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`UNITED STATES PATENT AND TRADEMARK OFFICE
`______________________________________________
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`BEFORE THE PATENT TRIAL AND APPEAL BOARD
`______________________________________________
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`DELL INC. AND DELL PRODUCTS LP.
`Petitioner
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`v.
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`NEODRON LTD.
`Patent Owner.
`
`
`
`
`DECLARATION OF DR. ANDREW WOLFE IN SUPPORT OF PETITION
`FOR INTER PARTES REVIEW OF U.S. PATENT NO. 9,372,580
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`DELL EXHIBIT 1002 PAGE 1
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`DELL EXHIBIT 1002 PAGE 1
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
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`TABLE OF CONTENTS
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`I.
`INTRODUCTION ........................................................................................... 1
`BACKGROUND AND QUALIFICATIONS ................................................. 1
`II.
`INFORMATION CONSIDERED ................................................................... 6
`III.
`IV. RELEVANT LEGAL STANDARDS ............................................................. 7
`A.
`Claim Interpretation .............................................................................. 7
`B.
`Perspective of One of Ordinary Skill in the Art .................................... 7
`C.
`Obviousness ........................................................................................... 8
`LEVEL OF ORDINARY SKILL IN THE ART ...........................................11
`V.
`VI. SUMMARY OF MY OPINIONS .................................................................12
`VII. Technical Background ...................................................................................12
`A. History of Touch Sensing Input ..........................................................12
`B.
`Capacitive Touch Sensing ...................................................................13
`VIII. THE CHALLENGED PATENT ...................................................................18
`IX. PATENT PROSECUTION HISTORY .........................................................20
`X.
`PRIORITY DATE .........................................................................................22
`XI. CLAIM CONSTRUCTION ..........................................................................23
`XII. BRIEF DESCRIPTION OF THE APPLIED PRIOR ART ..........................24
`A. US Patent Publication No. 2010/0060608 to Yousefpor
`(Yousefpor) (Ex. 1005) .......................................................................24
`US Patent No. 8,587,555 to Chang et. al. (Chang) (Ex. 1006) ...........34
`US Patent No. 9,746,967 to Krah et. al. (Krah) (Ex. 1007) ................40
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`B.
`C.
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`-i-
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`XIII. DETAILED EXPLANATION OF THE UNPATENTABILITY
`GROUNDS ....................................................................................................47
`A. Ground 1: Claims 1-12 are rendered obvious by Yousefpor (Ex.
`1005) in view of Chang (Ex. 1006), and further in light of the
`knowledge of a POSITA. ....................................................................47
`1.
`A POSITA would be motivated to combine the teachings
`of Yousefpor and Chang, and would have a reasonable
`expectation of success in doing so. ...........................................47
`Independent Claims 1, 5, and 9. ................................................50
`2.
`Dependent claims 2, 6, and 10. .................................................91
`3.
`Dependent claims 3, 7, and 11. .................................................93
`4.
`Dependent Claims 4, 8, and 12. ................................................95
`5.
`Ground 2: Claims 1-12 are rendered obvious by Yousefpor (Ex.
`1005) in view of Krah (Ex. 1007), and further in light of the
`knowledge of a POSITA. ....................................................................96
`1.
`A POSITA would be motivated to combine the teachings
`of Yousefpor and Krah, and would have a reasonable
`expectation of success in doing so. ...........................................96
`Independent Claims 1, 5, and 9. ................................................98
`2.
`Dependent Claims 2, 6, and 10. ..............................................125
`3.
`Dependent Claims 3, 7, and 11. ..............................................126
`4.
`Dependent Claims 4, 8, and 12. ..............................................127
`5.
`XIV. CONCLUSION ............................................................................................130
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`B.
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`-ii-
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
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`1.
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`I, Dr. Andrew Wolfe, declare as follows:
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`I.
`
`INTRODUCTION
`I have been retained by Dell Inc. and Dell Products LP (collectively,
`2.
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`“Dell” or “Petitioner”) as an independent expert consultant in this inter partes
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`review (“IPR”) proceeding before the United States Patent and Trademark Office
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`(“PTO”).
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`3.
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`I have been asked by Dell Counsel (“Counsel”) to consider whether
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`certain references teach or suggest the features recited in Claims 1-12 of U.S.
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`Patent No. 9,372,580 (“the ’580 Patent”) (Ex-1001)1. My opinions and the bases
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`for my opinions are set forth below.
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`4.
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`I am being compensated at my ordinary and customary consulting rate
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`for my work, which is $600 per hour. My compensation is in no way contingent
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`on the nature of my findings, the presentation of my findings in testimony, or the
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`outcome of this or any other proceeding. I have no other financial interest in this
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`proceeding.
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`II. BACKGROUND AND QUALIFICATIONS
`All of my opinions stated in this declaration are based on my own
`5.
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` 1
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` Where appropriate, I refer to exhibits that I understand are attached to the petition
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`for IPR of the ’580 Patent.
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`1
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`personal knowledge and professional judgment. In forming my opinions, I have
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`relied on my knowledge and experience in designing, developing, researching, and
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`teaching the technology referenced in this declaration.
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`6.
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`I am over 18 years of age and, if I am called upon to do so, I would be
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`competent to testify as to the matters set forth herein. I understand that a copy of
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`my current curriculum vitae, which details my education and professional and
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`academic experience, is being submitted as Ex-1003. The following provides a
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`brief overview of some of my experience that is relevant to the matters set forth in
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`this declaration.
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`7.
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`I am the founder and sole employee of Wolfe Consulting. Through
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`Wolfe Consulting, I provide technical and business analysis to businesses on
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`processor technology, computer systems, consumer electronics, software, design
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`tools, data security, cryptography and intellectual property issues. I have more
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`than thirty years' experience developing products, researching, consulting, and
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`teaching in those fields. In that time, I have worked as a computer architect,
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`computer system designer, and as an executive in the PC and electronics business.
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`I have also taught at some of the world's leading institutions in those fields,
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`including Stanford University, Princeton University, Carnegie Mellon University,
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`and Santa Clara University.
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`8.
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`In 1985, I earned the B.S.E.E. degree in Electrical Engineering and
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`2
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`Computer Science from The Johns Hopkins University. In 1987, I received the
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`M.S. degree in Electrical and Computer Engineering from Carnegie Mellon
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`University and in 1992, I received the Ph.D. degree in Computer Engineering from
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`Carnegie Mellon University. My doctoral dissertation proposed a new approach
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`for the architecture of a computer processor.
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`9.
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`In 1983, I began designing touch sensors, microprocessor-based
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`computer systems, and I/O (input/output) cards for personal computers as a senior
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`design engineer for Touch Technology, Inc. During the course of my design
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`projects with Touch Technology, I designed I/O cards for PC-compatible computer
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`systems, including the IBM PC-AT, to interface with interactive touch-based
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`computer terminals that I designed for use in public information systems. I
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`continued designing and developing related technology as a consultant to the
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`Carroll Touch division of AMP, Inc., where in 1986 I designed one of the first
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`custom touch-screen integrated circuits. I designed the touch/pen input system for
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`the Linus WriteTop, which many believe to be the first commercial tablet
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`computer. The Linus WriteTop included handwriting recognition.
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`10. From 1986 through 1987, I designed and built a high-performance
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`computer system as a student at Carnegie Mellon University. From 1986 through
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`early 1988, I also developed curriculum, and supervised the teaching laboratory,
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`for processor design courses.
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`3
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`In the latter part of 1989, I worked as a senior design engineer for
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`11.
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`ESL-TRW Advanced Technology Division. While at ESL-TRW, I designed and
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`built a bus interface and memory controller for a workstation-based computer
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`system, and also worked on the design of a multiprocessor system.
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`12. At the end of 1989, I (along with some partners) reacquired the rights
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`to the technology I had developed at Touch Technology and at AMP, and founded
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`The Graphics Technology Company. Over the next seven years, as an officer and
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`a consultant for The Graphics Technology Company, I managed the company's
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`engineering development activities and personally developed dozens of touch
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`screen sensors, controllers, and interactive touch-based computer systems.
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`13.
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`I have consulted, formally and informally, for a number of fabless
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`semiconductor companies. In particular, I have served on the technical advisory
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`boards for two processor design companies: BOPS, Inc., where I chaired the board,
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`and Siroyan Ltd., where I served in a similar role for three networking chip
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`companies—Intellon, Inc., Comsilica, Inc., and Entridia, Inc.—and one 3D game
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`accelerator company, Ageia, Inc.
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`14.
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`I have also served as a technology advisor to Motorola and to several
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`venture capital funds in the U.S. and Europe. Currently, I am a director of Turtle
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`Beach Corporation, providing guidance in its development of premium audio
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`peripheral devices for a variety of commercial electronic products.
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`4
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`15. From 1991 through 1997, I served on the Faculty of Princeton
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`University as an Assistant Professor of Electrical Engineering. At Princeton, I
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`taught undergraduate and graduate-level courses in Computer Architecture,
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`Advanced Computer Architecture, Display Technology, and Microprocessor
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`Systems, and conducted sponsored research in the area of computer systems and
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`related topics. From 1999 through 2002, I taught the Computer Architecture
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`course to both undergraduate and graduate students at Stanford University multiple
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`times as a Consulting Professor. At Princeton, I received several teaching awards,
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`both from students and from the School of Engineering. I have also taught
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`advanced microprocessor architecture to industry professionals in IEEE and ACM
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`sponsored seminars. I am currently a lecturer at Santa Clara University teaching
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`courses on Computer Organization and Architecture and Mechatronics.
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`16. From 1997 through 2002, I held a variety of executive positions at a
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`publicly held fabless semiconductor company originally called S3, Inc. and later
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`called Sonicblue Inc. I held the positions of Chief Technology Officer, Vice
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`President of Systems Integration Products, Senior Vice President of Business
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`Development, and Director of Technology, among others. During my time at
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`SonicBlue, we launched more than 30 new consumer electronics products.
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`17.
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`I served as a board member and technical advisor at KBGear Inc.
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`from 1999-2001. KBGear Inc. designed and produced digital cameras and music
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`5
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
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`players.
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`18.
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`I have published more than fifty peer-reviewed papers in computer
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`architecture and computer systems design. I have also chaired IEEE and ACM
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`conferences in microarchitecture and integrated circuit design. I am a named
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`inventor on at least 56 U.S. patents and 30 foreign patents.
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`19.
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`I have been the invited keynote speaker at the ACM/IEEE
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`International Symposium on Microarchitecture and at the International Conference
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`on Multimedia. I have also been an invited speaker on various aspects of
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`technology or the PC industry at numerous industry events including the Intel
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`Developer's Forum, Microsoft Windows Hardware Engineering Conference,
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`Microprocessor Forum, Embedded Systems Conference, Comdex, and Consumer
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`Electronics Show as well as at the Harvard Business School and the University of
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`Illinois Law School. I have been interviewed on subjects related to technology and
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`the electronics industry by publications such as the Wall Street Journal, New York
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`Times, LA Times, Time, Newsweek, Forbes, and Fortune as well as CNN, NPR,
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`and the BBC. I have also spoken at dozens of universities including MIT,
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`Stanford, University of Texas, Carnegie Mellon, UCLA, University of Michigan,
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`Rice, and Duke.
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`III.
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`INFORMATION CONSIDERED
`In preparation for this declaration, I have considered the materials
`20.
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`6
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`discussed in this declaration, including, for example, the ’580 Patent, the
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`references cited by the ’580 Patent, the prosecution history of the ’580 Patent
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`(including the references cited therein), various background references, articles and
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`materials referenced in this declaration, and the prior art references identified in
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`this declaration. In addition, my opinions are further based on my education,
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`training, experience, and knowledge in the relevant field.
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`IV. RELEVANT LEGAL STANDARDS
`I am not an attorney and offer no legal opinions. For the purposes of
`21.
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`this Declaration, I have been informed about certain aspects of the law that are
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`relevant to my analysis, as summarized below.
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`A. Claim Interpretation
`I have been informed and understand that in an IPR proceeding,
`22.
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`claims are to be interpreted according to the Phillips claim construction standard. I
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`have been informed and understand that claim construction is a matter of law and
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`that the final claim constructions for this proceeding will be determined by the
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`Patent Trial and Appeal Board (“PTAB”).
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`B.
`23.
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`Perspective of One of Ordinary Skill in the Art
`I have been informed and understand that a patent is to be understood
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`from the perspective of a hypothetical “person of ordinary skill in the art”
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`(“POSITA”). Such an individual is considered to possess normal skills and
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`knowledge in a particular technical field (as opposed to being a genius). I
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`understand that in considering what the claims of a patent require, what was known
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`prior to that patent, what a prior art reference discloses, and whether an invention
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`is obvious or not, one must use the perspective of such a POSITA.
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`C. Obviousness
`I have been informed and understand that a patent claim is obvious
`24.
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`under 35 U.S.C. § 103, and therefore invalid, if the claimed subject matter, as a
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`whole, would have been obvious to a POSITA as of the priority date of the patent
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`based on one or more prior art references and/or the knowledge of a POSITA.
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`25.
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`I understand that an obviousness analysis must consider (1) the scope
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`and content of the prior art, (2) the differences between the claims and the prior art,
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`(3) the level of ordinary skill in the pertinent art, and (4) secondary considerations,
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`if any, of non-obviousness (such as unexpected results, commercial success, long-
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`felt but unmet need, failure of others, copying by others, and skepticism of
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`experts).
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`26.
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`I understand that a prior art reference may be combined with other
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`references to disclose each element of the invention under 35 U.S.C. § 103. I
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`understand that a reference may also be combined with the knowledge of a
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`POSITA, and that this knowledge may be used to combine multiple references. I
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`further understand that a POSITA is presumed to know the relevant prior art. I
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`understand that the obviousness analysis may take into account the inferences and
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`creative steps that a POSITA would employ.
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`27.
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`In determining whether a prior art reference would have been
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`combined with other prior art or other information known to a POSITA, I
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`understand that the following principles may be considered:
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`a. whether the references to be combined involve non-analogous art;
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`b. whether the references to be combined are in different fields of
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`endeavor than the alleged invention in the Patent;
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`c. whether the references to be combined are reasonably pertinent to the
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`problems to which the inventions of the Patent are directed;
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`d. whether the combination is of familiar elements according to known
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`methods that yields predictable results;
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`e. whether a combination involves the substitution of one known
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`element for another that yields predictable results;
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`f. whether the combination involves the use of a known technique to
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`improve similar items or methods in the same way that yields
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`predictable results;
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`g. whether the combination involves the application of a known
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`technique to a prior art reference that is ready for improvement, to
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`yield predictable results;
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`h. whether the combination is “obvious to try”;
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`i. whether the combination involves the known work in one field of
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`endeavor prompting variations of it for use in either the same field or
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`a different one based on design incentives or other market forces,
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`where the variations are predictable to a POSITA;
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`j. whether there is some teaching, suggestion, or motivation in the prior
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`art that would have led one of ordinary skill in the art to modify the
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`prior art reference or to combine prior art reference teachings to arrive
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`at the claimed invention;
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`k. whether the combination requires modifications that render the prior
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`art unsatisfactory for its intended use;
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`l. whether the combination requires modifications that change the
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`principle of operation of the reference;
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`m. whether the combination is reasonably expected to be a success; and
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`n. whether the combination possesses the requisite degree of
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`predictability at the time the invention was made.
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`28.
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`I understand that in determining whether a combination of prior art
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`references renders a claim obvious, it is helpful to consider whether there is some
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`teaching, suggestion, or motivation to combine the references and a reasonable
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`expectation of success in doing so. I understand, however, that a teaching,
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
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`suggestion, or motivation to combine is not required.
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`V. LEVEL OF ORDINARY SKILL IN THE ART
`I understand that in the co-pending 1162 ITC Investigation, the
`29.
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`Administrative Law Judge found, with respect to the ’580 Patent, that “one of
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`ordinary skill in the art would have had a bachelor's degree in electrical
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`engineering, computer engineering, computer science, or a related field, and at
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`least two years of experience in the research, design, development, and/or testing
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`of touch sensors, human-machine interaction and interfaces, and/or graphical user
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`interfaces, and related firmware and software, or the equivalent, with additional
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`education substituting for experience and vice versa.” I agree with this statement of
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`the level of skill in the art and have applied it herein.
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`30.
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`In determining the level of ordinary skill in the art, I considered, for
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`example, the type of problems encountered in the art, prior art solutions to those
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`problems, the rapidity with which innovations are made, the sophistication of the
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`technology, and the educational level of active workers in the field.
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`31.
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`I met the definition of a POSITA in 2011. I also had greater
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`knowledge and experience than a POSITA. I worked with POSITAs in 2011, and I
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`am able to render opinions from the perspective of a POSITA based on my
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`knowledge and experience. My opinions concerning the ’580 Patent claims and
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`the prior art are from the perspective of a POSITA, as set forth above.
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`Declaration of Dr. Andrew Wolfe
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`VI. SUMMARY OF MY OPINIONS
`I have been asked to consider whether the claims of the ’580 Patent
`32.
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`are obvious over certain prior art references. As explained in detail in this
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`declaration, it is my opinion that:
`
`•
`
`Claims 1-12 are rendered obvious by US Patent Publication No.
`2010/0060608 to Yousefpor (Yousefpor, Ex-1005) in view of US
`Patent No. 8,587,555 to Chang et. al. (Chang, Ex-1006), and further in
`light of the knowledge of a POSITA.
`
`•
`
`Claims 1-12 are rendered obvious by Yousefpor in view of US Patent
`No. 9,746,967 to Krah et. al. (Krah, Ex-1007), and further in light of
`the knowledge of a POSITA.
`VII. TECHNICAL BACKGROUND
`A. History of Touch Sensing Input
`33. Touch sensing technology has existed for many decades. Broadly
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`speaking, touch sensing for flat panels can be divided into a few main categories
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`based on the physics of sensing the touch. These include resistive touch sensors,
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`surface acoustics wave (SAW) touch sensors, infrared / optically-based touch
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`sensors, and capacitive touch sensors. There are several other types of touch
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`sensor technologies as well (see, for example, Walker, Geoff. “A review of
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`technologies for sensing contact location on the surface of a display,” Journal of
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`the Society for Information Display 20, no. 8 (2012), Ex-1020: pp. 413-440.)
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`34. Resistive-based touch sensors were offered for commercial use many
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`decades ago. For example, a transparent resistive touch panel was developed by
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`12
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`U.S. Patent No. 9,372,580
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`ELO TouchSystems in 1977.
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`35. SAW-based touch sensors use ultrasonic waves that are propagated
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`over the surface of the touch panel. When touched, some of the wave energy is
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`absorbed, altering the propagation of the wave. This is detected to sense the touch.
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`36.
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`In optically-based sensors, light emitters and detectors are typically
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`located along the edges of the panel. When the panel is touched, certain light paths
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`are blocked, and this information can be used to sense the touch location.
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`37.
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`In capacitive touch sensors, capacitance changes due to the presence
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`of a touch are detected and form the basis of sensing. Capacitive touch sensing
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`itself is not new. For example, an early touch display using capacitive sensing was
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`described in 1967 in “Touch Displays: A Programmed Man-Machine Interface” in
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`the journal Ergonomics. Capacitive touch sensing technology was commercially
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`available decades ago as well. For example, Micro Touch Systems offered surface
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`capacitance-based touch sensors as early as 1985. The field expanded dramatically
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`over the succeeding decades, as various classes of capacitive touch sensing
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`systems were developed. Over the last decade or more, capacitive touch sensors
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`have become the dominant touch sensing technology, particularly for flat panels
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`such as those used in tablets, computers, and phones.
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`B. Capacitive Touch Sensing
`38. Capacitive touch sensing systems are often categorized into self and
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`13
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`mutual capacitance systems. In self capacitance systems, the touching object (e.g.,
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`a finger) acts as one plate of a capacitor. The other plate is provided by an
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`electrode on the sensors. Since the touching object acts to couple signals to
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`ground, there is a capacitive path formed between the touch sensor and ground at
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`the location of the touch, which can be detected using appropriate capacitance
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`sensing circuitry. In a mutual capacitance detection system, on the other hand, the
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`capacitance of the touch alters the capacitive coupling between two electrodes on
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`the sensor. Again, this change in effective capacitance can be detected using
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`appropriate sensing circuitry. Examples of these two approaches are shown
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`schematically in the figure below (from Walker):
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`39.
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`In recent decades, mutual capacitance systems have become
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`increasingly prevalent, since they allow a relatively convenient sensor platform for
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`detection of multiple touches. It should be noted that multi-touch can also be
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`implemented in self capacitance-only systems as well.
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`40. By the time the application leading to the ’580 Patent was filed, it was
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`common knowledge to use both mutual capacitance and self capacitance
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`measurements in capacitive touch sensors. The use of both measurement
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`techniques allowed for devices to use the benefits of both self and mutual
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`measurements to achieve more accurate and/or better touch results.
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`41. For example, US Patent 8,659,566, Ex-1021, filed on October 14,
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`2010 and assigned to Himax on issuance, discusses several techniques using both
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`self and mutual capacitance measurements to improve touch detection accuracy.
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`The ’566 patent discusses what it refers to as “the hollow effect.” The ’566 patent
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`explains:
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`However, for some applications, undesired issues may happen in touch
`devices. For example, the touch devices may have an undesired hollow
`effect under a low ground state. FIG. 1 shows a schematic diagram of the
`hollow effect in the related art. Referring to FIG. 1, the low ground state
`means that a touch device does not have a reference ground. That is to say,
`the touch device is put on a car holder or a table without connecting to a
`power core. When the touch panel 11 of the touch device is under the low
`ground state, the touch sensing controller (not shown) may report two error
`points P1 and P2 whereas the users’ gesture simply touches the touch panel
`11 with a big area 20 which should correspond to a single point. This
`phenomenon is called the hollow effect. The hollow effect detaches a single
`touch point from several touch points. Accordingly, how to prevent the
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`touch sensing controller from reporting error points is one of the important
`issues at present. Ex-1021, 1:32-49
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`42. The ’566 patent explains that this “hollow effect” error can be
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`corrected by using both self and mutual capacitance data. “In summary, in the
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`exemplary embodiments of the invention, the touch sensing method combines the
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`self capacitance mode and the mutual capacitance mode during each sensing
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`frame. Under the low ground state, the touch controller determines the touch
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`location associated with user’s gestures at least based on self-mode data obtained
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`in the self capacitance mode to prevent from reporting error touch locations due to
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`the hollow effect.” The ’566 patent includes several flow charts describing how
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`both measurements are used to determine the correct touch points, such as, e.g.,
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`Figure 7:
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`43. Additionally, at least the following references explain common
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`knowledge and the state of the prior art with respect to using self capacitance
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`measurements to compensate for shortcomings in mutual capacitance
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`measurements, and vice versa: US 6,730,863 (Ex-1022); US 9,069,405 (Ex-1023);
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`US 9,804,213 (Ex-1024); US 8,319,505 (Ex-1025); US 8,462,135 (Ex-1026); US
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`8,482,544 (Ex-1016); US 8,542,202 (Ex-1027); US 8,546,705 (Ex-1028); US
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`8,624,870 (Ex-1029); US 8,659,566 (Ex-1030); US 8,933,907 (Ex-1031); US
`
`8,749,512 (Ex-1032); US 9,069,405 (Ex-1033); US 9,104,277 (Ex-1034); US
`
`8,692,795 (Ex-1035); US 8,587,555 (Ex-1036); 8,773,146 (Ex-1018); US Pub.
`
`2010/0007631 (Ex-1037); US Pub. 2009/0284495A1 (Ex-1038); US Pub.
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`2010/0328262 (Ex-1039); US Pub. 2011/0216033 (Ex-1040); US Pub.
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`2010/149110 (Ex-1041); US Pub. 2010/0144391 (Ex-1042); US Pub.
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`2011/0175835 (Ex-1043); US Pub. 2011/0148801 (Ex-1044); Product Pamphlet
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`TB3064 (Ex-1017).
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`44. Additionally, at the time of the ’580 patent application, it also was
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`well known in the art to distinguish real touches from phantom touches and to
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`subtract stray and optionally palm touches. For example, US Patent Publication
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`2009/0284495, published on November 19, 2009, discloses ways to distinguish
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`real and phantom touches and to subtract stray and optionally palm touches. See,
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`e.g., FIGS. 2, 3A, 3B through 5A, 5B, paragraphs [0056] – [0064], Algorithm 1,
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`and the “Described Algorithm, in Psuedo-Code” at [0099] (line 3 in each
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`algorithm). See Ex-1049.
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`VIII. THE CHALLENGED PATENT
`45. The ’580 Patent is focused on a specific alleged improvement to the
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`accuracy of a touch sensor: reducing inaccurate touch results by using signal
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`values from one kind of touch sensing (self or cross capacitance) to adjust the
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`signal values from another kind of touch sensing (mutual capacitance). As
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`described in the ’580 Patent, a touch sensor can contain a grid or mesh of
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`electrically conductive lines called “electrodes,” four of which are shown in Fig.
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`1B, below, as X1, X4, Y1, Y5. Ex-1001, 2:26-45.
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`46. Because a touch by a user will generally impact the capacitance of the
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`electrodes, the location of the touch can be determined by sending and receiving
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`signals over the electrodes. The ’580 Patent explains the capacitance measurement
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`technique of sending a signal over one set of electrodes (e.g., vertical or “Y”
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`electrode lines) and measuring the resulting signals on those same electrodes. Id.
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`at 4:9-22. This is understood by those of skill in the art as a “self capacitance”
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`measurement. Additionally, the ’580 patent explains the capacitance measurement
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`technique of measuring the resulting signals on the electrode lines perpendicular to
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`the ones on which the signal was sent. Id. at 3:55-4:8. This is understood by those
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`of skill in the art as a “mutual capacitance” measurement. In both cases, the
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`Declaration of Dr. Andrew Wolfe
`U.S. Patent No. 9,372,580
`location of the touch can be determined by analyzing the capacitance values
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`measured from such signals.
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`47. The ’580 Patent purports to address a problem in which the signals
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`received on some of the electrodes are unexpected due to, for example, a person’s
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`hand touching the screen at two locations. As shown in Figure 1B, some of the
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`effect of the drive signal may be transmitted through the person’s hand (dotted
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`lines) directly from one electrode node to another. This is what the patent refers to
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`as “retransmission,” and it may lead to the potential failure to detect or
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`misidentification of certain touches. Id. at 1:26-41. The ’580 Patent purports to
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`address this “retransmission” problem by “compensating” one set of received
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`signals with a