製品がカートに追加されました
TECHSPEC® components are designed, specified, or manufactured by Edmund Optics. TECHSPEC® ブランドの製品は、エドモンド・オプティクスによってデザイン、規格化、あるいは製造されます。もっと詳しく

TS 耐久化 ブルー M12 マウントレンズ 16mm F2.5

16mm FL Rugged Blue Series M12 Lens

16mm FL Rugged Blue Series M12 Lens

16mm FL Rugged Blue Series M12 Lens
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商品コード #36-376 お問い合わせ
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Quantity Selector - Use the plus and minus buttons to adjust the quantity. +
¥14,450
数量 1-49
¥14,450
数量 50+
¥10,850
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アイリスオプション:
Fixed
全長 (mm):
22.50
水平方向実視野 @ 1/2型センサー:
58.0mm - 22.5°
最大直径 (mm):
16
水平方向実視野 @ 1/3型センサー:
43.5mm - 17.0°
最大イメージサークル (mm):
9.00
開口数 NA, 物体側:
0.026544
素子の枚数 (群数):
6 (6)
水平方向実視野 @ 1/1.8型センサー:
64.9mm - 25.3°
波長範囲 (nm):
400 - 700
水平方向実視野 @ 1/2.5型センサー:
52.5mm - 20.5°
タイプ:
Fixed Focal Length Lens
焦点距離 FL (mm):
16.00
光学倍率 PMAG:
0.1X
許容最大センサーフォーマット:
1/1.8"
作動距離 (mm):
150 - ∞
マウント:
M12 x 0.5 (S-Mount)
絞り範囲 (Fナンバー):
f/2.5
バックフォーカス BFL (mm):
10.79 - 10.05
コーティングスペック:
λ/4 MgF2 @ 588nm
入射瞳位置 (mm):
7.5143
水平方向実視野 @ 1/4型センサー:
32.6mm - 12.8°
物空間側主平面 (mm):
7.21
像空間側主平面 (mm):
-7.04
実視野 @ 最大センサーフォーマット:
Horizontal: 64.9mm - 25.3°
Vertical: 48.7mm - 19.1°
Diagonal: 81.2mm - 31.4°
最大ディストーション (%):
0.039 @ Full Field
IR カットフィルター:
No
射出瞳位置 (mm):
-6.7445
レンズ波長域:
VIS
撮像レンズタイプ:
High Performance Lens, Ruggedized to Withstand 50g of Shock

法規制対応状況

RoHS 2011/65:
適合証明書:

製品群全体の紹介

  • 最大 ½型までに対応したSマウントレンズ
  • 5 メガピクセル (1.4µmのピクセルサイズ) までに対応
  • 個々の構成レンズを所定の位置に接着固定した50G対応耐久化レンズ
  • 2mm から 25mm までの焦点距離
  • 耐久化していないデザインもラインナップ

TECHSPEC® 耐久化ブルーシリーズ M12マウントレンズは、衝撃や振動時にレンズが損傷するのを防ぎ、画素シフト低減と光学的ポインティング安定性の維持を実現する、安定化目的の耐久化が行われています。複数枚の精密ガラスレンズ素子で構成された本製品は、各レンズ素子が小型のアルミ鏡筒内に接着固定されています。この接着固定により、外部要因により発生する画素シフトを最小限に抑えます。強い振動や衝撃の後でも物体のイメージマッピングが維持され、画面中心にマップされた被写体の中心部は、同じ位置で常にマップされます。TECHSPEC 耐久化ブルーシリーズ M12マウントレンズは、計測やゲージ、3Dビジョンやロボット工学、センシングや自動運転技術、更にはオブジェクトトラッキングといったキャリブレーションのとれたイメージングアプリケーションに最適です。このレンズは、F2.5 から F8.0 までの固定絞りオプションをラインナップします。

エドモンド・オプティクスには、高解像力が得られるようにデザインされたM12 Sマウントレンズの複数の製品群があります。この高性能レンズは、メタルハウジング内に複数枚のガラス製レンズ素子を実装し、各製品群が顧客のアプリケーションニーズに合致するよう仕様を最適化しています。

タイトル 比較する商品コード  価格 (税別) カートに入れる
M12用ロックナット 10個入り #16-788 ¥13,850   見積依頼する
  • 5-7営業日
    ×
TS M12レンズ用ロックナット #64-102 ¥1,950   見積依頼する
  • 在庫あり
    ×
TS M12レンズ用ボードホルダー #66-382 ¥1,550   見積依頼する
  • 5-7営業日
    ×
TS M12レンズ用Cマウント変換アダプター (Oリング付き) #59-241 ¥5,500   見積依頼する
  • 在庫あり
    ×
TS M12レンズ用Cマウント変換アダプター (Oリングなし) #53-675 ¥3,850   見積依頼する
  • 在庫あり
    ×
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Distortion Plot
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Distortion Plot
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Relative Illumination Plot
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Relative Illumination Plot
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Working Distance versus Field of View Plot
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Working Distance versus Field of View Plot
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Modulated Transfer Function (MTF) Plot, 150mm Working Distance, f2.5
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Modulated Transfer Function (MTF) Plot, 150mm Working Distance, f2.5
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Depth of Field Plot, 150mm Working Distance, f2.5
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Depth of Field Plot, 150mm Working Distance, f2.5
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Modulated Transfer Function (MTF) Plot, 400mm Working Distance, f2.5
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Modulated Transfer Function (MTF) Plot, 400mm Working Distance, f2.5
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Depth of Field Plot, 400mm Working Distance, f2.5
#36-376, 16mm FL f/2.5 Rugged Blue Series M12 Lens, Depth of Field Plot, 400mm Working Distance, f2.5
Filter

反射防止コーティング

反射防止膜は、透過率を増やす、コントラストを高める、またゴースト像の発生を取り除くことによって、光学素子の効率を大幅に改善させます。

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オプティカルコーティング入門

Optical coatings are used to influence the transmission, reflection, or polarization properties of an optical component.

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Wavelength and f#

This demonstration exemplifies why wavelength and f/# can drastically affect the performance of imaging systems and should not be overlooked.

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Working Distance and Focal Length Basics

Working distance and focal length are two of the most fundamental parameters of any imaging system. Learn more in this hands-on video demo.

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焦点距離と実視野の理解

固定焦点レンズにおける焦点距離について。及び焦点距離の決定方法。レンズの焦点距離の計算例や固定倍率のレンズを用いた実視野の計算式について。

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レンズ性能曲線

Are you trying to measure the performance of your lens? Although this can be a difficult task, there are curves that can help. Read more at Edmund Optics.

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変調伝達関数入門

Want to know more about the Modular Transfer Function? Learn about the components, understanding, importance, and characterization of MTF at Edmund Optics.

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LIGHT TALK - EPISODE 5: Ruggedized Imaging Lenses with Cory Boone and Ben Weaver

The expansion of automation has made the ruggedization of imaging lenses from shocks, vibrations, and temperature swings more important than ever before.

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Ruggedized Imaging Systems – TRENDING IN OPTICS: EPISODE 9

A new generation of harsh environment lenses has been developed to support the spread of automation and protect their imaging systems.

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耐久化したイメージングレンズ

過酷な環境内で用いられるイメージングレンズは、標準的レンズに求められる以上の特別な要件が求められます。FAやロボット工学、また工業用検査に用いられるレンズは、振動や衝撃、また温度変化やコンタミに晒されることがしばしあります。

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イメージングレンズの高耐久化

Have an application in a demanding environment? Learn about the different types of ruggedization: industrial, ingress protection, and stability at Edmund Optics.

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Ruggedized Machine Vision Lenses for Harsh Environments

Edmund Optics imaging and machine vision lenses are robustly designed for use in harsh environments and are available in a number of options for the most demanding applications.

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耐久化イメージングレンズ

Edmund Optics® manufactures several different types of ruggedized imaging lens assemblies.

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Ruggedization of Machine Vision Lenses

Harsh Environments Call For Athermalized Imaging Lenses

Where can I find more information on the various types of Ruggedization?

I’m currently using a different Edmund Optics® imaging lens. Can you ruggedize my lens?

Are Zemax prescription files available for your standard ruggedized lenses?

Can ruggedization make lenses waterproof?

Vibration Rating

Top Trends of 2022 – TRENDING IN OPTICS: EPISODE 8

Happy holidays from Edmund Optics! Learn about the top trends in the photonics industry covered in our Trending in Optics Series in 2022.

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光学収差の比較

Trying to understand optical aberrations? Check out how to identify aberrations and view examples at Edmund Optics.

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レンズデザインによるMTFの収差バランス

Do you have multiple projects that involve the use of a lens? Find out about different lenses that can be adapted for multiple purposes at Edmund Optics.

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Basic Lens Selection

マシンビジョンレンズの種類

Fixed focal length, zoom, and macro lenses are all variable magnification lenses. Learn more at Edmund Optics.

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レンズ用スペーサーやシム、エクステンダーレンズ

Want to learn how to extend a lens beyond its limits in an application? Learn more about spacers, shims, and focal length extenders at Edmund Optics.

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MTF曲線とレンズ性能

Explore the differences in the performance of imaging lenses by directly comparing the associated modulation transfer function (MTF) curves.

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レンズの構造

Become familiarized with the key components of an imaging lens assembly and how they function.

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変調伝達関数 (MTF)

MTF curves allow you to compare the performance of multiple lenses at the same time. To find out how MTF curves are beneficial, read more at Edmund Optics.

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基本的なレンズ選定

To decide what imaging lens is right for a system, it is important to know the parameters of the imaging system used. Learn more at Edmund Optics.

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固定倍率レンズの選定方法

Fixed magnification lenses typically function properly at a single working distance and are specified by their magnification. Learn more at Edmund Optics.

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高度なレンズ選定

The modulation transfer function of a lens varies depending on working distance, sensor size, f/#, and wavelength. Learn more at Edmund Optics.

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Edmund Optics Imaging Lab 3.8: Sneak Peek at Future Modules

Learn how to specify imaging system components.

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Best Practice #1 Bigger is Better

Join Greg Hollows, Director of the Imaging Business Unit and EO's Imaging Expert, as he reviews some Best Practice to consider when designing an imaging system.

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Best Practice #2 Don't Believe Your Eyes

Join Greg Hollows, Director of the Imaging Business Unit and EO's Imaging Expert, as he reviews some Best Practice to consider when designing an imaging system.

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Best Practice #3 Don't Get Too Close

Join Greg Hollows, Director of the Imaging Business Unit and EO's Imaging Expert, as he reviews some Best Practice to consider when designing an imaging system.

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Best Practice #7 No Universal Solution

Join Greg Hollows, Director of the Imaging Business Unit and EO's Imaging Expert, as he reviews some best practices to consider when designing an imaging system.

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Best Practice #9 Be A Control Freak

Join Greg Hollows, Director of the Imaging Business Unit and EO's Imaging Expert, as he reviews some best practices to consider when designing an imaging system.

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Best Practice #10 Be The Squeaky Wheel

Join Greg Hollows, Director of the Imaging Business Unit and EO's Imaging Expert, as he reviews some best practices to consider when designing an imaging system.

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Best Practice #11 Make A List

Join Greg Hollows, Director of the Imaging Business Unit and EO’s Imaging Expert, as he reviews some best practices to consider when designing an imaging system.

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The Impact of Distortion

Nick Sischka explains distortion in this hands-on demonstration from the Edmund Optics 2021 Imaging Innovation Summit.

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Calculating Lens Resolution with Precision

Deciphering Lens Specifications and Choosing the Proper Lens

A Closer Look at Resolution Testing

I’ve been using the thin lens approximation to calculate the minimum object distance and field of view of an imaging lens and camera I have, is there a simple formula for estimating these parameters?

How do I know what lens mount is best to use for my imaging or vision system?

What are M12 (S-Mount) lenses?

M12 or S-Mount lenses are a type of compact imaging lens used in space-constrained applications.

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What is an MVO Double Gauss imaging lens?

What are fixed focal length lenses?

Fixed focal length lenses are entocentric imaging lenses used in machine vision.

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What different types of fixed focal length lenses does Edmund Optics offer?

Edmund Optics designs and manufacturers many types of imaging lenses.

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What different types of fixed focal length lenses does Edmund Optics offer?

Imaging lenses feature a wide variety of lens mounts, all of which offer different benefits.

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Vignetting

Working Distance (WD)

Working f/#

Zoom

Angular Field of View (AFOV)

Aperture (f/#)

Aperture Stop

Entrance Pupil

Exit Pupil

Field

Field Efficiency

Fixed Focal Length Lens

F-Mount

Image Circle

Line Pair (lp)

Imaging System Parameter Calculator

Imaging Lens Selector

センサーとレンズ

Imaging lenses and sensors must be paired together with special attention.

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イメージングの基本

Want to understand the basic concepts of imaging? Learn more about essential terms and how they incorporate in the imaging industry at Edmund Optics.

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コントラスト

Is the definition on your image not clear? Go back to the basics and learn more about the contrast of an image and its importance at Edmund Optics.

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被写界深度と焦点深度

Are you getting depth of field and depth of focus confused? Discover the differences and how to distinguish the two from one another at Edmund Optics.

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レンズマウント

There are numerous mount types for connecting an imaging lens to a camera. Depending on the application, some mounts are more useful than others.

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ディストーション

Distortion is an individual aberration that misplaces information but can be calculated or mapped out of an image. Learn more about distortion at Edmund Optics.

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システムスループット、 Fナンバー、開口数

When it comes to your lens, the f/# is one of the most important settings because it controls multiple parameters. Find out what the f/# controls at Edmund Optics.

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マシンビジョン フィルタリング技法

While working with machine vision, there are different types of filters that can be used to alter the image. Find out about the different types at Edmund Optics.

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レンズからセンサーへ: 情報を集めることの限界

Trying to understand how much information you can obtain from a lens and sensor? Learn more about the limitations of collecting data at Edmund Optics.

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物空間側の解像力

Are you new to imaging and want to learn more about lens magnification? Learn more about lens magnification and other key imaging concepts at Edmund Optics.

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周辺光量比、ロールオフ、口径食

In order to understand vignetting, it is important to understand sensor sizes, formats, and roll-off and relative illumination. Find out more at Edmund Optics.

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波長による性能上の影響

Wavelengths can be both valuable or hazardous when trying to obtain information from an imaging system. Learn more about fixing wavelength issues at Edmund Optics.

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Why Should I Use a Lens Designed Specifically for SWIR Wavelengths?

Short wave infrared (SWIR) imaging applications require specialized imaging optics, as lenses designed for visible use are not optimized for SWIR wavelengths

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EOイメージングレンズができるまで

イメージングレンズの設計、レンズ素子の製造、アッセンブリ、試験をはじめとした製造工程のすべてを動画でご紹介いたします。

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Imaging Innovation Summit Keynote

Master the mindset needed for building an imaging system from asking the right questions to properly combining imaging technologies.

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Edmund Optics Imaging Lab Module 1: Imaging Overview

Learn how to specify imaging system components.

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Edmund Optics Imaging: Telecentric Lenses versus Hypercentric Lenses

Join EO's Nick Sischka, Director of Imaging, as he inspects pipes for various defects using the TECHSPEC Telecentric Lens versus the TECHSPEC Hypercentric Lens.

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Best Practice #4 Light Up Your Life

Join Nick Sischka, Vision Solutions Specialist and member of EO's Imaging Team, as he reviews some best practices to consider when designing an imaging system

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LIGHT TALK - EPISODE 2: Increasing Imaging Sensor Sizes with Katie Schwertz

Join our discussion about increasing imaging sensor sizes and what that means for optical designers in the second episode of our LIGHT TALKS series.

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Manipulating Wavebands: Color & Filters

Nick Sischka explains why color consideration and illumination are so important for machine vision in this hands-on demonstration from the Edmund Optics 2021 Imaging Innovation Summit.

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液体レンズ実装 M12マウントレンズ

TECHSPEC® Liquid Lens M12 Imaging Lenses from Edmund Optics combine a high-resolution with the electronic auto-focus of an integrated liquid lens

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液体レンズ実装 Cxシリーズ 固定焦点レンズ

TECHSPEC® Liquid Lens Cx Series Fixed Focal Length Lenses from Edmund Optics offer both high resolution and fast electronic focus.

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Lens Selection Guide, Part 2

The makings of a successful imaging lens, Part Three: Testing and metrology, ensuring you get what you asked for

The makings of a successful imaging lens, Part Two: Performance-based specifications and their design considerations

The makings of a successful imaging lens, Part One: Application and specification development

Vision & Sensors Lens Selection Guide, Part 1

What is the difference between Primary Magnification and System Magnification?

I need a video lens for my camera - but where do I start?

What is the difference between depth of field and depth of focus?

Which type of colored filter is best for my imaging application?

Primary Magnification (PMAG)

Relative Illumination (RI)

S-Mount

Sliding Focusing Mechanism

T-Mount

Back Flange Distance

Depth of Field (DOF)

Depth of Focus

Distortion

Distortion, Non-Monotonic

Field Curvature

Focal Length Extender

Horizontal Resolution

Hyperfocal Distance

良質なイメージングを得るための11のベスト・プラクティス

Do you use imaging systems constantly in your professional field? Learn top tips for improving your imaging system and practices at Edmund Optics.

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収差

Need help understanding aberration theory? Learn about a few fundamental concepts to help clarify your understanding at Edmund Optics.

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エアリーディスクと解像限界

The diffraction pattern caused when light passes through an aperture is called the Airy Disk. Find out how the Airy Disk can impact your image at Edmund Optics.

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イメージングとは?

In imaging, light rays are mapped from an object onto an imaging sensor by an imaging lens, to reproduce the characteristics and likeness of the object for the purposes of inspection, sorting, or analysis.

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SWIRとは?

Have a question about short-wave infrared (SWIR)? Find definitions, application uses, and examples at Edmund Optics.

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解像力とMTFテスト

Hyperspectral and Multispectral Imaging

Are you trying to gauge depth of field in your imaging system? Take a closer look at this article on depth of field calculations at Edmund Optics.

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Lens Types, Resolution, and Sensor Coverage

No imaging lens is the ideal choice for every type of imaging sensor, as multiple tradeoffs must be weighed and prioritized for every application.

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Axial and Lateral Chromatic Aberration

Chromatic aberrations impact the performance of imaging systems in many different ways, as exemplified in this hands-on demonstration.

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Edmund Optics Imaging Lab 1.1: Field of View

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 1.2: Working Distance

Edmund Optics Imaging Lab 1.5: Sensor Size

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 3.2: The W of Illumination Geometry

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 3.3: Directional Illumination

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 3.4: Directional Illumination of Ring Lights

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 3.5: Backlights

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 3.6: Dome Lights

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 3.7: Line Lights

Learn how to specify imaging system components.

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Best Practice #5 Color Matters

Join Nick Sischka, Vision Solutions Specialist and member of EO's Imaging Team, as he reviews some best practices to consider when designing an imaging system.

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Best Practice #6 There Can Be Only One

Join Nick Sischka, Director of Imaging, as he reviews some best practices to consider when designing an imaging system.

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LIGHT TALK - EPISODE 1: Machine Vision Trends with Nick Sischka

Join our discussion around machine vision trends including such as increasing resolution and new sensors in the first episode of our LIGHT TALKS series.

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ハイパースペクトル & マルチスペクトルイメージング - 光学テクノロジー最前線: エピソード 7

Hyperspectral and multispectral imaging are imaging technologies that capture information from a broader portion of the electromagnetic spectrum.

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Next generation image sensors: Are suppliers ready to meet growing customer expectations?

If I want to design with your lenses and lens assemblies, how do I get the information that I need?

Spatial Frequency

Contrast

解像力とコントラスト特性の比較

Learn how Edmund Optics maintains optical performance across the entire image plane through this resolution and contrast comparison using our C Series FFL lens.

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Edmund Optics Imaging Lab 1.4: Depth of Field

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 1.7: Contrast In Depth

Learn how to specify imaging system components.

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Resolution

Resolving Power

Diffraction Limit

Modulation Transfer Function (MTF)

Nyquist Limit

Parfocality

解像力

Do you want to understand how a lens works? To do so, you must learn key terms for how the lens functions, including resolution. Find out more at Edmund Optics.

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Edmund Optics Imaging Lab 1.3: Resolution

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 1.6: Resolution In Depth

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 1.8: Depth of Field in Depth

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab Module 2: Gauging and Measurement Accuracy Overview

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 2.1: Distortion

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab 2.2: Telecentricity

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab Module 3: Illumination Overview

Learn how to specify imaging system components.

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Edmund Optics Imaging Lab Module 3.1: Introduction to Illumination Concepts

Learn how to specify imaging system components.

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How I do select the correct testing target for my electronic imaging system (camera & lens)?

C-Mount

Field of View (FOV)

Magnification

Numerical Aperture (NA)

2011 Telecentric Bell Choir

The Future Depends on Optics®

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What is an "in-line" video system?

Edmund Optics Imaging Comparison: Why Optics Matter

The success of your machine vision application depends on the quality of your optical components.

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EOのグローバル製造拠点

ラピッドプロトタイピング、1日24時間稼働の非球面レンズ製造セル、最新の測量法など、他社とは一線を画すエドモンド・オプティクスのグローバルな光学部品の製造拠点の機能についてご紹介

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エドモンド・オプティクスの計測:製造の主要な要素としての測定

Learn about the metrology that Edmund Optics® uses to guarantee the quality of all optical components and assemblies.

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Refraction

 
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