Physics-guided neural network for predicting chemical signatures

Cara P. Murphy; Cara P. Murphy; John P. Kerekes

doi:10.1364/AO.420688

Applied Optics
Vol. 60,
Issue 11,
pp. 3176-3181
(2021)
•https://doi.org/10.1364/AO.420688

Physics-guided neural network for predicting chemical signatures

Cara P. Murphy and John P. Kerekes

Not Accessible

Your library or personal account may give you access

Get PDF
Email
Share
Get Citation
Copy Citation Text
Cara P. Murphy and John P. Kerekes, "Physics-guided neural network for predicting chemical signatures," Appl. Opt. 60, 3176-3181 (2021)

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

Check for updates

Abstract

Achieving high classification accuracy on trace chemical residues in active spectroscopic sensing is challenging due to the limited amount of training data available to the classifier. Such classifiers often rely on physics-based models for generating training data though these models are not always accurate when compared to measured data. To overcome this challenge, we developed a physics-guided neural network (PGNN) for predicting chemical reflectance for a set of parameterized inputs that is more accurate than the state-of-the-art physics-based signature model for chemical residues. After training the PGNN, we use it to generate a library of predicted spectra for training a classifier. We compare the classification accuracy when using this PGNN library versus a library generated by the physics-based model. Using the PGNN, the average classification accuracy increases from 0.623 to 0.813 on real chemical reflectance data, including data from chemicals not included in the PGNN training set.

Full Article | PDF Article

More Like This

Physics-guided neural network for tissue optical properties estimation

Kian Chee Chong and Manojit Pramanik
Biomed. Opt. Express 14(6) 2576-2590 (2023)

Physics-guided neural network for channeled spectropolarimeter spectral reconstruction

Chan Huang, Huanwen Liu, Su Wu, Xiaoyun Jiang, Leiming Zhou, and Jigang Hu
Opt. Express 31(15) 24387-24403 (2023)

Neural network pattern recognition of thermal-signature spectra for chemical defense

Arthur H. Carrieri and Pascal I. Lim
Appl. Opt. 34(15) 2623-2635 (1995)

Previous Article Next Article

Data Availability

Data underlying the results presented in this paper are not publicly available at this time.

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 (3)

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 (3)

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 (3)

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

	Parameter
1	Wavenumber, $λ$ [ $m^{- 1}$ ]
2	Substrate ID
3	Chemical concentration [ $m g / {c m}^{2}$ ]
4	Mean particle diameter, $μ$ [ $µ m$ ]
5	Particle size standard deviation, $σ$ [ $µ m$ ]
6	Substrate scale factor, SSF
7	Chemical density [ $m g / {c m}^{3}$ ]
8	Substrate complex optical constant, ${\tilde{n}}_{s u b}$
9	Substrate reflectance, $R_{s u b}$
10	Chemical complex optical constant, ${\tilde{n}}_{c h e m}$

Substrate/Chemical	Cardboard	Glass	High-density Polyethylene (HDPE)	Rough Aluminum
Aspirin	14 at $50 µ g / {c m}^{2}$	1 at $100 µ g / {c m}^{2}$	2 at $100 µ g / {c m}^{2}$	7 at $100 µ g / {c m}^{2}$
Caffeine	15 at $50 µ g / {c m}^{2}$	1 at $50 µ g / {c m}^{2}$		3 at $100 µ g / {c m}^{2}$
		6 at $100 µ g / {c m}^{2}$
		3 at $150 µ g / {c m}^{2}$
Lactose		1 at $50 µ g / {c m}^{2}$		3 at $50 µ g / {c m}^{2}$
Lactose		3 at $100 µ g / {c m}^{2}$
Naproxen		1 at $100 µ g / {c m}^{2}$		1 at $100 µ g / {c m}^{2}$
Naproxen		2 at $150 µ g / {c m}^{2}$		3 at $150 µ g / {c m}^{2}$
Pentaerythritol	15 at $50 µ g / {c m}^{2}$	2 at $150 µ g / {c m}^{2}$	3 at $100 µ g / {c m}^{2}$	5 at $100 µ g / {c m}^{2}$
Pentaerythritol				1 at $150 µ g / {c m}^{2}$
Saccharin	2 at $50 µ g / {c m}^{2}$	6 at $100 µ g / {c m}^{2}$	2 at $100 µ g / {c m}^{2}$	5 at $100 µ g / {c m}^{2}$
Saccharin	3 at $100 µ g / {c m}^{2}$			1 at $150 µ g / {c m}^{2}$

Parameter	Experiment Values
Mean particle diameter, $μ$	0.10, 0.32, 1.00, 3.20, 10.00 µm
Particle diameter standard deviation, $σ$	0.10, 0.20, 0.40, 0.79, 1.59 µm
Substrate scale factor, SSF	0.10, 0.32, 1.00, 3.20, 10.00

	Parameter
1	Wavenumber, $λ$ [ $m^{- 1}$ ]
2	Substrate ID
3	Chemical concentration [ $m g / {c m}^{2}$ ]
4	Mean particle diameter, $μ$ [ $µ m$ ]
5	Particle size standard deviation, $σ$ [ $µ m$ ]
6	Substrate scale factor, SSF
7	Chemical density [ $m g / {c m}^{3}$ ]
8	Substrate complex optical constant, ${\tilde{n}}_{s u b}$
9	Substrate reflectance, $R_{s u b}$
10	Chemical complex optical constant, ${\tilde{n}}_{c h e m}$

Substrate/Chemical	Cardboard	Glass	High-density Polyethylene (HDPE)	Rough Aluminum
Aspirin	14 at $50 µ g / {c m}^{2}$	1 at $100 µ g / {c m}^{2}$	2 at $100 µ g / {c m}^{2}$	7 at $100 µ g / {c m}^{2}$
Caffeine	15 at $50 µ g / {c m}^{2}$	1 at $50 µ g / {c m}^{2}$		3 at $100 µ g / {c m}^{2}$
		6 at $100 µ g / {c m}^{2}$
		3 at $150 µ g / {c m}^{2}$
Lactose		1 at $50 µ g / {c m}^{2}$		3 at $50 µ g / {c m}^{2}$
Lactose		3 at $100 µ g / {c m}^{2}$
Naproxen		1 at $100 µ g / {c m}^{2}$		1 at $100 µ g / {c m}^{2}$
Naproxen		2 at $150 µ g / {c m}^{2}$		3 at $150 µ g / {c m}^{2}$
Pentaerythritol	15 at $50 µ g / {c m}^{2}$	2 at $150 µ g / {c m}^{2}$	3 at $100 µ g / {c m}^{2}$	5 at $100 µ g / {c m}^{2}$
Pentaerythritol				1 at $150 µ g / {c m}^{2}$
Saccharin	2 at $50 µ g / {c m}^{2}$	6 at $100 µ g / {c m}^{2}$	2 at $100 µ g / {c m}^{2}$	5 at $100 µ g / {c m}^{2}$
Saccharin	3 at $100 µ g / {c m}^{2}$			1 at $150 µ g / {c m}^{2}$

Abstract

Data Availability

Cited By

Figures (3)

Tables (3)

Equations (3)

Applied Optics