11056626 (P.T.A.B. Feb. 13, 2013)

Ex Parte Kulkarni et al

Patent Trial and Appeal BoardFeb 13, 2013

11056626 (P.T.A.B. Feb. 13, 2013)

UNITED STATES PATENT AND TRADEMARK OFFICE ____________ BEFORE THE PATENT TRIAL AND APPEAL BOARD ____________ Ex parte MANISH S. KULKARNI and LARS U. BORG ____________ Appeal 2010-010515 Application 11/056,626 Technology Center 2600 ____________ Before JAMESON LEE, KEVIN F. TURNER, and DAVID C. McKONE, Administrative Patent Judges. McKONE, Administrative Patent Judge. DECISION ON APPEAL Appellants appeal under 35 U.S.C. § 134(a) from a Final Rejection of claims 1-24, which constitute all the claims pending in this application. See App. Br. 1. We have jurisdiction under 35 U.S.C. § 6(b). We affirm. Appeal 2010-010515 Application 11/056,626 2 STATEMENT OF THE CASE Appellants’ invention relates to accurately reproducing digital data from print film. See Spec., Abstract. Claim 1, which is illustrative of the invention, reads as follows: 1. A method comprising: determining an exposure range of print film using an encoding range and a color calibration reference; sampling a sensitometric curve associated with the print film over the exposure range to obtain a plurality of density samples; converting the density samples to transmittance samples; and encoding the transmittance samples within a color profile. THE REJECTIONS The Examiner relies on the following prior art in rejecting the claims: Murashita US 2002/0093509 A1 July 18, 2002 Bogdanowicz US 2002/0163657 A1 Nov. 7, 2002 Bevans US 2004/0056965 A1 Mar. 25, 2004 Cineon KODAK MOTION PICTURE & TELEVISION IMAGING, CONVERSION OF 10-BIT LOG FILM DATA TO 8-BIT LINEAR OR VIDEO DATA FOR THE CINEON DIGITAL FILM SYSTEM, Ver. 2.1 (July 26, 1995) Bergmann LUDWIG BERGMANN ET AL., OPTICS OF WAVES AND PARTICLES (1993) Eastman Kodak EASTMAN KODAK, USING LAD TO SET UP AN ELECTRONIC COLOR ANALYZER AND PRINTING CONTROL (1992) Appeal 2010-010515 Application 11/056,626 3 Claims 1, 2, 4, 11-18, and 20-24 stand rejected under 35 U.S.C. § 103(a) as being unpatentable over Bevans, Cineon, and Bergmann. See Ans. 4-9. Claim 3 stands rejected under 35 U.S.C. § 103(a) as being unpatentable over Bevans, Cineon, Bergmann, and Bogdanowicz. See Ans. 9. Claim 5 stands rejected under 35 U.S.C. § 103(a) as being unpatentable over Bevans, Cineon, Bergmann, and Murashita. See Ans. 9- 10. Claims 6-10 stand rejected under 35 U.S.C. § 103(a) as being unpatentable over Bevans, Cineon, Bergmann, and Eastman Kodak. See Ans. 10-11. Claim 19 stands rejected under 35 U.S.C. § 103(a) as being unpatentable over Bergmann and Bevans. See Ans. 11-12. ANALYSIS REJECTION OF CLAIMS 1, 2, 4, 11-18, AND 20-24 UNDER 35 U.S.C. § 103(a) Claims 1, 2, 4, 17, 18, 20, 22, and 23 Appellants argue independent claims 1, 20, and 23 together. See App. Br. 10. Regarding independent claim 1, the Examiner finds: (1) Cineon teaches determining an exposure range of print film using an encoding range and a color calibration reference, and sampling a sensitometric curve associated with the print film over the exposure range to obtain a plurality of density samples; (2) Bergmann teaches converting density samples to transmittance samples; and (3) Bevans teaches encoding transmittance Appeal 2010-010515 Application 11/056,626 4 samples within a color profile. See Ans. 4. The Examiner concludes that it would have been obvious to combine these teachings. See Ans. 5. Appellants dispute the finding that Bevans teaches encoding transmittance samples within a color profile (see Ans. 4, citing Bevans, ¶0034), contending that Paragraph 0034 of Bevans is “silent on any teaching of ‘transmittance samples,’ much less ‘encoding the transmittance samples within a color profile,’” as recited in claim 1. App. Br. 6. According to Appellants, Bevans only discloses International Color Consortium (“ICC”) profiles. See id. The Examiner responds that Bevan’s disclosure that “the ICC profile may transform a red-green-blue triplet . . . into its corresponding coordinate on the chromaticity diagram 140 shown in FIG. 1c” means that colors are encoded within a color profile, and finds that encoding color samples is the same as encoding transmittance samples. Ans. 14 (quoting Bevans, ¶ 0034). Appellants reply that such disclosure of encoding color data generally is not a teaching of encoding transmittance samples because “transmittance is a more specific concept relating to the fraction of radiant energy that, having entered a layer of absorbing matter, reaches its farther boundary.” Reply Br. 3. Appellants have not adequately explained why Bevans’ disclosure of encoding color data is not a teaching of encoding transmittance samples. Bevans explains that at least one way to look at the color data it discusses is as a successive series of filters, each of which transmits some portion of a band of the visible spectrum and absorbs other portions. See Bevans, ¶ 0023. Bevans also explains that “RGB [Red Green Blue] information can be used as the basis for subtractive image reproduction.” Bevans, ¶ 0025. Thus, Bevans suggests that the “red-green-blue triplet” encoded in Appeal 2010-010515 Application 11/056,626 5 Paragraph 0034 is not simply a teaching of “color data generally” as Appellants argue (Reply Br. 3), but may also be more specific transmittance samples. See Ans. 14. Appellants also dispute the Examiner’s finding (see Ans. 4) that Cineon teaches “determining an exposure range of print film using an encoding range and a color calibration reference” and “sampling a sensitometric curve associated with the print film over the exposure range to obtain a plurality of density samples,” as recited in claim 1. See App. Br. 7- 9. Specifically, the Examiner finds that Cineon’s disclosure (page 4, §§ 1.1 and 1.2), of a Cineon scanner calibrated for a 2.048 density range, is a disclosure of determining an exposure range of print film using an encoding range and a color calibration reference. See Ans. 4. The Examiner finds that Cineon’s characteristic curve shown in Figure 9 is a sensitometric curve associated with print film that can be sampled to obtain a plurality of density samples over the 2.048 density range. See id. According to the Specification, a “sensitometric curve,” “also known as a characteristic curve, is a plot of density versus relative log exposure and indicates the response of film to each of red, green, and blue lights.” Spec. ¶ 0031. Appellants argue that “Cineon . . . provides no details about how the Cineon scanner operates and how the print film is processed because Cineon is merely describing converting digital negative data to specific output formats.” App. Br. 7. According to Appellants, Figure 9 of Cineon merely shows “a characteristic curve for the Cineon Digital negative for normally exposed negative film” rather than an exposure range that has been “determined.” App. Br. 8. Appeal 2010-010515 Application 11/056,626 6 In response, the Examiner finds that Cineon’s use of the term “color negative film” is the same as “print film” as used in claim 1. Ans. 14. The Examiner also points to Cineon, page 2, § 1.1, as providing additional disclosure of “digitize[ing] the full range of the original negative film,” which the Examiner finds is “determining.” Ans. 15. The Examiner also notes that Cineon’s use of “calibration” implies a “color calibration reference.” Id. We agree with the Examiner. Cineon teaches an exposure range for “color negative film” that is created by digitizing the full range (2.048 density range) of the negative film. See Cineon, p. 2, § 1.1; p. 4, § 1.1. This is similar to Appellants’ description of determining an exposure range. See Spec. ¶ 0031 (“This determination may, for example, be based on a 2.046 relative log exposure range (as based on a default 2.046 density range encoded by DPX files) from a sensitometric curve associated with the print film.”). And as the Examiner points out, Cineon terms this a “calibration range,” Cineon, p. 2 § 1.1, implying a color calibration reference. See Ans. 15. Appellants do not adequately explain why these findings are erroneous. Appellant also argues that Cineon does not teach sampling the curve of Figure 9. See App. Br. 8. The Examiner acknowledges that “Cineon does not explicitly teach sampling a sensitometric curve,” but concludes that “with the availability of a sensitometric curve associated with the print film over the exposure range, one of ordinary skill in the art would be able to obtain a plurality of density samples” from the curve. Ans. 15. In reply, Appellants simply argue that the Examiner is using hindsight reasoning and that, “[i]n the present situation, the knowledge within the level of ordinary skill in the art would not have led one, based on the cited art, to the claimed Appeal 2010-010515 Application 11/056,626 7 ‘sampling a sensitometric curve associated with the print film over the exposure range to obtain a plurality of density samples.’” Reply Br. 3-4. However, Appellants have not offered any evidence or explanation to show that sampling a sensitometric curve to obtain density samples would have been outside the level of ordinary skill. Indeed, it is logical that a curve that plots density as a function of exposure over a given range can be sampled to determined density values over that range. See Perfect Web Technologies, Inc. v. InfoUSA, Inc., 587 F.3d 1324, 1329 (Fed. Cir. 2009) (“[A]n analysis of obviousness . . . may include recourse to logic, judgment, and common sense available to the person of ordinary skill that do not necessarily require explication in any reference or expert opinion.”). Appellants also contend that the Examiner has articulated no reasoning with rational underpinning to support the conclusion of obviousness. See App. Br. 10. Appellants argue that Bevans is silent on scanning print film, while Cineon describes converting digital negative data to specific output formats. See id. The Examiner responds that a person of ordinary skill in the art would appreciate, from Cineon, that data can be converted among the three media that are typically used to store color pictures, namely film, computer data, and video images. See Ans. 16. The Examiner further finds that Cineon, Bergmann, and Bevans disclose the individual conversions recited in claim 1. See id. The Examiner then concludes that claim 1 is merely a predictable use of these conversions. See id. In reply, Appellants argue that the Examiner’s reasoning is improperly grounded in hindsight, and that Cineon describes converting digital negative data to a specific output data format, while Bevans and Bergmann are “silent Appeal 2010-010515 Application 11/056,626 8 regarding converting contents from film to computer.” Reply Br. 4. This argument does not adequately address the Examiner’s reason to combine. The Examiner does not find that Bevans or Bergmann teach converting image contents from film to computer data. See Ans. 3-4. Rather, the Examiner finds that Cineon teaches this conversion, and concludes that Cineon, Bevans, and Bergmann teach well known data conversion techniques that, when applied for their intended purposes in converting data among film, computer, and video images, as suggested by Cineon, yield no more than predictable results. See Ans. 4, 15-16. See also KSR Int’l Co. v. Teleflex, Inc., 550 U.S. 398, 417 (2007) (“[A] court must ask whether the improvement is more than the predictable use of prior art elements according to their established functions.”). Appellants do not adequately explain how claim 1 recites more than the predictable use of well-known conversions according to their established functions. Claims 20 and 23, argued together with claim 1, include recitations substantially the same as claim 1. Our reasoning for claim 1, then, applies to claims 20 and 23 as well. Appellants only nominally argue claims 2, 4, 17, 18, and 22 separately. See App. Br. 10. Accordingly, we sustain the rejection of: (1) claim 1; (2) claims 20 and 23; (3) claims 2, 4, 17, and 18, which depend on claim 1; and (4) claim 22, which depends on claim 20. Claim 11 Claim 11 depends on claim 1 and recites “wherein the encoding range is based on a density range encoded by a DPX file.” The Examiner finds that it was well-known that the DPX file format is derived from the Cineon Appeal 2010-010515 Application 11/056,626 9 file format and thus the density range encoded by a DPX file would be the same as that encoded by a Cineon file. See Ans. 5. From that, the Examiner concludes that it would have been obvious that Cineon’s encoding range can be based on a density range encoded by a DPX file. See id. Appellants disagree, contending that Cineon “only shows a density range, not one that is encoded by any file.” App. Br. 11. We are not persuaded by Appellants’ argument. As explained above for claim 1, we agree with the Examiner’s finding that Cineon discloses an encoding range. Moreover, Appellants’ own Specification details the relationship between Cineon and DPX. See Spec. ¶ 0026 (discussing the “CINEON / Digital Picture eXchange (DPX) format file”); 0033 (“The CINEON image file format is a subset of the ANSI/SMPTE DPX file format.”). Thus, we agree with the Examiner that a person of ordinary skill in the art would have known to encode Cineon’s encoding range using a Cineon/DPX file format. See Ans. 5, 11. Claims 12-16, 21, and 24 Claim 12 depends on claim 1; claim 21 depends on claim 20; and claim 24 depends on claim 23. Regarding claim 12 (and similar recitations in claims 21 and 24), the Examiner finds that Bergmann teaches “calculating red, green, and blue transmittance spectra respectively using the magenta layer, yellow layer, and cyan layer transmittance spectra.” See Ans. 5-6. Appellants argue that “Bergmann merely mentions that the colors red, green and blue are produced by the combination of two dyes, but does not teach or suggest calculating their transmittance spectra . . . .” App. Br. 11. In response, the Examiner finds that Bergmann, at the top of page 719, discloses an equation for calculating the spectral densities of other colors Appeal 2010-010515 Application 11/056,626 10 from values of yellow, cyan, and magenta (“Y1,” “Cy,” and “Mg”). See Ans. 19. The Examiner also points to Bergmann’s explanation that setting two of the yellow, cyan, and magenta values to “1” and the other to “0” would yield one of the red, green, and blue values. See Ans. 19 (the other two RGB values similarly would be obtained by different combinations of two “1’s” and one “0” for the Cy, Mg, and Yl values). Appellants do not adequately explain why this finding is erroneous. We note also that Bevans, too, explains this relationship and gives equations solvable for R, G, and B based on Cy, Mg, and Yl, see Bevans, ¶ 0025, further highlighting that this calculation was well-known. Also regarding claim 12, the Examiner finds that Bevans, at paragraphs 0008 and 0012-13, teaches “calculating X, Y, and Z values based on a viewing illuminant spectra and respectively based on the red, green, and blue transmittance spectra, and respectively based on X, Y, and Z color matching functions.” See Ans. 6. Appellants argue that “Bevans is silent on any teaching of a ‘viewing illuminant spectra’ as well as ‘red, green, and blue transmittance spectra.’” App. Br. 12. We are not persuaded by Appellants’ arguments. The Specification gives examples of viewing illuminant spectra as a xenon illuminant spectrum and CIE Illuminant D50, which “is a reference illuminant that defines the spectral distribution of daylight with a color temperature of 5003 K.” Spec. ¶¶ 0048-49. Similarly, Bevans teaches calculating X, Y, and Z values based on CIE Illuminant D65, a white illuminant. See Bevans, ¶¶ 0008, 0012-13; see also id. at ¶ 0010 (“exemplary matrix multiplication 125 for determining the tristimulus values (X, Y, Z) for a white light illuminant D65”). Bevans, at paragraph 0013, further notes that another example of a color model is “linear Red-Green- Appeal 2010-010515 Application 11/056,626 11 Blue (RGB).” Thus, Appellants have not adequately explained why the Examiner’s findings are erroneous. Claims 13-16 depend on claim 12, and are not argued separately. See App. Br. 10. Accordingly, we sustain the rejection of claims 12-16, 21, and 24. REJECTION OF CLAIM 3 UNDER 35 U.S.C. § 103(a) Claim 3 depends on claim 1. Appellants only nominally argue claim 3 separately. See App. Br. 13. Accordingly, we sustain the Examiner’s rejection of claim 3 for the same reasons given above for claim 1. REJECTION OF CLAIM 5 UNDER 35 U.S.C. § 103(a) Claim 5 depends on claim 1. Appellants only nominally argue claim 5 separately. See App. Br. 13. Accordingly, we sustain the Examiner’s rejection of claim 5 for the same reasons given above for claim 1. REJECTION OF CLAIMS 6-10 UNDER 35 U.S.C. § 103(a) Claims 6-10 depend on claim 1. Appellants only nominally argue claims 6-10 separately. See App. Br. 14. Accordingly, we sustain the Examiner’s rejection of claims 6-10 for the same reasons given above for claim 1. REJECTION OF CLAIM 19 UNDER 35 U.S.C. § 103(a) Regarding independent claim 19, the Examiner finds that Bergmann teaches calculating cyan layer, yellow layer, and magenta layer transmittance spectra; calculating red, green, and blue transmittance spectra Appeal 2010-010515 Application 11/056,626 12 respectively using the magenta layer, yellow layer, and cyan layer transmittance spectra; and calculating X, Y, and Z values based on a viewing illuminant spectra and respectively based on the red, green, and blue transmittance spectra. See Ans. 11-12. The Examiner concedes that Bergmann does not disclose either calculating X, Y, and Z values based on X, Y, and Z color matching functions or encoding X, Y, and Z values within a matrix in a color profile, but finds that these are taught by Bevans. See Ans. 12. Appellants argue that Bergmann does not teach “calculating red, green, and blue transmittance spectra respectively using the magenta layer, yellow layer, and cyan layer transmittance spectra.” App. Br. 14 (emphasis Appellants’). For the reasons given for claim 12, which also includes this claim language, we find that this limitation is taught by Bergmann. Appellants also argue that Bevans does not teach “encoding the X, Y, and Z values within a matrix in a color profile,” as recited in claim 19. See App. Br. 15-16. The Examiner finds this taught in paragraphs 0009 and 0034 of Bevans. Appellants argue that, while Bevans discloses matrix multiplication, at paragraph 0009, it does not teach encoding values within a matrix in a color profile. See App. Br. 15; Reply Br. 7-8. Appellants also argue that “the concept of a matrix is completely missing” from Bevans’s paragraph 0034. App. Br. 15; accord Reply Br. 7. The Examiner responds that Bevans’s paragraph 0034 teaches encoding X, Y, and Z values in an ICC color profile, and that paragraph 0009 teaches encoding X, Y, and Z information in a matrix. See Ans. 23. Logically, then, the ICC color profile of paragraph 0034 can be in the form of the matrix discussed in paragraph 0009. See Ans. 23. Indeed, Appeal 2010-010515 Application 11/056,626 13 Appellants’ Specification gives “an ICC Profile” as an example of a “three- component Matrix-based color profile.” Spec. ¶ 0029. Appellants have not persuasively explained why the Examiner’s finding is erroneous. Accordingly, we sustain the rejection of claim 19. ORDER The decision of the Examiner to reject claims 1-24 is affirmed. No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a)(1). See 37 C.F.R. § 1.136(a)(1)(iv) (2010). AFFIRMED rwk