4/8/2022
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Linear Stage Motorized Average ratng: 3,6/5 9388 reviews
  1. Zaber™ Long Travel Motorized Stages are computer-controlled stages capable of translation speeds of up to 280mm/s with 0.5μm resolution. Zaber™ Long Travel Motorized Stages can also be controlled using the Zaber™ Programmable Joystick Controller (sold separately), controlled by computer using an optional accessory data cable, or manually controlled by using the knob at the end of the unit.
  2. A motorized linear stage is essential for a wide range of applications, and provides programmable control of position in one or more axes. There are multiple technologies to choose from when selecting a motorized linear stage.

Motorized Goniometer Rotary Stages; Motorized Linear Stages; Custom Solutions; 3D Imaging; Calibration Standards; Camera adapters for Microscopes; C-Mount Lenses Sort Products By Number of Products to Show; Digital Cameras; Filter Wheels & Wavelength Switchers; Fluorescence Filters; Heating/Cooling Stages; Lightsources; Microscope Eyepieces.


Precision Linear Translational Stages

M-122 Fast High Precision Miniature Linear Positioning Stage with Integrated Optical Linear Encoder


  • Compact High Precision Linear Table
  • Motion Range 25 mm
  • 0.1 µm Optical Linear Encoder for Highest Accuracy & Repeatability
  • Min. Incremental Motion to 0.2 µm
  • Max. Velocity 20 mm/s
  • Cross-Roller Bearings
  • Recirculating Ball Screw Drives Provide High Speeds & Long Lifetimes
Linear Stage Data & Order Info PDF

High-Precision Miniature Linear Positioning Stages with Ballscrew: M-110.2 - M-112.2 Drive


  • Small Precision Linear Traslational Tables, 5 to 25 mm Motion Ranges
  • 5000 h MTBF
  • Very Cost Effective
  • 200 Nanometer Minimum Inc. Motion
  • Hall - Effect Limit & Reference Switches
  • Recirculating Ballscrew for Extended Lifetime
Linear Stage Data & Order Info PDF

Miniature Precision Linear Positioning Stage with Intertia Piezo Motor


  • High Resolution Linear Translational Stage with Closed Loop Motor
  • Motion Range 13 and 26 mm; Self Locking at Rest, no Heat Generation, no Servo Dither
  • Small Dimensions
  • Piezo Inertia Drive, Ideal for Micro- and Nano-Manipulation
  • Integrated Linear Encoder Option for Highest Accuracy with Nanometer Resolution
  • Up to 10 N Force Generation
Linear Stage Data & Order Info

N-565 High-Resolution Precision Translation Table with NEXACT® Piezo Stepping Motor Drive


  • Motion Range 1/2' 1', 2'
  • 0.5 Nanometer Encoder resolution
  • Excellent guiding accuracy
  • Max. velocity 10 mm/sec
Linear Stage Data & Order Info PDF

Miniature Piezo Motor Stage, Stick-Slip Motor Q-522


  • Ultra Compact Linear Motor Stage
  • 6 to 26 mm Travel
  • Nanometer Resolution
  • Self-Locking
  • XY-Combinations Available, Rotary Motor Available
  • Vacuum Option
Linear Stage Data & Order Info

Precision Miniature Linear Positioning Stage with Closed-Loop Ultrasonic Piezo Linear Motors, M-663/U-521


  • Smallest Precision Linear Table with Closed-Loop Linear Motor Drive and Linear Encoder
  • 20 mm Motion Range
  • Velocity up to 400 mm/s
  • Accelerations up to 20 g
  • Resolution to 0.1 Micron
  • Integrated Direct-Metrology Linear Encoder
  • AutoLock Feature
  • XY Combinations Available
  • 20,000 h MTBF
  • Vacuum Versions Available
Linear Stage Data & Order Info PDF

Linear Stage with Ultrasonic Piezo Motor


  • Compact and High Precision Linear Positioning Table, with 25 mm Motion Range
  • Max. Velocity 200 mm/s
  • Ultra-Low Profile
  • Direct Metrology Linear Encoder with 0.01 µm Resolution
  • High Guiding Accuracy with Crossed Roller Bearings
  • Compact XY Version also available
  • Piezo Linear Motor
  • Self Locking at Rest
Back to TopLinear Stage Data & Order Info PDF

Precision Linear Translational Stage; Low-Profile; Piezomotor, Direct Position Metrology


  • Low Profile Linear Positioning Table:
  • Max. Velocity 10 mm/sec
  • Compact XY Combination Possible
  • Up to 8N Force Generation
  • Direct Metrology Linear Encoder, 1 Nanometer Resolution
  • Motion Ranges 26mm
  • Excellent Guiding Accuracy Through Crossed Roller Bearings
  • Non-Magnetic and Vacuum-Compatible Working Principle
  • Self-Locking at Rest
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Linear Stage Data & Order Info

XY Air Bearing Stage with Linear Motor and Linear Encoders


  • XY Linear Positioning Table: Up to 1m Travel Range
  • Nanometer Resolution
  • Integrated Linear Encoders
  • Many Different Designs
  • X and XY Planar
  • Locking Option
  • Compatible with PI Piezo Nanopositioning / Scanning stages

Why Use Air Bearing Stages PDF Catalog

XY Linear Positioning Stage with Linear Encoders, Piezo Motor, Low-Profile: M-686


  • XY Linear Table: 25 x 25 mm Motion Ranges
  • Integrated Closed-Loop Piezomotor Drives Provide High Speed to 100 mm/s
  • Integrated Linear Encoders with 0.1 µm Resolution
  • Compact Design; 27 mm Profile Height, 150 x 150 mm Footprint
  • Large Clear Aperture 78 x 78 mm, 66 x 66 mm in Extreme Position
  • Self-Locking at Rest
  • Compatible with PI Piezo Nanopositioning / Scanning stages

Linear Stage Data & Order Info PDF

Miniature Linear Stage with Piezo


  • Extremely Compact Linear Stage Family
  • X, XY and XYZ Versions
  • Piezo Drive for Nanometer Resolution
  • Precisoin Bearings
Linear Stage Data & Order Info PDF

M-011 Ultra-High-Precision Linear Positioning Stage, Side-Drive with Magnetic-Kinematic Bearings


  • Precision Linear Table with extremely Straight / Flat Motion: ≤ 0.2 Micron
  • Motion Range to 15 mm
  • Compact Side Drive
  • PZT Drive for Scanning and Tracking Applications
  • 0.1 Micro-MeterResolution with Closed-Loop DC Motor
  • 5 Nanometer Resolution with Closed-Loop PZT Drive
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PDF

M-014 Ultra-High-Precision Linear Stage, Side-Drive Stage with Magnetic-Kinematic Bearings


  • Precision Linear Table with extremely Straight / Flat Motion: ≤ 0.3 Micron
  • Motion Range 25 mm
  • Compact Side Drive
  • PZT Drive for Scanning and Tracking Applications
  • 0.1 Micro-MeterResolution with Closed-Loop DC Motor
  • 5 Nanometer Resolution with Closed-Loop PZT Drive
  • 30 mm Ø Clear Aperture
PDF

M-126 Translation Stage with Crossed Roller Bearings


  • Economical High Precision inear Table with 25 mm Motion Range
  • Manual, DC-Servo and Stepper-Motor Drives
  • ActiveDrive™ Option
  • Compatible with Leading Industrial Motion Controllers
  • Crossed Roller Bearings
  • <0.1 Micro-MeterResolution
  • XY and XYZ Combinations
  • Direction-Sensing Origin Switch
  • Non-Contact Limit Switches
Linear Stage Data & Order Info PDF

High-Resolution Precision Linear Stage with Stepper and DC Motor Drives: M-403, M- 404, M-413, M-414


  • Cost-Effective Linear Table Family
  • Modular System with 4 Series: M-403, M-404, M-413, M-414
  • Preloaded Leadscrews or Recirculating Ball Screws
  • Motion Ranges from 25 to 300 mm
  • Stress-Relieved Aluminum Base 80 and 120 mm Width
  • Minimum Incremental Motion to 0.1 Micro-Meter
  • Resolution to 0.017 Micro-Meter
Linear Stage Data & Order Info PDF

M-400 Series High-Precision Linear Stages with Crossed Roller Bearings


  • High-Precision Linear Table Series with 50, 100 & 150 mm Motion Range
  • Stress-Relieved Aluminum Stage Base for Highest Stability
  • Crossed Roller Bearings
  • Manual, DC-Servo and Stepper-Motor Drives, ActiveDrive™ Option
  • Compatible with Leading Industrial Motion Controllers
  • Manual Knob for Convenient Position Adjustment
  • Non-Contact Direction-Sensing Origin Switch
  • Non-Contact Limit Switches
Linear Stage Data & Order Info PDF

M-605 Ultra-Compact, High-Accuracy Linear Stage


  • Ultra-Precision Linear Table with Integrated Linear-Scale Encoders
  • Motion Ranges 25 mm (1') and 50 mm (2')
  • Velocity up to 50 mm/sec.
  • Active Drive™ Motors
  • Compatible with Leading Industrial Motion Controllers
  • Stress-Relieved Aluminum Stage Base for Highest Stability
  • Zero-Backlash Recirculating Ballscrews
  • Non-Contact, Direction-Sensing Origin Switch
  • Non-Contact Limit Switches
  • Load Capacity 20 kg
  • >20,000 Hours MTBF
Linear Stage Data & Order Info PDF

M-505 Low-Profile Linear Stages with Ballscrew Drives


  • Precision Linear Table with Zero-Backlash Recirculating Ballscrews
  • Motion Ranges to 150 mm (6 inches)
  • Velocity up to 50 mm/sec.
  • ActiveDrive™ Motors
  • Compatible with Leading Industrial Motion Controllers
  • Stress-Relieved Aluminum Stage Base for Highest Stability
  • Non-Contact Direction-Sensing Origin Switch
  • Non-Contact Limit Switches
  • Load Capacity 100 kg
  • > 20,000 Hours MTBF
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Linear Stage Data & Order Info PDF

M-511 · M-521 · M-531 Low-Profile, High-Load Linear Stages with Ballscrew Drives


  • High-Load Linear Tables with Zero-Backlash Recirculating Ballscrews
  • Motion Ranges to 306 mm (12')
  • Velocity up to 125 mm/sec.
  • ActiveDrive™ Motors
  • Compatible with Leading Industrial Motion Controllers
  • Linear-Scale Encoders for Highest Accuracy
  • Stress-Relieved Aluminum Stage Base for Highest Stability
  • Non-Contacting Origin and Limit Switches
  • PIIntelliStage™ Version with Integrated Controller
  • Load Capacity 100 kg
  • >20000 Hours MTBF
Linear Stage Data & Order Info PDF

V-551 Long-Travel, High-Speed Linear Motor Staage


  • 3-Phase Linear Motor
  • 1 Nanometer Linear Encoder Resolution
  • 50m - 230mm Motion Range
  • Velocities to 250 mm/sec
  • Excellent Velocity Control
  • Absolute Encoder
  • Reliable Execution of Minimal Increments
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Linear Stage Data & Order Info PDF
Voice Coil Scanning Stage

V-52x Long-Travel, High-Dynamics Scanning Tables with Voice Coil Linear Motors


  • Fast Scanning and Positioning
  • Scanning Frequency 10s of Hz
  • Motion Ranges of 20 mm and 6 mm
  • Velocity up to 270 mm/s
  • 0.1 Micro-MeterLinear Encoder
  • Available PCI-Card Controller with On-Board Amplifiers
Linear Stage Data & Order Info PDF

This article will help you understand the basics of motorized linear stage design and specifications. Also, it gives advice on how to select the best stage for your application.

If you are new to the world of linear translation stages, it is important to understand manual linear stages in general before tackling motorized stages. Here is an example of an excellent beginners’ guide to manual linear stages. There are also videos on the website of a motion control technology company, Aerotech, on translation stage basics worth watching as a refresher or reminder.

From here, no doubt about it, you can’t wish it away, motorized linear stages are more complex especially In some of today's high precision environments. Before selecting a motorized linear stage it is imperative to have a clear understanding of the system’s characteristic motion attributes and associated performance specifications. Overlooking a critical motion attribute, such as drift, minimal incremental motion (not resolution!) and repeatability will result in underperforming results, wasted time and disappointment. Then there is velocity, acceleration, torque and inertia.

What is a motorized linear translation stage?

First, this short YouTube video is worth watching that illustrate the multi-axis motion of motorized linear stages.

There’s something about motion, especially on its own that can provide hours of entertainment for some of us…a motorized linear stage is simply a translation stage controlled by a motor to provide the desired point to point translation in either a single or multi-axis coordinate system.

Now let’s get down and dirty in the details…

Why Motorized stages are a step up in complexity from Manual Stages

Replace a human with a machine, repeat a task hundreds of thousands of times in as short a time as possible, error free (mostly), add electronic controllers with programming to make decisions and command action, and move an object with a motor precisely to a pre-determined point and you have a complex system, and as shown in thea above figure, that’s a single axis system. Now add a multi-axis coordinate system such as an XY linear system as shown in the video above. You get the point.

Motion is an easy concept. You jump in your car, start the engine, put the transmission in drive and push on the gas pedal (starting position). The period from 0 mph to cruising speed is acceleration. When you’re driving the speed limit, that is velocity. When you slow to a stop, that is deceleration and you’ve reached your destination (target position).

Motion Parameters required in any motorized motion control system

There are inherent parameters of a motorized motion control system not found in a manual translation stage system that need special attention and it involves motion, moving from point A to point B from a stopped position (zero velocity), starting the motion (acceleration), maintaining the motion (velocity), and ending the motion (deceleration and stop). Then, is it in the correct position? What is the smallest position incremental motion? How much load can be moved accurately without stressing the system mechanicals?

To address these questions, there is system terminology to be aware of in describing the performance of the motion:

» Position Stability: Is the ability of the stage to maintain the set position over a time interval; it is the sum of drift and vibration specifications.

» Drift: The basic definition of drift is “a continuous slow movement from one place to another.” In a motorized linear stage drift is typically caused by temperature fluctuations or lubricants used in the construction. Additional errors related to drift but caused by other outside forces are Hysteresis and Backlash.

» Resolution: In motorized translation stage systems resolution is typically referred to be the minimum step the system can be set to move based upon the encoder. This doesn’t mean the system can actually move or repeatably move this distance. It is better to look for the Minimum Incremental Motion specification and if this specification isn’t available than I would ask the supplier to clarify.

» Minimal Incremental Motion Is the smallest increment the system can move reliable. This s pecification takes into account not only the encoder which is usually the resolution specification but the bearings, actuators, motors, and control system; i.e. the complete motion system. Sounds Complicated? Will it is and the Thesis by Gaurav Parmar title Performance Specifications of Nanopositioning Systems: Accuracy, Precision, and Resolution will give more detail knowledge to understanding how this specification can be measured.

» Position Accuracy: This can be specified either as unidirectional positional accuracy or bidirectional positional accuracy. The basic term means how close to the target position the stage can move when commanded. This specification can be different if you are moving in only one direction or if you are trying to move in either direction of a standard motorized linear stage. The bidirectional positional accuracy will always be larger than the unidirectional positional accuracy.

» Repeatability: To calculate the repeatability of a motorized linear stage the test is performed in one direction multiple times. The stage is sent to the same position and the deviation from the actual position is measured. This is different but related to positional accuracy but it is only at a single point instead of multiple points.

Like any high technology product there is a lot of gamesmanship that goes on in specifications. If there is a specification critical to your application and the supplier product specification is close to your tolerance than you may want to dig a little deeper to understand how the specification was created and tested. If you want to learn even more or if you are building your own stage there is an in-depth overview of ISO and ASME standards for motion systems by Newport title Motion Basics Terminology & Standards.

Translation

So, exactly what are the components of a motorized motion control system and what do they do?

If this looks complicated, well, it may be at first blush, really though, it isn’t that bad when you gain an understanding of each component and what it does. National Instruments has a good tutorial titled Fundamentals of Motion Control. It goes into great detail on motorized motion control system components and software. The following descriptions of each component are basic and are intended to be just enough to whet your appetite.

What to know even more about the math, physics and science behind motorized motion systems? The Institute of Control Engineering National Chiao Tung University paper on Introduction to Servo System Design can give you a more in-depth understanding. Especially useful if you are trying to design your own system.

Motion Controller; is typically a DSP (digital signal processor) based electronic device acting on its own that converts the software commanded set-points and system parameters into a control signal for the motor driver/amplifier. It also takes feedback signals typically from a servo motor, and/or from the mechanical stage for position awareness and corrects for any errors in intended motion. Why can’t the computer do this you might be asking? For good reason in fact; you would not want your motion system to be interrupted or to stop because your computer system is overloaded with its own tasks such as running antivirus software or the operating system crashes.

Motor Amplifiers and Drives; another electronic device which takes the drive signal and converts it into a motor drive signal which is typically higher voltage/current required to rotate the motor to move the stage carrier. There are several different types of motors to drive linear stages varying in velocity and torque (highly dependent on the load), so you might guess then that motor drives come in many different varieties and are matched to the specific type of motor they drive.

Motors

As you would guess, the choice of motor is highly dependent on the application. The two main drivers in motorized linear stage applications are stepper motors and servo motors. Another option is a piezo motor but this is for nanopositioning; you can learn more about How to Select A Nanopositioning Piezo Stage for Your Application. Then, there are brushed DC servo motors and brushless AC servo motors. They are available in a variety of frame sizes offering different torque-speed profiles. Google “servo motor selection” guide and you’ll see a list of guides available to help you select a stepper and servo motor for your application. Variables include operating environment, motor load dependent on the stage type and carrier load, positional accuracy and resolution, positioning distance and time leading to the type of motor and its associated torque and inertia.

Motorized z stage

What is the difference between servo motors and stepper motors?

Stage

Even though stepper motors and servo motors perform the same basic function, i.e., convert a drive signal into rotation of the motor shaft, there are important differences from how they are built to how they work, to cost, to motor output torque and how motor shaft rotational location is controlled (and known).

Stepper Motor; lower cost option. Stepper motors operate just as it sounds, they respond with a step in shaft rotation to a drive signal. These motors are characterized by high torque at lower speeds and lower torque at higher speeds.

Servo Motor; higher cost option. Servo motors operate in a continuous motion over a limited rotational range, typically 180° with constant torque (mostly). These motors always include a feedback device such as an encoder and require a more sophisticated motion controller and drive amplifier for closed loop operation.

Now for the “I know where you are” part. Stepping motors can run open-loop due to their physical make-up (number of poles), servo motors cannot and need a means of providing information on where the motor shaft is in its rotation. These are known as feedback devices and “close the loop” providing information to the motion controller in the form of an electrical signal. When you watch a motorized stage, especially a multi-axis system it’s amazing to think that the controller knows throughout any range of motion where each axis is in its space. There is a whole technology space in motion control called Feedback devices.

Stage

Feedback Devices, encoders, potentiometers and tachometers

There are a number of feedback devices used on servo motors in motorized linear stage systems, the most common being the quadrature encoder, I know, big word, which gives position feedback relative to a starting point, “home” in motion control terminology. There are absolute encoders as well which don’t require a reference but provide a feedback signal on output shaft position. Another feedback device that’s been around pre-digital era, is the tried and true potentiometer which develops an analog voltage proportional to motor position. And, there are tachometers, you’ve seen them in the dashboard of your car, they provide a feedback signal for the motor shaft’s rotational speed.

And if this isn’t enough, there are hard-wired switches to tell the controller when the stage carrier has come home (or is told to go home), and to tell when it has reached its travel limits. This is called Motion I/O.

Motorized Translation Stage

Motion I/O, limit and home switches

These are simple devices mounted on the stage at the characteristic locations along the stage’s carrier travel path and somewhat arbitrary left up to the system designer as to their location. They work by interrupting an electrical signal when open and allow an electrical connection when closed. The motion controller uses this signal to either sense when the carrier is home thus enabling a motion command or to sense a maximum travel limit enabling a stop travel command.

Linear Xy Stage

So Where Do you Begin in Finding a Motorized Linear Stage?

Motorized Linear Stage Low Cost

First you must understand your application or system requirements including travel range, minimal incremental motion, and any other key specifications of the system. You must also know your load and space limitations. Now the easy part we have created an index that allows you to compare all the manufacturers and their data sheets in one location for motorized linear stages or multi-axis stages like XY motorized linear stages. See us missing a data sheet or supplier? Follow the link below or contact us.