Abstract:
A spectroscopic identification method and system are provided that uses the primary or main spectroscopic features of a source, such as those as arising from chemical functional groups, to describe and distinguish the source. These primary spectroscopic features make up a portion (i.e., are a subset) of the entire spectroscopic data for a particular source but can nevertheless be used as the basis of separating spectra from multiple source. When analyzing spectroscopic data obtained from a sample for one or more sources, the analysis first focuses on the primary spectroscopic features for a source rather than the entire spectra for a source.

Description:
BACKGROUND OF THE INVENTION 
   The present invention is directed to spectroscopic analysis and more particularly to a technique to improve the accuracy of spectroscopic analysis. 
   Spectroscopy is a well known technique to analyze the spectral properties associated with a source, such as a substance or object/scene being imaged, in order to identify compounds in the substance or particular objects in the scene. For example, spectroscopic techniques are used in Raman scattering techniques whereby a sample is illuminated with light and the spectrum of the scattered energy from the substance is analyzed to identify a specific substance as being present in the sample. High correlation between spectra of different substances, spectral clutter, and noise limit the sensitivity (i.e., decrease the probability of correct detection and identification) and specificity (i.e., increase false alarm rate) for many currently available spectroscopic techniques. 
   What is needed is a spectroscopic detection technique and system that is more accurate than techniques heretofore known. 
   SUMMARY OF THE INVENTION 
   Briefly, the present invention is directed a spectroscopic featured-based detection or identification system and method. The present invention uses the primary or main spectroscopic features of a source, such as those as arising from chemical functional groups, to describe and distinguish the source. These primary spectroscopic features make up a portion (i.e., are a subset) of the entire spectroscopic data for a particular source but can nevertheless be used as the basis of separating spectra from multiple sources. Thus, when analyzing spectroscopic data obtained from a sample for one or more sources, the analysis first focuses on the primary spectroscopic features for a source rather than the entire spectra for a source. This techniques reduces the correlation between sources of interest and other sources and makes it easier for an identifier to achieve optimum performance (i.e., reduced false alarms and maximum detections). 
   Thus, according to the present invention a method is provided for analyzing spectroscopic data to separate spectral data for at least one source from the spectroscopic data. The primary spectral features of the spectroscopic data for one or more sources of interest are identified and data is stored for the primary spectral features of the at least one source. Then, spectroscopic data is obtained from a sample and is first analyzed with the stored data for the primary spectral features to eliminate from consideration a source whose primary spectral features are not present in the spectroscopic data for the sample. The spectroscopic data for the sample is further analyzed using knowledge of one or more sources that are eliminated by the first analysis, in order to identify one or more sources present in the sample. The source may be a substance of interest, such as a chemical or biological agent, or may be a particular object of interest in an imaged scene. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a diagram showing primary and secondary spectral features associated with a source according to an embodiment of the present invention. 
       FIG. 2  is a flow chart illustrating a primary spectral feature determination process according to an embodiment of the present invention. 
       FIG. 3  is a diagram pictorially representing the feature determination process shown in  FIG. 2 . 
       FIG. 4  is a flow chart illustrating a spectral feature-based identification algorithm according to an embodiment of the present invention using data collected from the spectral feature determination process depicted in  FIGS. 2 and 3 . 
       FIG. 5  is a diagram pictorially representing the spectral feature-based identification algorithm shown in  FIG. 4 . 
       FIG. 6  is a block diagram of a spectral feature-based identification system according to an embodiment of the present invention. 
   

   DETAILED DESCRIPTION 
   The present invention is directed to improving the accuracy of spectroscopic analysis techniques, such as used in techniques for spectroscopic-based substance detection or spectroscopic-based imagery by introducing an analysis step that eliminates sources whose primary or main spectral features are not present in the sample spectroscopic data. Thus, the term source is used herein to include, without limitation a substance that has a spectral signature, as well as an object that has a spectral signature when a spectral imagery is employed. Examples of substances are chemical, biological or other compounds, in solid, liquid or gas form. For example, a substance of interest may be an agent of chemical and/or biological makeup that is harmful to humans, and thus whose presence is desired to be detected. Examples of objects of interest are military vehicles hidden under trees detected through sub-pixel processing of their spectral data to identify the presence of material the vehicles are made of. 
   Referring first to  FIG. 1 , a plot of the spectrum (also called spectroscopic data) associated with a particular source is shown. The spectrum is obtained using any conventional spectroscopy apparatus or system.  FIG. 1  shows that the plot of the spectrum for the source has different characteristics or shapes. For example, at the higher pixels (wavenumbers), there are three relatively sharp and strong spikes. The portion of the spectrum for this exemplary source that contains these three spikes may be designated the main or primary (distinctive) spectral features at reference numeral  10  for this particular source. By contrast, the portions of the spectrum for this agent that reside at lower wavenumbers (or pixels) may be designated the secondary spectral features at reference numeral  20  because they do not distinguish the source from the spectrum of other sources as well as the primary spectral features. Thus, as shown in  FIG. 1 , the spectroscopic data corresponding to the primary spectral features for a source are a subset of the entire spectroscopic data for the source. 
   Turning to  FIGS. 2 and 3 , a spectral feature determination process according to an embodiment of the present invention is described. The spectral feature determination process, shown at  100 , involves analyzing the spectroscopic data for a source to determine or identify the one or more features of the spectral data for the source that distinguish it from other sources. For example, in the case where the source is a substance, it is known that there are spectroscopic features of a substance that arise from the constituent chemical functional groups of the substance. These features, once identified or determined, may be used to simplify and improve the accuracy of spectroscopic basis identification techniques. Specifically, by focusing on the primary spectral features for a source rather than entire spectra for the source reduces the correlation between sources of interest and other sources and makes the process more accurate by reducing false detections. 
   Thus, in the spectral feature determination process  100 , the spectroscopic data for a source of interest is captured at  110  (e.g., from stored spectroscopic data for that source), where the spectroscopic data may have been obtained in a laboratory or field environment at some prior point in time. At  120 , the spectroscopic data for the source is analyzed to determine its main or primary spectral features. This may involve examining the shapes, location of spikes, height of spikes, etc., as compared with the spectral data for other sources. Features are determined through means such as correlation analysis (in order to determine the most prominent features for a given agent) or functional group analysis which consists of inspecting the primary chemical bonds between atoms forming a molecule. At  130 , data is stored to represent the primary spectral features determined at  120 , such as in a database shown at reference numeral  200  shown in  FIG. 3 . As shown at  140 , this process is repeated from each of a plurality of sources of interest. 
   Turning to  FIGS. 4 and 5 , a spectroscopic feature-based identification process shown at reference numeral  300  is now described. The process  300  uses the spectral feature data determined in process  200  for one or more substances of interest. At  310 , the spectroscopic data is captured for a sample to be analyzed. The sample may consist of a solid, liquid or gas substance, including airborne substances as well as substance on surfaces, or a scene that is imaged using spectral imagery techniques. As  320 , the spectroscopic data for the sample is analyzed against the library spectra for the presence of the primary spectral features.  FIG. 5  shows the boxes for portions of the library spectra that correspond to the primary spectral features for exemplary sources contained in the library spectra.  FIG. 5  also shows how the relevant library spectra can be reduced or simplified by eliminating from further consideration the sources whose primary features are not present in the sample spectroscopic data. Thus, the first analysis performed at  320  eliminates the library spectra for the one or more sources whose primary spectral features are not present in the spectroscopic data. 
   At  330 , a second analysis is performed of the spectroscopic data for the remaining possible features, thereby more closely analyzing the spectroscopic data against the reduced library spectra.  FIG. 5  shows the reduced library spectra where some of the sources are eliminated because their primary features were determined at  320  not to be present in the sample spectroscopic data. Thus, the second analysis allows for detecting the presence of one more sources that were not eliminated based on the primary spectral feature analysis at  320 . Thus, the identify of sources in the sample can be determined with greater accuracy. 
     FIG. 6  illustrates a block diagram of a spectroscopic detection system  400 . The system  400  comprises a computer or processor  410 , a spectroscopic detector  420  and a database  430  containing library spectra data including the primary spectral feature data obtained by the spectral feature determination process  200 . As is known in the art, there may be a light source that is directed onto the sample in order to excite the desired type scattering that is detected by the detector  420 . The computer  410  operates on computer software that performs the computations associated with the feature-based identification algorithm  300  depicted in  FIGS. 4 and 5 . 
   The spectroscopic techniques described herein may be used in any source-separation process for any type of data, including multispectral and hyperspectral imagery for military and non-military applications. 
   The system and methods described herein may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The foregoing embodiments are therefore to be considered in all respects illustrative and not meant to be limiting.