14170248 (P.T.A.B. Jan. 11, 2018)

Ex Parte Tokuda

Patent Trial and Appeal BoardJan 11, 2018

14170248 (P.T.A.B. Jan. 11, 2018)

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. 14/170,248 01/31/2014 Daisuke TOKUDA 002000-000158 7342 78198 7590 01/16/2018 StiiHehaker & Rraokett PP EXAMINER 8255 Greensboro Drive LU, ZHIYU Suite 300 Tysons, VA 22102 ART UNIT PAPER NUMBER 2649 NOTIFICATION DATE DELIVERY MODE 01/16/2018 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): info@ sbpatentlaw.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte DAISUKE TOKUDA Appeal 2017-006977 Application 14/170,248 Technology Center 2600 Before JOHN A. JEFFERY, DENISE M. POTHIER, and MATTHEW J. McNEILL, Administrative Patent Judges. JEFFERY, Administrative Patent Judge. DECISION ON APPEAL Appeal 2017-006977 Application 14/170,248 Appellant appeals under 35 U.S.C. § 134(a) from the Examiner’s decision to reject claims 1 and 6.12 We have jurisdiction under 35 U.S.C. § 6(b). We affirm. STATEMENT OF THE CASE Appellant’s invention is a high-frequency (HF) module with active and passive elements. The module includes a chip device with a substrate on which two regions are formed: (1) a passive circuit forming region 902U with capacitors 120-123, and (2) an active circuit forming region 901 with respective sections 101-103 for a switch, power amplifiers, and low noise amplifiers, respectively. See Spec. 41 42; Figs. 2-3. Inductors, however, are omitted from this device to reduce size. See Spec. 10, 12, 53. Instead, conductive wires 211-213 provide the requisite inductance due to 1 Although the Examiner’s Final Rejection mailed April 29, 2016 includes various grounds of rejection for claims 2 to 5, those claims were cancelled in a subsequent proposed amendment that the Examiner entered. See Advisory Action mailed Aug. 16, 2016 (“Adv. Act.”), at 1-2 (indicating that the proposed amendment filed July 29, 2016 would be entered for appeal purposes); see also App. Br. 2, 8 (noting this cancellation in the Claims Appendix). These entered amendments incorporated limitations from original dependent claims 2 and 3 into independent claim 1. Accord Ans. 6 (noting that claim 1 on appeal is actually original claim 3). Therefore, despite the Examiner’s erroneously indicating that claims 2 to 5 are rejected (see Ans. 2-5), only claims 1 and 6 remain pending. Accordingly, all references to claim 1 in this opinion are to the version in the Claims Appendix of the Appeal Brief unless otherwise indicated. 2 Although the Examiner indicated that the proposed amendment after Final Rejection would not be entered in an earlier Advisory Action mailed August 4, 2016, the Examiner nonetheless later indicated that the amendment would be entered in an Advisory Action mailed August 16, 2016. 2 Appeal 2017-006977 Application 14/170,248 their length and shape. See Spec. 12, 48-53; Figs. 3-6. Claim 1 is illustrative: 1. A high-frequency module comprising a first circuit composed of a group of passive elements including at least one inductor and at least one capacitor, and a second circuit including at least one active element, the at least one capacitor of the first circuit and the at least one active element of the second circuit being formed in a single chip device, wherein the at least one inductor includes a conductive wire to mount the single chip device on an external circuit substrate, the inductor and the capacitor are grounded, the chip device includes a ground via that grounds the capacitor, and a land, which is formed on the external circuit substrate and to which the conductive wire is bonded, and an electrode, which is formed on the external circuit substrate and is connected to the ground via, form an integrated common ground electrode. THE REJECTION3 The Examiner rejected claims 1 and 6 under 35 U.S.C. § 103 as unpatentable over Nishimura (US 2004/0152276 Al; Aug. 5, 2004), 3 Because only claims 1 and 6 are pending in this appeal, and the limitations from claims 2 and 3 were incorporated into independent claim 1 in an amendment filed after the Examiner’s Final Rejection that was entered as noted previously, we presume that the Examiner intended to reject amended claim 1 over the grounds indicated for claims 2 and 3 on pages 5 and 6 of the Final Rejection mailed April 29, 2016 (and pages 4 and 5 of the Answer mailed January 27, 2017) that include the Kanno and Okabe references. Accord App. Br. 3 (noting that claim 1 is “technically” rejected as obvious over Nishimura, Kemmochi, Kanno, and Okabe). Despite the Examiner’s erroneously indicating that claims 2 to 5 are rejected on pages 2 to 5 of the Answer, we nonetheless consolidate those grounds here for clarity. We, therefore, present the correct ground of rejection here in light of the entered 3 Appeal 2017-006977 Application 14/170,248 Kemmochi (US 2009/0206948 Al; Aug. 20, 2009), Kanno (US 2005/0285234 Al; Dec. 29, 2005), and Okabe (US 2005/0176380 Al; Aug. 11,2005). See Ans. 2-5.* * 4 CONTENTIONS Regarding independent claim 1, the Examiner finds that Nishimura’s high-frequency (HF) module includes a “first circuit” (bandpass filter 602) with passive elements, and a “second circuit” (Tx/Rx switch 610) with at least one active element. Ans. 2. Although the Examiner acknowledges that the passive elements in Nishimura’s first circuit do not include at least one inductor and capacitor, the Examiner cites Kemmochi for teaching this feature. Ans. 3. The Examiner also cites Kanno for teaching an inductor including a conductive wire to mount a single chip device on an external substrate. Ans. 4. Lastly, the Examiner cites (1) Kemmochi for teaching grounding an inductor and capacitor, (2) Kanno for teaching a chip device including a ground via, and (3) Okabe for teaching connecting electronic circuit blocks of a HF circuit to a common ground. Ans. 5. In light of these collective teachings, the Examiner concludes that claim 1 would have been obvious. See Ans. 2-9. Appellant argues that the cited prior art does not teach or suggest a circuit on a chip with an inductor and capacitor that are both grounded, let alone an integrated common ground electrode as claimed. App. Br. 3-6. amendment after final rejection, and treat the Examiner’s error in this regard as harmless. 4 Throughout this opinion, we refer to (1) the Appeal Brief filed October 18, 2016 (“App. Br.”); (2) the Examiner’s Answer mailed January 27, 2017 (“Ans.”); and (3) the Reply Brief filed March 27, 2017 (“Reply Br.”). 4 Appeal 2017-006977 Application 14/170,248 Appellant adds that Nishimura does not form a capacitor and an active element in a single chip device. Reply Br. 1-2. Appellant argues other recited limitations summarized below. ISSUES Under § 103, has the Examiner erred by finding that Nishimura, Kemmochi, Kanno, and Okabe collectively would have taught or suggested: (1) the single chip device recited in claim 1? (2) the first circuit is a band pass filter connected to an antenna as recited in claim 6? ANALYSIS Claim 1 We begin by noting that claim 1 recites, in pertinent part, that at least one capacitor of the first circuit and at least one active element of the second circuit are formed in a single chip device. We emphasize “device” here, for the Examiner apparently distinguishes a single chip from a single chip device in construing the claim. See Ans. 9 (noting that claim 1 does not preclude a substrate from being part of a “chip device,” and citing Kanno’s Figure 13 as an example of such a device). Appellant, however, apparently construes the recited single chip device as a single chip. See Reply Br. 2 (arguing that claim 1 requires forming the capacitor and active element in a single chip); see also App. Br. 5 (arguing that the cited prior art lacks a circuit on a chip with an inductor and capacitor that are both grounded, and asking where in the cited prior art a ground via is located in a chip that grounds the capacitor). 5 Appeal 2017-006977 Application 14/170,248 Appellant’s Specification does not define the term “chip device,” but does describe a semiconductor chip device 20 whose electrode patterns form capacitors of a bandpass filter BPF and field effect transistors (FETs) of a switch and various amplifiers. See Spec. 35 42. As shown in Appellant’s Figure 2 reproduced below, the chip device 20 includes a base substrate on which two regions are formed: (1) a passive circuit forming region 902U with capacitors 120-123, and (2) an active circuit forming region 901 with respective sections 101-103 for the switch, power amplifiers, and low noise amplifiers, respectively. See Spec. 41 42. 20 /' 153 121 552 131 Appellant’s Figure 2 showing chip device 20 Noticeably absent from this chip device is an inductor, for a key aspect of the invention is deliberately omitting inductors from this device to reduce size. See Spec. 10, 12, 53. Instead, conductive wires 211-213 6 Appeal 2017-006977 Application 14/170,248 provide the requisite inductance due to their length and shape. See Spec. HU 12, 48-53; Figs. 3-6. When interpreted in light of this disclosure, then, a “single chip device” is a device whose respective elements, when integrated, collectively form a chip. Although a chip device may have a substrate, such as the base substrate 100 in Figure 2, the device’s substrate must nevertheless be distinct from the external circuit substrate to which the chip device is mounted (e.g., substrate 300 in Figures 3 and 4). See Spec. HH 48-50. This distinction is consistent with claim 1 where this mounting is achieved with a conductive wire. See Spec. H 11 • Turning to the rejection, there is no dispute that Nishimura’s integrated circuit 903 can be formed as a chip, and include a capacitor and active element in light of Nishimura’s paragraphs 100 and 127. See Ans. 6- 8; see also Reply Br. 1 (acknowledging this point). Therefore, Nishimura forms a capacitor and active element as a single chip device, namely a device whose respective elements, including the capacitor and active element, collectively form a chip. Although Nishimura is silent regarding whether this chip device has a via that grounds the capacitor, we nonetheless see no error in the Examiner’s reliance on Kanno and Okabe for at least suggesting that ground vias are known in the art, and that providing such vias to ground the capacitor in Nishimura’s chip device would have been obvious. See Ans. 8-9. To be sure, Kanno’s vias 14 in Figure 1A and paragraph 83 are in substrate 1 and not HF functional element 2, which both Appellant and the Examiner acknowledge is a chip. See App. Br. 6; Ans. 9. But the Examiner finds that Kanno’s chip 2 would also have a ground via of its own for chip 7 Appeal 2017-006977 Application 14/170,248 circuit grounding (Ans. 9)—a finding that has not been squarely addressed, let alone persuasively rebutted on this record. See App. Br. 3-6; Reply Br. 1-2. Nor has Appellant squarely addressed—let alone persuasively rebutted—the Examiner’s finding that Okabe grounds circuit components with respective ground vias that lead to a common ground in Figure 2. See Ans. 9. Given these undisputed findings, the weight of the evidence on this record favors the Examiner’s position at least to the extent that providing a via that grounds the capacitor in Nishimura’s chip device would have been at least an obvious variation to those of ordinary skill in the art, namely electrical engineers with several years of related industry experience.5 That Okabe’s Figure 2 and paragraph 56 discloses grounding, among other components, capacitors 22a, 22b with respective vias to a common ground plane 480 only further bolsters the Examiner’s position in this regard. Nor do we see error in the Examiner’s reliance on Kanno for teaching providing a conductive wire 5 to function as an inductor, and that grounding this inductor (along with the capacitor) would have been obvious in light of Kemmochi’s Figure 3 that shows grounding both inductors and capacitors in filter circuit 30. See Ans. 4-5, 8. That Kanno accounts specifically for the inductance of wire 5 in Figures 7A and 7B and paragraphs 112 and 113 only further bolsters the notion that using a wire as an inductor in a HF module is 5 Cf. In reMouttet, 686 F.3d 1322, 1333 (Fed. Cir. 2012) (“The Board properly found that an electrical engineer with several years of related industry experience would indeed have recognized that Falk’s arithmetic processor could have been combined with Das’s wired crossbar array to predictably yield Mouttet’s claimed computing device.”) (emphasis added). 8 Appeal 2017-006977 Application 14/170,248 known in the art, and that grounding this inductor as well as a capacitor in a filter circuit would have been obvious in view of Kemmochi’s Figure 3. Doing so using an integrated common ground electrode in light of Okabe as the Examiner proposes (Ans. 5, 9) uses prior art elements predictably according to their established functions—an obvious improvement. See KSR Int’l Co. v. Teleflex, Inc., 550 U.S. 398, 417 (2007). Appellant’s arguments regarding the cited references’ individual shortcomings (App. Br. 5-6; Reply Br. 1-2) do not show nonobviousness where, as here, the rejection is based on the cited references’ collective teachings. See In re Merck & Co., 800 F.2d 1091, 1097 (Fed. Cir. 1986). Therefore, we are not persuaded that the Examiner erred in rejecting claim 1. Claim 6 We also sustain the Examiner’s rejection of claim 6 reciting, in pertinent part, that the first circuit is a band pass filter connected to an antenna. It is undisputed that Nishimura’s band pass filter 602 is connected indirectly to antennas 611 in Figure 6. See App. Br. 6 (acknowledging this indirect coupling). Despite Appellant’s arguments to the contrary (App. Br. 6-7), nothing in the claim requires connecting the recited band pass filter to the antenna directly as the Examiner indicates; the claim also encompasses indirect connections as well, namely those with intervening components. See Ans. 10. Indeed, this distinction between direct and indirect electrical connections was addressed by the Federal Circuit, which found no error in construing the recited term “electrically coupled” as “arranged so that 9 Appeal 2017-006977 Application 14/170,248 electrical signals may be passed either directly, or indirectly via intervening circuitry, from one component to another.” Mems Tech. Berhad v. Int’l Trade Comm’n, No. 2010-1018, 2011 WL 2214091 (Fed. Cir. 2011) (unpublished), at *6-9. Notably, the court declined to limit the recited electrical coupling to direct electrical coupling in view of the term’s plain meaning. Id. at *7-9. Although Appellant’s Figures 1A and IB show connecting a band pass filter to an antenna directly as Appellant indicates (App. Br. 6), we decline to import that embodiment into the claim. See Phillips v. A WH Corp., 415 F.3d 1303, 1323 (Fed. Cir. 2005) (enbanc) (“[Although the specification often describes very specific embodiments of the invention, we have repeatedly warned against confining the claims to those embodiments. . . . [CJlaims may embrace different subject matter than is illustrated in the specific embodiments in the specification.”) (citations and internal quotation marks omitted). To the extent that Appellant contends that the recited band pass filter must necessarily be connected directly to an antenna with no intervening components, there is no persuasive evidence on this record to substantiate such a contention. Although a direct connection is shown in the embodiment of Appellant’s Figures 1A and IB, we nevertheless find nothing on this record precluding an indirect connection as well—an interpretation that is not only reasonable on this record, but is also consistent with Berhad as noted above. Therefore, we are not persuaded that the Examiner erred in rejecting claim 6. 10 Appeal 2017-006977 Application 14/170,248 CONCLUSION The Examiner did not err in rejecting claims 1 and 6 under § 103. DECISION We affirm the Examiner’s decision to reject claims 1 and 6. No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a)(l)(iv). AFFIRMED 11