14525347 (P.T.A.B. Sep. 29, 2017)

Ex Parte Pelley et al

Patent Trial and Appeal BoardSep 29, 2017

14525347 (P.T.A.B. Sep. 29, 2017)

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. 14/525,347 10/28/2014 Perry H. Pelley 1080-DN30844TK 2874 114905 7590 NXP-Davidson Sheehan 6501 William Cannon Drive West Austin, TX 78735 EXAMINER MANDALA, MICHELLE ART UNIT PAPER NUMBER 2829 NOTIFICATION DATE DELIVERY MODE 10/03/2017 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 .u s @ nxp. com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte PERRY H. PELLEY, MICHAEL B. McSHANE, and TIM V. PHAM Appeal 2017-002812 Application 14/525,3471 Technology Center 2800 Before ADRIENE LEPIANE HANLON, KAREN M. HASTINGS, and DONNA M. PRAISS, Administrative Patent Judges. HANLON, Administrative Patent Judge. DECISION ON APPEAL A. STATEMENT OF THE CASE The Appellants filed an appeal under 35 U.S.C. § 134 from an Examiner’s decision finally rejecting claims 1—10 and 21. Claims 11—20 are also pending but have been withdrawn from consideration. We have jurisdiction under 35 U.S.C. § 6(b). We REVERSE. 1 According to the Appellants, the real party in interest is Freescale Semiconductor, Inc. Appeal Brief dated August 8, 2016 (“App. Br.”), at 1. Appeal 2017-002812 Application 14/525,347 Representative claims 1 and 10 are reproduced below from the Claims Appendix. The limitations at issue are italicized. 1. An integrated circuit device, comprising: a die address bus; a plurality of dies arranged in a stacked die integrated circuit, the plurality of dies comprising a first die including: a storage location configured to store information indicating a width of the die address bus; and an interface configured to receive a die address via the die address bus based on the information. App. Br. 9. 10. An integrated circuit device, comprising: a plurality of stacked die comprising a first die and a second die; and a data bus having a width based on the first die being disposed on the stack in a first orientation of a plurality of possible orientations and the second die being disposed on the stack in a second orientation of the plurality of orientations. App. Br. 10-11. The Examiner maintains the following rejections on appeal: (1) claims 1,9, and 21 under 35 U.S.C. § 103(a) as unpatentable over Ide;2 and (2) claims 2—8 and 10 under 35 U.S.C. § 103(a) as unpatentable over Ide in view of Foster, Sr. et al.3 B. DISCUSSION 1. Claims 1 and 21 2 US 2012/0134193 Al, published May 31, 2012 (“Ide”). 3 US 2011/0109381 Al, published May 12, 2011 (“Foster”). 2 Appeal 2017-002812 Application 14/525,347 The Examiner finds Ide discloses an integrated circuit device comprising a die address bus and a plurality of dies arranged in a stacked die integrated circuit (Ide Fig. 10, CC0-CC7) wherein a first die (e.g., CC7 or CCO) includes a storage location (43, SID) and an interface (41, access control circuit). Final 4.4 The Examiner finds: In reference to the claim language referring to the function of the device, i.e., “a storage location [configured] to store information indicating a width of the die address bus” and “an interface configured to receive a die address via the die address bus based on the information”, the device of Ide is capable of performing said functions. For example, the SID (43) of Ide contains a chip address register (|0048) but could also be programmed to contain information about the width of the die address bus (see e.g. 10049, programming the SID using TSVs). Final 5 (emphasis added). The Appellants argue that in In re Gianelli, 739 F.3d 1375 (Fed. Cir. 2014), the Court “held that the term ‘configured to’ ... in a device claim requires that the device be designed or constructed to be able to perform the recited features.” App. Br. 3^4 (emphasis omitted). In this case, the Appellants argue that the Examiner “has failed to show that it is obvious to modify [the] storage location and interface of Ide to correspond to the [limitation at issue] of claim 1.” App. Br. 4. According to the Examiner: [I]t is well-known in the art that a common method of addressing dies is to split the full address into two (or more) pieces, which are delivered throughout the time cycle of an operation. For example, a full 32-bit address may be chopped into two pieces, each piece being transmitted through a 16-line bus [i.e., n address width], and the two pieces being recombined by the die interface to form the full address [i.e., 2n address width] for an operation. This addressing scheme is nearly ubiquitous in large-memory applications because it allows the 4 Final Office Action dated December 11, 2015. 3 Appeal 2017-002812 Application 14/525,347 transmission of full addresses (with a 2n address width) through far fewer bus lines; therefore, the address bus of a device does not have to have n lines, which reduces manufacturing costs associated with creating larger and larger bus sizes. However, for such an addressing system to work, the receiving interface (e.g. 41 in Ide) must have information determining the size of the full die address and the die address bus in order to properly determine the intended address being transmitted by the die address bus. Thus, it would have been obvious to one of ordinary skill in the art to modify Ide with information indicating a width of the die address bus, as described in the rejection of claim 1 . . . . Final 2 (original emphasis omitted); see also Ans. 5.5 The Appellants argue: [T]he Office provides no support for this assertion, and has therefore failed to establish a prima facie showing of obviousness for claim 1. Further, even assuming arguendo that the assertion is correct, the mere fact that a die may receive a full address in two or more pieces does not teach “a storage location configured to store information indicating a width of the die address bus . . .” as provided by claim 1. That is, a die can receive a full address in two or more pieces without employing a storage location configured to store information indicating a width of the die address bus .... For example, assuming a die employs a fixed 16-bit address bus that receives a 32-bit address in two pieces, the die would have no need to employ a storage location indicating the width of the die address bus, as the width of the address bus is fixed and it receives the 32-bit address according to a regular pattern. App. Br. 5 (emphasis added). The Appellants argue that “under the system taught by Ide, the number of bits used to address a given die remains fixed, so it would not be obvious to program a chip address register to contain information about the width of the die address bus.” Reply Br. 3.6 5 Examiner’s Answer dated October 21, 2016. 6 Reply Brief dated December 20, 2016. 4 Appeal 2017-002812 Application 14/525,347 The Appellants’ argument is persuasive of reversible error. We recognize that SID (or chip address register) 43 (corresponding to the claimed storage location) could have been programmed to store information about the width of the die address bus, as found by the Examiner. The Examiner, however, has failed to show that the width of Ide’s die address bus is not fixed as the Appellants contend. Thus, absent the Appellants’ disclosure, it is not readily apparent on this record why one of ordinary skill in the art would have programmed SID (or chip address register) 43 with information indicating a width of the die address bus. For that reason, the § 103(a) rejection of claims 1, 9, and 21 based on Ide is not sustained. The Examiner does not rely on Foster to cure the deficiency in the § 103(a) rejection based on Ide. Therefore, the § 103(a) rejection of claims 2—8 is not sustained. 2. Claim 10 The Examiner finds Ide does not disclose “a data bus having a width based on the first die being disposed on the stack in a first orientation of a plurality of possible orientation[s] and the second die being disposed on the stack in a second orientation of the plurality of orientations” as recited in claim 10. Final 10. The Examiner, however, finds: Foster teaches an integrated circuit die stack with two types (28 and 30) of symmetrically disposed vias. Die 102 of Fig. 3 comprises a first set (30) of through silicon vias (TSVs) which also connect to electronic circuitry of the die and a second set (28) of pass-through (PTVs) which simply pass through the die without connecting to circuitry in the die (see 10019). Final 10. The Examiner finds: Taking Ide in view of Foster, a memory stack is taught in which the orientation of the chips (Fig. 3, dies 102—108) will affect the width of 5 Appeal 2017-002812 Application 14/525,347 the data bus. For instance, if die 108 is placed directly on die 102, data bus lines are required for the circuitry of both dies. However, if die 108 is flipped along a body diagonal and placed over die 102, then data bus [width] is not required for the PTV vias (which contain no information), so the data bus width is halved. In this case, the width of the data bus is a natural extension of the orientations of the two dies. Final 10-11 (emphasis added). The Appellants argue that “Foster teaches that dies are to be oriented to create connections between the dies, but does not teach or suggest that the orientation of the dies establish a bus width.” App. Br. 7. Moreover, the Appellants argue that “the [Examiner’s] rejection of claim 10 is premised on a theoretical arrangement of dies that is not actually disclosed or suggested by Foster.” App. Br. 7. More specifically, the Appellants argue: Foster teaches that “the TSVs (30) and PTVs (28) are disposed upon each identical die so that the positions of the TSVs and PTVs on each identical die are rotationally symmetrical with respect to the TSVs and PTVs on the other identical die. . . . That is, the TSVs and PTVs are disposed upon each identical die so that TSVs align with PTVs when one die is rotated 90 degrees in a same plane with respect to any other identical die.” (See, e.g., Foster para. [0026]). Thus, not only is the hypothetical arrangement of “consistently stacking” identical dies in the same orientation proposed by the Examiner not disclosed or suggested by Foster, it is inconsistent with the teaching of Foster that the dies are stacked so that each die is rotated with respect to the dies with which it connects so that TSVs align with PTVs. Reply Br. 4 (emphasis added). The Appellants’ argument is persuasive of reversible error. Foster discloses that each of dies 102, 104, 106, and 108 in Foster Figure 3 are identical. See Foster 126 (“[a]ll four dies in the example of FIG. 3 are identical”). Moreover, Foster discloses that each of dies 102, 104, 106, and 108 in a die stack are rotated relative to the previously stacked die, i.e., die 104 is rotated 90 degrees relative to die 102, 6 Appeal 2017-002812 Application 14/525,347 die 106 is rotated 90 degrees relative to die 104, and die 108 is rotated 90 degrees relative to die 106. Foster 127. We recognize that Foster discloses another embodiment wherein two or more identical dies, forming a first substack, are stacked upon one another without rotation with respect to one another. Foster 146. In that embodiment, however, a second substack (i.e., two or more identical dies stacked upon one another without rotation with respect to one another) is rotated with respect to the first substack and then mounted thereon. Foster 147. On this record, the Examiner has failed to show that the die orientations disclosed in Foster establish a bus width. For that reason, the § 103(a) rejection of claim 10 based on the combination of Ide and Foster is not sustained. C. DECISION The Examiner’s decision is reversed. REVERSED 7