Monday 28 November 2016

Ahead of the 3D Wave – Basler's First ToF Camera Entering Series Production

http://mvrpl.com

After a successful conclusion of the innovation and evaluation phase and extremely positive customer feedback Basler's first 3D camera, the Basler ToF camera, is now entering series production. The Basler ToF camera stands out for its combination of high resolution (VGA) and powerful features at a very attractive price. This outstanding price/performance ratio puts the Basler ToF camera in a unique position on the market and distinguishes it significantly from competitors' cameras. 

The Basler ToF camera operates on the pulsed time-of-flight principle. It is outfitted with eight high-power LEDs working in the NIR range, and generates 2D and 3D data in one shot with a multipart image, comprised of range, intensity and confidence maps. Beyond this, it delivers distance values in a working range from 0 to 13.3 meters, 20 frames per second and connects via a standard GigE interface. The measurement accuracy of the Basler ToF camera is +/-1 cm at a range from 0.5 to 5.8 meters. Powerful features such as HDR, multichannel, trigger and PTP are available to implement applications quickly and easily even in complex systems round off this innovative 3D camera. Jana Bartels, Product Manager at Basler, explains: "This third dimension makes it possible to simplify applications that require depth data, which in turn lets customers reap the full benefits of the technology. Instead of installing multiple 2D cameras for generating 3D data and/or laser triangulation, one single ToF camera is often enough to achieve the desired result – allowing customers to design their applications more efficiently and cut overall system costs. Beyond this, other ToF cameras often come with significantly lower resolution or a higher price." 


The Basler ToF camera is suitable for a variety of applications, including robotics, industrial automation, logistics and medical & life sciences, as well as augmented reality.




To Know More About Basler Camera Distributor, India, Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com


 

 

Contact Details



Address: 4, A-Wing, Bezzola Complex,
Sion Trombay Road, Chembur

400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com
 

Source - baslerweb.com

Saturday 26 November 2016

Tips for cleaning dust from a sensor

http://mvrpl.com

When changing lenses on machine vision cameras, some dust might get into the camera and land on the sensor’s cover glass. If this occurs, this dust will affect image quality. Read More to know how to clean dust from the sensor’s cover glass or other protective glass.
Important: “glassless” imagers, where the cover glass has been removed for UV sensitivity or other reasons SHOULD NOT be cleaned using this process.

1. What you need:

  • Flat LED light source whose light power is adjustable.
  • Lens whose aperture is adjustable; from completely closed to wide open, for example, COSMICAR.
  • C25010 (1inch, 50mm F1.8).
  • Cleaning fluid (see Note 1 below).
  • ESD-safe swab (see Note 2 below).
  • Lint-free gloves.
  • Moisture-free compressed air (optional).
Note 1: For cleaning fluid, isopropyl alcohol is a good starting point however, it may not be sufficient to remove all dust. A mixture of 70% isopropyl alcohol with 30% ether is recommended. Please read and follow safety precautions when mixing these chemicals.
Note 2: To avoid leaving any fibers behind, standard cotton swabs should not be used. Instead, the use of specialized ESD-safe swabs is strongly recommended.

2. How to clean up

The cleaning process (Steps 4-6 below) should be performed in a cleanroom or under a dust-free hood if a cleanroom is not available. Proper clothing should be worn in cleanrooms. At a minimum, lint-free gloves should always be worn during cleaning to avoid introducing additional contaminants.
1) Set up camera with lens and PC to monitor images from the camera.

2) Adjust the lens aperture to almost closed (small aperture); adjust the intensity of the flat LED to produce an image that is not saturated.

3) Check images from the camera to see whether or not some dust exists.
Some tips when trying to identify dust on the cover glass/filter glass are as follows:
  • Is the dust on the sensor glass or light source? Try moving the camera physically. If the dust moves when the camera is moving, the dust is on the light source.
  • Is the dust on the sensor glass or monitor? Try moving the image window on PC. If the dust does *not* follow the image window, the dust is on the monitor.
  • Is the dust on the sensor glass or lens? Try rotating the lens (loosening the lens). If the dust follows the lens rotation, the dust is on the lens.
Example image of dust:
4) If some dust exists on the cover glass, then,
  • Remove the lens
  • If you have a can of moisture-free compressed air, you can try a short burst to loosen the dust particles. Be sure to let the air run for 1-2 seconds away from the camera first, to clean out any contaminants in the nozzle. It is important that the compressed air be completely dry, otherwise it will introduce additional contamination. If you are not sure whether the compressed air being used is truly moisture-free, you should skip this step.
  • Put a little bit of cleaner fluid on the swab.
  • Touch the swab to top-left or top-right corner of the sensor’s cover glass, then wipe straight across to the other edge of the sensor (e.g., from left edge to right edge).
  • Lift the swab and return to a point just below where the first pass started and repeat the process.
  • Continue until the entire cover glass has been cleaned in the same direction.
  • Do not wipe back-and-forth across the sensor as this may unnecessarily drag dust particles across the surface.
5) Attach the lens and go back to Step 3. If some dust still exists, execute Step 4 again with a brand-new swab.
Note: Re-use of swab is not recommended due to the risk of reintroducing foreign object debris (FODs).
The cover glass could become dirtier.

6) Repeat Steps 3 – 5 until the cover glass becomes clean




To Know More About To Know More About Jai Industrial Cameras in Mumbai, India , Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com

 

Contact Details



Address: 4, A-Wing, Bezzola Complex,
Sion Trombay Road, Chembur

400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com

 



Source - jai.com

Tuesday 22 November 2016

Stable USB 3.0 Camera Systems Thanks to Harmonized Accessories – New White Paper

http://mvrpl.com

To set up a stable USB 3.0 system, all the components in the system must be harmonized to work together. Our latest White Paper "USB 3.0 Use Cases and Testing Vision Components" provides concrete use cases to highlight the role played by accessories in a vision system and the test methods Basler uses to ensure the reliability of the individual Vision components. 

For more information about Basler's USB 3.0 accessories, have a look at the Marketing Note "Basler Accessories for Stable USB 3.0 Systems: These Are the Components You Need." Our White Paper "Setting up a Stable USB 3.0 Camera System" details how to set up this kind of system. 


Interested in more information about USB 3.0 and compatible accessories? Then simply contact your local Basler Sales Team.




To Know More About Basler Camera Distributor, India, Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com


 

 

Contact Details



Address: 4, A-Wing, Bezzola Complex,
Sion Trombay Road, Chembur

400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com
 

Source - baslerweb.com

Thursday 17 November 2016

Embedded Vision – What is it and How Can it Help me?


http://mvrpl.com


"Embedded" is a currently-popular buzzword, in the field of image processing as well. Want to learn what "embedded" really involves and why you need it for your vision application? Basler can help you get started : Our website features a definition and technical data on the topic of "embedded vision". Our new video with Steve the Developer shows you how the right tools help make embedded vision much less complicated.

Already looking for products for embedded vision applications? Have a look at our embedded vision portfolio. It offers not just camera modules and evaluation and development kits, but also components and software. Our brochure contains a helpful overview of all our products for embedded vision applications.

The Basler Partner Network can be a valuable help if you're looking for hardware, software or integration partners during the planning phase of your embedded vision project. The network brings together companies with a wide range of different specialties that can help you with the implementation of lean embedded vision systems. Developers of embedded vision solutions can also find assistance at Imaginghub.com, an online community of developers networking and swapping ideas and reference designs.

Interested in learning more about Basler products for embedded vision applications? Our Sales team would be glad to provide advice.



To Know More About Basler Camera Distributor, India, Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com


 

Contact Details



Address: 4, A-Wing, Bezzola Complex,
Sion Trombay Road, Chembur

400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com
 

Source - baslerweb.com

Tuesday 15 November 2016

Cameras in Medicine and the Life Sciences


http://mvrpl.com

Medical devices, labs, operating rooms: all are increasingly outfitted with cameras. The fields of microscopy, ophthalmology, pathology, endoscopy, lab automation and biomedical research have become increasingly prevalent sites for cameras that support doctors and medical experts in their research and diagnostics. 

Our new White Paper "How Machine Vision Cameras Help Medicine – An Examination Focused on Color Fidelity and CCD/CMOS Sensor Technology" explores key camera criteria to highlight the advantages of Machine Vision (MV) cameras in medical applications. Authors Peter Behringer and Denis Dettmer, both product managers at Basler, put a particular focus on how color is calculated and the importance of color fidelity, as well as the advantages and disadvantages of CCD and CMOS sensor technology when used in medical and life science applications.

Are your applications concentrated around optical microscopy? Then our White Paper "How Can I Find the Right Digital Camera for My Microscopy Application?" runs through the key points for successful selection of a camera for this field. 

Comprehensive information about the potential uses of MV cameras can also be found in the "Medical & Life Sciences" section of our website. We take a tour of our virtual Basler Medical Center in the Vision Campus to see how cameras have already become part of daily medical life in many fields. Join us!




To Know More About Machine Vision Camera Distributor, India, Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com

 

Contact Details



Address: 4, A-Wing, Bezzola Complex,
Sion Trombay Road, Chembur

400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com
 

Source - baslerweb.com

Friday 11 November 2016

The Right Solution for Many Applications: Benefits of a Broad CMOS Portfolio

http://mvrpl.com/

Sony, the world's largest producer of CCD sensors, announced last year that it was halting production of that technology. Since then, a growing stream of users has made the switch to cameras with CMOS sensor technology. Basler was quick to recognize the trend toward CMOS and expanded its portfolio to include a broad range of CMOS sensors. This has many benefits for users. 

Cameras with CMOS sensor technology, such as the Basler ace with Sony's IMX and PYTHON sensors from ON Semiconductor, can be used in a variety of applications. Their uses range from applications such as steel inspection and sport analysis to microscopy and automatic license plate recognition. Our latest marketing note "The Right Solution for Many Applications: Benefits of a Broad CMOS portfolio" provides more details on this topic. 

For more information about switching from CCD to CMOS sensors, download our free White Paper "Modern CMOS Cameras as Replacements for CCD Cameras" and visit our info page on Switching from CCD to CMOS cameras. Do you have questions about our CMOS portfolio, or would you like to receive more information? Then please feel free to contact your local Basler Sales team.





To Know More About Basler Ace Camera Distributor, India, Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com

 

Contact Details



Address: 4, A-Wing, Bezzola Complex,
Sion Trombay Road, Chembur

400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com
Source - baslerweb.com

 

Tuesday 8 November 2016

Wide-Angle “FUJINON HF6XA-5M” Machine Vision Lens

  • Fujifilm produces the world's smallest wide-angle 6mm lens for 2/3”, 5-megapixel image sensors
  • Achieving high even resolution performance from the center of the image to the edges with “4D High Resolution”
  • Newly Development
FUJIFILM Corporation (President: Kenji Sukeno) has announced the development of the FUJINON HF6XA-5M wide-angle Lens (hereinafter “HF6XA”). This new product, which has an external diameter of 39 mm and a focal length of 6 mm, is the world's smallest* Machine Vision lens which is used for industrial processes such as product inspection and measurement on production lines. HF6XA is a new lens which is designed for compatibility with 2/3” sensors with a pixel pitch of 3.45µm (five megapixels).

HF6XA is a FUJINON Machine Vision lens designed for compatibility with 2/3” sensors, which has coverage of approximately twice the current product, the FUJINON HF8XA, which offers the widest coverage range. In the frequently used environments of customers, the lens is compatible with the ultra-high resolution of 3.45µm pixel pitch (equivalent to five megapixels when using a 2/3” sensor) under a large portion of the screen. Furthermore, for a wide range of installations and shooting conditions, the lens boasts “4D High Resolution”*4 performance, mitigating resolution degradation that typically occurs when changing a shooting distance or aperture value and maintaining a high level of even image sharpness across the entire image area at the ultra-high resolution of 4.4µm pixel pitch (equivalent to three megapixels when using a 2/3” sensor). Despite being a wide-angle 6mm lens, the lens achieves the world's smallest external diameter of just 39 mm. The lens is ideal for attachment inside compact inspection devices with restricted internal space when wide coverage and consistency is required for reading product codes and serial numbers or for inspecting product shape and appearance.

Fujifilm will be exhibiting the HF6XA at VISION 2016, one of the world's largest Machine Vision-related tradeshows, which will be held in Stuttgart, Germany from November 8 through November 10.

In December 2015, Fujifilm released the HF-XA series of five lenses for use with Machine Vision cameras. HF-XA series achieves both high resolution through 4D High Resolution technology and a compact design with an external diameter of 29.5 mm. Users have also praised the camera for features which include a lens barrel with three holes for fixing the iris and three holes for fixing the focus, providing for convenient shooting as the optimum holes can be selected to match the installation conditions. Fujifilm developed the HF6XA in order to respond to the need for a wide-angle lens with even wider coverage that further improves upon the characteristics of the HF-XA series. With the addition of the HF6XA, Fujifilm's portfolio of lenses for Machine Vision cameras now totals six series with a total of 36 models, which can match a wide range of diverse customer needs.
  • The smallest lens compatible with Machine Vision cameras with a 2/3” image sensor, a pixel pitch of 4.4 µm (three megapixel) or more with the filter attachment in place, and a focal length of 6 mm or less. As per a survey by Fujifilm on November 4, 2016.
  • At the working distance of 50cm.
  • Assuming the same shooting distance.
  • 4The name of FUJINON's proprietary high-resolution technology for maintaining a high level of even image sharpness at the center as well as around the edges (2D) while also mitigating resolution degradation that typically occurs when changing a working distance or aperture value (2D).

1. Main features:


(1) Approximately twice the coverage of the current model

Designed for compatibility with 2/3” sensors with a focal length of 6mm, the lens boasts approximately twice the coverage of the current model, FUJINON HF8XA, which has a focal length of 8mm.

(2) “4D High Resolution” technology unique to FUJINON lenses realizes high-resolution images across the entire image area under a variety of installation conditions

In the frequently used environments of customers, the lens is compatible with the ultra-high resolution of 3.45µm pixel pitch (equivalent to five megapixels when using a 2/3” sensor) under a large portion of the screen. Furthermore, for a wide range of installations and shooting conditions, the lens maintains even high-resolution performance across the entire image area at the ultra-high resolution of 4.4µm pixel pitch (equivalent to three megapixels when using a 2/3” sensor). The lens boasts “4D High Resolution” performance, mitigating resolution degradation that typically occurs when changing a shooting distance or aperture value.

(3) Achieves the world's smallest external diameter of just 39 mm, despite being a wide-angle 6mm lens

Thanks to the world's smallest body measuring just f39mm in external diameter, the HF6XA-5M can easily accommodate an installation environment with space constraints.

(4) Design that facilitates easy attachment

The lens barrel features three holes for fixing the iris and the same for fixing the focus, allowing for the optimum holes to be selected to match installation conditions.

2. Specifications :



Product nameHF6XA-5M
Focal length6mm
Iris range(F no.)F1.9-F16
Angle of view (H x V) *
* Mounted to 2/3” sensor cameras
74.7° x 58.1°
Focus range (from front of the lens) (mm)∞-100
OperationFocusManual
IrisManual
Filter thread (mm)M37.5 x 0.5
MountC-Mount
Sensor size (max.)2/3”
TV distortion (%)-2.88
Diameter (mm)φ39 x 51
Weight (ca.) (g)100
Fixing knobs bundled2

3. Reference Exhibit :


[VISION 2016 venue and booth]
Venue: Messe Stuttgart, Fujifilm booth: 1H15




To Know More About Machine Vision Applications Distributor, India, Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com


Source - fujifilm.com

How High-Speed Cameras Can Be Used to Study Human Motion Sequences

http://mvrpl.com

Motion analyses are most commonly used for sports motor skills. The primary task here is to study, train and optimize motion sequences. This applies to both individual and team sports as well as sports that involve the use of equipment or animals.

The applications are multifaceted. Wit the help of slow motion studies swimmers seek to optimize their butterfly stroke after the turn, horse and rider train to achieve a harmonious riding style and athletes improve their long jump. 

Motion analysis is also used in the development and testing of sports equipment and gear. The high-speed video to the right shows a golf stroke that was captured using the MotionBLITZ EoSens® mini1 high-speed camera. This high-speed recording aimed to optimally adapt the club to the player’s movements.

The club head can reach speeds of up to 200 km/h. To capture all the details, a sufficiently high frame rate must be used. This recording was taken at a frame rate of 2,009 frames per second and a resolution of 528 x 518 pixels. A case study explains how swing analysis can be put to good use when equipping golfers.

Motion analysis is also often used in medicine, particularly in the field of rehabilitation: Doctors and other medical professionals seek to visualize motion or gait disorders in order to develop targeted therapies. High-speed imaging helps them to develop individual training plans, to adjust and optimize aids such as insoles, orthotics and prosthetics and to assess the chances of successful orthopedic surgery.

Finding the Right Camera for Every Motion Analysis

At the heart of every motion laboratory is the high-speed camera. Often, multiple synchronously running cameras are used for three-dimensional analyses. To achieve the best results, there are some important points to be considered when selecting the camera. The decisive parameters are the frame rates, resolution and recording times that will be required. Other important criteria include the handling and ease of integration of the high-speed camera.

High Frame Rates

The required frame rate is determined based on the requirements of the motion to be analyzed. A gait analysis, for example, requires a lower frame rate than the analysis of the forehand stop in tennis. Motions in competitive sports are often especially fast. To analyze these processes in sufficient detail, the high-speed camera used must have a high frame rate of at least 500 pictures per second. 

The high-speed recording on the left shows the golf club head at impact. This is the critical moment for the analysis, the moment of the impact. It determines the ball’s takeoff velocity, direction of flight and spin. Here, the small image region meant the resolution could be reduced to 832 x 172 pixels. This allowed the MotionBLITZ EoSens®mini1 to reach a frame rate of 4,188 frames per second.

High-Precision Resolution

Resolution is crucial for the sharpness and the detail level of the recordings. This also depends on the specific requirements: For example, to achieve the same level of detailed sharpness, high-speed recordings of lower limb prostheses require a higher resolution than the images of prosthetic feet. 

The slow-motion sequence to the left was recording using the MotionBLITZ EoSens® Cube6. With a pixel resolution of 1,280 x 1,024 the camera delivered 150 frames per second. The video shows a jetski driver performing a bootleg turn. 

The MotionBLITZ EoSens® mini2 offers a resolution of 1,696 x 1,710 pixels; thus, it delivers extremely sharp images at maximum recording speeds of 523 frames per second. Here, the resolution is proportional to the recording speed.

The Right Recording Time

Since the entire motion process must be stored in the camera’s memory, the recording time is another important criterion when selecting the camera. For example, there are different requirements depending on whether you are recording a complete obstacle course run or only the start of it. In general, the camera should follow the defined test protocol – and not vice versa; the camera should not affect or even define the test sequence. 

Memory cameras offer recording times between 2 seconds and a maximum of 15 seconds. The MotionBLITZ® Cube records at full resolution and speed for up to 13 seconds. For a longer recording time, the frame rate and/or resolution can be reduced. For example, for a recording time of 30 seconds, a resolution of 100 x 800 pixels and a frame rate of 300 frames per second can be set. If longer recording times are required, Mikrotron offers long-time recording systems that can record from several minutes up to a few hours. 

This underwater video shows a diver during immersion. Having the right position is crucial: The diver should dive perpendicularly into the water and no longer be in the final stages of a turn. The video was taken with the MotionBLITZ EoSens® Cube6 at a frame rate of 718 frames per second and a resolution of 1,280 x 720 pixels. These settings allowed a recording time of 3.25 seconds. The camera was operated by hand.

Compact Handling

When selecting the right camera, the performance characteristics are of foremost importance. However, the design may also be an important criterion: overly large high-speed cameras can be more difficult to handle and reduce the usability, especially when space for the camera is limited. At the same time, the size of the camera is a characteristic that often only becomes apparent in the field: For example, if you want to record each part of a pole vault sequence on a training field, you need a fast and flexible high-speed camera. Confusing cables or unwieldy devices make it difficult to concentrate on the task at hand and should therefore be avoided. Mikrotron offers compact systems with ideal sizes of 65 x 65 x 65 mm to 200 x 200 x 350 mm. 

The high-speed video on the left shows a high jumper at the critical point of take-off. During the jump, the jumper must convert the horizontal velocity into vertical velocity and initiate the turn to cross the bar. The image sequence was created within 1 ¾ seconds and consists of a total of 1,764 images. The images were taken with the MotionBLITZ® Cube1 at a resolution of 640 x 512 pixels. Thanks to the compact size, flexible use in the field is also possible.

The high-speed Cube and eosens TS3 cameras by MIKROTRON can also operate completely selfsufficiently, without an external power supply, and run on battery power for up to one hour. In addition, the cameras have an internal SSD memory, where all data can be stored for final analysis. For example, the eosens TS3 can record without being connected to a computer for up to 13 seconds at full recording resolution and speed.

The software included in the delivery allows for easy use of the cameras. It will win you over with its well-executed and intuitive workflows, easily recognizable features and easy-to-use elements. It also offers the option to synchronize multiple cameras so that they can record at the same time. The software can be easily installed and operated on all computers – special hardware is not required.

A Range of Interfaces

MIKROTRON high-speed cameras are supplied with a C- or F-Mount lens connection. The C-Mount can be adapted to the greatest range of systems, including special optical systems such as endoscopes or telecentric lenses. F-Mount lenses also offer a particularly good imaging quality at focal lengths of over 50 mm. Open interfaces on the cameras allow users to select their own optical systems. For example, camera lenses, zoom lenses and microscopes can be connected without problems. Moreover, all MIKROTRON cameras are equipped with a trigger input. This means you do not have to stand next to the camera to start the recording – it can be easily started with a trigger. In addition, the models have interfaces that facilitate a parallel recording of analogue and digital signals.

An Extensive Portfolio

When choosing the right camera for the high-speed imaging of movements, several parameters play a crucial role. This includes the frame rate, resolution, and recording time, but also the handling, us ility and flexibility of the camera. It is equally important to consider the specific demands of each task. MIKROTRON’s product portfolio offers different options depending on the specific parameters and thus offers a suitable solution for each task.




To Know More About To Know More About Mikrotron High Speed Cameras in Mumbai, India , Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com


 

Contact Details



Address: 4, A-Wing, Bezzola Complex,
Sion Trombay Road, Chembur

400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com
Source - mikrotron.de

Sunday 6 November 2016

5 Fundamental Parameters of an Imaging System

http://mvrpl.com

The following parameters are the most basic concepts of imaging and are important to understand when studying more advanced topics.

Field of View (FOV): The viewable area of the object under inspection. This is the portion of the object that fills the camera’s sensor.

Working Distance (WD): The distance from the front of the lens to the object under inspection.

Resolution: The minimum feature size of the object that can be distinguished by the imaging system. Learn more in Resolution.

Depth of Field (DOF): The maximum object depth that can be maintained entirely in acceptable focus. DOF is also the amount of object movement (in and out of best focus) allowable while maintaining focus. Learn more in Depth of Field and Depth of Focus.

Sensor Size: The size of a camera sensor’s active area, typically specified in the horizontal dimension. This parameter is important in determining the proper lens magnification required to obtain a desired field of view.

PMAG: The Primary Magnification of the lens is defined as the ratio between the sensor size and the FOV. Although sensor size and field of view are fundamental parameters, it is important to realize that PMAG is not.

  Equation








To Know More About To Know More About Edmund Optics Imaging System Dealer in Mumbai, India , Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com


 

 

Contact Details



Address: 4, A-Wing, Bezzola Complex,
Sion Trombay Road, Chembur

400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com