The document provides instructions for setting up and using the Fibaro Motion Sensor, a Z-Wave multi-sensor device that detects motion, temperature, and light levels. It can be installed quickly on any surface and includes a battery, motion detector, light sensor, and LED indicator. The sensor can be added to a Z-Wave network to trigger lighting scenes and security systems based on motion or temperature changes.
3 in 1 multi sensor Philio PSM01 (door, window, temperature, lightness) manualDomotica daVinci
The slim multi-sensor PSM01 has three sensors - door/window, temperature, and illumination - in one device. It uses Z-Wave wireless technology to connect to a home automation network and controller. The device can detect door/window openings, temperature changes, and light levels, and report this information to the controller. It also has capabilities for controlling connected lights based on sensor readings and settings. The document provides detailed information on configuring, installing, and operating the multi-sensor device on a Z-Wave wireless home automation network.
The MIMOlite module is a wireless interface/bridge module that provides one analog or digital input and one relay output. It can be controlled via Z-Wave and includes status lights to indicate inclusion in a network. The module converts an input signal to a digital value and allows the input trigger levels and relay operation to be configured for flexibility. It has been certified for use in the US, EU, and other regions.
The Illumination Sensor is a Z-Wave enabled device that monitors ambient light levels. It can be configured to trigger alerts when the light level rises above or falls below set thresholds. When triggered, it will send RF signals to associated Z-Wave devices. It has options to set countdown timers, enable/disable radio signals and beep tones. The sensor supports inclusion and exclusion from Z-Wave networks and can associate with other devices to trigger automations.
This document provides information about a remotely controlled light dimming module. The dimmer module can be connected to two-wire or three-wire cable to operate with or without a neutral lead. It can switch or dim connected light sources via radio waves or an external wall switch. The dimmer is equipped with an algorithm to automatically detect the connected light source type to make configuration easier. It can operate various light sources including incandescent, halogen, LED, CFL, and dimmable fluorescent lights. The dimmer module has specifications for power supply, consumption, temperature range, dimensions, load current, and radio frequency protocol. It also provides instructions for installation, inclusion into a Z-Wave network, resetting, and
The document provides instructions for the ZXT-120 Z-Wave to AC IR Extender. It can be used to control IR-controlled air conditioners using Z-Wave commands from a controller. It has a built-in IR code library and temperature sensor. The document discusses including the ZXT-120 in a Z-Wave network, configuring its IR codes and operating modes, learning new IR codes, and resetting it to factory defaults. Safety precautions are provided for mounting the ZXT-120 to a wall.
Manual Outdoor motion detector Z-Wave Plus - PhilioDomotica daVinci
The motion sensor uses Z-Wave wireless technology to detect motion. It can be included in a Z-Wave network to remotely control devices. The sensor detects motion using a PIR sensor and supports two operation modes. It can associate with other devices and report events wirelessly. The device settings can be configured including sensitivity, detection interval, and auto reporting frequency.
The document provides information about a Z-Wave glass surface 4 channel touch panel switch, including:
1. It can switch 4 separate loads up to 1100W and includes or excludes from the Z-Wave network by pressing any key for 3 seconds.
2. As a Z-Wave device, it can control or be controlled by other Z-Wave devices and supports association groups to send commands to associated devices.
3. It has 4 groups to switch associated devices and 1 group to report state changes to the controller.
3 in 1 multi sensor Philio PSM01 (door, window, temperature, lightness) manualDomotica daVinci
The slim multi-sensor PSM01 has three sensors - door/window, temperature, and illumination - in one device. It uses Z-Wave wireless technology to connect to a home automation network and controller. The device can detect door/window openings, temperature changes, and light levels, and report this information to the controller. It also has capabilities for controlling connected lights based on sensor readings and settings. The document provides detailed information on configuring, installing, and operating the multi-sensor device on a Z-Wave wireless home automation network.
The MIMOlite module is a wireless interface/bridge module that provides one analog or digital input and one relay output. It can be controlled via Z-Wave and includes status lights to indicate inclusion in a network. The module converts an input signal to a digital value and allows the input trigger levels and relay operation to be configured for flexibility. It has been certified for use in the US, EU, and other regions.
The Illumination Sensor is a Z-Wave enabled device that monitors ambient light levels. It can be configured to trigger alerts when the light level rises above or falls below set thresholds. When triggered, it will send RF signals to associated Z-Wave devices. It has options to set countdown timers, enable/disable radio signals and beep tones. The sensor supports inclusion and exclusion from Z-Wave networks and can associate with other devices to trigger automations.
This document provides information about a remotely controlled light dimming module. The dimmer module can be connected to two-wire or three-wire cable to operate with or without a neutral lead. It can switch or dim connected light sources via radio waves or an external wall switch. The dimmer is equipped with an algorithm to automatically detect the connected light source type to make configuration easier. It can operate various light sources including incandescent, halogen, LED, CFL, and dimmable fluorescent lights. The dimmer module has specifications for power supply, consumption, temperature range, dimensions, load current, and radio frequency protocol. It also provides instructions for installation, inclusion into a Z-Wave network, resetting, and
The document provides instructions for the ZXT-120 Z-Wave to AC IR Extender. It can be used to control IR-controlled air conditioners using Z-Wave commands from a controller. It has a built-in IR code library and temperature sensor. The document discusses including the ZXT-120 in a Z-Wave network, configuring its IR codes and operating modes, learning new IR codes, and resetting it to factory defaults. Safety precautions are provided for mounting the ZXT-120 to a wall.
Manual Outdoor motion detector Z-Wave Plus - PhilioDomotica daVinci
The motion sensor uses Z-Wave wireless technology to detect motion. It can be included in a Z-Wave network to remotely control devices. The sensor detects motion using a PIR sensor and supports two operation modes. It can associate with other devices and report events wirelessly. The device settings can be configured including sensitivity, detection interval, and auto reporting frequency.
The document provides information about a Z-Wave glass surface 4 channel touch panel switch, including:
1. It can switch 4 separate loads up to 1100W and includes or excludes from the Z-Wave network by pressing any key for 3 seconds.
2. As a Z-Wave device, it can control or be controlled by other Z-Wave devices and supports association groups to send commands to associated devices.
3. It has 4 groups to switch associated devices and 1 group to report state changes to the controller.
Door sensor multisensor 4_ in_1 Zipato Z-Wave PlusDomotica daVinci
This document provides information about Zipato trademarks, product names, notices, electromagnetic compatibility, safety, and the specifications, features, and operation of the Zipato Multisensor 4 in 1 device. It includes sections on trademarks, notices, EMC compliance, safety precautions, introduction to the product, specifications, technical specs, models and frequencies, installation instructions, packaging contents, features, and troubleshooting. The document is the product manual for the Zipato Multisensor 4 in 1, a Z-Wave enabled multi-sensor device.
The document provides an operating manual for the Fibaro Flood Sensor, a Z-Wave compatible flood and temperature sensor that can be powered by batteries or 12/24 VDC. It has a built-in temperature sensor, tilt sensor, and LED indicator. The manual describes how to include/exclude the sensor from the Z-Wave network, install it, reset it, and power it in battery or constant power modes. Diagrams show how to connect it to an alarm system or power source.
The document provides operating instructions for a universal roller shutter that can be controlled via Z-Wave network or external switch. It describes the device's electrical connections, installation process, inclusion into a Z-Wave network, associations with other devices, and configuration via parameters to customize its control behavior. Resetting the device to factory settings can be done by removing it from the network, pressing the external switch buttons in a specific pattern, or changing a parameter.
Fibaro RGBW Controller is a universal Z-Wave compatible RGB/RGBW controller that uses PWM output signals to control LED, RGB, RGBW strips, halogen lights, and fans powered by 12 or 24 VDC. It also supports up to four 0V-10V analog sensors. The controller has multiple operating modes including RGB/RGBW for lighting control and IN/OUT mode for independent configuration of inputs and outputs. It provides current load and energy consumption monitoring and can be included in a Z-Wave network to be controlled by compatible controllers and associated with other Z-Wave devices.
The document provides specifications for a Z-Wave multi-sensor device. It includes details on the device's library and command classes, Z-Wave network operation including button functions and LED indicators, association groups and commands, wakeup settings, battery information, sensor readings for temperature, humidity, light and UV, notification types, manufacturer information, and configuration parameters.
The document provides instructions for installing and operating the TZ66-D ON/OFF MODULE, a radio frequency controlled, 6A, 230 VAC, European wall mounted 3-way switch. It can be used to control lights and other Z-Wave enabled devices. The switch has two sides that can be used to control up to 5 associated Z-Wave devices each in 4 groups through tapping or holding the switch. The document outlines wiring, inclusion, exclusion, basic and advanced operation including association, configuration, and LED indicators.
wiDom Energy Driven Switch C version and L version manualDomotica daVinci
The document provides installation and operating instructions for an Energy Driven Switch. It includes:
1) A description of the device, specifications, and electrical connections.
2) Instructions for installing the device, including warnings about safety and qualified electricians.
3) Details on the device's energy management capabilities like load control based on power thresholds.
This document provides information about a Z-Wave DIN dimmer module used for dimming lights and fans. The module can be controlled through a Z-Wave network or wall switch. It measures power consumption and supports connecting a temperature sensor. The module is small, designed to mount on a DIN rail, and can act as a repeater to improve the Z-Wave network range. Technical specifications, diagrams, instructions and configuration parameters are provided.
Mini Zipato drive with energy measurement allows the variation in your interior lighting to create a pleasant atmosphere in your home and also help you to reduce your energy consumption. Actually it is able to transmit the instantaneous power consumption (W) and cumulative (KWh) of equipment attached to it.
Fibaro Roller Shutter is a Z-Wave compatible electric motor controller that allows precise positioning of roller blinds, awnings, venetian blinds, gates and other AC powered motors. It can be controlled wirelessly through a Z-Wave network or via switch keys connected to it. The device also measures the connected motor's current power consumption. It supports electronic and mechanic end switches and can control motors of up to 1kW for 230V or 500W for 110V power supply.
This document provides information about a Z-Wave water meter sensor with firmware version 3.0. The sensor fits into water meters from Sensus and transmits meter readings via the Z-Wave network on a timed or delta change basis. It uses a lithium battery that provides an estimated 10 years of battery life. The sensor can be included and excluded from a Z-Wave network by placing a magnet on it for 3 seconds until the LED blinks red. It supports configuration of parameters like the reading reporting interval and wakeup interval to communicate with controllers.
This document provides instructions for a Z-Wave window blind actuator. The actuator can be included in a Z-Wave network by triple clicking a button and will indicate inclusion with a green LED blink. It controls 230V motors for blinds and calibration is required by moving the blind to upper and lower positions. The actuator has basic on/off association for controlling other nodes.
This device is a portable Z-Wave wall controller that can control other Z-Wave devices and act as a primary or secondary controller in a Z-Wave network. It includes devices by pressing the Include button for 2 seconds and issues node information frames with triple clicks of the Up/Down buttons. The controller runs on 2 AAA batteries and can be mounted on flat surfaces.
This document provides instructions for installing and operating a Z-Wave enabled in-wall roller shutter controller. The controller can switch a connected roller shutter up and down using radio signals, or a directly connected push button. It performs a calibration process to learn the shutter's range of motion and can then remotely position the shutter or report its position. The controller includes and excludes from Z-Wave networks, and supports basic switch and multilevel switch commands to control the shutter.
Qubino flush dimmer 0 10-v plus user manual_v1.0_engDomotica daVinci
The document describes the Qubino Flush Dimmer 0-10V, a Z-Wave compatible dimmer module with a 0-10V output and multi-function input. It can be controlled via push button, potentiometer, or 0-10V signal. The module includes to a Z-Wave network and supports association groups to control other devices. It has configuration parameters to set functions like input type, auto on/off times, minimum/maximum dimming levels, and sensor reporting thresholds.
The document provides an operating manual for a Scene Controller device that can:
1. Control Z-Wave devices like smart plugs and dimmers through a Z-Wave gateway and activate scenes with four buttons.
2. Be included in a Z-Wave network to remotely control devices anywhere and supports low battery and communication failure alarms.
3. Be reset by holding the Z-button for 20 seconds to clear network information and reset to factory defaults.
This document provides instructions for using a Zipato Z-Wave Remote control. It summarizes that the remote can control AV devices through a Z-Wave to IR extender and control 8 lighting groups. It provides details on inclusion, exclusion, resetting, and association procedures. It also specifies the remote's technical specifications, features, and overview.
This document summarizes the features and functionality of an in-wall dual relay switch module. The module contains two relays that can be used to control AC power to loads like lights. It supports inclusion and exclusion from Z-Wave networks as well as basic on/off control. The module can also monitor power usage of connected loads and report this data to the Z-Wave controller. It supports association groups to send reports to other devices and responds to metering commands to provide power readings.
This document summarizes the features and specifications of the Slim Multi-Sensor PSP01, a Z-Wave enabled motion, temperature, and light sensor. It has PIR, temperature and light sensors integrated into one device. It can be included into a Z-Wave home automation network to detect motion and changes in temperature or light levels and send notifications to other devices. It supports various configuration settings to customize its operation and reporting.
This document provides instructions for setting up and operating a Zipato indoor siren device. It includes directions on powering on the device, adding it to a Z-Wave network, updating its firmware over-the-air, and configuring its alarm sounds and notifications. The document also provides specifications for the device, including its operating temperature range, dimensions, weight, supported Z-Wave command classes, and frequency versions for different regions.
This document provides installation and operation instructions for the Fibaro Smoke Sensor. It includes:
1) Details on how to include the sensor in a Z-Wave network either automatically or manually and exclude it from the network.
2) An overview of the sensor's operation modes, smoke and temperature detection functionality, and ability to detect lack of Z-Wave range.
3) Guidelines for installing the sensor properly and configuring its sensitivity level.
1) The document provides instructions for replacing the battery in a Fibaro Smoke Sensor smoke detector. It describes detaching the sensor from its cover, removing the old battery, inserting a new battery while observing polarity, and reattaching the sensor to the cover.
2) The Fibaro Smoke Sensor is an optical smoke detector that detects smoke and sends alarm signals via sound, light, and Z-Wave commands. It can also monitor temperature and send warnings if thresholds are exceeded.
3) The instructions describe testing the sensor after battery replacement by performing a self-test where the sensor checks its operation and signals via light and sound.
Door sensor multisensor 4_ in_1 Zipato Z-Wave PlusDomotica daVinci
This document provides information about Zipato trademarks, product names, notices, electromagnetic compatibility, safety, and the specifications, features, and operation of the Zipato Multisensor 4 in 1 device. It includes sections on trademarks, notices, EMC compliance, safety precautions, introduction to the product, specifications, technical specs, models and frequencies, installation instructions, packaging contents, features, and troubleshooting. The document is the product manual for the Zipato Multisensor 4 in 1, a Z-Wave enabled multi-sensor device.
The document provides an operating manual for the Fibaro Flood Sensor, a Z-Wave compatible flood and temperature sensor that can be powered by batteries or 12/24 VDC. It has a built-in temperature sensor, tilt sensor, and LED indicator. The manual describes how to include/exclude the sensor from the Z-Wave network, install it, reset it, and power it in battery or constant power modes. Diagrams show how to connect it to an alarm system or power source.
The document provides operating instructions for a universal roller shutter that can be controlled via Z-Wave network or external switch. It describes the device's electrical connections, installation process, inclusion into a Z-Wave network, associations with other devices, and configuration via parameters to customize its control behavior. Resetting the device to factory settings can be done by removing it from the network, pressing the external switch buttons in a specific pattern, or changing a parameter.
Fibaro RGBW Controller is a universal Z-Wave compatible RGB/RGBW controller that uses PWM output signals to control LED, RGB, RGBW strips, halogen lights, and fans powered by 12 or 24 VDC. It also supports up to four 0V-10V analog sensors. The controller has multiple operating modes including RGB/RGBW for lighting control and IN/OUT mode for independent configuration of inputs and outputs. It provides current load and energy consumption monitoring and can be included in a Z-Wave network to be controlled by compatible controllers and associated with other Z-Wave devices.
The document provides specifications for a Z-Wave multi-sensor device. It includes details on the device's library and command classes, Z-Wave network operation including button functions and LED indicators, association groups and commands, wakeup settings, battery information, sensor readings for temperature, humidity, light and UV, notification types, manufacturer information, and configuration parameters.
The document provides instructions for installing and operating the TZ66-D ON/OFF MODULE, a radio frequency controlled, 6A, 230 VAC, European wall mounted 3-way switch. It can be used to control lights and other Z-Wave enabled devices. The switch has two sides that can be used to control up to 5 associated Z-Wave devices each in 4 groups through tapping or holding the switch. The document outlines wiring, inclusion, exclusion, basic and advanced operation including association, configuration, and LED indicators.
wiDom Energy Driven Switch C version and L version manualDomotica daVinci
The document provides installation and operating instructions for an Energy Driven Switch. It includes:
1) A description of the device, specifications, and electrical connections.
2) Instructions for installing the device, including warnings about safety and qualified electricians.
3) Details on the device's energy management capabilities like load control based on power thresholds.
This document provides information about a Z-Wave DIN dimmer module used for dimming lights and fans. The module can be controlled through a Z-Wave network or wall switch. It measures power consumption and supports connecting a temperature sensor. The module is small, designed to mount on a DIN rail, and can act as a repeater to improve the Z-Wave network range. Technical specifications, diagrams, instructions and configuration parameters are provided.
Mini Zipato drive with energy measurement allows the variation in your interior lighting to create a pleasant atmosphere in your home and also help you to reduce your energy consumption. Actually it is able to transmit the instantaneous power consumption (W) and cumulative (KWh) of equipment attached to it.
Fibaro Roller Shutter is a Z-Wave compatible electric motor controller that allows precise positioning of roller blinds, awnings, venetian blinds, gates and other AC powered motors. It can be controlled wirelessly through a Z-Wave network or via switch keys connected to it. The device also measures the connected motor's current power consumption. It supports electronic and mechanic end switches and can control motors of up to 1kW for 230V or 500W for 110V power supply.
This document provides information about a Z-Wave water meter sensor with firmware version 3.0. The sensor fits into water meters from Sensus and transmits meter readings via the Z-Wave network on a timed or delta change basis. It uses a lithium battery that provides an estimated 10 years of battery life. The sensor can be included and excluded from a Z-Wave network by placing a magnet on it for 3 seconds until the LED blinks red. It supports configuration of parameters like the reading reporting interval and wakeup interval to communicate with controllers.
This document provides instructions for a Z-Wave window blind actuator. The actuator can be included in a Z-Wave network by triple clicking a button and will indicate inclusion with a green LED blink. It controls 230V motors for blinds and calibration is required by moving the blind to upper and lower positions. The actuator has basic on/off association for controlling other nodes.
This device is a portable Z-Wave wall controller that can control other Z-Wave devices and act as a primary or secondary controller in a Z-Wave network. It includes devices by pressing the Include button for 2 seconds and issues node information frames with triple clicks of the Up/Down buttons. The controller runs on 2 AAA batteries and can be mounted on flat surfaces.
This document provides instructions for installing and operating a Z-Wave enabled in-wall roller shutter controller. The controller can switch a connected roller shutter up and down using radio signals, or a directly connected push button. It performs a calibration process to learn the shutter's range of motion and can then remotely position the shutter or report its position. The controller includes and excludes from Z-Wave networks, and supports basic switch and multilevel switch commands to control the shutter.
Qubino flush dimmer 0 10-v plus user manual_v1.0_engDomotica daVinci
The document describes the Qubino Flush Dimmer 0-10V, a Z-Wave compatible dimmer module with a 0-10V output and multi-function input. It can be controlled via push button, potentiometer, or 0-10V signal. The module includes to a Z-Wave network and supports association groups to control other devices. It has configuration parameters to set functions like input type, auto on/off times, minimum/maximum dimming levels, and sensor reporting thresholds.
The document provides an operating manual for a Scene Controller device that can:
1. Control Z-Wave devices like smart plugs and dimmers through a Z-Wave gateway and activate scenes with four buttons.
2. Be included in a Z-Wave network to remotely control devices anywhere and supports low battery and communication failure alarms.
3. Be reset by holding the Z-button for 20 seconds to clear network information and reset to factory defaults.
This document provides instructions for using a Zipato Z-Wave Remote control. It summarizes that the remote can control AV devices through a Z-Wave to IR extender and control 8 lighting groups. It provides details on inclusion, exclusion, resetting, and association procedures. It also specifies the remote's technical specifications, features, and overview.
This document summarizes the features and functionality of an in-wall dual relay switch module. The module contains two relays that can be used to control AC power to loads like lights. It supports inclusion and exclusion from Z-Wave networks as well as basic on/off control. The module can also monitor power usage of connected loads and report this data to the Z-Wave controller. It supports association groups to send reports to other devices and responds to metering commands to provide power readings.
This document summarizes the features and specifications of the Slim Multi-Sensor PSP01, a Z-Wave enabled motion, temperature, and light sensor. It has PIR, temperature and light sensors integrated into one device. It can be included into a Z-Wave home automation network to detect motion and changes in temperature or light levels and send notifications to other devices. It supports various configuration settings to customize its operation and reporting.
This document provides instructions for setting up and operating a Zipato indoor siren device. It includes directions on powering on the device, adding it to a Z-Wave network, updating its firmware over-the-air, and configuring its alarm sounds and notifications. The document also provides specifications for the device, including its operating temperature range, dimensions, weight, supported Z-Wave command classes, and frequency versions for different regions.
This document provides installation and operation instructions for the Fibaro Smoke Sensor. It includes:
1) Details on how to include the sensor in a Z-Wave network either automatically or manually and exclude it from the network.
2) An overview of the sensor's operation modes, smoke and temperature detection functionality, and ability to detect lack of Z-Wave range.
3) Guidelines for installing the sensor properly and configuring its sensitivity level.
1) The document provides instructions for replacing the battery in a Fibaro Smoke Sensor smoke detector. It describes detaching the sensor from its cover, removing the old battery, inserting a new battery while observing polarity, and reattaching the sensor to the cover.
2) The Fibaro Smoke Sensor is an optical smoke detector that detects smoke and sends alarm signals via sound, light, and Z-Wave commands. It can also monitor temperature and send warnings if thresholds are exceeded.
3) The instructions describe testing the sensor after battery replacement by performing a self-test where the sensor checks its operation and signals via light and sound.
This device is a Z-Wave carbon monoxide sensor that can be included in a Z-Wave network to wirelessly report carbon monoxide levels and alarm conditions. It combines a certified carbon monoxide detector with a Z-Wave module. When carbon monoxide levels reach certain thresholds, the sensor will send an alarm to the central controller and can trigger other Z-Wave devices. The sensor can also report tamper detection, low battery, and malfunctions.
Manual ES-12-ZIP-PD01Z PIR Z-Wave Plus motion sensorDomotica daVinci
The Zipato PIR Motion Sensor is a passive infrared sensor that detects motion within its detection range of 7 meters at a 110 degree viewing angle. It operates on a single CR123A battery for up to 1 year and communicates wirelessly via Z-Wave to notify a main controller when motion is detected, triggering associated devices. The sensor can be easily installed using included mounting hardware or adhesive and has adjustable settings that can be configured through the sensor's Z-Wave compatibility.
This smoke detector combines a 10-year smoke detector with a Z-Wave module to allow wireless alarm reporting and control of an indoor siren. It can detect smoke and send alarm messages to other Z-Wave devices. The battery in the Z-Wave module will need replacement before the 10-year battery in the smoke detector itself. The device can be included and excluded from a Z-Wave network by pressing the inclusion button, and supports secure communication between Z-Wave devices.
This document provides instructions for setting up and using a NEO CoolCam motion sensor that communicates using the Z-Wave wireless protocol. It includes steps for inserting batteries, including the sensor in a Z-Wave network, configuration parameters to customize sensor settings, and technical specifications. The sensor detects motion and sends notifications to associated Z-Wave devices.
The smoke detector Z-Wave detects fire and smoke emissions. In case of emergency, it gives an audible alert and sends an alarm signal to the Z-Wave network
Manual motion sensor with led spotlight xled home 2 - z-wave plus - steinelDomotica daVinci
This document summarizes a Steinel LED spotlight with a motion sensor that is compatible with Z-Wave wireless technology. The spotlight has a fully rotating LED panel and infrared motion sensor with wide detection angles. It can be controlled via app and integrated into a Z-Wave smart home network to add additional outdoor security. The device requires a 220-240V power supply and has an IP44 weather resistance rating.
Dry contact sensor with temperature sensor start guideDomotica daVinci
This document provides instructions for a Z-Wave binary sensor, thermostat, and temperature sensor device. It describes how to include the device in a Z-Wave network, set up its temperature monitoring and thermostat functions, and configure its battery-saving wakeup intervals. The document also summarizes the device's technical specifications and supported Z-Wave command classes.
The document is a product catalog for the FIBARO home intelligence system. It describes the FIBARO system as a complete home automation solution based on Z-Wave wireless technology. The system allows users to control connected devices remotely through apps. The catalog lists and describes FIBARO's devices such as sensors, controllers, switches and modules that make up the home automation system and can control lights, appliances, security systems and more.
This document provides information about a 10 year smoke detector and siren device that includes Z-Wave connectivity. It can detect smoke and wirelessly report an alarm, includes a replaceable battery, and can be included in a Z-Wave network to control other devices. The document outlines how to install, operate, and configure the device including resetting it and including/excluding it from the Z-Wave network.
This document provides product information for a 10 year smoke detector and siren with Z-Wave connectivity. It can detect smoke and wirelessly report alarms while also functioning as a controllable indoor siren. The detector uses a long-life battery while the Z-Wave module uses a replaceable battery. It can be included in a Z-Wave network to communicate with other devices and can trigger automated responses through associations. The document provides details on installation, operation, configuration parameters, and troubleshooting.
The document provides an operating manual for a Scene Controller device that can control Z-Wave devices and activate scenes wirelessly through a Z-Wave gateway. The Scene Controller uses a rechargeable battery, supports inclusion and exclusion from Z-Wave networks, and can control other devices through association groups activated by button presses of different lengths. It also describes resetting, low battery alerts, firmware updates, and testing network range functionality.
Product catalogue march_2014_final_smallYahia Ahmed
The document is a product catalog for FIBARO, a home automation system. It describes several key features:
1) FIBARO uses Z-Wave wireless technology to control electrical devices without interfering with building infrastructure. Miniature devices can be installed in wall sockets and switches.
2) The system includes control units that communicate wirelessly with devices to send commands, providing comfort, safety and remote control capabilities for users.
3) The Home Center 2 and Home Center Lite are hubs with intuitive interfaces to monitor and manage the system from phones, tablets, or computers remotely.
4) Various sensors and switches are described like the Wall Plug, Roller Shutter, Dimmer
This document provides information about a Z-Wave compatible smoke detector, including instructions for inclusion into a Z-Wave network, descriptions of its operating modes like alarm, low battery, and testing modes, and details about its configuration parameters and associations with other Z-Wave devices.
1) This document provides instructions for setting up and using a Hank motion sensor that uses Z-Wave technology for wireless communication.
2) It describes how to include the sensor in a Z-Wave network by putting the controller in add mode and pressing the sensor's Z-button, and explains the sensor's motion detection range and parameters that can be configured like sensitivity.
3) The technical specifications are also summarized, including the sensor's dimensions, battery type, supported command classes, and certifications.
This document provides an operating manual for the FIBARO Smart Implant device, which allows connecting various wired sensors to a Z-Wave network. The manual describes:
1) Main features of the device including supporting up to 6 temperature sensors and 2 each of analog, binary, and button inputs.
2) Installation instructions for connecting different sensor types like temperature, humidity, analog, binary, and buttons.
3) Instructions for adding the device to a Z-Wave network manually or via SmartStart and removing it from the network.
4) Details on the device's operation including button functions, menus, resetting, and testing.
This document provides instructions for installing and operating a Fibaro remotely controlled relay switch. The switch can control electric devices of up to 2.5kW and operates using radio signals. It has 2 terminals to control 2 circuits and supports inclusion in a Z-Wave home automation network to enable remote control. The summary provides key installation steps and configuration options for settings like alarm responses, auto-off times, and switch type (momentary or toggle).
This document provides information about the Hank Flood Sensor device, including how to include it in a Z-Wave network, its configuration parameters, technical specifications, and explanations of Z-Wave terminology. The sensor can detect leaks and floods and sends alerts. It uses the international Z-Wave protocol for wireless communication between smart home devices.
Ph pat02 - zipato flood multisensor 3 in 1 user manual v1.0Domotica daVinci
This document provides a summary of a quick installation guide for a Zipato Flood Multisensor 3 in 1 device. It includes sections on trademarks, notices, electromagnetic compatibility, safety, introduction, mounting, power up procedure, adding to a Z-Wave network, configuration settings, and specifications. The guide provides instructions on installing, setting up, and integrating the flood, temperature, and humidity sensor device into a Z-Wave home automation network.
The 2CH Dimmer Module allows manual control of lights through a push switch and app control. It can control up to two lighting circuits and provides options for permanent on/off or dimming control through short or long button pushes. Installation requires turning off power and properly wiring the unit according to diagrams. The module can be reset through a long button press or external button presses and pairs with Zigbee gateways through a learning mode button hold.
Zi-Stick is a self-powered Zigbee 3.0 USB adapter that is used to control actuators and sensors in a Zigbee network. It connects to a computer via USB and appears as a virtual serial or COM port. The user guide provides instructions for installing any necessary drivers, identifying the Zi-Stick's COM port, and connecting it to software like Home Assistant or OpenHAB. Safety information is also included, noting that the Zi-Stick should be used indoors and away from heat or moisture.
This document provides installation and operation instructions for a BRT-100 radiator thermostat in French. It includes:
1. An introduction and welcome message thanking the customer for their purchase.
2. Technical characteristics and features of the thermostat such as LED display, color display, curved design, energy efficient battery that lasts 1 year.
3. Step-by-step instructions for installation including selecting the correct adapter, installing the mounting plate and battery, and connecting the thermostat.
Cherubini Meta Z-Wave Double Switch A510083-84-90Domotica daVinci
Este documento proporciona instrucciones para un actuador con dos salidas independientes de 230V. Incluye especificaciones técnicas, información de seguridad, diagramas de conexión e instrucciones de instalación, control y configuración. El dispositivo permite controlar dos cargas de forma independiente a través de radio o pulsador y puede integrarse en sistemas domóticos Z-Wave.
Este documento proporciona instrucciones para el uso de un enchufe inteligente. Describe las especificaciones técnicas del dispositivo, cómo incluirlo y excluirlo de una red Z-Wave, cómo controlarlo y leer sus parámetros eléctricos, y cómo configurar sus alarmas y asociaciones con otros dispositivos.
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The document provides instructions for installing and operating the HE-RS01 five-channel relay switch. Key details include:
- The HE-RS01 can control up to five on/off devices or combinations of on/off and two-direction motor devices.
- It has five configurable relay outputs, two independent inputs, and supports schedules, motor control, and association with other Z-Wave devices.
- Installation requires connecting power, load, and external switch wires per the provided diagrams and safely turning power back on at the circuit breaker.
- The HE-RS01 can be included in a Z-Wave network and each relay and external input is configurable for different control modes.
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The document provides a user manual for the HE-HT01 thermostat. It has 6 operating modes including Comfort, Schedule, Floor Drying, Energy Saving, Vacation, and Manual. It can be installed flush in an electrical junction box and controls heating systems up to 16A. The thermostat integrates Z-Wave technology for smart home control and has touch buttons, LCD display, and sensors for temperature, humidity, and energy usage.
The document provides instructions for an energy-saving radiator thermostat that uses Z-Wave wireless technology. It includes details on installation, setup, operation, and technical specifications. The thermostat can be added to a Z-Wave network to communicate with other devices and be controlled remotely. It offers functions like setting target temperatures, child lock, operating modes, and displaying network information.
The motion sensor user guide provides specifications and setup instructions. It detects motion within 10 meters at a 120 degree angle using Zigbee wireless communication. To set up, download the Smart Life app, register an account, add the Zigbee controller, then search for and add the motion sensor, which can be configured for various alarm settings and linkages within the app.
The document provides a user guide for the Aeotec Range Extender 7, which is a Z-Wave signal amplifier developed to extend the range of a Z-Wave network. It describes how to include the Range Extender in a Z-Wave network using either SmartStart or classic inclusion. It also explains how to control the LED, test connectivity health, remove the device from the network, and manually reset the Range Extender.
Z-Stick 7 is a Z-Wave USB adapter that allows users to control Z-Wave devices and sensors. It uses Series700 and Gen7 technology with SmartStart and S2 security. The guide provides instructions on installing drivers, adding the Z-Stick to home automation software as a primary or secondary controller, using serial API mode, development tools, and resetting the Z-Stick. Compatible software setup guides are also listed.
Optimal protection for critical loads. To limit starting currents on problematic devices, such as energy saving bulbs and fluorescent bulbs. Problematic devices, such as electronic ballasts, energy-saving light bulbs, incandescent bulbs, LED drivers, and switching power supplies, consume a lot of power during ignition due to the multiplication of current. nominal and can therefore destroy the switching relay.
With the ESB200 current limiter, the high current that can occur when switching on electronic devices is limited to a harmless value. It is also possible to limit the inrush current of incandescent lamps to give them a longer life. A protection fuse is also integrated. This starting current limiter can be plugged directly into the power supply circuit for loads up to 200 VA. This compact device can be installed very easily in junction and recessed boxes or in lamp boxes, for example. The device is easily installed in series with the load
wiDom Smart Roller Shutter Z-Wave Plus Module ManualDomotica daVinci
The document provides instructions for installing and operating the WiDom Smart Roller Shutter, a Z-Wave enabled device for controlling roller shutters, blinds, and curtains. It can accurately control opening and closing positions through local or remote commands. After an initial calibration, it identifies the position without sensors. Safety information warns that installation requires qualified electricians and live voltages are present. Installation instructions explain connecting it according to the diagrams and including it in a Z-Wave network. The LED status indicator shows inclusion status and communication events.
wiDom Smart dry contact module Z-Wave Plus ManualDomotica daVinci
The document provides instructions for operating a WiDom Smart Dry Contact Switch, including:
- Connecting and installing the device
- Including and excluding the device from a Z-Wave network
- Configuring parameters like the number of external switch clicks needed to control loads
- Setting timers for switching the relay on and off
- Associating the device with other nodes to control loads based on external switch clicks
Salesforce Integration for Bonterra Impact Management (fka Social Solutions A...Jeffrey Haguewood
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This video focuses on integration of Salesforce with Bonterra Impact Management.
Interested in deploying an integration with Salesforce for Bonterra Impact Management? Contact us at sales@sidekicksolutionsllc.com to discuss next steps.
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During the hour, we’ll take you through:
Guest Speaker Segment with Hannah Barrington: Dive into the world of dynamic real estate marketing with Hannah, the Marketing Manager at Workspace Group. Hear firsthand how their team generates engaging descriptions for thousands of office units by integrating diverse data sources—from PDF floorplans to web pages—using FME transformers, like OpenAIVisionConnector and AnthropicVisionConnector. This use case will show you how GenAI can streamline content creation for marketing across the board.
Ollama Use Case: Learn how Scenario Specialist Dmitri Bagh has utilized Ollama within FME to input data, create custom models, and enhance security protocols. This segment will include demos to illustrate the full capabilities of FME in AI-driven processes.
Custom AI Models: Discover how to leverage FME to build personalized AI models using your data. Whether it’s populating a model with local data for added security or integrating public AI tools, find out how FME facilitates a versatile and secure approach to AI.
We’ll wrap up with a live Q&A session where you can engage with our experts on your specific use cases, and learn more about optimizing your data workflows with AI.
This webinar is ideal for professionals seeking to harness the power of AI within their data management systems while ensuring high levels of customization and security. Whether you're a novice or an expert, gain actionable insights and strategies to elevate your data processes. Join us to see how FME and AI can revolutionize how you work with data!
Digital Marketing Trends in 2024 | Guide for Staying AheadWask
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Feeling lost in the digital marketing whirlwind of 2024? Technology is changing, consumer habits are evolving, and staying ahead of the curve feels like a never-ending pursuit. This e-book is your compass. Dive into actionable insights to handle the complexities of modern marketing. From hyper-personalization to the power of user-generated content, learn how to build long-term relationships with your audience and unlock the secrets to success in the ever-shifting digital landscape.
5th LF Energy Power Grid Model Meet-up SlidesDanBrown980551
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Power Grid Model
The global energy transition is placing new and unprecedented demands on Distribution System Operators (DSOs). Alongside upgrades to grid capacity, processes such as digitization, capacity optimization, and congestion management are becoming vital for delivering reliable services.
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Power Grid Model is currently being applied in a wide variety of use cases, including grid planning, expansion, reliability, and congestion studies. It can also help in analyzing the impact of renewable energy integration, assessing the effects of disturbances or faults, and developing strategies for grid control and optimization.
What to expect
For the upcoming meetup we are organizing, we have an exciting lineup of activities planned:
-Insightful presentations covering two practical applications of the Power Grid Model.
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Overview
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2. Understanding Edge (IoT)
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5. Introduction to Apache Kafka and S3
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6. Viewing Kafka Messages in the Data Lake
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7. What is Prometheus?
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8. Monitoring Application Metrics with Prometheus
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9. What is Camel K?
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10. Configuring Camel K Integrations for Data Pipelines
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11. What is a Jupyter Notebook?
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12. Jupyter Notebooks with Code Examples
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2. Which barriers stand in the way of AI adoption.
3. How data quality and governance form the backbone of AI.
4. Organizational processes and structures that may inhibit effective AI adoption.
6. Ideas and approaches to help build your organization's AI strategy.
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In 2024, we are witnessing an explosion of new DeFi projects and protocols, each pushing the boundaries of what’s possible in finance.
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Ready to take your DeFi project to the next level? Partner with Intelisync for expert DeFi development services today!
Ivanti’s Patch Tuesday breakdown goes beyond patching your applications and brings you the intelligence and guidance needed to prioritize where to focus your attention first. Catch early analysis on our Ivanti blog, then join industry expert Chris Goettl for the Patch Tuesday Webinar Event. There we’ll do a deep dive into each of the bulletins and give guidance on the risks associated with the newly-identified vulnerabilities.
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With Skybuffer AI, various AI models can be integrated into a single communication channel such as Microsoft Teams. This integration empowers business users with insights drawn from SAP backend systems, enterprise documents, and the expansive knowledge of Generative AI. And the best part of it is that it is all managed through our intuitive no-code Action Server interface, requiring no extensive coding knowledge and making the advanced AI accessible to more users.
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zkStudyClub - LatticeFold: A Lattice-based Folding Scheme and its Application...Alex Pruden
Folding is a recent technique for building efficient recursive SNARKs. Several elegant folding protocols have been proposed, such as Nova, Supernova, Hypernova, Protostar, and others. However, all of them rely on an additively homomorphic commitment scheme based on discrete log, and are therefore not post-quantum secure. In this work we present LatticeFold, the first lattice-based folding protocol based on the Module SIS problem. This folding protocol naturally leads to an efficient recursive lattice-based SNARK and an efficient PCD scheme. LatticeFold supports folding low-degree relations, such as R1CS, as well as high-degree relations, such as CCS. The key challenge is to construct a secure folding protocol that works with the Ajtai commitment scheme. The difficulty, is ensuring that extracted witnesses are low norm through many rounds of folding. We present a novel technique using the sumcheck protocol to ensure that extracted witnesses are always low norm no matter how many rounds of folding are used. Our evaluation of the final proof system suggests that it is as performant as Hypernova, while providing post-quantum security.
Paper Link: https://eprint.iacr.org/2024/257
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Fibaro Motion Multisensor Manual
1. ENG
OPERATING MANUAL
FIBARO MOTION SENSOR
FGMS-001 V2.4
The Fibaro Motion Sensor is a universal Z-Wave multi-sensor. Along
with detecting motion the device measures the temperature and light
intensity. The sensor has a built-in accelerometer to detect any
tampering of the device. The Fibaro Motion Sensor is battery powe-
red device and designed to be installed quckly and easily on any
surface. The LED indicator signals motion, temperature level, opera-
ting mode and can be used to see if device is within the Z-Wave
network. The motion sensor can be used for lighting scenes and
security monitoring systems.
The Fibaro Motion Sensor can be included into the Z-Wave network
by using the B-button.
1) Insert the battery into the Fibaro Motion Sensor. Enclosure lock is
marked with a dot. Make sure the device is located within the direct
range of the main controller.
2) Set the main controller into the learning mode (see main
controller’s operating manual).
3) Quickly, triple click the B-button - LED diode will glow blue.
4) Fibaro Motion Sensor will be detected and included in the Z-Wave
network.
5) Wait for the main controller to configure the sensor.
6) If necessary, wake up the Motion Sensor by triple clicking the
B-button.
7) LED diode will glow blue to confirm the sensor woke up, and then
wait for the main controller to configure the sensor.
Diagram 1 - B-button.
Diagram 2 - Motion detector, light sensor, LED diode. Diagram 4 - Fibaro Motion Sensor installation.
Diagram 3 - preparing Fibaro Motion Sensor for operation.
TECHNICAL INFORMATION
III. EXCLUDING SENSOR FROM THE Z-WAVE NETWORK
I. GLOSSARY OF TERMS
IV. SENSOR INSTALLATION
VI. INSTALLATION NOTES
X. EARTHQUAKE DETECTOR MODE
XIV. BATTERY USAGE TIPS
V. DETECTION AREA AND WORKING CONDITIONS
VII. RESETTING THE FIBARO MOTION SENSOR
XI. SENSOR’S ORIENTATION IN SPACE
XII. LED VISUAL INDICATORS AND SETTINGS
XIII. Z-WAVE RANGE TEST
VIII. OPERATING WITHIN THE Z-WAVE NETWORK
IX. ASSOCIATIONS
II. Z-WAVE NETWORK INCLUSION
Power Supply:
EU directive compliance:
Recommended installation height:
Operational Temperature:
Measured Temperature Range:
Temperature Measuring
Accuracy:
Light Intensity Measuring Range:
Radio Protocol:
Radio Frequency:
Range:
CR123A battery, 3.6 VDC
LVD 2006/95/WE
EMC 2004/108/WE
R&TTE 1999/5/WE
RoHS II
2,4m
0-40o
C
-20 to 100o
C
0,5o
C (within 0o
C-40o
C range)
0-32000 LUX
Z-Wave
869 MHz EU;
908 MHz US;
921 MHz ANZ;
869 MHz RU;
up to 50 m outdoors
up to 30 m indoors
(depending on terrain and
building structure)
B-BUTTON
SENSOR
Diagram 6 - Fibaro Motion Sensor’s motion detection area.
Diagram 5 - Fibaro Motion Sensor’s proximity area.
I’M
READY
SPECIFICATIONS
- Compatible with any Z-Wave controller.
- Detects motion using a passive IR sensor.
- Measures the temperature.
- Measures the light intensity.
- Easy installation on a wall or any surface.
- Protected against tampering and theft - once vibrations are
detected, the notification is sent to the main controller.
- Alarms of movement and temperature are signaled by LED diode
blinking.
- Simple earthquake detector mode.
1) Make sure the sensor is connected to power source.
2) Set the main controller into the learn mode (see main controller’s
operating manual)
3) Quickly, triple click the B-button, located on Fibaro Motion Senso-
r’s enclosure.
4) LED diode will glow blue confirming the device has been excluded
from the network.
• INCLUSION (adding a device, learning mode) - a device sends the
Z-Wave Node Info command frame allowing to add the device to the
Fibaro System (Home Center)
• EXCLUSION (removing / deleting a device) - removing a device
from the Fibaro System.
• ASSOCIATION - controling other devices within the Fibaro System
• MultiChannelAssociation - controling other multi-channel devices
within the Fibaro System.
1) Include the device into the Z-Wave network (see p.II). Note that
the inclusion process may be performed ONLY in direct range of the
main controller.
2) Install the sensor’s holder in desired location.
3) If the sensor is already included in the Z-Wave network, wake it up
by triple clicking the B-button.
4) Insert the Motion Sensor in its holder.
5) Test the sensor’s operation - check whether the LED diode
indicates motion detection.
6) Test the Z-Wave network assuring the device is within range.
Fibaro Motion Sensor cannot be pointed at any source of heat (e.g.
radiators, fireplaces, cookers, etc.) or at any source of light (direct
sunlight, lamps).
It’s not recommended to install the motion sensor in places prone to
drafts. Sensor can be mounted using screw or the sticker.
Fibaro Motion Sensor allows for the association of three groups.
1st Association Group is assigned to the device status - sending
the BASIC SET control frame to the associated devices having
detected motion.
2nd Association Group is assigned to the tamper alarm. Alarm
frame will be sent to the associated devices once tampering is
detected.
3rd Association Group reports the device status and allows for
assigning a single device only (the main controller by default - the
device reports its status to the main controller). It’s not recommen-
ded to modify this association group.
The Fibaro Motion Sensor allows for controlling 5 regular and 5
multichannel devices per an association group, out of which 1 field is
reserved for the Z-Wave network main controller.
Fibaro Motion Sensor can be configured to work as a simple
earthquake detector, by setting the Parameter 24 value to 4. Reports
with scale of the vibrations (dimensionless) will be sent at the time
intervals specified in Parameter 22. First report will be sent
immediately after vibrations have been detected. The minimum
value of the vibrations, resulting in report being sent, can be defined
in Parameter 20. Once the vibrations cease, reports will stop being
sent. The Home Center 2 menu presents the earthquake detector
measurements in the following way:
The Fibaro Motion Sensor’s battery life is approximately 2 years at
factory default settings. The current battery level is displayed in a
Home Center 2 interface. Red battery icon means the battery needs
replacement. In order to avoid tamper detection while replacing the
battery, remove association of the 2-nd association group and
reduce tamper sensitivity (parameter 20 value set to 0). If battery
discharges quickly, please check for the following conditions which
may result in reducing the battery life:
- Wake up interval is too short - it’s recommended to lengthen the
interval.
- Temperature and light intensity reports are sent too frequently -
modify the advanced configuration settings to decrease the
frequency.
- If associated devices or the Z-Wave network main controller are
disconnected from the power source it will cause the sensor to
frequently attempt to reconnect to those devices which will result in
shortening the battery life.
The Fibaro Motion Sensor has a built-in accelerometer. When the
value of parameter 24 is set to 2 or 3, Z-Wave networ controller will
be informed on the Sensor’s orientation in space.
The Fibaro Motion Sensor is equipped with a LED diode for
indicating sensor’s operating modes and alarms. In addition the LED
indicator may inform of the Z-Wave network range and the current
temperature.
LED indicator modes:
1) Motion Alarm’s colour will vary depending on the temperature. The
colour and the signaling mode can be set in parameter 80.
2) Tamper alarm is signaled with an alternating blinking in red - blue
- white.
3) The Z-Wave Node Info command frame is signaled with glowing
in blue. Node Info command frame is sent each time the device
wakes up.
To enter MENU press and hold the B-button for 3 seconds. MENU
levels will be signaled with the LED colours:
- VIOLET - Z-Wave network range tester
- YELLOW - sensor reset.
The Fibaro Motion Sensor has a built in Z-Wave network main
controller’s range tester. Follow the below instructions to test the
main controller’s range:
1) Press and hold the B-button for 2 to 4 seconds until the LED glows
violet.
2) Release the B-button.
3) Press the B-button again, briefly.
4) LED will indicate the Z-Wave network’s range (range signaling
modes described below).
5) To exit Z-Wave range test, press the B-button breifly.
Z-Wave range tester signaling modes:
LED indicator pulsing green - Fibaro Motion Sensor attempts to
extablish a direct communication with the main controller. If a direct
communication attempt fails, sensor will try to establish a routed
communication, through other modules, which will be signaled by
LED indicator pulsing yellow.
LED indicator glowing green - Fibaro Motion Sensor communica-
tes with the main controller directly.
LED indicator pulsing yellow - Fibaro Motion Sensor tries to
establish a routed communication with the main controller through
other modules (repeaters).
LED indicator glowing yellow - Fibaro Motion Sensor communica-
tes with the main controller through the other modules. After 2
seconds the sensor will retry to establish a direct communication
with the main controller, which will be signaled with LED blinking in
green.
LED indicator pulsing violet - Fibaro Motion Sensor does
communicate at the maximum distance of the Z-Wave network. If
connection proves successful it will be confirmed with a yellow glow.
It’s not recommended to use the sensor at the range limit.
LED indicator glowing red - Fibaro Motion Sensor is not able to
connect to the main controller directly or through another Z-Wave
network device (repeater).
By using association with Fibaro’s devices the Fibaro Motion Sensor
may control another Z-Wave network device, e.g. a Dimmer, Relay
Switch, Roller Shutter, RGBW Controller, Wall Plug, or a scene
(scene only through the Home Center 2 main controller).
Fibaro Motion Sensor’s detection area is shown in diagram #6.
Fibaro Motion Sensor has to be installed in a corner of the room or
perpendicularly to the doors.
Actual range of the sensor can be influenced by environment
conditions. Should false motion alarms be reported, check for any
moving objects within the sensor’s detection area, such as trees
blowing in the wind, cars passing by, windmills. False motion alarms
may be caused by moving masses of air and heat as well. If the
device keeps on reporting false alarms, despite eliminating all of the
above-mentioned factors, install the device in another place.
The Fibaro Motion Sensor reset erases the EPROM memory,
including all information on the Z-Wave network and the main
controller.
Fibaro Motion Sensor reset procedure:
1) Make sure the battery works and is in place.
2) Press and hold the B-button for 4-6 seconds until the LED glows
signaling the 2nd menu level.
3) Release the B-button.
4) Again, press the B-button briefly.
Successful reset will be confirmed with the LED changing colour to
red and fading.
Motion, temperature and light intensity values are presented in
Home Center 2 menu with the following icons:
NOTE
Read this manual before attempting to install the
device. Failure to observe recommendations
included in this manual may be dangerous or cause
a violation of the law. The manufacturer, Fibar Group
Sp. z o.o., will not be held responsible for any loss or
damage resulting from not following the instructions
of operating manual.
!
NOTE
Work within local code height requirements for
installation of the Fibaro Smoke Sensor. Take
special precautions during installation and use tools
and equipment in perfect working order. It’s
recommended to observe ladders, lifts and other
obstacles.
When handled carelessly or used in non-specified
environment conditions, the device may not function
properly. It’s highly recommended to take all safety
precautions to ensure safety and property
protection.
!
!
NOTE
Device reset will not remove it from the Z-Wave
network main controller’s memory. Before resetting
the device, it must be excluded from the Z-Wave
network.
!
NOTE
The Fibaro Motion Sensor is a battery-powered
device. Using batteries other than specified may
result in explosion. Dispose of properly, observing
environmental protection rules.
!
NOTE
The Fibaro Motion Sensor features remote software
updates. The functionality is supported by the Fibaro
Home Center 2 and may not be supported by other
controllers. During the software update process, the
sensor does NOT support alarm functions.
!
NOTE
Fibaro Motion Sensor capabilities will vary
depending on the Z-Wave network controller. Certain
functionalities of the Fibaro Motion Sensor may not
be supported by some controllers. To make sure
your Z-Wave network controller supports the Fibaro
Motion Sensor, get in touch with its manufacturer.
!
3 m
0 m
7 m
0 m
5 m
5 m
7 m
NOTE
Association allows for direct communication
between Z-Wave network devices. Main controller
does not take part in such communication. Using this
mechanism, Fibaro Motion Sensor may
communicate with other devices even when the
main controller is damaged, e.g. in case of a fire.
!
Fibaro Motion Sensor has a bulit in motion detector, temperature
sensor and light intensity sensor, which make it a multi-channel
device. In the Home Center 2 menu it will be presented as three
devices, depending on the main controller software version.
NOTE
STICKER
2. XV. ADVANCED CONFIGURATION
40. ILLUMINATION REPORT THRESHOLD
The parameter determines the change in light intensity level
resulting in illumination report being sent to the main controller.
Available settings: 0 - 65535 (1 - 65535 lux; 0 = reports are not
sent)
Default setting: 200 (200 lux)
Parameter size: 2 [byte]
42. ILLUMINATION REPORTS INTERVAL
Time interval between consecutive illumination reports. The reports
are sent even if there are no changes in the light intensity.
Available settings: 0 - 65535 (1 - 65535 seconds; 0 = reports are
not sent)
9. NIGHT / DAY
The parameter defines the difference between night and day, in
terms of light intensity, used in parameter 8.
Available settings: 1 - 65535
Default setting: 200 (200 lux)
Parameter size: 2 [bytes]
12. BASIC COMMAND CLASS FRAMES CONFIGURATION
The parameter determines the command frames sent in 1-st
association group, assigned to PIR sensor.
0 - BASIC ON and BASIC OFF command frames sent in Basic
Command Class.
1 - only the BASIC ON command frame sent in Basic Command
Class.
1. MOTION SENSOR’S SENSITIVITY
The lower the value, the more sensitive the PIR sensor.
Available settings: 8 - 255
Default setting: 10
Parameter size: 1 [byte]
2. MOTION SENSOR’S BLIND TIME (INSENSITIVITY)
Period of time through which the PIR sensor is “blind” (insensitive) to
motion. After this time period the PIR sensor will be again able to
detect motion. The longer the insensitivity period, the longer the
battery life. If the sensor is required to detect motion quickly, the time
period may be shortened. The time of insensitivity should be shorter
that the time period set in parameter 6.
Available settings: 0 - 15
Formula to calculate the time: time [s] = 0.5 x (value + 1)
Default setting: 15 (8 seconds)
Parameter size: 1 [byte]
3. PIR sensor’s “PULSE COUNTER”
Sets the number of moves required for the PIR sensor to report
motion. The lower the value, the less sensitive the PIR sensor. It’s
not recommended to modify this parameter settings.
Available settings: 0 - 3
Formula to calculate the number of pulses: pulses = (value + 1)
Default setting: 1 (2 pulses)
Parameter size: 1 [byte]
4. PIR sensor’s “WINDOW TIME”
Period of time during which the number of moves set in parameter 3
must be detected in order for the PIR sensor to report motion. The
higher the value, the more sensitive the PIR sensor. It’s not
recommended to modify this parameter setting.
Available settings: 0 - 3
Formula to calculate the time: time [s] = 4 x (value + 1)
Default setting: 2 (12 seconds)
Parameter size: 1 [byte]
6. MOTION ALARM CANCELLATION DELAY
Motion alarm will be cancelled in the main controller and the
associated devices after the period of time set in this parameter. Any
motion detected during the cancellation delay time countdown will
result in the countdown being restarted. In case of small values,
below 10 seconds, the value of parameter 2 must be modified (PIR
sensor’s “Blind Time”).
Available settings: 1 - 65535
Default setting: 30 (30 seconds)
Parameter size: 2 [bytes]
14. BASIC ON command frame value
The value of 255 allows to turn ON a device. In case of the Dimmer,
the value of 255 means turning ON at the last memorized state, e.g.
the Dimmer turned ON at 30% and turned OFF using the value of
255, and then turned OFF, will be turned ON at 30%, i.e. the last
memorized state.
Available settings: 0 - 255
Default setting: 255
Parameter size: 1 [byte]
16. BASIC OFF command frame value
The command frame sent at the moment of motion alarm
cancellation, after the cancellation delay time, specified in parameter
6, has passed.
The value of 0 allows to turn a device OFF while the value of 255
allows to turn ON a device. In case of the Dimmer, the value of 255
means turning ON at the last memorized state, e.g. the Dimmer
turned ON at 30% and turned OFF using the value of 255, and then
turned OFF, will be turned ON at 30%, i.e. the last memorized state.
Available settings: 0 - 255
Default setting: 0
Parameter size: 1 [byte]
20. TAMPER SENSITIVITY
The parameter determines the chages in forces acting on the Fibaro
Motion Sensor resulting in tamper alarm beig reported - g-force
acceleration.
Available settigs: 0 - 122 (0.08 - 2g; multiply by 0.016g; 0 = tamper
inactive)
Default setting: 15 (0.224g)
Parameter size: 1 [byte]
22. TAMPER ALARM CANCELLATION DELAY
Time period after which a tamper alarm will be cacelled. Another
tampering detected durig the countdown to cancellation will not
extend the delay.
Available settings: 1 - 65535
Default setting: 30 (seconds)
Parameter size: 2 [bytes]
8. PIR SENSOR OPERATING MODE
The parameter determines the part of day in which the PIR sensor
will be active. This parameter influences only the motion reports and
associations. Tamper, light intensity and temperature measurements
will be still active, regardless of this parameter settings.
0 - PIR sensor always active
1 - PIR sensor active during the day only
2 - PIR sensor active during the night only.
Default setting: 0
Parameter size: 1 [byte]
24. TAMPER OPERATING MODES
The parameter determines the behaviour of tamper and how it
reports.
0 – Tamper alarm is reported in Sensor Alarm command class /
Cancellation is not reported.
1 – Tamper alarm is reported in Sensor Alarm command class /
Cancellation is reported in Sensor Alarm commad class after the
time period set in parameter 22 (Tamper Alarm Cancellation Delay)
2 - Tamper alarm is reported in Sensor Alarm command class /
Cancellation is not reported.
Sensor’s orientation in space is reported in Fibar Commad Class
after the time period set in paramer 22.
3 - Tamper alarm is reported in Sensor Alarm command class /
Cancellation is reported in Sensor Alarm commad class after the
time period set in parameter 22. Sensor’s orientation in space is
reported in Fibar Commad Class after the time period set in paramer
22.
4 - The maximum level of vibrations recorded in the time period set
in parameter 22 is reported. Reports stop being sent when the
vibrations cease. The reports are sent in Sensor Alarm command
class. Value displayed in the “value” field (0 - 100) depends on the
vibrations force. Reports to the association groups are sent using
Sensor Alarm command class
Available settings: 0 or 255
Default setting: 0
Parameter size: 1 [byte]
26. TAMPER ALARM BROADCAST MODE
The parameter determines whether the tamper alarm frame will or
will not be sent in broadcast mode. Alarm frames sent in broadcast
mode may be received by all of the devices within communication
range (if they accept such frames).
0 - Tamper alarm is not sent in broadcast mode.
1 - Tamper alarm sent in broadcast mode.
Default setting: 0
Parameter size: 1 [byte]
60. TEMPERATURE REPORT THRESHOLD
The parameter determines the change in level of temperature
resulting in temperature report being sent to the main controller.
Available settings: 0 - 255 (0.1 - 25.5oC; 0 = reports are not sent)
Default setting: 10 (1oC)
Parameter size: 1 [byte]
62. INTERVAL OF TEMPERATURE MEASURING
The parameter determines how often the temperature will be
measured. The shorter the time, the more frequently the temperature
will be measured, but the battery life will shorten.
Available settings: 0 - 65535 (1 - 65535 seconds; 0 = temperature
will not be measured)
Default setting: 900 (900 seconds)
Parameter size: 2 [bytes]
64. TEMPERATURE REPORTS INTERVAL
The parameter determines how often the temperature reports will be
sent to the main controller.
Available settings: 0 - 65535 (1 - 65535 sekund; 0 = reports are not
sent)
Default setting: 0
Parameter size: 2 [byte]
66. TEMPERATURE OFFSET
The value to be added to the actual temperature, measured by the
sensor (temperature compensation).
Available settings: 0 - 100 (0 to 100oC) or 64536 - 65535 (-100 to
-0.10oC)
Default setting: 0
Parameter size: 2 [bytes]
80. LED SIGNALING MODE
The parameter determines the way in which LED diode behaves
after motion has been detected.
Values from 1 to 9 = single long blink at the moment of reporting
motion. No other motion will be indicated until alarm is cancelled.
Values from 10 to 18 = single long blink at the moment of reporting
motion and one short blink each time the motion is detected again.
Values from 19 to 26 = single long blink at the moment of reporting
motion and two short blinks each time the motion is detected again.
0. LED inactive.
1. LED colour depends on the temperature. Set by parameters 86
and 87.
2. Flashlight mode - LED glows in white for 10 seconds.
3. White.
4. Red.
5. Green.
6. Blue.
7. Yellow.
8. Cyan.
9. Magenta.
10. LED colour depends on the temperature. Set by parameters
86 and 87.
11. Flashlight mode - LED glows in white through 10 seconds.
Each next detected motion extends the glowing by next 10
seconds.
12. White.
13. Red.
14. Green.
15. Blue.
16. Yellow.
17. Cyan
18. Magenta
19. LED colour depends on the temperature. Set by parameters
86 and 87.
20. White
21. Red
22. Green
23. Blue
24. Yellow
25. Cyan
26. Magenta
Default setting: 10
Parameter size: 1 [byte]
81. LED BRIGHTNESS
The parameter determines the brightness of LED when indicating
motion.
Available settings: 0 - 100 (1 - 100%; 0 = brightness determined by
the ambient lighting - see parameters 82 and 83)
Default setting: 50
Parameter size: 1 [byte]
86. MINIMUM TEMPERATURE RESULTING IN BLUE LED
ILLUMINATION
This parameter is relevant only when parameter 80 has been
properly configured.
Available settings: 0 to parameter 87 value (degrees celsius)
Default setting: 18 (18oC)
Parameter size: 1 [byte]
87. MAXIMUM TEMPERATURE RESULTING IN RED LED
ILLUMINATION
This parameter is relevant only when parameter 80 has been
properly configured.
Available settings: parameter 86 value to 255 (degrees celsius)
Default setting: 28 (28oC)
Parameter size: 1 [byte]
89. LED INDICATING TAMPER ALARM
Indicating mode resembles a police car (white, red and blue).
0 - LED does not indicate tamper alarm.
1 - LED indicates tamper alarm.
Default setting: 1
Parameter size: 1 [byte]
i
NOTE
The value of the parameter 83 must be higher than
the value of the parameter 82.
!NOTE
It’s not recommended to set the value of Wake Up
interval below 10 seconds. Short wake up interval
may shorten the battery life and delay the reports or
even make them impossible.
!
NOTE
Frequent reports will shorten the battery life.
Parameter value under 5 may result in blocking the
temperature reports.
!
NOTE
Frequent reports will shorten the battery life.
Parameter value under 5 may result in blocking the
ilumination reports.
!
82. AMBIENT ILLUMINATION LEVEL BELOW WHICH LED
BRIGHTNESS IS SET TO 1%
The parameter is relevant only when the parameter 81 is set to 0.
Available settings: 0 to parameter 83 value
Default setting: 100 (100 lux)
Parameter size: 2 [bytes]
83. AMBIENT ILLUMINATION LEVEL ABOVE WHICH LED
BRIGHTNESS IS SET TO 100%
The parameter is relevant only when the parameter 81 is set to 0.
Available settings: parameter 82 value to 65535
Default setting: 1 000 (1 000 lux)
Parameter size: 2 [bytes]
XVI. GUARANTEE
1. The Guarantee is provided by FIBAR GROUP Sp. z o.o.
(hereinafter "Manufacturer"), based in Poznan, ul. Lotnicza 1;
60-421 Poznan, entered in the register of the National Court
Register kept by the District Court in Poznań, VIII Economic
Department of the National Court Register, no. 370151, NIP
7811858097, REGON: 301595664.
2. The Manufacturer is responsible for equipment malfunction
resulting from physical defects (manufacturing or material) of the
Device for 12 months from the date of its purchasing.
3. During the Guarantee period, the Manufacturer shall remove any
defects, free of charge, by repairing or replacing (at the sole
discretion of the Manufacturer) any defective components of the
Device with new or regenerated components, that are free of
defects. When the repair impossible, the Manufacturer reserves the
right to replace the device with a new or regenerated one, which
shall be free of any defects and its condition shall not be worse than
the original device owned by the Customer.
4. In special cases, when the device cannot be replaced with the
device of the same type (e.g. the device is no longer available in the
commercial offer), the Manufacturer may replace it with a different
device having technical parameters similar to the faulty one. Such
activity shall be considered as fulfilling the obligations of the
Manufacturer. The Manufacturer shall not refund money paid for the
device.
5. The holder of a valid guarantee shall submit a guarantee claim
through the guarantee service. Remember: before you submit a gu-
arantee claim, contact our technical support using telephone or
e-mail. More than 50% of operational problems is resolved remotely,
saving time and money spent to initiating guarantee procedure. If
remote support is insufficient, the Customer shall fill the guarantee
claim form (using our website - www.fibargroup.com) in order to
obtain claim authorization. When the guarantee claim form is sub-
mitted correctly, the Customer shall receive the claim confirmation
with an unique number (Return Merchandise Authorization -RMA).
6. The claim may be also submitted by telephone. In this case, the
call is recorded and the Customer shall be informed about it by a
consultant before submitting the claim. Immediately after submitting
the claim, the consultant shall provide the Customer with the claim
number (RMA-number).
7. When the guarantee claim form is submitted correctly, a
representative of the Authorised Guarantee Service (hereinafter as
"AGS") shall contact the Customer.
8. Defects revealed within the guarantee period shall be removed
not later than 30 days from the date of delivering the Device to AGS.
The guarantee period shall be extended by the time in which the
Device was kept by AGS.
9. The faulty device shall be provided by the Customer with complete
standard equipment and documents proving its purchase.
10. Parts replaced under the guarantee are the property of the
Manufacturer. The guarantee for all parts replaced in the guarantee
process shall be equal to the guarantee period of the original device.
The guarantee period of the replaced part shall not be extended.
11. Costs of delivering the faulty device shall be borne by the
Customer. For unjustified service calls, the Service may charge the
Customer with travel expenses and handling costs related to the
case.
12. AGS shall not accept a complaint claim only when:
12. AGS shall not accept a complaint claim only when:
• the Device was misused or the manual was not observed,
• the Device was provided by the Customer incomplete, without
accessories or
nameplate,
• it was determined that the fault was caused by other reasons than
a material or
manufacturing defect of the Device
• the guarantee document is not valid or there is no proof of
purchase,
13. The Manufacturer shall not be liable for damages to property
caused by defective device. The Manufacturer shall not be liable for
indirect, incidental, special, consequential or punitive damages, or
for any damages, including, inter alia, loss of profits, savings, data,
loss of benefits, claims by third parties and any property damage or
personal injuries arising from or related to the use of the Device.
14. The guarantee shall not cover:
• mechanical damages (cracks, fractures, cuts, abrasions, physical
deformations caused by impact, falling or dropping the device or
other object, improper use or not observing the operating manual);
• damages resulting from external causes, e.g.: flood, storm, fire,
lightning, natural disasters, earthquakes, war, civil disturbance, force
majeure, unforeseen accidents, theft, water damage, liquid leakage,
battery spill, weather conditions, sunlight, sand, moisture, high or low
temperature, air pollution;
• damages caused by malfunctioning software, attack of a computer
virus, or by failure to update the software as recommended by the
Manufacturer;
• damages resulting from: surges in the power and/or telecommuni-
cation network, improper connection to the grid in a manner
inconsistent with the operating manual, or from connecting other
devices not recommended by the Manufacturer.
• damages caused by operating or storing the device in extremely
adverse conditions, i.e. high humidity, dust, too low (freezing) or too
high ambient temperature. Detailed permissible conditions for
operating the Device are defined in the operating manual;
• damages caused by using accessories not recommended by the
Manufacturer
• damages caused by faulty electrical installation of the Customer,
including the use of incorrect fuses;
• damages caused by Customer's failure to provide maintenance
and servicing activities defined in the operating manual;
• damages resulting from the use of spurious spare parts or
accessories improper for given model, repairing and introducing
alterations by unauthorized persons;
• defects caused by operating faulty Device or accessories.
15. The scope of the guarantee repairs shall not include periodic
maintenance and inspections, in particular cleaning, adjustments,
operational checks, correction of errors or parameter programming
and other activities that should be performed by the user (Buyer).
The guarantee shall not cover natural wear and tear of the Device
and its components listed in the operating manual and in technical
documentation as such elements have a defined operational life.
16. If a defect is not covered by the guarantee, the Manufacturer
reserves the right to remove such defect at its sole discretion,
repairing the damaged or destroyed parts or providing components
necessary for repair or replacement.
17. This guarantee shall not exclude, limit or suspend the Customer
rights when the provided product is inconsistent with the purchase
agreement.
This Device may be used with all devices
certified with Z-Wave certificate and should be
compatible with such devices produced by
other manufacturers.
Any device compatible with Z-Wave may be
added to Fibaro system.
FIBAR GROUP
FIBARO
In case of any technical questions contact customer service centre in
your country.
www.fibaro.com
2 - only the BASIC OFF command frame sent in Basic CommandC-
lass.
Values of BASIC ON and BASIC OFF command frames may be
modified by dedicated parameters.
Default setting: 0
Parameter size: 1 [byte]
WAKE UP INTERVAL
At each wake up the Fibaro Motion Sensor communicates with the
main controller, updates parameter settings and the software if
necessary. The Motion Sensor will wake up at a defined time interval
and will ALWAYS try to communicate with the main controller
Wake Up Interval set to 0 cancels the WAKE UP command frame,
i.e. the device will have to be woke up manually, through the B
button, sending NODE INFO command frame.
Available settings: 0-65535 (0-65535 seconds).
Default setting: 7200 (7200 seconds).
Parameter size: 2 [bytes]
Default setting: 0 (no reports)
Parameter size: 2 [bytes]