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`IN THE UNITED STATES PATENT AND TRADEMARK OFFICE
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`BEFORE THE PATENT TRIAL AND APPEAL BOARD
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`PETROLEUM GEO-SERVICES INC.
`Petitioner
`v.
`
`WESTERNGECO LLC
`Patent Owner
`
`
`
`CASE IPR: Unassigned
`Patent 7,080,607 B2
`
`
`DECLARATION OF DR. JACK H. COLE, PhD.
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`1
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 1
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`TABLE OF CONTENTS
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`INTRODUCTION ............................................................................................... 3
`I.
`QUALIFICATIONS ........................................................................................ 4
`II.
`III. COMPENSATION AND RELATIONSHIP TO THE PARTIES ................ 10
`IV. LEGAL STANDARDS ................................................................................. 11
`A.
`Claim Construction .................................................................................... 11
`B.
`Person of Ordinary Skill in the Art ............................................................ 11
`V.
`SUMMARY OF OPINION ........................................................................... 12
`VI. TECHNICAL BACKGROUND ................................................................... 13
`A. Overview of Marine Seismic Surveying .................................................... 13
`B.
`Streamer Steering Overview ...................................................................... 16
`C.
`Control Systems Overview ........................................................................ 17
`VII. THE PATENT AT ISSUE ............................................................................. 20
`A.
`The Specification of the ’607 Patent .......................................................... 20
`B.
`The Time Frame of the ’607 Patent ........................................................... 23
`C.
`Claims 1 and 15 of the ’607 Patent ............................................................ 23
`D.
`Relevant Claim Terms and Their Construction ......................................... 24
`“Control unit” ................................................................................................... 25
`VIII.
`THE ABILITY TO IMPLEMENT CONTROL SYSTEMS ..................... 25
`A.
`Control Systems for Use in Marine Seismic Surveys Were Disclosed in
`the 1960s ............................................................................................................... 25
`B.
`Control Systems Became More Automated in the 1970s and 1980s with
`Advances in Computer Control Systems ............................................................. 27
`C.
`Control Systems Continued to Progress in the 1980s and 1990s .............. 32
`D.
`State of Control Systems Art at the Priority Date ...................................... 40
`IX. CONCLUSION .............................................................................................. 45
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`2
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 2
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`I, Dr. Jack Cole, hereby state the following:
`I. INTRODUCTION
`1.
`Petroleum Geo-Services, Inc. (“PGS”) has retained me to provide
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`consulting services related to the filing of a Petition for Inter Partes Review of U.S.
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`Patent No. 7.080,607 B2 (“the ’607 Patent”) (Ex. 1001). All opinions presented in
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`this report are my own.
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`2.
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`PGS has asked me to provide an opinion as to whether or not a person
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`of ordinary skill in the art (“POSA”) would have been able, by the applicable
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`priority date, to implement certain claims of the ’607 Patent relating to control
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`systems. This report describes my opinions and the reasons for them. In reaching
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`my opinion, I have relied on my extensive expertise in the control systems field
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`and the materials in the table below. I have attached the list of materials that I
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`relied on in this report as Appendix A.
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`3.
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`I have reached the opinions in this report on the basis of the materials
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`and information currently available to me. I reserve the right to modify my
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`opinions, including to supplement my opinions in light of information that
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`becomes available to me. I also reserve the right to continue my investigation and
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`analysis, including concerning materials that have not yet been produced.
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`3
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 3
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`channel, two-wire communication system for sending commands and data requests
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`to and receiving data [f]rom many positioning sensors and cable-leveling devices
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`[i.e., streamer positioning devices] distributed along a seismic streamer.” Id. at
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`3:24-28. Rouquette’s system includes “a central controller comprising an
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`intelligent modem that can scan the many streamer devices for cable-positioning
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`data each seismic shot interval,” and the modem “polls each device in an efficient
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`and orderly fashion.” Id. at 3:29-34.
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`71. Parallel, high-speed communications over fiber optic lines was also
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`known by the priority date. See Ex. 1042 (U.S. Patent 6,011,753) (“Ambs”) at
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`3:10-13. Loring C. Chien filed for a patent on March 19, 1998, and the patent was
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`issued and entitled “Control and Monitoring of Devices External to a Marine
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`Seismic Streamer.” Ex. 1042. Chien disclosed a system that “has high speed
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`communications optimized for large amounts of data.” Id. at 5:1-5. One
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`embodiment of Chien’s system used fiber optic cables so that “a large number of
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`external devices may be transmitted to and/or received from in parallel.” Id. at
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`6:2-5. Thus, communications systems and distributed computer control technology
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`available on the priority date allowed seismic surveyors to easily control a
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`substantial number of streamer positioning devices at near-instantaneous response
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`times.
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`39
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 4
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`72. Automatic control systems and sophisticated control units on the
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`streamer positioning devices that could perform positioning calculations and
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`distribution of the overall control load between the global control system and the
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`control units on the streamer positioning devices was known in the art and
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`practiced in the 1980s and 1990s. Those systems could therefore have been
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`implemented at the time of the disclosures of Rouquette, Elholm, and the ’636 PCT
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`and certainly could have been implemented by a POSA with minimal effort by
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`October 1, 1998.
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`D. State of Control Systems Art at the Priority Date
`73. By the time of the priority date, global control systems and control
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`units that could perform positioning calculations were well known in the art.
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`Automatic computer control and distributed control for use in streamer steering
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`systems were also well known in the art. The following two references, Workman
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`and Ambs, reflect this state of the art around the time of the priority date, October
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`1, 1998.
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`74.
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`In August 1998, Ricky L. Workman was issued a patent entitled
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`“Adaptive Control of Marine Seismic Streamers.” Ex. 1004 (U.S. Patent No.
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`5,790,472) (“Workman”). He disclosed what he characterized as an “improved
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`system for controlling the position and shape of marine seismic streamer cables.”
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`Ex. 1004 (Workman) at 1:6-8.
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`40
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 5
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`75. Workman disclosed that “[l]ocation sensing devices and methods for
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`determining the positions of the seismic sources and seismic streamer cables
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`[were] also well known in the art,” including GPS and acoustic positioning
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`systems. Id. at 2:10-15. Workman stated that he disclosed “an improved system
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`for controlling the position and shape of marine seismic streamer cables” using,
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`among other things, a network solution that would implement a Kalman filter. Id.
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`at 2:32-37; 3:46-48. Kalman filters use “knowledge of the motion of the system”
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`to “make a very accurate prediction of where the network will be at any [time]
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`using just the previous position and the estimated configuration motion.” Ex. 1006
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`(Vassilis Gikas et al., A Rigorous and Integrated Approach to Hydrophone and
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`Source Positioning during Multi-Streamer Offshore Seismic Exploration, 77
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`Hydrographic J. 11 (1995)) at 12 [hereinafter “Gikas Article”]. The Kalman filter
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`can be used to compute “[t]he position of any point of interest throughout the
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`spread,” including the streamer positioning devices, hydrophones, and the source.
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`See id. at 24.
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`76.
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`I understand that Kalman filters are addressed in Dr. Evans’s
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`declaration, and I have been asked to assume that use of a Kalman filter in this
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`context would satisfy the limitation of a “prediction unit” that “predicts positions
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`of at least some of the streamer positioning devices.” I have been asked whether a
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`POSA could have implemented a system that uses a Kalman filter to predict
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`41
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 6
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`positions of streamer positioning devices and use those predicted positions to
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`calculate desired changes in positions of streamer positioning devices at the time of
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`the priority date. It is my opinion that a POSA could have implemented a system
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`that uses a Kalman filter to predict positions of streamer positioning devices with
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`ease at the time of the priority date. See, e.g., id. at 12, 24; Ex. 1041 (Vassilis N.
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`Gikas, Least Squares Filtering and Testing for Positioning and Quality Control
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`During 3D Marine Seismic Surveys 3 (Aug. 1996)) at 28-29, 66-67 [hereinafter
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`“Gikas Thesis”] (Ph.D. Thesis, University of Newcastle upon Tyne) (on file with
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`Newcastle University Library); Ex. 1014 (R.P. Loweth, Manual of Offshore
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`Surveying for Geoscientists and Engineers (1st ed. 1997)) at 73-74. Kalman filters
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`were commonly used components of control systems. See Ex. 1006 (Gikas
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`Article) at 15.
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`77. Moreover, a POSA could have used the positional information from
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`the Kalman filter to calculate desired changes in the positions of streamer
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`positioning devices such as birds. From a control systems perspective, whether
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`positions are obtained by prediction or some other method is irrelevant to
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`implementing Claim 1 and 15’s limitation of calculating desired changes in
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`position of one or more of the streamer positioning devices. Whatever position
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`information is used to calculate a desired change in position, a control unit would
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`42
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 7
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`operate in the same way to implement that limitation—namely, by comparing the
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`positions with the desired positions of the streamer positioning devices.
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`78. Workman disclosed a “streamer cable control processor for deciding
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`when the streamer cables should be repositioned and for calculating a position
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`correction to reposition the streamer cables.” Ex. 1004 (Workman) at 3:59-63. In
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`Workman’s system, the operator would enter “threshold parameters” into the
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`streamer cable control processor, which could include “minimum allowable
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`separations between streamer cables,” for example. Id. at 3:65-4:7. The streamer
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`control processor would then evaluate “real time signals” received from the
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`streamer positioning devices and navigation system, among others, and compare
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`those signals to the threshold parameters to “determine when the streamer cables
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`need to be repositioned.” Id. at 4:8-15. Then the streamer control processor would
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`“calculate the position correction required to keep the streamer cables within the
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`threshold parameters,” and “the position correction is used by the streamer device
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`controller to adjust the streamer positioning devices and reposition the streamer
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`cables.” Id. at 4:15-21.
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`79. Workman thus disclosed a sophisticated global control system that
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`receives many real-time inputs, compares them to threshold parameters input by an
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`operator, and, if need be, calculates position corrections and sends commands to
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`the streamer positioning device’s local control system to reposition the device.
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`43
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 8
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`
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`80. Loran D. Ambs and Ronald E. Chambers filed an application for a
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`patent on August 3, 1998, and it was granted and entitled “Seismic Streamer
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`Position Control Module.” Ex. 1042. In one embodiment of his invention, Ambs
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`disclosed that “[c]ommands generated by a tow vessel may instruct the bird to
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`change streamer depth and/or lateral position.” Ex. 1042 (Ambs) at 3:3-5. Those
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`commands are sent to the bird, which contains a “bird microprocessor” that uses
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`“fuzzy or proportional control algorithms” to “adjust the bird ‘wing’ angles to
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`achieve a desired change in position.” Id. at 3:5-8. The “streamer-position-module
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`controller” can either be located on “the tow vessel and is in communication with
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`the [streamer positioning device],” or, in an alternative embodiment, on the bird.
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`Id. at 6:4-9.
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`81. This “streamer-position-module controller” “computes an angle-of-
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`attack for each wing.” Id. at 6:10-12. In practice, “[a] computer assisted navigator
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`apparatus (or a human operator) generates ‘STREAMER CONTROL SIGNALS’
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`(e.g. depth setting, movement right or left),” and “[t]hese signals are sent via the
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`streamer to the bird’s control apparatus (‘FUZZY LOGIC CONTROL’).” Ambs
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`thus discloses a sophisticated and automatic global control system that calculates
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`and sends commands to a sophisticated control unit that performs its own
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`calculations to produce a desired change in position of the streamer positioning
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`device.
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`44
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 9
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`82. Ambs and Workman are examples of state of the art computer
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`technology, control systems, and control theory in the context of streamer
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`positioning around the time of the priority date. They demonstrate that advanced
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`global control systems and control units on the streamer positioning device capable
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`of performing positioning calculations and were disclosed and capable of being
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`implemented by the priority date.
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`IX.
`CONCLUSION
`83. As demonstrated by the foregoing discussion, a POSA would have
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`been able to implement Claim 1 and 15’s function of “a control unit adapted to use
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`predicted positions,” determined by a prediction unit, “to calculate desired changes
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`in positions of one or more of the streamer positioning devices” with ease at the
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`time of the priority date. I conclude that a POSA would have been able to
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`implement Claims 1 and 15 of the ’607 Patent at the time of the priority date with
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`minimal effort and, indeed, more than a year before the priority date.
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`84.
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`I understand that this report will be filed as evidence in a contested
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`case before the Patent Trial and Appeal Board of the United States Patent and
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`Trademark Office. I also understand that I may be subject to cross-examination
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`concerning this report, and I will appear for cross-examination, if required of me,
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`during the time allotted for cross-examination.
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`45
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 10
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`85.
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`I hereby declare that all of the statements made herein of my own
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`knowledge are true and that all statements made on information and belief are
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`believed to be true; and further that these statements were made with knowledge
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`that willful false statements and the like so made are punishable by fine or
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`imprisonment, or both, under Section 1001 of Title 18 of the United States Codes.
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`Respectfully Submitted,
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`Dr. Jack H. Cole
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`Date: April 22, 2014
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`46
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`PGS v. WESTERNGECO (IPR2014-00687)
`WESTERNGECO Exhibit 2062, pg. 11
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