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`IN THE UNITED STATES PATENT AND TRADEMARK OFFICE
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`In re patent of: Maguire
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`U.S. Patent No. 8,305,840
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`Issued: November 6, 2012
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`Title: DOWNSCAN IMAGING
`SONAR
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`70052.703
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`Petition for Inter Partes Review
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`Attorney Docket No.:
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`Customer No.:
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`Real Party in Interest: Raymarine, Inc.
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`27683
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`PETITION FOR INTER PARTES REVIEW
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`Mail Stop Patent Board
`Patent Trial and Appeal Board
`P.O. Box 1450
`Alexandria, VA 22313-1450
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`Dear Sir:
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`Pursuant to the provisions of 35 U.S.C. §§ 311-319, Raymarine, Inc.
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`(“Petitioner”) hereby petitions the Patent Trial and Appeal Board to institute an
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`inter partes review of claims 4, 6, 8-9, 12-15, 22, 27-28, 34-37, 43, 54-55, 63, and
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`65-68 of United States Patent No. 8,305,840 (“the ’840 Patent,” Exhibit RAY-
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`1001) that issued on November 6, 2012, to Brian T. Maguire, resulting from U.S.
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`Patent Application No. 12/460,139, filed on July 14, 2009. According to USPTO
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`records, the ’840 Patent has recently been assigned to Navico Holding AS.
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`TABLE OF CONTENTS
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`I. Mandatory Notices ............................................................................................... 1
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`A. Real Party-in-Interest .................................................................................... 1
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`B. Related Matters ............................................................................................. 1
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`C. Lead and Back-up Counsel and Service Information ................................... 1
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`II. Grounds for Standing ........................................................................................... 2
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`III. Relief Requested .................................................................................................. 2
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`IV. The Reasons for the Requested Relief ................................................................. 2
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`A. Summary of Reasons .................................................................................... 2
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`B. The ’840 Patent ............................................................................................. 5
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`1. Overview ................................................................................................. 5
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`2. Prosecution History ................................................................................. 7
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`C. Identification of Challenges........................................................................ 10
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`1. Challenged Claims ................................................................................ 10
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`2. Statutory Grounds for Challenges ......................................................... 10
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`3. Claim Construction ................................................................................ 11
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`4. Identification of How the Claims Are Unpatentable ............................. 13
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`i. Challenge #1: Claims 4, 6, 9, 12-15, 22, and 34-37 are obvious
`under 35 U.S.C. § 103(a) over Hydrography ......... 13
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`ii. Challenge #2: Claims 4, 6, 9, 12-15, 22, and 34-37 are obvious
`under 35 U.S.C. § 103(a) over Hydrography in view
`of Boucher ’552 ...................................................... 29
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`ii
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`iii. Challenge #3: Claims 4, 6, 9, 12-15, 22, and 34-37 are obvious
`under 35 U.S.C. § 103(a) over Hydrography in view
`of Boucher ‘798 and DeRoos ................................. 34
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`iv. Challenge #4: Claims 8, 12-15, 27-28, 34-37,43, 54-55, 63, and 65-
`68 are obvious under 35 U.S.C. § 103(a) over
`Hydrography in view of Adams and Betts ............. 39
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`v. Challenge #5: Claims 8, 12-15, 27-28, 34-37, 43, 54-55, 63, and
`65-68 are obvious under 35 U.S.C. § 103(a) over
`Hydrography in view of Boucher ‘552, Adams, and
`Betts ........................................................................ 51
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`vi. Challenge #6: Claims 8, 12-15, 27-28, 34-37, 43, 54-55, 63, and
`65-68 are obvious under 35 U.S.C. § 103(a) over
`Hydrography in view of Boucher ‘798, DeRoos,
`Adams, and Betts .................................................... 55
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`V. Conclusion .........................................................................................................59
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`I. Mandatory Notices
`A. Real Party-in-Interest
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`The real party-in-interest is Raymarine, Inc. a subsidiary of FLIR Systems, Inc.
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`B. Related Matters
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`As of the filing date of this petition, the ‘840 Patent was asserted against the real
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`party-in-interest in Navico, Inc. v. Raymarine, Inc. 4:13-cv-00251 (N.D. Okla.).
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`Petitioner filed petition IPR2013-00355 for inter partes review of claims 1-2, 5, 7,
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`16-21, 23, 25, 30, 32, 38-42, 45, 64, and 70-73 of the ‘840 Patent on June 13, 2013.
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`Concurrently with this petition, Petitioner is filing a petition for inter partes review
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`of claims 3, 10-11, 24, 26, 29, 31, 33, 44, 46-53, 56-62, and 69 of the ‘840 Patent.
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`C. Lead and Back-up Counsel and Service Information
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`Lead Counsel
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`David L. McCombs
`HAYNES AND BOONE, LLP
`2323 Victory Ave. Suite 700
`Dallas, TX 75219
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`Back-up Counsel
`Julie M. Nickols
`HAYNES AND BOONE, LLP
`2323 Victory Ave. Suite 700
`Dallas, TX 75219
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`Greg Michelson
`HAYNES AND BOONE, LLP
`18100 Von Karman Ave.
`Suite 750
`Irvine, California 92612
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`Phillip B. Philbin
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`
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`Phone: (972) 739-8636
`Fax: (214) 200-0853
`david.mccombs.ipr@haynesboone.com
`USPTO Reg. No. 32,271
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`Phone: (972) 739-8640
`Fax: (214) 200-0853
`julie.nickols.ipr@haynesboone.com
`USPTO Reg. No. 50,826
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`Phone: (949) 202-3022
`Fax: (214) 200-0853
`greg.michelson@haynesboone.com
`USPTO Reg. No. 44,940
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`Phone: (214) 651-5684
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`1
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`HAYNES AND BOONE, LLP
`2323 Victory Ave. Suite 700
`Dallas, TX 75219
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`Fax: (214) 200-0672
`phillip.philbin.ipr@haynesboone.com
`USPTO Reg. No. 35,979
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`II. Grounds for Standing
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`Petitioner certifies that the ’840 Patent is eligible for inter partes review and
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`Petitioner is not estopped or barred from requesting inter partes review of the ’840
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`Patent. A complaint asserting that Petitioner infringes the ‘840 Patent was filed on
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`April 29, 2013, but Petitioner has not yet been served. Petitioner has not initiated a
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`civil action challenging validity of any claim of the ‘840 Patent.
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`III. Relief Requested
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`Petitioner asks that the Board review the accompanying prior art, analysis,
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`and declarations, institute a trial for inter partes review of claims 4, 6, 8-9, 12-15,
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`22, 27-28, 34-37, 43, 54-55, 63, and 65-68 of the ’840 Patent, and cancel those
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`claims as unpatentable.
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`IV. The Reasons for the Requested Relief
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`The full statement of the reasons for the relief requested is as follows:
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`A.
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`Summary of Reasons
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`The ’840 Patent relates to a downward facing (referred to as “downscan” in
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`the ‘840 Patent) imaging sonar system utilizing a rectangular (referred to as
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`“linear” in the ‘840 Patent) transducer element to provide images of the sea floor
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`and other objects in the water column beneath a vessel. In general, the ’840 Patent
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`describes a sonar assembly with a conventional transducer having a rectangular
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`shape, with the longitudinal length of the transducer positioned in a fore-to-aft
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`direction. Similar to virtually all sonar systems, the transducer repeatedly emits
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`sonar beams (in this case, fan-shaped sonar beams, because the transducer has a
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`rectangular shape) perpendicular to the surface of the water as the watercraft
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`travels. A signal processor receives the sonar returns and creates an image from a
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`composite of images of the fan shaped regions of the underwater environment.
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`All these features were known in the art prior to 2009, when the application
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`that issued as the ’840 Patent was filed. For example, single transducer elements
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`in all shapes and sizes and mounted to watercraft in a wide variety of orientations
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`(of course including the default “vertically down” orientation) were known to
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`persons of ordinary skill in the art before 2009. Furthermore, aiming any type of
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`transducer (and particularly transducers producing fan-shaped beams) in any
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`variety of directions, including “downscan,” was also commonly known. As noted
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`in DeRoos (RAY-1008):
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`…forward-look sonar would be used in much the same manner as would side-
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`scan sonar. The main difference is the orientation of the sonar relative to the
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`vehicle on which it is mounted. Where the side-scan sonar is mounted to look
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`out toward the sides of the vehicle, the forward-look sonar would be mounted to
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`image the area in front of the vehicle. […] Bathymetric, or down-looking
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`sonars, are used for bottom contour mapping, depth sensing, fish finding,
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`altitude sensing, and other similar tasks. The bathymetric sonars are very
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`similar to forward-look sonars except they are aimed downward. The
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`transmitted beam is narrow along the travel path of the sonar and wide in the
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`plane normal to the direction of travel [e.g., the transmitted beams are “fan-
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`shaped”] (RAY-1008, p.129)
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`Thus, side-scan, forward-scan, and down-looking (“downscan”) sonar systems are
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`all effectively interchangeable, and there is no special technique or novelty
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`involved in aiming a rectangular transducer downward. (RAY-1009, ¶23; RAY-
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`1010, ¶23)
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`The references cited as evidence in this petition, alone or in combination,
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`anticipate or render obvious the claims of the ’840 Patent. The references include
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`references omitted from the Examiner’s review, along with references buried in the
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`flood of over 300 patent and non-patent publications presented during prosecution
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`and never used in a rejection. To explain, the Examiner for the ‘840 Patent stated,
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`on the record, that the number of references submitted in the ‘840 Patent was an
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`“excessive number,” and because most were provided without citations or
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`indications of relevance, he was forced to provide only “cursory review.” Thus,
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`the Examiner was unable to articulate an effective rejection of the ‘840 Patent, due
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`at least in part to an inability to investigate all the cited references fully while
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`attempting to perform a substantive prior art search.
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`For example, the Examiner was not made aware of a 2002 textbook entitled
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`Hydrography (RAY-1003), which includes a chapter dedicated to basic sonar
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`techniques and systems, including a watercraft-mounted, downward facing sonar
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`transducer having a rectangular shape. Hydrography shows a rectangular
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`transducer producing downward facing fan-shaped beams, perpendicular to the
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`surface of the water, as the watercraft travels. Hydrography also teaches that sonar
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`returns are used conventionally to generate a composite image of the underwater
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`environment over which the watercraft has traveled.
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`The Examiner was also not made aware of either of two prior-filed US
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`patent applications by Airmar Technology Corporation disclosing systems
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`including a downward facing rectangular (e.g., “linear”) transducer. The
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`corresponding patents, (RAY-1004; RAY-1005), demonstrate that Airmar had
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`previously developed a product that included a linear transducer for downward
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`facing sonar.
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`In summary, this petition demonstrates that at least claims 4, 6, 8-9, 12-15,
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`22, 27-28, 34-37, 43, 54-55, 63, and 65-68 all recite features that were known in
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`the prior art and, therefore, are anticipated by or rendered obvious over one or
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`more references cited herein.
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`B.
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`The ’840 Patent
`1. Overview
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`The ’840 Patent includes 73 claims and three independent claims 1, 23, and
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`73, each of which are separately challenged in petition IPR2013-00355, as noted
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`above in Related Matters. Each independent claim is directed to a sonar assembly
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`comprising a rectangular/ linear transducer element positioned in a housing
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`mountable to a watercraft. The first two independent claims 1 and 23 recite a
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`downward facing single rectangular transducer element positioned within a
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`housing mountable to a watercraft, as shown in FIG. 8B. The
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`third independent claim 73 also recites a rectangular
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`transducer element, but without explicitly requiring the
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`transducer element to be single or downward facing (“downscan”).
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`Due to the rectangular geometry of the
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`downward facing transducer, it inherently projects a
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`fan-shaped sonar beam perpendicular to the plane of
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`the surface of the body of water as shown in FIG.
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`9A (e.g., the middle one of the three transducers).
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`The fan-shaped sonar beams are repeatedly emitted as the watercraft travels, and
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`the sonar returns are processed by a sonar signal processor to create an image of
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`the underwater environment from a composite of images arranged in the
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`progressive order of the travelling watercraft. Although the ‘840 Patent does not
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`use the term “composite of images” to describe creating an image using a single
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`transducer element (“composite” is used only once in the description of the ‘840
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`Patent, at 13:59), one example which apparently uses a composite of images is
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`provided at FIG. 12B. In FIG. 12B, “[b]oat position is represented by the numeral
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`0, or some other desirable icon, for the most recent sonar pings, and the oldest
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`composite image produced
`by down facing
`rectangular element with
`oldest sonar pings to the
`left and most recent sonar
`pings to the right
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`sonar pings are presented by the left side of the screen, presenting a scrolling
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`image as the boat (and transducer) move across the water surface over time.”
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`None of the recited features were novel and nonobvious when the’840 Patent was
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`filed on July 14, 2009.
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`2.
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`Prosecution History
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`The ’840 Patent, originally assigned to Navico, Inc. (“Applicant”) issued on
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`November 6, 2012. Applicant submitted over 300 references in six Information
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`Disclosure Statements, an amount characterized by the Examiner as an “excessive
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`number of references . . .[that] have only been given a cursory review to gather
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`relevance to the claimed inventions.” (RAY-1002, Final Rejection, Dec. 20, 2011)
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`Early in prosecution, Applicant elected to prosecute Species II described in
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`Claims 57-99 directed to “a linear transducer array and a sonar system including
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`the linear transducer array.” The first substantive Office Action rejected all of the
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`claims under 35 U.S.C. § 103(a) over US Pat. No. 5,561,641 to Nishimori in view
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`of US Pat. App. Pub. No. 2006/0002232 to Shah et al., together or in combination
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`with other prior art references. An Examiner interview was conducted in which
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`the Applicant explained its only alleged point of novelty was pointing a rectangular
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`transducer downward from a watercraft:
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`[I]t was conventional in the prior art to aim a conical beam straight down from
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`the watercraft, for purposes of depth sounding as well as acquiring images of
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`water-borne objects such as fish. It was further explained that linear or
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`rectangular transducers were conventionally used for side scan purposes, using
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`the fan-shaped beams produced by such linear transducers to insonify regions to
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`the port and starboard sides of a watercraft. As presently understood by
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`Applicant, however, no prior art reference cited by Applicant or the
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`Examiner has a linear transducer used for downscan as described in
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`Applicant’s application. (RAY-1002, Amendment dated Nov. 30, 2011,
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`emphasis added)
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`In a written response, Applicant distinguished Nishimori as failing to
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`disclose a linear transducer element producing fan-shaped beams in a direction
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`substantially perpendicular to the plane of the surface of the water. Applicant also
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`added 38 new claims. A final Office Action was then issued with an additional
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`election of species requirement and a rejection of all claims under 35 U.S.C. §
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`103(a) over US Pat. No. 5,805,528 to Hamada in view of a publication describing
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`an Imagenex Model 855 sonar system, together or in combination with other
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`references. Applicant responded by electing the species directed toward “a
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`singular downscan linear transducer element with optional conical downscan
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`transducer element,” and then amended independent claims 57 and 76 (issued
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`claims 1 and 23) to recite a “single” linear “downscan” transducer element and to
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`8
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`include a sonar signal processor for receiving return sonar signals and processing
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`the signals to create an image. Applicant argued:
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`Hamada requires the use of multiple transducer elements that are physically
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`distributed in an array, as distinct from a single linear transducer element. . . . In
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`contrast, Applicant’s claimed invention uses a single linear transducer element
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`to produce a single-transmission fan-shaped beam directed beneath the boat, and
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`sonar returns from the narrow region insonified by the fan-shaped beam are
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`received with no phased-array beam steering required. (RAY-1002, Amnd.
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`After Final dated Feb. 21, 2012)
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`Applicant then explained the meaning of a single linear downscan transducer
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`element:
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` It will be understood, of course, that the recitation of a "single linear downscan
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`transducer element" does not require the single element to be a monolithic
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`structure formed of a single crystal of material. It is well known in the
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`transducer field that a plurality of such crystals can be arranged (e.g., end-to-
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`end) and can be electrically connected to circuitry such that the plurality of
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`crystals act together as if they were a single crystal or element. Claims 57 and 76
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`encompass any “single downscan transducer element” (whether monolithic or
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`not) as distinct from a multi-element phased array-type transducer. (Id.)
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`A Notice of Allowance subsequently issued without providing Reasons for
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`Allowance. Petitioner notes that issued claim 73 does not expressly recite the
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`“single” and “downscan” limitations, which is inconsistent with the prosecution
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`history and the admitted prior art.
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`C.
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`Identification of Challenges
`1.
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`Challenged Claims
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`Claims 4, 6, 8-9, 12-15, 22, 27-28, 34-37, 43, 54-55, 63, and 65-68 of the
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`’840 Patent are challenged in this petition. Claims 3-4, 6, 8-15, and 22 depend
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`from and incorporate Claim 1, and Claims 24, 26-29, 31, 33-37, 43-44, 46-63, and
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`65-69 depend from and incorporate Claim 23. Claims 1 and 23 are addressed in
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`the challenges below, and, as noted above, are separately challenged in petition
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`IPR2013-00355.
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`2.
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`Statutory Grounds for Challenges
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`Challenge #1: Claims 4, 6, 9, 12-15, 22, and 34-37 are obvious under 35
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`U.S.C. § 103(a) over de Jong, C.D. et al., Hydrography, (1st ed. 2002)
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`(“Hydrography”), an introductory-level textbook published in 2002. (See, RAY-
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`1003)
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`Challenge #2: Claims 4, 6, 9, 12-15, 22, and 34-37 are obvious under 35
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`U.S.C. § 103(a) over Hydrography in view of U.S. Pat. No. 7,961,552 to Boucher
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`et al. (“Boucher ’552”). Boucher ‘522 was filed Aug. 28, 2008 and is prior art
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`under 35 U.S.C. § 102(e). (See, RAY-1004)
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`Challenge #3: Claims 4, 6, 9, 12-15, 22, and 34-37 are obvious under 35
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`U.S.C. § 103(a) over Hydrography in view U.S. Pat. No. 6,904,798 to Boucher et
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`al. (“Boucher ‘798”) and DeRoos, Bradley G. et al., Technical Survey and
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`Evaluation of Underwater Sensors and Remotely Operated Vehicles, (May 1993)
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`(“DeRoos”). Boucher ‘798 was filed Jul. 30, 2003, and both references are prior
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`art under 35 U.S.C. § 102(b). (See, RAY-1005, RAY-1008)
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`Challenge #4: Claims 8, 27-28, 43, 54-55, 63, and 65-68 are obvious under
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`35 U.S.C. § 103(a) over Hydrography in view of U.S. Pat. No. 5,184,330 to Adams
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`et al. (“Adams”) and U.S. Pat. No. 7,652,952 to Betts et al. (“Betts”). Adams was
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`filed June 25, 1991, Betts was filed on August 2, 2005, and both are prior art under
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`35 U.S.C. § 102(b). (See, RAY-1006; RAY-1007)
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`Challenge #5: Claims 8, 27-28, 43, 54-55, 63, and 65-68 are obvious under
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`35 U.S.C. § 103(a) over Hydrography in view of Boucher ‘522, Adams, and Betts.
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`Challenge #6: Claims 8, 27-28, 43, 54-55, 63, and 65-68 are obvious under
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`35 U.S.C. § 103(a) over Hydrography in view of Boucher ‘798, DeRoos, Adams,
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`and Betts.
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`3.
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`Claim Construction
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`This petition presents claim analysis in a manner that is consistent with the
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`broadest reasonable interpretation in light of the specification. See 37 C.F.R. §
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`42.100(b). Claim terms are given their ordinary and accustomed meaning as would
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`be understood by one of ordinary skill in the art, unless the inventor, as a
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`lexicographer, has set forth a special meaning for a term. Multiform Desiccants,
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`Inc. v. Medzam, Ltd., 133 F.3d 1473, 1477 (Fed. Cir. 1998); York Prods., Inc. v.
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`Central Tractor Farm & Family Ctr., 99 F.3d 1568, 1572 (Fed. Cir. 1996).
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`In the ’840 Patent, the inventor did not act as a lexicographer and did not provide a
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`special meaning for any of the claim terms. Accordingly, using the broadest
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`reasonable interpretation standard, the terms should be given their ordinary and
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`custom meaning as understood by a person of ordinary skill in the art:
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`• “a single linear downscan transducer”: a downwardly directed transducer
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`comprising either a single monolithic rectangular shaped transducer element or a
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`plurality of transducer elements arranged end-to-end and electrically connected to
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`act as a single rectangular element. (RAY-1009, ¶26-28; RAY-1010, ¶26-28;
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`RAY-1001, 2:66-3:3, 9:36-46; RAY-1002, Feb. 21, 2012 Amnd. After Final)
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`• “fan-shaped sonar beam”: a sonar beam with a narrow beamwidth in one
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`direction and a wide beamwidth in the other perpendicular direction. (RAY-1009,
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`¶29-30; RAY-1010, ¶29-30; RAY-1001, 10:21-25)
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`• “sequentially insonify different fan-shaped regions of the underwater
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`environment”: emit sonar pulses into an underwater environment and detect echo
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`returns from the underwater environment as the transducer is moved across the
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`water over time. (RAY-1009, ¶31-32; RAY-1010, ¶31-32; RAY-1001, 3:7-8 and
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`13:55-61)
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`• “composite of images of the fan-shaped regions”: sonar reflection data from
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`multiple fan-shaped regions represented on a common display. (RAY-1009, ¶33-
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`12
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`Petition for Inter Partes Review of U.S. Patent No. 8,305,840
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`34; RAY-1010, ¶33-34; RAY-1001, 13:53-64)
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`The foregoing proposed claim construction is presented by Petitioner using
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`the broadest reasonable interpretation standard applied for purposes of inter partes
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`review. Petitioner reserves the right to advocate a different claim interpretation in
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`district court or any other forum in accordance with the claim construction
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`standards applied in such forum.
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`4.
`Identification of How the Claims Are Unpatentable
`i. Challenge #1: Claims 4, 6, 9, 12-15, 22, and 34-37 are obvious
`under 35 U.S.C. § 103(a) over Hydrography
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`Claims 4, 6, 9, 12-15, 22, and 34-37 are obvious under 35 U.S.C. § 103(a)
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`over Hydrography (RAY-1003, published in 2002). The analysis of the
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`independent claims from which the challenged claims depend is provided for
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`completeness.
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`During prosecution, the Applicant stated that, “no prior art reference cited by
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`Applicant or the Examiner has a linear transducer used for downscan as described
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`in Applicant’s application.” Hydrography, published seven years before the filing
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`date of the ‘840 Patent, discloses just such a “downscan” or downward facing
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`transducer. Specifically, chapter 11 of Hydrography teaches the use of a sonar
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`assembly with a single linear downscan transducer element that produces fan-
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`shaped beams for imaging an underwater environment. (RAY-1009, ¶35-37;
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`RAY-1010, ¶35-37; RAY-1003, p. 325-326)
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`Hydrography is laid out in several basic sections that build upon the
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`previous sections. Section 11.1 introduces the basic aspects of echo-sounding
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`generally and explains how to use transducers to image the area below and around
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`a vessel. Section 11.1 discusses transducers generally, noting: “[c]eramics can be
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`molded in any desired shape.” (RAY-1003, p. 321) Section 11.2 details how
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`beam shapes are selected and introduces two main transducer shapes – circular and
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`rectangular/linear. Section 11.3 discusses using single beam transducers, and
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`Section 11.4 introduces the concept of multi-beam transducers.” (RAY-1009, ¶35-
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`37; RAY-1010, ¶35-37)
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`Claim 1 [1.0] A sonar assembly for imaging an underwater environment beneath
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`a watercraft traveling on a surface of a body of water, the sonar assembly
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`comprising:
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`Section 11.1 of Hydrography, which describes echo sounder systems generally,
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`teaches sonar assemblies: “An acoustic pulse transmitted by a transducer travels
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`through the column of water and is reflected by the target (sea floor) back to the
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`hydrophone.” (RAY-1003, p.319) “The transducer is mounted on the ship’s hull
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`and is in contact with water.” (RAY-1003, p. 320) As shown in FIG. 11.8, the
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`watercraft
`traveling
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`recorded
`image of
`underwater
`environment
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`underwater environment is imaged as the watercraft travels on the surface of a
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`body of water. (RAY-1003, p. 323 annotated) Thus, Hydrography teaches [1.0].
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`(RAY-1009, ¶37; RAY-1010, ¶37, [charts are included in the paragraphs])
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`[1.1] a housing mountable to the watercraft
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`Hydrography teaches a housing mounted to the
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`watercraft: “The transducer is mounted on the ship’s
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`hull and is in contact with water.” (RAY-1003, p.320)
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`Hydrography at FIG. 11.3 depicts the housing with a transducer mounted therein.
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`Thus, Hydrography teaches [1.1]. (RAY-1009, ¶37; RAY-1010, ¶37)
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`[1.2] a single linear downscan transducer element positioned within the housing
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`Section 11.2 of Hydrography, which discusses the two main transducer shapes
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`used in echo sounding, teaches the use of a single linear downscan transducer
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`element as claimed: “A single point source radiates energy omni-directionally. In
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`the case of transducers used for hydrography, energy is normally concentrated
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`along the axis that is perpendicular to the radiating surface.” (RAY-1003, p.324)
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`FIG. 11.12 illustrates a
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`single linear downscan
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`transducer element. As
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`indicated by its shape,
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`proportion, and
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`
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`wide
`beamwidth
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`rectangular shape
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`fan-shaped
`beam
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`narrow beamwidth
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`arrangement within FIG. 11.12, the beam footprint is shown directly vertically
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`beneath the linear or rectangular transducer. Furthermore, as shown in FIG. 11.8
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`(see [1.0]) and 11.9 (see [1.4]) the sonar beams contemplated in these portions of
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`Hydrography are directed generally vertically downward. (RAY-1003, p.326, FIG.
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`11.12, annotated) Thus, Hydrography teaches [1.2]. (RAY-1009, ¶37; RAY-1010,
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`¶37)
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` [1.3] the linear downscan transducer element having a substantially rectangular
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`shape configured to produce a fan-shaped sonar beam having a relatively
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`narrow beamwidth in a direction parallel to a longitudinal length of the linear
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`downscan transducer element and a relatively wide beamwidth in a direction
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`perpendicular to the longitudinal length of the transducer element,
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`Section 11.2 of Hydrography teaches:
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` “A rectangular transducer will produce a different beamwidth in each of its two
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`principal axes. Consider a rectangular transducer of dimension L1 (shorter
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`dimension) by L2 (longer dimension). The beam footprint will be narrow in the
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`direction parallel to the long direction of the transducer. By contrast, the
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`footprint will be wide in the direction orthogonal to the long direction of the
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`transducer (i.e., parallel to the short dimension of the transducer), as shown in
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`Figure 11.12 above for claim element [1.2]. The wide beamwidth β1 and the
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`narrow beamwidth β2 of a rectangular transducer, both expressed in degrees, are
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`given respectively by .” (RAY-1003, p.326)
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`Note that FIG. 11.12 of Hydrography should indicate L1 as the shorter
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`dimension and L2 as the longer dimension to correctly correspond to the cited text
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`of Hydrography. One skilled in the art would recognize this error as a simple
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`typographical error in the printing of the book. Thus, Hydrography teaches [1.3].
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`(RAY-1009,¶37; RAY-1010,¶37)
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`[1.4] the linear downscan transducer element being positioned with the
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`longitudinal length thereof extending in a fore-to-aft direction of the housing
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`As shown in FIG. 11.12 of Hydrography, the linear downscan transducer produces
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`a wide beamwidth in the direction perpendicular to the longitudinal length of the
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`transducer. In order to provide the wide fan-shaped beam and maximize seabed
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`coverage for the fore-to-aft positioned ship shown in FIG. 11.9, the transducer of
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`FIG. 11.12 must be positioned with the longitudinal length in the fore-to-aft
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`direction. (RAY-1003, FIG. 11.9 and FIG. 11.12 annotated) It is very unlikely
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`that such a transducer would be by default oriented with the longitudinal length in
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`other directions, as those types of orientations would produce fan-shaped beams
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`inefficiently sweeping out relatively narrow portions of the sea bed/water column
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`beneath the vessel as the vessel traveled in its normal fore-to-aft direction.
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`aft
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`fore
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`Thus, Hydrography teaches [1.4]. (RAY-1009,¶37;RAY-1010,¶37)
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`[1.5] wherein the linear downscan transducer element is positioned within the
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`housing to project fan-shaped sonar beams in a direction substantially
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`perpendicular to a plane corresponding to the surface of the body of water,
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`General section 11.1 of Hydrography teaches, “[a] single point source radiates
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`energy omni-directionally. In the case of transducers used for hydrography, energy
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`is normally concentrated along the axis that is perpendicular to the radiating
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`surface.” (RAY-1003, p. 324) As shown in FIGs. 11.8, 9, and 12 of Hydrography
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`(see [1.4], [1.6]), the axis perpendicular to the radiating surface is directed
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`downward generating a “beam footprint” on the sea floor directly below the water
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`vessel, as viewed from multiple orientations. Hydrography therefore teaches
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`projecting fan-shaped beams in the direction perpendicular to the surface of the
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`water. Thus, Hydrography teaches [1.5].(RAY-1009,¶37;RAY-1010,¶37)
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`[1.6] said sonar beams being repeatedly emitted so as to sequentially insonify
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`different fan-shaped regions of the underwater environment as the watercraft
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`travels; and
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`As shown in FIG. 11.8, and set forth in the general Section 11.1 of Hydrography,
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`sonar beams are repeatedly emitted to sequentially insonify different underwater
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`fan-shaped regions as the watercraft “pass[es] across” the sea floor. One skilled in
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`the art would recognize that the regions could be fan-shaped, conical, or otherwise
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`shaped as taught by Hydrography, and produce a recorded profile with some
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`amount of hyperbolic echo, as shown in exaggerated form in FIG. 11.8. (RAY-
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`watercraft
`traveling while
`sequentially
`insonifying the
`water under the
`watercraft
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`1009,¶37; RAY-1010, ¶37) Hydrography also teaches that:
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`[t]he T/R [transmitter/receiver] switch is used to trigger a pulse with a specific
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`length. Normally the pulse length varies from 0.1 to 50 ms. In shallow water, a
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`single short pulse of length of 0.2 ms is transmitted and received before the next
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`pulse is transmitted. In deep water, many pulses of lengths varying