Kinesis® K-Cube™ NanoTrak® Active Auto-Alignment Fiber Controllers
- Maintain Long-Term Optical System and Fiber Alignment
- Two Outputs for Driving Piezo Actuators
- Visible (320 to 1000 nm) or IR (900 to 1700 nm) Detector
KNA-VIS
320 nm - 1000 nm
(Power Supply Sold Separately)
Table Mounting Plate (Included with K-Cube)
Kinesis® Software GUI Screen
Software Included with All K-Cube NanoTrak® Controllers
Please Wait
NanoTrak® Active Auto-Alignment Controllers | |||||
---|---|---|---|---|---|
K-Cube 2-Channel Controllers | |||||
Benchtop 2-Channel Controller | |||||
Modular 2-Channel Rack System Module | |||||
K-Cube™ Motion Control Modules | |||||
Brushed DC Servo Motor Controller | |||||
Brushless DC Servo Motor Controller | |||||
Four-Channel Piezo Inertia Actuator Controller | |||||
PSD Auto Aligner | |||||
Single-Channel Piezo Controller and Strain Gauge Reader | |||||
Solenoid Controller | |||||
Stepper Motor Controller |
Applications
- Fiber-to-Fiber Active Alignment
- Fiber-to-Free-Space Active Alignment
- Optical Device Alignment
- Waveguide Characterization
- Fiber Characterization and Testing
- Fiber Pigtailing of Active and Passive Devices
- Maintain High Power Throughput to an Entire Optical Setup
Click to Enlarge
Back View of the K-Cube NanoTrak® Controller (See the Pin Diagrams Tab for More Information)
Click to Enlarge
Top View of the K-Cube NanoTrak® Controller
Features
- Compact Footprint: 121 mm x 60 mm x 47 mm
- Two Piezo Actuator Output Channels Provide Closed-Loop Feedback
- Two Detector Options:
- Si for 320 to 1000 nm
- InGaAs for 900 nm to 1700 nm
- Control Using Top Panel or PC Software via USB Plug-and-Play Connectivity
- FC/PC Optical Input Connector
- Tracking Mode Achieves and Maintains Optimum Throughput
- Latched Mode Maintains Stable Positioning
- Includes Kinesis® and APT™ Software Control Suites
- Magnetic, Clip-On Optical Table Mounting Adapter Included
- Single- and Multi-Channel PSU Options Available Separately
K-Cube™ NanoTrak® Active Auto-Alignment Controllers are a part of Thorlabs' new and growing Kinesis® line of high-end, compact motion controllers. The active auto-alignment controllers are designed to maximize the power throughput of an optical setup, including fiber-to-fiber and fiber-to-free-space systems. By driving a piezo-actuated stage to move the fiber tip in a circular scan pattern, the controller performs a power gradient search to determine the direction of peak power and positions the fiber for maximum throughput. Two high-voltage output channels provide the drive signal for the associated piezo actuators, eliminating the need for external piezo drivers. In combination with a multi-axis, piezo-driven stage, such as our 3-Axis NanoMax and 6-Axis NanoMax stages, a K-Cube active auto-alignment controller creates a complete, compact auto-alignment system (see the Application tab for more details).
The small footprint of this unit (121 mm x 60 mm x 47 mm) and quickly detachable mounting plate allow the K-Cube to be securely mounted to an optical table in close proximity to the system it controls. Each controller comes with a preinstalled detector. The KNA-VIS has a Si detector optimized for the visible spectrum (320 nm to 1000 nm), while the KNA-IR has an InGaAs detector for the infrared (900 nm to 1700 nm). The front of each unit features a power switch that, when turned off, saves all user-adjustable settings. Top panel controls enable convenient standalone operation, and the easy-to-read digital display allows the user to monitor the alignment.
USB connectivity provides easy 'Plug-and-Play' PC-controlled operation, and a suitable cable is included with each K-Cube NanoTrak controller (USB 3.0 type A to USB type Micro-B). Two software packages are available: Kinesis, which features new .NET controls that can be used by third-party developers working in compatible languages such as C, C# and LabVIEW™ to create custom applications, and our legacy APT software. For more details, please see the Motion Control Software, Kinesis Tutorials, and APT Tutorials tabs.
Optical Table Mounting Plate
Each unit comes with a mounting plate that clips onto the base of the module. The plate contains two magnets for temporary placement on an optical table and two counterbores for 1/4"-20 (M6) cap screws for a more permanent placement on the tabletop. Please see the Specs for a mechanical drawing of the table mounting plate and the Mounting Options tab for how to mount the plate.
Power Supply Options
The preferred power supply (multi-channel or hub-based) depends on the end user's application and whether you already own compatible power supplies. To that end and in keeping with Thorlabs' green initiative, we do not ship these units bundled with a power supply.
The TPS002 Power Supply Unit should only be used to power a single KNA-VIS or KNA-IR unit to avoid exceeding current limitations. The KCH301 or KCH601 USB Controller Hubs, available below, are ideal for applications involving multiple K-Cubes and/or T-Cubes. The KCH301 features three controller mounting bays while the KCH601 features six controller mounting bays. These K-Cube NanoTrak controllers occupy two mounting bays, so only the KCH601 hub can be used to power multiple K-Cube NanoTrak controllers. All compatible power supply options can be found below.
Item # | KNA-VIS | KNA-IR |
---|---|---|
Optical Power Measurement | ||
Photodiode Type | Si | InGaAs |
Optical Input Connector | FC/PC | |
Detector Photocurrent | 5 nA to 2.5 mA | |
Saturation Power | 4 mW | 1.5 mW |
Wavelength | 320 to 1000 nm | 900 to 1700 nm |
Optical Power Monitor (SMA) | Multiple Ranges | |
Signal Phase Compensation | -180° to 180° | |
Power Gradient Search | ||
Circle Scanning Frequency | 4.4 to 87.5 Hz | |
Circle Position Range | <1% to >99% Max Piezo Extension | |
Circle Diameter Adjustment Modes | Automatic or Manual | |
Piezoelectric Input/Output | ||
HV OUT Connectors (SMC Male) |
Voltage Output: 0 to 150 VDC/Channel Current Output: 7.5 mA/Channel |
|
MONITOR Outputs (SMA) | 0 to 10 VDC | |
EXT IN Analog Inputs (SMA) | 0 to 10 VDC | |
Other Input/Output | ||
I/O 1 Auxiliary Input/Output | Trigger I/O: 0 to 5 V, External Input: 0 to 2 V | |
I/O 2 Auxiliary Input/Output | Trigger I/O: 0 to 5 V, External Output: 0 to 2 V | |
Input Power Requirements | ||
Voltage | +5 V (160 mA), +15 V (380 mA), -15 V (60 mA), | |
Power | <3 W | |
General | ||
USB Connector Type | USB 3.0 | |
USB Connection Speed | USB 1.1 Full Speed (12 Mbps) | |
Housing Dimensionsa | 121 mm x 60 mm x 47 mm (4.8" x 2.4" x 1.8") | |
Weight | 0.45 kg (0.99 lb) |
Click to Enlarge
Mechanical Drawing of K-Cube NanoTrak® Fiber Alignment Controller
Computer Connection*
*The USB 3.0 port is compatible with a USB 2.0 Micro B connector if the Micro B connector is plugged into the shaded region in the photo above. A USB 3.0 type A to type Micro B cable is included with the K-Cube NanoTrak® Controller.
I/O 1SMA Female |
I/O 2SMA Female |
+5 V TTL | +5 V TTL |
These ports are dual purpose. They can be used as a trigger input and output (0 to 5 V). I/O 1 may be also used as an external input (0 to 2 V), amplifying the input signal and presenting it as a drive signal at the HV OUT connectors on the rear panel. I/O 2 may be also used as an external output (0 to 2 V), providing an analogue monitor OUT for the PIN photodiode. I/O 2 may be connected to I/O 1 for use in a dual NanoTrak® setup. |
Power Connector
Mini-DIN Female
Pin | Description | Pin | Description |
---|---|---|---|
1 | +5 V | 6 | Common Ground |
2 | +5 V | 7 | Common Ground |
3 | -15 V | 8 | Common Ground |
4 | +15 V | Shield | Common Ground |
5 | +5 V |
MONITOR 1SMA Female |
MONITOR 2SMA Female |
HV OUT 1SMC Male |
HV OUT 2SMC Male |
EXT IN 1SMA Female |
EXT IN 2SMA Female |
These low-voltage (0 to +10 V) outputs can be used to monitor the signal at the associated HV OUT high-voltage outputs. They are usually connected directly to an oscilloscope to observe the waveforms or voltage levels present at the high-voltage outputs. | These outputs (0 to 150 V, 0 to 7.5 mA) provide the drive signal to the associated piezo actuators. The maximum voltage (75 V or 150 V) can be set via the front panel or software | Used to receive a piezo feedback signal from a source such as the KPC101 Piezo Controller and Strain Gauge Reader. The input voltage range is 0 to +10 V and the input impedance is 10 kΩ. |
K-Cube Mounting Options
Two options are available to securely mount our K-Cube controllers onto an optical table. An optical table mounting plate, provided with every K-Cube, allows for a single controller to be attached to an optical table. Alternatively, three- and six-port USB controller hubs are offered (sold separately) that can mount and power our K-Cube controllers. These options are described in further detail below.
Optical Table Mounting Plate
Each K-Cube unit comes with a mounting plate that clips onto the base of the controller, as shown in the animation below. The plate contains two magnets for temporary placement on an optical table and two counterbores for 1/4"-20 (M6) cap screws for a more permanent placement on the tabletop. Please see the Specs tab for a mechanical drawing of the table mounting plate.
Kinesis USB Controller Hubs
Multiple units can be mounted and connected to a single PC by using the KCH301 or KCH601 USB Controller Hubs. They each consist of two parts: the hub, which can support up to three (KCH301) or six (KCH601) K-Cubes or T-Cubes, and a power supply that plugs into a standard wall outlet. K-Cubes simply clip into place using the provided on-unit clips, while current- and previous-generation T-Cubes require the KAP101 Adapter Plate, shown in the animation below. The hub vastly reduces the number of USB and power cables required when operating multiple controllers.
K-Cube Table Mounting Plate
Kinesis USB Controller Hubs
3- and 6-Port USB Controller Hubs allow multiple controllers to be connected to one PC for multi-axis applications. K-Cubes can be directly attached to the hubs while T-Cubes require a KAP101 Adapter Plate.
Thorlabs offers two platforms to drive our wide range of motion controllers: our Kinesis® software package or the legacy APT™ (Advanced Positioning Technology) software package. Either package can be used to control devices in the Kinesis family, which covers a wide range of motion controllers ranging from small, low-powered, single-channel drivers (such as the K-Cubes™ and T-Cubes™) to high-power, multi-channel, modular 19" rack nanopositioning systems (the APT Rack System).
The Kinesis Software features .NET controls which can be used by 3rd party developers working in the latest C#, Visual Basic, LabVIEW™, or any .NET compatible languages to create custom applications. Low-level DLL libraries are included for applications not expected to use the .NET framework. A Central Sequence Manager supports integration and synchronization of all Thorlabs motion control hardware.
Kinesis GUI Screen
APT GUI Screen
Our legacy APT System Software platform offers ActiveX-based controls which can be used by 3rd party developers working on C#, Visual Basic, LabVIEW™, or any Active-X compatible languages to create custom applications and includes a simulator mode to assist in developing custom applications without requiring hardware.
By providing these common software platforms, Thorlabs has ensured that users can easily mix and match any of the Kinesis and APT controllers in a single application, while only having to learn a single set of software tools. In this way, it is perfectly feasible to combine any of the controllers from single-axis to multi-axis systems and control all from a single, PC-based unified software interface.
The software packages allow two methods of usage: graphical user interface (GUI) utilities for direct interaction with and control of the controllers 'out of the box', and a set of programming interfaces that allow custom-integrated positioning and alignment solutions to be easily programmed in the development language of choice.
A range of video tutorials is available to help explain our APT system software. These tutorials provide an overview of the software and the APT Config utility. Additionally, a tutorial video is available to explain how to select simulator mode within the software, which allows the user to experiment with the software without a controller connected. Please select the APT Tutorials tab above to view these videos.
Software
Kinesis Version 1.14.49
The Kinesis Software Package, which includes a GUI for control of Thorlabs' Kinesis and APT™ system controllers.
Also Available:
- Communications Protocol
Thorlabs' Kinesis® software features new .NET controls which can be used by third-party developers working in the latest C#, Visual Basic, LabVIEW™, or any .NET compatible languages to create custom applications.
C#
This programming language is designed to allow multiple programming paradigms, or languages, to be used, thus allowing for complex problems to be solved in an easy or efficient manner. It encompasses typing, imperative, declarative, functional, generic, object-oriented, and component-oriented programming. By providing functionality with this common software platform, Thorlabs has ensured that users can easily mix and match any of the Kinesis controllers in a single application, while only having to learn a single set of software tools. In this way, it is perfectly feasible to combine any of the controllers from the low-powered, single-axis to the high-powered, multi-axis systems and control all from a single, PC-based unified software interface.
The Kinesis System Software allows two methods of usage: graphical user interface (GUI) utilities for direct interaction and control of the controllers 'out of the box', and a set of programming interfaces that allow custom-integrated positioning and alignment solutions to be easily programmed in the development language of choice.
For a collection of example projects that can be compiled and run to demonstrate the different ways in which developers can build on the Kinesis motion control libraries, click on the links below. Please note that a separate integrated development environment (IDE) (e.g., Microsoft Visual Studio) will be required to execute the Quick Start examples. The C# example projects can be executed using the included .NET controls in the Kinesis software package (see the Kinesis Software tab for details).
Click Here for the Kinesis with C# Quick Start Guide Click Here for C# Example Projects Click Here for Quick Start Device Control Examples |
LabVIEW
LabVIEW can be used to communicate with any Kinesis- or APT-based controller via .NET controls. In LabVIEW, you build a user interface, known as a front panel, with a set of tools and objects and then add code using graphical representations of functions to control the front panel objects. The LabVIEW tutorial, provided below, provides some information on using the .NET controls to create control GUIs for Kinesis- and APT-driven devices within LabVIEW. It includes an overview with basic information about using controllers in LabVIEW and explains the setup procedure that needs to be completed before using a LabVIEW GUI to operate a device.
Click Here to View the LabVIEW Guide Click Here to View the Kinesis with LabVIEW Overview Page |
The APT video tutorials available here fall into two main groups - one group covers using the supplied APT utilities and the second group covers programming the APT System using a selection of different programming environments.
Disclaimer: The videos below were originally produced in Adobe Flash. Following the discontinuation of Flash after 2020, these tutorials were re-recorded for future use. The Flash Player controls still appear in the bottom of each video, but they are not functional.
Every APT controller is supplied with the utilities APTUser and APTConfig. APTUser provides a quick and easy way of interacting with the APT control hardware using intuitive graphical control panels. APTConfig is an 'off-line' utility that allows various system wide settings to be made such as pre-selecting mechanical stage types and associating them with specific motion controllers.
APT User Utility
The first video below gives an overview of using the APTUser Utility. The OptoDriver single channel controller products can be operated via their front panel controls in the absence of a control PC. The stored settings relating to the operation of these front panel controls can be changed using the APTUser utility. The second video illustrates this process.
APT Config Utility
There are various APT system-wide settings that can be made using the APT Config utility, including setting up a simulated hardware configuration and associating mechanical stages with specific motor drive channels. The first video presents a brief overview of the APT Config application. More details on creating a simulated hardware configuration and making stage associations are present in the next two videos.
APT Programming
The APT Software System is implemented as a collection of ActiveX Controls. ActiveX Controls are language-independant software modules that provide both a graphical user interface and a programming interface. There is an ActiveX Control type for each type of hardware unit, e.g. a Motor ActiveX Control covers operation with any type of APT motor controller (DC or stepper). Many Windows software development environments and languages directly support ActiveX Controls, and, once such a Control is embedded into a custom application, all of the functionality it contains is immediately available to the application for automated operation. The videos below illustrate the basics of using the APT ActiveX Controls with LabVIEW, Visual Basic, and Visual C++. Note that many other languages support ActiveX including LabWindows CVI, C++ Builder, VB.NET, C#.NET, Office VBA, Matlab, HPVEE etc. Although these environments are not covered specifically by the tutorial videos, many of the ideas shown will still be relevant to using these other languages.
Visual Basic
Part 1 illustrates how to get an APT ActiveX Control running within Visual Basic, and Part 2 goes on to show how to program a custom positioning sequence.
LabVIEW
Full Active support is provided by LabVIEW and the series of tutorial videos below illustrate the basic building blocks in creating a custom APT motion control sequence. We start by showing how to call up the Thorlabs-supplied online help during software development. Part 2 illustrates how to create an APT ActiveX Control. ActiveX Controls provide both Methods (i.e. Functions) and Properties (i.e. Value Settings). Parts 3 and 4 show how to create and wire up both the methods and properties exposed by an ActiveX Control. Finally, in Part 5, we pull everything together and show a completed LabVIEW example program that demonstrates a custom move sequence.
Part 1: Accessing Online Help
Part 2: Creating an ActiveX Control
Part 3: Create an ActiveX Method
Part 4: Create an ActiveX Property
Part 5: How to Start an ActiveX Control
The following tutorial videos illustrate alternative ways of creating Method and Property nodes:
Create an ActiveX Method (Alternative)
Create an ActiveX Property (Alternative)
Visual C++
Part 1 illustrates how to get an APT ActiveX Control running within Visual C++, and Part 2 goes on to show how to program a custom positioning sequence.
MATLAB
For assistance when using MATLAB and ActiveX controls with the Thorlabs APT positioners, click here.
To further assist programmers, a guide to programming the APT software in LabVIEW is also available here.
K-Cube™ NanoTrak® Active Auto-Alignment Application
A K-Cube™ NanoTrak® Active Auto-Alignment Controller can be used in conjunction with a NanoMax Flexure Stage to create a continuous active fiber alignment system. Light from a K-Cube laser source is transmitted through the input fiber to the fiber end attached to the moving world of the stage. An output fiber is fixed to the stationary portion of the stage, and the light transmitted through the second fiber is fed into the power sensor on the NanoTrak controller.
The NanoTrak controller looks for the gradient in the power signal to determine the direction of peak power. This is achieved by scanning the stage in a circular path. As the input fiber is driven in a circle, the optical power coupling between the two fibers will fluctuate. The NanoTrak samples the power at multiple points around the test circle and then directs the piezos to move the stage in the direction of the highest signal. This process is continued until the highest power lies in the center of the circle and the power at every point on the circle is equal.
Continuous active alignment (Tracking Mode) can be used to maintain alignment in a setup, or the gradient search can be halted (Latched Mode) for next step assembly or R&D operations. The setup below can be used for fiber characterization and testing. If the output fiber is replaced with one of our Fiber Optic Couplers, the same setup may be used to maintain high power throughput to an entire fiber-based setup.
Click to Enlarge
Fiber-to-Fiber Auto-Alignment Setup Using a K-Cube NanoTrak® to Control a NanoMax Stage
Suggested Components | ||
---|---|---|
Laser Source | KLS635 K-Cube Laser Source | KLS1550 K-Cube Laser Source |
Fiber Patch Cablesa | Two Fiber Patch Cables Are Required | |
Fiber Alignment Controller | KNA-VIS | KNA-IR |
NanoMax Flexure Stage (Choose One) |
MAX312D(/M) 3-Axis Stage, Open-Loop Piezos MAX311D(/M) 3-Axis Stage, Closed-Loop Piezos MAX381(/M) 3-Axis Stage, Closed-Loop Piezosb |
|
Extension Platform | AMA009(/M) Fixed Platform Bracket | |
Fiber Holder (Two Required) |
HFB001B SMA Fiber Holder for Multi-Axis Stages HFB004W Wide Key FC/PC Fiber Holder for Multi-Axis Stages HFB004N Narrow Key FC/PC Fiber Holder for Multi-Axis Stages HFB005W Wide Key FC/APC Fiber Holder for Multi-Axis Stages HFB005N Narrow Key FC/APC Fiber Holder for Multi-Axis Stages |
Posted Comments: | |
Leonel Stenkhoff
 (posted 2024-10-01 12:40:46.773) Hello Thorlabs,
I'd like to build a setup with two MAX311D/M stages for fiber applications and optimize the position of each in all 3 axes. Would I be able to achievethat with 3 KNA devices connected on a KCH601 HUB? I would like to feed the optical signal only to one of the KNA devices.
Best,
Leonel dnewnham
 (posted 2024-10-07 10:52:43.0) Thank you for your inquiry I will reach out to you directly to discuss your application. Kevin Heylman
 (posted 2024-07-25 09:11:50.97) Please ignore previous comment - Thorlabs has documented this feature in the Kinesis manual for the Nanotrak. It can accept a 0-2V analog electrical single on I/O 1, e.g. from a PM100 power meter. Kevin Heylman
 (posted 2024-07-23 17:45:34.437) Hi Thorlabs, Is it possible to use the Nanotrak with an electrical feedback signal? I have a photonic testing setup with a fiber launch and freespace detection and was planning to use a freespace detector (DET10C). I would prefer to take the output of the DET10 (after converting to voltage in a logarithmic amp) into the Nanotrak instead of needing to align my signal into a fiber. Thanks, Kevin do'neill
 (posted 2024-07-29 08:00:58.0) Thank you for reaching out. It is possible to control the nanotrack with an electrical input using the EXT IN ports. I will reach out to you directly to discuss this and the specific input requirements. Vicky Su
 (posted 2024-03-29 13:07:54.04) What's the rate in unit of step/s mean? what's the length of step. I don't find a tab to change the unit to mm/s spolineni
 (posted 2024-04-05 07:23:05.0) Thank you for reaching out to us. I will personally contact you to provide the assistance needed in this matter. Kok-Wei Bong
 (posted 2023-07-28 13:19:00.443) Can you send me a manual for the nanotrak and the strain gauge reader? fguzman
 (posted 2023-07-31 10:42:14.0) Thanks for your enquiry. You can download the manuals from our website. For example https://www.thorlabs.com/drawings/6827c73412cd56db-B272FF13-9A89-AAD9-B8AF67C89426E359/KNA-IR-KinesisManual.pdf If you have any more questions please contact your local tech team techsupport.uk@thorlabs.com David De Vocht
 (posted 2023-07-27 17:09:55.577) I want to order 2 nanomax stages with closed feedback controller. Can you please confirm if the following is what I need?
2x MAX311D/M NanoMax Stage
2x KNA-IR - K-Cube NanoTrak
1x TPS002
Not sure if the numbers are correct. fguzman
 (posted 2023-07-28 11:36:58.0) Thanks for your enquiry. These items and quantities are correct. For connection please check Figs. 5.8 and 5.9 of the manual. Please note that the KNA-IR is only for 2 axes per each stage, and will only work in open loop. For closed loop you need the BPC303 or the BNT001/IR but this latter is only for two axes. We will contact you directly to check your application. Andrew Barrette
 (posted 2020-09-01 11:22:30.513) This is a great system for aligning our pulsed laser into an optical fiber but, on it's own, the NanoTrak alignment algorithm doesn't work with our pulsed laser. We solved the problem by using a lock-in detector to convert the pulsed signal from the alignment photodiode to a CW signal.
It would be nice if you could build this functionality into the NanoTrak controller. I'm imagining a "Sync" BNC port on the controller that takes a sync signal from the laser. cwright
 (posted 2020-09-03 08:19:44.0) Response from Charles at Thorlabs: Hello Andrew and thank you for your feedback! We understand there is increasing interest in using our alignment devices with pulsed sources and your suggestion is something I will present on our internal engineering forums for future design considerations. klee
 (posted 2009-09-14 12:40:46.0) A response from Ken at Thorlabs to emsicustomer: "apt" stands for "Advanced Positioning Technology". emsicustomer
 (posted 2009-09-14 11:45:22.0) What does "apt" stand for? |
The K-Cube™ NanoTrak® Active Auto-Alignment Controllers optimize the coupling power when aligning fiber and free-space devices. Two options are available: the KNA-VIS controller is shipped with a preinstalled Si detector for 320 nm to 1000 nm, while the KNA-IR controller is shipped with a preinstalled InGaAs detector for 900 nm to 1700 nm.
Power supply options for the K-Cubes are sold separately below.
- Individual ±15 V/5 V Power Supply
- TPS002: For up to Two K-Cubes™ or T-Cubes™ with Mini-DIN Input*
- USB Controller Hubs Provide Power and Communications
- KCH301: For up to Three K-Cubes or T-Cubes
- KCH601: For up to Six K-Cubes or T-Cubes
The TPS002 supplies power for up to two K-Cubes* or T-Cubes. The cubes still require individual computer connection via USB cable.
The KCH301 and KCH601 USB Controller Hubs each consist of two parts: the hub, which can support up to three (KCH301) or six (KCH601) K-Cubes or T-Cubes, and a power supply that plugs into a standard wall outlet. The hub draws a maximum current of 10 A; please verify that the cubes being used do not require a total current of more than 10 A. In addition, the hub provides USB connectivity to any docked K-Cube or T-Cube through a single USB connection.
For more information on the USB Controller Hubs, see the full web presentation.
*The TPS002 can only support one KNA-VIS or KNA-IR controller or one KLD101 driver and should not be used to power any additional units as that may exceed current limitations.