High resolution ultraviolet imaging spectrometer for latent image analysis.

In this work, we present a close-range ultraviolet imaging spectrometer with high spatial resolution, and reasonably high spectral resolution. As the transmissive optical components cause chromatic aberration in the ultraviolet (UV) spectral range, an all-reflective imaging scheme is introduced to promote the image quality. The proposed instrument consists of an oscillating mirror, a Cassegrain objective, a Michelson structure, an Offner relay, and a UV enhanced CCD. The finished spectrometer has a spatial resolution of 29.30μm on the target plane; the spectral scope covers both near and middle UV band; and can obtain approximately 100 wavelength samples over the range of 240~370nm. The control computer coordinates all the components of the instrument and enables capturing a series of images, which can be reconstructed into an interferogram datacube. The datacube can be converted into a spectrum datacube, which contains spectral information of each pixel with many wavelength samples. A spectral calibration is carried out by using a high pressure mercury discharge lamp. A test run demonstrated that this interferometric configuration can obtain high resolution spectrum datacube. The pattern recognition algorithm is introduced to analyze the datacube and distinguish the latent traces from the base materials. This design is particularly good at identifying the latent traces in the application field of forensic imaging.

[1]  A. Barducci,et al.  Theoretical aspects of Fourier Transform Spectrometry and common path triangular interferometers. , 2010, Optics express.

[2]  Gregory Brown,et al.  Detection of explosives by differential hyperspectral imaging , 2014 .

[3]  K. Savage,et al.  Hyperspectral imaging of gel pen inks: an emerging tool in document analysis. , 2014, Science & justice : journal of the Forensic Science Society.

[4]  Richard F. Horton,et al.  Optical design for a high-etendue imaging Fourier-transform spectrometer , 1996, Optics & Photonics.

[5]  Keith T. Knox,et al.  Enhancement of overwritten text in the Archimedes Palimpsest , 2008, Electronic Imaging.

[6]  Wayne B. Bosma,et al.  Demonstration of Thermodynamics and Kinetics Using FriXion Erasable Pens. , 2012 .

[7]  C J Sansonetti,et al.  Wavelengths of spectral lines in mercury pencil lamps. , 1996, Applied optics.

[8]  Edelman 6-VISUALIZATION OF LATENT BLOOD STAINS USING VISIBLE REFLECTANCE HYPERSPECTRAL IMAGING AND CHEMOMETRICS , 2014 .

[9]  Claus Vielhauer,et al.  Capturing latent fingerprints from metallic painted surfaces using UV-VIS spectroscope , 2015, Electronic Imaging.

[10]  R. K. Chan,et al.  Toward a UV-visible-near-infrared hyperspectral imaging platform for fast multiplex reflection spectroscopy. , 2010, Optics letters.

[11]  L. Rabiner,et al.  The chirp z-transform algorithm and its application , 1969 .

[12]  Fenella G. France Advanced Spectral Imaging for Noninvasive Microanalysis of Cultural Heritage Materials: Review of Application to Documents in the U.S. Library of Congress , 2011, Applied spectroscopy.

[13]  Roger L. Easton,et al.  Text recovery from the ultraviolet-fluorescent spectrum for treatises of the Archimedes Palimpsest , 2010, Electronic Imaging.