
return;
}
newSettings.dhw.target -= 1;
newSettings.dhw.target -= 1.0;
modifiedTime = Date.now();
if (newSettings.dhw.target < prevSettings.dhw.minTemp) {
@@ -265,7 +265,7 @@
return;
}
newSettings.dhw.target += 1;
newSettings.dhw.target += 1.0;
modifiedTime = Date.now();
if (newSettings.dhw.target > prevSettings.dhw.maxTemp) {
@@ -287,7 +287,7 @@
document.querySelector('#thermostat-dhw-enabled').addEventListener('change', (event) => {
modifiedTime = Date.now();
newSettings.heating.dhw = event.currentTarget.checked;
newSettings.dhw.enable = event.currentTarget.checked;
});
setTimeout(async function onLoadPage() {
@@ -326,7 +326,7 @@
}
const result = await response.json();
noRegulators = !result.equitherm.enable && !result.pid.enable;
noRegulators = !result.opentherm.nativeHeatingControl && !result.equitherm.enable && !result.pid.enable;
prevSettings = result;
newSettings.heating.enable = result.heating.enable;
newSettings.heating.turbo = result.heating.turbo;

15
src_data/index.html
View File

@@ -87,7 +87,7 @@
<tbody>
<tr>
<th scope="row">Version:</th>
<td><b id="version"></b></td>
<td><b id="version"></b>, core/sdk: <b id="core-version"></b></td>
</tr>
<tr>
<th scope="row">Build date:</th>
@@ -101,6 +101,10 @@
<th scope="row">Free memory:</th>
<td><b id="free-heap"></b> of <b id="total-heap"></b> bytes (min: <b id="min-free-heap"></b> bytes)<br />max free block: <b id="max-free-block-heap"></b> bytes (min: <b id="min-max-free-block-heap"></b> bytes)</td>
</tr>
<tr>
<th scope="row">Board:</th>
<td>Chip <b id="chip-model"></b> (rev. <span id="chip-revision"></span>)<br />Cores: <b id="chip-cores"></b>, frequency: <b id="cpu-freq"></b> mHz<br />Flash size: <b id="flash-size"></b> MB (real: <b id="flash-real-size"></b> MB)</td>
</tr>
<tr>
<th scope="row">Last reset reason:</th>
<td><b id="reset-reason"></b></td>
@@ -164,6 +168,15 @@
setValue('#max-free-block-heap', result.system.maxFreeBlockHeap);
setValue('#min-max-free-block-heap', result.system.minMaxFreeBlockHeap);
setValue('#reset-reason', result.system.resetReason);
setValue('#chip-model', result.system.chipModel);
setValue('#chip-revision', result.system.chipRevision);
setValue('#chip-cores', result.system.chipCores);
setValue('#cpu-freq', result.system.cpuFreq);
setValue('#core-version', result.system.coreVersion);
setValue('#flash-size', result.system.flashSize / 1024 / 1024);
setValue('#flash-real-size', result.system.flashRealSize / 1024 / 1024);
setBusy('#system-busy', '#system-table', false);
} catch (error) {

4
src_data/network.html
View File

@@ -76,7 +76,7 @@
</hgroup>
<form action="/api/network/scan" id="network-scan">
<figure style="max-height: 25em;">
<div style="max-height: 25rem;" class="overflow-auto">
<table id="networks" role="grid">
<thead>
<tr>
@@ -87,7 +87,7 @@
</thead>
<tbody></tbody>
</table>
</figure>
</div>
<button type="submit">Refresh</button>
</form>

62
src_data/settings.html
View File

@@ -67,12 +67,12 @@
<legend>Unit system</legend>
<label>
<input type="radio" id="system-unit-system" name="system[unitSystem]" value="0" />
<input type="radio" class="system-unit-system" name="system[unitSystem]" value="0" />
Metric (celsius, liters, bar)
</label>
<label>
<input type="radio" id="system-unit-system" name="system[unitSystem]" value="1" />
<input type="radio" class="system-unit-system" name="system[unitSystem]" value="1" />
Imperial (fahrenheit, gallons, psi)
</label>
</fieldset>
@@ -116,9 +116,7 @@
<small>Default: 23</small>
</label>
</div>
</fieldset>
<fieldset>
<mark>After changing this settings, the ESP must be restarted for the changes to take effect.</mark>
</fieldset>
@@ -317,7 +315,7 @@
<label for="pid-i-factor">
I factor
<input type="number" inputmode="numeric" id="pid-i-factor" name="pid[i_factor]" min="0" max="100" step="0.001" required>
<input type="number" inputmode="numeric" id="pid-i-factor" name="pid[i_factor]" min="0" max="100" step="0.0001" required>
</label>
<label for="pid-d-factor">
@@ -361,12 +359,12 @@
<legend>Unit system</legend>
<label>
<input type="radio" id="opentherm-unit-system" name="opentherm[unitSystem]" value="0" />
<input type="radio" class="opentherm-unit-system" name="opentherm[unitSystem]" value="0" />
Metric (celsius)
</label>
<label>
<input type="radio" id="opentherm-unit-system" name="opentherm[unitSystem]" value="1" />
<input type="radio" class="opentherm-unit-system" name="opentherm[unitSystem]" value="1" />
Imperial (fahrenheit)
</label>
</fieldset>
@@ -437,6 +435,27 @@
<input type="checkbox" id="opentherm-get-min-max-temp" name="opentherm[getMinMaxTemp]" value="true">
Get min/max temp from boiler
</label>
<hr />
<fieldset>
<label for="opentherm-fault-state-gpio">
Fault state GPIO
<input type="number" inputmode="numeric" id="opentherm-fault-state-gpio" name="opentherm[faultStateGpio]" min="0" max="254" step="1">
<small>Can be useful to switch on another boiler <u>via relay</u>. Blank - not use.</small>
</label>
<label for="opentherm-invert-fault-state">
<input type="checkbox" id="opentherm-invert-fault-state" name="opentherm[invertFaultState]" value="true">
Invert fault state
</label>
</fieldset>
<hr />
<label for="opentherm-native-heating-control">
<input type="checkbox" id="opentherm-native-heating-control" name="opentherm[nativeHeatingControl]" value="true">
Native heating control (boiler)<br />
<small>Works <u>ONLY</u> if the boiler requires the desired room temperature and regulates the temperature of the coolant itself. Not compatible with PID and Equitherm regulators and hysteresis in firmware.</small>
</label>
</fieldset>
<button type="submit">Save</button>
@@ -456,6 +475,11 @@
<input type="checkbox" id="mqtt-enable" name="mqtt[enable]" value="true">
Enable
</label>
<label for="mqtt-ha-discovery">
<input type="checkbox" id="mqtt-ha-discovery" name="mqtt[homeAssistantDiscovery]" value="true">
Home Assistant Discovery
</label>
</fieldset>
<div class="grid">
@@ -510,17 +534,17 @@
<legend>Source type</legend>
<label>
<input type="radio" id="outdoor-sensor-type" name="sensors[outdoor][type]" value="0" />
<input type="radio" class="outdoor-sensor-type" name="sensors[outdoor][type]" value="0" />
From boiler via OpenTherm
</label>
<label>
<input type="radio" id="outdoor-sensor-type" name="sensors[outdoor][type]" value="1" />
<input type="radio" class="outdoor-sensor-type" name="sensors[outdoor][type]" value="1" />
Manual via MQTT/API
</label>
<label>
<input type="radio" id="outdoor-sensor-type" name="sensors[outdoor][type]" value="2" />
<input type="radio" class="outdoor-sensor-type" name="sensors[outdoor][type]" value="2" />
External (DS18B20)
</label>
</fieldset>
@@ -551,17 +575,17 @@
<legend>Source type</legend>
<label>
<input type="radio" id="indoor-sensor-type" name="sensors[indoor][type]" value="1" />
<input type="radio" class="indoor-sensor-type" name="sensors[indoor][type]" value="1" />
Manual via MQTT/API
</label>
<label>
<input type="radio" id="indoor-sensor-type" name="sensors[indoor][type]" value="2" />
<input type="radio" class="indoor-sensor-type" name="sensors[indoor][type]" value="2" />
External (DS18B20)
</label>
<label>
<input type="radio" id="indoor-sensor-type" name="sensors[indoor][type]" value="3" />
<input type="radio" class="indoor-sensor-type" name="sensors[indoor][type]" value="3" />
BLE device <i>(ONLY for some ESP32 which support BLE)</i>
</label>
</fieldset>
@@ -655,7 +679,7 @@
setInputValue('#system-serial-baudrate', data.system.serial.baudrate);
setCheckboxValue('#system-telnet-enable', data.system.telnet.enable);
setInputValue('#system-telnet-port', data.system.telnet.port);
setRadioValue('#system-unit-system', data.system.unitSystem);
setRadioValue('.system-unit-system', data.system.unitSystem);
setInputValue('#system-status-led-gpio', data.system.statusLedGpio < 255 ? data.system.statusLedGpio : '');
setBusy('#system-settings-busy', '#system-settings', false);
@@ -666,10 +690,12 @@
setBusy('#portal-settings-busy', '#portal-settings', false);
// Opentherm
setRadioValue('#opentherm-unit-system', data.opentherm.unitSystem);
setRadioValue('.opentherm-unit-system', data.opentherm.unitSystem);
setInputValue('#opentherm-in-gpio', data.opentherm.inGpio < 255 ? data.opentherm.inGpio : '');
setInputValue('#opentherm-out-gpio', data.opentherm.outGpio < 255 ? data.opentherm.outGpio : '');
setInputValue('#opentherm-rx-led-gpio', data.opentherm.rxLedGpio < 255 ? data.opentherm.rxLedGpio : '');
setInputValue('#opentherm-fault-state-gpio', data.opentherm.faultStateGpio < 255 ? data.opentherm.faultStateGpio : '');
setCheckboxValue('#opentherm-invert-fault-state', data.opentherm.invertFaultState);
setInputValue('#opentherm-member-id-code', data.opentherm.memberIdCode);
setCheckboxValue('#opentherm-dhw-present', data.opentherm.dhwPresent);
setCheckboxValue('#opentherm-sw-mode', data.opentherm.summerWinterMode);
@@ -679,10 +705,12 @@
setCheckboxValue('#opentherm-dhw-blocking', data.opentherm.dhwBlocking);
setCheckboxValue('#opentherm-sync-modulation-with-heating', data.opentherm.modulationSyncWithHeating);
setCheckboxValue('#opentherm-get-min-max-temp', data.opentherm.getMinMaxTemp);
setCheckboxValue('#opentherm-native-heating-control', data.opentherm.nativeHeatingControl);
setBusy('#opentherm-settings-busy', '#opentherm-settings', false);
// MQTT
setCheckboxValue('#mqtt-enable', data.mqtt.enable);
setCheckboxValue('#mqtt-ha-discovery', data.mqtt.homeAssistantDiscovery);
setInputValue('#mqtt-server', data.mqtt.server);
setInputValue('#mqtt-port', data.mqtt.port);
setInputValue('#mqtt-user', data.mqtt.user);
@@ -692,13 +720,13 @@
setBusy('#mqtt-settings-busy', '#mqtt-settings', false);
// Outdoor sensor
setRadioValue('#outdoor-sensor-type', data.sensors.outdoor.type);
setRadioValue('.outdoor-sensor-type', data.sensors.outdoor.type);
setInputValue('#outdoor-sensor-gpio', data.sensors.outdoor.gpio < 255 ? data.sensors.outdoor.gpio : '');
setInputValue('#outdoor-sensor-offset', data.sensors.outdoor.offset);
setBusy('#outdoor-sensor-settings-busy', '#outdoor-sensor-settings', false);
// Indoor sensor
setRadioValue('#indoor-sensor-type', data.sensors.indoor.type);
setRadioValue('.indoor-sensor-type', data.sensors.indoor.type);
setInputValue('#indoor-sensor-gpio', data.sensors.indoor.gpio < 255 ? data.sensors.indoor.gpio : '');
setInputValue('#indoor-sensor-offset', data.sensors.indoor.offset);
setInputValue('#indoor-sensor-ble-addresss', data.sensors.indoor.bleAddresss);