StarkE. and LuchterK., “Diversity in NIR instrumentation”, in Near Infrared Spectroscopy: Proceedings of the 11th International Conference, Ed by DaviesA.M.C. and Garrido-VaroA.NIR Publications, Chichester, pp. 55–66 (2004).
HockerG.B.YoungnerD.DeutschE.VolpicelliA.SenturiaS.ButlerM.SinclairM.PlowmanT. and RiccoA.J., “The Polychromator: A Programmable MEMS Diffraction Grating for Synthetic Spectra”, Proc. Solid-State Sensor and Actuator Workshop (Hilton Head, SC, June 4–8, 2000), pp. 89–92 (2000).
5.
KrippnerP.KuhnerT.MohrJ. and SaileV., “Microspectrometer system for the near infrared wavelength range based on LIGA technology”, SPIE3912, 141–149 (2000).
6.
KraftM.KendaA.FrankA.ScherfW.HebererA.SandnerT.SchenkH. and ZimmerF., Anal. Bioanal. Chem., doi: 10.1007/s00216-006-0726-5.
7.
DeVerseR.A.HammakerR.M. and FateleyW.G., “Realization of the Hadamard Multiplex Advantage Using a Programmable Optical Mask in a Dispersive Flat-Field Near-Infrared Spectrometer”, Appl. Spectrosc.54(12), 1751–1758 (2000).
8.
MalbertF.KernP.DuportSchanen I.BergerJ.P. and Rousselet-PerrautK., Astron. Astrophys. Suppl. Ser.138, 135–145 (1999).
9.
BergerJ.P.Rousselet-PerrautK.KernP.MalbetF.Schanen-DuportI.ReynaudF.HaguenauerP. and BenechP., “Integrated optics for astronomical interferometry. II First laboratory white light interferogram”, Astron. Astrophys. Suppl. Ser.139, 173–177 (1999).
10.
LammelG.SchweizerS. and RenaudP., “Microspectrometer based on a tunable optical filter of porous silicon”, Sensors and Actuators A-Physical92(1–3), 52–59 (2001).
11.
CrocombeR., “MEMS technology moves process spectroscopy into a new dimension”, Spectrosc. Europe16(3), 16–19 (2004), www.spectroscopyeurope.com/NIR_16_3.pdf.
WolffenbuttelR.F., “MEMS-based optical mini- and microspectrom-eters for the visible and infrared spectral range”, J. Micromech. Microeng.15, S145–S152 (2005).
14.
KeatingA., The optical performances of infrared micro-spectrometers based on MEMS, ICNIRS Conference, 11–15 April, Auckland, New Zealand (2005).
15.
McClureW.F., “204 years of near infrared technology: 1800–2003”, J. Near Infrared Spectrosc.11, 467–718 (2003).
16.
TaylorS.K. and McClureW.F., “NIR imaging spectroscopy: Measuring the distribution of chemical components”, in Proceedings of the Second International Near Infrared Spectroscopy Conference, Ed by IwamotoM. and KawanoS.Korin Publishing Co., Tokyo, Japan, pp. 393–404 (1990).
17.
BellonV.RabatelG. and GuizardC., “Automatic sorting of fruit: Sensors for the future”, Food Control January, 49–54 (1992).
18.
RobertP.BertrandD.DevauxM.F. and SireA., “Identification of chemical constituents by multivariate near infrared spectral imaging”, Anal. Chem.64, 664–667 (1992).
19.
ParkB.LawrenceK.C.WindhamW.R. and SmithD.P., “Detection Of Cecal Contaminants In Visceral Cavity Of Broiler Carcasses Using Hyperspectral Imaging”, Applied Engineering in Agriculture21(4), 627–635 (2005).
20.
ChenY-R. and KimS.M., “Visible NIR imaging spectroscopy for assessing quality and safety of agro-foods”, in Near Infrared Spectroscopy: Proceedings of the 11th International Conference, Ed by DaviesA.M.C. and Garrido-VaroA.NIR Publications, Chichester, pp. 67–75 (2004).
21.
GatN., “Imaging spectroscopy using tunable filters: A review”, Proceedings of SPIE (Wavelet Applications VII), Ed by SzuV. and CampbellB.), Volume 4056, pp. 50–64 (2000).
22.
TreadoP.J.LevinI.W. and LewisE.N., “Near-Infrared Acousto-optic filtered spectroscopic microscopy: A solid-state approach to chemical imaging”, Appl. Spectrosc.46(4), 553–559 (1992).
23.
NeelamG. and RachidD., “Multispectral and hyperspectral imaging with AOTF for object recognition”, Proceedings of SPIE (27th AIPR Workshop: Advances in Computer-Assisted Recognition), Ed by MericskoR.J., Volume 3584, pp. 128–135 (1999).
24.
InoueY. and PenuelaJ., Int. J. Remote Sensing22(18), 3883–3888 (2001).
25.
KhaitO.SmirnovS. and TranC.D., Appl. Spectrosc.54(12), 1734–1742 (2000).
26.
ChrienT.G.ChovitC. and MillerP.J., “Imaging spectrometer using a liquid crystal tunable filter”, Proceedings of SPIE (Imaging Spectrometry of the Terrestrial Environment), Ed by VaneG., Volume 1937, pp. 256–261 (1993).
27.
CogdillR.P.HurburghC.R.Jr and RippkeG.R., Trans. ASAE47(1), 311–320 (2004).
28.
Bellon-MaurelV.GorrettaN.RabatelG. and RogerJ.M., From multispectral to hyperspectral imaging for analysing agricultural product quality: A critical review and opportunities, ICNIRS Conference, 11–15 April, Auckland, New Zealand (2005).
29.
Perez-MartinDolores M.Garrido-VaroA.GuerreroJ.E.MurrayI.PuldgomenechA.DardenneP.BaetenV. and ZegersJ., “Detection and quantification of mammalian meat and bone meal in compound feedingstuffs using NIR”, in Near Infrared Spectroscopy: Proceedings of the 11th International Conference, Ed by DaviesA.M.C. and Garrido-VaroA.NIR Publications, Chichester, pp. 667–671 (2004).
30.
NaylorD.FultonT.R.DavisP.W.ChapmanI.M.GomB.G.SpencerL.D.LindnerJ.V.NelsonFitzpatrickN.E.TahicM.K. and DavisG.R., “Data processing pipeline for a time-sampled imaging Fourier transform spectrometer”, Proceedings of SPIE (Imaging Spectrometry X), Ed by ShenS.S. and LewisP.E., Volume 5546, pp. 61–72 (2004).
31.
BhargavaR.RibarT. and KoenigJ.L., Appl. Spectrosc.53(11), 1313–1322 (1999).
32.
LewisE.N.GorbachA.M.MarcottC. and LevinI.W., Appl. Spectrosc.50, 263–269 (1996).
33.
Burling-ClaridgeR., Hyperspectral imaging by a single detector array, employing Hadamard coding with mechanical shutters Conference, 11–15 April, Auckland, New Zealand (2005).
34.
ReichG., Adv. Drug Delivery Rev.57, 1109–1143 (2005).
