OPAA1DF Optoelectronics

Series:	OPA
Part Status:	Active
Lead Free Status / RoHS Status:	--
Type:	Lens, Sub Lens
Moisture Sensitivity Level (MSL):	--
Color:	Clear
Number of LEDs:	1
Lens Style:	Round with Flat Top
Lens Size:	26mm Dia
Lens Transparency:	Diffused
Optical Pattern:	Diffuser
Viewing Angle:	10°
For Use With/Related Manufacturer:	Osram
Material:	Acrylic
Mounting Type:	Snap In

Due to market price fluctuations, if you need to purchase or consult the price. You can contact us or emial to us:   sales@allicdata.com

Introduction

OPAA1DF application field and working principle are related to the use and benefits of a type of optical lens called the opto-aperture axicon (OPAA). This type of lens produces an image with various advantages over traditional lenses. It can be used for many applications including: medical imaging, surveying and mapping, aerial photography, security, and optical communications. This article will discuss how the OPAA works and the different applications it can be employed for.

The Opto-Aperture Axicon

The opto-aperture axicon is an optical lens that uses a combination of two optical components to form an image. The first component is a converging or diverging lens, which captures light from a wide field of view and focuses as a beam of light on a light-sensitive device such as a CCD sensor. The second component is an achromatic lens, which bends the light as it leaves the lens in a special way. The optical design of the OPAA lens means that it produces an image that has higher contrast and sharper detail than a typical lens. The optical principles used to construct the lens are based on the optical axicon. The axicon is a kind of optical prism that causes light rays to converge or diverge in a way that produces a ring-shaped pattern. This is due to the fact that the refracting surface, or lens element, has a conical shape. The axicon can be formed into different versions such as a Bessell prism or a Babinet compensator, and is the basis of the Opto-Aperture Axicon.

Applications of the Opto-Aperture Axicon

The Opto-Aperture Axicon has many uses and applications, the most popular being medical imaging. Medical imaging is important as it provides doctors with detailed pictures of the internal organs and tissues of a patient. The OPAA lens provides sharper detail of these images and can be used to diagnose diseases with greater accuracy. It is also used in surveying and mapping, this is due to the fact that the lens can be adjusted to accurately capture images of a large area with a single sweep. Aerial photography is another application of the OPAA lens. This type of photography is used to take images of the Earth from an aircraft, and the OPAA lens is particularly useful for capturing images of large areas in a single exposure. It is also used for security applications, such as identifying objects in security cameras footage. Finally, optical communications technology is rapidly advancing, and the OPAA lens can be used to transmit data in the form of optical signals. This data can be sent over large distances without loss of information.

Working Principle

The working principle behind the OPAA lens is based on the fact that it is made up of two components. The converging or diverging lens focuses light from a wide angle to the light-sensitive device, which is typically a CCD sensor. The second component is the achromatic lens, which bends the light as it leaves the lens in a special way. The bending of the light by the lens causes the light to form a ring-shaped pattern, which is known as the optical axicon. The OPAA lens produces an image with increased contrast and sharper detail compared to traditional lenses, due to its unique design.

Conclusion

The Opto-Aperture Axicon (OPAA) is a type of optical lens with many advantages over traditional lenses. Its unique design produces an image with increased contrast and sharper detail. It is used for many applications including medical imaging, surveying and mapping, aerial photography, security, and optical communications. The OPAA lens works by focusing light from a wide field of view onto a light-sensitive device, and then using an achromatic lens to bend the light and form a ring-shaped pattern. This article has discussed the various applications and working principle of the OPAA lens.

The specific data is subject to PDF, and the above content is for reference

Part Number	Manufacturer	Price	Quantity	Description