How to eliminate glare in machine vision systems

Machine vision – indeed human vision too – relies heavily on contrast. The feature(s) being identified need to stand out against any competing candidate features. Otherwise confusion is present. Which means vision either doesn’t work, or isn’t efficient.

While it’s easy to achieve good contrast in certain machine vision applications, sometimes we’re presented with the special challenges of glare. The target object is the same, in the two images below. If the goal is to read the alphanumeric information, which image would you rather pass to your machine vision software?

Courtesy:
Advanced Illumination
Courtesy: Advanced Illumination

Techniques to eliminate glare

Glare can arise due to highly reflective surfaces, especially in combination with the direction of the light source relative to the lens and sensor capturing the image. Thankfully there are a number of techniques to eliminate or substantially reduce glare.

Off-axis lighting

For the 1-D bar code reading application illustrated below, moving the light to an off-axis position creates dark field orientation, eliminating the glare. Identical materials but different geometry does the trick!

a. Lighting diagram; b. High-angle light reflects from specular surface; c. Off-axis light improves the image; Courtesy Advanced Illumination

Diverse lights and geometries

Consider another example. In this case we have a titration tray, with multiple wells. Each well has a laser-etched 2-D code.

Analysis/discussion below. Courtesy Advanced Illumination
  • (a) the titration tray at low resolution, marked up with red outline around 6 wells isolated in high resolution images (b) – (f)
  • (b) High-angle ring light
  • (c) Coaxial light
  • (d) Dark field ring light
  • (e) Diffuse dome light
  • (f) Flat diffuse light

In this scenario, both (d) the dark field ring light, and (f) the flat diffuse light, are far superior to the other options, and the flat diffuse light is the winner.

Flat diffuse light function diagram – light is directed downward, and more off-axis than a coaxial illuminator, yet less off-axis contribution than a dome light. Courtesy Advanced Illumination

NOTE: The example above is NOT meant to suggest that flat diffuse light is always the winner. It’s important to understand the characteristics of the surface you are inspecting, and each candidate type of lighting, and the geometric options. And to test!

Guideline

The following diagram is a general guideline, based upon the two most prevalent surface characteristics: (1) Surface flatness and texture, and (2) Surface reflectivity profile

Guide to likely “best approach” based on prevalent surface characteristics – Courtesy Advanced Illumination

Send your samples

Lighting is a complex topic, so we’re happy to help. If you are uncertain which light type to choose and how to configure, we may be able to do some testing for you. Contact us to arrange sending samples to test in our lab, and we can recommend sensor, lensing, lighting, and configuration options.

For comprehensive coverage on glare reduction – and more – download A Practical Guide to Machine Vision lighting from our knowledge base.

1st Vision’s sales engineers have over 100 years of combined experience to assist in your camera and components selection.  With a large portfolio of cameraslensescablesNIC cards and industrial computers, we can provide a full vision solution!

About you: We want to hear from you!  We’ve built our brand on our know-how and like to educate the marketplace on imaging technology topics…  What would you like to hear about?… Drop a line to info@1stvision.com with what topics you’d like to know more about.

#glare

#contrast

#machinevisionlighting

#diffuser

#polariser

KOWA Innovations: New LF Large Format ruggedized lenses

Kowa LF high-resolution large-format machine vision lenses are engineered for rigorous industrial imaging. With a 46.0mm image circle, these optics are optimized for 4K line scan cameras and large-sensor area scan systems.

Rugged large format lenses – Courtesy Kowa

Two mount options

F-mount or TFL-II mount

  • Large image circle options up to approximately 43.3mm to 46mm depending on model.
  • For sensors with pixel sizes from 7.5µm on LF line scan models and 3.1µm on CLS color line scan model.
  • Very low distortion for web, print, packaging and materials inspection
  • Manual focus and iris control.

Noteworthy features

Anti-Rattle F-Mount: Ensures the lens stays locked in place to eliminate image shake in vibration-prone installations.

Enhanced Thumb-Screw Retention: Specialized slide mechanisms prevent thumb screws from working loose, yet allow swift lens removal or changeout as needed.

4K-Ready Optics, Multiple Focal Lengths: Designed for 4K line scan and high-resolution imaging, the LF Series is available in 28 mm, 35 mm, and 50 mm focal lengths for a range of applications.

Industrial reliability: The new ruggedized LF prototypes set a new standard for stability and service life, delivering secure imaging performance under the most demanding circumstances.

Lens selection

If you are a seasoned imaging professional, you may know exactly how to choose the optimal lens, from the large range of available lenses.

Or you may prefer a guided approach.

Contact us

Or a hybrid approach, using your own review of key considerations in machine vision lens selection, together with our guidance.

1st Vision’s sales engineers have over 100 years of combined experience to assist in your camera and components selection.  With a large portfolio of cameraslensescablesNIC cards and industrial computers, we can provide a full vision solution!

About you: We want to hear from you!  We’ve built our brand on our know-how and like to educate the marketplace on imaging technology topics…  What would you like to hear about?… Drop a line to info@1stvision.com with what topics you’d like to know more about.

#Largeformat

#F-mount

#TFL-II

What is TDI? Time Delay Integration?

TDI is based on the concept of accumulating multiple exposures of the same (moving) object, effectively increasing the integration time available to collect incident light. The object motion must be synchronized with the exposures to ensure a crisp image.

Line scan sensors are available for diverse applications – Courtesy Teledyne DALSA

Context

If an object were stationary, and one wasn’t in a hurry, one could just do a longer exposure in order to achieve an ideally saturated image. But the object in question is in fact moving. And it’s a line scan application. Each line exposure is extremely fast, so there’s not much opportunity to accumulate sufficient light into the sensor.

Candidate solutions

Use “faster” sensor that is more sensitive in low light situations? Conceptually plausible but not always available relative to speed of motion and available light.

Introduce artificial light? Usually one already adds concentrated light with line scan, but for challenging applications it may not be sufficient… relative to the speeds one hopes to attain.

Use Time Delay Integration (TDI) to build up final image as composite from multiple exposures carefully synchronized to object’s motion. Key concept: the object is moving anyway, so take advantage of that movement as an opportunity to get multiple “looks” at the same slice of the object. A variation on “when given lemons make lemonade”.

See the video below for an illustrative simulation. The conceptual application is mail processing, where the goal is to read whether a letter is stamped, with which denomination of postage, all while the letter is moving at continuous speed along a conveyor belt, lit only by ambient or low intensity light.

Courtesy Teledyne DALSA

The memory summing of the successive exposures builds the readout image.

Benefits

Speed: You can increase the speed of the target object or inspection web, improving overall throughput. This alone may be a huge competitive advantage.

Lower lighting costs: Get by with just one instead of two lights, and perhaps just a modest light rather than a high-intensity one.

Signal to noise ratio: SNR is improved.  Since multiple exposures are summed, useful image signal increases while random noise is reduced. This gives cleaner images and better defect detection.

Tradeoffs

Clearly sufficient synchronization must be achieved for TDI to work effectively. Thankfully the synchronization doesn’t have to be perfect – a TDI device can comfortably tolerate a 2-4% velocity mismatch between inspection web and imager. This is not difficult to achieve using a web-mounted encoder to supply a sync signal to the camera, even with webs that change speed. There are thousands of successful implementations.


For a wide range of line scan products, the the Teledyne DALSA Linea families. For TDI in particular, drill in on the Linea HS and Linea HS2 products.

Applications

Typical applications include, but are not limited to:

  • Semiconductor wafer inspection
  • High-density interconnect inspection
  • Quality control on flat panel displays
  • Some life science applications

In a nutshell, if it’s “light starved” and line scan, TDI can be the answer.

1st Vision’s sales engineers have over 100 years of combined experience to assist in your camera and components selection.  With a large portfolio of cameraslensescablesNIC cards and industrial computers, we can provide a full vision solution!

About you: We want to hear from you!  We’ve built our brand on our know-how and like to educate the marketplace on imaging technology topics…  What would you like to hear about?… Drop a line to info@1stvision.com with what topics you’d like to know more about.

#Timedelayintegration

#TDI

#Linescan

Computar LensConnect Motorized Telecentric Lenses

Optical metrology is an application area within machine vision focused on precise measurement using controlled optics, lighting, cameras, and calibration. Telecentric lenses are designed to maintain constant magnification over a defined depth range, reducing perspective error.

Computar LensConnect telecentric motorized lenses are the first in the industry to combine these features. That brings precision telecentric optics with intelligent remote focus control for high-accuracy industrial imaging and measurement applications.

LensConnect USB powered motorized telecentric lenses – Courtesy Computar

Example application: PCB Inspection

Consider the following application:

Courtesy Computar

The application needs to BOTH measure the height of all three indicated components AND to OCR read/verify/record the markings on the components. That requires both telecentricity and focus control.

Courtesy Computar

Motorized automated focus is key differentiator

In the short 35 second video below, one can see how lens controls are parameterized to automatically optimize focus, adapting to variable conditions.

Four different magnification options

There are 4 different lens models in the series, with magnifications of:

  • 0.25 <—— just click for full specs
  • 0.5 <—— just click for full specs
  • 1.0 <—— just click for full specs
  • 2.0 <—— just click for full specs
Contact us

Key benefits include:

  • Supports high-resolution machine vision cameras
  • Reduces downtime and manual recalibration
  • Precise stepper motor focus positioning
  • Ideal for metrology, semiconductor, and electronics inspection
  • Simplifies remote setup and multi-camera calibration systems

1stVision is pleased to have these LensConnect motorized telecentric lenses in our portfolio, along with all the other Computar lenses. Call us at 978-474-0044.

1st Vision’s sales engineers have over 100 years of combined experience to assist in your camera and components selection.  With a large portfolio of cameraslensescablesNIC cards and industrial computers, we can provide a full vision solution!

About you: We want to hear from you!  We’ve built our brand on our know-how and like to educate the marketplace on imaging technology topics…  What would you like to hear about?… Drop a line to info@1stvision.com with what topics you’d like to know more about.

#Computar

#LensConnect

#telecentric