Merge 06c2ddcf96 into 8b50ed48c1

Merge branch 'master' into new-equitherm
2025-12-25 01:23:35 +05:00 · 2025-05-20 22:22:18 +00:00 · 2025-05-21 01:20:55 +03:00 · 2025-05-19 23:45:13 +03:00 · 2025-05-19 22:49:09 +03:00 · 2025-03-18 09:38:09 +03:00
34 changed files with 519 additions and 2366 deletions
--- a/.github/workflows/pio-dependabot.yaml
+++ b/.github/workflows/pio-dependabot.yaml
@@ -0,0 +1,22 @@
 name: PlatformIO Dependabot
 on:
  workflow_dispatch: # option to manually trigger the workflow
  schedule:
    # Runs every day at 00:00
    - cron: "0 0 * * *"
 permissions:
  contents: write
  pull-requests: write
 jobs:
  dependabot:
    runs-on: ubuntu-latest
    name: run PlatformIO Dependabot
    steps:
      - name: Checkout
        uses: actions/checkout@v4
      - name: run PlatformIO Dependabot
        uses: peterus/platformio_dependabot@v1.2.0
        with:
          github_token: ${{ secrets.GITHUB_TOKEN }}
--- a/.github/workflows/stale.yaml
+++ b/.github/workflows/stale.yaml
@@ -7,7 +7,7 @@ jobs:
  stale:
    runs-on: ubuntu-latest
    steps:
-      - uses: actions/stale@v10
+      - uses: actions/stale@v9
        with:
          stale-issue-message: >
            This issue is stale because it has been open 15 days with no activity. Remove stale label or comment or this will be closed in 5 days.
--- a/.gitignore
+++ b/.gitignore
@@ -1,6 +1,5 @@
 .pio
 .vscode
 .PVS-Studio
 build/*
 data/*
 managed_components/*
--- a/README.md
+++ b/README.md
@@ -71,10 +71,5 @@ All available information and instructions can be found in the wiki:
      * [Connection](https://github.com/Laxilef/OTGateway/wiki/OT-adapters#connection)
      * [Leds on board](https://github.com/Laxilef/OTGateway/wiki/OT-adapters#leds-on-board)
-## Gratitude
+___
-* To the developers of the libraries used: [OpenTherm Library](https://github.com/ihormelnyk/opentherm_library), [ESP8266Scheduler](https://github.com/nrwiersma/ESP8266Scheduler), [ArduinoJson](https://github.com/bblanchon/ArduinoJson), [NimBLE-Arduino](https://github.com/h2zero/NimBLE-Arduino), [ArduinoMqttClient](https://github.com/arduino-libraries/ArduinoMqttClient), [ESPTelnet](https://github.com/LennartHennigs/ESPTelnet), [FileData](https://github.com/GyverLibs/FileData), [GyverPID](https://github.com/GyverLibs/GyverPID), [GyverBlinker](https://github.com/GyverLibs/GyverBlinker), [OneWireNg](https://github.com/pstolarz/OneWireNg) & [OneWire](https://github.com/PaulStoffregen/OneWire)
+This project is tested with BrowserStack.
 * To the [PlatformIO](https://platformio.org/) Team
 * To the team and contributors of the [pioarduino](https://github.com/pioarduino/platform-espressif32) project
 * To the [BrowserStack](https://www.browserstack.com/) team. This project is tested with BrowserStack.
 * To the [PVS-Studio](https://pvs-studio.com/pvs-studio/?utm_source=website&utm_medium=github&utm_campaign=open_source) - static analyzer for C, C++, C#, and Java code.
 * And of course to the contributors for their contribution to the development of the project!
--- a/lib/CustomOpenTherm/CustomOpenTherm.h
+++ b/lib/CustomOpenTherm/CustomOpenTherm.h
@@ -4,8 +4,8 @@
 class CustomOpenTherm : public OpenTherm {
 public:
  typedef std::function<void(unsigned int)> DelayCallback;
-  typedef std::function<void(unsigned long, uint8_t)> BeforeSendRequestCallback;
+  typedef std::function<void(unsigned long, byte)> BeforeSendRequestCallback;
-  typedef std::function<void(unsigned long, unsigned long, OpenThermResponseStatus, uint8_t)> AfterSendRequestCallback;
+  typedef std::function<void(unsigned long, unsigned long, OpenThermResponseStatus, byte)> AfterSendRequestCallback;
  CustomOpenTherm(int inPin = 4, int outPin = 5, bool isSlave = false, bool alwaysReceive = false) : OpenTherm(inPin, outPin, isSlave, alwaysReceive) {}
  ~CustomOpenTherm() {}
@@ -106,14 +106,10 @@ public:
    return isValidResponse(response) && isValidResponseId(response, OpenThermMessageID::RemoteRequest);
  }
  static bool isCh2Active(unsigned long response) {
      return response & 0x20;
  }
  static bool isValidResponseId(unsigned long response, OpenThermMessageID id) {
-    uint8_t responseId = (response >> 16) & 0xFF;
+    byte responseId = (response >> 16) & 0xFF;
-    return (uint8_t)id == responseId;
+    return (byte)id == responseId;
  }
  static uint8_t getResponseMessageTypeId(unsigned long response) {
--- a/lib/HomeAssistantHelper/HomeAssistantHelper.h
+++ b/lib/HomeAssistantHelper/HomeAssistantHelper.h
@@ -147,19 +147,8 @@ public:
    return topic;
  }
  template <class DT, class VT> 
  String getEntityIdWithPrefix(DT domain, VT value, char separator = '_') {
    String topic = "";
    topic.concat(domain);
    topic.concat('.');
    topic.concat(this->devicePrefix);
    topic.concat(separator);
    topic.concat(value);
    return topic;
  }
  template <class T> 
-  String getUniqueIdWithPrefix(T value, char separator = '_') {
+  String getObjectIdWithPrefix(T value, char separator = '_') {
    String topic = "";
    topic.concat(this->devicePrefix);
    topic.concat(separator);
--- a/lib/HomeAssistantHelper/strings.h
+++ b/lib/HomeAssistantHelper/strings.h
@@ -12,67 +12,66 @@ const char HA_ENTITY_SELECT[]                   PROGMEM = "select";
 const char HA_ENTITY_SENSOR[]                   PROGMEM = "sensor";
 const char HA_ENTITY_SWITCH[]                   PROGMEM = "switch";
-// https://www.home-assistant.io/integrations/mqtt/#supported-abbreviations-in-mqtt-discovery-messages
+const char HA_DEVICE[]                          PROGMEM = "device";
-const char HA_DEFAULT_ENTITY_ID[]               PROGMEM = "def_ent_id";               // "default_entity_id "
+const char HA_IDENTIFIERS[]                     PROGMEM = "identifiers";
-const char HA_DEVICE[]                          PROGMEM = "dev";                      // "device"
+const char HA_SW_VERSION[]                      PROGMEM = "sw_version";
-const char HA_IDENTIFIERS[]                     PROGMEM = "ids";                      // "identifiers"
+const char HA_MANUFACTURER[]                    PROGMEM = "manufacturer";
-const char HA_SW_VERSION[]                      PROGMEM = "sw";                       // "sw_version"
+const char HA_MODEL[]                           PROGMEM = "model";
 const char HA_MANUFACTURER[]                    PROGMEM = "mf";                       // "manufacturer"
 const char HA_MODEL[]                           PROGMEM = "mdl";                      // "model"
 const char HA_NAME[]                            PROGMEM = "name";
-const char HA_CONF_URL[]                        PROGMEM = "cu";                       // "configuration_url"
+const char HA_CONF_URL[]                        PROGMEM = "configuration_url";
-const char HA_COMMAND_TOPIC[]                   PROGMEM = "cmd_t";                    // "command_topic"
+const char HA_COMMAND_TOPIC[]                   PROGMEM = "command_topic";
-const char HA_COMMAND_TEMPLATE[]                PROGMEM = "cmd_tpl";                  // "command_template"
+const char HA_COMMAND_TEMPLATE[]                PROGMEM = "command_template";
-const char HA_ENABLED_BY_DEFAULT[]              PROGMEM = "en";                       // "enabled_by_default"
+const char HA_ENABLED_BY_DEFAULT[]              PROGMEM = "enabled_by_default";
-const char HA_UNIQUE_ID[]                       PROGMEM = "uniq_id";                  // "unique_id"
+const char HA_UNIQUE_ID[]                       PROGMEM = "unique_id";
-const char HA_ENTITY_CATEGORY[]                 PROGMEM = "ent_cat";                  // "entity_category"
+const char HA_OBJECT_ID[]                       PROGMEM = "object_id";
 const char HA_ENTITY_CATEGORY[]                 PROGMEM = "entity_category";
 const char HA_ENTITY_CATEGORY_DIAGNOSTIC[]      PROGMEM = "diagnostic";
 const char HA_ENTITY_CATEGORY_CONFIG[]          PROGMEM = "config";
-const char HA_STATE_TOPIC[]                     PROGMEM = "stat_t";                   // "state_topic"
+const char HA_STATE_TOPIC[]                     PROGMEM = "state_topic";
-const char HA_VALUE_TEMPLATE[]                  PROGMEM = "val_tpl";                  // "value_template"
+const char HA_VALUE_TEMPLATE[]                  PROGMEM = "value_template";
-const char HA_OPTIONS[]                         PROGMEM = "ops";                      // "options"
+const char HA_OPTIONS[]                         PROGMEM = "options";
-const char HA_AVAILABILITY[]                    PROGMEM = "avty";                     // "availability"
+const char HA_AVAILABILITY[]                    PROGMEM = "availability";
-const char HA_AVAILABILITY_MODE[]               PROGMEM = "avty_mode";                // "availability_mode"
+const char HA_AVAILABILITY_MODE[]               PROGMEM = "availability_mode";
-const char HA_TOPIC[]                           PROGMEM = "t";                        // "topic"
+const char HA_TOPIC[]                           PROGMEM = "topic";
-const char HA_DEVICE_CLASS[]                    PROGMEM = "dev_cla";                  // "device_class"
+const char HA_DEVICE_CLASS[]                    PROGMEM = "device_class";
-const char HA_UNIT_OF_MEASUREMENT[]             PROGMEM = "unit_of_meas";             // "unit_of_measurement"
+const char HA_UNIT_OF_MEASUREMENT[]             PROGMEM = "unit_of_measurement";
 const char HA_UNIT_OF_MEASUREMENT_C[]           PROGMEM = "°C";
 const char HA_UNIT_OF_MEASUREMENT_F[]           PROGMEM = "°F";
 const char HA_UNIT_OF_MEASUREMENT_PERCENT[]     PROGMEM = "%";
 const char HA_UNIT_OF_MEASUREMENT_L_MIN[]       PROGMEM = "L/min";
 const char HA_UNIT_OF_MEASUREMENT_GAL_MIN[]     PROGMEM = "gal/min";
-const char HA_ICON[]                            PROGMEM = "ic";                       // "icon"
+const char HA_ICON[]                            PROGMEM = "icon";
 const char HA_MIN[]                             PROGMEM = "min";
 const char HA_MAX[]                             PROGMEM = "max";
 const char HA_STEP[]                            PROGMEM = "step";
 const char HA_MODE[]                            PROGMEM = "mode";
 const char HA_MODE_BOX[]                        PROGMEM = "box";
-const char HA_STATE_ON[]                        PROGMEM = "stat_on";                  // "state_on"
+const char HA_STATE_ON[]                        PROGMEM = "state_on";
-const char HA_STATE_OFF[]                       PROGMEM = "stat_off";                 // "state_off"
+const char HA_STATE_OFF[]                       PROGMEM = "state_off";
-const char HA_PAYLOAD_ON[]                      PROGMEM = "pl_on";                    // "payload_on"
+const char HA_PAYLOAD_ON[]                      PROGMEM = "payload_on";
-const char HA_PAYLOAD_OFF[]                     PROGMEM = "pl_off";                   // "payload_off"
+const char HA_PAYLOAD_OFF[]                     PROGMEM = "payload_off";
-const char HA_STATE_CLASS[]                     PROGMEM = "stat_cla";                 // "state_class"
+const char HA_STATE_CLASS[]                     PROGMEM = "state_class";
 const char HA_STATE_CLASS_MEASUREMENT[]         PROGMEM = "measurement";
-const char HA_EXPIRE_AFTER[]                    PROGMEM = "exp_aft";                  // "expire_after"
+const char HA_EXPIRE_AFTER[]                    PROGMEM = "expire_after";
-const char HA_CURRENT_TEMPERATURE_TOPIC[]       PROGMEM = "curr_temp_t";              // "current_temperature_topic"
+const char HA_CURRENT_TEMPERATURE_TOPIC[]       PROGMEM = "current_temperature_topic";
-const char HA_CURRENT_TEMPERATURE_TEMPLATE[]    PROGMEM = "curr_temp_tpl";            // "current_temperature_template"
+const char HA_CURRENT_TEMPERATURE_TEMPLATE[]    PROGMEM = "current_temperature_template";
-const char HA_TEMPERATURE_COMMAND_TOPIC[]       PROGMEM = "temp_cmd_t";               // "temperature_command_topic"
+const char HA_TEMPERATURE_COMMAND_TOPIC[]       PROGMEM = "temperature_command_topic";
-const char HA_TEMPERATURE_COMMAND_TEMPLATE[]    PROGMEM = "temp_cmd_tpl";             // "temperature_command_template"
+const char HA_TEMPERATURE_COMMAND_TEMPLATE[]    PROGMEM = "temperature_command_template";
-const char HA_TEMPERATURE_STATE_TOPIC[]         PROGMEM = "temp_stat_t";              // "temperature_state_topic"
+const char HA_TEMPERATURE_STATE_TOPIC[]         PROGMEM = "temperature_state_topic";
-const char HA_TEMPERATURE_STATE_TEMPLATE[]      PROGMEM = "temp_stat_tpl";            // "temperature_state_template"
+const char HA_TEMPERATURE_STATE_TEMPLATE[]      PROGMEM = "temperature_state_template";
-const char HA_TEMPERATURE_UNIT[]                PROGMEM = "temp_unit";                // "temperature_unit"
+const char HA_TEMPERATURE_UNIT[]                PROGMEM = "temperature_unit";
-const char HA_MODE_COMMAND_TOPIC[]              PROGMEM = "mode_cmd_t";               // "mode_command_topic"
+const char HA_MODE_COMMAND_TOPIC[]              PROGMEM = "mode_command_topic";
-const char HA_MODE_COMMAND_TEMPLATE[]           PROGMEM = "mode_cmd_tpl";             // "mode_command_template"
+const char HA_MODE_COMMAND_TEMPLATE[]           PROGMEM = "mode_command_template";
-const char HA_MODE_STATE_TOPIC[]                PROGMEM = "mode_stat_t";              // "mode_state_topic"
+const char HA_MODE_STATE_TOPIC[]                PROGMEM = "mode_state_topic";
-const char HA_MODE_STATE_TEMPLATE[]             PROGMEM = "mode_stat_tpl";            // "mode_state_template"
+const char HA_MODE_STATE_TEMPLATE[]             PROGMEM = "mode_state_template";
 const char HA_MODES[]                           PROGMEM = "modes";
-const char HA_ACTION_TOPIC[]                    PROGMEM = "act_t";                    // "action_topic"
+const char HA_ACTION_TOPIC[]                    PROGMEM = "action_topic";
-const char HA_ACTION_TEMPLATE[]                 PROGMEM = "act_tpl";                  // "action_template"
+const char HA_ACTION_TEMPLATE[]                 PROGMEM = "action_template";
 const char HA_MIN_TEMP[]                        PROGMEM = "min_temp";
 const char HA_MAX_TEMP[]                        PROGMEM = "max_temp";
 const char HA_TEMP_STEP[]                       PROGMEM = "temp_step";
-const char HA_PRESET_MODE_COMMAND_TOPIC[]       PROGMEM = "pr_mode_cmd_t";            // "preset_mode_command_topic"
+const char HA_PRESET_MODE_COMMAND_TOPIC[]       PROGMEM = "preset_mode_command_topic";
-const char HA_PRESET_MODE_COMMAND_TEMPLATE[]    PROGMEM = "pr_mode_cmd_tpl";          // "preset_mode_command_template"
+const char HA_PRESET_MODE_COMMAND_TEMPLATE[]    PROGMEM = "preset_mode_command_template";
-const char HA_PRESET_MODE_STATE_TOPIC[]         PROGMEM = "pr_mode_stat_t";           // "preset_mode_state_topic"
+const char HA_PRESET_MODE_STATE_TOPIC[]         PROGMEM = "preset_mode_state_topic";
-const char HA_PRESET_MODE_VALUE_TEMPLATE[]      PROGMEM = "pr_mode_val_tpl";          // "preset_mode_value_template"
+const char HA_PRESET_MODE_VALUE_TEMPLATE[]      PROGMEM = "preset_mode_value_template";
-const char HA_PRESET_MODES[]                    PROGMEM = "pr_modes";                 // "preset_modes"
+const char HA_PRESET_MODES[]                    PROGMEM = "preset_modes";
--- a/lib/NetworkUtils/NetworkMgr.h
+++ b/lib/NetworkUtils/NetworkMgr.h
@@ -35,7 +35,7 @@ namespace NetworkUtils {
      return this;
    }
-    NetworkMgr* setApCredentials(const char* ssid, const char* password = nullptr, uint8_t channel = 0) {
+    NetworkMgr* setApCredentials(const char* ssid, const char* password = nullptr, byte channel = 0) {
      this->apName = ssid;
      this->apPassword = password;
      this->apChannel = channel;
@@ -43,7 +43,7 @@ namespace NetworkUtils {
      return this;
    }
-    NetworkMgr* setStaCredentials(const char* ssid = nullptr, const char* password = nullptr, uint8_t channel = 0) {
+    NetworkMgr* setStaCredentials(const char* ssid = nullptr, const char* password = nullptr, byte channel = 0) {
      this->staSsid = ssid;
      this->staPassword = password;
      this->staChannel = channel;
@@ -140,7 +140,7 @@ namespace NetworkUtils {
      return this->staPassword;
    }
-    uint8_t getStaChannel() {
+    byte getStaChannel() {
      return this->staChannel;
    }
@@ -377,7 +377,7 @@ namespace NetworkUtils {
      }
    }
-    static uint8_t rssiToSignalQuality(short int rssi) {
+    static byte rssiToSignalQuality(short int rssi) {
      return constrain(map(rssi, -100, -50, 0, 100), 0, 100);
    }
@@ -397,11 +397,11 @@ namespace NetworkUtils {
    const char* hostname = "esp";
    const char* apName = "ESP";
    const char* apPassword = nullptr;
-    uint8_t apChannel = 1;
+    byte apChannel = 1;
    const char* staSsid = nullptr;
    const char* staPassword = nullptr;
-    uint8_t staChannel = 0;
+    byte staChannel = 0;
    bool useDhcp = true;
    IPAddress staticIp;
--- a/platformio.ini
+++ b/platformio.ini
@@ -14,15 +14,15 @@ extra_configs = secrets.default.ini
 core_dir = .pio
 [env]
-version = 1.6.0
+version = 1.5.4
 framework = arduino
 lib_deps = 
-	bblanchon/ArduinoJson@^7.4.2
+	bblanchon/ArduinoJson@^7.3.0
 	;ihormelnyk/OpenTherm Library@^1.1.5
 	https://github.com/Laxilef/opentherm_library#esp32_timer
 	arduino-libraries/ArduinoMqttClient@^0.1.8
-	lennarthennigs/ESP Telnet@^2.2.3
+	lennarthennigs/ESP Telnet@^2.2
-	gyverlibs/FileData@^1.0.3
+	gyverlibs/FileData@^1.0.2
 	gyverlibs/GyverPID@^3.3.2
 	gyverlibs/GyverBlinker@^1.1.1
 	https://github.com/pstolarz/Arduino-Temperature-Control-Library.git#OneWireNg
@@ -60,16 +60,10 @@ monitor_filters =
 	esp8266_exception_decoder
 board_build.flash_mode = dio
 board_build.filesystem = littlefs
 check_tool = ; pvs-studio
 check_flags =
 ;  pvs-studio:
 ;    --analysis-mode=4
 ;    --exclude-path=./.pio/libdeps
 ; Defaults
 [esp8266_defaults]
 platform = espressif8266@^4.2.1
 platform_packages = ${env.platform_packages}
 lib_deps = 
 	${env.lib_deps}
 	nrwiersma/ESP8266Scheduler@^1.2
@@ -83,8 +77,6 @@ build_flags =
 	;-D PIO_FRAMEWORK_ARDUINO_LWIP2_HIGHER_BANDWIDTH_LOW_FLASH
 	-D PIO_FRAMEWORK_ARDUINO_ESPRESSIF_SDK305
 board_build.ldscript = eagle.flash.4m1m.ld
 check_tool = ${env.check_tool}
 check_flags = ${env.check_flags}
 [esp32_defaults]
 ;platform = espressif32@^6.7
@@ -92,13 +84,13 @@ check_flags = ${env.check_flags}
 ;platform_packages = 
 ;  framework-arduinoespressif32 @ https://github.com/espressif/arduino-esp32.git#3.0.5
 ;  framework-arduinoespressif32-libs @ https://github.com/espressif/esp32-arduino-lib-builder/releases/download/idf-release_v5.1/esp32-arduino-libs-idf-release_v5.1-33fbade6.zip
-platform = https://github.com/pioarduino/platform-espressif32/releases/download/55.03.34/platform-espressif32.zip
+platform = https://github.com/pioarduino/platform-espressif32/releases/download/54.03.20/platform-espressif32.zip
-platform_packages = ${env.platform_packages}
+platform_packages =
 board_build.partitions = esp32_partitions.csv
 lib_deps =
 	${env.lib_deps}
 	laxilef/ESP32Scheduler@^1.0.1
-nimble_lib = h2zero/NimBLE-Arduino@2.3.7
+nimble_lib = h2zero/NimBLE-Arduino@^2.1.0
 lib_ignore = 
 extra_scripts = 
 	post:tools/esp32.py
@@ -108,14 +100,11 @@ build_flags =
 	${env.build_flags}
 	-D CORE_DEBUG_LEVEL=0
 	-Wl,--wrap=esp_panic_handler
 check_tool = ${env.check_tool}
 check_flags = ${env.check_flags}
 ; Boards
 [env:d1_mini]
 platform = ${esp8266_defaults.platform}
 platform_packages = ${esp8266_defaults.platform_packages}
 board = d1_mini
 lib_deps = ${esp8266_defaults.lib_deps}
 lib_ignore = ${esp8266_defaults.lib_ignore}
@@ -130,12 +119,9 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=14
 	-D DEFAULT_STATUS_LED_GPIO=13
 	-D DEFAULT_OT_RX_LED_GPIO=15
 check_tool = ${esp8266_defaults.check_tool}
 check_flags = ${esp8266_defaults.check_flags}
 [env:d1_mini_lite]
 platform = ${esp8266_defaults.platform}
 platform_packages = ${esp8266_defaults.platform_packages}
 board = d1_mini_lite
 lib_deps = ${esp8266_defaults.lib_deps}
 lib_ignore = ${esp8266_defaults.lib_ignore}
@@ -150,12 +136,9 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=14
 	-D DEFAULT_STATUS_LED_GPIO=13
 	-D DEFAULT_OT_RX_LED_GPIO=15
 check_tool = ${esp8266_defaults.check_tool}
 check_flags = ${esp8266_defaults.check_flags}
 [env:d1_mini_pro]
 platform = ${esp8266_defaults.platform}
 platform_packages = ${esp8266_defaults.platform_packages}
 board = d1_mini_pro
 lib_deps = ${esp8266_defaults.lib_deps}
 lib_ignore = ${esp8266_defaults.lib_ignore}
@@ -170,12 +153,9 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=14
 	-D DEFAULT_STATUS_LED_GPIO=13
 	-D DEFAULT_OT_RX_LED_GPIO=15
 check_tool = ${esp8266_defaults.check_tool}
 check_flags = ${esp8266_defaults.check_flags}
 [env:nodemcu_8266]
 platform = ${esp8266_defaults.platform}
 platform_packages = ${esp8266_defaults.platform_packages}
 board = nodemcuv2
 lib_deps = ${esp8266_defaults.lib_deps}
 lib_ignore = ${esp8266_defaults.lib_ignore}
@@ -190,8 +170,6 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=4
 	-D DEFAULT_STATUS_LED_GPIO=2
 	-D DEFAULT_OT_RX_LED_GPIO=16
 check_tool = ${esp8266_defaults.check_tool}
 check_flags = ${esp8266_defaults.check_flags}
 [env:s2_mini]
 platform = ${esp32_defaults.platform}
@@ -214,8 +192,6 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=7
 	-D DEFAULT_STATUS_LED_GPIO=11
 	-D DEFAULT_OT_RX_LED_GPIO=12
 check_tool = ${esp32_defaults.check_tool}
 check_flags = ${esp32_defaults.check_flags}
 [env:s3_mini] 
 platform = ${esp32_defaults.platform}
@@ -234,7 +210,7 @@ build_flags =
 	${esp32_defaults.build_flags}
 	-D ARDUINO_USB_MODE=0
 	-D ARDUINO_USB_CDC_ON_BOOT=1
-	-D MYNEWT_VAL_BLE_EXT_ADV=1
+	-D CONFIG_BT_NIMBLE_EXT_ADV=1
 	-D USE_BLE=1
 	-D DEFAULT_OT_IN_GPIO=35
 	-D DEFAULT_OT_OUT_GPIO=36
@@ -242,8 +218,6 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=12
 	-D DEFAULT_STATUS_LED_GPIO=11
 	-D DEFAULT_OT_RX_LED_GPIO=10
 check_tool = ${esp32_defaults.check_tool}
 check_flags = ${esp32_defaults.check_flags}
 [env:c3_mini] 
 platform = ${esp32_defaults.platform}
@@ -260,7 +234,7 @@ build_unflags =
 build_type = ${esp32_defaults.build_type}
 build_flags = 
 	${esp32_defaults.build_flags}
-	-D MYNEWT_VAL_BLE_EXT_ADV=1
+	-D CONFIG_BT_NIMBLE_EXT_ADV=1
 	-D USE_BLE=1
 	-D DEFAULT_OT_IN_GPIO=8
 	-D DEFAULT_OT_OUT_GPIO=10
@@ -268,8 +242,6 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=1
 	-D DEFAULT_STATUS_LED_GPIO=4
 	-D DEFAULT_OT_RX_LED_GPIO=5
 check_tool = ${esp32_defaults.check_tool}
 check_flags = ${esp32_defaults.check_flags}
 [env:nodemcu_32]
 platform = ${esp32_defaults.platform}
@@ -291,12 +263,6 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=26
 	-D DEFAULT_STATUS_LED_GPIO=2
 	-D DEFAULT_OT_RX_LED_GPIO=19
 check_tool = ${esp32_defaults.check_tool}
 check_flags = ${esp32_defaults.check_flags}
 [env:nodemcu_32_160mhz] 
 extends = env:nodemcu_32 
 board_build.f_cpu = 160000000L ; set frequency to 160MHz
 [env:d1_mini32]
 platform = ${esp32_defaults.platform}
@@ -318,8 +284,6 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=18
 	-D DEFAULT_STATUS_LED_GPIO=2
 	-D DEFAULT_OT_RX_LED_GPIO=19
 check_tool = ${esp32_defaults.check_tool}
 check_flags = ${esp32_defaults.check_flags}
 [env:esp32_c6]
 platform = ${esp32_defaults.platform}
@@ -327,11 +291,6 @@ framework = arduino, espidf
 platform_packages = ${esp32_defaults.platform_packages}
 board = esp32-c6-devkitm-1
 board_build.partitions = ${esp32_defaults.board_build.partitions}
 board_build.embed_txtfiles = 
 	managed_components/espressif__esp_insights/server_certs/https_server.crt
 	managed_components/espressif__esp_rainmaker/server_certs/rmaker_mqtt_server.crt
 	managed_components/espressif__esp_rainmaker/server_certs/rmaker_claim_service_server.crt
 	managed_components/espressif__esp_rainmaker/server_certs/rmaker_ota_server.crt
 lib_deps = ${esp32_defaults.lib_deps}
 lib_ignore = 
 	${esp32_defaults.lib_ignore}
@@ -348,8 +307,6 @@ build_flags =
 	-D DEFAULT_SENSOR_INDOOR_GPIO=0
 	-D DEFAULT_STATUS_LED_GPIO=11
 	-D DEFAULT_OT_RX_LED_GPIO=10
 check_tool = ${esp32_defaults.check_tool}
 check_flags = ${esp32_defaults.check_flags}
 [env:otthing] 
 platform = ${esp32_defaults.platform}
@@ -366,7 +323,7 @@ build_unflags =
 build_type = ${esp32_defaults.build_type}
 build_flags = 
 	${esp32_defaults.build_flags}
-	-D MYNEWT_VAL_BLE_EXT_ADV=1
+	-D CONFIG_BT_NIMBLE_EXT_ADV=1
 	-D USE_BLE=1
 	-D DEFAULT_OT_IN_GPIO=3
 	-D DEFAULT_OT_OUT_GPIO=1
@@ -375,5 +332,3 @@ build_flags =
 	-D DEFAULT_STATUS_LED_GPIO=8
 	-D DEFAULT_OT_RX_LED_GPIO=2
 	-D OT_BYPASS_RELAY_GPIO=20
 check_tool = ${esp32_defaults.check_tool}
 check_flags = ${esp32_defaults.check_flags}
--- a/src/HaHelper.h
+++ b/src/HaHelper.h
@@ -3,8 +3,8 @@
 class HaHelper : public HomeAssistantHelper {
 public:
-  static const uint8_t TEMP_SOURCE_HEATING = 0;
+  static const byte TEMP_SOURCE_HEATING = 0;
-  static const uint8_t TEMP_SOURCE_INDOOR = 1;
+  static const byte TEMP_SOURCE_INDOOR = 1;
  static const char AVAILABILITY_OT_CONN[];
  static const char AVAILABILITY_SENSOR_CONN[];
@@ -261,13 +261,8 @@ public:
    }
    // object id's
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(objId.c_str());
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(objId.c_str());
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
      sSensor.type == Sensors::Type::MANUAL 
        ? FPSTR(HA_ENTITY_NUMBER) 
        : FPSTR(HA_ENTITY_SENSOR),
      objId.c_str()
    );
    const String& configTopic = this->makeConfigTopic(
      sSensor.type == Sensors::Type::MANUAL ? FPSTR(HA_ENTITY_NUMBER) : FPSTR(HA_ENTITY_SENSOR),
@@ -328,8 +323,8 @@ public:
    String objId = Sensors::makeObjectIdWithSuffix(sSensor.name, F("connected"));
    // object id's
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(objId.c_str());
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(objId.c_str());
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), objId.c_str());
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    // state topic
    doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(
@@ -375,8 +370,8 @@ public:
    String objId = Sensors::makeObjectIdWithSuffix(sSensor.name, F("signal_quality"));
    // object id's
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(objId.c_str());
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(objId.c_str());
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_SENSOR), objId.c_str());
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    // state topic
    doc[FPSTR(HA_STATE_TOPIC)] = this->getDeviceTopic(
@@ -412,6 +407,7 @@ public:
  }
  bool deleteSignalQualityDynamicSensor(Sensors::Settings& sSensor) {
    JsonDocument doc;
    const String& configTopic = this->makeConfigTopic(
      FPSTR(HA_ENTITY_SENSOR),
      Sensors::makeObjectIdWithSuffix(sSensor.name, F("signal_quality")).c_str()
@@ -425,8 +421,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("heating_turbo"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("heating_turbo"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_SWITCH), F("heating_turbo"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("Turbo heating");
    doc[FPSTR(HA_ICON)] = F("mdi:rocket-launch-outline");
@@ -443,34 +439,12 @@ public:
    return this->publish(this->makeConfigTopic(FPSTR(HA_ENTITY_SWITCH), F("heating_turbo")).c_str(), doc);
  }
  bool publishSwitchHeatingHysteresis(bool enabledByDefault = true) {
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("heating_hysteresis"));
    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_SWITCH), F("heating_hysteresis"));
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("Use heating hysteresis");
    doc[FPSTR(HA_ICON)] = F("mdi:altimeter");
    doc[FPSTR(HA_STATE_TOPIC)] = this->settingsTopic.c_str();
    doc[FPSTR(HA_STATE_ON)] = true;
    doc[FPSTR(HA_STATE_OFF)] = false;
    doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.heating.hysteresis.enabled }}");
    doc[FPSTR(HA_COMMAND_TOPIC)] = this->setSettingsTopic.c_str();
    doc[FPSTR(HA_PAYLOAD_ON)] = F("{\"heating\": {\"hysteresis\" : {\"enabled\" : true}}}");
    doc[FPSTR(HA_PAYLOAD_OFF)] = F("{\"heating\": {\"hysteresis\" : {\"enabled\" : false}}}");
    doc[FPSTR(HA_EXPIRE_AFTER)] = this->expireAfter;
    doc.shrinkToFit();
    return this->publish(this->makeConfigTopic(FPSTR(HA_ENTITY_SWITCH), F("heating_hysteresis")).c_str(), doc);
  }
  bool publishInputHeatingHysteresis(UnitSystem unit = UnitSystem::METRIC, bool enabledByDefault = true) {
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("heating_hysteresis"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("heating_hysteresis"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("heating_hysteresis"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_TEMPERATURE);
@@ -484,9 +458,9 @@ public:
    doc[FPSTR(HA_NAME)] = F("Heating hysteresis");
    doc[FPSTR(HA_ICON)] = F("mdi:altimeter");
    doc[FPSTR(HA_STATE_TOPIC)] = this->settingsTopic.c_str();
-    doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.heating.hysteresis.value|float(0)|round(2) }}");
+    doc[FPSTR(HA_VALUE_TEMPLATE)] = F("{{ value_json.heating.hysteresis|float(0)|round(2) }}");
    doc[FPSTR(HA_COMMAND_TOPIC)] = this->setSettingsTopic.c_str();
-    doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"heating\": {\"hysteresis\" : {\"value\" : {{ value }}}}}");
+    doc[FPSTR(HA_COMMAND_TEMPLATE)] = F("{\"heating\": {\"hysteresis\" : {{ value }}}}");
    doc[FPSTR(HA_MIN)] = 0;
    doc[FPSTR(HA_MAX)] = 15;
    doc[FPSTR(HA_STEP)] = 0.01f;
@@ -501,8 +475,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("heating_turbo_factor"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("heating_turbo_factor"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("heating_turbo_factor"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("power_factor");
    doc[FPSTR(HA_NAME)] = F("Heating turbo factor");
@@ -525,8 +499,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("heating_min_temp"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("heating_min_temp"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("heating_min_temp"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_TEMPERATURE);
@@ -559,8 +533,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("heating_max_temp"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("heating_max_temp"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("heating_max_temp"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_TEMPERATURE);
@@ -594,8 +568,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("dhw_min_temp"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("dhw_min_temp"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("dhw_min_temp"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_TEMPERATURE);
@@ -628,8 +602,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("dhw_max_temp"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("dhw_max_temp"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("dhw_max_temp"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_TEMPERATURE);
@@ -663,8 +637,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("pid"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("pid"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_SWITCH), F("pid"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("PID");
    doc[FPSTR(HA_ICON)] = F("mdi:chart-bar-stacked");
@@ -685,8 +659,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("pid_p"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("pid_p"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("pid_p"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("PID factor P");
    doc[FPSTR(HA_ICON)] = F("mdi:alpha-p-circle-outline");
@@ -708,8 +682,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("pid_i"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("pid_i"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("pid_i"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("PID factor I");
    doc[FPSTR(HA_ICON)] = F("mdi:alpha-i-circle-outline");
@@ -731,8 +705,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("pid_d"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("pid_d"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("pid_d"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("PID factor D");
    doc[FPSTR(HA_ICON)] = F("mdi:alpha-d-circle-outline");
@@ -754,8 +728,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("pid_dt"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("pid_dt"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("pid_dt"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("duration");
    doc[FPSTR(HA_UNIT_OF_MEASUREMENT)] = F("s");
@@ -779,8 +753,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("pid_min_temp"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("pid_min_temp"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("pid_min_temp"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_TEMPERATURE);
@@ -813,8 +787,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("pid_max_temp"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("pid_max_temp"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("pid_max_temp"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_TEMPERATURE);
@@ -848,8 +822,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("equitherm"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("equitherm"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_SWITCH), F("equitherm"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("Equitherm");
    doc[FPSTR(HA_ICON)] = F("mdi:sun-snowflake-variant");
@@ -870,8 +844,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("equitherm_slope"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("equitherm_slope"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("equitherm_slope"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("Equitherm slope");
    doc[FPSTR(HA_ICON)] = F("mdi:slope-uphill");
@@ -893,8 +867,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("equitherm_exponent"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("equitherm_exponent"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("equitherm_exponent"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("Equitherm exponent");
    doc[FPSTR(HA_ICON)] = F("mdi:exponent");
@@ -916,8 +890,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("equitherm_shift"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("equitherm_shift"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("equitherm_shift"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_TEMPERATURE);
    doc[FPSTR(HA_NAME)] = F("Equitherm shift");
@@ -943,8 +917,8 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = F("{{ iif(value_json.pid.enabled, 'offline', 'online') }}");
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("equitherm_target_diff_factor"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("equitherm_target_diff_factor"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_NUMBER), F("equitherm_target_diff_factor"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_NAME)] = F("Equitherm target diff factor");
    doc[FPSTR(HA_ICON)] = F("mdi:chart-timeline-variant-shimmer");
@@ -966,8 +940,8 @@ public:
  bool publishStatusState(bool enabledByDefault = true) {
    JsonDocument doc;
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("status"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("status"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), F("status"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("problem");
    doc[FPSTR(HA_NAME)] = F("Status");
@@ -984,8 +958,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("emergency"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("emergency"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), F("emergency"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("problem");
    doc[FPSTR(HA_NAME)] = F("Emergency");
@@ -1002,8 +976,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("ot_status"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("ot_status"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), F("ot_status"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("connectivity");
    doc[FPSTR(HA_NAME)] = F("Opentherm status");
@@ -1023,8 +997,9 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = JsonString(AVAILABILITY_OT_CONN, true);
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("heating"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("heating"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), F("heating"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    //doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("running");
    doc[FPSTR(HA_NAME)] = F("Heating");
    doc[FPSTR(HA_ICON)] = F("mdi:radiator");
@@ -1043,8 +1018,9 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = JsonString(AVAILABILITY_OT_CONN, true);
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("dhw"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("dhw"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), F("dhw"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    //doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("running");
    doc[FPSTR(HA_NAME)] = F("DHW");
    doc[FPSTR(HA_ICON)] = F("mdi:faucet");
@@ -1063,8 +1039,9 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = JsonString(AVAILABILITY_OT_CONN, true);
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("flame"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("flame"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), F("flame"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    //doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("running");
    doc[FPSTR(HA_NAME)] = F("Flame");
    doc[FPSTR(HA_ICON)] = F("mdi:gas-burner");
@@ -1083,8 +1060,8 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = JsonString(AVAILABILITY_OT_CONN, true);
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("fault"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("fault"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), F("fault"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("problem");
    doc[FPSTR(HA_NAME)] = F("Fault");
@@ -1104,8 +1081,8 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = JsonString(AVAILABILITY_OT_CONN, true);
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("problem");
    doc[FPSTR(HA_NAME)] = F("Diagnostic");
@@ -1122,8 +1099,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("ext_pump"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("ext_pump"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BINARY_SENSOR), F("ext_pump"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("running");
    doc[FPSTR(HA_NAME)] = F("External pump");
@@ -1143,8 +1120,8 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = F("{{ iif(value_json.slave.connected and value_json.slave.fault.active, 'online', 'offline') }}");
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("fault_code"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("fault_code"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_SENSOR), F("fault_code"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_NAME)] = F("Fault code");
    doc[FPSTR(HA_ICON)] = F("mdi:cog-box");
@@ -1163,8 +1140,8 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = F("{{ iif(value_json.slave.connected and value_json.slave.fault.active or value_json.slave.diag.active, 'online', 'offline') }}");
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("diagnostic_code"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("diagnostic_code"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_SENSOR), F("diagnostic_code"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_NAME)] = F("Diagnostic code");
    doc[FPSTR(HA_ICON)] = F("mdi:information-box");
@@ -1180,8 +1157,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(FPSTR(S_RSSI));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(FPSTR(S_RSSI));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_SENSOR), FPSTR(S_RSSI));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("signal_strength");
    doc[FPSTR(HA_STATE_CLASS)] = FPSTR(HA_STATE_CLASS_MEASUREMENT);
@@ -1200,8 +1177,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("uptime"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("uptime"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_SENSOR), F("uptime"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_DIAGNOSTIC);
    doc[FPSTR(HA_DEVICE_CLASS)] = F("duration");
    doc[FPSTR(HA_STATE_CLASS)] = F("total_increasing");
@@ -1217,12 +1194,12 @@ public:
  }
-  bool publishClimateHeating(UnitSystem unit = UnitSystem::METRIC, uint8_t minTemp = 20, uint8_t maxTemp = 90, bool enabledByDefault = true) {
+  bool publishClimateHeating(UnitSystem unit = UnitSystem::METRIC, byte minTemp = 20, byte maxTemp = 90, bool enabledByDefault = true) {
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("heating"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("heating"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_CLIMATE), F("heating"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_NAME)] = F("Heating");
    doc[FPSTR(HA_ICON)] = F("mdi:radiator");
@@ -1269,12 +1246,12 @@ public:
    return this->publish(this->makeConfigTopic(FPSTR(HA_ENTITY_CLIMATE), F("heating"), '_').c_str(), doc);
  }
-  bool publishClimateDhw(UnitSystem unit = UnitSystem::METRIC, uint8_t minTemp = 40, uint8_t maxTemp = 60, bool enabledByDefault = true) {
+  bool publishClimateDhw(UnitSystem unit = UnitSystem::METRIC, byte minTemp = 40, byte maxTemp = 60, bool enabledByDefault = true) {
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("dhw"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("dhw"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_CLIMATE), F("dhw"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_NAME)] = F("DHW");
    doc[FPSTR(HA_ICON)] = F("mdi:faucet");
@@ -1318,8 +1295,8 @@ public:
    JsonDocument doc;
    doc[FPSTR(HA_AVAILABILITY)][FPSTR(HA_TOPIC)] = this->statusTopic.c_str();
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(FPSTR(S_RESTART));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(FPSTR(S_RESTART));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BUTTON), FPSTR(S_RESTART));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_RESTART);
    doc[FPSTR(HA_NAME)] = F("Restart");
@@ -1338,8 +1315,8 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = F("{{ iif(value_json.slave.fault.active, 'online', 'offline') }}");
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("reset_fault"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("reset_fault"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BUTTON), F("reset_fault"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_RESTART);
    doc[FPSTR(HA_NAME)] = F("Reset fault");
@@ -1358,8 +1335,8 @@ public:
    doc[FPSTR(HA_AVAILABILITY)][1][FPSTR(HA_VALUE_TEMPLATE)] = F("{{ iif(value_json.slave.diag.active, 'online', 'offline') }}");
    doc[FPSTR(HA_AVAILABILITY_MODE)] = F("all");
    doc[FPSTR(HA_ENABLED_BY_DEFAULT)] = enabledByDefault;
-    doc[FPSTR(HA_UNIQUE_ID)] = this->getUniqueIdWithPrefix(F("reset_diagnostic"));
+    doc[FPSTR(HA_UNIQUE_ID)] = this->getObjectIdWithPrefix(F("reset_diagnostic"));
-    doc[FPSTR(HA_DEFAULT_ENTITY_ID)] = this->getEntityIdWithPrefix(FPSTR(HA_ENTITY_BUTTON), F("reset_diagnostic"));
+    doc[FPSTR(HA_OBJECT_ID)] = doc[FPSTR(HA_UNIQUE_ID)];
    doc[FPSTR(HA_ENTITY_CATEGORY)] = FPSTR(HA_ENTITY_CATEGORY_CONFIG);
    doc[FPSTR(HA_DEVICE_CLASS)] = FPSTR(S_RESTART);
    doc[FPSTR(HA_NAME)] = F("Reset diagnostic");
--- a/src/MainTask.h
+++ b/src/MainTask.h
@@ -29,7 +29,6 @@ protected:
  enum class PumpStartReason {NONE, HEATING, ANTISTUCK};
  Blinker* blinker = nullptr;
  unsigned long miscRunned = 0;
  unsigned long lastHeapInfo = 0;
  unsigned int minFreeHeap = 0;
  unsigned int minMaxFreeBlockHeap = 0;
@@ -43,8 +42,6 @@ protected:
  bool telnetStarted = false;
  bool emergencyDetected = false;
  unsigned long emergencyFlipTime = 0;
  bool freezeDetected = false;
  unsigned long freezeDetectedTime = 0;
  #if defined(ARDUINO_ARCH_ESP32)
  const char* getTaskName() override {
@@ -153,16 +150,17 @@ protected:
      Sensors::setConnectionStatusByType(Sensors::Type::MANUAL, false, false);
    }
    this->yield();
-    this->yield();
+    this->emergency();
    if (this->misc()) {
      this->yield();
    }
    this->ledStatus();
    this->cascadeControl();
    this->externalPump();
    this->yield();
    // telnet
    if (this->telnetStarted) {
      this->yield();
      telnetStream->loop();
      this->yield();
    }
@@ -181,27 +179,14 @@ protected:
    // heap info
    this->heap();
  }
  bool misc() {
    if (millis() - this->miscRunned < 1000) {
      return false;
    }
-    // restart if required
+    // restart
    if (this->restartSignalReceived && millis() - this->restartSignalReceivedTime > 15000) {
      this->restartSignalReceived = false;
      ESP.restart();
    }
    this->heating();
    this->emergency();
    this->cascadeControl();
    this->externalPump();
    this->miscRunned = millis();
    return true;
  }
  void heap() {
@@ -243,65 +228,6 @@ protected:
    }
  }
  void heating() {
    // freeze protection
    if (!settings.heating.enabled) {
      float lowTemp = 255.0f;
      uint8_t availableSensors = 0;
      if (Sensors::existsConnectedSensorsByPurpose(Sensors::Purpose::INDOOR_TEMP)) {
        auto value = Sensors::getMeanValueByPurpose(Sensors::Purpose::INDOOR_TEMP, Sensors::ValueType::PRIMARY);
        if (value < lowTemp) {
          lowTemp = value;
        }
        availableSensors++;
      }
      if (Sensors::existsConnectedSensorsByPurpose(Sensors::Purpose::HEATING_TEMP)) {
        auto value = Sensors::getMeanValueByPurpose(Sensors::Purpose::HEATING_TEMP, Sensors::ValueType::PRIMARY);
        if (value < lowTemp) {
          lowTemp = value;
        }
        availableSensors++;
      }
      if (Sensors::existsConnectedSensorsByPurpose(Sensors::Purpose::HEATING_RETURN_TEMP)) {
        auto value = Sensors::getMeanValueByPurpose(Sensors::Purpose::HEATING_RETURN_TEMP, Sensors::ValueType::PRIMARY);
        if (value < lowTemp) {
          lowTemp = value;
        }
        availableSensors++;
      }
      if (availableSensors && lowTemp <= settings.heating.freezeProtection.lowTemp) {
        if (!this->freezeDetected) {
          this->freezeDetected = true;
          this->freezeDetectedTime = millis();
        } else if (millis() - this->freezeDetectedTime > (settings.heating.freezeProtection.thresholdTime * 1000)) {
          this->freezeDetected = false;
          settings.heating.enabled = true;
          fsSettings.update();
          Log.sinfoln(
            FPSTR(L_MAIN),
            F("Heating turned on by freeze protection, current low temp: %.2f, threshold: %hhu"),
            lowTemp, settings.heating.freezeProtection.lowTemp
          );
        }
      } else if (this->freezeDetected) {
        this->freezeDetected = false;
      }
    } else if (this->freezeDetected) {
      this->freezeDetected = false;
    }
  }
  void emergency() {
    // flags
    uint8_t emergencyFlags = 0b00000000;
@@ -609,12 +535,7 @@ protected:
      if (GPIO_IS_VALID(settings.externalPump.gpio)) {
        configuredGpio = settings.externalPump.gpio;
        pinMode(configuredGpio, OUTPUT);
-        digitalWrite(
+        digitalWrite(configuredGpio, LOW);
          configuredGpio,
          settings.externalPump.invertState
            ? HIGH 
            : LOW
        );
      } else if (configuredGpio != GPIO_IS_NOT_CONFIGURED) {
        configuredGpio = GPIO_IS_NOT_CONFIGURED;
@@ -642,12 +563,7 @@ protected:
    if (!settings.externalPump.use) {
      if (vars.externalPump.state) {
-        digitalWrite(
+        digitalWrite(configuredGpio, LOW);
          configuredGpio,
          settings.externalPump.invertState
            ? HIGH 
            : LOW
        );
        vars.externalPump.state = false;
        vars.externalPump.lastEnabledTime = millis();
@@ -660,12 +576,7 @@ protected:
    if (vars.externalPump.state && !this->heatingEnabled) {
      if (this->extPumpStartReason == MainTask::PumpStartReason::HEATING && millis() - this->heatingDisabledTime > (settings.externalPump.postCirculationTime * 1000u)) {
-        digitalWrite(
+        digitalWrite(configuredGpio, LOW);
          configuredGpio,
          settings.externalPump.invertState
            ? HIGH 
            : LOW
        );
        vars.externalPump.state = false;
        vars.externalPump.lastEnabledTime = millis();
@@ -673,12 +584,7 @@ protected:
        Log.sinfoln(FPSTR(L_EXTPUMP), F("Disabled: expired post circulation time"));
      } else if (this->extPumpStartReason == MainTask::PumpStartReason::ANTISTUCK && millis() - this->externalPumpStartTime >= (settings.externalPump.antiStuckTime * 1000u)) {
-        digitalWrite(
+        digitalWrite(configuredGpio, LOW);
          configuredGpio,
          settings.externalPump.invertState
            ? HIGH 
            : LOW
        );
        vars.externalPump.state = false;
        vars.externalPump.lastEnabledTime = millis();
@@ -694,12 +600,7 @@ protected:
      this->externalPumpStartTime = millis();
      this->extPumpStartReason = MainTask::PumpStartReason::HEATING;
-      digitalWrite(
+      digitalWrite(configuredGpio, HIGH);
        configuredGpio,
        settings.externalPump.invertState
          ? LOW 
          : HIGH
      );
      Log.sinfoln(FPSTR(L_EXTPUMP), F("Enabled: heating on"));
@@ -708,12 +609,7 @@ protected:
      this->externalPumpStartTime = millis();
      this->extPumpStartReason = MainTask::PumpStartReason::ANTISTUCK;
-      digitalWrite(
+      digitalWrite(configuredGpio, HIGH);
        configuredGpio,
        settings.externalPump.invertState
          ? LOW 
          : HIGH
      );
      Log.sinfoln(FPSTR(L_EXTPUMP), F("Enabled: anti stuck"));
    }
--- a/src/MqttTask.h
+++ b/src/MqttTask.h
@@ -486,7 +486,6 @@ protected:
  void publishHaEntities() {
    // heating
    this->haHelper->publishSwitchHeatingTurbo(false);
    this->haHelper->publishSwitchHeatingHysteresis();
    this->haHelper->publishInputHeatingHysteresis(settings.system.unitSystem);
    this->haHelper->publishInputHeatingTurboFactor(false);
    this->haHelper->publishInputHeatingMinTemp(settings.system.unitSystem);
@@ -559,7 +558,7 @@ protected:
  }
  bool publishNonStaticHaEntities(bool force = false) {
-    static uint8_t _heatingMinTemp, _heatingMaxTemp, _dhwMinTemp, _dhwMaxTemp = 0;
+    static byte _heatingMinTemp, _heatingMaxTemp, _dhwMinTemp, _dhwMaxTemp = 0;
    static bool _indoorTempControl, _dhwSupport = false;
    bool published = false;
--- a/src/OpenThermTask.h
+++ b/src/OpenThermTask.h
@@ -19,8 +19,8 @@ protected:
  CustomOpenTherm* instance = nullptr;
  unsigned long instanceCreatedTime = 0;
-  uint8_t instanceInGpio = 0;
+  byte instanceInGpio = 0;
-  uint8_t instanceOutGpio = 0;
+  byte instanceOutGpio = 0;
  bool initialized = false;
  unsigned long connectedTime = 0;
  unsigned long disconnectedTime = 0;
@@ -31,7 +31,7 @@ protected:
  unsigned long heatingSetTempTime = 0;
  unsigned long dhwSetTempTime = 0;
  unsigned long ch2SetTempTime = 0;
-  uint8_t configuredRxLedGpio = GPIO_IS_NOT_CONFIGURED;
+  byte configuredRxLedGpio = GPIO_IS_NOT_CONFIGURED;
  #if defined(ARDUINO_ARCH_ESP32)
  const char* getTaskName() override {
@@ -90,7 +90,7 @@ protected:
    Log.sinfoln(FPSTR(L_OT), F("Started. GPIO IN: %hhu, GPIO OUT: %hhu"), settings.opentherm.inGpio, settings.opentherm.outGpio);
-    this->instance->setAfterSendRequestCallback([this](unsigned long request, unsigned long response, OpenThermResponseStatus status, uint8_t attempt) {
+    this->instance->setAfterSendRequestCallback([this](unsigned long request, unsigned long response, OpenThermResponseStatus status, byte attempt) {
      Log.sverboseln(
        FPSTR(L_OT),
        F("ID: %4d   Request: %8lx   Response: %8lx   Msg type: %s   Attempt: %2d   Status: %s"),
@@ -169,15 +169,12 @@ protected:
    // Heating settings
    vars.master.heating.enabled = this->isReady()
-      && settings.heating.enabled
+      && (settings.heating.enabled || vars.emergency.state) 
      && vars.cascadeControl.input 
-      && (!vars.master.heating.blocking || settings.heating.hysteresis.action != HysteresisAction::DISABLE_HEATING)
+      && !vars.master.heating.blocking;
      && !vars.master.heating.overheat;
    // DHW settings
-    vars.master.dhw.enabled = settings.opentherm.options.dhwSupport 
+    vars.master.dhw.enabled = settings.opentherm.options.dhwSupport && settings.dhw.enabled;
      && settings.dhw.enabled 
      && !vars.master.dhw.overheat;
    vars.master.dhw.targetTemp = settings.dhw.target;
    // CH2 settings
@@ -208,12 +205,6 @@ protected:
      summerWinterMode = vars.master.heating.enabled == summerWinterMode;
    }
    // DHW blocking
    bool dhwBlocking = settings.opentherm.options.dhwBlocking;
    if (settings.opentherm.options.dhwStateAsDhwBlocking) {
      dhwBlocking = vars.master.dhw.enabled == dhwBlocking;
    }
    unsigned long response = this->instance->setBoilerStatus(
      vars.master.heating.enabled,
      vars.master.dhw.enabled,
@@ -221,7 +212,7 @@ protected:
      settings.opentherm.options.nativeHeatingControl,
      vars.master.ch2.enabled,
      summerWinterMode,
-      dhwBlocking,
+      settings.opentherm.options.dhwBlocking,
      statusLb
    );
@@ -236,8 +227,7 @@ protected:
      vars.slave.heating.active = CustomOpenTherm::isCentralHeatingActive(response);
      vars.slave.dhw.active = settings.opentherm.options.dhwSupport ? CustomOpenTherm::isHotWaterActive(response) : false;
      vars.slave.flame = CustomOpenTherm::isFlameOn(response);
-      vars.slave.cooling.active = CustomOpenTherm::isCoolingActive(response);
+      vars.slave.cooling = CustomOpenTherm::isCoolingActive(response);
      vars.slave.ch2.active = CustomOpenTherm::isCh2Active(response);
      vars.slave.fault.active = CustomOpenTherm::isFault(response);
      if (!settings.opentherm.options.ignoreDiagState) {
@@ -248,9 +238,9 @@ protected:
      }
      Log.snoticeln(
-        FPSTR(L_OT), F("Received boiler status. Heating: %hhu; DHW: %hhu; flame: %hhu; cooling: %hhu; channel 2: %hhu; fault: %hhu; diag: %hhu"),
+        FPSTR(L_OT), F("Received boiler status. Heating: %hhu; DHW: %hhu; flame: %hhu; cooling: %hhu; fault: %hhu; diag: %hhu"),
        vars.slave.heating.active, vars.slave.dhw.active,
-        vars.slave.flame, vars.slave.cooling.active, vars.slave.ch2.active, vars.slave.fault.active, vars.slave.diag.active
+        vars.slave.flame, vars.slave.cooling, vars.slave.fault.active, vars.slave.diag.active
      );
    }
@@ -318,8 +308,6 @@ protected:
      vars.slave.dhw.enabled = false;
      vars.slave.dhw.active = false;
      vars.slave.flame = false;
      vars.slave.cooling.active = false;
      vars.slave.cooling.setpoint = 0;
      vars.slave.fault.active = false;
      vars.slave.fault.code = 0;
      vars.slave.diag.active = false;
@@ -690,22 +678,6 @@ protected:
      this->prevUpdateNonEssentialVars = millis();
    }
    // Set cooling setpoint = heating max modulation
    if (settings.opentherm.options.coolingSupport) {
      if (this->setCoolingSetpoint(settings.heating.maxModulation)) {
        Log.snoticeln(
          FPSTR(L_OT), F("Set cooling setpoint: %hhu%% (response: %hhu%%)"),
          settings.heating.maxModulation, vars.slave.cooling.setpoint
        );
      } else {
        Log.swarningln(
          FPSTR(L_OT), F("Failed set cooling setpoint: %hhu%% (response: %hhu%%)"),
          settings.heating.maxModulation, vars.slave.cooling.setpoint
        );
      }
    }
    // Set max modulation level
    uint8_t targetMaxModulation = vars.slave.modulation.max;
    if (vars.slave.heating.active) {
@@ -1209,8 +1181,8 @@ protected:
      }
    }
-    // Set indoor temp for Native heating control/Always set indoor temp
+    // Native heating control
-    if (settings.opentherm.options.nativeHeatingControl || settings.opentherm.options.alwaysSetIndoorTemp) {
+    if (settings.opentherm.options.nativeHeatingControl) {
      // Converted current indoor temp
      float convertedTemp = convertTemp(vars.master.heating.indoorTemp, settings.system.unitSystem, settings.opentherm.unitSystem);
@@ -1237,13 +1209,10 @@ protected:
          Log.swarningln(FPSTR(L_OT_HEATING), F("Failed set current CH2 indoor temp"));
        }
      }
    }
    // Native heating control
    if (settings.opentherm.options.nativeHeatingControl) {
      // Converted target indoor temp
-      float convertedTemp = convertTemp(vars.master.heating.targetTemp, settings.system.unitSystem, settings.opentherm.unitSystem);
+      convertedTemp = convertTemp(vars.master.heating.targetTemp, settings.system.unitSystem, settings.opentherm.unitSystem);
      // Set target indoor temp
      if (this->needSetHeatingTemp(convertedTemp)) {
@@ -1338,84 +1307,6 @@ protected:
        }
      }
    }
    // Heating overheat control
    if (settings.heating.overheatProtection.highTemp > 0 && settings.heating.overheatProtection.lowTemp > 0) {
      float highTemp = convertTemp(
        max({
          vars.slave.heating.currentTemp,
          vars.slave.heating.returnTemp,
          vars.slave.heatExchangerTemp
        }),
        settings.opentherm.unitSystem,
        settings.system.unitSystem
      );
      if (vars.master.heating.overheat) {
        if ((float) settings.heating.overheatProtection.lowTemp - highTemp + 0.0001f >= 0.0f) {
          vars.master.heating.overheat = false;
          Log.sinfoln(
            FPSTR(L_OT_HEATING), F("Overheating not detected. Current high temp: %.2f, threshold (low): %hhu"),
            highTemp, settings.heating.overheatProtection.lowTemp
          );
        }
      } else if (vars.slave.heating.active) {
        if (highTemp - (float) settings.heating.overheatProtection.highTemp + 0.0001f >= 0.0f) {
          vars.master.heating.overheat = true;
          Log.swarningln(
            FPSTR(L_OT_HEATING), F("Overheating detected! Current high temp: %.2f, threshold (high): %hhu"),
            highTemp, settings.heating.overheatProtection.highTemp
          );
        }
      }
    } else if (vars.master.heating.overheat) {
      vars.master.heating.overheat = false;
    }
    // DHW overheat control
    if (settings.dhw.overheatProtection.highTemp > 0 && settings.dhw.overheatProtection.lowTemp > 0) {
      float highTemp = convertTemp(
        max({
          vars.slave.heating.currentTemp,
          vars.slave.heating.returnTemp,
          vars.slave.heatExchangerTemp,
          vars.slave.dhw.currentTemp,
          vars.slave.dhw.currentTemp2,
          vars.slave.dhw.returnTemp
        }),
        settings.opentherm.unitSystem,
        settings.system.unitSystem
      );
      if (vars.master.dhw.overheat) {
        if ((float) settings.dhw.overheatProtection.lowTemp - highTemp + 0.0001f >= 0.0f) {
          vars.master.dhw.overheat = false;
          Log.sinfoln(
            FPSTR(L_OT_DHW), F("Overheating not detected. Current high temp: %.2f, threshold (low): %hhu"),
            highTemp, settings.dhw.overheatProtection.lowTemp
          );
        }
      } else if (vars.slave.dhw.active) {
        if (highTemp - (float) settings.dhw.overheatProtection.highTemp + 0.0001f >= 0.0f) {
          vars.master.dhw.overheat = true;
          Log.swarningln(
            FPSTR(L_OT_DHW), F("Overheating detected! Current high temp: %.2f, threshold (high): %hhu"),
            highTemp, settings.dhw.overheatProtection.highTemp
          );
        }
      }
    } else if (vars.master.dhw.overheat) {
      vars.master.dhw.overheat = false;
    }
  }
  void initialize() {
@@ -1589,26 +1480,6 @@ protected:
    return CustomOpenTherm::getUInt(response) == request;
  }
  bool setCoolingSetpoint(const uint8_t value) {
    const unsigned int request = CustomOpenTherm::toFloat(value);
    const unsigned long response = this->instance->sendRequest(CustomOpenTherm::buildRequest(
      OpenThermRequestType::WRITE_DATA,
      OpenThermMessageID::CoolingControl,
      request
    ));
    if (!CustomOpenTherm::isValidResponse(response)) {
      return false;
    } else if (!CustomOpenTherm::isValidResponseId(response, OpenThermMessageID::CoolingControl)) {
      return false;
    }
    vars.slave.cooling.setpoint = CustomOpenTherm::getFloat(response);
    return CustomOpenTherm::getUInt(response) == request;
  }
  bool setMaxModulationLevel(const uint8_t value) {
    const unsigned int request = CustomOpenTherm::toFloat(value);
    const unsigned long response = this->instance->sendRequest(CustomOpenTherm::buildRequest(
--- a/src/RegulatorTask.h
+++ b/src/RegulatorTask.h
@@ -57,23 +57,12 @@ protected:
    this->turbo();
    this->hysteresis();
    if (vars.master.heating.blocking && settings.heating.hysteresis.action == HysteresisAction::SET_ZERO_TARGET) {
      vars.master.heating.targetTemp = 0.0f;
      vars.master.heating.setpointTemp = 0.0f;
      // tick if PID enabled
      if (settings.pid.enabled) {
        this->getHeatingSetpointTemp();
      }
    } else {
    vars.master.heating.targetTemp = settings.heating.target;
    vars.master.heating.setpointTemp = roundf(constrain(
      this->getHeatingSetpointTemp(),
      this->getHeatingMinSetpointTemp(),
      this->getHeatingMaxSetpointTemp()
    ), 0);
    }
    Sensors::setValueByType(
      Sensors::Type::HEATING_SETPOINT_TEMP, vars.master.heating.setpointTemp,
@@ -101,15 +90,15 @@ protected:
  void hysteresis() {
    bool useHyst = false;
-    if (settings.heating.hysteresis.enabled && this->indoorSensorsConnected) {
+    if (settings.heating.hysteresis > 0.01f && this->indoorSensorsConnected) {
      useHyst = settings.equitherm.enabled || settings.pid.enabled || settings.opentherm.options.nativeHeatingControl;
    }
    if (useHyst) {
-      if (!vars.master.heating.blocking && vars.master.heating.indoorTemp - settings.heating.target + 0.0001f >= settings.heating.hysteresis.value) {
+      if (!vars.master.heating.blocking && vars.master.heating.indoorTemp - settings.heating.target + 0.0001f >= settings.heating.hysteresis) {
        vars.master.heating.blocking = true;
-      } else if (vars.master.heating.blocking && vars.master.heating.indoorTemp - settings.heating.target - 0.0001f <= -(settings.heating.hysteresis.value)) {
+      } else if (vars.master.heating.blocking && vars.master.heating.indoorTemp - settings.heating.target - 0.0001f <= -(settings.heating.hysteresis)) {
        vars.master.heating.blocking = false;
      }
@@ -215,8 +204,7 @@ protected:
        }*/
        float error = pidRegulator.setpoint - pidRegulator.input;
-        bool hasDeadband = settings.pid.deadband.enabled 
+        bool hasDeadband = (error > -(settings.pid.deadband.thresholdHigh))
          && (error > -(settings.pid.deadband.thresholdHigh))
          && (error < settings.pid.deadband.thresholdLow);
        if (hasDeadband) {
--- a/src/Sensors.h
+++ b/src/Sensors.h
@@ -138,7 +138,7 @@ public:
    }
    uint8_t amount = 0;
-    for (uint8_t id = 0; id <= getMaxSensorId(); id++) {
+    for (uint8_t id = 0; id < getMaxSensorId(); id++) {
      if (settings[id].type == type && (!onlyEnabled || settings[id].enabled)) {
        amount++;
      }
@@ -149,10 +149,10 @@ public:
  static int16_t getIdByName(const char* name) {
    if (settings == nullptr) {
-      return -1;
+      return 0;
    }
-    for (uint8_t id = 0; id <= getMaxSensorId(); id++) {
+    for (uint8_t id = 0; id < getMaxSensorId(); id++) {
      if (strcmp(settings[id].name, name) == 0) {
        return id;
      }
@@ -163,11 +163,11 @@ public:
  static int16_t getIdByObjectId(const char* objectId) {
    if (settings == nullptr) {
-      return -1;
+      return 0;
    }
    String refObjectId;
-    for (uint8_t id = 0; id <= getMaxSensorId(); id++) {
+    for (uint8_t id = 0; id < getMaxSensorId(); id++) {
      Sensors::makeObjectId(refObjectId, settings[id].name);
      if (refObjectId.equals(objectId)) {
        return id;
@@ -247,7 +247,7 @@ public:
    uint8_t updated = 0;
    // read sensors data for current instance
-    for (uint8_t sensorId = 0; sensorId <= getMaxSensorId(); sensorId++) {
+    for (uint8_t sensorId = 0; sensorId < getMaxSensorId(); sensorId++) {
      auto& sSensor = settings[sensorId];
      // only target & valid sensors
@@ -311,7 +311,7 @@ public:
    uint8_t updated = 0;
    // read sensors data for current instance
-    for (uint8_t sensorId = 0; sensorId <= getMaxSensorId(); sensorId++) {
+    for (uint8_t sensorId = 0; sensorId < getMaxSensorId(); sensorId++) {
      auto& sSensor = settings[sensorId];
      // only target & valid sensors
@@ -329,18 +329,18 @@ public:
  static float getMeanValueByPurpose(Purpose purpose, const ValueType valueType, bool onlyConnected = true) {
    if (settings == nullptr || results == nullptr) {
-      return 0.0f;
+      return 0;
    }
    uint8_t valueId = (uint8_t) valueType;
    if (!isValidValueId(valueId)) {
-      return 0.0f;
+      return false;
    }
    float value = 0.0f;
    uint8_t amount = 0;
-    for (uint8_t id = 0; id <= getMaxSensorId(); id++) {
+    for (uint8_t id = 0; id < getMaxSensorId(); id++) {
      auto& sSensor = settings[id];
      auto& rSensor = results[id];
@@ -363,10 +363,10 @@ public:
  static bool existsConnectedSensorsByPurpose(Purpose purpose) {
    if (settings == nullptr || results == nullptr) {
-      return false;
+      return 0;
    }
-    for (uint8_t id = 0; id <= getMaxSensorId(); id++) {
+    for (uint8_t id = 0; id < getMaxSensorId(); id++) {
      if (settings[id].purpose == purpose && results[id].connected) {
        return true;
      }
--- a/src/SensorsTask.h
+++ b/src/SensorsTask.h
@@ -8,45 +8,6 @@
 extern FileData fsSensorsSettings;
 #if USE_BLE
 class BluetoothClientCallbacks : public NimBLEClientCallbacks {
 public:
  BluetoothClientCallbacks(uint8_t sensorId) : sensorId(sensorId) {}
  void onConnect(NimBLEClient* pClient) {
    auto& sSensor = Sensors::settings[this->sensorId];
    Log.sinfoln(
      FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': connected to %s"),
      sensorId, sSensor.name, pClient->getPeerAddress().toString().c_str()
    );
  }
  void onDisconnect(NimBLEClient* pClient, int reason) {
    auto& sSensor = Sensors::settings[this->sensorId];
    Log.sinfoln(
      FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': disconnected, reason %i"),
      sensorId, sSensor.name, reason
    );
  }
  void onConnectFail(NimBLEClient* pClient, int reason) {
    auto& sSensor = Sensors::settings[this->sensorId];
    Log.sinfoln(
      FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': failed to connect, reason %i"),
      sensorId, sSensor.name, reason
    );
    pClient->cancelConnect();
  }
 protected:
  uint8_t sensorId;
 };
 #endif
 class SensorsTask : public LeanTask {
 public:
  SensorsTask(bool _enabled = false, unsigned long _interval = 0) : LeanTask(_enabled, _interval) {
@@ -80,7 +41,6 @@ protected:
  std::unordered_map<uint8_t, bool> dallasPolling;
  std::unordered_map<uint8_t, unsigned long> dallasLastPollingTime;
  #if USE_BLE
  std::unordered_map<uint8_t, NimBLEClient*> bleClients;
  std::unordered_map<uint8_t, bool> bleSubscribed;
  std::unordered_map<uint8_t, unsigned long> bleLastSetDtTime;
  #endif
@@ -425,7 +385,7 @@ protected:
        continue;
      }
-      const float sensorResistance = value > 1
+      const float sensorResistance = value > 0.001f
        ? DEFAULT_NTC_REF_RESISTANCE / (DEFAULT_NTC_VREF / (float) value - 1.0f)
        : 0.0f;
      const float rawTemp = 1.0f / (
@@ -445,35 +405,47 @@ protected:
  #if USE_BLE
  void cleanBleInstances() {
    #if USE_BLE
    if (!NimBLEDevice::isInitialized()) {
      return;
    }
-    for (auto& [sensorId, pClient]: this->bleClients) {
+    for (auto client : NimBLEDevice::getConnectedClients()) {
-      if (pClient == nullptr) {
+      auto address = client->getPeerAddress();
      bool used = false;
      for (uint8_t sensorId = 0; sensorId <= Sensors::getMaxSensorId(); sensorId++) {
        auto& sSensor = Sensors::settings[sensorId];
        if (!sSensor.enabled || sSensor.type != Sensors::Type::BLUETOOTH || sSensor.purpose == Sensors::Purpose::NOT_CONFIGURED) {
          continue;
        }
-      auto& sSensor = Sensors::settings[sensorId];
+        auto pAddress = address.getVal();
-      const auto sAddress = NimBLEAddress(sSensor.address, 0);
+        uint8_t addr[] = {
          pAddress[5], pAddress[4], pAddress[3],
          pAddress[2], pAddress[1], pAddress[0]
        };
-      if (sAddress.isNull() || !sSensor.enabled || sSensor.type != Sensors::Type::BLUETOOTH || sSensor.purpose == Sensors::Purpose::NOT_CONFIGURED) {
+        if (isEqualAddress(addr, sSensor.address, sizeof(addr))) {
          used = true;
          break;
        }
      }
      if (!used) {
        Log.sinfoln(
-          FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s', deleted unused client"),
+          FPSTR(L_SENSORS_BLE), F("Deleted unused client connected to %s"),
-          sensorId, sSensor.name
+          address.toString().c_str()
        );
-        NimBLEDevice::deleteClient(pClient);
+        NimBLEDevice::deleteClient(client);
        pClient = nullptr;
      }
    }
    #endif
  }
  void pollingBleSensors() {
    if (!Sensors::getAmountByType(Sensors::Type::BLUETOOTH, true)) {
      return;
    }
    if (!NimBLEDevice::isInitialized() && millis() > 5000) {
      Log.sinfoln(FPSTR(L_SENSORS_BLE), F("Initialized"));
      BLEDevice::init("");
@@ -488,47 +460,38 @@ protected:
        continue;
      }
-      const auto address = NimBLEAddress(sSensor.address, 0);
+      auto client = this->getBleClient(sensorId);
-      if (address.isNull()) {
+      if (client == nullptr) {
        continue;
      }
-      auto pClient = this->getBleClient(sensorId);
+      if (!client->isConnected()) {
      if (pClient == nullptr) {
        continue;
      }
      if (pClient->getPeerAddress() != address) {
        if (pClient->isConnected()) {
          if (!pClient->disconnect()) {
            continue;
          }
        }
        pClient->setPeerAddress(address);
      }
      if (!pClient->isConnected()) {
        this->bleSubscribed[sensorId] = false;
        this->bleLastSetDtTime[sensorId] = 0;
-        if (pClient->connect(false, true, true)) {
+        if (client->connect()) {
          Log.sinfoln(
-            FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': trying connecting to %s..."),
+            FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': connected to %s"),
-            sensorId, sSensor.name, pClient->getPeerAddress().toString().c_str()
+            sensorId, sSensor.name, client->getPeerAddress().toString().c_str()
          );
        } else {
          Log.swarningln(
            FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': failed connecting to %s"),
            sensorId, sSensor.name, client->getPeerAddress().toString().c_str()
          );
        }
          continue;
        }
      }
      if (!this->bleSubscribed[sensorId]) {
-        if (this->subscribeToBleDevice(sensorId, pClient)) {
+        if (this->subscribeToBleDevice(sensorId, client)) {
          this->bleSubscribed[sensorId] = true;
        } else {
          this->bleSubscribed[sensorId] = false;
-          pClient->disconnect();
+          client->disconnect();
          continue;
        }
      }
@@ -540,7 +503,7 @@ protected:
        struct tm ti;
        if (getLocalTime(&ti)) {
-          if (this->setDateOnBleSensor(pClient, &ti)) {
+          if (this->setDateOnBleSensor(client, &ti)) {
            Log.sinfoln(
              FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s', successfully set date: %02d.%02d.%04d %02d:%02d:%02d"),
              sensorId, sSensor.name,
@@ -573,28 +536,48 @@ protected:
      return nullptr;
    }
-    if (this->bleClients[sensorId] && this->bleClients[sensorId] != nullptr) {
+    uint8_t addr[6] = {
-      return this->bleClients[sensorId];
+      sSensor.address[0], sSensor.address[1], sSensor.address[2],
      sSensor.address[3], sSensor.address[4], sSensor.address[5]
    };
    const auto address = NimBLEAddress(addr, 0);
    NimBLEClient* pClient = NimBLEDevice::getClientByPeerAddress(address);
    if (pClient == nullptr) {
      pClient = NimBLEDevice::getDisconnectedClient();
    }
-    auto pClient = NimBLEDevice::createClient();
+    if (pClient == nullptr) {
      if (NimBLEDevice::getCreatedClientCount() >= NIMBLE_MAX_CONNECTIONS) {
        return nullptr;
      }
      pClient = NimBLEDevice::createClient();
      if (pClient == nullptr) {
        return nullptr;
      }
-    //pClient->setConnectionParams(BLE_GAP_CONN_ITVL_MS(10), BLE_GAP_CONN_ITVL_MS(100), 10, 150);
+      /**
-    pClient->setConnectTimeout(30000);
+       *  Set initial connection parameters:
-    pClient->setSelfDelete(false, false);
+       *  These settings are safe for 3 clients to connect reliably, can go faster if you have less
-    pClient->setClientCallbacks(new BluetoothClientCallbacks(sensorId), true);
+       *  connections. Timeout should be a multiple of the interval, minimum is 100ms.
       *  Min interval: 12 * 1.25ms = 15, Max interval: 12 * 1.25ms = 15, 0 latency, 1000 * 10ms = 10000ms timeout
       */
      pClient->setConnectionParams(12, 12, 0, 1000);
      pClient->setConnectTimeout(5000);
      pClient->setSelfDelete(false, true);
    }
-    this->bleClients[sensorId] = pClient;
+    if (!pClient->isConnected()) {
      pClient->setPeerAddress(address);
    }
    return pClient;
  }
  bool subscribeToBleDevice(const uint8_t sensorId, NimBLEClient* pClient) {
    auto& sSensor = Sensors::settings[sensorId];
-    auto pAddress = pClient->getPeerAddress().toString();
+    auto pAddress = pClient->getPeerAddress().toString().c_str();
    NimBLERemoteService* pService = nullptr;
    NimBLERemoteCharacteristic* pChar = nullptr;
@@ -605,13 +588,13 @@ protected:
    if (!pService) {
      Log.straceln(
        FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': failed to find env service (%s) on device %s"),
-        sensorId, sSensor.name, serviceUuid.toString().c_str(), pAddress.c_str()
+        sensorId, sSensor.name, serviceUuid.toString().c_str(), pAddress
      );
    } else {
      Log.straceln(
        FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': found env service (%s) on device %s"),
-        sensorId, sSensor.name, serviceUuid.toString().c_str(), pAddress.c_str()
+        sensorId, sSensor.name, serviceUuid.toString().c_str(), pAddress
      );
      // 0x2A6E - Notify temperature x0.01C (pvvx)
@@ -623,7 +606,7 @@ protected:
        if (pChar && (pChar->canNotify() || pChar->canIndicate())) {
          Log.straceln(
            FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': found temp char (%s) in env service on device %s"),
-            sensorId, sSensor.name, charUuid.toString().c_str(), pAddress.c_str()
+            sensorId, sSensor.name, charUuid.toString().c_str(), pAddress
          );
          pChar->unsubscribe();
@@ -678,14 +661,14 @@ protected:
            Log.straceln(
              FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': subscribed to temp char (%s) in env service on device %s"),
              sensorId, sSensor.name,
-              charUuid.toString().c_str(), pAddress.c_str()
+              charUuid.toString().c_str(), pAddress
            );
          } else {
            Log.swarningln(
              FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': failed to subscribe to temp char (%s) in env service on device %s"),
              sensorId, sSensor.name,
-              charUuid.toString().c_str(), pAddress.c_str()
+              charUuid.toString().c_str(), pAddress
            );
          }
        }
@@ -700,7 +683,7 @@ protected:
        if (pChar && (pChar->canNotify() || pChar->canIndicate())) {
          Log.straceln(
            FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': found temp char (%s) in env service on device %s"),
-            sensorId, sSensor.name, charUuid.toString().c_str(), pAddress.c_str()
+            sensorId, sSensor.name, charUuid.toString().c_str(), pAddress
          );
          pChar->unsubscribe();
@@ -755,14 +738,14 @@ protected:
            Log.straceln(
              FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': subscribed to temp char (%s) in env service on device %s"),
              sensorId, sSensor.name,
-              charUuid.toString().c_str(), pAddress.c_str()
+              charUuid.toString().c_str(), pAddress
            );
          } else {
            Log.swarningln(
              FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': failed to subscribe to temp char (%s) in env service on device %s"),
              sensorId, sSensor.name,
-              charUuid.toString().c_str(), pAddress.c_str()
+              charUuid.toString().c_str(), pAddress
            );
          }
        }
@@ -771,7 +754,7 @@ protected:
      if (!tempNotifyCreated) {
        Log.swarningln(
          FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': not found supported temp chars in env service on device %s"),
-          sensorId, sSensor.name, pAddress.c_str()
+          sensorId, sSensor.name, pAddress
        );
        pClient->disconnect();
@@ -789,7 +772,7 @@ protected:
          if (pChar && (pChar->canNotify() || pChar->canIndicate())) {
            Log.straceln(
              FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': found humidity char (%s) in env service on device %s"),
-              sensorId, sSensor.name, charUuid.toString().c_str(), pAddress.c_str()
+              sensorId, sSensor.name, charUuid.toString().c_str(), pAddress
            );
            pChar->unsubscribe();
@@ -844,14 +827,14 @@ protected:
              Log.straceln(
                FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': subscribed to humidity char (%s) in env service on device %s"),
                sensorId, sSensor.name,
-                charUuid.toString().c_str(), pAddress.c_str()
+                charUuid.toString().c_str(), pAddress
              );
            } else {
              Log.swarningln(
                FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': failed to subscribe to humidity char (%s) in env service on device %s"),
                sensorId, sSensor.name,
-                charUuid.toString().c_str(), pAddress.c_str()
+                charUuid.toString().c_str(), pAddress
              );
            }
          }
@@ -860,7 +843,7 @@ protected:
        if (!humidityNotifyCreated) {
          Log.swarningln(
            FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': not found supported humidity chars in env service on device %s"),
-            sensorId, sSensor.name, pAddress.c_str()
+            sensorId, sSensor.name, pAddress
          );
        }
      }
@@ -874,13 +857,13 @@ protected:
      if (!pService) {
        Log.straceln(
          FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': failed to find battery service (%s) on device %s"),
-          sensorId, sSensor.name, serviceUuid.toString().c_str(), pAddress.c_str()
+          sensorId, sSensor.name, serviceUuid.toString().c_str(), pAddress
        );
      } else {
        Log.straceln(
          FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': found battery service (%s) on device %s"),
-          sensorId, sSensor.name, serviceUuid.toString().c_str(), pAddress.c_str()
+          sensorId, sSensor.name, serviceUuid.toString().c_str(), pAddress
        );
        // 0x2A19 - Notify the battery charge level 0..99% (pvvx)
@@ -892,7 +875,7 @@ protected:
          if (pChar && (pChar->canNotify() || pChar->canIndicate())) {
            Log.straceln(
              FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': found battery char (%s) in battery service on device %s"),
-              sensorId, sSensor.name, charUuid.toString().c_str(), pAddress.c_str()
+              sensorId, sSensor.name, charUuid.toString().c_str(), pAddress
            );
            pChar->unsubscribe();
@@ -947,14 +930,14 @@ protected:
              Log.straceln(
                FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': subscribed to battery char (%s) in battery service on device %s"),
                sensorId, sSensor.name,
-                charUuid.toString().c_str(), pAddress.c_str()
+                charUuid.toString().c_str(), pAddress
              );
            } else {
              Log.swarningln(
                FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': failed to subscribe to battery char (%s) in battery service on device %s"),
                sensorId, sSensor.name,
-                charUuid.toString().c_str(), pAddress.c_str()
+                charUuid.toString().c_str(), pAddress
              );
            }
          }
@@ -963,7 +946,7 @@ protected:
        if (!batteryNotifyCreated) {
          Log.swarningln(
            FPSTR(L_SENSORS_BLE), F("Sensor #%hhu '%s': not found supported battery chars in battery service on device %s"),
-            sensorId, sSensor.name, pAddress.c_str()
+            sensorId, sSensor.name, pAddress
          );
        }
      }
--- a/src/Settings.h
+++ b/src/Settings.h
@@ -12,13 +12,13 @@ struct NetworkSettings {
  struct {
    char ssid[33] = DEFAULT_AP_SSID;
    char password[65] = DEFAULT_AP_PASSWORD;
-    uint8_t channel = 6;
+    byte channel = 6;
  } ap;
  struct {
    char ssid[33] = DEFAULT_STA_SSID;
    char password[65] = DEFAULT_STA_PASSWORD;
-    uint8_t channel = 0;
+    byte channel = 0;
  } sta;
 } networkSettings;
@@ -42,7 +42,7 @@ struct Settings {
    } ntp;
    UnitSystem unitSystem = UnitSystem::METRIC;
-    uint8_t statusLedGpio = DEFAULT_STATUS_LED_GPIO;
+    byte statusLedGpio = DEFAULT_STATUS_LED_GPIO;
  } system;
  struct {
@@ -54,9 +54,9 @@ struct Settings {
  struct {
    UnitSystem unitSystem = UnitSystem::METRIC;
-    uint8_t inGpio = DEFAULT_OT_IN_GPIO;
+    byte inGpio = DEFAULT_OT_IN_GPIO;
-    uint8_t outGpio = DEFAULT_OT_OUT_GPIO;
+    byte outGpio = DEFAULT_OT_OUT_GPIO;
-    uint8_t rxLedGpio = DEFAULT_OT_RX_LED_GPIO;
+    byte rxLedGpio = DEFAULT_OT_RX_LED_GPIO;
    uint8_t memberId = 0;
    uint8_t flags = 0;
    float minPower = 0.0f;
@@ -71,14 +71,12 @@ struct Settings {
      bool heatingToCh2 = false;
      bool dhwToCh2 = false;
      bool dhwBlocking = false;
      bool dhwStateAsDhwBlocking = false;
      bool maxTempSyncWithTargetTemp = true;
      bool getMinMaxTemp = true;
      bool ignoreDiagState = false;
      bool autoFaultReset = false;
      bool autoDiagReset = false;
      bool setDateAndTime = false;
      bool alwaysSetIndoorTemp = true;
      bool nativeHeatingControl = false;
      bool immergasFix = false;
    } options;
@@ -104,39 +102,19 @@ struct Settings {
    bool enabled = true;
    bool turbo = false;
    float target = DEFAULT_HEATING_TARGET_TEMP;
    float hysteresis = 0.5f;
    float turboFactor = 7.5f;
-    uint8_t minTemp = DEFAULT_HEATING_MIN_TEMP;
+    byte minTemp = DEFAULT_HEATING_MIN_TEMP;
-    uint8_t maxTemp = DEFAULT_HEATING_MAX_TEMP;
+    byte maxTemp = DEFAULT_HEATING_MAX_TEMP;
    uint8_t maxModulation = 100;
    struct {
      bool enabled = true;
      float value = 0.5f;
      HysteresisAction action = HysteresisAction::DISABLE_HEATING;
    } hysteresis;
    struct {
      uint8_t highTemp = 95;
      uint8_t lowTemp = 90;
    } overheatProtection;
    struct {
      uint8_t lowTemp = 10;
      unsigned short thresholdTime = 600;
    } freezeProtection;
  } heating;
  struct {
    bool enabled = true;
    float target = DEFAULT_DHW_TARGET_TEMP;
-    uint8_t minTemp = DEFAULT_DHW_MIN_TEMP;
+    byte minTemp = DEFAULT_DHW_MIN_TEMP;
-    uint8_t maxTemp = DEFAULT_DHW_MAX_TEMP;
+    byte maxTemp = DEFAULT_DHW_MAX_TEMP;
    uint8_t maxModulation = 100;
    struct {
      uint8_t highTemp = 95;
      uint8_t lowTemp = 90;
    } overheatProtection;
  } dhw;
  struct {
@@ -168,8 +146,7 @@ struct Settings {
  struct {
    bool use = false;
-    uint8_t gpio = DEFAULT_EXT_PUMP_GPIO;
+    byte gpio = DEFAULT_EXT_PUMP_GPIO;
    bool invertState = false;
    unsigned short postCirculationTime = 600;
    unsigned int antiStuckInterval = 2592000;
    unsigned short antiStuckTime = 300;
@@ -178,15 +155,15 @@ struct Settings {
  struct {
    struct {
      bool enabled = false;
-      uint8_t gpio = GPIO_IS_NOT_CONFIGURED;
+      byte gpio = GPIO_IS_NOT_CONFIGURED;
-      bool invertState = false;
+      byte invertState = false;
      unsigned short thresholdTime = 60;
    } input;
    struct {
      bool enabled = false;
-      uint8_t gpio = GPIO_IS_NOT_CONFIGURED;
+      byte gpio = GPIO_IS_NOT_CONFIGURED;
-      bool invertState = false;
+      byte invertState = false;
      unsigned short thresholdTime = 60;
      bool onFault = true;
      bool onLossConnection = true;
@@ -303,7 +280,6 @@ struct Variables {
      bool blocking = false;
      bool enabled = false;
      bool indoorTempControl = false;
      bool overheat = false;
      float setpointTemp = 0.0f;
      float targetTemp = 0.0f;
      float currentTemp = 0.0f;
@@ -316,7 +292,6 @@ struct Variables {
    struct {
      bool enabled = false;
      bool overheat = false;
      float targetTemp = 0.0f;
      float currentTemp = 0.0f;
      float returnTemp = 0.0f;
@@ -337,14 +312,10 @@ struct Variables {
    bool connected = false;
    bool flame = false;
    bool cooling = false;
    float pressure = 0.0f;
    float heatExchangerTemp = 0.0f;
    struct {
      bool active = false;
      uint8_t setpoint = 0;
    } cooling;
    struct {
      bool active = false;
      uint8_t code = 0;
@@ -420,7 +391,6 @@ struct Variables {
    } dhw;
    struct {
      bool active = false;
      bool enabled = false;
      float targetTemp = 0.0f;
      float currentTemp = 0.0f;
--- a/src/defines.h
+++ b/src/defines.h
@@ -163,9 +163,4 @@ enum class UnitSystem : uint8_t {
  IMPERIAL  = 1
 };
 enum class HysteresisAction : uint8_t {
  DISABLE_HEATING = 0,
  SET_ZERO_TARGET = 1
 };
 char buffer[255];
--- a/src/strings.h
+++ b/src/strings.h
@@ -34,11 +34,9 @@ const char L_CASCADE_OUTPUT[]                       PROGMEM = "CASCADE.OUTPUT";
 const char L_EXTPUMP[]                              PROGMEM = "EXTPUMP";
 const char S_ACTION[]                               PROGMEM = "action";
 const char S_ACTIONS[]                              PROGMEM = "actions";
 const char S_ACTIVE[]                               PROGMEM = "active";
 const char S_ADDRESS[]                              PROGMEM = "address";
 const char S_ALWAYS_SET_INDOOR_TEMP[]               PROGMEM = "alwaysSetIndoorTemp";
 const char S_ANTI_STUCK_INTERVAL[]                  PROGMEM = "antiStuckInterval";
 const char S_ANTI_STUCK_TIME[]                      PROGMEM = "antiStuckTime";
 const char S_AP[]                                   PROGMEM = "ap";
@@ -70,7 +68,6 @@ const char S_DATE[]                                 PROGMEM = "date";
 const char S_DEADBAND[]                             PROGMEM = "deadband";
 const char S_DHW[]                                  PROGMEM = "dhw";
 const char S_DHW_BLOCKING[]                         PROGMEM = "dhwBlocking";
 const char S_DHW_STATE_AS_DHW_BLOCKING[]            PROGMEM = "dhwStateAsDhwBlocking";
 const char S_DHW_SUPPORT[]                          PROGMEM = "dhwSupport";
 const char S_DHW_TO_CH2[]                           PROGMEM = "dhwToCh2";
 const char S_DIAG[]                                 PROGMEM = "diag";
@@ -87,7 +84,6 @@ const char S_EXPONENT[]                             PROGMEM = "exponent";
 const char S_EXTERNAL_PUMP[]                        PROGMEM = "externalPump";
 const char S_FACTOR[]                               PROGMEM = "factor";
 const char S_FAULT[]                                PROGMEM = "fault";
 const char S_FREEZE_PROTECTION[]                    PROGMEM = "freezeProtection";
 const char S_FILTERING[]                            PROGMEM = "filtering";
 const char S_FILTERING_FACTOR[]                     PROGMEM = "filteringFactor";
 const char S_FLAGS[]                                PROGMEM = "flags";
@@ -103,7 +99,6 @@ const char S_HEATING[]                              PROGMEM = "heating";
 const char S_HEATING_TO_CH2[]                       PROGMEM = "heatingToCh2";
 const char S_HEATING_STATE_TO_SUMMER_WINTER_MODE[]  PROGMEM = "heatingStateToSummerWinterMode";
 const char S_HIDDEN[]                               PROGMEM = "hidden";
 const char S_HIGH_TEMP[]                            PROGMEM = "highTemp";
 const char S_HOME_ASSISTANT_DISCOVERY[]             PROGMEM = "homeAssistantDiscovery";
 const char S_HOSTNAME[]                             PROGMEM = "hostname";
 const char S_HUMIDITY[]                             PROGMEM = "humidity";
@@ -122,7 +117,6 @@ const char S_I_FACTOR[]                             PROGMEM = "i_factor";
 const char S_I_MULTIPLIER[]                         PROGMEM = "i_multiplier";
 const char S_LOGIN[]                                PROGMEM = "login";
 const char S_LOG_LEVEL[]                            PROGMEM = "logLevel";
 const char S_LOW_TEMP[]                             PROGMEM = "lowTemp";
 const char S_MAC[]                                  PROGMEM = "mac";
 const char S_MASTER[]                               PROGMEM = "master";
 const char S_MAX[]                                  PROGMEM = "max";
@@ -154,8 +148,6 @@ const char S_OPTIONS[]                              PROGMEM = "options";
 const char S_OUTDOOR_TEMP[]                         PROGMEM = "outdoorTemp";
 const char S_OUT_GPIO[]                             PROGMEM = "outGpio";
 const char S_OUTPUT[]                               PROGMEM = "output";
 const char S_OVERHEAT[]                             PROGMEM = "overheat";
 const char S_OVERHEAT_PROTECTION[]                  PROGMEM = "overheatProtection";
 const char S_PASSWORD[]                             PROGMEM = "password";
 const char S_PID[]                                  PROGMEM = "pid";
 const char S_PORT[]                                 PROGMEM = "port";
@@ -193,7 +185,6 @@ const char S_STA[]                                  PROGMEM = "sta";
 const char S_STATE[]                                PROGMEM = "state";
 const char S_STATIC_CONFIG[]                        PROGMEM = "staticConfig";
 const char S_STATUS_LED_GPIO[]                      PROGMEM = "statusLedGpio";
 const char S_SETPOINT[]                             PROGMEM = "setpoint";
 const char S_SETPOINT_TEMP[]                        PROGMEM = "setpointTemp";
 const char S_SUBNET[]                               PROGMEM = "subnet";
 const char S_SUMMER_WINTER_MODE[]                   PROGMEM = "summerWinterMode";
--- a/src/utils.h
+++ b/src/utils.h
@@ -72,7 +72,7 @@ time_t mkgmtime(const struct tm *ptm) {
 inline bool isDigit(const char* ptr) {
  char* endPtr;
-  auto tmp = strtol(ptr, &endPtr, 10);
+  strtol(ptr, &endPtr, 10);
  return *endPtr == 0;
 }
@@ -461,14 +461,12 @@ void settingsToJson(const Settings& src, JsonVariant dst, bool safe = false) {
    otOptions[FPSTR(S_HEATING_TO_CH2)] = src.opentherm.options.heatingToCh2;
    otOptions[FPSTR(S_DHW_TO_CH2)] = src.opentherm.options.dhwToCh2;
    otOptions[FPSTR(S_DHW_BLOCKING)] = src.opentherm.options.dhwBlocking;
    otOptions[FPSTR(S_DHW_STATE_AS_DHW_BLOCKING)] = src.opentherm.options.dhwStateAsDhwBlocking;
    otOptions[FPSTR(S_MAX_TEMP_SYNC_WITH_TARGET_TEMP)] = src.opentherm.options.maxTempSyncWithTargetTemp;
    otOptions[FPSTR(S_GET_MIN_MAX_TEMP)] = src.opentherm.options.getMinMaxTemp;
    otOptions[FPSTR(S_IGNORE_DIAG_STATE)] = src.opentherm.options.ignoreDiagState;
    otOptions[FPSTR(S_AUTO_FAULT_RESET)] = src.opentherm.options.autoFaultReset;
    otOptions[FPSTR(S_AUTO_DIAG_RESET)] = src.opentherm.options.autoDiagReset;
    otOptions[FPSTR(S_SET_DATE_AND_TIME)] = src.opentherm.options.setDateAndTime;
    otOptions[FPSTR(S_ALWAYS_SET_INDOOR_TEMP)] = src.opentherm.options.alwaysSetIndoorTemp;
    otOptions[FPSTR(S_NATIVE_HEATING_CONTROL)] = src.opentherm.options.nativeHeatingControl;
    otOptions[FPSTR(S_IMMERGAS_FIX)] = src.opentherm.options.immergasFix;
@@ -491,22 +489,12 @@ void settingsToJson(const Settings& src, JsonVariant dst, bool safe = false) {
  heating[FPSTR(S_ENABLED)] = src.heating.enabled;
  heating[FPSTR(S_TURBO)] = src.heating.turbo;
  heating[FPSTR(S_TARGET)] = roundf(src.heating.target, 2);
-  heating[FPSTR(S_HYSTERESIS)][FPSTR(S_ENABLED)] = src.heating.hysteresis.enabled;
+  heating[FPSTR(S_HYSTERESIS)] = roundf(src.heating.hysteresis, 3);
  heating[FPSTR(S_HYSTERESIS)][FPSTR(S_VALUE)] = roundf(src.heating.hysteresis.value, 3);
  heating[FPSTR(S_HYSTERESIS)][FPSTR(S_ACTION)] = static_cast<uint8_t>(src.heating.hysteresis.action);
  heating[FPSTR(S_TURBO_FACTOR)] = roundf(src.heating.turboFactor, 3);
  heating[FPSTR(S_MIN_TEMP)] = src.heating.minTemp;
  heating[FPSTR(S_MAX_TEMP)] = src.heating.maxTemp;
  heating[FPSTR(S_MAX_MODULATION)] = src.heating.maxModulation;
  auto heatingOverheatProtection = heating[FPSTR(S_OVERHEAT_PROTECTION)].to<JsonObject>();
  heatingOverheatProtection[FPSTR(S_HIGH_TEMP)] = src.heating.overheatProtection.highTemp;
  heatingOverheatProtection[FPSTR(S_LOW_TEMP)] = src.heating.overheatProtection.lowTemp;
  auto freezeProtection = heating[FPSTR(S_FREEZE_PROTECTION)].to<JsonObject>();
  freezeProtection[FPSTR(S_LOW_TEMP)] = src.heating.freezeProtection.lowTemp;
  freezeProtection[FPSTR(S_THRESHOLD_TIME)] = src.heating.freezeProtection.thresholdTime;
  auto dhw = dst[FPSTR(S_DHW)].to<JsonObject>();
  dhw[FPSTR(S_ENABLED)] = src.dhw.enabled;
  dhw[FPSTR(S_TARGET)] = roundf(src.dhw.target, 1);
@@ -514,10 +502,6 @@ void settingsToJson(const Settings& src, JsonVariant dst, bool safe = false) {
  dhw[FPSTR(S_MAX_TEMP)] = src.dhw.maxTemp;
  dhw[FPSTR(S_MAX_MODULATION)] = src.dhw.maxModulation;
  auto dhwOverheatProtection = dhw[FPSTR(S_OVERHEAT_PROTECTION)].to<JsonObject>();
  dhwOverheatProtection[FPSTR(S_HIGH_TEMP)] = src.dhw.overheatProtection.highTemp;
  dhwOverheatProtection[FPSTR(S_LOW_TEMP)] = src.dhw.overheatProtection.lowTemp;
  auto equitherm = dst[FPSTR(S_EQUITHERM)].to<JsonObject>();
  equitherm[FPSTR(S_ENABLED)] = src.equitherm.enabled;
  equitherm[FPSTR(S_SLOPE)] = roundf(src.equitherm.slope, 3);
@@ -546,7 +530,6 @@ void settingsToJson(const Settings& src, JsonVariant dst, bool safe = false) {
    auto externalPump = dst[FPSTR(S_EXTERNAL_PUMP)].to<JsonObject>();
    externalPump[FPSTR(S_USE)] = src.externalPump.use;
    externalPump[FPSTR(S_GPIO)] = src.externalPump.gpio;
    externalPump[FPSTR(S_INVERT_STATE)] = src.externalPump.invertState;
    externalPump[FPSTR(S_POST_CIRCULATION_TIME)] = roundf(src.externalPump.postCirculationTime / 60, 0);
    externalPump[FPSTR(S_ANTI_STUCK_INTERVAL)] = roundf(src.externalPump.antiStuckInterval / 86400, 0);
    externalPump[FPSTR(S_ANTI_STUCK_TIME)] = roundf(src.externalPump.antiStuckTime / 60, 0);
@@ -941,15 +924,6 @@ bool jsonToSettings(const JsonVariantConst src, Settings& dst, bool safe = false
      }
    }
    if (src[FPSTR(S_OPENTHERM)][FPSTR(S_OPTIONS)][FPSTR(S_DHW_STATE_AS_DHW_BLOCKING)].is<bool>()) {
      bool value = src[FPSTR(S_OPENTHERM)][FPSTR(S_OPTIONS)][FPSTR(S_DHW_STATE_AS_DHW_BLOCKING)].as<bool>();
      if (value != dst.opentherm.options.dhwStateAsDhwBlocking) {
        dst.opentherm.options.dhwStateAsDhwBlocking = value;
        changed = true;
      }
    }
    if (src[FPSTR(S_OPENTHERM)][FPSTR(S_OPTIONS)][FPSTR(S_MAX_TEMP_SYNC_WITH_TARGET_TEMP)].is<bool>()) {
      bool value = src[FPSTR(S_OPENTHERM)][FPSTR(S_OPTIONS)][FPSTR(S_MAX_TEMP_SYNC_WITH_TARGET_TEMP)].as<bool>();
@@ -1004,15 +978,6 @@ bool jsonToSettings(const JsonVariantConst src, Settings& dst, bool safe = false
      }
    }
    if (src[FPSTR(S_OPENTHERM)][FPSTR(S_OPTIONS)][FPSTR(S_ALWAYS_SET_INDOOR_TEMP)].is<bool>()) {
      bool value = src[FPSTR(S_OPENTHERM)][FPSTR(S_OPTIONS)][FPSTR(S_ALWAYS_SET_INDOOR_TEMP)].as<bool>();
      if (value != dst.opentherm.options.alwaysSetIndoorTemp) {
        dst.opentherm.options.alwaysSetIndoorTemp = value;
        changed = true;
      }
    }
    if (src[FPSTR(S_OPENTHERM)][FPSTR(S_OPTIONS)][FPSTR(S_NATIVE_HEATING_CONTROL)].is<bool>()) {
      bool value = src[FPSTR(S_OPENTHERM)][FPSTR(S_OPTIONS)][FPSTR(S_NATIVE_HEATING_CONTROL)].as<bool>();
@@ -1326,41 +1291,15 @@ bool jsonToSettings(const JsonVariantConst src, Settings& dst, bool safe = false
    }
  }
-  if (src[FPSTR(S_HEATING)][FPSTR(S_HYSTERESIS)][FPSTR(S_ENABLED)].is<bool>()) {
+  if (!src[FPSTR(S_HEATING)][FPSTR(S_HYSTERESIS)].isNull()) {
-    bool value = src[FPSTR(S_HEATING)][FPSTR(S_HYSTERESIS)][FPSTR(S_ENABLED)].as<bool>();
+    float value = src[FPSTR(S_HEATING)][FPSTR(S_HYSTERESIS)].as<float>();
-    if (value != dst.heating.hysteresis.enabled) {
+    if (value >= 0.0f && value <= 15.0f && fabsf(value - dst.heating.hysteresis) > 0.0001f) {
-      dst.heating.hysteresis.enabled = value;
+      dst.heating.hysteresis = roundf(value, 2);
      changed = true;
    }
  }
  if (!src[FPSTR(S_HEATING)][FPSTR(S_HYSTERESIS)][FPSTR(S_VALUE)].isNull()) {
    float value = src[FPSTR(S_HEATING)][FPSTR(S_HYSTERESIS)][FPSTR(S_VALUE)].as<float>();
    if (value >= 0.0f && value <= 15.0f && fabsf(value - dst.heating.hysteresis.value) > 0.0001f) {
      dst.heating.hysteresis.value = roundf(value, 2);
      changed = true;
    }
  }
  if (!src[FPSTR(S_HEATING)][FPSTR(S_HYSTERESIS)][FPSTR(S_ACTION)].isNull()) {
    uint8_t value = src[FPSTR(S_HEATING)][FPSTR(S_HYSTERESIS)][FPSTR(S_ACTION)].as<uint8_t>();
    switch (value) {
      case static_cast<uint8_t>(HysteresisAction::DISABLE_HEATING):
      case static_cast<uint8_t>(HysteresisAction::SET_ZERO_TARGET):
        if (static_cast<uint8_t>(dst.heating.hysteresis.action) != value) {
         dst.heating.hysteresis.action = static_cast<HysteresisAction>(value);
          changed = true;
        }
        break;
      default:
        break;
    }
  }
  if (!src[FPSTR(S_HEATING)][FPSTR(S_TURBO_FACTOR)].isNull()) {
    float value = src[FPSTR(S_HEATING)][FPSTR(S_TURBO_FACTOR)].as<float>();
@@ -1373,7 +1312,7 @@ bool jsonToSettings(const JsonVariantConst src, Settings& dst, bool safe = false
  if (!src[FPSTR(S_HEATING)][FPSTR(S_MIN_TEMP)].isNull()) {
    unsigned char value = src[FPSTR(S_HEATING)][FPSTR(S_MIN_TEMP)].as<unsigned char>();
-    if (value != dst.heating.minTemp && value >= vars.slave.heating.minTemp && value < vars.slave.heating.maxTemp && value != dst.heating.maxTemp) {
+    if (value != dst.heating.minTemp && value >= vars.slave.heating.minTemp && value < vars.slave.heating.maxTemp && value != dst.heating.minTemp) {
      dst.heating.minTemp = value;
      changed = true;
    }
@@ -1382,7 +1321,7 @@ bool jsonToSettings(const JsonVariantConst src, Settings& dst, bool safe = false
  if (!src[FPSTR(S_HEATING)][FPSTR(S_MAX_TEMP)].isNull()) {
    unsigned char value = src[FPSTR(S_HEATING)][FPSTR(S_MAX_TEMP)].as<unsigned char>();
-    if (value != dst.heating.maxTemp && value > vars.slave.heating.minTemp && value <= vars.slave.heating.maxTemp && value != dst.heating.minTemp) {
+    if (value != dst.heating.maxTemp && value > vars.slave.heating.minTemp && value <= vars.slave.heating.maxTemp && value != dst.heating.maxTemp) {
      dst.heating.maxTemp = value;
      changed = true;
    }
@@ -1403,49 +1342,6 @@ bool jsonToSettings(const JsonVariantConst src, Settings& dst, bool safe = false
    }
  }
  if (!src[FPSTR(S_HEATING)][FPSTR(S_OVERHEAT_PROTECTION)][FPSTR(S_HIGH_TEMP)].isNull()) {
    unsigned char value = src[FPSTR(S_HEATING)][FPSTR(S_OVERHEAT_PROTECTION)][FPSTR(S_HIGH_TEMP)].as<unsigned char>();
    if (isValidTemp(value, dst.system.unitSystem, 0.0f, 100.0f) && value != dst.heating.overheatProtection.highTemp) {
      dst.heating.overheatProtection.highTemp = value;
      changed = true;
    }
  }
  if (!src[FPSTR(S_HEATING)][FPSTR(S_OVERHEAT_PROTECTION)][FPSTR(S_LOW_TEMP)].isNull()) {
    unsigned char value = src[FPSTR(S_HEATING)][FPSTR(S_OVERHEAT_PROTECTION)][FPSTR(S_LOW_TEMP)].as<unsigned char>();
    if (isValidTemp(value, dst.system.unitSystem, 0.0f, 99.0f) && value != dst.heating.overheatProtection.lowTemp) {
      dst.heating.overheatProtection.lowTemp = value;
      changed = true;
    }
  }
  if (dst.heating.overheatProtection.highTemp < dst.heating.overheatProtection.lowTemp) {
    dst.heating.overheatProtection.highTemp = dst.heating.overheatProtection.lowTemp;
    changed = true;
  }
  if (!src[FPSTR(S_HEATING)][FPSTR(S_FREEZE_PROTECTION)][FPSTR(S_LOW_TEMP)].isNull()) {
    unsigned short value = src[FPSTR(S_HEATING)][FPSTR(S_FREEZE_PROTECTION)][FPSTR(S_LOW_TEMP)].as<uint8_t>();
    if (isValidTemp(value, dst.system.unitSystem, 1, 30) && value != dst.heating.freezeProtection.lowTemp) {
      dst.heating.freezeProtection.lowTemp = value;
      changed = true;
    }
  }
  if (!src[FPSTR(S_HEATING)][FPSTR(S_FREEZE_PROTECTION)][FPSTR(S_THRESHOLD_TIME)].isNull()) {
    unsigned short value = src[FPSTR(S_HEATING)][FPSTR(S_FREEZE_PROTECTION)][FPSTR(S_THRESHOLD_TIME)].as<unsigned short>();
    if (value >= 30 && value <= 1800) {
      if (value != dst.heating.freezeProtection.thresholdTime) {
        dst.heating.freezeProtection.thresholdTime = value;
        changed = true;
      }
    }
  }
  // dhw
  if (src[FPSTR(S_DHW)][FPSTR(S_ENABLED)].is<bool>()) {
@@ -1489,29 +1385,6 @@ bool jsonToSettings(const JsonVariantConst src, Settings& dst, bool safe = false
    }
  }
  if (!src[FPSTR(S_DHW)][FPSTR(S_OVERHEAT_PROTECTION)][FPSTR(S_HIGH_TEMP)].isNull()) {
    unsigned char value = src[FPSTR(S_DHW)][FPSTR(S_OVERHEAT_PROTECTION)][FPSTR(S_HIGH_TEMP)].as<unsigned char>();
    if (isValidTemp(value, dst.system.unitSystem, 0.0f, 100.0f) && value != dst.dhw.overheatProtection.highTemp) {
      dst.dhw.overheatProtection.highTemp = value;
      changed = true;
    }
  }
  if (!src[FPSTR(S_DHW)][FPSTR(S_OVERHEAT_PROTECTION)][FPSTR(S_LOW_TEMP)].isNull()) {
    unsigned char value = src[FPSTR(S_DHW)][FPSTR(S_OVERHEAT_PROTECTION)][FPSTR(S_LOW_TEMP)].as<unsigned char>();
    if (isValidTemp(value, dst.system.unitSystem, 0.0f, 99.0f) && value != dst.dhw.overheatProtection.lowTemp) {
      dst.dhw.overheatProtection.lowTemp = value;
      changed = true;
    }
  }
  if (dst.dhw.overheatProtection.highTemp < dst.dhw.overheatProtection.lowTemp) {
    dst.dhw.overheatProtection.highTemp = dst.dhw.overheatProtection.lowTemp;
    changed = true;
  }
  if (!safe) {
    // external pump
@@ -1541,15 +1414,6 @@ bool jsonToSettings(const JsonVariantConst src, Settings& dst, bool safe = false
      }
    }
    if (src[FPSTR(S_EXTERNAL_PUMP)][FPSTR(S_INVERT_STATE)].is<bool>()) {
      bool value = src[FPSTR(S_EXTERNAL_PUMP)][FPSTR(S_INVERT_STATE)].as<bool>();
      if (value != dst.externalPump.invertState) {
        dst.externalPump.invertState = value;
        changed = true;
      }
    }
    if (!src[FPSTR(S_EXTERNAL_PUMP)][FPSTR(S_POST_CIRCULATION_TIME)].isNull()) {
      unsigned short value = src[FPSTR(S_EXTERNAL_PUMP)][FPSTR(S_POST_CIRCULATION_TIME)].as<unsigned short>();
@@ -1952,7 +1816,7 @@ bool jsonToSensorSettings(const uint8_t sensorId, const JsonVariantConst src, Se
  // gpio
  if (!src[FPSTR(S_GPIO)].isNull()) {
-    if (dst.type != Sensors::Type::DALLAS_TEMP && dst.type != Sensors::Type::NTC_10K_TEMP) {
+    if (dst.type != Sensors::Type::DALLAS_TEMP && dst.type == Sensors::Type::BLUETOOTH && dst.type == Sensors::Type::NTC_10K_TEMP) {
      if (dst.gpio != GPIO_IS_NOT_CONFIGURED) {
        dst.gpio = GPIO_IS_NOT_CONFIGURED;
        changed = true;
@@ -1988,20 +1852,12 @@ bool jsonToSensorSettings(const uint8_t sensorId, const JsonVariantConst src, Se
      );
      if (parsed == 8) {
-        for (uint8_t i = 0; i < parsed; i++) {
+        for (uint8_t i = 0; i < 8; i++) {
          if (dst.address[i] != tmp[i]) {
            dst.address[i] = tmp[i];
            changed = true;
          }
        }
      } else {
        // reset
        for (uint8_t i = 0; i < sizeof(dst.address); i++) {
          dst.address[i] = 0x00;
        }
        changed = true;
      }
    } else if (dst.type == Sensors::Type::BLUETOOTH) {
@@ -2014,20 +1870,12 @@ bool jsonToSensorSettings(const uint8_t sensorId, const JsonVariantConst src, Se
      );
      if (parsed == 6) {
-        for (uint8_t i = 0; i < parsed; i++) {
+        for (uint8_t i = 0; i < 6; i++) {
          if (dst.address[i] != tmp[i]) {
            dst.address[i] = tmp[i];
            changed = true;
          }
        }
      } else {
        // reset
        for (uint8_t i = 0; i < sizeof(dst.address); i++) {
          dst.address[i] = 0x00;
        }
        changed = true;
      }
    }
  }
@@ -2134,10 +1982,7 @@ void varsToJson(const Variables& src, JsonVariant dst) {
  slave[FPSTR(S_PROTOCOL_VERSION)] = src.slave.appVersion;
  slave[FPSTR(S_CONNECTED)] = src.slave.connected;
  slave[FPSTR(S_FLAME)] = src.slave.flame;
-
+  slave[FPSTR(S_COOLING)] = src.slave.cooling;
  auto sCooling = slave[FPSTR(S_COOLING)].to<JsonObject>();
  sCooling[FPSTR(S_ACTIVE)] = src.slave.cooling.active;
  sCooling[FPSTR(S_SETPOINT)] = src.slave.cooling.setpoint;
  auto sModulation = slave[FPSTR(S_MODULATION)].to<JsonObject>();
  sModulation[FPSTR(S_MIN)] = src.slave.modulation.min;
@@ -2171,7 +2016,6 @@ void varsToJson(const Variables& src, JsonVariant dst) {
  mHeating[FPSTR(S_ENABLED)] = src.master.heating.enabled;
  mHeating[FPSTR(S_BLOCKING)] = src.master.heating.blocking;
  mHeating[FPSTR(S_INDOOR_TEMP_CONTROL)] = src.master.heating.indoorTempControl;
  mHeating[FPSTR(S_OVERHEAT)] = src.master.heating.overheat;
  mHeating[FPSTR(S_SETPOINT_TEMP)] = roundf(src.master.heating.setpointTemp, 2);
  mHeating[FPSTR(S_TARGET_TEMP)] = roundf(src.master.heating.targetTemp, 2);
  mHeating[FPSTR(S_CURRENT_TEMP)] = roundf(src.master.heating.currentTemp, 2);
@@ -2183,7 +2027,6 @@ void varsToJson(const Variables& src, JsonVariant dst) {
  auto mDhw = master[FPSTR(S_DHW)].to<JsonObject>();
  mDhw[FPSTR(S_ENABLED)] = src.master.dhw.enabled;
  mDhw[FPSTR(S_OVERHEAT)] = src.master.dhw.overheat;
  mDhw[FPSTR(S_TARGET_TEMP)] = roundf(src.master.dhw.targetTemp, 2);
  mDhw[FPSTR(S_CURRENT_TEMP)] = roundf(src.master.dhw.currentTemp, 2);
  mDhw[FPSTR(S_RETURN_TEMP)] = roundf(src.master.dhw.returnTemp, 2);
--- a/src_data/locales/cn.json
+++ b/src_data/locales/cn.json
@@ -1,533 +0,0 @@
 {
  "values": {
    "logo": "OpenTherm Gateway",
    "nav": {
      "license": "授权许可",
      "source": "源代码",
      "help": "帮助",
      "issues": "问题与反馈",
      "releases": "发行版"
    },
    "dbm": "dBm",
    "kw": "kW",
    "time": {
      "days": "天",
      "hours": "小时",
      "min": "分",
      "sec": "秒"
    },
    "button": {
      "upgrade": "固件升级",
      "restart": "重启",
      "save": "保存",
      "saved": "已保存",
      "refresh": "刷新",
      "restore": "恢复",
      "restored": "已恢复",
      "backup": "备份",
      "wait": "请等待...",
      "uploading": "上传中...",
      "success": "成功",
      "error": "错误"
    },
    "index": {
      "title": "OpenTherm Gateway",
      "section": {
        "network": "网络",
        "system": "系统"
      },
      "system": {
        "build": {
          "title": "Build",
          "version": "固件版本",
          "date": "日期",
          "core": "内核版本",
          "sdk": "SDK"
        },
        "uptime": "运行时间",
        "memory": {
          "title": "可用内存",
          "maxFreeBlock": "max free block",
          "min": "min"
        },
        "board": "开发板",
        "chip": {
          "model": "芯片",
          "cores": "核心数",
          "freq": "频率"
        },
        "flash": {
          "size": "闪存容量",
          "realSize": "实际容量"
        },
        "lastResetReason": "上次重置原因"
      }
    },
    "dashboard": {
      "name": "仪表盘",
      "title": "仪表盘 - OpenTherm Gateway",
      "section": {
        "control": "调节",
        "states": "状态",
        "sensors": "传感器",
        "diag": "OpenTherm 诊断"
      },
      "thermostat": {
        "heating": "供暖",
        "dhw": "生活热水",
        "temp.current": "当前温度",
        "enable": "启用",
        "turbo": "Turbo 模式"
      },
      "notify": {
        "fault": {
          "title": "锅炉报警状态已激活!",
          "note": "建议检查锅炉并查看说明书对应的报警代码:"
        },
        "diag": {
          "title": "锅炉诊断状态已激活!",
          "note": "锅炉可能需要检查，建议查看说明书对应的诊断代码:"
        },
        "reset": "点击复位"
      },
      "states": {
        "mNetworkConnected": "网络连接状态",
        "mMqttConnected": "MQTT服务器连接状态",
        "mEmergencyState": "应急模式",
        "mExtPumpState": "外置循环泵",
        "mCascadeControlInput": "Cascade 控制 (input)",
        "mCascadeControlOutput": "Cascade 控制 (output)",
        "sConnected": "OpenTherm 通讯状态",
        "sFlame": "火焰",
        "sCoolingActive": "制冷",
        "sCoolingSetpoint": "冷却设定点",
        "sFaultActive": "报警状态",
        "sFaultCode": "报警代码",
        "sDiagActive": "诊断状态",
        "sDiagCode": "诊断代码",
        "mHeatEnabled": "供暖功能已启用",
        "mHeatBlocking": "供暖",
        "mHeatOverheat": "供暖超热保护",
        "sHeatActive": "供暖激活状态",
        "mHeatSetpointTemp": "供暖供水设定温度",
        "mHeatTargetTemp": "供暖供水目标温度",
        "mHeatCurrTemp": "供暖当前供水温度",
        "mHeatRetTemp": "供暖回水温度",
        "mHeatIndoorTemp": "供暖，室内温度",
        "mHeatOutdoorTemp": "供暖，室外温度",
        "mDhwEnabled": "生活热水功能已启用",
        "mDhwOverheat": "生活热水超热保护",
        "sDhwActive": "生活热水激活",
        "mDhwTargetTemp": "生活热水目标温度",
        "mDhwCurrTemp": "生活热水当前出水温度",
        "mDhwRetTemp": "生活热水回水温度"
      },
      "sensors": {
        "values": {
          "temp": "温度",
          "humidity": "湿度",
          "battery": "电量",
          "rssi": "RSSI"
        }
      }
    },
    "network": {
      "title": "网络 - OpenTherm Gateway",
      "name": "网络设置",
      "section": {
        "static": "静态设置",
        "availableNetworks": "可用网络",
        "staSettings": "WiFi 设置",
        "apSettings": "AP 设置"
      },
      "scan": {
        "pos": "#",
        "info": "Info"
      },
      "wifi": {
        "ssid": "SSID",
        "password": "密码",
        "channel": "频道",
        "signal": "信号强度",
        "connected": "已连接"
      },
      "params": {
        "hostname": "Hostname",
        "dhcp": "自动 (DHCP)",
        "mac": "物理地址 (MAC)",
        "ip": "IP",
        "subnet": "子网掩码",
        "gateway": "网关",
        "dns": "DNS 服务器"
      },
      "sta": {
        "channel.note": "自动选择设置为0"
      }
    },
    "sensors": {
      "title": "传感器设置 - OpenTherm Gateway",
      "name": "传感器设置",
      "enabled": "启用",
      "sensorName": {
        "title": "传感器名称",
        "note": "只能包含：a-z、A-Z、0-9、下划线和空格"
      },
      "purpose": "用途",
      "purposes": {
        "outdoorTemp": "室外温度",
        "indoorTemp": "室内温度",
        "heatTemp": "供暖，温度",
        "heatRetTemp": "供暖回水温度",
        "dhwTemp": "生活热水温度",
        "dhwRetTemp": "生活热水回水温度",
        "dhwFlowRate": "生活热水水流量",
        "exhaustTemp": "烟气温度",
        "modLevel": "Modulation level (%)",
        "number": "Number (raw)",
        "powerFactor": "功率 (%)",
        "power": "功率(kW)",
        "fanSpeed": "风机转速",
        "co2": "CO2",
        "pressure": "压力",
        "humidity": "湿度",
        "temperature": "温度",
        "notConfigured": "未配置"
      },
      "type": "类型/来源",
      "types": {
        "otOutdoorTemp": "OpenTherm, outdoor temp",
        "otHeatTemp": "OpenTherm, heating, temp",
        "otHeatRetTemp": "OpenTherm, heating, return temp",
        "otDhwTemp": "OpenTherm, DHW, temperature",
        "otDhwTemp2": "OpenTherm, DHW, temperature 2",
        "otDhwFlowRate": "OpenTherm, DHW, flow rate",
        "otCh2Temp": "OpenTherm, channel 2, temp",
        "otExhaustTemp": "OpenTherm, exhaust temp",
        "otHeatExchangerTemp": "OpenTherm, heat exchanger temp",
        "otPressure": "OpenTherm, pressure",
        "otModLevel": "OpenTherm, modulation level",
        "otCurrentPower": "OpenTherm, current power",
        "otExhaustCo2": "OpenTherm, exhaust CO2",
        "otExhaustFanSpeed": "OpenTherm, exhaust fan speed",
        "otSupplyFanSpeed": "OpenTherm, supply fan speed",
        "otSolarStorageTemp": "OpenTherm, solar storage temp",
        "otSolarCollectorTemp": "OpenTherm, solar collector temp",
        "otFanSpeedSetpoint": "OpenTherm, setpoint fan speed",
        "otFanSpeedCurrent": "OpenTherm, current fan speed",
        "otBurnerStarts": "OpenTherm, number of burner starts",
        "otDhwBurnerStarts": "OpenTherm, number of burner starts (DHW)",
        "otHeatingPumpStarts": "OpenTherm, number of pump starts (heating)",
        "otDhwPumpStarts": "OpenTherm, number of pump starts (DHW)",
        "otBurnerHours": "OpenTherm, number of burner operating hours",
        "otDhwBurnerHours": "OpenTherm, number of burner operating hours (DHW)",
        "otHeatingPumpHours": "OpenTherm, number of pump operating hours (heating)",
        "otDhwPumpHours": "OpenTherm, number of pump operating hours (DHW)",
        "ntcTemp": "NTC 传感器",
        "dallasTemp": "DALLAS 传感器",
        "bluetooth": "BLE 传感器",
        "heatSetpointTemp": "Heating, setpoint temp",
        "manual": "通过 MQTT/API 手动配置",
        "notConfigured": "未配置"
      },
      "gpio": "GPIO",
      "address": {
        "title": "传感器地址",
        "note": "如需自动检测DALLAS传感器，请保持默认设置；如需连接BLE设备，则需提供MAC地址"
      },
      "correction": {
        "desc": "数值校正",
        "offset": "补偿值（偏移量）",
        "factor": "Multiplier"
      },
      "filtering": {
        "desc": "数值滤波",
        "enabled": {
          "title": "启用滤波",
          "note": "如果图表中有大量尖锐的噪声，此功能会很有用。使用的滤波器是 \"滑动平均滤波器\"."
        },
        "factor": {
          "title": "滤波系数",
          "note": "数值越低，数值变化越平滑且响应越滞后"
        }
      }
    },
    "settings": {
      "title": "设置 - OpenTherm Gateway",
      "name": "设置",
      "section": {
        "portal": "Portal 设置",
        "system": "系统设置",
        "diag": "诊断",
        "heating": "供热设置",
        "dhw": "生活热水设置",
        "emergency": "应急模式设置",
        "equitherm": "气候补偿设置",
        "pid": "PID 参数设置",
        "ot": "OpenTherm协议设置",
        "mqtt": "MQTT 服务器设置",
        "extPump": "外置循环泵设置",
        "cascadeControl": "Cascade 级联控制设置"
      },
      "enable": "启用",
      "note": {
        "restart": "更改这些设置后，必须重启设备以使变更生效",
        "blankNotUse": "空白 - 未使用",
        "bleDevice": "BLE设备仅支持搭载BLE功能的特定ESP32开发板使用!"
      },
      "temp": {
        "min": "最低温度",
        "max": "最高温度"
      },
      "maxModulation": "最大调制范围",
      "ohProtection": {
        "title": "超温保护",
        "desc": "<b>注意：</b> 当锅炉内置过热保护失效或工作异常导致系统超温时，此功能可提供额外保护。如需禁用，请将<b>最高温度</b>和<b>最低温度</b>均设为0。",
        "highTemp": {
          "title": "高温阈值",
          "note": "触发燃烧器强制关闭的阈值温度"
        },
        "lowTemp": {
          "title": "低温阈值",
          "note": "燃烧器重新启动的阈值温度"
        }
      },
      "freezeProtection": {
        "title": "防冻保护",
        "desc": "当热媒或室内温度在<b>等待时间</b> 内降至<b>低温阈值</b>以下时，系统将强制启动加热功能。",
        "lowTemp": "低温阈值",
        "thresholdTime": "等待时间<small>(秒)</small>"
      },
      "portal": {
        "login": "登录",
        "password": "密码",
        "auth": "需身份验证",
        "mdns": "使用 mDNS"
      },
      "system": {
        "unit": "单位",
        "metric": "公制 <small>(摄氏度、升、巴)</small>",
        "imperial": "英制 <small>(华氏度、加仑、psi)</small>",
        "statusLedGpio": "状态指示灯GPIO引脚",
        "logLevel": "日志级别",
        "serial": {
          "enable": "启用串口",
          "baud": "串口波特率"
        },
        "telnet": {
          "enable": "启用 Telnet",
          "port": {
            "title": "Telnet 端口",
            "note": "默认值：23"
          }
        },
        "ntp": {
          "server": "NTP服务器",
          "timezone": "时区",
          "timezonePresets": "选择预设配置..."
        }
      },
      "heating": {
        "hyst": {
          "title": "滞回",
          "desc": "滞回有助于维持设定的室内温度（在使用«Equitherm»和/或«PID»时）。强制禁用加热当<code>current indoor > target + value</code>，启用加热当<code>current indoor < (target - value)</code>。",
          "value": "值 <small>(以度为单位)</small>",
          "action": {
            "title": "行动",
            "disableHeating": "禁用加热",
            "set0target": "设置空目标"
          }
        },
        "turboFactor": "Turbo 模式系数"
      },
      "emergency": {
        "desc": "紧急模式会在以下情况自动激活（当PID或气候补偿无法计算热媒设定值时）：<br />启用气候补偿但室外温度传感器断开连接；<br />启用PID或 OpenTherm 选项中启用<i>原生供暖控制</i>但室内温度传感器断开连接。<br /><b>注意：</b> 网络故障或MQTT 服务器连接故障时，类型为<i>通过MQTT/API手动控制<i>的传感器将显示为断开连接状态。",
        "target": {
          "title": "目标温度",
          "note": "<b>重要提示：</b> 若启用OpenTherm选项 <i>«原生供暖控制»</i>，此处设定值为<u>目标室内温度</u>；<br />其他所有情况下，此处设定值为 <u>目标热媒出水温度</u>."
        },
        "treshold": "阈值时间 <small>(秒)</small>"
      },
      "equitherm": {
        "slope": {
          "title": "斜率",
          "note": "热损失补偿。主要调谐参数。"
        },
        "exponent": {
          "title": "指数",
          "note": "散热器效率。典型值：<code>1.1</code> - 地板采暖，<code>1.2</code> - 铸铁，<code>1.3</code> - 面板散热器，<code>1.4</code> - 对流器。"
        },
        "shift": {
          "title": "偏移",
          "note": "补偿额外热损失（例如，在管道中）或额外热源。"
        },
        "targetDiffFactor": {
          "title": "T 因子",
          "note": "如果启用 PID，则不使用。将目标和当前室内温度之间的差值添加到设定点：<code>setpoint = setpoint + ((target - indoor) * T)</code>。"
        },
        "chart": {
          "targetTemp": "目标室内温度",
          "setpointTemp": "热载体温度",
          "outdoorTemp": "室外温度"
        }
      },
      "pid": {
        "p": "P 系数",
        "i": "I 系数",
        "d": "D 系数",
        "dt": "DT <small>以秒为单位</small>",
        "limits": {
          "title": "Limits",
          "note": "<b>重要提示：</b> When using «Equitherm» and «PID» at the same time, the min and max temperatures limit the influence on the «Equitherm» result temperature.<br />Thus, if the min temperature is set to -15 and the max temperature is set to 15, then the final heat carrier setpoint will be from <code>equitherm_result - 15</code> to <code>equitherm_result + 15</code>."
        },
        "deadband": {
          "title": "Deadband",
          "note": "Deadband is a range around the target temperature where PID regulation becomes less active. Within this range, the algorithm can reduce intensity or pause adjustments to avoid overreacting to small fluctuations.<br /><br />For instance, with a target temperature of 22°, a lower threshold of 1.0, and an upper threshold of 0.5, the deadband operates between 21° and 22.5°. If the I coefficient is 0.0005 and the I multiplier is 0.05, then within the deadband, the I coefficient becomes: <code>0.0005 * 0.05 = 0.000025</code>",
          "p_multiplier": "Multiplier for P factor",
          "i_multiplier": "Multiplier for I factor",
          "d_multiplier": "Multiplier for D factor",
          "thresholdHigh": "Threshold high",
          "thresholdLow": "Threshold low"
        }
      },
      "ot": {
        "advanced": "高级设置",
        "inGpio": "In GPIO",
        "outGpio": "Out GPIO",
        "ledGpio": "RX LED GPIO",
        "memberId": "主设备成员 ID",
        "flags": "主设备标志",
        "minPower": {
          "title": "最小锅炉功率 <small>(kW)</small>",
          "note": "该值对应锅炉0-1%的调制水平，通常在锅炉参数设置中的\"最小有效热输出\"。"
        },
        "maxPower": {
          "title": "最大锅炉功率 <small>(kW)</small>",
          "note": "<b>0</b> - 自动检测，通常在锅炉参数设置中的\"最大有效热输出\"。 "
        },
        "options": {
          "title": "选项（附加设置）",
          "desc": "附加设置选项可调整锅炉的运行逻辑。由于协议未完整记录所有选项，同一选项在不同锅炉上可能产生不同效果。<br /><b>注意：</b>若系统运行正常，无需修改设置。",
          "dhwSupport": "生活热水支持",
          "coolingSupport": "制冷支持",
          "summerWinterMode": "夏季/冬季模式",
          "heatingStateToSummerWinterMode": "以供暖状态作为夏季/冬季模式",
          "ch2AlwaysEnabled": "CH2 始终启用",
          "heatingToCh2": "将供暖同步至 CH2",
          "dhwToCh2": "将生活热水同步至 CH2",
          "dhwBlocking": "生活热水锁定",
          "dhwStateAsDhwBlocking": "以生活热水状态作为生活热水锁定依据",
          "maxTempSyncWithTargetTemp": "将最高供暖温度与目标温度同步",
          "getMinMaxTemp": "从锅炉获取最小/最大温度参数",
          "ignoreDiagState": "忽略诊断状态",
          "autoFaultReset": "自动报警复位 <small>(不推荐！)</small>",
          "autoDiagReset": "自动诊断复位 <small>(不推荐！)</small>",
          "setDateAndTime": "同步设置锅炉日期与时间",
          "immergasFix": "针对Immergas锅炉的兼容性修复"
        },
        "nativeHeating": {
          "title": "原生锅炉供暖控制",
          "note": "<u>注意：</u> 仅适用于锅炉需接收目标室温并自主调节载热介质温度的场景，与固件中的PID及Equithermq气候补偿功能不兼容。"
        }
      },
      "mqtt": {
        "homeAssistantDiscovery": "Home Assistant 自动发现",
        "server": "服务器地址",
        "port": "端口",
        "user": "用户名",
        "password": "密码",
        "prefix": "Prefix 前缀",
        "interval": "发布间隔 <small>(秒)</small>"
      },
      "extPump": {
        "use": "使用外置循环泵",
        "gpio": "继电器 GPIO引脚",
        "invertState": "切换 GPIO 状态",
        "postCirculationTime": "后循环时间 <small>(分钟)</small>",
        "antiStuckInterval": "防卡死间隔时间<small>(天)</small>",
        "antiStuckTime": "防卡死运行时长<small>(分钟)</small>"
      },
      "cascadeControl": {
        "input": {
          "desc": "仅当另一台锅炉发生故障时启用本锅炉加热。另一台锅炉的控制器需在故障发生时切换GPIO输入状态以触发本功能。",
          "enable": "启用 input",
          "gpio": "GPIO",
          "invertState": "切换 GPIO 状态",
          "thresholdTime": "状态变化阈值时间<small>(秒)</small>"
        },
        "output": {
          "desc": "可通过<u>继电器</u>控制另一台锅炉的启停。",
          "enable": "启用 output",
          "gpio": "GPIO",
          "invertState": "切换 GPIO 状态",
          "thresholdTime": "状态变化阈值时间 <small>(秒)</small>",
          "events": {
            "desc": "事件",
            "onFault": "当故障状态激活时",
            "onLossConnection": "当OpenTherm连接中断时",
            "onEnabledHeating": "当供暖功能启用时"
          }
        }
      }
    },
    "upgrade": {
      "title": "固件升级 - OpenTherm Gateway",
      "name": "固件升级",
      "section": {
        "backupAndRestore": "备份与恢复",
        "backupAndRestore.desc": "本功能支持备份和恢复全部设置",
        "upgrade": "升级",
        "upgrade.desc": "本模块支持升级设备的固件与系统文件。<br />可从以下地址下载最新版本 <a href=\"https://github.com/Laxilef/OTGateway/releases\" target=\"_blank\">Releases page</a> 。" 
      },
      "note": {
        "disclaimer1": "升级系统文件成功后，所有设置将恢复为默认值！升级前请务必备份配置。",
        "disclaimer2": "升级成功后，设备将在15秒后自动重启。"
      },
      "settingsFile": "设置文件",
      "fw": "Firmware",
      "fs": "Filesystem"
    }
  }
 }
--- a/src_data/locales/en.json
+++ b/src_data/locales/en.json
@@ -109,8 +109,7 @@
        "sConnected": "OpenTherm connection",
        "sFlame": "Flame",
-        "sCoolingActive": "Cooling",
+        "sCooling": "Cooling",
        "sCoolingSetpoint": "Cooling setpoint",
        "sFaultActive": "Fault",
        "sFaultCode": "Fault code",
        "sDiagActive": "Diagnostic",
@@ -118,7 +117,6 @@
        "mHeatEnabled": "Heating enabled",
        "mHeatBlocking": "Heating blocked",
        "mHeatOverheat": "Heating overheat",
        "sHeatActive": "Heating active",
        "mHeatSetpointTemp": "Heating setpoint temp",
        "mHeatTargetTemp": "Heating target temp",
@@ -128,7 +126,6 @@
        "mHeatOutdoorTemp": "Heating, outdoor temp",
        "mDhwEnabled": "DHW enabled",
        "mDhwOverheat": "DHW overheat",
        "sDhwActive": "DHW active",
        "mDhwTargetTemp": "DHW target temp",
        "mDhwCurrTemp": "DHW current temp",
@@ -305,24 +302,6 @@
        "max": "Maximum temperature"
      },
      "maxModulation": "Max modulation level",
      "ohProtection": {
        "title": "Overheating protection",
        "desc": "<b>Note:</b> This feature can be useful if the built-in boiler overheating protection does not work or does not work correctly and the heat carrier boils. To disable, set 0 as <b>high</b> and <b>low</b> temperature.",
        "highTemp": {
          "title": "High temperature threshold",
          "note": "Threshold at which the burner will be forcibly switched off"
        },
        "lowTemp": {
          "title": "Low temperature threshold",
          "note": "Threshold at which the burner can be turned on again"
        }
      },
      "freezeProtection": {
        "title": "Freeze protection",
        "desc": "Heating will be forced to turn on if the heat carrier or indoor temperature drops below <b>Low temperature</b> during <b>Waiting time</b>.",
        "lowTemp": "Low temperature threshold",
        "thresholdTime": "Waiting time <small>(sec)</small>"
      },
      "portal": {
        "login": "Login",
@@ -356,16 +335,7 @@
      },
      "heating": {
-        "hyst": {
+        "hyst": "Hysteresis <small>(in degrees)</small>",
          "title": "Hysteresis",
          "desc": "Hysteresis is useful for maintaining a set indoor temp (when using «Equitherm» and/or «PID»). Forces disable heating when <code>current indoor > target + value</code> and enable heating when <code>current indoor < (target - value)</code>.",
          "value": "Value <small>(in degrees)</small>",
          "action": {
            "title": "Action",
            "disableHeating": "Disable heating",
            "set0target": "Set null target"
          }
        },
        "turboFactor": "Turbo mode coeff."
      },
@@ -386,7 +356,7 @@
        },
        "exponent": {
          "title": "Exponent",
-          "note": "Radiator efficiency.  Typical values: <code>1.1</code> - Floor heating, <code>1.2</code> - Cast iron, <code>1.3</code> - Panel radiators, <code>1.4</code> - Convectors."
+          "note": "Radiator efficiency.  Typical values: 1.1 - Floor heating, 1.2 - Cast iron, 1.3 - Panel radiators, 1.4 - Convectors."
        },
        "shift": {
          "title": "Shift",
@@ -394,7 +364,7 @@
        },
        "targetDiffFactor": {
          "title": "T factor",
-          "note": "Not used if PID is enabled. Adds to the setpoint the difference between the target and current indoor temp: <code>setpoint = setpoint + ((target - indoor) * T)</code>."
+          "note": "Not used if PID is enabled"
        },
        "chart": {
          "targetTemp": "Target indoor temperature",
@@ -440,8 +410,7 @@
        },
        "options": {
-          "title": "Options (additional settings)",
+          "desc": "Options",
          "desc": "Options can change the logic of the boiler. Not all options are documented in the protocol, so the same option can have different effects on different boilers.<br /><b>Note:</b> There is no need to change anything if everything works well.",
          "dhwSupport": "DHW support",
          "coolingSupport": "Cooling support",
          "summerWinterMode": "Summer/winter mode",
@@ -450,14 +419,12 @@
          "heatingToCh2": "Duplicate heating to CH2",
          "dhwToCh2": "Duplicate DHW to CH2",
          "dhwBlocking": "DHW blocking",
          "dhwStateAsDhwBlocking": "DHW state as DHW blocking",
          "maxTempSyncWithTargetTemp": "Sync max heating temp with target temp",
          "getMinMaxTemp": "Get min/max temp from boiler",
          "ignoreDiagState": "Ignore diag state",
          "autoFaultReset": "Auto fault reset <small>(not recommended!)</small>",
          "autoDiagReset": "Auto diag reset <small>(not recommended!)</small>",
          "setDateAndTime": "Set date & time on boiler",
          "alwaysSetIndoorTemp": "Always set indoor temperature",
          "immergasFix": "Fix for Immergas boilers"
        },
@@ -480,7 +447,6 @@
      "extPump": {
        "use": "Use external pump",
        "gpio": "Relay GPIO",
        "invertState": "Invert GPIO state",
        "postCirculationTime": "Post circulation time <small>(min)</small>",
        "antiStuckInterval": "Anti stuck interval <small>(days)</small>",
        "antiStuckTime": "Anti stuck time <small>(min)</small>"
--- a/src_data/locales/it.json
+++ b/src_data/locales/it.json
@@ -109,8 +109,7 @@
        "sConnected": "Connessione OpenTherm",
        "sFlame": "Fiamma",
-        "sCoolingActive": "Raffrescamento",
+        "sCooling": "Raffrescamento",
        "sCoolingSetpoint": "Raffrescamento setpoint",
        "sFaultActive": "Anomalia",
        "sFaultCode": "Codice anomalia",
        "sDiagActive": "Diagnostica",
@@ -118,7 +117,6 @@
        "mHeatEnabled": "Riscaldamento attivato",
        "mHeatBlocking": "Riscaldamento bloccato",
        "mHeatOverheat": "Riscaldamento surriscaldamento",
        "sHeatActive": "Riscaldamento attivo",
        "mHeatSetpointTemp": "Temp riscaldamento impostato",
        "mHeatTargetTemp": "Target Temp caldaia",
@@ -128,7 +126,6 @@
        "mHeatOutdoorTemp": "Riscaldamento, temp esterna",
        "mDhwEnabled": "ACS attivata",
        "mDhwOverheat": "ACS surriscaldamento",
        "sDhwActive": "ACS attiva",
        "mDhwTargetTemp": "ACS temp impostata",
        "mDhwCurrTemp": "ACS temp attuale",
@@ -305,24 +302,6 @@
        "max": "Temperatura massima"
      },
      "maxModulation": "Max livello modulazione",
      "ohProtection": {
        "title": "Protezione contro il surriscaldamento",
        "desc": "<b>Nota:</b> questa funzione può essere utile se la protezione contro il surriscaldamento integrata nella caldaia non funziona o non funziona correttamente e il fluido termovettore bolle. Per disattivarla, impostare 0 come temperatura <b>alta</b> e <b>bassa</b>.",
        "highTemp": {
          "title": "Soglia di temperatura alta",
          "note": "Soglia alla quale il bruciatore verrà spento forzatamente"
        },
        "lowTemp": {
          "title": "Soglia di temperatura bassa",
          "note": "Soglia alla quale il bruciatore può essere riacceso"
        }
      },
      "freezeProtection": {
        "title": "Protezione antigelo",
        "desc": "Il riscaldamento verrà attivato forzatamente se la temperatura del vettore di calore o interna scende al di sotto della <b>temperatura minima</b> durante il <b>tempo di attesa</b>.",
        "lowTemp": "Soglia di temperatura minima",
        "thresholdTime": "Tempo di attesa <small>(sec)</small>"
      },
      "portal": {
        "login": "Login",
@@ -356,16 +335,7 @@
      },
      "heating": {
-        "hyst": {
+        "hyst": "Isteresi <small>(in gradi)</small>",
          "title": "Isteresi",
          "desc": "L'isteresi è utile per mantenere una temperatura interna impostata (quando si utilizza «Equitherm» e/o «PID»). Forza la disabilitazione del riscaldamento quando <code>current indoor > target + value</code> e abilita il riscaldamento quando <code>current indoor < (target - value)</code>.",
          "value": "Valore <small>(in gradi)</small>",
          "action": {
            "title": "Azione",
            "disableHeating": "Disabilita riscaldamento",
            "set0target": "Imposta target nullo"
          }
        },
        "turboFactor": "Turbo mode coeff."
      },
@@ -382,23 +352,23 @@
      "equitherm": {
        "slope": {
          "title": "Pendenza",
-          "note": "Compensazione della perdita di calore. Parametro di regolazione principale."
+          "note": "Compensazione delle perdite di calore. Principale parametro di regolazione."
        },
        "exponent": {
          "title": "Esponente",
-          "note": "Efficienza del radiatore. Valori tipici: <code>1.1</code> - Riscaldamento a pavimento, <code>1.2</code> - Ghisa, <code>1.3</code> - Radiatori a pannello, <code>1.4</code> - Convettori."
+          "note": "Efficienza del radiatore. Valori tipici: 1.1 - Riscaldamento a pavimento, 1.2 - Radiatori in ghisa, 1.3 - Radiatori a pannelli, 1.4 - Convetttori."
        },
        "shift": {
-          "title": "Spostamento",
+          "title": "Spostare",
-          "note": "Compensa perdite di calore aggiuntive (ad es., nelle tubature) o fonti di calore extra."
+          "note": "Compensa le perdite di calore aggiuntive (ad esempio, nelle tubature) o fonti di calore extra."
        },
        "targetDiffFactor": {
          "title": "Fattore T",
-          "note": "Non utilizzato se PID è abilitato. Aggiunge al setpoint la differenza tra la temperatura target e quella interna attuale: <code>setpoint = setpoint + ((target - indoor) * T)</code>."
+          "note": "Non usato se PID è attivato"
        },
        "chart": {
          "targetTemp": "Temperatura interna target",
-          "setpointTemp": "Temperatura del vettore termico",
+          "setpointTemp": "Temperatura del portatore di calore",
          "outdoorTemp": "Temperatura esterna"
        }
      },
@@ -440,8 +410,7 @@
        },
        "options": {
-          "title": "Opzioni (impostazioni aggiuntive)",
+          "desc": "Opzioni",
          "desc": "Le opzioni possono modificare la logica della caldaia. Non tutte le opzioni sono documentate nel protocollo, quindi la stessa opzione può avere effetti diversi su caldaie diverse.<br /><b>Nota:</b> Non è necessario modificare nulla se tutto funziona correttamente.",
          "dhwSupport": "Supporto ACS",
          "coolingSupport": "Supporto rafferscamento",
          "summerWinterMode": "Modalità Estate/inverno",
@@ -450,7 +419,6 @@
          "heatingToCh2": "Riproduci riscaldamento su CH2",
          "dhwToCh2": "Riproduci ACS su CH2",
          "dhwBlocking": "Bloccare ACS",
          "dhwStateAsDhwBlocking": "Stato ACS come bloccare ACS",
          "maxTempSyncWithTargetTemp": "Sincronizza la temperatura massima di riscaldamento con la temperatura target",
          "getMinMaxTemp": "Prendi temp min/max dalla caldaia",
          "ignoreDiagState": "Ignora lo stato diagnostico",
@@ -479,7 +447,6 @@
      "extPump": {
        "use": "Usa pompa/circolatore esterno",
        "gpio": "GPIO relè",
        "invertState": "Inverti stato GPIO",
        "postCirculationTime": "Tempo di post circolazione <small>(min)</small>",
        "antiStuckInterval": "Intervallo antiblocco <small>(days)</small>",
        "antiStuckTime": "Tempo antiblocco <small>(min)</small>"
--- a/src_data/locales/nl.json
+++ b/src_data/locales/nl.json
@@ -1,490 +0,0 @@
 {
  "values": {
    "logo": "OpenTherm Gateway",
    "nav": {
      "license": "Licentie",
      "source": "Broncode",
      "help": "Help",
      "issues": "Problemen & vragen",
      "releases": "Releases"
    },
    "dbm": "dBm",
    "kw": "kW",
    "time": {
      "days": "d.",
      "hours": "u.",
      "min": "min.",
      "sec": "sec."
    },
    "button": {
      "upgrade": "Upgraden",
      "restart": "Herstarten",
      "save": "Opslaan",
      "saved": "Opgeslagen",
      "refresh": "Vernieuwen",
      "restore": "Herstellen",
      "restored": "Hersteld",
      "backup": "Back-up",
      "wait": "Even wachten...",
      "uploading": "Uploaden...",
      "success": "Succes",
      "error": "Fout"
    },
    "index": {
      "title": "OpenTherm Gateway",
      "section": {
        "network": "Netwerk",
        "system": "Systeem"
      },
      "system": {
        "build": {
          "title": "Build",
          "version": "Versie",
          "date": "Datum",
          "core": "Core",
          "sdk": "SDK"
        },
        "uptime": "Uptime",
        "memory": {
          "title": "Vrij geheugen",
          "maxFreeBlock": "max. vrij blok",
          "min": "min"
        },
        "board": "Board",
        "chip": {
          "model": "Chip",
          "cores": "Kernen",
          "freq": "frequentie"
        },
        "flash": {
          "size": "Flash-grootte",
          "realSize": "werkelijke grootte"
        },
        "lastResetReason": "Reden laatste herstart"
      }
    },
    "dashboard": {
      "name": "Dashboard",
      "title": "Dashboard - OpenTherm Gateway",
      "section": {
        "control": "Bediening",
        "states": "Statussen",
        "sensors": "Sensoren",
        "diag": "OpenTherm diagnose"
      },
      "thermostat": {
        "heating": "Verwarming",
        "dhw": "Warm water",
        "temp.current": "Huidig",
        "enable": "Inschakelen",
        "turbo": "Turbomodus"
      },
      "notify": {
        "fault": {
          "title": "Ketelstoring is actief!",
          "note": "Het wordt aanbevolen de ketel te inspecteren en de documentatie te raadplegen om de storingscode te interpreteren:"
        },
        "diag": {
          "title": "Keteldiagnose is actief!",
          "note": "Heeft uw ketel misschien een inspectie nodig? Het wordt aanbevolen de documentatie te raadplegen om de diagnosecode te interpreteren:"
        },
        "reset": "Probeer te resetten"
      },
      "states": {
        "mNetworkConnected": "Netwerkverbinding",
        "mMqttConnected": "MQTT-verbinding",
        "mEmergencyState": "Noodmodus",
        "mExtPumpState": "Externe pomp",
        "mCascadeControlInput": "Cascaderegeling (ingang)",
        "mCascadeControlOutput": "Cascaderegeling (uitgang)",
        "sConnected": "OpenTherm-verbinding",
        "sFlame": "Vlam",
        "sCoolingActive": "Koeling",
        "sCoolingSetpoint": "Koelinstelpunt",
        "sFaultActive": "Storing",
        "sFaultCode": "Storingscode",
        "sDiagActive": "Diagnose",
        "sDiagCode": "Diagnosecode",
        "mHeatEnabled": "Verwarming ingeschakeld",
        "mHeatBlocking": "Verwarming geblokkeerd",
        "mHeatOverheat": "Verwarming oververhit",
        "sHeatActive": "Verwarming actief",
        "mHeatSetpointTemp": "Insteltemperatuur verwarming",
        "mHeatTargetTemp": "Doeltemperatuur verwarming",
        "mHeatCurrTemp": "Huidige temperatuur verwarming",
        "mHeatRetTemp": "Retourtemperatuur verwarming",
        "mHeatIndoorTemp": "Verwarming, binnentemperatuur",
        "mHeatOutdoorTemp": "Verwarming, buitentemperatuur",
        "mDhwEnabled": "Warm water ingeschakeld",
        "mDhwOverheat": "Warm water oververhit",
        "sDhwActive": "Warm water actief",
        "mDhwTargetTemp": "Doeltemperatuur warm water",
        "mDhwCurrTemp": "Huidige temperatuur warm water",
        "mDhwRetTemp": "Retourtemperatuur warm water"
      },
      "sensors": {
        "values": {
          "temp": "Temperatuur",
          "humidity": "Luchtvochtigheid",
          "battery": "Batterij",
          "rssi": "RSSI"
        }
      }
    },
    "network": {
      "title": "Netwerk - OpenTherm Gateway",
      "name": "Netwerkinstellingen",
      "section": {
        "static": "Statische instellingen",
        "availableNetworks": "Beschikbare netwerken",
        "staSettings": "WiFi-instellingen",
        "apSettings": "AP-instellingen"
      },
      "scan": {
        "pos": "#",
        "info": "Info"
      },
      "wifi": {
        "ssid": "SSID",
        "password": "Wachtwoord",
        "channel": "Kanaal",
        "signal": "Signaal",
        "connected": "Verbonden"
      },
      "params": {
        "hostname": "Hostnaam",
        "dhcp": "Gebruik DHCP",
        "mac": "MAC",
        "ip": "IP",
        "subnet": "Subnet",
        "gateway": "Gateway",
        "dns": "DNS"
      },
      "sta": {
        "channel.note": "zet op 0 voor automatische selectie"
      }
    },
    "sensors": {
      "title": "Sensorinstellingen - OpenTherm Gateway",
      "name": "Sensorinstellingen",
      "enabled": "Ingeschakeld",
      "sensorName": {
        "title": "Sensornaam",
        "note": "Mag alleen bevatten: a-z, A-Z, 0-9, _ en spatie"
      },
      "purpose": "Doel",
      "purposes": {
        "outdoorTemp": "Buitentemperatuur",
        "indoorTemp": "Binnentemperatuur",
        "heatTemp": "Verwarming, temperatuur",
        "heatRetTemp": "Verwarming, retourtemperatuur",
        "dhwTemp": "Warm water, temperatuur",
        "dhwRetTemp": "Warm water, retourtemperatuur",
        "dhwFlowRate": "Warm water, doorstroomsnelheid",
        "exhaustTemp": "Rookgastemperatuur",
        "modLevel": "Modulatieniveau (in procenten)",
        "number": "Getal (ruw)",
        "powerFactor": "Vermogen (in procent)",
        "power": "Vermogen (in kWt)",
        "fanSpeed": "Ventilatorsnelheid",
        "co2": "CO2",
        "pressure": "Druk",
        "humidity": "Luchtvochtigheid",
        "temperature": "Temperatuur",
        "notConfigured": "Niet geconfigureerd"
      },
      "type": "Type/bron",
      "types": {
        "otOutdoorTemp": "OpenTherm, buitentemp.",
        "otHeatTemp": "OpenTherm, verwarming, temp.",
        "otHeatRetTemp": "OpenTherm, verwarming, retourtemp.",
        "otDhwTemp": "OpenTherm, warm water, temperatuur",
        "otDhwTemp2": "OpenTherm, warm water, temperatuur 2",
        "otDhwFlowRate": "OpenTherm, warm water, doorstroomsnelheid",
        "otCh2Temp": "OpenTherm, kanaal 2, temp.",
        "otExhaustTemp": "OpenTherm, rookgastemp.",
        "otHeatExchangerTemp": "OpenTherm, warmtewisselaar temp.",
        "otPressure": "OpenTherm, druk",
        "otModLevel": "OpenTherm, modulatieniveau",
        "otCurrentPower": "OpenTherm, huidig vermogen",
        "otExhaustCo2": "OpenTherm, rookgas CO2",
        "otExhaustFanSpeed": "OpenTherm, rookgasventilator snelheid",
        "otSupplyFanSpeed": "OpenTherm, toevoerventilator snelheid",
        "otSolarStorageTemp": "OpenTherm, zonneboiler opslagtemp.",
        "otSolarCollectorTemp": "OpenTherm, zonnecollector temp.",
        "otFanSpeedSetpoint": "OpenTherm, instelpunt ventilatorsnelheid",
        "otFanSpeedCurrent": "OpenTherm, huidige ventilatorsnelheid",
        "otBurnerStarts": "OpenTherm, aantal branderstarts",
        "otDhwBurnerStarts": "OpenTherm, aantal branderstarts (warm water)",
        "otHeatingPumpStarts": "OpenTherm, aantal pompstarts (verwarming)",
        "otDhwPumpStarts": "OpenTherm, aantal pompstarts (warm water)",
        "otBurnerHours": "OpenTherm, aantal branderuren",
        "otDhwBurnerHours": "OpenTherm, aantal branderuren (warm water)",
        "otHeatingPumpHours": "OpenTherm, aantal pompuren (verwarming)",
        "otDhwPumpHours": "OpenTherm, aantal pompuren (warm water)",
        "ntcTemp": "NTC-sensor",
        "dallasTemp": "DALLAS-sensor",
        "bluetooth": "BLE-sensor",
        "heatSetpointTemp": "Verwarming, insteltemperatuur",
        "manual": "Handmatig via MQTT/API",
        "notConfigured": "Niet geconfigureerd"
      },
      "gpio": "GPIO",
      "address": {
        "title": "Sensoradres",
        "note": "Laat leeg voor automatische detectie van DALLAS-sensoren. Voor BLE-apparaten is een MAC-adres vereist."
      },
      "correction": {
        "desc": "Correctie van waarden",
        "offset": "Compensatie (offset)",
        "factor": "Vermenigvuldiger"
      },
      "filtering": {
        "desc": "Filteren van waarden",
        "enabled": {
          "title": "Filteren ingeschakeld",
          "note": "Kan handig zijn bij veel scherpe ruis in de grafieken. Het gebruikte filter is \"Voortschrijdend gemiddelde\"."
        },
        "factor": {
          "title": "Filterfactor",
          "note": "Hoe lager de waarde, hoe vloeiender en <u>langer</u> de verandering in numerieke waarden."
        }
      }
    },
    "settings": {
      "title": "Instellingen - OpenTherm Gateway",
      "name": "Instellingen",
      "section": {
        "portal": "Portaalinstellingen",
        "system": "Systeeminstellingen",
        "diag": "Diagnose",
        "heating": "Verwarmingsinstellingen",
        "dhw": "Warmwaterinstellingen",
        "emergency": "Instellingen noodmodus",
        "equitherm": "Equitherm-instellingen",
        "pid": "PID-instellingen",
        "ot": "OpenTherm-instellingen",
        "mqtt": "MQTT-instellingen",
        "extPump": "Instellingen externe pomp",
        "cascadeControl": "Instellingen cascaderegeling"
      },
      "enable": "Inschakelen",
      "note": {
        "restart": "Na het wijzigen van deze instellingen moet het apparaat opnieuw worden opgestart om de wijzigingen door te voeren.",
        "blankNotUse": "leeg - niet gebruiken",
        "bleDevice": "BLE-apparaat kan <u>alleen</u> worden gebruikt met sommige ESP32-boards met BLE-ondersteuning!"
      },
      "temp": {
        "min": "Minimumtemperatuur",
        "max": "Maximumtemperatuur"
      },
      "maxModulation": "Max. modulatieniveau",
      "ohProtection": {
        "title": "Oververhittingsbeveiliging",
        "desc": "<b>Let op:</b> Deze functie kan handig zijn als de ingebouwde oververhittingsbeveiliging van de ketel niet of niet correct werkt en de warmtedrager kookt. Om uit te schakelen, stel 0 in als <b>hoge</b> en <b>lage</b> temperatuur.",
        "highTemp": {
          "title": "Drempelwaarde hoge temperatuur",
          "note": "Drempelwaarde waarbij de brander geforceerd wordt uitgeschakeld"
        },
        "lowTemp": {
          "title": "Drempelwaarde lage temperatuur",
          "note": "Drempelwaarde waarbij de brander weer ingeschakeld kan worden"
        }
      },
      "freezeProtection": {
        "title": "Vorstbeveiliging",
        "desc": "De verwarming wordt geforceerd ingeschakeld als de temperatuur van de warmtedrager of de binnentemperatuur onder de <b>Lage temperatuur</b> daalt gedurende de <b>Wachttijd</b>.",
        "lowTemp": "Drempelwaarde lage temperatuur",
        "thresholdTime": "Wachttijd <small>(sec)</small>"
      },
      "portal": {
        "login": "Gebruikersnaam",
        "password": "Wachtwoord",
        "auth": "Authenticatie vereisen",
        "mdns": "Gebruik mDNS"
      },
      "system": {
        "unit": "Eenheidssysteem",
        "metric": "Metrisch <small>(celsius, liters, bar)</small>",
        "imperial": "Imperiaal <small>(fahrenheit, gallons, psi)</small>",
        "statusLedGpio": "Status LED GPIO",
        "logLevel": "Logniveau",
        "serial": {
          "enable": "Seriële poort ingeschakeld",
          "baud": "Baudrate seriële poort"
        },
        "telnet": {
          "enable": "Telnet ingeschakeld",
          "port": {
            "title": "Telnet-poort",
            "note": "Standaard: 23"
          }
        },
        "ntp": {
          "server": "NTP-server",
          "timezone": "Tijdzone",
          "timezonePresets": "Selecteer voorinstelling..."
        }
      },
      "heating": {
        "hyst": {
          "title": "Hysterese",
          "desc": "Hysterese is nuttig voor het handhaven van een ingestelde binnentemperatuur (bij gebruik van «Equitherm» en/of «PID»). Forceert uitschakelen van verwarming wanneer <code>current indoor > target + value</code> en inschakelen van verwarming wanneer <code>current indoor < (target - value)</code>.",
          "value": "Waarde <small>(in graden)</small>",
          "action": {
            "title": "Actie",
            "disableHeating": "Verwarming uitschakelen",
            "set0target": "Stel null target in"
          }
        },
        "turboFactor": "Turbomodus coëff."
      },
      "emergency": {
        "desc": "Noodmodus wordt automatisch geactiveerd wanneer «PID» of «Equitherm» het instelpunt van de warmtedrager niet kan berekenen:<br />- als «Equitherm» is ingeschakeld en de buitentemperatuursensor is losgekoppeld;<br />- als «PID» of OT-optie <i>«Natuurlijke verwarmingsregeling»</i> is ingeschakeld en de binnentemperatuursensor is losgekoppeld.<br /><b>Let op:</b> Bij een netwerk- of MQTT-storing krijgen sensoren van het type <i>«Handmatig via MQTT/API»</i> de status ONVERBONDEN.",
        "target": {
          "title": "Doeltemperatuur",
          "note": "<b>Belangrijk:</b> <u>Doel binnentemperatuur</u> als OT-optie <i>«Natuurlijke verwarmingsregeling»</i> is ingeschakeld.<br />In alle andere gevallen, de <u>doel warmtedragertemperatuur</u>."
        },
        "treshold": "Drempeltijd <small>(sec)</small>"
      },
      "equitherm": {
        "slope": {
          "title": "Helling",
          "note": "Compensatie voor warmteverlies. Hoofdafstelparameter."
        },
        "exponent": {
          "title": "Exponent",
          "note": "Radiator efficiëntie. Typische waarden: <code>1.1</code> - Vloerverwarming, <code>1.2</code> - Gietijzer, <code>1.3</code> - Paneelradiatoren, <code>1.4</code> - Convectors."
        },
        "shift": {
          "title": "Verschuiving",
          "note": "Compenseert voor extra warmteverliezen (bijv. in leidingen) of extra warmtebronnen."
        },
        "targetDiffFactor": {
          "title": "T factor",
          "note": "Niet gebruikt als PID is ingeschakeld. Voegt aan de setpoint de verschil tussen de target en huidige binnentemperatuur toe: <code>setpoint = setpoint + ((target - indoor) * T)</code>."
        },
        "chart": {
          "targetTemp": "Doel binnentemperatuur",
          "setpointTemp": "Warmtedrager temperatuur",
          "outdoorTemp": "Buitentemperatuur"
        }
      },
      "pid": {
        "p": "P-factor",
        "i": "I-factor",
        "d": "D-factor",
        "dt": "DT <small>in seconden</small>",
        "limits": {
          "title": "Limieten",
          "note": "<b>Belangrijk:</b> Bij gelijktijdig gebruik van «Equitherm» en «PID» beperken de min- en maxtemperaturen de invloed op de resulterende «Equitherm»-temperatuur.<br />Dus, als de min-temperatuur is ingesteld op -15 en de max-temperatuur op 15, zal het uiteindelijke instelpunt van de warmtedrager liggen tussen <code>equitherm_resultaat - 15</code> en <code>equitherm_resultaat + 15</code>."
        },
        "deadband": {
          "title": "Deadband",
          "note": "Deadband is een bereik rond de doeltemperatuur waarbinnen de PID-regeling minder actief wordt. Binnen dit bereik kan het algoritme de intensiteit verminderen of aanpassingen pauzeren om overreactie op kleine schommelingen te voorkomen.<br /><br />Bijvoorbeeld, met een doeltemperatuur van 22°, een onderdrempel van 1.0 en een bovendrempel van 0.5, werkt de deadband tussen 21° en 22.5°. Als de I-coëfficiënt 0.0005 is en de I-vermenigvuldiger 0.05, dan wordt de I-coëfficiënt binnen de deadband: <code>0.0005 * 0.05 = 0.000025</code>",
          "p_multiplier": "Vermenigvuldiger voor P-factor",
          "i_multiplier": "Vermenigvuldiger voor I-factor",
          "d_multiplier": "Vermenigvuldiger voor D-factor",
          "thresholdHigh": "Bovendrempel",
          "thresholdLow": "Onderdrempel"
        }
      },
      "ot": {
        "advanced": "Geavanceerde instellingen",
        "inGpio": "In GPIO",
        "outGpio": "Uit GPIO",
        "ledGpio": "RX LED GPIO",
        "memberId": "Master member ID",
        "flags": "Master flags",
        "minPower": {
          "title": "Min. ketelvermogen <small>(kW)</small>",
          "note": "Deze waarde is bij 0-1% modulatieniveau van de ketel. Typisch te vinden in de ketelspecificatie als \"minimum nuttig warmtevermogen\"."
        },
        "maxPower": {
          "title": "Max. ketelvermogen <small>(kW)</small>",
          "note": "<b>0</b> - probeer automatisch te detecteren. Typisch te vinden in de ketelspecificatie als \"maximum nuttig warmtevermogen\"."
        },
        "options": {
          "title": "Opties (aanvullende instellingen)",
          "desc": "Opties kunnen de logica van de ketel veranderen. Niet alle opties zijn gedocumenteerd in het protocol, dus dezelfde optie kan verschillende effecten hebben op verschillende ketels.<br /><b>Let op:</b> Het is niet nodig om iets te veranderen als alles goed werkt.",
          "dhwSupport": "Warm water ondersteuning",
          "coolingSupport": "Koeling ondersteuning",
          "summerWinterMode": "Zomer/wintermodus",
          "heatingStateToSummerWinterMode": "Verwarmingsstatus als zomer/wintermodus",
          "ch2AlwaysEnabled": "CH2 altijd ingeschakeld",
          "heatingToCh2": "Dupliceer verwarming naar CH2",
          "dhwToCh2": "Dupliceer warm water naar CH2",
          "dhwBlocking": "Blokkering warm water",
          "dhwStateAsDhwBlocking": "Status warm water als blokkering warm water",
          "maxTempSyncWithTargetTemp": "Synchroniseer max. verwarmingstemp. met doeltemp.",
          "getMinMaxTemp": "Haal min/max temp. op van ketel",
          "ignoreDiagState": "Negeer diagnosestatus",
          "autoFaultReset": "Automatische storingsreset <small>(niet aanbevolen!)</small>",
          "autoDiagReset": "Automatische diagnosereset <small>(niet aanbevolen!)</small>",
          "setDateAndTime": "Stel datum & tijd in op ketel",
          "immergasFix": "Fix voor Immergas-ketels"
        },
        "nativeHeating": {
          "title": "Natuurlijke verwarmingsregeling (ketel)",
          "note": "Werkt <u>ALLEEN</u> als de ketel de gewenste kamertemperatuur vereist en zelf de temperatuur van de warmtedrager regelt. Niet compatibel met PID- en Equitherm-regelaars in de firmware."
        }
      },
      "mqtt": {
        "homeAssistantDiscovery": "Home Assistant Discovery",
        "server": "Server",
        "port": "Poort",
        "user": "Gebruiker",
        "password": "Wachtwoord",
        "prefix": "Prefix",
        "interval": "Publicatie-interval <small>(sec)</small>"
      },
      "extPump": {
        "use": "Gebruik externe pomp",
        "gpio": "Relais GPIO",
        "invertState": "Inverteer GPIO-status",
        "postCirculationTime": "Nacirculatietijd <small>(min)</small>",
        "antiStuckInterval": "Anti-vastloopinterval <small>(dagen)</small>",
        "antiStuckTime": "Anti-vastlooptijd <small>(min)</small>"
      },
      "cascadeControl": {
        "input": {
          "desc": "Kan worden gebruikt om de verwarming alleen in te schakelen als een andere ketel defect is. De besturing van de andere ketel moet de status van de GPIO-ingang wijzigen in geval van een storing.",
          "enable": "Ingang ingeschakeld",
          "gpio": "GPIO",
          "invertState": "Inverteer GPIO-status",
          "thresholdTime": "Drempeltijd statuswijziging <small>(sec)</small>"
        },
        "output": {
          "desc": "Kan worden gebruikt om een andere ketel in te schakelen <u>via een relais</u>.",
          "enable": "Uitgang ingeschakeld",
          "gpio": "GPIO",
          "invertState": "Inverteer GPIO-status",
          "thresholdTime": "Drempeltijd statuswijziging <small>(sec)</small>",
          "events": {
            "desc": "Gebeurtenissen",
            "onFault": "Als de storingsstatus actief is",
            "onLossConnection": "Als de verbinding via Opentherm is verbroken",
            "onEnabledHeating": "Als de verwarming is ingeschakeld"
          }
        }
      }
    },
    "upgrade": {
      "title": "Upgrade - OpenTherm Gateway",
      "name": "Upgrade",
      "section": {
        "backupAndRestore": "Back-up & herstel",
        "backupAndRestore.desc": "In deze sectie kunt u een back-up van ALLE instellingen opslaan en herstellen.",
        "upgrade": "Upgrade",
        "upgrade.desc": "In deze sectie kunt u de firmware en het bestandssysteem van uw apparaat upgraden.<br />De nieuwste releases kunnen worden gedownload van de <a href=\"https://github.com/Laxilef/OTGateway/releases\" target=\"_blank\">Releases-pagina</a> van de projectrepository."
      },
      "note": {
        "disclaimer1": "Na een succesvolle upgrade van het bestandssysteem worden ALLE instellingen teruggezet naar de standaardwaarden! Sla een back-up op voordat u gaat upgraden.",
        "disclaimer2": "Na een succesvolle upgrade zal het apparaat automatisch herstarten na 15 seconden."
      },
      "settingsFile": "Instellingenbestand",
      "fw": "Firmware",
      "fs": "Bestandssysteem"
    }
  }
 }
--- a/src_data/locales/ru.json
+++ b/src_data/locales/ru.json
@@ -109,8 +109,7 @@
        "sConnected": "Подключение к OpenTherm",
        "sFlame": "Пламя",
-        "sCoolingActive": "Охлаждение",
+        "sCooling": "Охлаждение",
        "sCoolingSetpoint": "Охлаждение, уставка",
        "sFaultActive": "Ошибка",
        "sFaultCode": "Код ошибки",
        "sDiagActive": "Диагностика",
@@ -118,7 +117,6 @@
        "mHeatEnabled": "Отопление",
        "mHeatBlocking": "Блокировка отопления",
        "mHeatOverheat": "Отопление, перегрев",
        "sHeatActive": "Активность отопления",
        "mHeatSetpointTemp": "Отопление, уставка",
        "mHeatTargetTemp": "Отопление, целевая температура",
@@ -128,7 +126,6 @@
        "mHeatOutdoorTemp": "Отопление, наружная темп.",
        "mDhwEnabled": "ГВС",
        "mDhwOverheat": "ГВС, перегрев",
        "sDhwActive": "Активность ГВС",
        "mDhwTargetTemp": "ГВС, целевая температура",
        "mDhwCurrTemp": "ГВС, текущая температура",
@@ -305,24 +302,6 @@
        "max": "Макс. температура"
      },
      "maxModulation": "Макс. уровень модуляции",
      "ohProtection": {
        "title": "Защита от перегрева",
        "desc": "<b>Примечание:</b> Эта функция может быть полезна, если встроенная защита от перегрева котла не срабатывает или срабатывает некорректно и теплоноситель закипает. Для отключения установите 0 в качестве <b>верхнего</b> и <b>нижнего</b> порога температуры.",
        "highTemp": {
          "title": "Верхний порог температуры",
          "note": "Порог, при котором горелка будет принудительно отключена"
        },
        "lowTemp": {
          "title": "Нижний порог температуры",
          "note": "Порог, при котором горелка может быть включена снова"
        }
      },
      "freezeProtection": {
        "title": "Защита от замерзания",
        "desc": "Отопление будет принудительно включено, если темп. теплоносителя или внутренняя темп. опустится ниже <b>нижнего порога</b> в течение <b>времени ожидания</b>.",
        "lowTemp": "Нижний порог температуры",
        "thresholdTime": "Время ожидания <small>(сек)</small>"
      },
      "portal": {
        "login": "Логин",
@@ -356,16 +335,7 @@
      },
      "heating": {
-        "hyst": {
+        "hyst": "Гистерезис <small>(в градусах)</small>",
          "title": "Гистерезис",
          "desc": "Гистерезис полезен для поддержания заданной внутр. темп. (при использовании «ПЗА» и/или «ПИД»). Принудительно откл. отопление, когда <code>current indoor > target + value</code>, и вкл. отопление, когда <code>current indoor < (target - value)</code>.",
          "value": "Значение <small>(в градусах)</small>",
          "action": {
            "title": "Действие",
            "disableHeating": "Отключить отопление",
            "set0target": "Установить 0 в качестве целевой темп."
          }
        },
        "turboFactor": "Коэфф. турбо режима"
      },
@@ -386,7 +356,7 @@
        },
        "exponent": {
          "title": "Экспонента",
-          "note": "Эффективность радиатора. Типичные значения: <code>1.1</code> - Тёплый пол, <code>1.2</code> - Чугунные радиаторы, <code>1.3</code> - Панельные радиаторы, <code>1.4</code> - Конвекторы."
+          "note": "Эффективность радиатора. Типичные значения: 1.1 - Тёплый пол, 1.2 - Чугунные радиаторы, 1.3 - Панельные радиаторы, 1.4 - Конвекторы."
        },
        "shift": {
          "title": "Смещение",
@@ -394,7 +364,7 @@
        },
        "targetDiffFactor": {
          "title": "Коэффициент T",
-          "note": "Не используется, если ПИД включен. Добавляет разницу между целевой и текущей температурой в помещении: <code>setpoint = setpoint + ((target - indoor) * T)</code>."
+          "note": "Не используется, если ПИД включен"
        },
        "chart": {
          "targetTemp": "Целевая внутренняя температура",
@@ -440,8 +410,7 @@
        },
        "options": {
-          "title": "Опции (дополнительные настройки)",
+          "desc": "Опции",
          "desc": "Опции могут менять логику работы котла. Не все опции задокументированы в протоколе, поэтому одна и та же опция может иметь разный эффект на разных котлах.<br /><b>Примечание:</b> Нет необходимости что-то менять, если всё работает хорошо.",
          "dhwSupport": "Поддержка ГВС",
          "coolingSupport": "Поддержка охлаждения",
          "summerWinterMode": "Летний/зимний режим",
@@ -450,7 +419,6 @@
          "heatingToCh2": "Дублировать параметры отопления в канал 2",
          "dhwToCh2": "Дублировать параметры ГВС в канал 2",
          "dhwBlocking": "DHW blocking",
          "dhwStateAsDhwBlocking": "DHW blocking в качестве состояния ГВС",
          "maxTempSyncWithTargetTemp": "Синхронизировать макс. темп. отопления с целевой темп.",
          "getMinMaxTemp": "Получать мин. и макс. температуру от котла",
          "ignoreDiagState": "Игнорировать состояние диагностики",
@@ -479,7 +447,6 @@
      "extPump": {
        "use": "Использовать доп. насос",
        "gpio": "GPIO реле",
        "invertState": "Инвертировать состояние GPIO",
        "postCirculationTime": "Время постциркуляции <small>(в минутах)</small>",
        "antiStuckInterval": "Интервал защиты от блокировки <small>(в днях)</small>",
        "antiStuckTime": "Время работы насоса <small>(в минутах)</small>"
--- a/src_data/pages/dashboard.html
+++ b/src_data/pages/dashboard.html
@@ -21,9 +21,7 @@
          <li>
            <select id="lang" aria-label="Lang">
              <option value="en" selected>EN</option>
              <option value="cn">CN</option>
              <option value="it">IT</option>
              <option value="nl">NL</option>
              <option value="ru">RU</option>
            </select>
          </li>
@@ -154,14 +152,9 @@
                  <th scope="row" data-i18n>dashboard.states.sFlame</th>
                  <td><i class="sFlame"></i></td>
                </tr>
                <tr>
-                  <th scope="row" data-i18n>dashboard.states.sCoolingActive</th>
+                  <th scope="row" data-i18n>dashboard.states.sCooling</th>
-                  <td><i class="sCoolingActive"></i></td>
+                  <td><i class="sCooling"></i></td>
                </tr>
                <tr>
                  <th scope="row" data-i18n>dashboard.states.sCoolingSetpoint</th>
                  <td><b class="sCoolingSetpoint"></b> %</td>
                </tr>
@@ -191,10 +184,6 @@
                  <th scope="row" data-i18n>dashboard.states.mHeatBlocking</th>
                  <td><i class="mHeatBlocking"></i></td>
                </tr>
                <tr>
                  <th scope="row" data-i18n>dashboard.states.mHeatOverheat</th>
                  <td><i class="mHeatOverheat"></i></td>
                </tr>
                <tr>
                  <th scope="row" data-i18n>dashboard.states.sHeatActive</th>
                  <td><i class="sHeatActive"></i></td>
@@ -229,10 +218,6 @@
                  <th scope="row" data-i18n>dashboard.states.mDhwEnabled</th>
                  <td><i class="mDhwEnabled"></i></td>
                </tr>
                <tr>
                  <th scope="row" data-i18n>dashboard.states.mDhwOverheat</th>
                  <td><i class="mDhwOverheat"></i></td>
                </tr>
                <tr>
                  <th scope="row" data-i18n>dashboard.states.sDhwActive</th>
                  <td><i class="sDhwActive"></i></td>
@@ -563,9 +548,7 @@
              result.slave.connected ? "green" : "red"
            );
            setState('.sFlame', result.slave.flame);
-
+            setState('.sCooling', result.slave.cooling);
            setState('.sCoolingActive', result.slave.cooling.active);
            setValue('.sCoolingSetpoint', result.slave.cooling.setpoint);
            setValue('.sModMin', result.slave.modulation.min);
            setValue('.sModMax', result.slave.modulation.max);
@@ -628,11 +611,6 @@
              result.master.heating.blocking ? "red" : "green"
            );
            setState('.mHeatIndoorTempControl', result.master.heating.indoorTempControl);
            setStatus(
              '.mHeatOverheat',
              result.master.heating.overheat ? "success" : "error",
              result.master.heating.overheat ? "red" : "green"
            );
            setValue('.mHeatSetpointTemp', result.master.heating.setpointTemp);
            setValue('.mHeatTargetTemp', result.master.heating.targetTemp);
            setValue('.mHeatCurrTemp', result.master.heating.currentTemp);
@@ -643,11 +621,6 @@
            setValue('.mHeatMaxTemp', result.master.heating.maxTemp);
            setState('.mDhwEnabled', result.master.dhw.enabled);
            setStatus(
              '.mDhwOverheat',
              result.master.dhw.overheat ? "success" : "error",
              result.master.dhw.overheat ? "red" : "green"
            );
            setValue('.mDhwTargetTemp', result.master.dhw.targetTemp);
            setValue('.mDhwCurrTemp', result.master.dhw.currentTemp);
            setValue('.mDhwRetTemp', result.master.dhw.returnTemp);
--- a/src_data/pages/index.html
+++ b/src_data/pages/index.html
@@ -21,9 +21,7 @@
          <li>
            <select id="lang" aria-label="Lang">
              <option value="en" selected>EN</option>
              <option value="cn">CN</option>
              <option value="it">IT</option>
              <option value="nl">NL</option>
              <option value="ru">RU</option>
            </select>
          </li>
--- a/src_data/pages/network.html
+++ b/src_data/pages/network.html
@@ -21,9 +21,7 @@
          <li>
            <select id="lang" aria-label="Lang">
              <option value="en" selected>EN</option>
              <option value="cn">CN</option>
              <option value="it">IT</option>
              <option value="nl">NL</option>
              <option value="ru">RU</option>
            </select>
          </li>
--- a/src_data/pages/sensors.html
+++ b/src_data/pages/sensors.html
@@ -21,9 +21,7 @@
          <li>
            <select id="lang" aria-label="Lang">
              <option value="en" selected>EN</option>
              <option value="cn">CN</option>
              <option value="it">IT</option>
              <option value="nl">NL</option>
              <option value="ru">RU</option>
            </select>
          </li>
--- a/src_data/pages/settings.html
+++ b/src_data/pages/settings.html
@@ -21,9 +21,7 @@
          <li>
            <select id="lang" aria-label="Lang">
              <option value="en" selected>EN</option>
              <option value="cn">CN</option>
              <option value="it">IT</option>
              <option value="nl">NL</option>
              <option value="ru">RU</option>
            </select>
          </li>
@@ -193,92 +191,21 @@
              </div>
              <div class="grid">
                <label>
                  <span data-i18n>settings.heating.hyst</span>
                  <input type="number" inputmode="decimal" name="heating[hysteresis]" min="0" max="5" step="0.05" required>
                </label>
                <label>
                  <span data-i18n>settings.heating.turboFactor</span>
                  <input type="number" inputmode="decimal" name="heating[turboFactor]" min="1.5" max="10" step="0.1" required>
                </label>
              </div>
              <label>
                <span data-i18n>settings.maxModulation</span>
                <input type="number" inputmode="numeric" name="heating[maxModulation]" min="1" max="100" step="1" required>
              </label>
              </div>
              <hr />
              <details>
                <summary><b data-i18n>settings.heating.hyst.title</b></summary>
                <div>
                  <fieldset>
                    <label>
                      <input type="checkbox" name="heating[hysteresis][enabled]" value="true">
                      <span data-i18n>settings.enable</span>
                    </label>
                  </fieldset>
                  <div class="grid">
                    <label>
                      <span data-i18n>settings.heating.hyst.value</span>
                      <input type="number" inputmode="decimal" name="heating[hysteresis][value]" min="0" max="5" step="0.05" required>
                    </label>
                    <label>
                      <span data-i18n>settings.heating.hyst.action.title</span>
                      <select name="heating[hysteresis][action]">
                        <option value="0" data-i18n>settings.heating.hyst.action.disableHeating</option>
                        <option value="1" data-i18n>settings.heating.hyst.action.set0target</option>
                      </select>
                    </label>
                  </div>
                </div>
                <small data-i18n>settings.heating.hyst.desc</small>
              </details>
              <hr />
              <details>
                <summary><b data-i18n>settings.ohProtection.title</b></summary>
                <div class="grid">
                  <label>
                    <span data-i18n>settings.ohProtection.highTemp.title</span>
                    <input type="number" inputmode="numeric" name="heating[overheatProtection][highTemp]" min="0" max="0" step="1" required>
                    <small data-i18n>settings.ohProtection.highTemp.note</small>
                  </label>
                  <label>
                    <span data-i18n>settings.ohProtection.lowTemp.title</span>
                    <input type="number" inputmode="numeric" name="heating[overheatProtection][lowTemp]" min="0" max="0" step="1" required>
                    <small data-i18n>settings.ohProtection.lowTemp.note</small>
                  </label>
                </div>
                <small data-i18n>settings.ohProtection.desc</small>
              </details>
              <hr />
              <details>
                <summary><b data-i18n>settings.freezeProtection.title</b></summary>
                <div class="grid">
                  <label>
                    <span data-i18n>settings.freezeProtection.lowTemp</span>
                    <input type="number" inputmode="numeric" name="heating[freezeProtection][lowTemp]" min="0" max="0" step="1" required>
                  </label>
                  <label>
                    <span data-i18n>settings.freezeProtection.thresholdTime</span>
                    <input type="number" inputmode="numeric" name="heating[freezeProtection][thresholdTime]" min="30" max="1800" step="1" required>
                  </label>
                </div>
                <small data-i18n>settings.freezeProtection.desc</small>
              </details>
              <br />
              <button type="submit" data-i18n>button.save</button>
            </form>
@@ -309,30 +236,6 @@
                <input type="number" inputmode="numeric" name="dhw[maxModulation]" min="1" max="100" step="1" required>
              </label>
              <hr />
              <details>
                <summary><b data-i18n>settings.ohProtection.title</b></summary>
                <div class="grid">
                  <label>
                    <span data-i18n>settings.ohProtection.highTemp.title</span>
                    <input type="number" inputmode="numeric" name="dhw[overheatProtection][highTemp]" min="0" max="0" step="1" required>
                    <small data-i18n>settings.ohProtection.highTemp.note</small>
                  </label>
                  <label>
                    <span data-i18n>settings.ohProtection.lowTemp.title</span>
                    <input type="number" inputmode="numeric" name="dhw[overheatProtection][lowTemp]" min="0" max="0" step="1" required>
                    <small data-i18n>settings.ohProtection.lowTemp.note</small>
                  </label>
                </div>
                <small data-i18n>settings.ohProtection.desc</small>
              </details>
              <br />
              <button type="submit" data-i18n>button.save</button>
            </form>
          </div>
@@ -603,15 +506,9 @@
                </label>
              </div>
              <details>
                <summary><b data-i18n>settings.ot.options.title</b></summary>
                <div>
              <fieldset>
-                    <small data-i18n>settings.ot.options.desc</small>
+                <legend data-i18n>settings.ot.options.desc</legend>
                  </fieldset>
                  <fieldset>
                <label>
                  <input type="checkbox" name="opentherm[options][dhwSupport]" value="true">
                  <span data-i18n>settings.ot.options.dhwSupport</span>
@@ -652,11 +549,6 @@
                  <span data-i18n>settings.ot.options.dhwBlocking</span>
                </label>
                    <label>
                      <input type="checkbox" name="opentherm[options][dhwStateAsDhwBlocking]" value="true">
                      <span data-i18n>settings.ot.options.dhwStateAsDhwBlocking</span>
                    </label>
                <label>
                  <input type="checkbox" name="opentherm[options][maxTempSyncWithTargetTemp]" value="true">
                  <span data-i18n>settings.ot.options.maxTempSyncWithTargetTemp</span>
@@ -687,28 +579,19 @@
                  <span data-i18n>settings.ot.options.setDateAndTime</span>
                </label>
                    <label>
                      <input type="checkbox" name="opentherm[options][alwaysSetIndoorTemp]" value="true">
                      <span data-i18n>settings.ot.options.alwaysSetIndoorTemp</span>
                    </label>
                <label>
                  <input type="checkbox" name="opentherm[options][immergasFix]" value="true">
                  <span data-i18n>settings.ot.options.immergasFix</span>
                </label>
                <hr />
                <label>
                  <input type="checkbox" name="opentherm[options][nativeHeatingControl]" value="true">
                  <span data-i18n>settings.ot.nativeHeating.title</span><br />
                  <small data-i18n>settings.ot.nativeHeating.note</small>
                </label>
              </fieldset>
                </div>
              </details>
              <br />
              <button type="submit" data-i18n>button.save</button>
            </form>
          </div>
@@ -786,11 +669,6 @@
                  <input type="checkbox" name="externalPump[use]" value="true">
                  <span data-i18n>settings.extPump.use</span>
                </label>
                <label>
                  <input type="checkbox" name="externalPump[invertState]" value="true">
                  <span data-i18n>settings.externalPump.invertState</span>
                </label>
              </fieldset>
              <div class="grid">
@@ -935,8 +813,7 @@
          unitSystem: null,
          targetTemp: null,
          minTemp: null,
-          maxTemp: null,
+          maxTemp: null
          decimated: false
        };
        const hasNeedDecimationChart = () => {
@@ -996,6 +873,12 @@
                    },
                    legend: {
                      display: false
                    },
                    decimation: {
                      enabled: hasNeedDecimationChart(),
                      algorithm: 'lttb',
                      samples: 30,
                      threshold: 30
                    }
                  },
                  scales: {
@@ -1041,18 +924,19 @@
            return;
          }
-          let data = [];
+          while (etChart.data.datasets[0].data.length) {
-          etChartConfig.decimated = hasNeedDecimationChart();
+            etChart.data.datasets[0].data.pop();
-          for (let value = 30; value >= -30; value -= etChartConfig.decimated ? 2 : 1) {
+          }
          for (let value = 30; value >= -30; value--) {
            const outdoorTemp = etChartConfig.unitSystem == 0 ? value : c2f(value);
-            data.push({
+            etChart.data.datasets[0].data.push({
              x: parseFloat(outdoorTemp.toFixed(1)),
              y: parseFloat(calculateEquithermTemp(outdoorTemp).toFixed(1))
            });
          }
          etChart.data.datasets[0].data = data;
          etChart.data.datasets[0].label = i18n("settings.equitherm.chart.setpointTemp");
          etChart.options.scales.x.title.text = i18n("settings.equitherm.chart.outdoorTemp");
          etChart.options.scales.y.title.text = i18n("settings.equitherm.chart.setpointTemp");
@@ -1115,14 +999,12 @@
          setCheckboxValue("[name='opentherm[options][heatingToCh2]']", data.opentherm.options.heatingToCh2);
          setCheckboxValue("[name='opentherm[options][dhwToCh2]']", data.opentherm.options.dhwToCh2);
          setCheckboxValue("[name='opentherm[options][dhwBlocking]']", data.opentherm.options.dhwBlocking);
          setCheckboxValue("[name='opentherm[options][dhwStateAsDhwBlocking]']", data.opentherm.options.dhwStateAsDhwBlocking);
          setCheckboxValue("[name='opentherm[options][maxTempSyncWithTargetTemp]']", data.opentherm.options.maxTempSyncWithTargetTemp);
          setCheckboxValue("[name='opentherm[options][getMinMaxTemp]']", data.opentherm.options.getMinMaxTemp);
          setCheckboxValue("[name='opentherm[options][ignoreDiagState]']", data.opentherm.options.ignoreDiagState);
          setCheckboxValue("[name='opentherm[options][autoFaultReset]']", data.opentherm.options.autoFaultReset);
          setCheckboxValue("[name='opentherm[options][autoDiagReset]']", data.opentherm.options.autoDiagReset);
          setCheckboxValue("[name='opentherm[options][setDateAndTime]']", data.opentherm.options.setDateAndTime);
          setCheckboxValue("[name='opentherm[options][alwaysSetIndoorTemp]']", data.opentherm.options.alwaysSetIndoorTemp);
          setCheckboxValue("[name='opentherm[options][nativeHeatingControl]']", data.opentherm.options.nativeHeatingControl);
          setCheckboxValue("[name='opentherm[options][immergasFix]']", data.opentherm.options.immergasFix);
          setBusy('#ot-settings-busy', '#ot-settings', false);
@@ -1141,7 +1023,6 @@
          // Extpump
          setCheckboxValue("[name='externalPump[use]']", data.externalPump.use);
          setInputValue("[name='externalPump[gpio]']", data.externalPump.gpio < 255 ? data.externalPump.gpio : '');
          setCheckboxValue("[name='externalPump[invertState]']", data.externalPump.invertState);
          setInputValue("[name='externalPump[postCirculationTime]']", data.externalPump.postCirculationTime);
          setInputValue("[name='externalPump[antiStuckInterval]']", data.externalPump.antiStuckInterval);
          setInputValue("[name='externalPump[antiStuckTime]']", data.externalPump.antiStuckTime);
@@ -1171,24 +1052,9 @@
            "min": data.system.unitSystem == 0 ? 1 : 33,
            "max": data.system.unitSystem == 0 ? 100 : 212
          });
-          setCheckboxValue("[name='heating[hysteresis][enabled]']", data.heating.hysteresis.enabled);
+          setInputValue("[name='heating[hysteresis]']", data.heating.hysteresis);
          setInputValue("[name='heating[hysteresis][value]']", data.heating.hysteresis.value);
          setSelectValue("[name='heating[hysteresis][action]']", data.heating.hysteresis.action);
          setInputValue("[name='heating[turboFactor]']", data.heating.turboFactor);
          setInputValue("[name='heating[maxModulation]']", data.heating.maxModulation);
          setInputValue("[name='heating[overheatProtection][highTemp]']", data.heating.overheatProtection.highTemp, {
            "min": 0,
            "max": data.system.unitSystem == 0 ? 100 : 212
          });
          setInputValue("[name='heating[overheatProtection][lowTemp]']", data.heating.overheatProtection.lowTemp, {
            "min": 0,
            "max": data.system.unitSystem == 0 ? 99 : 211
          });
          setInputValue("[name='heating[freezeProtection][lowTemp]']", data.heating.freezeProtection.lowTemp, {
            "min": data.system.unitSystem == 0 ? 1 : 34,
            "max": data.system.unitSystem == 0 ? 30 : 86
          });
          setInputValue("[name='heating[freezeProtection][thresholdTime]']", data.heating.freezeProtection.thresholdTime);
          setBusy('#heating-settings-busy', '#heating-settings', false);
          // DHW
@@ -1201,21 +1067,14 @@
            "max": data.system.unitSystem == 0 ? 100 : 212
          });
          setInputValue("[name='dhw[maxModulation]']", data.dhw.maxModulation);
          setInputValue("[name='dhw[overheatProtection][highTemp]']", data.dhw.overheatProtection.highTemp, {
            "min": 0,
            "max": data.system.unitSystem == 0 ? 100 : 212
          });
          setInputValue("[name='dhw[overheatProtection][lowTemp]']", data.dhw.overheatProtection.lowTemp, {
            "min": 0,
            "max": data.system.unitSystem == 0 ? 99 : 211
          });
          setBusy('#dhw-settings-busy', '#dhw-settings', false);
          // Emergency mode
          setInputValue("[name='emergency[tresholdTime]']", data.emergency.tresholdTime);
          if (data.opentherm.options.nativeHeatingControl) {
            setInputValue("[name='emergency[target]']", data.emergency.target, {
              "min": data.system.unitSystem == 0 ? 5 : 41,
-              "max": data.system.unitSystem == 0 ? 40 : 104
+              "max": data.system.unitSystem == 0 ? 40 : 86
            });
          } else {
@@ -1224,7 +1083,7 @@
              "max": data.heating.maxTemp,
            });
          }
-          setInputValue("[name='emergency[tresholdTime]']", data.emergency.tresholdTime);
+
          setBusy('#emergency-settings-busy', '#emergency-settings', false);
          // Equitherm
@@ -1372,8 +1231,9 @@
          if (etChart) {
            etChart.resize();
-            if (etChartConfig.decimated != hasNeedDecimationChart()) {
+            if (etChart.options.plugins.decimation.enabled != hasNeedDecimationChart()) {
-              makeEquithermChart();
+              etChart.options.plugins.decimation.enabled = hasNeedDecimationChart();
              etChart.update();
            }
          }
        });
--- a/src_data/pages/upgrade.html
+++ b/src_data/pages/upgrade.html
@@ -21,9 +21,7 @@
          <li>
            <select id="lang" aria-label="Lang">
              <option value="en" selected>EN</option>
              <option value="cn">CN</option>
              <option value="it">IT</option>
              <option value="nl">NL</option>
              <option value="ru">RU</option>
            </select>
          </li>
--- a/src_data/scripts/chart.js
+++ b/src_data/scripts/chart.js
--- a/src_data/styles/app.css
+++ b/src_data/styles/app.css
@@ -3,10 +3,6 @@
    --pico-block-spacing-vertical: calc(var(--pico-spacing) * 0.75);
    --pico-block-spacing-horizontal: calc(var(--pico-spacing) * 0.75);
  }
  .logo {
    font-size: 1.2rem;
  }
 }
@media (min-width: 768px) {
@@ -14,10 +10,6 @@
    --pico-block-spacing-vertical: var(--pico-spacing);
    --pico-block-spacing-horizontal: var(--pico-spacing);
  }
  .logo {
    font-size: 1.25rem;
  }
 }
@media (min-width: 1024px) {
@@ -25,10 +17,6 @@
    --pico-block-spacing-vertical: calc(var(--pico-spacing) * 1.25);
    --pico-block-spacing-horizontal: calc(var(--pico-spacing) * 1.25);
  }
  .logo {
    font-size: 1.25rem;
  }
 }
@media (min-width: 1280px) {
@@ -37,10 +25,6 @@
    --pico-block-spacing-horizontal: calc(var(--pico-spacing) * 1.5);
  }
  .logo {
    font-size: 1.3rem;
  }
  .container {
    max-width: 1000px;
  }
@@ -52,10 +36,6 @@
    --pico-block-spacing-horizontal: calc(var(--pico-spacing) * 1.75);
  }
  .logo {
    font-size: 1.3rem;
  }
  .container {
    max-width: 1000px;
  }
@@ -131,7 +111,7 @@ tr.network:hover {
  border-radius: var(--pico-border-radius);
  color: var(--pico-code-kbd-color);
  font-weight: bolder;
-  /*font-size: 1.3rem;*/
+  font-size: 1.3rem;
  font-family: var(--pico-font-family-monospace);
 }
--- a/tools/esp32.py
+++ b/tools/esp32.py
@@ -23,15 +23,10 @@ Import("env")
 platform = env.PioPlatform()
 import sys
 import os
 import subprocess
 from os.path import join
-def normalize_paths(cmd):
+sys.path.append(join(platform.get_package_dir("tool-esptoolpy")))
-    for i, arg in enumerate(cmd):
+import esptool
        if isinstance(arg, str) and '/' in arg:
            cmd[i] = os.path.normpath(arg)
    return cmd
 def esp32_create_combined_bin(source, target, env):
    print("Generating combined binary for serial flashing")
@@ -44,21 +39,26 @@ def esp32_create_combined_bin(source, target, env):
    sections = env.subst(env.get("FLASH_EXTRA_IMAGES"))
    firmware_name = env.subst("$BUILD_DIR/${PROGNAME}.bin")
    chip = env.get("BOARD_MCU")
-    flash_size = env.BoardConfig().get("upload.flash_size", "4MB")
+    flash_size = env.BoardConfig().get("upload.flash_size")
-    flash_mode = env["__get_board_flash_mode"](env)
+    flash_freq = env.BoardConfig().get("build.f_flash", '40m')
-    flash_freq = env["__get_board_f_flash"](env)
+    flash_freq = flash_freq.replace('000000L', 'm')
-
+    flash_mode = env.BoardConfig().get("build.flash_mode", "dio")
    memory_type = env.BoardConfig().get("build.arduino.memory_type", "qio_qspi")
    if flash_mode == "qio" or flash_mode == "qout":
        flash_mode = "dio"
    if memory_type == "opi_opi" or memory_type == "opi_qspi":
        flash_mode = "dout"
    cmd = [
        "--chip",
        chip,
-        "merge-bin",
+        "merge_bin",
        "-o",
        new_file_name,
-        "--flash-mode",
+        "--flash_mode",
        flash_mode,
-        "--flash-freq",
+        "--flash_freq",
        flash_freq,
-        "--flash-size",
+        "--flash_size",
        flash_size,
    ]
@@ -71,12 +71,9 @@ def esp32_create_combined_bin(source, target, env):
    print(f" - {hex(app_offset)} | {firmware_name}")
    cmd += [hex(app_offset), firmware_name]
-    # print('Using esptool.py arguments: %s' % ' '.join(cmd))
+    print('Using esptool.py arguments: %s' % ' '.join(cmd))
-    cmdline = [env.subst("$OBJCOPY")] + normalize_paths(cmd)
+
-    print('Command Line: %s' % cmdline)
+    esptool.main(cmd)
    result = subprocess.run(cmdline, text=True, check=False, stdout=subprocess.DEVNULL)
    if result.returncode != 0:
        print(f"esptool create firmware failed with exit code: {result.returncode}")
 env.AddPostAction("$BUILD_DIR/${PROGNAME}.bin", esp32_create_combined_bin)
Author	SHA1	Message	Date
Yurii	9577dc9f6f	Merge `06c2ddcf96` into `8b50ed48c1`	2025-05-20 22:22:18 +00:00
Yurii	06c2ddcf96	Merge branch 'master' into new-equitherm	2025-05-21 01:20:55 +03:00
Yurii	0bb05006f4	Merge branch 'master' into new-equitherm	2025-05-19 23:45:13 +03:00
Yurii	5046bc0e8f	Merge branch 'master' into new-equitherm	2025-05-19 22:49:09 +03:00
P43YM	0d3adad446	refactor: added notes for equitherm parameters	2025-03-18 09:38:09 +03:00
Yurii	587678f184	Merge branch 'master' into new-equitherm	2025-03-06 04:52:12 +03:00
Yurii	72235286c0	chore: resolve conflicts	2025-03-06 04:50:02 +03:00
Yurii	ee868b22ce	chore: remove unused files	2025-03-04 21:31:44 +03:00
Yurii	8046a7e13f	refactor: cosmetic changes	2025-03-03 04:03:08 +03:00
Yurii	0ec1fc5f24	chore: fix typo	2025-03-03 02:26:09 +03:00
Yurii	061136b13e	refactor: cosmetic changes (equitherm chart)	2025-03-03 02:05:33 +03:00
Yurii	3e61dabeab	refactor: refactoring after #144	2025-03-02 22:44:53 +03:00
P43YM	e5f4281d4c	feat: new equitherm algorithm and chart for it (#144 )	2025-02-28 23:21:55 +03:00