Sage Journals: Discover world-class research

Abstract

The previously described optimized binary compressive detection (OB-CD) strategy enables fast hyperspectral Raman (and fluorescence) spectroscopic analysis of systems containing two or more chemical components. However, each OB-CD filter collects only a fraction of the scattered photons and the remainder of the photons are lost. Here, we present a refinement of OB-CD, the OB-CD2 strategy, in which all of the collected Raman photons are detected using a pair of complementary binary optical filters that direct photons of different colors to two photon counting detectors. The OB-CD2 filters are generated using a new optimization algorithm described in this work and implemented using a holographic volume diffraction grating and a digital micromirror device (DMD) whose mirrors are programed to selectively direct photons of different colors either to one or the other photon-counting detector. When applied to pairs of pure liquids or two-component solid powder mixtures, the resulting OB-CD2 strategy is shown to more accurately estimate Raman scattering rates of each chemical component, when compared to the original OB-CD, thus facilitating chemical classification at speeds as fast as 3 μs per measurement and the collection of Raman images in under a second.

Keywords

Raman spectroscopy chemometrics compressive sampling

Get full access to this article

View all access options for this article.

References

Nafie

L.A.

“Recent Advances in Linear and Non-linear Raman Spectroscopy. Part IX”. J. Raman Spectrosc. 2015. 46(12): 1173–1190.

Kumar

Verma

Mukherjee

Ariese

et al.

“Raman and Infra-Red Microspectroscopy: Towards Quantitative Evaluation for Clinical Research by Ratiometric Analysis”. Chem. Soc. Rev. 2016. 45(7): 1879–1900.

Sweatt

W.C.

Boye

C.A.

Gentry

S.M.

Descour

M.R.

et al.

“Isis: An Information-Efficient Spectral Imaging System”. SPIE Proceedings. 1998. 3438: 98–106.

Uzunbajakava

de Peinder

t Hooft

G.W.

van Gogh

A.T.M.

“Low-cost Spectroscopy with a Variable Multivariate Optical Element”. Anal. Chem. 2006. 78(20): 7302–7308.

Maltas

D.C.

Kwok

Wang

Taylor

L.S.

et al.

“Rapid Classification of Pharmaceutical Ingredients with Raman Spectroscopy using Compressive Detection Strategy with PLS-DA Multivariate Filters”. J. Pharm. Biomed. Anal. 2013. 80: 63–68.

Davis

B.M.

Hemphill

A.J.

Maltas

D.C.

Zipper

M.A.

et al.

“Multivariate Hyperspectral Raman Imaging Using Compressive Detection”. Anal. Chem. 2011. 83(13): 5086–5092.

Vornehm

J.E.

Dong

A.J.

Boyd

R.W.

Shi

“Multiple-Output Multivariate Optical Computing for Spectrum Recognition”. Opt. Express. 2014. 21: 25005–25014.

Hanley

Q.S.

Verveer

P.J.

Jovin

T.M.

“Optical Sectioning Fluorescence Spectroscopy in a Programmable Array Microscope”. Appl. Spectrosc. 1998. 52(6): 783–789.

Quyen

N.T.

Da Silva

Quy Dao

Jouan

M.D.

“New Raman Spectrometer Using a Digital Micromirror Device and a Photomultiplier Tube Detector for Rapid On-Line Industrial Analysis. Part I: Description of the Prototype and Preliminary Results”. Appl. Spectrosc. 2008. 62(3): 273–278.

10.

Quyen

N.T.

Jouan

M.D.

Quy Dao

Da Silva

Phuong

D.A.

“New Raman Spectrometer Using a Digital Micromirror Device and a Photomultiplier Tube Detector for Rapid On-Line Industrial Analysis. Part II: Choice of Analytical Methods”. Appl. Spectrosc. 2008. 62(3): 279–284.

11.

Soyemi

O.O.

Haiback

F.G.

Gemperline

P.J.

Myrick

M.L.

“Nonlinear Optimization Algorithm for Multivariate Optical Element Design”. Appl. Spectrosc. 2002. 56(4): 477–487.

12.

Duarte

M.F.

Davenport

M.A.

Tarkhar

Laska

J.N.

et al.

“Single-Pixel Imaging via Compressive Sampling”. IEEE Signal Process. Mag. 1998. 25(2): 83–101.

13.

Wilcox

D.S.

Buzzard

G.T.

Lucier

B.J.

Wang

et al.

“Photon Level Chemical Classification Using Digital Compressive Detection”. Anal. Chim. Acta. 2012. 755: 17–27.

14.

Wilcox

D.S.

Buzzard

G.T.

Lucier

B.J.

Rehrauer

O.G.

et al.

“Digital Compressive Chemical Quantitation and Hyperspectral Imaging”. The Analyst. 2013. 138(17): 4982–4990.

15.

Buzzard

G.T.

Lucier

B.J.

“Optimal Filters for High-Speed Compressive Detection in Spectroscopy”. SPIE Proceedings. 2013. 8657: 865707–865717.

16.

Rehrauer

O.G.

Mankani

Buzzard

G.T.

Lucier

B.J.

et al.

“Fluorescence Modeling for Optimized-Binary Compressive Detection Raman Spectroscopy”. Opt. Express. 2015. 23(18): 423935–423951.

17.

Atkinson

Donev

Tobias

Optimum Experimental Designs, with SAS, Oxford: Oxford University Press, 2007 Vol. 37.

18.

Pukelsheim

Optimal Design of Experiments, Chichester: John Wiley and Sons Inc., 1993.

19.

Marshall

A.G.

Comisarow

M.B.

“Fourier and Hadamard Transform Methods in Spectroscopy”. Anal. Chem. 1975. 47(4): 491A–504A.

20.

DeVerse

R.A.

Hammaker

R.M.

Fateley

W.G.

“Realization of the Hadamard Multiplex Advantage using a Programmable Optical Mask in a Dispersive Flat-Field Near-Infrared Spectrometer”. Appl. Spectrosc. 2000. 54(12): 1751–1758.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

9.73 MB

Binary Complementary Filters for Compressive Raman Spectroscopy

Abstract

Keywords

Get full access to this article

References

Supplementary Material