Sage Journals: Discover world-class research

Abstract

Complex-valued chemometrics utilizes both the absorption index and refractive index spectra. Through application of a Kramers–Kronig transformation, it can also be extended to absorbance and Raman spectra. In this work, we expand complex-valued chemometrics to include partial least squares (PLS) regression. Several strategies for implementing complex-valued PLS are explored. One approach builds on the nonlinear iterative partial least squares (NIPALS) formalism to compute real and imaginary components of the PLS solutions in parallel. Additionally, as both the real and imaginary parts can assume positive or negative values, this results in 2 ^N possible solutions for N components. In this case, the optimal solutions are selected using a brute-force approach combined with a nested leave-one-out (LOO) scheme. Additionally, single-value decomposition (SVD) can be directly applied to the complex matrix product of the spectral and concentration matrices. We compare these approaches using complex refractive index spectra of mixtures from the thermodynamically ideal systems benzene–toluene, benzene–cyclohexane, and benzene–carbon tetrachloride (CCl₄). In particular, when the high-wavenumber refractive index differs between the neat components, complex-valued PLS achieves errors more than an order of magnitude lower than conventional PLS based solely on the imaginary part.

Graphical abstract

This is a visual representation of the abstract.

Keywords

Ideal binary liquid mixtures partial least squares regression PLSR complex refractive index spectra chemometrics

Get full access to this article

View all access options for this article.

References

Kramer

. Chemometric Techniques for Quantitative Analysis. Boca Raton, Florida: CRC Press, 1998.

Mark

Workman

Jr . Chemometrics in Spectroscopy. Amsterdam: Elsevier/Academic Press, 2021. 10.1016/C2020-0-01907-9

Olivieri

. Introduction to Multivariate Calibration: A Practical Approach. Cham: Springer International Publishing, 2024.

Haaland

D.M.

Thomas

E.V.

. “Partial Least-Squares Methods for Spectral Analyses. 1. Relation to Other Quantitative Calibration Methods and the Extraction of Qualitative Information”. Anal. Chem. 1988. 60(11): 1193–1202. 10.1021/ac00162a020

Mayerhöfer

T.G.

. Wave Optics in Infrared Spectroscopy: Theory, Simulation, and Modeling. Philadelphia: Elsevier, 2024.

Artigue

Smith

. “The Principal Problem with Principal Components Regression”. Cogent Math. Stat. 2019. 6(1): 1622190. 10.1080/25742558.2019.1622190

Tapp

H.S.

Kemsley

E.K.

. “Notes on the Practical Utility of OPLS”. TrAC, Trends Anal. Chem. 2009. 28(11): 1322–1327. 10.1016/j.trac.2009.08.006

Mayerhöfer

T.G.

Ilchenko

Kutsyk

Popp

. “Complex-Valued Chemometrics in Spectroscopy: Classical Least Squares Regression”. Appl. Spectrosc. 2025. 79(12): 1768–1775.10.1177/00037028251343908

Mayerhöfer

T.G.

Ilchenko

Kutsyk

Popp

. “Complex-Valued Chemometrics in Spectroscopy: Inverse Least Square Regression”. Appl. Spectrosc. 2025. 0(0). 10.1177/00037028251358392

10.

Mayerhöfer

T.G.

Ilchenko

Kutsyk

Piehler

, et al “Complex-Valued Chemometrics for Analyzing Absorbance or Raman Spectra. Appl. Spectrosc. 2025. 10.1177/00037028251401941

11.

Mayerhöfer

T.G.

Ilchenko

Kutsyk

Popp

. “Complex-Valued Chemometrics in Spectroscopy: Principal Component Regression”. Appl. Spectrosc. 2025. 10.1177/00037028251393273

12.

Mayerhöfer

T.G.

Pahlow

Hübner

Popp

. “Removing Interference-Based Effects from the Infrared Transflectance Spectra of Thin Films on Metallic Substrates: A Fast and Wave Optics Conform Solution”. Analyst. 2018. 143(13): 3164–3175. 10.1039/C8AN00526E

13.

Mayerhöfer

T.G.

Pahlow

Hübner

Popp

. “Removing Interference-Based Effects from Infrared Spectra–Interference Fringes Re-Revisited”. Analyst. 2020. 145(9): 3385–3394. 10.1039/D0AN00062K

14.

Mayerhöfer

T.G.

Pahlow

Hübner

Popp

. “CaF₂: An Ideal Substrate Material for Infrared Spectroscopy?”. Anal. Chem. 2020. 92(13): 9024–9031. 10.1021/acs.analchem.0c01158

15.

Mayerhöfer

T.G.

Costa

W.D.P.

Popp

. “Sophisticated Attenuated Total Reflection Correction Within Seconds for Unpolarized Incident Light at 45°”. Appl. Spectrosc. 2024. 78(3): 321–328. 10.1177/00037028231219528

16.

Mayerhöfer

T.G.

Popp

“Attenuated Total and Internal Reflection Correction Based on Fresnel’s Equations Beyond the Low Absorption Assumption“. Appl. Spectrosc. 2025. 79(12): 1747–1757. 10.1177/00037028251352565

17.

Mayerhöfer

T.G.

Popp

. “Understanding and Employing (Non-)Linearities in Attenuated Total Reflection Spectroscopy”. Appl. Spectrosc. 2025. 79(8): 1290–1296. 10.1177/00037028251317540

18.

Mayerhöfer

T.G.

Popp

. “Developing Correction Methods by Revisiting the Concept of Effective Thickness in Attenuated Total Reflection Spectroscopy”. Appl. Spectrosc. 2025. 79(3): 465–472. 10.1177/00037028241290838

19.

Cheng

Mayerhöfer

T.G.

Kiefer

“Theoretical Calculation and Simulation of Peak Distortion of Absorption Spectra of Complex Mixtures“. Appl. Spectrosc. 2024. 79(5): 852–861. 10.1177/00037028241297179

20.

Kramers

H.A.

. “Die Dispersion und Absorption von Röntgenstrahlen”. Physikal. Z. 1929. 30: 522–523.

21.

Lorentz

H.A.

. Collected Papers: Volume II. Dordrecht: Springer-Science + Business Media, B.V., 1936.

22.

Lorentz

H.A.

. “Ueber die beziehung zwischen der fortpflanzungsgeschwindigkeit des lichtes und der körperdichte”. Annal. Phys. 1880. 245(4): 641–665. 10.1002/andp.18802450406

23.

Mayerhöfer

T.G.

Popp

. “Beyond Beer's Law: Revisiting the Lorentz–Lorenz Equation”. ChemPhysChem. 2020. 21(12): 1218–1223. 10.1002/cphc.202000301

24.

Mayerhöfer

T.G.

Popp

. “Beyond Beer's Law: Spectral Mixing Rules”. Appl. Spectrosc. 2020. 74(10): 1287–1294. 10.1177/0003702820942273

25.

Mayerhöfer

T.G.

Ilchenko

Kutsyk

Popp

. “Quantitative Chemometrics Using Refractive Index Spectra”. Appl. Spectrosc. 2025. 79(11): 1659–1664. 10.1177/00037028251345774

26.

Mayerhöfer

T.G.

Ilchenko

Kutsyk

Popp

. “Beyond Beer’s Law: Quasi-Ideal Binary Liquid Mixtures”. Appl. Spectrosc. 2022. 76(1): 92–104. 10.1177/00037028211056293

27.

De Jong

. “SIMPLS: An Alternative Approach to Partial Least Squares Regression”. Chemom. Intell. Lab. Syst. 1993. 18(3): 251–263. 10.1016/0169-7439(93)85002-X

28.

Petersen

K.B.

Pedersen

M.S.

. The Matrix Cookbook. https://www2.imm.dtu.dk/pubdb/edoc/imm3274.pdf [accessed 14 November 2025].

29.

Myers

T.L.

Tonkyn

R.G.

Danby

T.O.

Taubman

M.S.

, et al. “Accurate Measurement of the Optical Constants n and k for a Series of 57 Inorganic and Organic Liquids for Optical Modeling and Detection”. Appl. Spectrosc. 2018. 72(4): 535–550. 10.1177/0003702817742848

30.

Sellmeier

. “Ueber die durch die Aetherschwingungen erregten Mitschwingungen der Koerpertheilchen und deren Rueckwirkung auf die ersteren, besonders zur Erklaerung der Dispersion und ihrer Anomalien”. Ann. Phys. 1872. 223(12): 525–554. 10.1002/andp.18722231203

31.

Bertie

J.E.

Eysel

H.H.

. “Infrared Intensities of Liquids I: Determination of Infrared Optical and Dielectric Constants by FT-IR Using the Circle ATR Cell”. Appl. Spectrosc. 1985. 39(3): 392–401. 10.1366/0003702854248575

32.

Ohta

Ishida

. “Efficient Method for Optical Constant Determination by FTIR-ATR”. Proceeding SPIE 1575, 8th International Conference on Fourier Transform Spectroscopy. 1992. Pp. 604–605. 10.1117/12.56372

33.

Mayerhöfer

T.G.

Popp

. “Understanding Advanced Attenuated Total Reflection Correction: The Low Absorbance Assumption”. Appl. Spectrosc. 2024. 79(2): 298–305. 10.1177/00037028241268024

34.

Mayerhöfer

T.G.

Popp

. “Developing Correction Methods by Revisiting the Concept of Effective Thickness in Attenuated Total Reflection Spectroscopy”. Appl. Spectrosc. 2024. 79(3): 465–472. 10.1177/00037028241290838

35.

Mayerhöfer

T.G.

Popp

. “Understanding and Employing (Non-)Linearities in ATR Spectroscopy”. Appl. Spectrosc. 2024. 79(8): 1290–1296. 10.1177/00037028251317540

36.

Myers

T.L.

Bernacki

B.E.

Wilhelm

M.J.

Jensen

K.L.

, et al. “Influence of Intermolecular Interactions on the Infrared Complex Indices of Refraction for Binary Liquid Mixtures”. Phys. Chem. Chem. Phys. 2022. 24(36): 22206–22221. 10.1039/D2CP02920K

37.

Mayerhöfer

T.G.

Dabrowska

Schwaighofer

Lendl

Popp

. “Beyond Beer's Law: Why the Index of Refraction Depends (Almost) Linearly on Concentration”. ChemPhysChem. 2020. 21(8): 707–711. 10.1002/cphc.202000018

38.

Mayerhöfer

T.G.

Costa

W.D.P.

Popp

. “Combining Infrared Refraction and Attenuated Total Reflection Spectroscopy”. Appl. Spectrosc. 2025. 79(6): 1018–1027. 10.1177/00037028241283050

39.

Smilde

A.K.

Bro

Geladi

. Multi-Way Analysis: Applications in the Chemical Sciences. Wiley, 2005.

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

1.49 MB

0.14 MB

0.08 MB

Complex-Valued Chemometrics in Spectroscopy: Partial Least Squares Regression

Abstract

Keywords

Get full access to this article

References

Supplementary Material