OPERATING MANUAL EN FIBARO SMART IMPLANT FGBS-222 v1.
Table of contents 1: Important safety information 4 2: Description and features 5 2.1: Description 5 2.2: Main features 5 3: Specifications 6 4: Installation 7 4.1: Before installation 7 4.2: Connection with alarm line 9 4.3: Connection with DS18B20 10 4.4: Connection with DHT22 10 4.5: Connection with 2-wire 0-10V sensor 11 4.6: Connection with 3-wire 0-10V sensor 11 4.7: Connection with binary sensor 12 4.8: Connection with button 13 4.
1: Important safety information 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 S.A. will not be held responsible for any loss or damage resulting from not following the instructions of operating manual. ! Do not modify! ! Do not modify this device in any way not included in this manual. It might result in losing warranty privileges otherwise.
2: Description and features 2.1: Description FIBARO Smart Implant allows to enhance the functionality of wired sensors and other devices by adding Z-Wave network communication. You can connect binary sensors, analog sensors, DS18B20 temperature sensors or DHT22 humidity and temperature sensor to report their readings to the Z-Wave controller. It can also control devices by opening/closing output contacts independently of the inputs. 2.
3: Specifications Power supply Inputs Outputs Supported digital sensors Maximum current on outputs Maximum voltage on outputs Built-in temperature sensor measurement range Operating temperature Radio protocol Radio frequency Transmit power Range Dimensions (Length x Width x Height) Compliance with EU directives 9-30V DC ±10% 2 0-10V or digital inputs 1 serial 1-wire input 2 potential-free outputs 6 DS18B20 or 1 DHT22 150mA 30V DC / 20V AC ±5% -55°C–126°C (-67°F–259°F) 0–40°C (32–104°F) Z-Wave (500 ser
4: Installation 4.1: Before installation ! Connecting the device in a manner inconsistent with this manual may cause risk to health, life or material damage.
Notes for diagrams: ant GnD sD sp In2 In1 GnD p out2 B out1 ANT (black) – antenna GND (blue) – ground conductor SD (white)– signal conductor for DS18B20 or DHT22 sensor SP (brown) – power supply conductor for DS18B20 or DHT22 sensor (3.3V) IN2 (green) – input no. 2 IN1 (yellow) – input no. 1 GND (blue) – ground conductor P (red) – power supply conductor OUT1 – output no. 1 assigned to input IN1 OUT2 – output no.
4.2: Connection with alarm line 1. Turn off the alarm system. 2. Connect with one of the diagrams below: In2 In1 GnD p nc nc tmp tmp com 12V auX com Z1 Z2 2 1 Diagram 1: Example connection with regular alarm line (1 – alarm sensor, 2 – alarm system hub) r1 r2 In2 In1 GnD p nc nc tmp tmp com 12V 1 com auX com Z1 2 Diagram 2: Example connection with parametric alarm line (1 – alarm sensor, 2 – alarm system hub) 3. Verify correctness of connection. 4.
4.3: Connection with DS18B20 The DS18B20 sensor may easily be installed wherever very precise temperature measurements are required. If proper protective measures are undertaken, the sensor may be used in humid environments or under water, it may be embedded in concrete or placed under the floor. You can connect up to 6 DS18B20 sensors in parallel to SP-SD terminals. 1. Disconnect power. 2.
3. Verify correctness of connection. 4. Power the device. 5. Add the device to the Z-Wave network. 4.5: Connection with 2-wire 0-10V sensor The 2-wire analog sensor requires pull-up resistor. You can connect up to 2 analog sensors to IN1/IN2 terminals. The 12V supply is required for these type of sensors. 1. Disconnect power. 2. Connect with the diagram below: 1 analoG out In2 GnD GnD p GnD 12V Diagram 5: Example connection with 2-wire analog sensor to IN2 input (1 – 2-wire analog sensor) 3.
3. Verify correctness of connection. 4. Power the device. 5. Add the device to the Z-Wave network. 6. Change values of parameters: • Connected to IN1: change parameter 20 to 4 • Connected to IN2: change parameter 21 to 4 4.7: Connection with binary sensor You connect normally opened or normally binary sensors to IN1/IN2 terminals. 1. Disconnect power. 2. Connect with the diagram below: 2 1 In2 In1 GnD p GnD 9-30V Diagram 7: Example connection with 2 binary sensors (1,2 – binary sensor) 3.
4.8: Connection with button You can connect monostable or bistable switches to IN1/IN2 terminals to activate scenes. 1. Disconnect power. 2. Connect with the diagram below: 2 1 In2 In1 GnD p GnD 9-30V Diagram 8: Example connection with 2 buttons (1,2 – button) 3. Verify correctness of connection. 4. Power the device. 5. Add the device to the Z-Wave network. 6.
4.9: Connection with gate opener Smart Implant can be connected to different devices to control them. In this example it is connected to gate opener with impulse input (every impulse will start and stop the gate motor, alternately opening/closing) 1. Disconnect power. 2. Connect with the diagram below: 1 In1 GnD p GnD 2 out1 start/stop GnD 9-30V Diagram 9: Example gate opener (1 – monostable button, 2 – gate opener controller) 3. Verify correctness of connection. 4. Power the device. 5.
5: Adding to Z-Wave network Adding (Inclusion) – Z-Wave device learning mode, allowing to add the device to existing Z-Wave network. 5.1: Adding manually To add the device to the Z-Wave network manually: 1. Power the device. 2. Set the main controller in (Security/non-Security Mode) add mode (see the controller’s manual). 3. Quickly, triple click button on the device housing or switch connected to IN1 or IN2. 4.
6: Removing from Z-Wave network Removing (Exclusion) – Z-Wave device learning mode, allowing to remove the device from existing Z-Wave network. Removing also results in resetting the device to factory defaults. To remove the device from the Z-Wave network: 1. Power the device. 2. Set the main controller into remove mode (see the controller’s manual). 3. Quickly, triple click button on the device housing or switch connected to IN1 or IN2. 4.
7: Operating the device 7.1: Controlling the outputs It is possible to control the outputs with the inputs or with the B-button: • single click – switch OUT1 output • double click – switch OUT2 output 7.2: Visual indications The built-in LED light shows current device status.
7.2: Menu Menu allows to perform Z-Wave network actions. In order to use the menu: 1. Press and hold the button to enter the menu, device blinks to signal adding status (see 7.2: Visual indications). 2. Release the button when device signals desired position with colour: • MAGENTA - start range test • YELLOW - reset the device 3. Quickly click the button to confirm. 7.
8: Z-Wave range test The device has a built in Z-Wave network main controller’s range tester. To make Z-Wave range test possible, the device must be added to the Z-Wave controller. Testing may stress the network, so it is recommended to perform the test only in special cases. i To test the main controller’s range: 1. Press and hold the button to enter the menu. 2. Release button when the device glows magenta. 3. Quickly click the button to confirm. 4.
9: Activating scenes The device can activate scenes in the Z-Wave controller by sending scene ID and attribute of a specific action using Central Scene Command Class. In order for this functionality to work connect monostable or bistable switch to the IN1 or IN2 input and set parameter 20 (IN1) or 21 (IN2) to 2 or 3. By default scenes are not activated, set parameters 40 and 41 to enable scene activation for selected actions.
10: Configuration 10.1: Associations Association (linking devices) - direct control of other devices within the Z-Wave system network e.g. Dimmer, Relay Switch, Roller Shutter or scene (may be controlled only through a Z-Wave controller). Association ensures direct transfer of control commands between devices, is performed without participation of the main controller and requires associated device to be in the direct range.
ParameNo. 41 No. 52 No. 54 No. 151 No. 153 No. 63 No. 64 ter 21 0 or 1 2 or 3 4 or 5 Available parameters: 20. Input 1 - operating mode This parameter allows to choose mode of 1st input (IN1). Change it depending on connected device.
24. Inputs orientation This parameter allows reversing operation of IN1 and IN2 inputs without changing the wiring. Use in case of incorrect wiring. Parameter size 1B Default value Available values 0 (default) 0 – default (IN1 - 1st input, IN2 - 2nd input) 1 – reversed (IN1 - 2nd input, IN2 - 1st input) 25. Outputs orientation This parameter allows reversing operation of OUT1 and OUT2 inputs without changing the wiring. Use in case of incorrect wiring.
47. Input 1 - value sent to 2nd association group when activated This parameter defines value sent to devices in 2nd association group when IN1 input is triggered (using Basic Command Class). Parameter is relevant only if parameter 20 is set to 0 or 1 (alarm mode). Parameter size 2B Default value Available values 49.
150. Input 1 - sensitivity This parameter defines the inertia time of IN1 input in alarm modes. Adjust this parameter to prevent bouncing or signal disruptions. Parameter is relevant only if parameter 20 is set to 0 or 1 (alarm mode). Parameter size 1B Default value Available values 10 (100ms) 1-100 (10ms-1000ms, 10ms step) 151. Input 2 - sensitivity This parameter defines the inertia time of IN2 input in alarm modes. Adjust this parameter to prevent bouncing or signal disruptions.
154. Output 1 - logic of operation This parameter defines logic of OUT1 output operation. Parameter size 1B Default value Available values 0 (NO) 0 – contacts normally open / closed when active 1 – contacts normally closed / open when active 155. Output 2 - logic of operation This parameter defines logic of OUT2 output operation. Parameter size 1B Default value Available values 0 (NO) 0 – contacts normally open / closed when active 1 – contacts normally closed / open when active 156.
64. Analog inputs - periodical reports This parameter defines reporting period of analog inputs value. Periodical reports are independent from changes in value (parameter 63). Parameter is relevant only for analog inputs (parameter 20 or 21 set to 4 or 5). Parameter size 2B Default value 0 (periodical reports disabled) Available values 0 – periodical reports disabled 65.
68. External sensors - periodical reports This parameter defines reporting period of analog inputs value. Periodical reports are independent from changes in value (parameter 67). Parameter is relevant only for connected DS18B20 or DHT22 sensors.
11: Z-Wave specification Supported Command Classes: Command Class Version Secure 1. COMMAND_CLASS_ZWAVEPLUS_INFO [0x5E] V2 2. COMMAND_CLASS_SWITCH_BINARY [0x25] V1 YES 3. COMMAND_CLASS_ASSOCIATION [0x85] V2 YES 4. COMMAND_CLASS_MULTI_CHANNEL_ASSOCIATION [0x8E] V3 YES 5. COMMAND_CLASS_ASSOCIATION_GRP_INFO [0x59] V2 YES 6. COMMAND_CLASS_TRANSPORT_SERVICE [0x55] V2 7. COMMAND_CLASS_VERSION [0x86] V2 YES 8. COMMAND_CLASS_MANUFACTURER_SPECIFIC [0x72] V2 YES 9.
Multichannel Command Class: MULTICHANNEL CC ROOT (Endpoint 1) Generic Device Class Specific Device Class GENERIC_TYPE_SENSOR_NOTIFICATION SPECIFIC_TYPE_NOTIFICATION_SENSOR COMMAND_CLASS_ZWAVEPLUS_INFO [0x5E] Command Classes COMMAND_CLASS_ASSOCIATION [0x85] COMMAND_CLASS_MULTI_CHANNEL_ASSOCIATION [0x8E] COMMAND_CLASS_ASSOCIATION_GRP_INFO [0x59] COMMAND_CLASS_NOTIFICATION [0x71] COMMAND_CLASS_SUPERVISION [0x6C] COMMAND_CLASS_APPLICATION_STATUS [0x22] COMMAND_CLASS_SECURITY [0x98] COMMAND_CLASS_SECURITY_
Endpoint 3 Generic Device Class Specific Device Class GENERIC_TYPE_SENSOR_MULTILEVEL SPECIFIC_TYPE_ROUTING_SENSOR_MULTILEVEL COMMAND_CLASS_ZWAVEPLUS_INFO [0x5E] Command Classes COMMAND_CLASS_ASSOCIATION [0x85] COMMAND_CLASS_MULTI_CHANNEL_ASSOCIATION [0x8E] COMMAND_CLASS_ASSOCIATION_GRP_INFO [0x59] COMMAND_CLASS_SENSOR_MULTILEVEL [0x31] COMMAND_CLASS_SUPERVISION [0x6C] COMMAND_CLASS_APPLICATION_STATUS [0x22] COMMAND_CLASS_SECURITY [0x98] COMMAND_CLASS_SECURITY_2 [0x9F] Description Analog Input 1 – Vo
Endpoint 5 Generic Device Class Specific Device Class GENERIC_TYPE_SWITCH_BINARY SPECIFIC_TYPE_POWER_SWITCH_BINARY COMMAND_CLASS_ZWAVEPLUS_INFO [0x5E] COMMAND_CLASS_SWITCH_BINARY [0x25] Command Classes COMMAND_CLASS_ASSOCIATION [0x85] COMMAND_CLASS_MULTI_CHANNEL_ASSOCIATION [0x8E] COMMAND_CLASS_ASSOCIATION_GRP_INFO [0x59] COMMAND_CLASS_PROTECTION [0x75] COMMAND_CLASS_SUPERVISION [0x6C] COMMAND_CLASS_APPLICATION_STATUS [0x22] COMMAND_CLASS_SECURITY [0x98] COMMAND_CLASS_SECURITY_2 [0x9F] Description O
Endpoint 7 Generic Device Class Specific Device Class GENERIC_TYPE_SENSOR_MULTILEVEL SPECIFIC_TYPE_ROUTING_SENSOR_MULTILEVEL COMMAND_CLASS_ZWAVEPLUS_INFO [0x5E] Command Classes COMMAND_CLASS_ASSOCIATION [0x85] COMMAND_CLASS_MULTI_CHANNEL_ASSOCIATION [0x8E] COMMAND_CLASS_ASSOCIATION_GRP_INFO [0x59] COMMAND_CLASS_NOTIFICATION [0x71] COMMAND_CLASS_SENSOR_MULTILEVEL [0x31] COMMAND_CLASS_SUPERVISION [0x6C] COMMAND_CLASS_APPLICATION_STATUS [0x22] COMMAND_CLASS_SECURITY [0x98] COMMAND_CLASS_SECURITY_2 [0x9F]
Endpoint 8 (when DHT22 sensor connected) Generic Device GENERIC_TYPE_SENSOR_MULTILEVEL Class Specific Device SPECIFIC_TYPE_ROUTING_SENSOR_MULTILEVEL Class COMMAND_CLASS_ZWAVEPLUS_INFO [0x5E] Command Classes COMMAND_CLASS_ASSOCIATION [0x85] COMMAND_CLASS_MULTI_CHANNEL_ASSOCIATION [0x8E] COMMAND_CLASS_ASSOCIATION_GRP_INFO [0x59] COMMAND_CLASS_NOTIFICATION [0x71] COMMAND_CLASS_SENSOR_MULTILEVEL [0x31] COMMAND_CLASS_SUPERVISION [0x6C] COMMAND_CLASS_APPLICATION_STATUS [0x22] COMMAND_CLASS_SECURITY [0x98] CO
Notification Command Class: The device uses Notification Command Class to report different events to the controller (“Lifeline” group).
Assocation groups mapping: Root Endpoint Association group in endpoint Association Group 2 Endpoint 1 Association Group 2 Association Group 3 Endpoint 2 Association Group 2 Basic commands mapping: Endpoints Command Root 1-2 3-4 5-6 7-13 Application Rejected Switch Binary Set Application Rejected Sensor Sensor Switch BiMultilevel Multilevel nary Get Get Get Basic Set = EP1 Application Rejected Basic Get = EP1 Notification Get = EP1 Notification Report Basic Report Sensor Multile
12: Regulations This device complies with Part 15 of the FCC Rules Operation is subject to the following two conditions: 1. This device may not cause harmful interference 2. This device must accept any interference received, including interference that may cause undesired operation. This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15 of the FCC Rules.
Legal Notices All information, including, but not limited to, information regarding the features, functionality, and/or other product specification are subject to change without notice. Fibaro reserves all rights to revise or update its products, software, or documentation without any obligation to notify any individual or entity. FIBARO and Fibar Group logo are trademarks of Fibar Group S.A. All other brands and product names referred to herein are trademarks of their respective holders.