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Broadband Polarizers

Broadband Polarizers

×
  • 넓은 입사각
  • 탁월한 Transmitted Contrast
  • 손쉽게 결합할 수 있는 컴팩트한 디자인

공통 스펙

Angle of Incidence (°):
±40
Operating Temperature (°C):
-50 to 80
Thickness (mm):
2.50
Thickness Tolerance (mm):
±0.3
Dimensional Tolerance (mm):
+0.0/-0.1
Mount Thickness (mm):
4.5
Wavelength Range (nm):
300 - 2700
Polarization Axis Mark (°):
±2
 Extinction Ratio   Wavelength Range (nm)  Dia. (mm)  Dimensional Tolerance (mm)   Thickness (mm)  AOI (°)  제품 비교하기   재고 번호   가격(부가세 별도)  구입하기
>100:1 @ 300 - 400nm (Typical)
>50,000:1 @ 450 - 550nm (Typical)
>800:1 @ 700 - 1400nm (Typical)
>1000:1 @ 1400 - 2650nm (Typical)
300 - 2700 12.70 +0.0/-0.1 2.50 ±40 #71-207 신제품 KRW 1,087,500   견적 요청  
  • 3~5일내 배송
    ×
 
>100:1 @ 300 - 400nm (Typical)
>50,000:1 @ 450 - 550nm (Typical)
>800:1 @ 700 - 1400nm (Typical)
>1000:1 @ 1400 - 2650nm (Typical)
300 - 2700 25.40 +0.0/-0.1 2.50 ±40 #89-602 KRW 1,500,800   견적 요청  
  • 3~5일내 배송
    ×
 
>100:1 @ 300 - 400nm (Typical)
>50,000:1 @ 450 - 550nm (Typical)
>800:1 @ 700 - 1400nm (Typical)
>1000:1 @ 1400 - 2650nm (Typical)
300 - 2700 50.80 +0.0/-0.1 2.50 ±40 #71-208 신제품 KRW 4,313,800   견적 요청  
  • 3~5일내 배송
    ×
 

Broadband Polarizers는 Wire Grid Polarizer가 적합하지 않은 UV부터 SWIR까지의 광대역 용도에 적합한 솔루션입니다. Broadband Polarizer는 ±40° 의 acceptance angle을 갖고 있으며 non-collimated 광원에 사용하기에 적합합니다. 아울러, 이 polarizer는 300 – 2700nm 범위에서 일관성 있는 transmitted contrast를 허용하는 독특한 디자인을 활용합니다.

참고: 입력 beam은 음각 표시가 되어 있는 옵틱 앞쪽으로 입력됩니다.

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Introduction to Polarization

Is polarization a new topic for you? Learn about key terminology, types, and more information to help you understand polarization at Edmund Optics.

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Laser-Cut Polymer Polarizer and Retarder Quote Tool

Polymer Polarizers and Retarders

Polymer polarizers and retarders, consisting of sheets of polyvinyl alcohol and TAC cellulose triacetate, alter the polarization of light.

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Polarizer Selection Guide

Edmund Optics' Polarizer Selection Guide refines your search for a specific type of polarizer.

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Waveplate 이해하기

Waveplates (retarders) are different when used in polarized light than unpolarized light. Consider terminology, fabrication, or applications at Edmund Optics.

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How Do 3D Movies Work? Polarization

Optical Engineer Katie Schwertz explains how 3D movies work because of polarization in a kid-friendly way.

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Polarization Overview - Part 1: Polarization Basics

Polarizers are optical components designed to filter, modify, or analyze the various polarization states of light.

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Polarization Overview - Part 2: Waveplates & Retarders (Advanced)

Waveplates and retarders are optical components designed to transmit light while modifying its polarization state without attenuating, deviating, or displacing the beam.

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You offer many types of polarizers. What are some key benefits to help me decide which is best for my application?

Are the polarizers shipped with a protective film?

What is the difference between s- and p-polarization states?

What are the meanings for the different terms used for polarizers?

How can I tell what the polarization axis is for a linear polarizer?

When you list the average transmission of a polarizer, what is the difference between single, parallel, and crossed?

I have a linear polarizer glass filter and would like to create circularly polarized light. What type of optics do I need for this?

What is the maximum amount of light a polarizer can transmit?

Does the circular polarizer material have to face a particular direction?

What is the fast and slow axis of a retarder and how do they differ?

How can I find the fast and slow axes of a retarder?

What is the difference between multiple and zero-order retarders and when should I pick one over the other?

How can I determine if a retarder is quarter or half wave?

Can I adapt a retarder for use with a specific wavelength other than the design wavelength?

What is the benefit of polymer retarders?

Analyzer

Birefringence(복굴절)

Circular Polarizer

Polarization

Polarizer

Polarizing Efficiency

P-Polarization

Retardance

Retarder (Waveplate)

S-Polarization

Unpolarized

Wire Grid Polarizer

Successful Light Polarization Techniques

Are you looking for a solution to common imaging problems? Discover different polarization techniques to improve your image at Edmund Optics.

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Polarization Directed Flat Lenses Product Review

Polarization Directed Flat Lenses, which are formed with polymerized liquid crystal thin-film, create a focal length that is dependent on polarization state.

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Optical Polarizers 리뷰

Polarizers are used in a wide range of imaging and research and development applications.

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Does the polarization of light change after reflecting off a mirror?

Do diffusers affect the polarization of light?

Does the polarization of light change when it passes through a beamsplitter?

I would like to split light from a circularly polarized laser source into two beams. What happens when it passes through a cube beamsplitter – both non-polarizing and polarizing?

Does light entering a multimode fiber undergo a polarization change during propagation through the fiber? If so, can the emerging light be linearly polarized by placing a polarizer at the fiber’s output end?

Why does the polarization of a laser matter?

The polarization state of a laser source is important for many different applications.

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Extinction Ratio(소광비)

Non-Polarizing Beamsplitter

Polarizing Beamsplitter

Optical Microscopy Application: Differential Interference Contrast

Differential interference contrast (DIC) is one of the polarization techniques that can be used in optical microscopy. Learn about this technique at Edmund Optics.

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Laser Polarization: The Importance of Polarization in Laser Applications

Understanding the polarization of laser light is critical for many applications, as polarization impacts reflectance, focusing the beam, and other key behaviors.

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