Methods to obtain quantitative parametric descriptions of the optical surfaces of the human crystalline lens from Scheimpflug slit-lamp images. I. Image processing methods

Christopher A. Cook; Jane F. Koretz

doi:10.1364/JOSAA.15.001473

Journal of the Optical Society of America A
Vol. 15,
Issue 6,
pp. 1473-1485
(1998)
•https://doi.org/10.1364/JOSAA.15.001473

Methods to obtain quantitative parametric descriptions of the optical surfaces of the human crystalline lens from Scheimpflug slit-lamp images. I. Image processing methods

Christopher A. Cook and Jane F. Koretz

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Christopher A. Cook and Jane F. Koretz, "Methods to obtain quantitative parametric descriptions of the optical surfaces of the human crystalline lens from Scheimpflug slit-lamp images. I. Image processing methods," J. Opt. Soc. Am. A 15, 1473-1485 (1998)

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Abstract

Of the methods developed (e.g., phakometry, magnetic resonance imaging, etc.) for noninvasive measurement of the geometry of the anterior segment of the human eye, Scheimpflug photography offers the best resolution and the highest precision. The primary obstacle encountered with this or any other image-based method has been in obtaining quantitative measurements directly from the images. Image enhancement (gray-scale gradient analysis) and pattern recognition methods (Hough transform and recursive least-squares algorithms) are developed so that parametric representations of lens surfaces and zone boundaries can be obtained directly from the images. Methods to correct for nonlinear Scheimpflug camera reproduction ratios and provide error estimates for geometrical parameters are also developed and will be presented separately. Combined, these techniques yield representations of lens geometry having sufficient precision, to which paraxial ray tracing can be applied to determine lens optical properties by using well-posed optical models with one unknown.

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Surface or Boundary	τ	$σ_{τ}$	υ	$σ_{υ}$	$R$	$σ_{R}$
CAS	0.00	1.530	0.00	1.074	396.70	1.303
CPS	2.30	1.900	38.86	1.444	360.48	1.498
LAS	3.22	3.280	285.40	1.205	781.98	5.356
	9.53	6.081	293.32	2.246	768.74	9.731
	5.03	4.840	299.96	2.256	608.38	6.231
	9.57	6.352	309.22	3.942	454.68	6.124
	$- 4.18$	14.627	324.08	10.928	359.50	11.901
NAB	$- 10.94$	4.480	335.56	5.396	218.67	2.245
	$- 23.97$	15.681	506.02	17.631	$- 229.89$	8.476
	$- 27.88$	11.497	518.63	12.599	$- 239.03$	6.374
NPB	$- 18.92$	8.823	526.37	8.560	$- 264.39$	5.469
	$- 15.92$	8.559	539.40	7.403	$- 304.37$	5.978
	$- 28.07$	7.385	551.10	5.638	$- 329.11$	5.870
	$- 33.69$	5.338	558.22	3.723	$- 363.26$	4.589
LPS	$- 30.86$	3.566	568.15	2.428	$- 394.29$	3.150

Surfaceor Boundary	τ	$σ_{τ}$	υ	$σ_{υ}$	$R$	$σ_{R}$
CAS	0.00	1.648	0.00	1.143	392.18	1.417
CPS	3.49	1.570	38.12	1.217	348.93	1.213
LAS	5.64	2.280	246.32	1.233	501.78	2.536
	7.68	3.694	253.94	2.319	428.50	3.487
	10.65	6.477	254.03	3.583	491.51	6.949
	1.78	5.296	259.49	3.717	386.20	4.489
	1.40	10.525	268.67	8.287	323.39	8.061
	$- 0.37$	4.820	284.13	5.053	254.14	2.781
NAB	1.00	3.365	295.17	4.559	199.37	1.501
	$- 5.25$	8.487	311.98	16.971	134.15	2.579
	$- 8.49$	17.308	510.19	26.884	$- 170.16$	6.769
NPB	$- 7.22$	8.428	525.75	11.521	$- 194.58$	3.730
	$- 17.25$	12.105	543.48	12.928	$- 265.69$	6.847
	$- 17.70$	13.743	552.39	12.991	$- 286.14$	8.824
LPS	$- 25.19$	8.522	568.28	6.779	$- 355.58$	6.447

Surface or Boundary	τ	$σ_{τ}$	υ	$σ_{υ}$	$R$	$σ_{R}$
CAS	0.00	1.530	0.00	1.074	396.70	1.303
CPS	2.30	1.900	38.86	1.444	360.48	1.498
LAS	3.22	3.280	285.40	1.205	781.98	5.356
	9.53	6.081	293.32	2.246	768.74	9.731
	5.03	4.840	299.96	2.256	608.38	6.231
	9.57	6.352	309.22	3.942	454.68	6.124
	$- 4.18$	14.627	324.08	10.928	359.50	11.901
NAB	$- 10.94$	4.480	335.56	5.396	218.67	2.245
	$- 23.97$	15.681	506.02	17.631	$- 229.89$	8.476
	$- 27.88$	11.497	518.63	12.599	$- 239.03$	6.374
NPB	$- 18.92$	8.823	526.37	8.560	$- 264.39$	5.469
	$- 15.92$	8.559	539.40	7.403	$- 304.37$	5.978
	$- 28.07$	7.385	551.10	5.638	$- 329.11$	5.870
	$- 33.69$	5.338	558.22	3.723	$- 363.26$	4.589
LPS	$- 30.86$	3.566	568.15	2.428	$- 394.29$	3.150

Surfaceor Boundary	τ	$σ_{τ}$	υ	$σ_{υ}$	$R$	$σ_{R}$
CAS	0.00	1.648	0.00	1.143	392.18	1.417
CPS	3.49	1.570	38.12	1.217	348.93	1.213
LAS	5.64	2.280	246.32	1.233	501.78	2.536
	7.68	3.694	253.94	2.319	428.50	3.487
	10.65	6.477	254.03	3.583	491.51	6.949
	1.78	5.296	259.49	3.717	386.20	4.489
	1.40	10.525	268.67	8.287	323.39	8.061
	$- 0.37$	4.820	284.13	5.053	254.14	2.781
NAB	1.00	3.365	295.17	4.559	199.37	1.501
	$- 5.25$	8.487	311.98	16.971	134.15	2.579
	$- 8.49$	17.308	510.19	26.884	$- 170.16$	6.769
NPB	$- 7.22$	8.428	525.75	11.521	$- 194.58$	3.730
	$- 17.25$	12.105	543.48	12.928	$- 265.69$	6.847
	$- 17.70$	13.743	552.39	12.991	$- 286.14$	8.824
LPS	$- 25.19$	8.522	568.28	6.779	$- 355.58$	6.447

Abstract

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Figures (10)

Tables (2)

Equations (43)

Journal of the Optical Society of America A