Patent Publication Number: US-2015077748-A1

Title: Spectroscopic imaging device adjusting method and spectroscopic imaging system

Description:
TECHNICAL FIELD 
     The present invention relates to a method of adjusting spectroscopic imaging device and a spectroscopic imaging system. 
     BACKGROUND ART 
     A spectroscopic imaging device includes a collimating lens that collimates input light, a diffraction grating to which light collimated by the collimating lens is inputted and which outputs the light in a different direction according to a wavelength, a condensing lens that condenses the light outputted from the diffraction grating at a different position according to the wavelength, and an array type light receiving part that receives the light condensed by the condensing lens with any of a plurality of light receiving sensors arrayed along a predetermined line. The spectroscopic imaging device can measure a spectrum of input light. 
     For instance, by measuring an absorption spectrum of a substance, the spectroscopic imaging device can analyze components of the substance. Also, by measuring a spectrum of interference fringes formed by object light and reference light, the spectroscopic imaging device can obtain the thickness of the object and a relative distance. Further, by measuring the spectrum of the interference fringes formed by the object light from a measurement object and the reference light by the spectroscopic imaging device and Fourier-transforming the interference spectrum, an FD-OCT (Fourier Domain Optical Coherence Tomography) can acquire an optical tomographic image in the depth direction of the measurement object in a noninvasive manner (See Patent Literature 1). 
     CITATION LIST 
     Patent Literature 
     
         
         Patent Literature 1: Japanese Patent Application Laid-Open No. 2011-024842 
       
    
     SUMMARY OF INVENTION 
     Technical Problem 
     In order to measure the spectrum of light with a high wavelength resolution by the spectroscopic imaging device, a condensing point of the light of respective wavelengths condensed by the condensing lens also needs to be positioned on the above-mentioned predetermined line. However, in the spectroscopic imaging device, the relative arrangement relationship among respective components sometimes varies due to an impact from the outside and loosening with time or the like. In this case, when the condensing point of the light of the respective wavelengths condensed by the condensing lens gets out of the above-mentioned predetermined line, the wavelength resolution and detection efficiency of the spectrum to be measured decline. Also, in the FD-OCT, when the condensing point of the light of the respective wavelengths condensed by the condensing lens in the spectroscopic imaging device gets out of the above-mentioned predetermined line, the intensity of the object light reflected at a long distance declines and sensitivity declines. 
     In order to solve such problems, when monochromatic light is inputted to the spectroscopic imaging device, the size of a condensing area on the plurality of light receiving sensors of the array type light receiving part is obtained, and the relative arrangement relationship of respective optical components of the spectroscopic imaging device is adjusted so as to make the condensing area small, the decline of the wavelength resolution and detection efficiency of the spectrum to be measured can be evaded. 
     However, in such an adjusting method, since the size of the condensing area on the plurality of light receiving sensors of the array type light receiving part needs to be at least about several times as large as the size of the respective light receiving sensors, it is difficult to accurately obtain the size of the condensing area under the condition. Also, when the plurality of monochromatic lights are inputted to the spectroscopic imaging device, since the respective size of the condensing area of each of the plurality of monochromatic lights in the array type light receiving part needs to be checked, the time required for adjustment becomes longer, and there is the possibility of erroneously determining noise as the condensing area. 
     The present invention has been made in order to solve the above-mentioned problems, and has an object to provide a spectroscopic imaging device adjusting method capable of easily adjusting the relative arrangement relationship among the respective components in the spectroscopic imaging device, and a spectroscopic imaging system to which such a spectroscopic imaging device adjusting method is applicable. 
     Solution to Problem 
     One aspect of the present invention relates to a spectroscopic imaging device adjusting method. The spectroscopic imaging device adjusting method is a method of adjusting a spectroscopic imaging device comprising a collimating lens which collimates input light, a diffraction grating which inputs the light collimated by the collimating lens and outputs the light in a different direction according to a wavelength, a condensing lens which condenses the light outputted from the diffraction grating at a different position according to the wavelength, and an array type light receiving part which receives the light condensed by the condensing lens with any of a plurality of light receiving sensors P 1  to P N  arrayed along a predetermined line. A relative arrangement relationship among the collimating lens, the diffraction grating, the condensing lens and the array type light receiving part is adjusted so as to maximize a value of the following expression (1) for output values ƒ n  from the respective light receiving sensors P n  when monochromatic light is inputted to the spectroscopic imaging device. Provided that n is each integer equal to or larger than 1 and equal to or smaller than N. Also, in the spectroscopic imaging device adjusting method, the full width at half maximum of the spectrum of the monochromatic light may be smaller than a wavelength resolution of the array type light receiving part. 
     
       
         
           
             
               
                 
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     Also, the spectroscopic imaging device adjusting method as another aspect of the present invention is a method of adjusting a spectroscopic imaging device comprising a collimating lens which collimates input light, a diffraction grating which inputs the light collimated by the collimating lens and outputs the light in a different direction according to a wavelength, a condensing lens which condenses the light outputted from the diffraction grating at a different position according to the wavelength, and an array type light receiving part which receives the light condensed by the condensing lens with any of a plurality of light receiving sensors P 1  to P N  arrayed along a predetermined line. A plurality of monochromatic lights λ 1  to λ M  having the full width at half maximum of the spectrum of each monochromatic light smaller than the wavelength resolution of the array type light receiving part and having the minimum value of the wavelength interval of two adjacent monochromatic lights larger than the wavelength resolution, are inputted to the spectroscopic imaging device. The plurality of light receiving sensors P 1  to P N  are divided into M groups G 1  to G M  so that a group G m  includes the light receiving sensor in a continuous range including the condensing position of the monochromatic light λ m  among the plurality of light receiving sensors P 1  to P N . The relative arrangement relationship among the collimating lens, the diffraction grating, the condensing lens and the array type light receiving part is adjusted so as to maximize the value of the following expression (2) for output values ƒ n  from the respective light receiving sensors P n . Provided that n is each integer equal to or larger than 1 and equal to or smaller than N, m is each integer equal to or larger than 1 and equal to or smaller than M. In the spectroscopic imaging device adjusting method, the minimum value of the wavelength interval of the two adjacent monochromatic lights may be at least 10 times as large as the wavelength resolution, and the wavelength bandwidth of the light received by the array type light receiving part may be at least 10 times as large as the maximum value of the wavelength interval of the two adjacent monochromatic lights. 
     
       
         
           
             
               
                 
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     The spectroscopic imaging system as yet another aspect of the present invention comprises a collimating lens which collimates input light, a diffraction grating which inputs the light collimated by the collimating lens and outputs the light in a different direction according to a wavelength, a condensing lens which condenses the light outputted from the diffraction grating at a different position according to the wavelength, an array type light receiving part which receives the light condensed by the condensing lens with any of a plurality of light receiving sensors arrayed along a predetermined line, a monochromatic light supply source arranged on an optical path of the light to be inputted to the collimating lens, the monochromatic light supply source inputting monochromatic light to the collimating lens, and adjusting means which adjusts a relative arrangement relationship among the collimating lens, the diffraction grating, the condensing lens, and the array type light receiving part. 
     In the spectroscopic imaging system, the full width at half maximum of the spectrum of the monochromatic light may be smaller than a wavelength resolution of the array type light receiving part. Also, the minimum value of the wavelength interval of the two adjacent monochromatic lights may be at least 10 times as large as the wavelength resolution of the array type light receiving part, and the wavelength bandwidth of the light received by the array type light receiving part may be at least 10 times as large as the maximum value of the wavelength interval of the two adjacent monochromatic lights. 
     Advantageous Effects of Invention 
     According to the present invention, the relative arrangement relationship among the respective components can be easily adjusted in the spectroscopic imaging device. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         FIG. 1  is a diagram illustrating a configuration of a spectroscopic imaging system  1  according to a first embodiment. 
         FIG. 2  is a chart illustrating line data outputted from an array type light receiving part  35  when monochromatic light outputted from a single wavelength light source  22  is inputted to a spectroscopic imaging device  30 . 
         FIG. 3  is a chart illustrating a relationship between a relative arrangement relationship among respective optical components in the spectroscopic imaging device  30  and a focus score. 
         FIG. 4  is a diagram illustrating a configuration of a spectroscopic imaging system  1 A which is a variation of the first embodiment. 
         FIG. 5  is a diagram illustrating a configuration of a spectroscopic imaging system  1 B which is a variation of the first embodiment. 
         FIG. 6  is a diagram illustrating a configuration of a spectroscopic imaging system  1 C which is a variation of the first embodiment. 
         FIG. 7  is a diagram illustrating a configuration of a spectroscopic imaging system  2  according to a second embodiment. 
         FIG. 8  is a chart illustrating line data outputted from the array type light receiving part  35  when the monochromatic lights with multiple wavelengths having the equal light quantity are inputted to the spectroscopic imaging device  30 . 
         FIG. 9  is a chart illustrating line data outputted from the array type light receiving part  35  when the monochromatic lights with multiple wavelengths having different light quantities are inputted to the spectroscopic imaging device  30 . 
         FIG. 10  is a diagram illustrating a configuration of a spectroscopic imaging system  2 A which is a variation of the second embodiment. 
         FIG. 11  is a diagram illustrating a configuration of a spectroscopic imaging system  2 B which is a variation of the second embodiment. 
         FIG. 12  is a diagram illustrating a configuration of a spectroscopic imaging system  2 C which is a variation of the second embodiment. 
     
    
    
     DESCRIPTION OF EMBODIMENTS 
     Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same symbol is attached to the same element in the descriptions of the drawings and redundant descriptions are omitted. 
     First Embodiment 
       FIG. 1  is a diagram illustrating a configuration of a spectroscopic imaging system  1  according to the first embodiment. The spectroscopic imaging system  1  is for acquiring an optical tomographic image of a measurement object  3  by FD-OCT, and includes a light source  10 , an interference device  11 , an irradiating unit  12 , a coupler  21 , a single wavelength light source  22 , a spectroscopic imaging device  30 , a data extracting part  41 , a tomographic image data generating part  42 , an imaging part  43 , a focus score calculating part  44 , and a position controlling part  45 . 
     The light source  10  is capable of outputting wideband continuous light. As the light source  10 , for instance, an SC light source, an ASE light source, and an SLD or the like can be suitably used. The interference device  11  is a Michelson type interferometer, inputs light outputted from the light source  10 , divides the light into two to attain measurement light and reference light, outputs the measurement light to the irradiating unit  12 , then inputs, from the irradiating unit  12 , object light which is generated in the measurement object  3  when the measurement object  3  is irradiated with the measurement light by the irradiating unit  12 , and outputs interference light by the object light and the reference light to the coupler  21 . 
     The single wavelength light source  22  outputs the monochromatic light of a single wavelength. The wavelength of the monochromatic light is the wavelength that can be detected by the spectroscopic imaging device  30 . The full width at half maximum of the spectrum of the monochromatic light is smaller than the wavelength resolution of the array type light receiving part  35  (a value for which the bandwidth of the array type light receiving part  35  is divided by the number of light receiving sensors). The coupler  21  inputs the light outputted from the interference device  11  or the monochromatic light with single wavelength outputted from the single wavelength light source  22  to the spectroscopic imaging device  30 . The coupler  21  and the single wavelength light source  22  configure a monochromatic light supply source for inputting the monochromatic light with single wavelength to the spectroscopic imaging device  30 . 
     The spectroscopic imaging device  30  measures the spectrum of the light arriving from the coupler  21 . The spectroscopic imaging device  30  includes an optical fiber  31 , a collimating lens  32 , a diffraction grating  33 , a condensing lens  34  and an array type light receiving part  35 . Also, the spectroscopic imaging device  30  includes adjusting means that adjusts the relative arrangement relationship among the collimating lens  32 , the diffraction grating  33 , the condensing lens  34 , and the array type light receiving part  35 . 
     The optical fiber  31  guides the light outputted from the coupler  21  and outputs the light from an end face. The collimating lens  32  collimates the light outputted from the end face of the optical fiber  31 . The diffraction grating  33  inputs the light collimated by the collimating lens  32  and outputs the light in a different direction according to the wavelength. The condensing lens  34  condenses the light outputted from the diffraction grating  33  at a different position according to the wavelength. The array type light receiving part  35  has a plurality of light receiving sensors arrayed at a fixed pitch along a predetermined line and receives the light condensed by the condensing lens  34 . 
     The adjusting means that adjusts the relative arrangement relationship includes means that moves the collimating lens  32 , the diffraction grating  33 , the condensing lens  34  and the array type light receiving part  35  respectively in parallel and means that changes directions of these components. In particular, the adjusting means includes means that adjusts the position of the collimating lens  32 , and means that adjusts a distance between the condensing lens  34  and the array type light receiving part  35 . As the adjusting means, a movable stage or the like is used. 
     The data extracting part  41  receives line data (a row of output data from the respective light receiving sensors) outputted from the plurality of light receiving sensors of the array type light receiving part  35 . The tomographic image data generating part  42  Fourier-transforms the line data, and acquires one-dimensional optical tomographic images in a depth direction of the measurement object  3  on the basis of the result of the Fourier transformation. The irradiating unit  12  one-dimensionally or two-dimensionally scans irradiation of the measurement light to the measurement object  3 , and the tomographic image data generating part  42  acquires the one-dimensional optical tomographic images in the depth direction of the measurement object  3  at respective irradiating positions during scanning thereof. Then, the imaging part  43  forms and displays the two-dimensional or three-dimensional optical tomographic images of the measurement object  3  by laminating the one-dimensional optical tomographic images acquired by the tomographic image data generating part  42 . 
     The focus score calculating part  44  calculates an evaluation value (focus score) indicating the excellence degree of the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , on the basis of the line data received from the array type light receiving part  35  by the data extracting part  41 . The position controlling part  45  controls the adjusting means that adjusts the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , on the basis of the focus score. 
     In this embodiment, in order to obtain the focus score and adjust the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , the monochromatic light with single wavelength outputted from the single wavelength light source  22  is inputted to the spectroscopic imaging device  30 . When the monochromatic light with single wavelength is inputted to the spectroscopic imaging device  30 , a light intensity distribution on a light receiving surface of the array type light receiving part  35  has a peak at a position according to the wavelength, and the intensity declines with distance from the position. It is assumed that each of the plurality of light receiving sensors of the array type light receiving part  35  is in a linear relationship that output data is fixed with respect to incident light intensity. 
     The line data ƒ(x) outputted from the array type light receiving part  35  is expressed by a Gaussian function in the following expression (3). A value a is a positive value and indicates the size of a condensing area on the light receiving surface of the array type light receiving part  35 . The line data outputted from the array type light receiving part  35  is actually discrete for a position x, however, is handled here as a function in which the position x is a variable. 
     [Expression 3] 
       ƒ( x )= a   1/2 exp(− ax   2 )  (3)
 
     An integrated value (called “simple sum”, hereinafter) of the line data ƒ(x) is expressed by the following expression (4a). The value of the simple sum is a fixed value regardless of the value a, and is independent of the size of the condensing area. In the meantime, the integrated value of the α-th power (called “α-th power sum”, hereinafter) of the line data ƒ(x) is expressed by the following expression (4b). When it is α&gt;1, as the value a is larger (as the condensing area is narrower), the value of the α-th power sum is larger. From this, the value of the α-th power sum is defined as the focus score, and the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  may be adjusted so as to increase the value. 
     
       
         
           
             
               
                 
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     However, the line data outputted from the array type light receiving part  35  is actually discrete for the position x. Then, the plurality of arrayed light receiving sensors of the array type light receiving part  35  are defined as P 1  to P N , the output values from the respective light receiving sensors P n  when the monochromatic light is inputted to the spectroscopic imaging device  30  are defined as ƒ n , the value of the following expression (5) is defined as the focus score, and the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  may be adjusted so as to maximize the focus score. 
     
       
         
           
             
               
                 
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     When adjusting the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , the coupler  21  does not input the light from the interference device  11  to the spectroscopic imaging device  30 , but inputs the monochromatic light from the single wavelength light source  22  to the spectroscopic imaging device  30 . The coupler  21  may be an optical switch for selecting either one of the light outputted from the interference device  11  and the monochromatic light outputted from the single wavelength light source  22  and inputting it to the spectroscopic imaging device  30 . 
       FIG. 2  is a chart illustrating the line data outputted from the array type light receiving part  35  when the monochromatic light outputted from the single wavelength light source  22  is inputted to the spectroscopic imaging device  30 . The line data has a peak at a position according to the wavelength of the monochromatic light, and the value declines with distance from the peak position. In the case A that the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  is excellent, the peak of the line data is high, and the width of the peak is narrow. On the other hand, in the case B that the relative arrangement relationship is not sufficient, the peak of the line data is low, and the width of the peak is wide. 
       FIG. 3  is a chart illustrating a relationship between the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  and the focus score. A horizontal axis indicates the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , that is, the positions and the directions of the respective optical components. In comparison with the case B that the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  is not sufficient, in the case A that the relative arrangement relationship is excellent, the focus score is high. With respect to the continuous change of the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , the shape (peak height and width) of the line data also continuously changes, and the focus score also continuously changes. 
     Therefore, when the change of the focus score is checked while adjusting the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , and the relative arrangement relationship in which the focus score becomes the maximum is obtained, the best relative arrangement relationship can be obtained. Also, the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  may be cyclically changed, the fluctuation component of the same cycle in the focus score obtained at the time may be extracted, and the relative arrangement relationship may be adjusted to minimize the component. 
       FIG. 4  to  FIG. 6  are diagrams illustrating configurations of variations of the first embodiment. In comparison with the configuration illustrated in  FIG. 1 , variations illustrated in  FIG. 4  to  FIG. 6  are different regarding the configuration of the monochromatic light supply source that inputs the monochromatic light with single wavelength to the spectroscopic imaging device  30 . 
       FIG. 4  is a diagram illustrating a configuration of a spectroscopic imaging system  1 A which is a variation of the first embodiment. In comparison with the configuration illustrated in  FIG. 1 , the spectroscopic imaging system  1 A illustrated in  FIG. 4  is the same in that the coupler  21  and the single wavelength light source  22  are provided as the monochromatic light supply source for inputting the monochromatic light with single wavelength to the spectroscopic imaging device  30 , but is different in that the coupler  21  is provided between the light source  10  and the interference device  11 . When adjusting the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , the coupler  21  does not input the light from the light source  10  to the interference device  11  but inputs the monochromatic light from the single wavelength light source  22  to the interference device  11 . The coupler  21  may be an optical switch for selecting either one of the light outputted from the light source  10  and the monochromatic light outputted from the single wavelength light source  22  and inputting it to the interference device  11 . In this variation, the light source  10  and the single wavelength light source  22  can be put together into one. 
       FIG. 5  is a diagram illustrating a configuration of a spectroscopic imaging system  1 B which is a variation of the first embodiment. In comparison with the configuration illustrated in  FIG. 1 , the spectroscopic imaging system  1 B illustrated in  FIG. 5  is different in that the coupler  21 , a divider  23  and a single wavelength transmission filter  24  are provided as the monochromatic light supply source for inputting the monochromatic light with single wavelength to the spectroscopic imaging device  30 . The divider  23  is provided between the light source  10  and the interference device  11 . The coupler  21  is provided between the interference device  11  and the spectroscopic imaging device  30 . A transmission bandwidth of the single wavelength transmission filter  24  is narrower than the wavelength resolution of the spectroscopic imaging device  30 . When adjusting the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , the light outputted from the light source  10  is introduced into the single wavelength transmission filter  24  by the divider  23 , and the monochromatic light with single wavelength transmitted through the single wavelength transmission filter  24  is inputted to the spectroscopic imaging device  30  by the coupler  21 . The coupler  21  or the divider  23  may be an optical switch. In this variation, it is not needed to provide the single wavelength light source for obtaining the focus score separately from the light source  10 . 
       FIG. 6  is a diagram illustrating a configuration of a spectroscopic imaging system  1 C which is a variation of the first embodiment. In comparison with the configuration illustrated in  FIG. 5 , the spectroscopic imaging system  1 C illustrated in  FIG. 6  is the same in that the coupler  21 , the divider  23  and the single wavelength transmission filter  24  are provided as the monochromatic light supply source for inputting the monochromatic light with single wavelength to the spectroscopic imaging device  30 , but is different in that both of the coupler  21  and the divider  23  are provided between the light source  10  and the interference device  11 . The coupler  21  or the divider  23  may be an optical switch. Also in this variation, it is not needed to provide the single wavelength light source for obtaining the focus score separately from the light source  10 . 
     Second Embodiment 
       FIG. 7  is a diagram illustrating a configuration of a spectroscopic imaging system  2  according to a second embodiment. The spectroscopic imaging system  2  is for acquiring an optical tomographic image of a measurement object by FD-OCT, and includes the light source  10 , the interference device  11 , the irradiating unit  12 , the coupler  21 , a multiplexer  25 , single wavelength light sources  26   1  to  26   M , the spectroscopic imaging device  30 , the data extracting part  41 , the tomographic image data generating part  42 , the imaging part  43 , the focus score calculating part  44 , and the position controlling part  45 . 
     In comparison with the configuration of the first embodiment illustrated in  FIG. 1 , the spectroscopic imaging system  2  illustrated in  FIG. 7  is different in that the coupler  21 , the multiplexer  25  and the plurality of single wavelength light sources  26   1  to  26   M  are provided as the monochromatic light supply source that inputs the monochromatic light to the spectroscopic imaging device  30 . 
     Each single wavelength light source  26   m  outputs the monochromatic light with a center wavelength λ m . The wavelengths λ 1  to λ M  are the wavelengths that can be detected by the spectroscopic imaging device  30 , and are different from each other. The full width at half maximum of the spectrum of each monochromatic light is smaller than the wavelength resolution of the array type light receiving part  35 . The minimum value of the wavelength interval of the two adjacent monochromatic lights is larger than the wavelength resolution of the array type light receiving part  35 . It is suitable that the minimum value of the wavelength interval of the two adjacent monochromatic lights is at least 10 times as large as the wavelength resolution of the array type light receiving part  35 , and it is suitable that the wavelength bandwidth of the light received by the array type light receiving part  35  is at least 10 times as large as the maximum value of the wavelength interval of the two adjacent monochromatic lights. 
     The multiplexer  25  multiplexes the monochromatic lights with the wavelengths λ 1  to λ M  outputted from the plurality of single wavelength light sources  26   1  to  26   M  and outputs the multiplexed light to the coupler  21 . The coupler  21  inputs the light outputted from the interference device  11  or the monochromatic lights with multiple wavelengths outputted from the multiplexer  25  to the spectroscopic imaging device  30 . 
     In this embodiment, in order to obtain the focus score and adjust the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , the monochromatic lights with the wavelengths λ 1  to λ M  outputted from the plurality of single wavelength light sources  26   1  to  26   M  are multiplexed and inputted to the spectroscopic imaging device  30 . When the monochromatic lights with the multiple wavelengths are inputted to the spectroscopic imaging device  30 , a light intensity distribution on a light receiving surface of the array type light receiving part  35  has a peak at a position according to each wavelength, and the intensity declines with distance from the position. 
     When the light quantities of the monochromatic lights outputted from the plurality of single wavelength light sources  26   1  to  26   M  are fixed, the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  can be adjusted on the basis of the focus score similar to that in the first embodiment. When the light quantities of the monochromatic lights outputted from the plurality of single wavelength light sources  26   1  to  26   M  are not fixed, the relative arrangement relationship is adjusted as follows. 
     The line data outputted from the array type light receiving part  35  is expressed by the sum of a Gaussian function ƒ m (x) in the following expression (6). The Gaussian function ƒ m (x) expresses the line data to be outputted from the array type light receiving part  35  when only the monochromatic light with the wavelength λ m  outputted from the single wavelength light source  26   m  is inputted to the spectroscopic imaging device  30 . A value A m  indicates the light quantity of the monochromatic light with the wavelength λ m , a value a m  indicates the size of the condensing area of the monochromatic light with the wavelength λ m , and a value x 0m , indicates a peak position in the condensing area of the monochromatic light with the wavelength λ m . 
       [Expression 6] 
       ƒ m ( x )= A   m   a   m   1/2 exp(− a   m ( x−x   0m ) 2 )  (6)
 
     The simple sum is expressed by the following expression (7a). The value of the simple sum is a fixed value regardless of the value a m , and is independent of the size of the condensing area. In the meantime, the α-th power sum is expressed by the following expression (7b). When it is α&gt;1, as the value a m  is larger (as the condensing area is narrower), the value of the α-th power sum is larger. However, for the value of the α-th power sum, contribution of the monochromatic light with the wavelength λ m  having a large light quantity A m  is great. 
     
       
         
           
             
               
                 
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     Then, in this embodiment, the plurality of light receiving sensors P 1  to P N  are divided into M groups G 1  to G M  so that a group G m  includes the light receiving sensor in a continuous range including the condensing position of the monochromatic light λ m  among the plurality of light receiving sensors P 1  to P N  of the array type light receiving part  35 . Each group G m  includes the light receiving sensor at the condensing position of the monochromatic light λ m , and the light receiving sensor in the vicinity of the light receiving sensor. Then, the ratio of the value of the α-th power of the simple sum and the α-th power sum (the following expression (8)) in each group G m  is obtained, and the total sum of the ratio (the following expression (9)) is defined as a focus score. The focus score is independent of the light quantity A m  of each monochromatic light λ m . The relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  may be adjusted so as to maximize the focus score. 
     
       
         
           
             
               
                 
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     However, the line data outputted from the array type light receiving part  35  is actually discrete for the position x. Then, the plurality of arrayed light receiving sensors of the array type light receiving part  35  are defined as P 1  to P N , the output values from the respective light receiving sensors P n  when the monochromatic lights with multiple wavelengths λ 1  to λ M  are inputted to the spectroscopic imaging device  30  are defined as ƒ n , the value of the following expression (10) is defined as the focus score, and the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  may be adjusted so as to maximize the focus score. 
     
       
         
           
             
               
                 
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     When adjusting the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , the coupler  21  does not input the light from the interference device  11  to the spectroscopic imaging device  30 , but inputs the monochromatic lights with multiple wavelengths from the multiplexer  25  to the spectroscopic imaging device  30 . The coupler  21  may be an optical switch that selects either one of the light outputted from the interference device  11  and the monochromatic lights with multiple wavelengths outputted from the multiplexer  25  and inputs it to the spectroscopic imaging device  30 . 
       FIG. 8  is a chart illustrating the line data outputted from the array type light receiving part  35  when the monochromatic lights with multiple wavelengths having the equal light quantity are inputted to the spectroscopic imaging device  30 . The line data has a peak at a position according to each wavelength of the monochromatic light, and the value declines with distance from the peak position. In the case A that the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  is excellent, all the peaks of the line data are high, and the widths of all the peaks are narrow. On the other hand, in the case B that the relative arrangement relationship is not sufficient, one of the peaks of the line data is low, and the width of one of the peaks is wide. When the light quantities of the monochromatic lights with multiple wavelengths are equal, the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  can be adjusted on the basis of the focus score similar to that in the first embodiment. 
       FIG. 9  is a chart illustrating the line data outputted from the array type light receiving part  35  when the monochromatic light of the multiple wavelengths having different light quantities are inputted to the spectroscopic imaging device  30 . A state like this may occur when there is a difference in the output intensities of the monochromatic lights with respective wavelengths, or when the loss of a route is different depending on the wavelength. In the case of the state like this, the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30  can be adjusted on the basis of the focus score in the above-mentioned expression (10). 
       FIG. 10  to  FIG. 12  are diagrams illustrating configurations of variations of the second embodiment. In comparison with the configuration illustrated in  FIG. 7 , variations illustrated in  FIG. 10  to  FIG. 12  are different regarding the configuration of the monochromatic light supply source that inputs the monochromatic lights with multiple wavelengths to the spectroscopic imaging device  30 . 
       FIG. 10  is a diagram illustrating a configuration of a spectroscopic imaging system  2 A which is a variation of the second embodiment. In comparison with the configuration illustrated in  FIG. 7 , the spectroscopic imaging system  2 A illustrated in  FIG. 10  is the same in that the coupler  21 , the multiplexer  25  and the single wavelength light sources  26   1  to  26   M  are provided as the monochromatic light supply source that inputs the monochromatic lights with multiple wavelengths to the spectroscopic imaging device  30 , but is different in that the coupler  21  is provided between the light source  10  and the interference device  11 . When adjusting the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , the coupler  21  does not input the light from the light source  10  to the interference device  11 , but inputs the monochromatic lights with multiple wavelengths from the multiplexer  25  to the interference device  11 . The coupler  21  may be an optical switch that selects either one of the light outputted from the light source  10  and the monochromatic lights with multiple wavelengths outputted from the multiplexer  25  and inputs it to the interference device  11 . In this variation, the light source  10  and the single wavelength light sources  26   1  to  26   M  can be put together into one. 
       FIG. 11  is a diagram illustrating a configuration of a spectroscopic imaging system  2 B which is a variation of the second embodiment. In comparison with the configuration illustrated in  FIG. 7 , the spectroscopic imaging system  2 B illustrated in  FIG. 11  is different in that the coupler  21 , a divider  23  and a multiple wavelength transmission filter  26  are provided as the monochromatic light supply source that inputs the monochromatic lights with multiple wavelengths to the spectroscopic imaging device  30 . The divider  23  is provided between the light source  10  and the interference device  11 . The coupler  21  is provided between the interference device  11  and the spectroscopic imaging device  30 . The multiple wavelength transmission filter  26  is capable of transmitting the discrete light of the multiple wavelengths, and is an etalon filter for instance. The respective transmission bandwidths of the multiple wavelength transmission filter  26  are narrower than the wavelength resolution of the spectroscopic imaging device  30 . When adjusting the relative arrangement relationship among the respective optical components in the spectroscopic imaging device  30 , the light outputted from the light source  10  is introduced into the multiple wavelength transmission filter  26  by the divider  23 , and the monochromatic lights with multiple wavelengths transmitted through the multiple wavelength transmission filter  26  are inputted to the spectroscopic imaging device  30  by the coupler  21 . The coupler  21  or the divider  23  may be an optical switch. In this variation, it is not needed to provide a plurality of single wavelength light sources for obtaining the focus score separately from the light source  10 . 
       FIG. 12  is a diagram illustrating a configuration of a spectroscopic imaging system  2 C which is a variation of the second embodiment. In comparison with the configuration illustrated in  FIG. 11 , the spectroscopic imaging system  2 C illustrated in  FIG. 12  is the same in that the coupler  21 , the divider  23  and the multiple wavelength transmission filter  26  are provided as the monochromatic light supply source that inputs the monochromatic light of the multiple wavelengths to the spectroscopic imaging device  30 , but is different in that both of the coupler  21  and the divider  23  are provided between the light source  10  and the interference device  11 . The coupler  21  or the divider  23  may be an optical switch. Also in this variation, it is not needed to provide the single wavelength light source for obtaining the focus score separately from the light source  10 . 
     INDUSTRIAL APPLICABILITY 
     According to the present invention, the relative arrangement relationship among the respective components in a spectroscopic imaging device can be easily adjusted. 
     REFERENCE SIGNS LIST 
       1 ,  1 A,  1 B,  1 C,  2 ,  2 A,  2 B,  2 C . . . Spectroscopic imaging system,  3  . . . Measurement object,  10  . . . Light source,  11  . . . Interference device,  12  . . . Irradiating unit,  21  . . . Coupler,  22  . . . Single wavelength light source,  23  . . . Divider,  24  . . . Single wavelength transmission filter,  25  . . . Multiplexer,  26   1  to  26   M  . . . Single wavelength light source,  27  . . . Multiple wavelength transmission filter,  30  . . . Spectroscopic imaging device,  31  . . . Optical fiber,  32  . . . Collimating lens,  33  . . . Diffraction grating,  34  . . . Condensing lens,  35  . . . Array type light receiving part,  41  . . . Data extracting part,  42  . . . Tomographic image data generating part,  43  . . . Imaging part,  44  . . . Focus score calculating part,  45  . . . Position controlling part.