Error-reduction methods for shape measurement by temporal phase unwrapping

J. M. Huntley; H. O. Saldner

doi:10.1364/JOSAA.14.003188

Journal of the Optical Society of America A
Vol. 14,
Issue 12,
pp. 3188-3196
(1997)
•https://doi.org/10.1364/JOSAA.14.003188

Error-reduction methods for shape measurement by temporal phase unwrapping

J. M. Huntley and H. O. Saldner

Not Accessible

Your library or personal account may give you access

Get PDF
Email
Share
Get Citation
Copy Citation Text
J. M. Huntley and H. O. Saldner, "Error-reduction methods for shape measurement by temporal phase unwrapping," J. Opt. Soc. Am. A 14, 3188-3196 (1997)

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

Abstract

Temporal phase unwrapping is a method of analyzing fringe patterns in which the fringe phase Φ at each pixel is measured and unwrapped as a function of time $t .$ We propose two methods for improving the signal-to-noise ratio of the total phase change by incorporating data from the intermediate phase values. The first involves fitting the expected curve to the measured phase history; the second involves Fourier transformation of the corresponding phasors. The performance of these methods is compared both experimentally, with data from a fringe projector based on a spatial-light modulator, and numerically. It is shown that the optimum performance is given by the Fourier transform method. The best way to use the first method is with Φ decreasing exponentially with time from its maximum value to zero; this provides significant improvements in reliability, accuracy, and computation time compared with the original temporal unwrapping algorithm.

Full Article | PDF Article

More Like This

Flexible error-reduction method for shape measurement by temporal phase unwrapping: phase averaging method

Liu Yong, Huang Dingfa, and Jiang Yong
Appl. Opt. 51(21) 4945-4953 (2012)

Robustness of reduced temporal phase unwrapping in the measurement of shape

Lars Kinell and Mikael Sjödahl
Appl. Opt. 40(14) 2297-2303 (2001)

Temporal phase unwrapping: application to surface profiling of discontinuous objects

H. O. Saldner and J. M. Huntley
Appl. Opt. 36(13) 2770-2775 (1997)

Previous Article Next Article

References

You do not have subscription access to this journal. Citation lists with outbound citation 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

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 (9)

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 (2)

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 (34)

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

Method	Data Acquisition Time	Computational Effort	Standard Deviation of $\hat{ω}$
A, No fitting	$q τ ({log}_{2} s + 1)$	$(2 q + 8) ({log}_{2} s + 1)$	$σ_{ϕ} / s$
B, Fitted to linear sequence	$q τ s$	$(2 q + 9) s$	$\sqrt{3} σ_{ϕ} / s^{3 / 2}$
C, Fitted to exponential sequence	$q τ ({log}_{2} s + 1)$	$(2 q + 9) ({log}_{2} s + 1)$	$\sqrt{3} σ_{ϕ} / 2 s$
D, Fitted to reversed exponential sequence	$q τ ({log}_{2} s + 1)$	$(2 q + 9) ({log}_{2} s + 1)$	$σ_{ϕ} / s \sqrt{{log}_{2} s}$
E, Fourier transform ranging	$q τ s$	$(2 q - 2 + 4 {log}_{2} s) s$	$\sim σ_{ϕ} / s^{3 / 2}$

Method	950 ms	200 ms	80 ms	Theoretical
A, No fitting	1.00	1.00	1.00	1.00
B, Fitted to linear sequence	0.51	0.37	0.37	0.41
C, Fitted to exponential sequence	0.85	0.81	0.80	0.87
D, Fitted to reversed exponential sequence	0.60	0.50	0.56	0.54
E, Fourier transform ranging	0.51	0.36	0.35	—

Method	Data Acquisition Time	Computational Effort	Standard Deviation of $\hat{ω}$
A, No fitting	$q τ ({log}_{2} s + 1)$	$(2 q + 8) ({log}_{2} s + 1)$	$σ_{ϕ} / s$
B, Fitted to linear sequence	$q τ s$	$(2 q + 9) s$	$\sqrt{3} σ_{ϕ} / s^{3 / 2}$
C, Fitted to exponential sequence	$q τ ({log}_{2} s + 1)$	$(2 q + 9) ({log}_{2} s + 1)$	$\sqrt{3} σ_{ϕ} / 2 s$
D, Fitted to reversed exponential sequence	$q τ ({log}_{2} s + 1)$	$(2 q + 9) ({log}_{2} s + 1)$	$σ_{ϕ} / s \sqrt{{log}_{2} s}$
E, Fourier transform ranging	$q τ s$	$(2 q - 2 + 4 {log}_{2} s) s$	$\sim σ_{ϕ} / s^{3 / 2}$

Method	950 ms	200 ms	80 ms	Theoretical
A, No fitting	1.00	1.00	1.00	1.00
B, Fitted to linear sequence	0.51	0.37	0.37	0.41
C, Fitted to exponential sequence	0.85	0.81	0.80	0.87
D, Fitted to reversed exponential sequence	0.60	0.50	0.56	0.54
E, Fourier transform ranging	0.51	0.36	0.35	—

Abstract

References

Cited By

Figures (9)

Tables (2)

Equations (34)

Metrics

Journal of the Optical Society of America A

Login or Create Account