Method for improved automatic partial color constancy correction
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06K-009/00
G06K-009/36
출원번호
US-0953205
(2001-09-17)
§371/§102 date
20000911
(20000911)
발명자
/ 주소
Spitzer, Hedva
출원인 / 주소
Ramot At Tel Aviv University Ltd.
대리인 / 주소
G.E. Ehrlich (1995) Ltd.
인용정보
피인용 횟수 :
12인용 특허 :
5
초록▼
A method for providing partial color constancy of a stimulus represented by an array of picture elements each represented by a color spectrum. The method comprising: (a) assigning to each picture element in the array, for each color, a color value, thereby to provide a plurality of pre-processed sin
A method for providing partial color constancy of a stimulus represented by an array of picture elements each represented by a color spectrum. The method comprising: (a) assigning to each picture element in the array, for each color, a color value, thereby to provide a plurality of pre-processed single color images each respectively arranged as a series of pre-processed color values one at each picture element; (b) for each picture element, defining at least two regions of picture elements; (c) at each picture element, adapting each one of the pre-processed color values using pre-processed color values from at least one of the two regions of picture elements, thereby to form, at each picture element, a set of center response values; and (d) at each picture element, transforming the set of center response values into a set of center corrected color values, using response values from the two regions of picture elements to provide a plurality of processed single color images having partial color constancy.
대표청구항▼
1. A method for providing partial color constancy of a stimulus represented by an array of picture elements each represented by a color spectrum the method comprising:assigning to each picture element in the array, for each color, a color value, thereby to provide a plurality of pre-processed single
1. A method for providing partial color constancy of a stimulus represented by an array of picture elements each represented by a color spectrum the method comprising:assigning to each picture element in the array, for each color, a color value, thereby to provide a plurality of pre-processed single color images each respectively arranged as a series of pre-processed color values one at each picture element; for each picture element, defining at least two regions of picture elements; at each picture element, adapting each one of said pre-processed color values using pre-processed color values from at least one of said two regions of picture elements, thereby to form, at each picture element, a set of center response values; and at each picture element, transforming said set of center response values into a set of center corrected color values, using response values from said two regions of picture elements to provide a plurality of processed single color images having partial color constancy. 2. The method of claim 1, wherein said at least two regions of picture element comprise a first region of nearby picture elements and a second region of remote picture elements.3. The method of claim 2, wherein said plurality of single color images comprises a red single color image, a green single color image and a blue single color image.4. The method of claim 3, wherein said step of assigning to each picture element in the array, for each color, a color value, comprises resolving an overall colors spectrum with respect to the wavelength of each of said plurality of colors at each picture element.5. The method of claim 3, wherein said adapting comprises using said second region for transforming each said pre-processed color value to a center remote value and combining said pre-processed color value with said center remote value.6. The method of claim 5, further comprising using said first region for transforming each said pre-processed color value to a center surround value and combining said pre-processed color value with said center surround value.7. The method of claim 3, wherein said transforming said center response values comprises combining at each picture element, at least two center response values.8. The method of claim 3, wherein said array of picture elements comprises a two-dimensional rectangular grid of picture elements.9. The method of claim 8, wherein said resolving comprises(a) at each picture element, multiplying the color spectrum by a response function of a red photoreceptor, to provide a red product, and integrating said red product, thereby providing a red pre-processed image; (b) at each picture element, multiplying said color spectrum by a response function of a green photoreceptor, to provide a green product, and integrating said green product, thereby providing a green pre-processed image; and (c) at each picture element, multiplying said color spectrum by a response function of a blue photoreceptor, to provide a blue product and integrating said blue product, thereby providing a blue pre-processed image; thereby providing at each picture element, a pre-processed red value, a pre-processed green value and a pre-processed blue value.10. The method of claim 8, wherein said adapting each one of said color values comprises, for each picture element: for each said single color pre-processed image:transforming said pre-processed image to a center remote image; and combining said pre-processed image with said center remote image thereby providing at each picture element, a red center response value, Rr, a green center response value, Rg and a blue center response value, Rb. 11. The method of claim 10, wherein said step of transforming comprises:(a) convoluting said pre-processed image with a center local spatial filter, thereby producing a center convoluted image constituting a center processed function, Gc; (b) convoluting said center convoluted image with a center remote spatial filter, thereby producing a center remote adaptation term, σc,r; (c) selecting a third center parameter cc and multiplying said center remote adaptation term σc,r by said third center parameter cc. 12. The method of claim 11, wherein said center local spatial filter is a spatial decaying filter.13. The method of claim 12, wherein said decaying is Gaussian decaying.14. The method of claim 12, wherein said decaying is exponential decaying.15. The method of claim 11, wherein said center remote spatial filter is a spatial decaying filter.16. The method of claim 15, wherein said decaying is Gaussian decaying.17. The method of claim 15, wherein said decaying is exponential decaying.18. The method of claim 11, wherein said step (a) is preceded by the step of replacing each pre-processed color value, p, with p/(p+p0), where said p0 is a constant.19. The method of claim 11, wherein said step (a) is preceded by the step of replacing each pre-processed color value, p, with pn/(pn+p0), where said p0 is a constant, and where said n is a curvature constant.20. The method of claim 10, wherein said step of combining comprises:(a) selecting a first center parameter ac; (b) selecting a second center parameter bc; (c) setting a center local adaptation term, σc,l, equal to (ac?1) Gc,b+bc where Gc,b is a center adaptive function; (d) for each picture element, setting said center response value equal to Gc/(Gc+σc,l+σc,r). 21. The method of claim 20, wherein said center adaptive function is identical to said center processed function.22. The method of claim 20, further comprising for each picture element and for each time, t: setting said center adaptive function equal to a time-convolution of a center adaptive low-pass temporal filter with said center processed function.23. The method of claim 22, wherein said center adaptive low-pass temporal filter is equal to exp[(t′?t)/τc]/τc,b, where said t′ is a variable of said time-convolution, where said τc is a center low-pass temporal filter time constant and where said τc,b is a center decay time function.24. The method of claim 23, wherein said center decay time function isτc,b=τc,m/(1+|Gc,b?Gc|/Gc,n), where said τc,m is an expected maximum value of said center decay time function, and where said Gc,n is a normalization constant.25. The method of claim 22, wherein said center decay time function is a center decay time constant.26. The method of claim 8, wherein said adapting each one of said color values comprises, for each picture element:for said red pre-processed image and said green pre-processed image transforming said pre-processed image to a surround remote image; and for said red pre-processed image and said green pre-processed image combining said pre-processed image with said surround remote image to provide a surround response value, Rs; thereby providing at each picture element, a red surround response value and a green surround response value.27. The method of claim 26, further comprising for each picture element:subtracting said green surround response value from said red center response value; subtracting said red surround response value from said green surround response value; combining said red surround response value and said green surround response value, thereby providing a yellow surround response value; and subtracting said yellow surround response value from said blue center response value. 28. The method of claim 27, wherein said step of combining said red surround response value and said green surround response value comprises averaging said red surround response value and said green surround response value.29. The method of claim 26, wherein said step of transforming comprises:(a) convoluting said preprocessed image with a surround local spatial filter, thereby producing a surround convoluted image constituting a surround processed function, Gs; (b) convoluting said surround convoluted image with a surround remote spatial filter, thereby producing a surround remote adaptation term, σs,r; (c) selecting a third surround parameter cs and multiplying said surround remote adaptation term by said third surround parameter cs. 30. The method of claim 29, wherein said surround local spatial filter is a spatial decaying filter.31. The method of claim 30, wherein said decaying is Gaussian decaying.32. The method of claim 30, wherein said decaying is exponential decaying.33. The method of claim 29, wherein said surround remote spatial filter is a spatial decaying filter.34. The method of claim 33, wherein said decaying is exponential decaying.35. The method of claim 29, wherein said decaying is Gaussian decaying.36. The method of claim 29, wherein said step (a) is preceded by the step of replacing each color value, p, with p/(p+p0), where said p0 is a constant.37. The method of claim 29, wherein said step (a) is preceded by the step of replacing each color value, p, with pn/(pn+p0), where said p0 is a constant, and where said n is a curvature constant.38. The method of claim 26, wherein said step of combining comprises:(a) selecting a first surround parameter as; (b) selecting a second surround parameter bs; (c) setting a surround local adaptation term, σs,l, equal to (as?1) Gs,b+bs, where Gs,b is a surround adaptive function; and (d) setting said surround response value equal to Gs/(Gs+σs,l+σs,r). 39. The method of claim 38, wherein said surround adaptive function is identical to said surround processed function.40. The method of claim 38, further comprising for each picture element and for each time, t: setting said surround adaptive function equal to a time-convolution of a surround adaptive low-pass temporal filter with said surround processed function.41. The method of claim 40, wherein said surround decay time function is a surround decay time constant.42. The method of claim 40, wherein said surround adaptive low-pass temporal filter is equal to exp[(t′?t)/τs]/τs,b, where said t′ is a variable of said time-convolution, where said τs is a surround low-pass temporal filter time constant and where said τs,b is a surround decay time function.43. The method of claim 42, wherein said surround decay time function isτs,b=τs,m/(1+|Gs,b?Gs|/Gs,n), where said τs,m is an expected maximum value of said surround decay time function, and where said Gs,n is a normalization constant.44. The method of claim 8, wherein said step of transforming said set of center response values into a set of center corrected color values comprises,(a) obtaining a remote picture element luminosity Yr; (b) selecting a ratio coefficient CSR; (c) selecting a set of region parameters ac, as, bc, bs, cc and cs; (d) using said ratio coefficient, said remote picture element luminosity and said center response values for setting a set of eleven variables, δ and zj, where said j is an integer-valued index ranging between 1 and 10; and (e) using said set of eleven variables, for assigning a set of center corrected color values. 45. The method of claim 44, wherein said step (a) comprises:(i) at each said picture element of said remote region of picture elements, multiplying said set of center response values by an XYZ transformation matrix, thereby providing a transformed XYZ vector, said transformed XYZ vector comprising a first component, a second component and a third component; and (ii) setting the value of said remote picture element luminosity equal to the sum of all said second components of said transformed XYZ vectors of said remote region of picture elements. 46. The method of claim 44, comprising settingsaid z1 equal to bc+ccYr, said z2 equal to bc+csYr, said z3 equal to (as?ac?Rracas)CSR, said z4 equal to (as?ac?Rgacas)CSR/z3, said z5 equal to z2(1?Rrac), said z6 equal to ?z1(1+Rras)CSR, said z7 equal to ?Rrz1z2, said z8 equal to ?z1(1+Rgas)CSR?z4z5, said z9 equal to (z4z6?z2(1?Rgac))/z8, said z10 equal to (z4z7+Rgz1z2)/zs, and said δ equal to as+(2/CSR)z2/(Rt,g+Rt,r). 47. The method of claim 46, wherein said step (e) comprises setting a center corrected green value, Rt,g, equal to:?z3z10?z5z9?z6+√((z3z10+z5z9+z6)2?4z3z9(z5z10+z7)), setting a center corrected red value, Rt,r, equal to:z9Rt,g+z10, and setting a center corrected blue value, Rt,b, equal to:z1/((Rb+1/δ)?1?ac). 48. The method of claim 44, further comprising the step of replacing each center corrected color value, Rt, with Rt,0Rt/(1?Rt), where said Rt,0 is a constant, thereby producing a pigment RGB response.49. The method of claim 48, further comprising transforming said pigment RGB response {right arrow over (R)} into a transformed color scale {right arrow over (X)}, using a transformation.50. The method of claim 48, wherein said transformed color scale is an XYZ color scale.51. The method of claim 50, wherein said transformation matrix is equal to 52. The method of claim 44, further comprising the step of replacing each center corrected color value, Rt, with (Rt,0Rt/(1?Rt))1/n, where said Rt,0 is a constant, and where n is a curvature constant, thereby producing a pigment ROB response.53. The method of claim 1, wherein said picture element comprises at least one pixel.54. A color constancy apparatus for providing partial color constancy of a stimulus arranged gridwise in a plurality of picture elements, each represented by a color spectrum resolvable into a plurality of individual colors over said grid, the apparatus comprising:an imager for resolving the spectrum into a plurality of pre-processed single color images each respectively arranged as a series of pre-processed color values one at each picture element; a corrector for partially correcting each of said pre-processed color values at each picture element by adapting each of said pre-processed color values into a center response value, using said pre-processed color values of picture elements from at least two regions of picture elements; and a transforming unit for transforming each of said center response values into a center corrected color value, using response values of picture elements from said two regions of picture elements, thereby to provide a processed image having partial color constancy. 55. The color constancy apparatus according to claim 54, further comprising a saturator connected between said imager and said corrector for substitution of each said pre-processed color value of each said pre-processed single color image with a new pre-processed color value.56. The color constancy apparatus according to claim 54, wherein said imager comprises electronic-calculating functionality for sorting said color spectrum with respect to the wavelength of each color at each picture element.57. The color constancy apparatus according to claim 54, wherein said transforming unit comprises electronic-calculating functionality for combining at each picture element, at least two center response values.58. The color constancy apparatus according to claim 54, wherein said picture element comprises at least one pixel.59. The color constancy apparatus according to claim 54, wherein said plurality of pre-processed single color images are a red image, a green image and a blue image.60. The color constancy apparatus according to claim 54, wherein said at least two regions of picture element comprise a first region of nearby picture elements and a second region of remote picture elements.61. The color constancy apparatus according to claim 60, wherein said imager comprises electronic-calculating functionality for integrating the multiplication of the color spectrum of each picture element with a response function.62. The color constancy apparatus according to claim 60, wherein said response function is selected from a group consisting of a response function of a red photoreceptor, a response function of a green photoreceptor and a response function of a blue photoreceptor.63. The color constancy apparatus according to claim 60, wherein said saturator comprises electronic-calculating functionality for substitution of a new pre-processed color value for each existing pre-processed color value, in accordance with the formula p/(p+p0), where said p0 is a constant and where p is said existing pre-processed color value.64. The color constancy apparatus according to claim 60, wherein said saturator comprises electronic-calculating functionality for substitution of a new pre-processed color value for each existing pre-processed color value, in accordance with the formula pn/(pn+p0), where said p0 is a constant, where p is said existing pre-processed color value and where said n is a curvature constant.65. The color constancy apparatus according to claim 60, wherein said corrector comprises a convolutor for calculating by integration, for each said pre-processed single color image, a center processed function Gc.66. The color constancy apparatus according to claim 65, wherein said convolutor further comprises electronic-calculating functionality for calculating by integration, for each said pre-processed single color image, a surround processed function Gs.67. The color constancy apparatus according to claim 66, wherein surround processed function is in accordance with the formula Gs=∫∫fs(x,y)I(x,y)dxdy, where said I is said pre-processed single color image and where said fs is a surround local spatial filter.68. The color constancy apparatus according to claim 67, wherein said surround local spatial filter is a spatial decaying filter.69. The color constancy apparatus according to claim 68, wherein said decaying is Gaussian decaying.70. The color constancy apparatus according to claim 68, wherein said decaying is exponential decaying.71. The color constancy apparatus according to claim 65, wherein said corrector further comprises an adapter for adapting said center processed function, to provide, at each picture element, a red center response value Rr, a green center response value Rg, and a blue center response value Rb.72. The color constancy apparatus according to claim 71, wherein said adapter further comprises electronic-calculating functionality for adapting said surround processed function, to produce, at each picture element, a red surround response value Rs,r and a green surround response value Rs,g.73. The color constancy apparatus according to claim 72, wherein said corrector further comprises a subtractor for replacing each center response value with the combination of said center response value and said surround response value.74. The color constancy apparatus according to claim 73, wherein said combination is in accordance with the following formulae:Rr:=Rr?Rs,g, Rg:=Rg?Rs,r, Rb:=Rb?(Rs,r+Rs,b)/2. 75. The color constancy apparatus according to claim 72, wherein said adapting is in accordance with the formula: Gs/(Gs+σs,l+σs,r), where said σs,l is a surround local adaptation term, and where said σs,r is a surround remote adaptation term.76. The color constancy apparatus according to claim 75, wherein said surround local adaptation tert is in accordance with the formula: σs,l=(as?1)Gs,b+bs, where said Gs,b is a surround adaptive function and where as and bs are a first and second surround region parameters.77. The color constancy apparatus according to claim 76, wherein said surround adaptive function is accordance with the formula Gs,b=Gs.78. The color constancy apparatus according to claim 76, wherein said surround adaptive function is a function of time t, in accordance with the formula Gs,b(t)=?Gs(t′)exp[(t′?t)/τs]/τs,bdt′, where said τs is a surround low-pass temporal filter time constant and where said τs,b is a surround decay time function.79. The color constancy apparatus according to claim 78, wherein said surround decay time function is a surround decay time constant.80. The color imaging device according to claim 79, wherein said transforming unit further comprises electronic-calculating functionality operable on each said picture element for combining each response value with said response values of said two regions of picture elements.81. The color imaging device according to claim 80, wherein said two regions are a remote region and a nearby region.82. The color constancy apparatus according to claim 78, wherein said surround decay time function is a function of time t, in accordance with the formula τs,b=τs,m/(1+|Gs,b?Gs|/Gs,n), where said τs,m is an expected maximum value of said surround decay time function, and where said Gs,n is a normalization constant.83. The color constancy apparatus according to claim 75, wherein said surround remote adaptation term is in accordance with the formula:σs,r=cs??Gs(x′,y′)exp(?sqrt(x?x′)2+(y?y′)2)/r0,s)dx′dy′, where said cs is a third surround region parameter, and where said r0,s is a surround radius parameter.84. The color constancy apparatus according to claim 71, wherein said adapting is in accordance with the formula: Gc/(Gc+σc,l+σc,r), where said σc,l is a center local adaptation term, and where said σc,r is a center remote adaptation term.85. The color constancy apparatus according to claim 84, wherein said center local adaptation term is in accordance with the formula: σc,l=(ac?1)Gc,b+bc, where said Gc,b is a center adaptive function and where ac and bc are a first and second center region parameters.86. The color constancy apparatus according to claim 85, wherein said center adaptive function is accordance with the formula Gc,b=Gc.87. The color constancy apparatus according to claim 85, wherein said center adaptive function is a function of time t, in accordance with the formula Gc,b(t)=?Gc(t′)exp[(t′?t)/τc]/τc,bdt′, where said τc is a center low-pass temporal filter time constant and where said τc,b is a center decay time function.88. The color constancy apparatus according to claim 87, wherein said center decay time function is a center decay time constant.89. The color constancy apparatus according to claim 87, wherein said center decay time function is a function of time t, in accordance with the formula τc,b=τc,m/(1+|Gc,b?Gc|/Gc,n), where said τc,m is an expected maximum value of said center decay time function, and where said Gc,n is a normalization constant.90. The color constancy apparatus according to claim 84, wherein said center remote adaptation term is in accordance with the formula: σc,r=cc??Gc(x′,y′)exp(?sqrt((x?x′)2+(y?y′)2)/r0,c)dx′dy′, where said cc is a third center region parameter and where said r0,c is a center radius parameter.91. The color constancy apparatus according to claim 65, wherein said center processed function is in accordance with the formula Gc∫∫fc(x,y)I(x,y)dxdy, where said I is said pre-processed single color image and where said fc is a center local spatial filter.92. The color constancy apparatus according to claim 91, wherein said center local spatial filter is a spatial decaying filter.93. The color constancy apparatus according to claim 92, wherein said decaying is Gaussian decaying.94. The color constancy apparatus according to claim 92, wherein said decaying is exponential decaying.95. The color constancy apparatus according to claim 60, wherein said transforming unit comprises electronic-calculating functionality for setting eleven variables, δ and zj, where said j is an integer-valued index ranging between 1 and 10.96. The color constancy apparatus according to claim 95, wherein said transforming unit further comprising electronic-calculating functionality for selecting a set of region parameters ac, as, bc, bs, cc and cs, and an electronic storing-recalling functionality for storing and recalling said set of region parameters.97. The color constancy apparatus according to claim 95, wherein said transforming unit further comprising electronic-calculating functionality for selecting a ratio coefficient and an electronic storing-recalling functionality for storing and recalling said ratio coefficient.98. The color constancy apparatus according to claim 97, wherein said transforming unit further comprising a multiplier for obtaining a remote picture element luminosity Yr.99. The color constancy apparatus according to claim 98, wherein said multiplier comprises electronic-calculating functionality for:(i) multiplying said set of center response values of each said picture element of said remote region of picture elements by an XYZ transformation matrix, to provide a transformed XYZ vector, said transformed XYZ vector comprising a first component, a second component and a third component; and (ii) setting setting the value of said remote picture element luminosity equal to the sum of all said second components of said transformed XYZ vectors of said remote region of picture elements. 100. The color constancy apparatus according to claim 99, wherein said transforming unit further comprises electronic-calculating functionality for making a value of: a center corrected red value, Rt,r, a center corrected green value, Rt,g, and a center corrected blue value, Rt,b, in accordance with the following formulae:Rt,g=?z3z10?z5z9?z6+√(z3z10+z5z9+z6)2?4z3z9(z5z10+z7)), Rt,r=z9Rt,g+z10, Rt,b=z1/(Rb+1/δ)?1?ac). 101. The color constancy apparatus according to claim 100, wherein transforming unit further comprises electronic-calculating functionality for transforming each said center corrected color value into a pigment RGB response, in accordance with the formula Rt,0Rt/(1?Rt) where Rt is a center corrected color value and where Rt,0 is a constant.102. The color constancy apparatus according to claim 101, wherein transforming unit further comprises electronic-calculating functionality for transforming said pigment RGB response into a transformed color scale, in accordance with the formula:{right arrow over (X)}=M{right arrow over (R)}, where said {right arrow over (X)} is a three-vector of said transformed color scale, where said {right arrow over (R)} is the three-vector of a pigment RGB response and where M is a transformation matrix.103. The color constancy apparatus according to claim 102, wherein said transformed color scale is an XYZ color scale.104. The color constancy apparatus according to claim 103, wherein said transformation matrix equal to 105. The color constancy apparatus according to claim 100, wherein transforming unit further comprises electronic-calculating functionality for transforming each said center corrected color value into a pigment RGB response, in accordance with the formula (Rt,0Rt/(1?Rt))1/n where Rt is a center corrected color value, where Rt,0 is a constant and where n is a curvature rate constant.106. The color constancy apparatus according to claim 99, wherein said eleven variables are in accordance with the following formulae:z1=bc+ccYr, z2=bs+csYr, z3=(as?ac?Rracas)CSR, z4=(as?ac?Rgacas)CSR/z3, z5=z2(1?Rrac), z6=?z1(1+Rras)CSR, z7=?Rrz1z2, z8=?z1(1+Rgas)CSR?z4?z5, z9=(z4z6?z2(1?Rgac))/z8, z10=(z4z7+Rgz1z2)/z8, and δ=as+(2/CSR)z2/(Rt,g+Rt,r). 107. A color imaging device having a color constancy mechanism, the color constancy mechanism comprising:an imager for resolving a color spectrum into a plurality of pre-processed single color images each respectively arranged as a series of pre-processed color values one at each of a plurality of picture elements; a corrector for partially correcting each said pre-processed color value by adapting each said pre-processed color value into a center response value, using pre-processed color values of said picture elements from at least two regions of picture elements; and a transforming unit for transforming each of said center response values into a center corrected color value, using response values of picture elements from said two regions of picture elements, thereby to provide a processed image having partial color constancy. 108. The color imaging device according to claim 107, which is a camera.109. The color imaging device according to claim 108, wherein said imager comprises electronic-calculating functionality for sorting said color spectrum with respect to the wavelength of each color at each picture element.110. The color imaging device according to claim 108, wherein said corrector comprises electronic-calculating functionality for combining pre-processed color values of each picture element with pre-processed color values of close picture elements.111. The color imaging device according to claim 110, wherein said corrector further comprises electronic-calculating functionality for combining pre-processed color values of each picture element with pre-processed color values of far picture elements.112. The color imaging device according to claim 108, wherein said transforming unit comprises electronic-calculating functionality for combining at each picture element, at least two center response values.113. The color imaging device according to claim 108, wherein said picture element comprises at least one pixel.114. The color imaging device according to claim 108, wherein said plurality of single color pre-processed images are a red pre-processed image, a green pre-processed image and a blue pre-processed image.115. The color imaging device according to claim 114, wherein said imager comprises electronic-calculating functionality for integrating the multiplication of said color spectrum of each picture element with a response function.116. The color imaging device according to claim 114, wherein said corrector comprises electronic-calculating functionality for calculating by integration, a red center processed function Gc,r, a green center processed function Gc,g, a blue center processed function Gc,b, a red surround processed function Gs,r and a green surround processed function Gs,g, each said processed function having a response value R at each picture element.117. The color imaging device according to claim 116, wherein said corrector further comprises electronic-calculating functionality for replacing at least one response value with the combination of said center response value and said surround response value.118. The color imaging device according to claim 117, wherein said combination of said center response value and said surround response value is in accordance with the following formulae:Rr:=Rc,r?Rs,g, Rg:=Rc,g?Rs,r, Rb:=Rc,b?(Rs,r+Rs,b)/2.
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Myers Robin D. ; McGreggor Keith ; Johnson Robert ; Othmer Konstantin, Color matching apparatus and method.
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