`___________________
`
`BEFORE THE PATENT TRIAL AND APPEAL BOARD
`___________________
`
`APPLE INC.
`Petitioner
`
`v.
`
`ANDREA ELECTRONICS CORPORATION
`Patent Owner
`___________________
`
`Case No. IPR2017-00626
`U.S. Patent 6,363,345
`___________________
`
`DECLARATION OF SCOTT C, DOUGLAS, PH.D. IN SUPPORT OF
`PATENT OWNER’S RESPONSE
`
`Patent Owner
`Andrea Electronics Corp.
`EXHIBIT 2002
`IPR2017-00626
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`IPage 1 of 104
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`TABLE OF CONTENTS
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`I.
`
`II.
`
`Introduction ..................................................................................................... 1
`A.
`Engagement .......................................................................................... 1
`B.
`Compensation and Prior Testimony ..................................................... 1
`C. Qualifications and Professional Experience ......................................... 2
`D.
`Summary of My Study ......................................................................... 5
`
`Relevant Legal Standards ............................................................................... 6
`A.
`Claim Construction .............................................................................. 7
`B. Anticipation .......................................................................................... 7
`C. Obviousness .......................................................................................... 8
`
`III. Claim Construction and one of ordinary skill in the art ............................... 10
`Claim Construction ............................................................................ 10
`A.
`B. One Of Ordinary Skill In The Art ...................................................... 11
`
`IV. Background of the Technology .................................................................... 12
`A. Audio Signals ..................................................................................... 13
`B. Analyzing Audio Signals ................................................................... 17
`C. Adaptive Filtering............................................................................... 21
`
`V. Overview Of The ’345 Patent ....................................................................... 22
`
`VI. CLAIMS 4-11, 13-25, 38-42, AND 43-47 ARE NOT OBVIOUS
`OVER HIRSCH IN VIEW OF ANY SECONDARY REFERENCE .......... 24
`A. Grounds Based on The Combination of Hirsch and Martin .............. 25
`1.
`Summary of the Asserted References ...................................... 25
`a)
`Hirsch .............................................................................. 25
`b) Martin ............................................................................. 27
`c)
`Martin’s Techniques Allegedly Reduce Delay............... 31
`d)
`The Role of Subwindows in Martin’s Algorithm ........... 33
`e)
`Martin’s SNR Computation ............................................ 34
`Claims 4-11 are Not Obvious Over Hirsch In View of
`Martin ....................................................................................... 35
`a)
`The combination of Hirsch and Martin does not
`teach or disclose a “current minimum” and a
`“future minimum” ........................................................... 35
`
`2.
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`(1)
`
`5.
`
`b)
`
`c)
`
`b)
`c)
`
`PMmin is Not a “Future Minimum” in the
`Rapidly Varying Noise Power Case (i.e., for
`monotonically increasing signals) ........................ 36
`(2) There is No “Future Minimum” in the
`Slowly Varying Noise Power Case (i.e., for
`non-monotonically increasing signals) ................ 37
`Pn(i) is Not Set to PMmin Periodically .............................. 38
`The Combination of Hirsch and Martin Fails to
`disclose the “Current Magnitude” of Claim 10 .............. 41
`3. Method Claims ......................................................................... 43
`4.
`A skilled artisan would not have been motivated to
`combine Hirsch and Martin ..................................................... 44
`Apple’s Validity Positions are Based on Dr. Hochwald’s
`Incomplete Analysis and His Incorrect Understanding of
`the Martin System .................................................................... 53
`a)
`Apple’s Attempt to Eliminate Subwindows Is
`Contrary to Martin’s Express Disclosure ....................... 53
`Dr. Hochwald Failed to Analyze the Monotonic
`Decision Block ................................................................ 55
`Dr. Hochwald Has an Erroneous Understanding of
`the Sample Counter and the Update of the
`Min_Vec Array ............................................................... 58
`B. Grounds Based on The Combination of Hirsch And The Other
`Relied-Upon Secondary References .................................................. 62
`1.
`Summary of the Asserted References ...................................... 62
`a)
`Boll.................................................................................. 62
`b)
`Arslan .............................................................................. 63
`c)
`Uesugi ............................................................................. 63
`A skilled artisan would not have been motivated to
`combine Hirsch and Boll or Arslan as alleged ........................ 64
`Ground Based on the Combination of Hirsch, Martin, and
`Boll ........................................................................................... 69
`Ground Based on the combination of Hirsch, Boll, and
`Arslan ....................................................................................... 71
`Grounds Based on the Combinations of Hirsch and
`Uesugi, and Hirsch, Martin and Uesugi ................................... 71
`
`2.
`
`3.
`
`4.
`
`5.
`
`VII. Conclusion .................................................................................................... 73
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`I, Scott C. Douglas, Ph.D., do hereby declare:
`
`I.
`
`INTRODUCTION
`
`A. Engagement
`I have been retained by counsel for Andrea Electronics Corporation as
`1.
`
`an expert witness to render opinions on certain issues concerning Inter Partes
`
`Review No. IPR2017-00626 of U.S. Patent No. 6,363,345 to Joseph Marash et al.
`
`(Ex. 1001, “the ’345 Patent”).
`
`B. Compensation and Prior Testimony
`I am being compensated at a standard rate of $575 per hour for my
`2.
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`study and preparation of this declaration. I am also being reimbursed for
`
`reasonable and customary expenses associated with my work and testimony in this
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`study. This compensation is not dependent on my opinions or testimony or the
`
`outcome of this matter.
`
`3.
`
`I have previously testified as an expert in the following matters, which
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`also involved the ’345 Patent: U.S. International Trade Commission Investigation
`
`Nos. 337-TA-949 and 337-TA-1026 on behalf of Andrea Electronics Corp. During
`
`the previous four years, I have additionally testified as an expert in the following
`
`matters: Ericsson Inc. v. Apple Inc., E.D.Tx., 2:15-cv-288-JRG-RSP; and Masimo
`
`v. Covidien, U.S. Patent and Trademark Office, Interference No. 105875.
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`C. Qualifications and Professional Experience
`I am currently a professor in the Department of Electrical Engineering
`4.
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`at the Bobby B. Lyle School of Engineering at Southern Methodist University. I
`
`have been a professor in the Department of Electrical Engineering at Southern
`
`Methodist University since August 1998. I have taught, and continue to teach,
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`courses to undergraduate and graduate level students in the areas of signal
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`processing, including adaptive filtering and adaptive arrays. My research at
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`Southern Methodist University is focused in the areas of acoustic signal
`
`processing, active noise control, adaptive filtering, array processing, multichannel
`
`blind deconvolution and source separation.
`
`5.
`
`Prior to my position at Southern Methodist University, I was an
`
`assistant professor in the Department of Electrical Engineering at the University of
`
`Utah. I taught courses to undergraduate and graduate level students in the areas of
`
`signal processing, including digital signal processing, adaptive filtering, and active
`
`noise control. In addition to teaching, I also performed research in the areas of
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`adaptive filtering, active noise control, multichannel blind deconvolution and
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`source separation, and hardware implementations of adaptive signal processing
`
`systems.
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`6.
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`I have been a member of the Institute of Electrical and Electronics
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`Engineers since 1988, and am currently a Senior Member. I have been an
`
`Associate Editor of the IEEE Transactions on Signal Processing and IEEE Signal
`
`Processing Letters. I have had leadership roles in IEEE organizational activities,
`
`including conference and workshop organization, and I have served on three
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`Technical Committees of the IEEE Signal Processing Society and held leadership
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`positions of Secretary or Chair of some of these committees. In 2010, I was the
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`General Chair and the organizer of the IEEE International Conference on
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`Acoustics, Speech, and Signal Processing, the premier yearly IEEE conference
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`series on all aspects of signal processing theory, methods, and applications, and I
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`have published in and attended this conference every year it has been offered since
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`1990. I was the recipient of the Best Paper Award in Audio and Electroacoustics
`
`of the IEEE Signal Processing Society in 2003.
`
`7.
`
`I have written several book chapters related to adaptive filters,
`
`microphone arrays, blind deconvolution, and source separation. I was section
`
`editor of the Adaptive Filters portion of The Digital Signal Processing Handbook,
`
`Vijay Madisetti and Douglas Williams, eds. (Boca Raton, FL: CRC/IEEE Press,
`
`1998), and authored one chapter and co-authored another chapter on adaptive
`
`filters for this text. I co-authored, with Shun-ichi Amari, the book chapter entitled
`
`“Natural Gradient Adaptation,” in Unsupervised Adaptive Filtering, Vol. I: Blind
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`Signal Separation, Simon Haykin, ed., (New York: Wiley, 2000), and I co-
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`authored, with Simon Haykin, the book chapter entitled “Relationships Between
`
`Blind Deconvolution and Blind Source Separation,” in Unsupervised Adaptive
`
`Filtering, Vol. II: Blind Deconvolution, Simon Haykin, ed., (New York: Wiley,
`
`2000). I wrote the book chapter entitled, “Blind Separation of Acoustic Signals,”
`
`appearing in Microphone Arrays: Techniques and Applications, Michael
`
`Brandstein and Darren Ward, eds., (New York: Springer-Verlag, 2001). I co-
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`authored, with Malay Gupta, the book chapter entitled, “Convolutive Blind Source
`
`Separation for Audio Signals,” in Blind Speech Separation, Shoji Makino, Te-Won
`
`Lee, and Hiroshi Sawada, eds. (New York: Springer, 2007).
`
`8.
`
`I received my bachelors degree (June 1988), masters degree (June
`
`1989), and doctorate degree (June 1992) in electrical engineering from Stanford
`
`University. For my doctorate degree, the focus of my studies were in the area of
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`signal processing, adaptive filters, and statistical estimation and detecting.
`
`9.
`
`By virtue of the above experience, I have gained a detailed
`
`understanding of the technology that is at issue in this proceeding. I believe I am
`
`qualified to provide opinions about how one of ordinary skill in the art would have
`
`interpreted and understood the ’345 Patent and the art relied upon by the Petitioner
`
`at the time of the invention of the ’345 Patent.
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`10. A copy of my curriculum vitae, appended hereto as Appendix A,
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`further describes in detail my qualifications, responsibilities, employment history,
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`honors, awards, publications, and professional associations.
`
`D.
`11.
`
`Summary of My Study
`I understand that the Petition for Inter Partes Review in IPR2017-
`
`00626 (Paper 1, “the ’626 Petition”) challenges the validity of certain claims of the
`
`’345 Patent, and that the Institution Decision (Paper 7, “the ’626 Decision”)
`
`instituted this proceeding on the following grounds:
`
`•
`
`Ground 1: Claims 1-3, 12, 13, 21, 23, and 38 as being anticipated by
`
`an article by H. Hirsch et al., entitled “Noise estimation techniques for
`
`robust speech recognition” (Ex. 1005, “Hirsch”);
`
`•
`
`Ground 2: Claims 4-11, 25, 39-42, and 46 as being obvious over
`
`Hirsch in view of an article by R. Martin, entitled “An efficient
`
`algorithm to estimate instantaneous SNR of speech signals” (Ex.
`
`1006, “Martin”);
`
`•
`
`Ground 3: Claims 13, 14, 17-21, 23, and 47 as being obvious over
`
`Hirsch in view of an article by S. Boll, entitled “Suppression of
`
`acoustic noise in speech using spectral subtraction” (Ex. 1009,
`
`“Boll”);
`
`•
`
`Ground 4: Claim 43 as being obvious over Hirsch, Martin, and Boll;
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`•
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`Ground 5: Claims 15, 16, and 24 as being obvious over Hirsch and
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`Boll and further in view of U.S. Patent No. 5,706,395 of Arslan et al.
`
`(Ex. 1011, “Arslan”);
`
`•
`
`•
`
`Ground 6: Claim 22 as being obvious over Hirsch in view of U.S.
`
`Patent No. 5,459,683 of Uesugi et al. (Ex. 1015, “Uesugi”); and
`
`Ground 7: Claims 44 and 45 as being obvious over Hirsch and Martin
`
`and further in view of Uesugi.
`
`12.
`
`In preparing this declaration, I have reviewed the ’345 Patent, the
`
`’626 Petition, the declaration of Dr. Bertand Hochwald (Ex. 1003, “the ’626
`
`Hochwald Report”), and the ’626 Decision, as well as each of Hirsch, Martin, Boll,
`
`Arslan, and Uesugi. I also reviewed relevant portions of the deposition transcript
`
`of Dr. Hochwald. My opinions are set forth below, and are based on my years of
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`education, research, and experience, as well as my investigation and study of the
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`materials identified above. I make these statements based upon facts and matters
`
`within my own knowledge or on information provided to me by others. All such
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`facts and matters are true to the best of my knowledge and belief.
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`II. RELEVANT LEGAL STANDARDS
`
`13. My understanding of the relevant legal standards is based on
`
`information provided to me by Patent Owner’s counsel.
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`A. Claim Construction
`I understand that in an inter partes review proceeding, the claims of a
`14.
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`non-expired patent are construed from the perspective of one of ordinary skill in
`
`the art at the time of the claimed invention and are given their broadest reasonable
`
`construction consistent with the specification.
`
`B. Anticipation
`I understand that a claim is anticipated if a single prior art reference
`15.
`
`discloses, explicitly or inherently, all limitations of the invention arranged or
`
`combined in the same way as in the claim. I further understand that inherency may
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`not be established by probabilities or possibilities, and the fact that one of ordinary
`
`skill in the art understands that the missing limitation could exist under certain
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`circumstances is not sufficient. Instead, I understand that the party claiming
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`inherency must prove that the missing matter is necessarily present and that it
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`would be so recognized by a person of ordinary skill in the relevant art. I
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`understand that whether the inherent disclosure was recognized at the time of the
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`reference is immaterial.
`
`16.
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`I further understand that the disclosure of an anticipatory reference
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`must describe the claimed invention to a degree adequate to enable person of
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`ordinary skill in the art to not only comprehend the invention, but also to make, or
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`in the case of a method, use, the claimed invention without undue experimentation.
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`Provided that the reference asserted is enabling, it is my understanding that it need
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`not disclose any independent use or utility to anticipate a claimed invention.
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`C. Obviousness
`It is my understanding that an invention is unpatentable if the
`17.
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`differences between the invention and the prior art are such that the subject matter
`
`of the invention as a whole would have been obvious at the time the invention was
`
`made to a person having ordinary skill in the art. I further understand that
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`obviousness is determined by evaluating: (1) the scope and content of the prior art,
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`(2) the differences between the prior art and the claim, (3) the level of ordinary
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`skill in the art, and (4) secondary considerations of nonobviousness. To establish
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`obviousness based on a combination of prior art references, it is my understanding
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`that a petitioner must identify a specific combination that teaches all limitations
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`and establish that a person of ordinary skill in the art at the time of the claimed
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`invention would have found it obvious to make that combination.
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`18. To guard against hindsight and an unwarranted finding of
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`obviousness, I understand that an important component of any obviousness inquiry
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`is whether the petitioner has identified any teaching, suggestion, or motivation that
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`would have prompted a person of ordinary skill in the art to make the claimed
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`combination and have a reasonable expectation of success in doing so. I
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`understand that this test should not be rigidly applied, but can be an important tool
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`to avoid the use of hindsight in the determination of obviousness.
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`19.
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`I further understand that the teaching, suggestion, or motivation may
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`be found explicitly or implicitly: (1) in the prior art; (2) in the knowledge of those
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`of ordinary skill in the art that certain references, or disclosures in those references,
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`are of special interest or importance in the field; or (3) from the nature of the
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`problem to be solved. Additionally, I understand that the legal determination of
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`the motivation to combine references allows recourse to logic, judgment, and
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`common sense. In order to resist the temptation to read into prior art the teachings
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`of the invention in issue, however, it should be apparent that “common sense”
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`should not be conflated with what appears obvious in hindsight.
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`20.
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`I understand that it is improper to combine references where the
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`references teach away from their combination. I understand that a reference may
`
`be said to teach away when a person of ordinary skill in the relevant art, upon
`
`reading the reference, would be discouraged from following the path set out in the
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`reference, or would be led in a direction divergent from the path that was taken by
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`the applicant. I further understand that if the teachings of a prior art reference
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`would lead a person of ordinary skill in the art to make a modification that would
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`render another prior art device inoperable, then such a modification would
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`generally not be obvious. I also understand that if a proposed modification would
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`render the prior art invention being modified unsatisfactory for its intended
`
`purpose, then there would have been no suggestion or motivation to make the
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`proposed modification.
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`III. CLAIM CONSTRUCTION AND ONE OF ORDINARY SKILL IN
`THE ART
`
`A. Claim Construction
`
`21.
`
`I understand that claim construction is the common terminology used
`
`to describe the interpretation of claim terms. It is also my understanding that in
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`this inter partes review proceeding, the claim terms of an unexpired patent are to
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`be given their broadest reasonable interpretation consistent with the specification
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`and file history of the ’345 Patent, as understood by one of ordinary skill in the art.
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`22.
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`It is also my understanding that Petitioner has proposed constructions
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`for the terms “magnitude” (independent claims 1 and 38); “frequency spectrum
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`generator”/ “generating the frequency spectrum” (independent claims 1 and 38);
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`“threshold detector for setting a threshold … and for detecting” (independent claim
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`1); and “generating a noise canceling signal for canceling noise” (independent
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`claim 38). ’626 Petition at 13-16. I have been instructed to apply, and have
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`applied, Petitioner’s construction of these terms for the purposes of my opinions.
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`23. Additionally, I provide the following comments on the term
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`“periodically” as recited in claims 6 and 9 of the ’345 Patent, and which the ’627
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`Petition alleges encompasses a meaning of “from time to time” based on a non-
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`technical definition within Merriam-Webster Dictionary. I initially note that this
`
`excerpt from the Merriam-Webster Dictionary provides two definitions for
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`“periodically”: “1: at regular intervals of time;” and “2: from time to time.” Ex.
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`1013. However, only the first definition would be consistent with the
`
`understanding of a person skilled in the art in light of the specification of the ’345
`
`Patent and its use in the particular field of audio signal processing. Like the
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`“period” of an audio signal itself, which is the amount of time it takes for a signal
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`to repeat itself, “periodically” as recited in claims 6 and 9 and throughout the
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`remainder of the specification of the ’345 Patent refers to actions that occur at
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`regular intervals (e.g., every 5 seconds) rather than merely “from time to time”.
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`B. One Of Ordinary Skill In The Art
`
`24.
`
`I understand that Petitioner and the ’626 Hochwald Declaration have
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`alleged that a person of ordinary skill in the art in the field of the invention claimed
`
`in the ’345 Patent would have had “a good working knowledge of digital signal
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`processing techniques and their applications” gained through “an undergraduate
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`education in electrical engineering or a comparable field, in combination with
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`either a graduate degree (or two years of graduate work) in electrical engineering
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`or a comparable field, or through two years of practical work experience, where
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`such graduate education or work experience focused on or involved the use of
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`digital signal processing techniques.” ’626 Petition at 12; Ex. 1003 at ¶37.
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`25.
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`I believe I am qualified based on my education and experience,
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`discussed above, to render opinions from the perspective of a person of ordinary
`
`skill in the art according to Petitioner’s proposed definition, and for the purposes of
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`my opinions herein, I have used Petitioner’s definition. In particular, I have read
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`the ’345 Patent, Hirsch, Martin, Boll, Arslan, and Uesugi, and have considered
`
`their disclosures from the perspective of such a person of ordinary skill at the time
`
`of the invention of the ’345 Patent. Unless otherwise stated, my statements herein
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`refer to the knowledge of one of ordinary skill in the field of the invention claimed
`
`in the ’345 Patent.
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`IV. BACKGROUND OF THE TECHNOLOGY
`
`26. The ’345 Patent, entitled “System, Method and Apparatus for
`
`Cancelling Noise,” is generally directed to systems, methods, and apparatuses for
`
`processing audio signals, and more specifically to the processing of audio signals
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`so as to cancel noise components. See Ex. 1001 at 1:19-21.
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`A. Audio Signals
`27. Audio signals are a representation of sound. Sound is a vibration that
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`propagates as a pressure wave through a medium (e.g., air). These physical sound
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`waves can be represented in terms of electrical voltage, for example, when picked
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`up by a microphone. A microphone typically includes a membrane which vibrates
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`when the sound wave (vibrations) impact the membrane. The vibrations of the
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`membrane are converted into electrical energy and measured in terms of electrical
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`voltage. When a loud sound (which carries more energy) hits the membrane, it
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`results in a greater vibration in the membrane, which translates into a higher
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`measure of electrical voltage. Likewise, when a soft sound (which carries less
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`energy) hits the membrane, it results in a smaller vibration in the membrane, which
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`translates into a lower measure of electrical voltage. These measures of electrical
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`voltage, collected over time, correspond to the audio signal, and they can be
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`plotted to show the waveform of the audio signal. Below is an example of the
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`waveform of an audio signal, with the oscillations in the waveform correspond to
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`the physical vibration of the membrane in a microphone (the audio signal shown is
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`an example of a sinusoidal signal, and is sometimes called a sine wave).
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`28. Typically, the audio signals generated from a microphone are analog
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`signals. Analog signals are unsampled, continuous signals that vary over time.
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`These analog signals can be analyzed and modified using analog systems (e.g.,
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`usually consisting of analog amplifiers, resistors, capacitors, and other electronic
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`elements). Analog systems, however, are relatively limited in function and often
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`require substantial hardware redesign to incorporate additional functionality.
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`Digital systems allow for much greater functionality, as they can be implemented
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`using general purpose computational systems programmed with software to
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`achieve the desired functionality. As such, audio signals are typically processed
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`using digital systems when such processing hardware is available.
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`29.
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`In order to process audio signals in digital systems, they must first be
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`converted into digital signals. The conversion of an analog signal into a digital
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`signal is accomplished by use of an analog-to-digital converter (A/D converter).
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`The A/D converter samples the input signal by taking measurements of the
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`amplitude of the analog signal at regular time intervals, i.e., by “sampling.” This
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`sampling is illustrated, for example, in the diagram below:
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`Unlike analog signals, digital signals allow for the representation of a signal using
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`a discrete and finite number of points. Because of the discrete nature of digital
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`signals, the digitized samples may not exactly match the values of the analog
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`signals, as shown for example in the figure above, which shows that the digital
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`samples do not line up exactly with the analog counterpart. But it is the discrete
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`nature of digital signals that allows each point of the digital signal to be stored into
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`discrete memory locations in the digital system.
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`30. Higher sampling rates and more accurate digitization of the samples
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`can be employed within the A/D converter to provide for a more accurate
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`representation of the analog signal in digital form. However, using a higher
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`sampling rate and/or a more-accurate digitizer requires increased memory (to store
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`the additional measurements of the higher-quality samples of the analog signal)
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`and processing power (to process the additional data).
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`31. Lower sampling rates can also be used, but too low of a sampling rate
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`may result in aliasing. When aliasing occurs, the sampled signal becomes
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`indistinguishable from other signals and can cause unwanted distortions or artifacts
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`in the signal when it is converted back into analog form. An example of an aliased
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`signal is shown below, in which the blue signal corresponds to the original signal,
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`while the red signal represents an aliased signal that can result from using too low
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`of a sampling rate:
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`To avoid aliasing, the signal should be sampled at a sampling rate that is at least
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`two times that of the highest frequency component that appears in the signal. For
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`example, if the highest frequency component that appears in the signal has a
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`frequency of 10 kHz, the signal should be sampled at a rate of at least 20 kHz to
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`avoid aliasing. This rule is referred to in the art as the Nyquist theorem or the
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`sampling theorem.
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`B. Analyzing Audio Signals
`32. Audio signals can be analyzed with respect to time. Such an analysis
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`is referred to in the art as “time domain” analysis. The properties of a periodic
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`signal (e.g., a sinusoid) can be readily ascertained in the time domain. Take, for
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`example, the following sinusoid:
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`The period of the signal is the amount of time it takes for a signal to repeat itself.
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`The period of the sinusoidal signal is illustrated below:
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`From the period of the sinusoidal signal, one can specify its frequency, which is
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`another property of the sinusoidal signal. The frequency is defined as the inverse
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`of the period, or 𝑓𝑓𝑟𝑟𝑒𝑒𝑞𝑞𝑢𝑢𝑒𝑒𝑛𝑛𝑐𝑐𝑦𝑦 =
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`1𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝 .
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`33. Another property of a periodic signal is its amplitude. The amplitude
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`is a characteristic property that describes the general size or height of a signal.
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`One way to characterize the amplitude is the peak amplitude, which is the highest
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`value of the signal in the given period. This is illustrated in the diagram below:
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`Another way to characterize the amplitude is the peak-to-peak amplitude which
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`describes the amount of change between the lowest value and the highest value of
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`the signal in the given period. So in the figure above, the peak-to-peak amplitude
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`would be the range from -1 to 1, or a value of 2.
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`34.
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`In the real world, however, signals are more complex, and as such, the
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`properties of such signals can be much more difficult to ascertain. Take the
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`following exemplary signal, which represents a chord - a particular combination of
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`sine waves:
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`This chord is actually the sum result of three sinusoids at different frequencies, as
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`illustrated by the diagram below:
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`As one can see, once the chord is broken down into its individual frequency
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`components, the signal becomes easier to analyze over time. Analyzing signals
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`with regard to frequency is referred to in the art as “frequency domain” analysis.
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`In frequency domain analysis, the signal is represented in terms of its frequency
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`components.
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`35. One way of extracting the frequency components of a signal is by
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`using a Discrete Fourier Transform (DFT). The DFT represents a signal as a
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`weighted sum of sine and cosine waves of increasing frequency. The DFT
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`computes the set of coefficients for each of the sine and cosine components to
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`indicate how much of each sine and cosine component is present in the signal. For
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`example, an 8-point DFT takes 8 samples (points) of the digital input signal, and
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`outputs 8 complex pairs, representing the “real” and “imaginary” part of each input
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`sample. The “real” part of the complex pair represents the magnitude of the
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`sample, while the “imaginary” part represents the phase information. The Fast
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`Fourier Transform (“FFT”) is an algorithm that runs a DFT computation quickly.
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`C. Adaptive Filtering
`36. An adaptive filter is a digital signal processing system that, in its
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`simplest form, models the relationship between an input signal and a desired
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`response or main signal. Adaptive filters are used for many different applications
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`in signal processing, including noise removal, signal enhancement, beam forming,
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`and echo cancellation.
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`V. OVERVIEW OF THE ’345 PATENT
`37. The ’345 patent is generally directed to systems, methods, and
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`apparatuses for processing audio signals, and more specifically to the processing of
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`audio signals so as to cancel noise components. See Ex. 1001 at 1:19-21.
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`38. The ’345 patent breaks the signal into its constituent frequency
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`components, called “frequency bins,” using a “frequency spectrum generator,” for
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`example, an FFT. Ex. 1001 at 2:11-19. The claimed invention has the ability to
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`detect and cancel noise on a frequency bin-by-frequency bin basis by setting an
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`adaptive threshold for each frequency bin. Ex. 1001 at 3:24-45.
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`39. Once the frequency bins are generated, the ’345 patent teaches that the
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`sample values within each frequency bin can be optionally smoothed. Ex. 1001 at
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`5: 45-58. After the smoothing process, there are still a collection of sample values
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`in each bin.
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`40. An adaptive threshold is set for each frequency bin based on the
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`magnitude characteristics of the samples within the bin. Ex. 1001 at 6:10-22. The
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`’345 patent sets the threshold using a cascading minimum determination process.
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`First, a “future minimum” is determined as the minimum magnitude of the
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`frequency bin for a given period of time, for example, five seconds. Ex. 1001 at
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`6:23-32. After this five-second period elapses, the “future minimum” value is used
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`to initiate the “current minimum” parameter. Ex. 1001 at 6:33-41. The initiated
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`“current minimum” is then compared to each sample in the frequency bin over the
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`next five second period, and its value is updated whenever the magnitude of a
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`sample in the frequency bin is less than the “current minimum’s” value. Id. Thus,
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`the “current minimum” is ultimately determined as the small