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A Review of Quality Assurance Texture for Highly Pigmented Iris Recognition using an Optimal Wavelength Band

G. Shirisha*

Department of Electronics and Communication Engineering, Sri Venkateshwara University College of Engineering, Tirupati, Andhra Pradesh, India.

Periodicity:January - March'2024
DOI : https://doi.org/10.26634/jele.14.2.20499

Abstract

The iris identification technology that is commercially available often uses segmentation to capture images of the eye within the 850-nm electromagnetic radiation spectrum. In this paper, the strongly pigmented iris image is taken with a camera at 12 different wavelengths, ranging from 420 to 940 nm. The goal is to identify the best wavelength band to expand the iris image wavelengths from 420 to 940 nm in NIR (near infrared) for the purpose of densely pigmented iris recognition. A system that obtains data, usually by digitizing analog channels and storing the data in digital form, is primarily anticipated for imaging the iris at narrow spectral bands in the range of 420–940 nm. This system takes pictures within particular wavelength ranges across the electromagnetic spectrum. Then, 200 human black iris that match the left and right eyes of 100 distinct people are obtained for the assessment. The most common wavelength for recognizing an iris with significant pigmentation is based on texture quality assurance, Equivalent Error Rate (EER), and False Rejection Rate (FRR) matching performance. The visual perception of heightened, detailed local iris texture information supports this effect.

Keywords

Pigmented Iris, Near Infrared, Quality Assurance Texture, Optimal Wavelength Band, Equivalent Error Rate (EER), False Rejection Rate (FRR).

How to Cite this Article?

Shirisha, G. (2024). A Review of Quality Assurance Texture for Highly Pigmented Iris Recognition using an Optimal Wavelength Band. i-manager’s Journal on Electronics Engineering, 14(2), 40-47. https://doi.org/10.26634/jele.14.2.20499

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A Review of Quality Assurance Texture for Highly Pigmented Iris Recognition using an Optimal Wavelength Band

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