Fusion Relay 4-Channel 30-Amp with RS-232 Interface
The FR430_ZRS is a 4th Generation relay controller offering the ultimate relay control solution... without exception. Capable of
making decisions to control relays based on sensor reading or a time schedule. Fusion series controllers offer easy setup without programming. Fusion
controllers can be adapted to any automation application you could imagine.
Two Communication Ports
The FR430_ZRS has two communications ports! The first port has a RS-232 interface that will allow you to connect the board to the DB9 port on
your computer. The board will mount to any existing COM port. Use it as a second communication port with a different interface, use it
to wirelessly communicate to other Fusion boards or leave it empty.
It's All Here
The FR430_ZRS combines ProXR Computer Control, Reactor Sensor Control, Taralist Time Scheduling, and Remote Access wireless communications,
use all feature or just some of them! It's the best of all technologies fused into a single controller!
Fusion Relay 4-Channel 30-Amp with RS-232 Interface
4 30-Amp Relays Installed
- Single Pole Single Throw (SPST) Relay
- Highly reliable Under Almost any Conditions
- Temperature Rating -40° C to 85° C
- Expandable up to 256 Relays
RS232 Interface w/Choice of RS-232 connector
- On-board DB9 Connector:
- Screw Terminal Connector
- Off the Board DB9 Connector
- Connects to Any Available COM Port
Industry Leading Command Set
- Time Schedule Control
- Sensor Control
- Push Notification
- Two UXP Ports
Connects to Third Party Devices
RS-232 devices are perhaps versatile and most popular choices because of their ability to adapt to any other communication protocol and devices. For instance, using 3rd party devices, RS-232 relay controllers can be controlled from GSM modems, Ethernet to Serial Adapters, WiFi to Serial Adapters, USB to Serial Adapters, Bluetooth to Serial Adapters, and Wireless Mesh Network to Serial Adapters. RS-232 will continue to adapt to all emerging technologies, as the foundation for all communication technologies has provisions for RS-232 communications. With the DB-9 or direct wire capabilities this controller can connect to third party devices including Crestron almost any way possible.
Integrates with Crestron
This relay can integrate with Crestron, in fact we have many Crestron customers using our devices. The most important thing you need to know is how to format the data out the serial port of the Crestron device. Our devices work with Hex/Decimal byte values. Crestron systems usually work with Hex values, our devices start with a header byte of 254, followed by a command (ProXR controllers need 254, 108, 1 to activate the first relay). So you need to convert all of these values to Hex for the Crestron system and send the bytes out the port. For a detailed list of all the commands with descriptions see our ProXR Enhanced Command Set.
Mounts as a COM Port
This ProXR Lite series controller connects to the RS-232 port of your computer and requires a 12VDC Power Supply. This ProXR series controller connects to the serial port of your computer and will mount as a COM port on your PC. Once powered up, the controller waits for a command. A command consists of a few bytes of data in numerical format usually between 2 and 6 bytes. Once the command has been received, the controller processes the command, and sends you back ASCII character code 85 to signal the completion of your command.
This board is equipped with a ZRS Module. The ZRS RS-232 Serial Interface module adds a serial port to the NCD line of products. The ZRS Module
is offered with 3 different RS-232 connection options depending on the wiring option that best suits your application. The ZRS module is powered from the serial port of your computer. The board itself will require 12 volts of power and can be hard wired or you can purchase a "wall wart" type Power Supply at checkout.
Three ZRS Modules Available
There are three RS-232 connection options available for this controller.
ZRS-A Wire It Up
ZRS-B Plug It In
Choose Your Connector
Choose the connection that fits your needs. The ZRS-A connection is recommended for applications where hard wiring directly to the board is needed. ZRS-B has the full 9-Pin DB-9 connector on the board. The ZRS-AB Has the DB-9 connector but is is located off the board for applications where the board may be place inside an enclosure an the RS-232 connector needs to reach to the side of the enclosure. You can choose one of these connection options at checkout.
Perhaps the most overlooked aspect of relay control is proper handling of inductive loads. Inductive loads can best be defined as anything with a magnetic coil, such as a motor, solenoid, or a transformer. Controlling a inductive load using this relay controller requires the use of induction suppression capacitors. The purpose of this capacitor is to absorb the high voltages generated by inductive loads, blocking them from the contacts of the relay. Without this capacitor, the lifespan of the relay will be greatly reduced. Induction can be so severe that it electrically interferes with the microprocessor logic of our controllers, causing relay banks to shut themselves down unexpectedly. In the case of Serial devices, it is not as severe as using a USB port a capacitor is still recommended. Capacitors that we offer are available at checkout, for more information view our Induction Suppression Video.
USB Induction Solution
If USB is required, an RS-232 communications module will allow RS-232 communications between your PC and controller with no complications. A USB to RS-232 adapter (available at checkout) can be used in combination with the RS-232 controller. The RS-232 communications format with a capacitor effectively blocks induction to safe levels for a USB to RS-232 adapter to function without errors.
Fusion controllers are the most powerful relay controllers we offer. Fusion controllers are essentially three separate relay controllers built into a single device. Each controller has the ability to control relays in very different ways. Specializing in autonomous and computer controlled switching applications, Fusion controllers are capable of operating by themselves or under computer control from anywhere in the world.
Dual Port Interface
One of the most exciting and most requested features - Dual Interface communication port. You may use these two communication ports to talk to computers, servers, or mobile devices! For the most part, these ports are identical to each other and may be used independently. No port has any particular priority over the other. However, Port Number 2 is the Remote Access port. The Remote Access Port has special features that enable Fusion controllers to talk to other Fusion controllers. Remote Access can be used to send commands and to access sensors in other wireless locations. By default, Fusion firmware is burned with Remote Access configured on Port 2. You do not really need to do anything to disable Remote Access if you do not plan on using it. Remote Access does not get in the way when not in use.
ProXR Relay control capabilities offer the ultimate computer controlled relay solution. The 4th Generation ProXR Advanced command set is designed to give you computer control of relays, overriding the sensor and time control features configured into the controller.
Reactor Sensor Control
When your application demands sensor controlled relays, Reactor will let you point and click your way into a simple configuration that triggers relays, timers, and counters based on sensor values. Let Reactor manage your relay control needs based on temperature, light levels, humidity, motion detection, and much more. Compatible with most sensors, Reactor is a powerhouse relay control solution for managing your most demanding automation tasks without programming.
Time Schedule Control
Taralist allows you to build a Time Activated Relay Schedule with up to 999 events with Daylight Savings Time, Holidays, and Leap Year support, Taralist is capable of managing about any application that requires relay control on a regular time schedule. Link Taralist and Reactor for applications that require sensor controlled relays on a time schedule. (see recommended accessories below for important information)
Remote Access Wireless
Combine several Fusion controllers together within wireless range and Fusion series controllers act as a single, gigantic relay controller, capable of sharing sensor data among the group of wireless Fusion controllers. Develop your software to talk to one controller and Fusion will automatically manage wireless communications to all remote devices. Your software will seamlessly communicate with wireless devices as though they were a single relay controller.
4th Generation Technology
The Fusion series is NCD's 4th Generation relay controller offering the ultimate relay control solution. Capable of making decisions to control relays based on sensor reading. Fusion series controllers offer easy setup without programming. Fusion controllers can be adapted to any automation application you could imagine. Combining ProXR Computer Control, Reactor Sensor Control, Taralist Time Scheduling, and Remote Access wireless communications, it's the best of all technologies merged into a single controller!
Fusion - Built to Automate
Fusion Series Relay Controllers were built to make relay control decisions automatically. From time scheduling to sensor monitoring, Fusion offers an arsenal of features designed to quickly and intuitively automate relays control functions without programming. We chose Fusion as the series name because it is a true blending of technologies we have been developing since 1995. Fusion is the most powerful series controllers we have ever created, with a clear overlap of technologies working together to create the ultimate relay control solution.
Base Station Configuration
Fusion Controllers are configured using Base Station Software. Using a point-and-click interface for configuration means you can accomplish complex automation tasks in minutes. There are no programming languages to learn and no heavy documents to read. Base Station intuitively guides you through the process of monitoring sensors, setting limits, triggering counters, timers, and relay control events. Base Station will communicate to any Fusion controller using any interface, providing you access to your most important automation applications. Base Station is an essential starting point for Fusion controllers.
Time Schedule Control
Fusion controllers include our 3rd generation Taralist time scheduling firmware. With support for Daylight Savings time and Leap-Year Compensation, Fusion controllers offer the world's most powerful relay time scheduling system. Holiday mode may also be scheduled, temporarily halting event processing. Taralist works with Reactor to decide if a relay should be triggered based on a time schedule and a sensor reading.
Fusion controllers include our 2nd generation Reactor automatic relay control firmware. Built to read sensors, both local and wireless remote, Reactor analyzes sensor readings, makes decisions, and control relays... no programming required! Define sensor limits, increase and decrease relay pattern counters, trigger timers, send push notifications, and much more. Reactor is the most powerful automatic relay control solution available.
Fusion controllers read up to 16 sensors in the background, waiting for a sensor to violate user-defined limits. Monitor contact closure and analog inputs from on-board I/O or from any supported UXP Expansion device. Fusion controllers can acquire sensor data from other Fusion controllers when linked together through Wireless Remote Access...with up to 1-Mile wireless distance between Fusion controllers. You control the speed of sensor monitoring to best fit your application. Sensors are monitored with up to 16-bit resolution when possible.
Input Limits & Triggers
Fusion knows the difference between Analog and Digital sensors, with dedicated Input Limits and Trigger control panels for each type of sensor. Analog sensors are monitored with up to 16-Bit resolution while digital sensors are monitored at 8-Bit resolution. Fusion controllers allow you to define up to seven analog sensor limits per sensor (with the TLEE Expansion Module installed). When a sensor value crosses a preset limit, Fusion will automatically trigger relay control events, timers, counters, relay flashers, and/or send a push notification to the user.
Fusion Controllers use a standardized event list throughout the configuration process. When a sensor violates preset limits, an event is triggered. Events include relay control functions such as activating or deactivating a relay. Relay flashers are also supported (used to flash a relay on and off automatically). Events also include timers, used for duration timing applications (such as activating a relay for 5 minutes). Counters are used to directly control relay patterns (allowing relays to be controlled in sequence). Other events include Push Notification support, allowing the controller to notify a user or a server of important sensor activity.
Fusion Controllers include 16 timers that may be present for up to 255 hours, 255 minutes, and 255 seconds. Timers are mostly used for controlling relays for a preset period of time. For instance Timer 1 can be configured to control Relay 1 for 10 minutes. Anytime Timer 1 is triggered, Relay 1 will activate for 10 minutes. However, Timers have the ability to trigger any function in the Event list, so timers are not limited to just relay control applications.
Fusion controllers support 16 different counters. A counter allows a Fusion controller to control a group of up to 8 relays. As the counter is increased, more relays in the group turn on. As the counter is decreased, more relays in the group are turned off. Relays may be turned on and off in sequence, or may be activated in a number of useful patterns. Counters may be increased or decreased based on sensor input, allowing powerful relay control sequences for lighting control applications.
Fusion controllers support 16 flashers. When a Flasher is activated, a relay turns on and off automatically. Flashers are ideally suited for security and alert signaling applications. Combined with sensor control functions, flashers can activate or deactivate as sensors are triggered.
In the real world, there will be times when you need to manually take control. Every automation solution must include powerful provisions for manual control applications. Fusion offers a comprehensive override controller for those times when you need complete control from anywhere in the world.
Reactor enables a Fusion Series relay controller to control relays based on sensor inputs. Reactor has the ability to read sensors connected directly to a Fusion controller or to wireless remote Fusion controllers linked using our Remote Access wireless communication technology. This allows Fusion controllers to share sensors with each other in a wireless group. Reactor allows you to mix local and wireless remote sensors together in any combination.
Monitor 16 Sensors
Reactor is capable of monitoring up to 16 different sensors, with special provisions for analog and digital sensor data. Reactor also includes 16 counters, used for controlling relay sequences, as well as 16 timers. Reactor is capable of controlling the first 32 relays of a Fusion controller. Additional relays may be controlled using Taralist (time schedule) or ProXR (computer control).
Preset List of Events
Reactor has a preset list of events available. When sensor values match user-defined settings, events are triggered. Events allow you to control relays, flash relays, trigger/reset timers, increase/decrease counters, send/push notifications to a server, and much more.
TLEE Expansion Module
The capabilities of the Reactor processor are greatly expanded when the TLEE expansion module is plugged into the Fusion controller. The TLEE expansion module provides additional memory as well as Real Time Clock, allowing the Fusion controller to control relays based on a time schedule. With the TLEE expansion module installed, users will have many more ways to trigger events. For example, analog sensors will be capable of handling up to 7 limits per sensor with 32 total events per sensor! Without the TLEE, analog sensors are limited to 2 limits per sensor and 12 events. Push notifications are possible for users with the TLEE expansion module installed.
Remote Access features allow a Fusion controller to ask other Fusion controllers for sensor data using wireless communications. A TLEE expansion module is required for a Fusion controller to ask another Fusion controller for data. However, a Fusion controller is capable of responding to requests for sensor data without a TLEE expansion module. Put simply, a TLEE is required in applications where the Fusion controller acts as a master (requesting sensor data), but the TLEE is not required when Fusion is acting as a slave (responding to sensor data requests).
Relays & Timers
Reactor also includes a method of associating relays to Timers and Counters. This allows relays to follow the sequence of a counter (with many counting sequence types available). Relays may also be associated with timers, activating or deactivating as timers reach various states. Timer and counters may be combined, allowing relays to be progressively switched as time increases (perfect for runway or driveway light applications).
Since Fusion controllers have three separate relay controllers integrated into the firmware (Reactor, Taralist, and ProXR), these three controllers require a clearly defined strategy for managing relay priorities. Without it, relay state changes would be unpredictable. Fusion controllers have a very powerful and flexible relay priority system that is color coded when using our Base Station software, making it easy to see which controller has control of the relay.
By default, Reactor relay control has priority over a Taralist relay (time schedule relay), and has a lower priority than a ProXR Relay (computer controlled relay). However, Taralist and Reactor can control a relay cooperatively. Using cooperative relay control you can tie a sensor to a time schedule. The relay priority system can be configured so that both Taralist and Reactor must tell the same relay to turn on before the relay will activate. The cooperative state of the relay may also be changed so that either Taralist OR Reactor can activate the same relay. However, the default cooperative state of the relay is for Reactor to take control and override a Taralist relay, and when this happens, Taralist will be unable to control a Reactor relay. ProXR (computer control) always has top priority over Taralist and Reactor, allowing users to override sensor and time scheduled relay control.
Base Station Software
Reactor is configured using Base Station Software. Base Station is capable of communicating and configuring a Fusion controller using any supported communication technology. Fusion controllers equipped with Wi-Fi, Ethernet or Web-i interface may be configured remotely over the internet provided port forwarding is properly configured on your router. A static IP address is not required for remote configuration.
Analog Data Sources
The objective of ADC is to convert a sensor to a voltage and a voltage to a value. Reactor works with these data values directly, making decisions based on the values. Reactor is capable of reading analog data from various data sources, analog data is limited to 0 to 5 Volts DC. The process of analog to digital conversion is completely managed by the Fusion controller, converting this voltage to numeric values that can be monitored by Reactor. Analog to Digital Conversion (ADC) makes it possible for Reactor to read the light levels in the room and activate relays accordingly. Similarly, ADC allows Reactor to read temperature, humidity, moisture, sound levels, and much more. There are many kinds of sensors that are compatible with Reactor ADC.
During configuration, you may see options for 8-bit, 10-bit, 12-bit or other resolutions of data sources. Reading an analog data source at 8-bit resolution means Reactor is capable of reading a voltage from 0 to 5 volts converting it to a value from 0 to 255. Reading an analog data source at 10-bit resolution means Reactor is capable of reading a voltage from 0 to 5 volts and converting it to a value from 0 to 1023. Similarly, 12-bit resolution converts the incoming voltage to a value from 0 to 4095.
One limit is defined at a value of 100 (1.95 volts). When the analog value equals or falls below 100, the “Events Triggered Below Limit” are executed. When the Analog value goes above 100, four events are triggered in the “Events Triggered Above Limit” column. Reactor is automatically smoothing the input using the “8-Bit Analog with Data Smoothing” option. Data smoothing may be turned off in applications that may require Reactor to instantly respond to analog changes. Data Smoothing is the default option, making Reactor immune to occasional random voltage spikes that may be presented to the controller in electrically noisy installations. In the sample to the right, a TLEE expansion module is NOT installed, so only two limits are possible for this data source. With the TLEE expansion module installed, seven limits are possible, see example below.
Fusion Reactor Videos
A Push Notification is a message sent to a computer from the Fusion controller. Push notifications often contain sensor and relay status information to keep the computer updated on what the Fusion controller is doing, or to notify a computer of any sensor values that may be out of range. Push notifications are triggered as a Reactor event, and may be triggered in the same method as any other Reactor event. Because Reactor events may be triggered from a Taralist time schedule, Push notifications may be sent at specific times of the day. A Push Notification consists of data bytes that may be sent out Port 1 or Port 2 on the Fusion controller. It is not possible to send a Push Notification on Port 2 if Remote Access is configured. Remote Access allows Fusion controllers to exchange data among each other, whereas Push Notification should only be used to send data from a Fusion controller to a user or server.
Push notifications have a few customization variables that indicate the data content of a Push Notification. A Push Notification may consist of only a few bytes of data or as much as 44 bytes of data, depending on the options you have chosen. The Push Notification Setup window does not really have too many user-configured options, despite the size of the window. This configuration control panel uses most of its screen space demonstrating the organization of a Push Notification data packet, greatly simplifying software development for interpreting Fusion Push Notification data packets.
Push Notification Configuration
Push notifications are configured using a few checks to indicate data that is to be included in the data packet. Header Bytes 1 through 4 shown below may be used for anything or to help identify the controller that sent the Push Notification. Push notifications can be sent to Port 1 or Port 2. Port 2 will be unavailable if your Fusion controller is configured for Remote Access. Use Reactor events to trigger push notifications. Taralist is capable of triggering Reactor events.
Fusion Remote Access
Send commands from any Fusion controller to any other Fusion controller. Using Remote Access, 257 relay controllers can act as one gigantic relay controller. All 257 relay controllers must be within 1 mile, line of site, for proper operation.
Second Communication Port
Remote Access uses the second communication port on your Fusion controller. Every Fusion controller must use the second port to join in on the Remote Access “group”. Remote Access wirelessly links your Fusion controllers together. Up to 257 relay controllers can be wirelessly linked together using Remote Access (Master + 256 Wireless Remote Slaves). What you end up with is a single, gigantic relay controller with all the pieces spread up to one mile away. Every remote Fusion controller is capable of talking to the entire group, so every Fusion controller can act as a Master or a Slave to another Fusion controller. Building this group is what configuration is all about.
Tunneling is the ability to use a Fusion controller to take control of another Fusion controller. Tunneling essentially turns your Fusion controller into a modem or communications relay station, forwarding all commands directly to a remote Fusion controller. Tunneling can effectively double the useful wireless range of a Fusion controller as it is possible to send wireless commands to a Fusion controller and have this controller forward your commands to a remote Fusion controller.
Remote Command Execution
Remote Command Execution is where one Fusion controller forwards a single command to a remote Fusion controller. If you are a software developer, you can easily forward commands to 256 different Fusion controllers in the local area. Remote Command Execution is instantaneous, allowing you to process up to ten commands per second. Instantly control relays in the pool house, the kitchen, the office, or open any of the doors to your 20-car garage! Read sensors all around the estate to gather temperature, humidity, light levels and even ground moisture. Your software talks to one controller, Remote Access COMPLETELY handles communications to all 256 slaves.
Remote Data Collection
Remote Data Collection is a Reactor feature. Using Remote Data Collection, Reactor has the ability to access up to 16 remote sensors on any of the first 16 wireless Fusion controllers that are connected to the Remote Access group. Reactor can be configured to control relays automatically based on remote sensor values.
Fusion series controllers are capable of communicating to I2C devices such as temperature sensors, gyros, accelerometers, light sensors, humidity sensors, non-volatile EEPROM, SRAM, and many other types of I2C devices. The I2C capabilities of a Fusion controller provide users with a pathway to access these devices using any of our interface technologies.
Select Fusion I2C capable devices support at least two I2C communication ports (Port 0 and Port 1). Port 0 has a fixed communication rate of 100 KHz and may be used by NCD devices that contain integrated sensors, I/O Expanders, or other types of I2C devices. Though we may allow access to Port 0 on select controllers, Port 0 should generally be considered for use by the NCD products and peripheral devices. For instance, we may offer expansions that offer additional features by utilizing Port 0. Port 0 is typically accessed using the FXR Relay Expansion Port. I2C Port 1 is for general use by our customers. Port 1 is available for on AD8 Port 1 (shared with UXP Port 1) using I/O Lines 1 (SDA) and 2 (SCL). I2C Port 1 can be tuned for faster or slower speeds. Slower speeds allow Fusion controllers to communicate I2C data over longer distances while faster speeds offer greater compatibility.
Fusion I2C Port 1 supports 500 Hz, 1 KHz, 10 KHz, 50 KHz, 100 KHz, and 130 KHz communication speeds (which has all been precisely timed with an oscilloscope), and supports I2C device clock stretching, as required by the I2C communication protocol (a feature often skipped by most I2C implementations). Development of the I2C communication routines were centered on a 24LC515 Non-Volatile EEPROM, and has been tested with various I2C sensors to prove functionality.
Use of I2C communication functions on Fusion series controllers require prior knowledge of I2C, as it is outside the scope of our documentation to go into a detailed explanation of the protocol. Here we will focus on the data exchange between a computer and the Fusion controller. The Fusion controller will manage the data exchange with the I2C device, greatly simplifying the amount of information that must be studied.
First Time Users
When working with I2C for the first time, it is helpful to use the 24LC515 EERPOM connected to a Fusion controller. The 24LC515 demonstrates 2-way communications with the device, showing you how to read and write data as shown in the sample provided in Base Station software.
Overview of I2C
For complete details on the I2C protocol there are many resources available online, some of which have some very good descriptions of the protocol itself. Most of the detailed protocol information may be skipped when working with a Fusion controller as the difficult part of communications is completely handled by the firmware. Even so, there are a few things you need to understand before you can successfully implement communications to an I2C device. Full descriptions can be found in the Fusion I2C Guide in the Data Sheets tab above.
Fusion Master Control Panel
Fusion Series controllers have some very important commands that warranted their own control panel. The Fusion Master Control Panel is used to control the performance of the Fusion CPU as well as control the three most important background tasks. The Fusion Master Control Panel also allows you to download and upload device settings to the controller. Great for backing up certain features of the Fusion controller.
Taralist Event Processing
Turn Taralist Event Processing on or off with this control panel. When off, Taralist event processing will stop functioning, but the Taralist command set will
continue to function.
Reactor Event Processing
Turn Reactor Event Processing on or off with this control panel. When off, Reactor will stop evaluating sensors. Note that if this function is turned off, Remote Sensor Data Collection stops functioning, as remote data collection operates under Reactor. The interface will NOT reflect this condition, as the interface is designed to directly modify the on/off states of each of these three features. Turning off Reactor Processing does not turn off Remote Sensor Data Collection, but it does stop the task that calls Remote Data Collection.
Remote Sensor Data Collection
Turn Remote Sensor Data Collection off to stop communications with wireless sensors. This feature will stop functioning if Reactor Processing is stopped. Remote Data Collection is used by Reactor to access wireless sensors. Remote Access should be turned off when tunneling to another device or when sending commands to a remote device.
Reactor Event Processing Speed
Reactor Event Processing Speed is used to control how fast Reactor reads sensors and makes decisions to control relays. Users might be tempted to set this value to full speed, however, this will affect performance of other background tasks and may cause relays to glitch on and off if a sensor is setting on the threshold of a relay control operation. Users should experiment with this setting, keeping in mind the default processing speed is 7. Small adjustments and experimentation is advised.
Remote Sensor Data Collection Speed
The speed of Remote Sensor Data Collection can be adjusted using this control panel. This is a rather intensive operation for the Fusion controllers, as very large API packets of data must be assembled and sent as a background task. Decreasing this speed significantly increases the workload of the Fusion CPU. Experimentation is advised as this function will slow the performance of the CPU for other tasks, including communications with a computer. Users are advised to set this setting as high as possible so Fusion has plenty of time to service other tasks.
Sensor Trap Time
Sensor Trapping is an experimental feature. If a sensor detects a value that is out of range, the sensor value can be trapped for the number of seconds defined by this setting. When the sensor is trapped, the actual value of the sensor will be ignored. Instead, the trapped value will be shared.
The Power-Up State of Reactor, Taralist, and Remote Access may also be controlled from this control panel. Note that these functions modify internal EEPROM memory that is only examined when the controller first powers up.
Loading and Saving Fusion Settings
Fusion Controllers contain EEPROM used to store various configuration settings. The Fusion Master Control Panel should be used to directly load and save EEPROM data into a Fusion controller.
Fusion - Built to Expand
With 2 UXP expansion ports, Fusion controllers know how to expand. Easily add Analog to Digital Converters, Contact Closure detectors and digital potentiometers to your Fusion controller. Fusion controllers also support I2C devices, adding a wide variety of sensors to meet your application objectives. The FXR Expansion Port allows you to add expansion relay boards to your Fusion controller.
16 Programmable I/O Lines
Fusion Series Controllers have 16 programmable I/O lines, which may be used for contact closure input, digital input, digital output, 8/10-Bit Analog to Digital Conversion, or I2C expansion. In most cases, these features may be mixed and matched as your application requires.
Read a Variety of Sensors
Fusion Series Relay Controllers know how to connect to your application. With a simple point and click configuration, you can read a variety of sensors in just a few minutes. Fusion will automatically monitor your sensor in the background and make relay control decisions if a sensor is tripped or goes outside an acceptable range.
Contact Closure Input Capabilities
Configure your Fusion Relay controller to read up to 16 contact closure inputs, making light work of complex relay control tasks. Connect magnet detection sensors, break-beam detectors, contact-closure output current sensors, or any kind of switch you can imagine. Fusion Series Relay Controllers will monitor your sensor and trigger relays or send a notification to your server if any sensor is triggered.
Digital I/O Capabilities
With 16 programmable I/O lines available, Fusion Relay Controllers can easily interface to a variety of logic circuits, ideal for the expert developer who needs low-level bit control. Program any I/O line as an input or output. Read and Write individual data bits or read and write data one 8-bit port at a time.
Analog to Digital Conversion
Fusion Series controllers include 16-Channels of Analog to Digital conversion, capable of reading many popular sensors with an output voltage of 0 to 5VDC. Interface to photocells for light sensing applications, thermostats for temperature sensing applications, or interface to potentiometers, current sensors, or any other device capable of providing a 0 to 5VDC output.
Fusion Series Controllers include a I2C port for access to devices such as gyroscopes, high-resolution analog to digital converters, digital to analog converters, port expanders, potentiometers, light, temperature, humidity sensors, and much more. A second "hidden" I2C bus in the Fusion Expansion Relay (FXR) Port allows us to develop a wide variety of I2C and Relay Expansion devices combined on a single expansion.
UXP Port Capabilities
Fusion Series controllers include TWO UXP Ports allowing interface to a variety of NCD expansion devices. Expand contact closure input detection up to 2,048 Channels per UXP Port. Add 16, 32, or 48-Channels of 12-Bit Analog-to-Digital Conversion per UXP port, expanding your Analog input capabilities up to
96-Channels per Fusion controller! Each UXP port is also capable of controlling 256 Potentiometer output channels. Connect a simple Breakout board to the UXP port to access the 8 programmable digital I/O or 8/10-Bit Analog input channels.
Distance Measurement Capabilities
Fusion Series controllers easily interface to Ultrasonic Transducers capable of accurately measuring distance up to 6 feet with .250" (6.35mm) resolution. Use Ultrasonic sensors to control relays if an obstruction is detected. Up to 8 ultrasonic transducers are supported by the Fusion series CPU.
FXR Expansion Port Capabilities
Fusion Series controllers are equipped with our Second Generation FXR Relay Expansion Port. The FXR Port carries the same relay control data as the XR Expansion port found in earlier controllers. Expansion boards can be added using the FXR expansion port and can control up to 2566 relays. Expansion boards are not available with 20 or 30 amp relays installed.
Power Supply Available
Reliable Power Means Reliable Switching
The PWR12 is regulated power supply providing clean power necessary for
the performance of these boards. The PWR12 US power supply is a 120VAC to 12VDC 1.25A 60Hz regulated
power supply and it plugs into the barrel connector on the board. The output connector is a 2.1mm I.D. x 5.5mm
O.D. x 9.5mm R/A barrel connector.
The TLEE expansion module defines the way
a Fusion controller is configured in Base Station software. The Fusion CPU has a small amount of memory used to store essential settings. By
itself Fusion can do many things. However, the really powerful features require the memory resources of the TLEE expansion module. The TLEE Module
is required for most Reactor (Sensor Control) Features, all Taralist (Time Schedules) features and Push Notification. Not required for all functions
so we offer it as an option at checkout.
A/D 8-Channel Expansion
Connect a simple Breakout board to the
UXP port to access the 8 programmable digital I/O or 8/10-Bit Analog input channels. The AD8 8-Channel Expansion Module provides 8 0-5 volt analog
inputs capable of reading many popular sensors with an output voltage of 0 to 5VDC. Interface
to photocells for light sensing applications, thermistors for temperature sensing applications, or interface to potentiometers, current sensors, or any
other device capable of providing a 0 to 5VDC output.
an inductive load using our relay controllers requires the use of induction suppression capacitors. The purpose of this capacitor
is to absorb the high voltages generated by inductive loads, blocking them from the contacts of the relay. Without this capacitor,
the lifespan of the relay will be greatly reduced. Induction can be so severe that it electrically interferes with the microprocessor
logic of our controllers, causing relay banks to shut themselves down unexpectedly.
Lite is software that allows you to configure buttons to control relays and read the status of those relays without programming. You
can also create meters for reading variable input sensors connected to the board in real time!
Data Sheets & Quick Start Guides
Below are the Data Sheets Quick Start Guides for this board. These are the guides that will help you communicate and
configure this board.