Peripheral refraction validity of the Shin-Nippon SRW5000 autorefractor

Uchechukwu Levi Osuagwu; Marwan Suheimat; James S. Wolffsohn; David A. Atchison

doi:10.1097/OPX.0000000000000954

Peripheral refraction validity of the Shin-Nippon SRW5000 autorefractor

Uchechukwu Levi Osuagwu, Marwan Suheimat, James S. Wolffsohn, David A. Atchison

Research output: Contribution to journal › Article › peer-review

Abstract

PURPOSE: To investigate the operation of the Shin-Nippon/Grand Seiko autorefractor and whether higher-order aberrations affect its peripheral refraction measurements.

METHODS: Information on instrument design, together with parameters and equations used to obtain refraction, was obtained from a patent. A model eye simulating the operating principles was tested with an optical design program. Effects of induced defocus and astigmatism on the retinal image were used to calibrate the model eye to match the patent equations. Coma and trefoil were added to assess their effects on the image. Peripheral refraction of a physical model eye was measured along four visual field meridians with the Shin-Nippon/Grand Seiko autorefractor SRW-5000 and a Hartmann-Shack aberrometer, and simulated autorefractor peripheral refraction was derived using the Zernike coefficients from the aberrometer.

RESULTS: In simulation, the autorefractor's square image was changed in size by defocus, into rectangles or parallelograms by astigmatism, and into irregular shapes by coma and trefoil. In the presence of 1.0 D oblique astigmatism, errors in refraction were proportional to the higher-order aberrations, with up to 0.8 D sphere and 1.5 D cylinder for ±0.6 μm of coma or trefoil coefficients with a 5-mm-diameter pupil. For the physical model eye, refraction with the aberrometer was similar in all visual field meridians, but refraction with the autorefractor changed more quickly along one oblique meridian and less quickly along the other oblique meridian than along the horizontal and vertical meridians. Simulations predicted that higher-order aberrations would affect refraction in oblique meridians, and this was supported by the experimental measurements with the physical model eye.

CONCLUSIONS: The autorefractor's peripheral refraction measurements are valid for horizontal and vertical field meridians, but not for oblique field meridians. Similar instruments must be validated before being adopted outside their design scope.

Original language	English
Number of pages	8
Journal	Optometry and Vision Science
Volume	93
Issue number	10
Early online date	17 Aug 2016
DOIs	https://doi.org/10.1097/OPX.0000000000000954
Publication status	Published - Oct 2016

Bibliographical note

This is a non-final version of an article published in final form in Osuagwu, U. L., Suheimat, M., Wolffsohn, J. S., & Atchison, D. A. (2016). Peripheral refraction validity of the Shin-Nippon SRW5000 autorefractor. Optometry and Vision Science, 93(10).

Keywords

Shin-Nippon/Grand Seiko autorefractor
higher-order aberrations
Hartmann-Shack aberrometer
COAS-HD aberrometer
peripheral refraction

Access to Document

10.1097/OPX.0000000000000954

Formatted version for QUT Shin Nippon investigation
This is a non-final version of an article published in final form in Osuagwu, U. L., Suheimat, M., Wolffsohn, J. S., & Atchison, D. A. (2016). Peripheral refraction validity of the Shin-Nippon SRW5000 autorefractor. Optometry and Vision Science, 93(10).
Accepted author manuscript, 2.37 MB

Cite this

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title = "Peripheral refraction validity of the Shin-Nippon SRW5000 autorefractor",

abstract = "PURPOSE: To investigate the operation of the Shin-Nippon/Grand Seiko autorefractor and whether higher-order aberrations affect its peripheral refraction measurements.METHODS: Information on instrument design, together with parameters and equations used to obtain refraction, was obtained from a patent. A model eye simulating the operating principles was tested with an optical design program. Effects of induced defocus and astigmatism on the retinal image were used to calibrate the model eye to match the patent equations. Coma and trefoil were added to assess their effects on the image. Peripheral refraction of a physical model eye was measured along four visual field meridians with the Shin-Nippon/Grand Seiko autorefractor SRW-5000 and a Hartmann-Shack aberrometer, and simulated autorefractor peripheral refraction was derived using the Zernike coefficients from the aberrometer.RESULTS: In simulation, the autorefractor's square image was changed in size by defocus, into rectangles or parallelograms by astigmatism, and into irregular shapes by coma and trefoil. In the presence of 1.0 D oblique astigmatism, errors in refraction were proportional to the higher-order aberrations, with up to 0.8 D sphere and 1.5 D cylinder for ±0.6 μm of coma or trefoil coefficients with a 5-mm-diameter pupil. For the physical model eye, refraction with the aberrometer was similar in all visual field meridians, but refraction with the autorefractor changed more quickly along one oblique meridian and less quickly along the other oblique meridian than along the horizontal and vertical meridians. Simulations predicted that higher-order aberrations would affect refraction in oblique meridians, and this was supported by the experimental measurements with the physical model eye.CONCLUSIONS: The autorefractor's peripheral refraction measurements are valid for horizontal and vertical field meridians, but not for oblique field meridians. Similar instruments must be validated before being adopted outside their design scope.",

keywords = "Shin-Nippon/Grand Seiko autorefractor, higher-order aberrations, Hartmann-Shack aberrometer, COAS-HD aberrometer, peripheral refraction",

author = "Osuagwu, {Uchechukwu Levi} and Marwan Suheimat and Wolffsohn, {James S.} and Atchison, {David A.}",

note = "This is a non-final version of an article published in final form in Osuagwu, U. L., Suheimat, M., Wolffsohn, J. S., & Atchison, D. A. (2016). Peripheral refraction validity of the Shin-Nippon SRW5000 autorefractor. Optometry and Vision Science, 93(10). ",

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AU - Osuagwu, Uchechukwu Levi

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AU - Atchison, David A.

N1 - This is a non-final version of an article published in final form in Osuagwu, U. L., Suheimat, M., Wolffsohn, J. S., & Atchison, D. A. (2016). Peripheral refraction validity of the Shin-Nippon SRW5000 autorefractor. Optometry and Vision Science, 93(10).

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N2 - PURPOSE: To investigate the operation of the Shin-Nippon/Grand Seiko autorefractor and whether higher-order aberrations affect its peripheral refraction measurements.METHODS: Information on instrument design, together with parameters and equations used to obtain refraction, was obtained from a patent. A model eye simulating the operating principles was tested with an optical design program. Effects of induced defocus and astigmatism on the retinal image were used to calibrate the model eye to match the patent equations. Coma and trefoil were added to assess their effects on the image. Peripheral refraction of a physical model eye was measured along four visual field meridians with the Shin-Nippon/Grand Seiko autorefractor SRW-5000 and a Hartmann-Shack aberrometer, and simulated autorefractor peripheral refraction was derived using the Zernike coefficients from the aberrometer.RESULTS: In simulation, the autorefractor's square image was changed in size by defocus, into rectangles or parallelograms by astigmatism, and into irregular shapes by coma and trefoil. In the presence of 1.0 D oblique astigmatism, errors in refraction were proportional to the higher-order aberrations, with up to 0.8 D sphere and 1.5 D cylinder for ±0.6 μm of coma or trefoil coefficients with a 5-mm-diameter pupil. For the physical model eye, refraction with the aberrometer was similar in all visual field meridians, but refraction with the autorefractor changed more quickly along one oblique meridian and less quickly along the other oblique meridian than along the horizontal and vertical meridians. Simulations predicted that higher-order aberrations would affect refraction in oblique meridians, and this was supported by the experimental measurements with the physical model eye.CONCLUSIONS: The autorefractor's peripheral refraction measurements are valid for horizontal and vertical field meridians, but not for oblique field meridians. Similar instruments must be validated before being adopted outside their design scope.

AB - PURPOSE: To investigate the operation of the Shin-Nippon/Grand Seiko autorefractor and whether higher-order aberrations affect its peripheral refraction measurements.METHODS: Information on instrument design, together with parameters and equations used to obtain refraction, was obtained from a patent. A model eye simulating the operating principles was tested with an optical design program. Effects of induced defocus and astigmatism on the retinal image were used to calibrate the model eye to match the patent equations. Coma and trefoil were added to assess their effects on the image. Peripheral refraction of a physical model eye was measured along four visual field meridians with the Shin-Nippon/Grand Seiko autorefractor SRW-5000 and a Hartmann-Shack aberrometer, and simulated autorefractor peripheral refraction was derived using the Zernike coefficients from the aberrometer.RESULTS: In simulation, the autorefractor's square image was changed in size by defocus, into rectangles or parallelograms by astigmatism, and into irregular shapes by coma and trefoil. In the presence of 1.0 D oblique astigmatism, errors in refraction were proportional to the higher-order aberrations, with up to 0.8 D sphere and 1.5 D cylinder for ±0.6 μm of coma or trefoil coefficients with a 5-mm-diameter pupil. For the physical model eye, refraction with the aberrometer was similar in all visual field meridians, but refraction with the autorefractor changed more quickly along one oblique meridian and less quickly along the other oblique meridian than along the horizontal and vertical meridians. Simulations predicted that higher-order aberrations would affect refraction in oblique meridians, and this was supported by the experimental measurements with the physical model eye.CONCLUSIONS: The autorefractor's peripheral refraction measurements are valid for horizontal and vertical field meridians, but not for oblique field meridians. Similar instruments must be validated before being adopted outside their design scope.

KW - Shin-Nippon/Grand Seiko autorefractor

KW - higher-order aberrations

KW - Hartmann-Shack aberrometer

KW - COAS-HD aberrometer

KW - peripheral refraction

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DO - 10.1097/OPX.0000000000000954

M3 - Article

C2 - 27536977

SN - 1040-5488

VL - 93

JO - Optometry and Vision Science

JF - Optometry and Vision Science

IS - 10

ER -

Peripheral refraction validity of the Shin-Nippon SRW5000 autorefractor

Abstract

Bibliographical note

Keywords

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