HALLIBURTON ENERGY SERVICES INC.

Patent Trials and Appeals BoardNov 13, 2020

14412308 - (D) (P.T.A.B. Nov. 13, 2020)

UNITED STATES PATENT AND TRADEMARK OFFICE UNITED STATES DEPARTMENT OF COMMERCE United States Patent and Trademark Office Address: COMMISSIONER FOR PATENTS P.O. Box 1450 Alexandria, Virginia 22313-1450 www.uspto.gov APPLICATION NO. FILING DATE FIRST NAMED INVENTOR ATTORNEY DOCKET NO. CONFIRMATION NO. 14/412,308 12/31/2014 David L. Perkins 2013-083543 U1 US 4212 142050 7590 11/13/2020 HALLIBURTON ENERGY SERVICES, INC. C/O PARKER JUSTISS, P.C. 14241 DALLAS PARKWAY SUITE 620 DALLAS, TX 75254 EXAMINER MILLER, MICHAEL G ART UNIT PAPER NUMBER 1712 NOTIFICATION DATE DELIVERY MODE 11/13/2020 ELECTRONIC Please find below and/or attached an Office communication concerning this application or proceeding. The time period for reply, if any, is set in the attached communication. Notice of the Office communication was sent electronically on above-indicated "Notification Date" to the following e-mail address(es): docket@pj-iplaw.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE ____________ BEFORE THE PATENT TRIAL AND APPEAL BOARD ____________ Ex parte DAVID L. PERKINS, ROBERT PAUL FREESE, CHRISTOPHER MICHAEL JONES and RICHARD NEAL GARDNER Appeal 2019-005698 Application 14/412,308 Technology Center 1700 ____________ Before MICHAEL P. COLAIANNI, MICHAEL G. McMANUS, and JANE E. INGLESE, Administrative Patent Judges. COLAIANNI, Administrative Patent Judge. DECISION ON APPEAL Pursuant to 35 U.S.C. § 134(a), Appellant1 appeals from the Examiner’s decision to reject claims 1–17. We have jurisdiction under 35 U.S.C. § 6(b). We AFFIRM. 1 We use the word “Appellant” to refer to “applicant” as defined in 37 C.F.R. § 1.42. Appellant identifies the real party in interest as Halliburton Energy Services, Inc. Appeal Br. 3. Appeal 2019-005698 Application 14/412,308 2 Appellant’s invention is directed to a method of fabricating an integrated computational element (ICE) used in optical analysis tools for analyzing a substance of interest, such as crude petroleum, gas, water, or other wellbore fluids (Spec. ¶ 1; Claim 1). Claim 1 is representative of the subject matter on appeal: 1. A method comprising: receiving, by a fabrication system, a design of an integrated computational element (ICE), the ICE design comprising specification of a substrate and a plurality of layers, their respective target thicknesses and complex refractive indices, wherein complex refractive indices of adjacent layers are different from each other, and wherein a notional ICE fabricated in accordance with the ICE design is related to a characteristic of a sample over an operational wavelength range; forming, by the fabrication system, at least one of the layers of the ICE in accordance with the ICE design; optically monitoring, during said forming, by a measurement system associated with the fabrication system, optical properties of the formed layers using monochromatic probe- light having a probe wavelength that is selected to be outside of the operational wavelength range of the ICE based on a material of the formed layers; and adjusting, by the fabrication system, said forming, at least in part, based on the optically monitored optical properties of the formed layers of the ICE. Appellant appeals the following rejections presented in the Non- Final Action dated September 17, 2018: 1. Claims 1, 2, 7, and 11–17 are rejected under 35 U.S.C. § 103(a) as unpatentable over Myrick (US 7,138,156 B1, issued November 21, 2006) in view of Rosencwaig (US 6,781,692 B1, issued August 24, 2004), Fraction definition (https://merriam- Appeal 2019-005698 Application 14/412,308 3 webster.com/dictionary/fraction 2017) and Infrared definition (Previous (Information graphics) (/entry/lnformation_graphics). 2. Claims 3–6 and 8–10 are rejected under 35 U.S.C. § 103(a) as unpatentable over Myrick in view of Rosencwaig and Thomas (US 2007/0019204 A1, published January 25, 2007). Appellant’s arguments focus on the subject matter of claim 1 only (Appeal Br. 4–10). Appellant’s only argument regarding rejection (2) is that Thomas does not cure the alleged deficiencies in Myrick and Rosencwaig (Appeal Br. 11). Accordingly, claims 2–17 will stand or fall with our analysis of the rejection of claim 1. FINDINGS OF FACT & ANALYSIS The Examiner’s findings regarding the obviousness of claim 1 over Myrick, Rosencwaig, Fraction, and Infrared are located on pages 4–6 of the Non-Final Action dated September 17, 2018. The Examiner finds that Myrick teaches most of the limitations in claim 1, except for a specific light source that emits monochromatic light with a wavelength outside the operational wavelength range of the ICE (Non-Final Act. 4–5). The Examiner finds that Rosencwaig teaches forming wavelength specific filters composed of alternating layers of high and low index of refraction materials (Non-Final Act. 5). The Examiner finds that Rosencwaig teaches optically monitoring the thickness of the alternating layers formed using a probe beam of radiation (Non-Final Act. 5). The Examiner finds Rosencwaig teaches that the probe radiation has a wavelength either approximately that of the operative wavelength or a fraction thereof (Non-Final Act. 5). The Appeal 2019-005698 Application 14/412,308 4 Examiner finds Rosencwaig’s ellipsometry process uses a light beam reflected from a forming surface (Non-Final Act. 5–6). The Examiner finds that because Rosencwaig’s ellipsometry process reflects off the substrate, the materials forming the substrate must inherently be selected based on the forming material (Non-Final Act. 6). Based on the definition of “fraction,” the Examiner finds Rosencwaig’s disclosure of fractional wavelengths includes fractions greater than 1 and less than 1 (Non-Final Act. 6). The Examiner concludes it would have been obvious to modify Myrick’s method to include the measurement techniques suggested by Rosencwaig because Myrick wants to use optical methods to determine the thickness of thin layers in an optical filter, and Rosencwaig teaches using a light source at a fraction of the desired transmission wavelength as a known method for determining the thickness of thin films with a high degree of accuracy and repeatability (Non-Final Act. 5). Appellant argues that Myrick and Rosencwaig fail to teach all the limitations in claim 1 (Appeal Br. 4). Appellant contends that Rosencwaig fails to teach selecting a probe beam to be outside of the operational wavelength range of the ICE based on a material of the formed layers and teaches away from such a selection of probe wavelength (Appeal Br. 6). Appellant argues that Rosencwaig prefers to use a wavelength of the light that is near the operational wavelength range of the filter (i.e., 1500/1550 nm range) to improve sensitivity and minimize uncertainties in the measurement (Appeal Br. 6). Appellant argues that Rosencwaig’s teaching to select a wavelength near the operational wavelength of the resulting filter amounts to a teaching away from selecting a wavelength outside of the operational wavelength range of the ICE (Appeal Br. 7). Appellant contends that Appeal 2019-005698 Application 14/412,308 5 Rosencwaig does not inherently teach selecting a wavelength of its light based on the forming materials (Appeal Br. 8). Appellant argues the Examiner has not considered the claim as a whole in omitting the claim requirement that the selected wavelength is outside the operational wavelength range of an ICE in determining that Rosencwaig inherently bases the operational wavelength on the material of the formed layers (Appeal Br. 9). We have fully considered Appellant’s arguments and we find that the preponderance of the evidence favors the Examiner’s obviousness conclusion. We are unpersuaded by Appellant’s argument that Rosencwaig teaches away from the using a probe wavelength outside the operational wavelength of the ICE. Rosencwaig prefers using a light source 52 having an output wavelength “near” the desired transmission band of the filter (col. 7, ll. 14–16). Rosencwaig teaches “to improve sensitivity and minimize uncertainties in the measurement of films transmitting in the 1550 nm range, it may be desirable to use a probe beam having a wavelength in the 1550 nm region or fractions thereof.” (Col. 4, ll. 13–16). A wavelength that is “near” the desired transmission band must be outside of the band, otherwise the near wavelength would have been characterized as being within the desired transmission band. Merriam-Webster Dictionary defines “near” as “close to.”2 A wavelength that is “close to” a transmission range is outside the range (i.e., it is not at or within the transmission range). The Examiner’s finding that “Rosencwaig teaches a desire to select a measurement wavelength near (as opposed to inside) the operational wavelength range of 2 https://www.merriam-webster.com/dictionary/near accessed on November 2, 2020. Appeal 2019-005698 Application 14/412,308 6 its optical device” is reasonable (Ans. 4). Appellant argues that “near” is not the opposite of “inside” such that Rosencwaig does not exclude selecting the wavelength inside the optical wavelength range (Reply Br. 3). Appellant’s argument is without merit. If Rosencwaig’s probe wavelength was at the wavelength range, it would not be near the wavelength range, but would rather have been characterized as being within wavelength range. Appellant contends that a fraction of the wavelength does not mean that the fractional wavelength is outside of the operational wavelength range of an ICE (Appeal Br. 10). Appellant’s argument does not address Rosencwaig’s example at column 2, lines 13–17, where the film transmits in the 1550 nm region relied upon by the Examiner (Non-Final Act 5). Appellant’s argument is not fully understood because, for example, if a fractional wavelength is used for a layer that transmits in the 1550 nm wavelength region as taught by Rosencwaig, then it would stand to reason that the fractional wavelength (e.g., 750 nm) would have been outside of the 1550 nm region. (Rosencwaig col. 2, ll. 13-17). Appellant has not shown reversible error in the Examiner’s rejection. We are further unpersuaded by Appellant’s argument regarding the Examiner’s finding that Rosencwaig’s operational wavelength range is based on a material of the formed layers (Appeal Br. 9). Appellant contends the Examiner’s finding assumes that Rosencwaig’s ellipsometry process always selects/changes a wavelength to make light reflect off a material and such changing/selecting always makes the light reflect off materials (Appeal Br. 9). Appellant contends that Rosencwaig teaches that the wavelength is selected based on the operating wavelength of the resulting filter (Appeal Br. 9). Appeal 2019-005698 Application 14/412,308 7 The Examiner finds Rosencwaig teaches that ellipsometry requires measurement of a light beam reflected from a forming substrate surface (Non-Final Act. 5). The Examiner finds that Rosencwaig must inherently select the material based upon the forming materials themselves (Non-Final Act. 5). Although Appellant contends the Examiner assumes that ellipsometry always requires reflection of the light off a material, we note that Examiner’s rejection is based on the teachings of Rosencwaig, not a mere assumption (Non-Final Act. 5). The Examiner cites to Rosencwaig to teach that well-known ellipsometric principles include that the reflected beam will be in a mixed linear and circular polarization state after interacting with the sample (Non-Final Act. 5; Rosencwaig col. 4, ll. 26–31). In other words, it is undisputed that Rosencwaig teaches that the ellipsometry involves reflections off a surface. A preponderance of the evidence supports the Examiner’s finding that a person of ordinary skill in the art would have selected substrate materials so that the reflection required in ellipsometry could occur. We find Rosencwaig teaches that the applied films transmit the probe light in the 1550 nm range (col. 2, ll. 13–14). Rosencwaig teaches that the layers used are made of silicon or tantalum to provide high and low index of refraction material (col. 2, ll. 52–56). Stated differently, the composition of the layers are selected based upon their index of refraction and transmission range. We find that Rosencwaig would have suggested selecting the film compositions to have a particular operation wavelength range. Rosencwaig’s teaching that the probe light source has a wavelength “near” the transmission band of the filter would have suggested that the wavelength used is outside the transmission band (operational wavelength) of the filter Appeal 2019-005698 Application 14/412,308 8 (ICE). The Examiner has not treated the claims in a piecemeal fashion as argued by Appellant (Appeal Br. 9). On this record, we affirm the Examiner’s § 103 rejection of claims 1, 2, 7, and 11–17 over Myrick, and Rosencwaig. We further affirm the § 103 rejections of claims 3–6 and 8–10 over Myrick, Rosencwaig, and Thomas. CONCLUSION In summary: Claims Rejected 35 U.S.C. § Prior Art Affirmed Reversed 1, 2, 7, 11–17 103(a) Myrick, Rosencwaig 1, 2, 7, 11–17 3–6, 8–10 103(a) Myrick, Rosencwaig, Thomas 3–6, 8–10 Overall Outcome 1–17 TIME PERIOD FOR RESPONSE No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a). See 37 C.F.R. § 1.136(a)(1)(iv). AFFIRMED