2019003045 (P.T.A.B. Nov. 16, 2020)

NXP B.V.

Patent Trials and Appeals BoardNov 16, 2020

2019003045 (P.T.A.B. Nov. 16, 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. 15/602,160 05/23/2017 Anthony Kerselaers 82020458US01 3332 65913 7590 11/16/2020 Intellectual Property and Licensing NXP B.V. 411 East Plumeria Drive, MS41 SAN JOSE, CA 95134 EXAMINER YANG, JIANXUN ART UNIT PAPER NUMBER 2664 NOTIFICATION DATE DELIVERY MODE 11/16/2020 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): ip.department.us@nxp.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE ____________ BEFORE THE PATENT TRIAL AND APPEAL BOARD ____________ Ex parte ANTHONY KERSELAERS and PIETER VERSCHUEREN ____________ Appeal 2019-003045 Application 15/602,160 Technology Center 2600 ____________ Before JOSEPH L. DIXON, MAHSHID D. SAADAT, and BRIAN D. RANGE, Administrative Patent Judges. SAADAT, Administrative Patent Judge. DECISION ON APPEAL Pursuant to 35 U.S.C. § 134(a), Appellant1 appeals from the Examiner’s decision to reject claims 1–3, 11–17, 19, and 20.2 We have jurisdiction under 35 U.S.C. § 6(b). We REVERSE. 1 We use the word “Appellant” to refer to “applicant” as defined in 37 C.F.R. § 1.42(a) (2017). Appellant identifies the real party in interest as NXP B.V. Appeal Br. 16. 2 Claims 4–10 and 18 have been withdrawn from consideration. Appeal 2019-003045 Application 15/602,160 2 STATEMENT OF THE CASE Introduction Appellant’s disclosure is directed to “systems, methods, apparatuses, devices, articles of manufacture and instructions for near-field signal analysis.” Spec. ¶ 1. Claim 1 is illustrative of the invention and reads as follows: 1. A near-field device, comprising: a near-field receiver coupled to a near-field receiver antenna and a decoder circuit; wherein the near-field receiver antenna is configured to be capacitively coupled at a first location on a conductive structure and receive a non- propagating quasi-static magnetic near-field signal and a non- propagating quasi-static electric near-field signal from the conductive structure through the receiver’s capacitive coupling, wherein the decoder circuit includes a degradation detector that is configured to interpret variations in the magnetic and electric near-field signals as a structural degradation in the conductive structure. Appeal Br. 17 (Claims Appendix). The Examiner’s Rejections Claims 1–3, 11, 13–17, and 19 stand rejected under 35 U.S.C. § 103(a) as being unpatentable over Hancock (US 2008/0319285 Al; pub. Dec. 25, 2008), Simons (US 2006/0235633 Al; pub. Oct. 19, 2006), and Chapman (US 2002/0155625 Al; pub. Oct. 24, 2002). Final Act. 5–15. Claim 20 stands rejected under 35 U.S.C. § 103(a) as being unpatentable over Hancock, Simons, Chapman, and Nassiri (RF Cavities Appeal 2019-003045 Application 15/602,160 3 and Components for Accelerators, Massachusetts Institute of Technology, USPAS 2010). Final Act. 16–17.3 ANALYSIS 35 U.S.C. § 103(a) REJECTION In rejecting claim 1, the Examiner finds Hancock discloses the recited near-field device including “a near-field receiver coupled to a near-field receiver antenna and a decoder circuit” and Simons discloses “wherein the near-field receiver antenna is configured to be capacitively coupled at a first location on a conductive structure.” Final Act. 5–7 (citing Hancock Fig. 1; ¶¶ 45, 46, 49 (create a resonant microwave cavity within the tissue structures between the two antennas)). The Examiner relies on Chapman as disclosing “wherein the decoder circuit is configured to detect variations in the magnetic and electric near-field signals.” Final Act. 7–8 (citing Chapman Fig. 1; ¶¶ 7, 16, 43, 73). Appellant contends the Examiner erred in characterizing Chapman’s “detection of molecular events using temperature control of the detection environment” as the claimed degradation detector because “[c]laim 1, as amended, recites: ‘includes a degradation detector that is configured to interpret variations in the magnetic and electric near-field signals as a structural degradation in the conductive structure” whereas “Chapman is directed to detection of molecular events using temperature control of the 3 In the Answer, the Examiner has withdrawn the 35 U.S.C. § 103(a) rejection of claim 12 over Hancock, Simons, Chapman, and Zdeblick, and the non-statutory obviousness-type double patenting rejection of claims 1 and 16 over claims 1 and 19 of copending Application 15/642,168 in view of Hancock, Simons, and Chapman. Ans. 23. Appeal 2019-003045 Application 15/602,160 4 detection environment.” Appeal Br. 7 (emphasis omitted). Appellant asserts “[a] person having ordinary skill in the art would not regard a high blood glucose level as a ‘structural degradation in the conductive structure,” and therefore, Chapman lacks any disclosure of the disputed limitation related to “a degradation detector that is configured to interpret variations in the magnetic and electric near-field signals as a structural degradation in the conductive structure,” as recited in claim 1. Id. The Examiner responds by explaining that: A “degradation detector” is a loose term. Any detector that detects variations of a material structure, directly or indirectly, may be considered as a degradation detector of the material structure. Hancock teaches a material characterization system that measures changes of material properties/structures such as dielectric constant (Fig. 1, [0091–97]). Such detected changes in material’s dielectric constant represent the change of the material structure under test (blood) and may indicate high blood-glucose level that implies a degraded blood structure. So the detector is indeed a blood (structure) degradation detector. Blood is a conductive material for an electromagnetic field. Similarly, Chapman et al teaches a similar RF test system for study of molecular structures (Fig. 1, [0007]; “Molecular structure is typically detected by comparing the signal obtained tram a molecule of unknown structure and/or function to the signal obtained from a molecule of known structure and/or function”, [0043]). The detector of Chapman et al can be considered as a degradation detector since it detects the structural deviation of a material from a known structure. Ans. 18. Chapman relates to “obtaining an electromagnetic signature of the molecule in the detection range using the now-enabled new techniques, to classify unknown molecules as having structure relationship.” Chapman ¶ 7. Chapman discloses a method for detecting molecular interactions by Appeal 2019-003045 Application 15/602,160 5 “detecting a molecular event, comprising (1) applying an electromagnetic test signal in a frequency range from 1 MHz to 1000 GHz to a sample in which a molecular event is being detected.” Chapman ¶ 16. We agree with Appellant that claim 1’s recited “conductive structure” and “interpret[ting] variations in the magnetic and electric near-field signals as a structural degradation in the conductive structure” should not be construed so broadly that it encompasses, for example, the detection of high- blood glucose within blood, as described by Chapman. Appeal Br. 7; Reply Br. 2. In that regard, we find Chapman’s disclosure relates to “obtaining an electromagnetic signature of the molecule in the detection range using the now-enabled new techniques, to classify unknown molecules.” Chapman ¶ 7. To identify the unknown structure, Chapman detects the molecular structure of a sample “by comparing the signal obtained from a molecule of unknown structure and/or function to the signal obtained from a molecule of known structure.” Chapman ¶ 43. Additionally, Chapman’s cited portion, in paragraph 73, describes a signal generating circuit that “launches a signal that couples to the sample in the detection region,” which refers to the sample of the molecule of unknown structure that is being identified. Accordingly, we disagree with the Examiner’s characterization of a “high blood-glucose level that implies a degraded blood structure” (see Ans. 18) as the disputed claim limitation because Chapman’s detection is based on comparing a measured signal to a signal associated with a known molecular structure, rather than interpreting “variations in the magnetic and electric near-field signals as a structural degradation in the conductive structure,” as recited in Appellant’s claim 1. Appeal 2019-003045 Application 15/602,160 6 Conclusion For the above reasons, we agree with Appellant that the Examiner’s proposed combination does not teach or suggest the disputed limitation of claim 1. Therefore, Appellant’s arguments have persuaded us of error in the Examiner’s position with respect to the rejections of claim 1, independent claim 16 which recites similar limitations, as well as the remaining claims dependent therefrom. See Appeal Br. 17–21 (Claims App.). DECISION SUMMARY In summary: Claims Rejected 35 U.S.C. § Basis Affirmed Reversed 1–3, 11, 13–17, 19 103 Hancock, Simons, Chapman 1–3, 11, 13– 17, 19 20 103 Hancock, Simons, Chapman, Nassiri 20 Overall Outcome 1–3, 11, 13– 17, 19, 20 REVERSED