Automatic estimation of noise parameters in Fourier-domain optical coherence tomography cross sectional images using statistical information

Patrick Steiner; Jens H. Kowal; Boris Považay; Christoph Meier; Raphael Sznitman

doi:10.1364/AO.54.003650

Applied Optics
Vol. 54,
Issue 12,
pp. 3650-3657
(2015)
•https://doi.org/10.1364/AO.54.003650

Automatic estimation of noise parameters in Fourier-domain optical coherence tomography cross sectional images using statistical information

Patrick Steiner, Jens H. Kowal, Boris Považay, Christoph Meier, and Raphael Sznitman

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Patrick Steiner, Jens H. Kowal, Boris Považay, Christoph Meier, and Raphael Sznitman, "Automatic estimation of noise parameters in Fourier-domain optical coherence tomography cross sectional images using statistical information," Appl. Opt. 54, 3650-3657 (2015)

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Table of Contents Category
- Optical Coherence Tomography
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About this Article
History
- Original Manuscript: February 5, 2015
- Revised Manuscript: March 18, 2015
- Manuscript Accepted: March 22, 2015
- Published: April 14, 2015
Virtual Issues
Virtual Journal for Biomedical Optics Vol. 10, Iss. 5

Abstract

We present an application and sample independent method for the automatic discrimination of noise and signal in optical coherence tomography Bscans. The proposed algorithm models the observed noise probabilistically and allows for a dynamic determination of image noise parameters and the choice of appropriate image rendering parameters. This overcomes the observer variability and the need for a priori information about the content of sample images, both of which are challenging to estimate systematically with current systems. As such, our approach has the advantage of automatically determining crucial parameters for evaluating rendered image quality in a systematic and task independent way. We tested our algorithm on data from four different biological and nonbiological samples (index finger, lemon slices, sticky tape, and detector cards) acquired with three different experimental spectral domain optical coherence tomography (OCT) measurement systems including a swept source OCT. The results are compared to parameters determined manually by four experienced OCT users. Overall, our algorithm works reliably regardless of which system and sample are used and estimates noise parameters in all cases within the confidence interval of those found by observers.

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Measurement System	Type	$λ_{c}$ (nm)	$Δ λ$ (nm)	$T_{int}$	Output Power (mW)	Measurement Range (mm)	Lateral Resolution (μm)
Octomore	Spectrometer-based	830	175	14 μs	1.3	2.1	13
Arges	Spectrometer-based	877	62.5	25 μs	1.1	4.6	35
Steropes	Swept source	1280	105	—	9.8	5.5	25

	Subjective		Percentile [13]	Percentile [12]	Proposed Method
Sample	$μ_{ε}$	$θ_{th}$	$θ_{th}$	$θ_{th}$	$μ_{ε}$	$θ_{th}$	RMSE
Index finger	$0.350 \pm 0.054$	$0.724 \pm 0.050$	0.656	0.556	0.338	0.725	0.0096
Lemon	$0.333 \pm 0.025$	$0.646 \pm 0.156$	0.756	0.626	0.363	0.778	0.0053
Sticky tape	$0.325 \pm 0.052$	$0.450 \pm 0.196$	0.516	0.446	0.367	0.606	0.0048
IR detector card	$0.255 \pm 0.039$	$0.537 \pm 0.080$	0.526	0.436	0.243	0.521	0.0072

	Subjective		Percentile [13]	Percentile [12]	Proposed Method
Sample	$μ_{ε}$	$θ_{th}$	$θ_{th}$	$θ_{th}$	$μ_{ε}$	$θ_{th}$	RMSE
Index finger	$0.113 \pm 0.005$	$0.268 \pm 0.055$	0.195	0.165	0.101	0.216	0.0095
Lemon	$0.103 \pm 0.005$	$0.218 \pm 0.023$	0.195	0.165	0.104	0.222	0.0034
Sticky tape	$0.095 \pm 0.006$	$0.228 \pm 0.028$	0.225	0.185	0.102	0.219	0.0030
IR detector card	$0.110 \pm 0.000$	$0.271 \pm 0.064$	0.225	0.185	0.107	0.230	0.0041

	Subjective		Percentile [13]	Percentile [12]	Proposed Method
Sample	$μ_{ε}$	$θ_{th}$	$θ_{th}$	$θ_{th}$	$μ_{ε}$	$θ_{th}$	RMSE
Index finger	$6.825 \pm 0.674$	$10.464 \pm 5.148$	21.421	15.261	6.625	14.217	0.0055
Lemon	$2.850 \pm 0.125$	$3.817 \pm 1.779$	10.971	7.591	3.040	6.525	0.0046
Sticky tape	$3.005 \pm 0.192$	$3.720 \pm 1.822$	11.683	7.750	2.944	6.632	0.0063
IR detector card	$2.948 \pm 0.792$	$4.301 \pm 1.636$	7.248	5.598	2.781	5.967	0.0042

Measurement System	Type	$λ_{c}$ (nm)	$Δ λ$ (nm)	$T_{int}$	Output Power (mW)	Measurement Range (mm)	Lateral Resolution (μm)
Octomore	Spectrometer-based	830	175	14 μs	1.3	2.1	13
Arges	Spectrometer-based	877	62.5	25 μs	1.1	4.6	35
Steropes	Swept source	1280	105	—	9.8	5.5	25

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