Optical Aberration Coefficients. V. On the Quality of Predicted Displacements

H. A. Buchdahl

doi:10.1364/JOSA.49.001113

Journal of the Optical Society of America
Vol. 49,
Issue 11,
pp. 1113-1114
(1959)
•https://doi.org/10.1364/JOSA.49.001113

Optical Aberration Coefficients. V. On the Quality of Predicted Displacements

H. A. Buchdahl

Not Accessible

Your library or personal account may give you access

Get PDF
Email
Share
Get Citation
Copy Citation Text
H. A. Buchdahl, "Optical Aberration Coefficients. V. On the Quality of Predicted Displacements," J. Opt. Soc. Am. 49, 1113-1114 (1959)

Export Citation
- BibTex
- Endnote (RIS)
- HTML
- Plain Text
Citation alert
Save article

Abstract

The author’s previous work on the computation of algebraic higher order aberration coefficients and their derivatives has been illustrated numerically by providing explicit calculations, relating to a certain simple triplet operating over a relatively small field and at low aperture. Doubts have been expressed as to the usefulness of using such aberration coefficients to describe the (geometrical) behavior of systems operating at higher apertures and over wider fields. In this paper, therefore, all the primary, secondary, and tertiary aberration coefficients, and the coefficient of quaternary spherical aberration are given for two further systems, viz. (i) a wide angle objective operating at an aperture of f/4.5 and over a field of 70°; and (ii) an objective operating at an aperture of f/2.3 over a field of 40°. A number of diagrams compare the predicted displacements, relative to the ideal image point, of the intersection points with the ideal image plane of certain selected (a) tangential pencils, (b) sagittal pencils, and (c) general skew pencils of rays, with the actual displacements as obtained from trigonometrical traces. The agreement is very satisfactory. Even in cases, however, in which the agreement—for the largest apertures or fields considered—leaves something to be desired a knowledge of the coefficients and their derivatives provides a powerful tool for the control over the performance of the system. A detailed elementary example illustrating this assertion is included.

Full Article | PDF Article

More Like This

Use of a Digital Computer for the Calculation of Aberration Coefficients

P. W. Ford
J. Opt. Soc. Am. 49(9) 875-877 (1959)

Optical Aberration Coefficients. III. The Computation of the Tertiary Coefficients

H. A. Buchdahl
J. Opt. Soc. Am. 48(10) 747-756 (1958)

Projective Formulation of the Problems of Geometrical Optics. I. Theoretical Foundations

Enzo Cambi
J. Opt. Soc. Am. 49(1) 2-15 (1959)

Previous Article Next Article

Cited By

You do not have subscription access to this journal. Cited by links are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Figures (7)

You do not have subscription access to this journal. Figure files are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Tables (5)

You do not have subscription access to this journal. Article tables are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Equations (46)

You do not have subscription access to this journal. Equations are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Surface	Curvature	Separation	k(=N/N′)
1	3.892769		0.6207710
2	−1.049144	0.0505838	1.046107
3	5.479496	0.0228123	1.53990
4	4.236250	0.0079347	0.6407792
5	2.840077	0.0347143	1.56060
6	−3.046004	0.0565349	0.6407792
7	−4.441530	0.0396736	1.56060
8	−5.570317	0.0158695	0.6493928
9	1.302619	0.0188450	0.9559253
10	−3.969398	0.0555431	1.61090

A	1.6996	T₁	−3871.3
Ᾱ	−0.10951	${\bar{T}}_{1}$	6.21
$\bar{B}$	0.023546	T₂	−7.24
C	0.10056	${\bar{T}}_{2}$	−64.574
$\bar{C}$	−0.003391	T₃	−139.23
		${\bar{T}}_{3}$	13.176
S₁	−108.99	T₄	91.52
${\bar{S}}_{1}$	6.0816	${\bar{T}}_{4}$	55.079
S₂	24.598	T₅	26.715
${\bar{S}}_{2}$	3.5450	${\bar{T}}_{5}$	4.3402
S₃	−1.9548	T₆	−2.3130
${\bar{S}}_{3}$	−0.30859	${\bar{T}}_{6}$	−0.26228
S₄	1.8154	T₇	21.424
${\bar{S}}_{4}$	0.03768	${\bar{T}}_{7}$	6.8380
S₅	−0.37703	T₈	4.5130
${\bar{S}}_{5}$	−0.12717	${\bar{T}}_{8}$	−0.25973
S₆	−0.33092	T₉	−0.3581
${\bar{S}}_{6}$	0.004726	${\bar{T}}_{9}$	0.15859
		T₁₀	0.12859
		${\bar{T}}_{10}$	0.00008
		Q₁	−100602

Surface	Curvature	Separation	k
1	2.050960		0.6032091
2	−2.026320	0.135000	1.002419
3	0.3362860	0.030000	1.65380
4	−1.516390	0.118460	0.6624710
5	2.608440	0.030000	1.50950
6	1.144580	0.075318	0.6046608
7	3.373670	0.030000	0.9975872
8	−1.652440	0.140000	1.65780

A	0.36632	T₁	−52.394
Ᾱ	−0.03768	${\bar{T}}_{1}$	2.626
$\bar{B}$	−0.099610	T₂	13.483
C	0.15252	${\bar{T}}_{2}$	−8.6838
$\bar{C}$	−0.016516	T₃	−18.525
		${\bar{T}}_{3}$	1.8456
S₁	−4.3153	T₄	−8.0508
${\bar{S}}_{1}$	0.2563	${\bar{T}}_{4}$	−1.2620
S₂	1.2518	T₅	3.6432
${\bar{S}}_{2}$	−2.5041	${\bar{T}}_{5}$	−7.2301
S₃	−1.9112	T₆	−2.3658
${\bar{S}}_{3}$	0.09448	${\bar{T}}_{6}$	0.78632
S₄	−2.8850	T₇	−2.6256
${\bar{S}}_{4}$	0.18069	${\bar{T}}_{7}$	0.5095
S₅	0.29320	T₈	−2.1688
${\bar{S}}_{5}$	0.17578	${\bar{T}}_{8}$	0.4560
S₆	−0.47100	T₉	0.9914
${\bar{S}}_{6}$	−0.16103	${\bar{T}}_{9}$	2.6581
		T₁₀	−0.09120
		${\bar{T}}_{10}$	−0.35311
		Q₁	−466.39

j →		1	2	3	4	5	6	7	8
(N′−N)t₁²	r₁	0.65780	−0.0031693	−0.48979	0.26958	−0.26076	0.35949	0.0021770	−0.34036
(N′−N)t₁t₄	r₂	0.17958	−0.0₃5753	−0.077375	−0.0081357	0.017828	−0.075619	−0.0₃5301	0.13704
(N′−N)t₄²	r₃	0.049027	−0.031044	−0.012223	0.0₃2455	−0.0012189	0.015907	0.0₃1291	−0.055181
t₁₅″−t₁₅	r₄	0.36632	−0.66614	−0.70818	−0.93020	0.75688	1.8285	1.6044	1.5861
t₁₆″−t₁₆	r₅	−0.03768	0.18386	0.16534	−0.16291	0.80832	0.05814	0.35800	0.36883
t₂₀″−t₂₀	r₆	−0.53769	0.01498	0.00164	0.01690	0.38837	−0.38176	−0.13409	−0.12252
t₆₉″−t₆₉	r₇	−4.3153	−6.7929	−7.1157	−8.5653	−0.2269	6.7693	5.2142	5.0754
(t₇₀+t₇₁+t₈₆)″−(t₇₀+t₇₁+t₈₆)	r₈	0.8447	4.1989	3.5565	−0.5516	15.709	2.0834	7.2248	7.5372
N(t₉t₅″−t₈₁t₂″) = ∂υ_pk′/∂d_j			−0.029289	−0.024747	−0.21926	−0.30412	0.61160	−0.13837	−0.14302
r₁t₅″−r₂t₂″=∂υ_pk′/∂c₀_j		0.47003	−0.005546	−0.40632	0.27437	−0.27534	0.43063	0.026800	−0.47317
$4 N [\frac{1}{4} (3 r_{5} + r_{6}) t_{9} - r_{4} t_{81}] = \partial {A_{p k}}^{'} / \partial d_{j}$			3.5891	3.7355	5.1703	−0.96344	3.5799	−1.0294	−1.0589
$k t_{3} r_{1} (\frac{3}{2} k t_{3} - t_{2}) = \partial a_{p} / \partial c_{0}$	r₉	1.5102	−0.039496	−0.91393	1.3862	−1.6843	0.37185	0.017500	−2.5435
$4 [\frac{1}{4} (3 r_{5} * + r_{6} ) r_{1} - r_{2} r_{4} ] + r_{9} = \partial {A_{p k}}^{'} / \partial c_{0 j}$		2.3614	−0.04270	−0.97073	2.1693	−1.7606	1.1950	0.02300	−2.5435
−2t₂₀t₈₁−t₁₅t₈₂+t₉t₂₁+t₉t₂₂=α_y⁽^d⁾/N	r₁₀		−0.26425	−0.30254	−1.1081	0.90012	2.6512	0.83972	0.82552
$4 [- \frac{1}{4} (3 t_{16} + t_{20}) t_{9} + t_{15} t_{81}] = {α_{υ}}^{(d)} / N$	r₁₁		3.5802	3.6917	8.3438	−0.007096	2.9359	−0.46664	−0.47604
$N {6 [\frac{1}{2} (r_{4} r_{10} + r_{5} r_{11}) - r_{7} t_{81}] + r_{8} t_{9}} = \partial {S_{1 p k}}^{'} / \partial d_{j}$			54.144	56.005	78.538	6.1173	35.324	0.90643	0.63666
1/(Nt₃²)=q*	r₁₂	0.23773	0.088043	2.1602	0.19423	0.30828	0.69975	0.10829	0.34609
t₆r₉+t₁₀r₁₂=∂ā_p/∂c₀	r₁₃	−0.078602	−0.013693	−0.87156	0.47037	0.84878	−0.34094	−0.008345	−0.042564
$[k (k t_{3} - t_{2} ) + t_{2} + t_{3}] \frac{1}{4} t_{1} t_{10}$	r₁₄	0.80535	−0.04911	−0.13156	0.96022	−0.95495	0.069868	0.015948	−1.5991
(1−k)t₁t₂−r₁₃−r₃t₁₅+r₁t₂₁+r₁t₂₂	r₁₅	0.049597	0.013444	0.41277	−0.50894	−0.39957	0.14487	0.007241	0.075784
−2r₂t₂₀+r₁₅=α_y*⁽^c⁾	r₁₆	0.24810	0.012823	0.32695	−0.52401	−0.39401	0.083827	0.006801	0.22316
$4 [- \frac{1}{4} (3 t_{16} * + t_{20} ) r_{1} + t_{15} r_{2}] + r_{9} = {α_{υ}}^{(c)}$	r₁₇	3.0526	−0.045608	−1.4028	2.3328	−1.9042	1.3182	0.023645	−2.5642
$\frac{1}{3} r_{1} r_{8} * + r_{16} r_{4} * + r_{17} r_{5} * + t_{34} r_{9} + r_{14}$	r₁₈	3.3300	−0.13081	−0.16133	4.4656	−3.3747	1.6167	0.065230	−3.9776
3(−2r₂r₇+t₁₅r₁₃−t₂₀r₉+r₁₈) = ∂S₁_pk/∂c*₀_j		17.309	−0.52488	−8.7487	17.544	−16.522	8.8853	0.26402	−14.945

Abstract

Cited By

Figures (7)

Tables (5)

Equations (46)

Journal of the Optical Society of America