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MASSACHUSETTS INSTITUTE OF TECHNOLOGY
`School of Engineering Faculty Personnel Record
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`
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`Name:
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`
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`Brian W. Anthony
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`Mechanical Engineering / Institute of Medical Engineering and Science
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`July 1972
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`USA
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`Degree
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`BS
`SM
`PhD
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`Date
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`1994
`1998
`2006
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`Date: November 19, 2016
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`Department:
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`1. Date of Birth:
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`2. Citizenship:
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`3. Education:
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`School
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` Carnegie Mellon University
` MIT
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` MIT
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`4. Title of Thesis for Most Advanced Degree:
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` Video Based System Monitoring
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`5. Principal Fields of Interest:
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`Computational Instrumentation, Medical Device Design and Manufacturing, Innovation and
`Product Realization
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`6. Name and Rank of Other Department Faculty in the Same Field:
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` Harry Asada, Professor
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`Ian Hunter, Professor
` Kamal Youcef-Toumi, Professor
` Charlie Sodini, Professor (EECS)
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`Employer
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`Position
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`Beginning
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`Ending
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`LANL
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`Independent Consultant
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` Xcitex
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` Cooper Perkins
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`dRNOME
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`8. History of MIT Appointments:
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`Scientist
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`Consultant
`CoFounder / CTO
`CTO
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`CoFounder
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`1992
`1994
`1998
`2005
`2011
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`1994
`1998
`2005
`2007
`2016
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`7. Non-MIT Experience (including military service):
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`Apple Inc.
`APL1004
`U.S. Patent No. 8,989,830
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`0001
`
`FITBIT, Ex. 1004
`
`

`

` Rank
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`Beginning
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`Ending
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`2009
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`2006
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`Lecturer, Sloan
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` (present)
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`2006
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`Lecturer, MechE
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` 2013
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`2006
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` Research Scientist
` (present)
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`2013
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`
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`Principal Research Scientist
` Director Singapore MIT Alliance – Manufacturing Systems and Technology
`
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`Program (SMA-MST)
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`2006
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` 2010
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` Director Master of Engineering in Manufacturing Program (MEngM)
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`2006
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` (present)
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`Faculty Lead for Education, MIT Skoltech Initiative 2011
`
` 2016
` Deputy Director, MIT Skoltech Initiative
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`2014
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` 2016
` Associate Director, AIM Academy
`
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`2016
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`(present)
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`9. Consulting Record:
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`10. Professional Service
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`Firm
`Engagements greater than 3 months.
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`Los Alamos National Labs
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`Textron
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`Federal Trade Commission
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`FAA
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` Kodak
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` Redlake
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` Olympus
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`
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`TIS
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`Photron
`
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` Cooper Perkins
`
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`IDEO
`
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` Alcon
`
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` Ximedica
`
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` Herman Miller
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` Novartis
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`
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`Lenze
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` Activity
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`Beginning
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`Ending
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`2009
`2009
`2010
`2012
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`2012
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`2013
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`2014
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`2015
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`2015
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`2000
`2000
`2000
`2004
`2004
`2005
`2006
`2012
`2011
`2012
`---
`---
`2014
`2014
`2015
`2016
`
`Beginning
`
`Ending
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`
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` MEngM Admissions Committee
`
`
` CDO Admissions Committee
` Career Fair – SMA in Singapore, Org Chair
` Career Fair – SMA/MIT in Singapore, Org Chair
` Mfg. microFluidics Symp, Chair
`
`
`
`2006
`2007
`2007
`2008
`2009
`
`
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`
`
`present
`2008
`2007
`2008
`2010
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`0002
`
`FITBIT, Ex. 1004
`
`

`

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` Organization
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`Offices Held
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` ASME
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`IEEE
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`SPIE
` AIUM (American Institute of Ultrasound in Medicine)
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`Sigma Xi
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`13. Patents and Patent Applications Pending:
`
`
`1. US Patent 5606130 “Method for determining the octane rating of gasoline samples by
`observing corresponding acoustic resonances therein.”
`
`2. US Patent 6393384 “Apparatus and method for remote ultrasonic determination of thin
`material properties using signal correlation.”
`
`3. US Patent 6226081 “Optical height of fill detection system and associated methods.”
`4. US Patent 8,333,704, B. Anthony and M. Gilbertson, “Handheld Force-Controlled
`Ultrasound Probe,” Dec 11, 2012
`5. US Patent 8,328,725, B. Anthony and M. Gilbertson, “Ultrasound Probe,” Dec 18, 2012
`6. US Patent 8,382,671, B. Anthony and M. Gilbertson, “Handheld Ultrasound Probe,” Feb
`26, 2013
`7. US Patent 9,121,705, B. Anthony and D. Ljubicic, “Sensor for Simultaneous
`Measurement of Thickness and Lateral Position of a transparent object,” Sept 1, 2015
`
`
`
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`SMART Proposal Lead on Med Devices
`
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`LMP Summit Co-Chair
`
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` MEDRC Workshop, Chair
`
`
`
`
`Pilot IMI Proposal, MIT Lead
`
`
` Additive mfg working group, Lead
`
` MIT's role in reducing the cost of health care
`
`9/2010
`3/2010
`2011
`2011
`
`2012
`2012
`
`6/2012
`
`5/2012
`6/2012
`8/2012
`
`2014
`
`2015
`
` Activity
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`
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`Beginning
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`Ending
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`
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`SPIE Conference Committee
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`
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`SPIE Conference Committee
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` Co-Chair Education Workstream, AMP 2.0
`
`2011
`2012
`2013
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`
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`
`11. Awards Received:
`
` Award
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`National Television Academy, Emmy for Innovative
`Technical Achievement. "Golf on CBS, SwingVision."
`BPLA Invented Here, Featured Honoree
`
`
`
`
`12. Current Organization Membership:
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`
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`
`
`
`
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`2012
`2013
`2014
`
`Date
`
`2005
`2014
`
`0003
`
`FITBIT, Ex. 1004
`
`

`

`8. US Patent 9,456,800, Brian W. Anthony, Matthew W. Gilbertson, “Ultrasound scanning
`system”, Oct 4, 2016
`9. MIT Case 14088, Force Controlled Ultrasound Probe, 16-Dec-09
`10. MIT Case 14387, Deformation Estimation and Correction in Elastography with a
`Handheld Force Controlled Ultrasound Probe, 16-Jul-10
`11. MIT Case 14422, High-Speed Profilometer for Manufacturing Inspection, 30-Jul-10
`12. MIT Case 14966J, Force Measurement Ultrasound Probe for Sonographer Fatigue
`Monitoring, 10-Jun-11
`13. MIT Case 15012, A 6-DOF Optical System for Freehand 3D Ultrasound, 05-Jul-11
`14. MIT Case 15681J, Local Actuation and Control of Stamp Deformation in Microcontact
`Printing, 06-Jun-12
`15. MIT Case 15782, Usability Improvements to a Handheld Force-Controlled Ultrasound
`Probe, 03-Aug-12
`16. MIT Case 15884, Computer-Guided Restoration of Ultrasound Scan Poses by Optical
`Tracking, 01-Oct-12
`17. MIT Case 16160, Quick-Release Mechanism for a Force-Measuring Ultrasound Probe,
`22-Feb-13
`18. MIT Case 16447, Force-correlated Quantitative Ultrasound Image Analysis, 02-Jul-13
`19. MIT Case 17106J, Acoustic Characterization of Superficial Body Fluids, 07-May-14
`20. MIT Case 17211J, Wireless Capsule Endoscopic Ultrasound, 24-Jun-14
`21. MIT Case 17259K, A Concentric Circle Scanning Technique for Large Area Inspection,
`09-Jul-14
`22. MIT Case 17260K, Grid-Based Matching for Full-Field Large-Area Deformation
`Measurement, 09-Jul-14
`23. MIT Case 17344, Recovery and Computer-Guided Restoration of Ultrasound Scan Poses
`Based on Human Skin Features, 21-Aug-14
`24. MIT Case 17864J, Ultrasound-Based Individual Scatterer Detection Method Using
`Scatterer Motion Induced by Acoustic Radiation Force, 21-Apr-15
`25. MIT Case 17865, Ultrasound-Based Absolute Scatterer Concentration Measurement
`Technique: Image Volume Estimation from Scatter Spread Function Extracted From the
`Image, 21-Apr-15
`26. MIT Case 17990, Hydrogel Ultrasound Angle Wedge, 04-Jun-15
`27. MIT Case 18074, Joint Camera-Ultrasound Data Acquisition for Limb Scanning, 13-Jul-
`15
`28. MIT Case 18544, An Iterative RTM with a Priori Data to Estimate Bone Thickness Using
`a Cylindrically Scanning Ultrasound Tomography Scanner, 22-Feb-16
`29. MIT Case 18545K, Block-Wise Inversion for the Soundspeed of Human Soft Tissue and
`Bone Using Ray Based Travel Time Tomographic Techniques, 22-Feb-16
`30. MIT Case 18636, Concentric Ring-Based Point Pattern Matching of Skin Features, 05-
`Apr-16
`
`14. Professional Registration:
`
` N/A.
`
`
`
`
`
`0004
`
`FITBIT, Ex. 1004
`
`

`

`
`15. Major New Products, Processes Designs, or Systems:
`
`
`
` See next.
`
`
`
`0005
`
`FITBIT, Ex. 1004
`
`

`

`16. Major New Products, Processes Designs, or Systems:
`
`The following is split between a) University Programs or Significant Initiatives, b) Products, and c) Companies.
`
`A. Programs, Centers, or Significant Initiatives
`
`MEngM
`
`
`Director of the Master of Engineering in Manufacturing Program, and previously the director of the
`Singapore MIT Alliance - Manufacturing Systems and Technology Program since 2006. In these roles I
`have developed an education partnership program with small to multi-national corporations, defined and
`built the MEngM program and structure for the development and execution of company based projects.
`I place student groups into companies, teach professional engineering practice in the contact of industry
`based group projects, and broadly define and execute the operations of the MEngM degree program.
`Between 2007 and 2010, I raised over $900,000 from our partner companies to support program
`sponsored student fellowship and program operations.
`
`MEDRC
`
`
`Co-Founder, Co-Director of the Medical Electronic Device Realization Center (MEDRC). Along with
`Charlie Sodini, and Joel Voldman, I recruit large Medical Device manufacturing companies, lead
`research, and engage with the Med Tech community nationally and internationally.
`
`The MEDRC establishes partnerships between the microelectronics industry, the medical devices
`industry, medical professionals, and MIT faculty, researchers and students to collaboratively achieve
`improvements in the cost and performance of medical electronic devices. The successful realization of
`such a vision also demands innovations in the usability and productivity of medical devices, and new
`technologies and approaches to manufacture devices. The MEDRC is a focal point for large business,
`for venture-funded startups, and for the medical community.
`
`The unique research methodology of the MEDRC begins with the project definition. Research activities
`are jointly defined by faculty, physicians and clinicians, and industrial partners. Visiting scientists from
`microelectronic and medical device companies, physically resident at the Center, provide the industrial
`viewpoint in the project definitions and participate in the realization of the technology. Prototype
`systems are developed which are used in clinical tests early in the projects to help guide the research
`technology being developed in parallel.
`
`To date we have raised significant funding and identified a visiting scientist from GE, Analog Devices,
`Maxim, Philips, Nihon Kohden. Each company commits to $900,000 over 3 years.
`
`MIT Skoltech Initiative
`
`
`Deputy Director, and Lead Education, MIT Skoltech Initiative. I am serving as the education faculty
`lead in the development of high level curriculum concept for SkolTech Master’s degree programs,
`spanning across domains (space, nuclear, biomedicine, IT, and energy). We develop the education-team
`collaboration, build consensus on vision, objectives, and plans, and to create education programs for
`each domain.
`
`AIM Academy
`
`
`Associate Director of AIM Advance Integrated Photonics Manufacturing Academy. The AIM
`Photonics manufacturing institute is a public-private partnership that focuses the nation’s premiere
`
`0006
`
`FITBIT, Ex. 1004
`
`

`

`capabilities and expertise to capture critical global manufacturing leadership in Integrated Photonics
`technology that is essential to the U.S. economy. In this role I support community, careers and
`investment for US world leadership in Integrated Photonics manufacturing. I lead development of a
`Masters program in Integrated Photonics Manufacturing and development of an Education Factory
`practice facility.
`
`
`Other Significant, formative, Initiatives
`
`SMART Center - March through September 2010
`
`
` I
`
` developed consensus around a theme, built the team of 10 investigators in Singapore and 10
`investigators at MIT for a whitepaper and requested full center-proposal for SMART, entitled
`“Realization (Design, Manufacturing, and Use) of Injectable Physiological Monitors – Enabling a
`Patient Centric Information Driven Healthcare Future.” The research was motivated by addressing the
`need for unobtrusive, continuous, ambulatory, physiological monitoring of Congestive Heart Failure and
`Chronic Obstructive Pulmonary Disease patients. The 'state of health' information generated from these
`sensors can help reduce societal health care costs, improve quality of health care, increase quality
`lifespan, and lead to new understanding of the human physiology. Principal: Brian W. Anthony, David
`Brock, Jung-Hoon Chun, David Hardt, Rahul Sarpeshkar, David Trumper, Lorenzo Turicchia, Kamal
`Youcef-Toumi. Associate: H. Harry Asada, Joel L. Dawson , Elazer R. Edelman#, Karl Iagnemma,
`Collin Stultz#. Singapore Collaborators: Lian Yong, Guo Yong Xin, Lim Jui#, Lim Chwee Teck,
`Chui Chee Kong, Ho Khek Yu#, Dieter Wilhelm Trau, Michael Raghunath, Tay Eng Hock, Jason
`Phua#. (# Indicates investigator is a Medical Doctor (MD), or MD and PhD, all are practicing
`physicians)
`
`Our proposal made it to the final round but was not selected. However these efforts lead to the creation
`of the MEDRC.
`
`Pilot Innovation Manufacturing Institute (IMI) Proposal – May, June 2012
`
`
`A team (University of Massachusetts Amherst, University of Connecticut, Massachusetts Institute of
`Technology, the Connecticut Center for Advanced Technology, the Pennsylvania State University,
`UMass Lowell, United Technologies Corporation, and the National Center for Manufacturing Sciences)
`proposed to form an independent, non-profit technical center of excellence to accelerate technological
`progress and innovation in additive manufacturing (AM), in response to the May 8, 2012 Air Force
`Research Laboratory Broad Agency Announcement (BAA-122-17-PKM) for the NNMI pilot. The
`NNMI Pilot Institute will demonstrate the value of the kind of collaborative problem-solving and asset-
`building that could occur on a broader scale with a nation-wide network of Institutes for Manufacturing
`Innovation. Federal government funding for the 2.5-year pilot program is $30M with a minimum of
`$30M in required cost sharing from industry, state government and universities.
`
`In our center, The Advanced Direct Additive Manufacturing Institute (ADAM-I), we proposed to
`address key gap-bridging challenges in AM, including: rapid net shape production of structural metal,
`ceramic and polymer parts, and cost-effective manufacturing of large-area functional materials,
`components and devices.
`
`Marty Schmidt and I spearheaded the MIT collaboration. We developed the business plan and financial
`sustainability model for the proposed center. I raised $3 million in matching fund commitments (10% of
`the total match commitment).
`
`Flexible Hybrid Electronics Manufacturing Innovation Institute (NextFlex) – October 2015
`
`
`
`
`
`
`0007
`
`FITBIT, Ex. 1004
`
`

`

`
`
`MIT PI on winning proposal, including a team of : Marc Baldo, Duane Boning, Vladimir Bulovic, Karen
`K Gleason, David E Hardt, Anastasios John Hart, Sang-Gook Kim.
`
`$150M national center with a mission to catalyze the development of an ecosystem for manufacturing
`new forms of electronics that integrate bulk ICs and printed devices with functions such as power,
`communications, fluidics, and bio-sensing in flexible systems that can bend, fold, stretch, and conform.
`
`
`
`
`B. Products
`
`Fuselage Crack Inspection System for FAA
`
`
`In support of the Federal Aviation Administration National Aging Aircraft Research Program (NAARP)
`the state-of-the-art Full-Scale Aircraft Structural Test Evaluation and Research (FASTER) Facility was
`established at the FAA William J. Hughes Technical Center. A fixture was designed to simulate the
`actual loads to which an aircraft fuselage structure is subjected while in flight. Data from tests using this
`fixture was used to experimentally validate analytical theories and methodologies to evaluate and predict
`the onset of Widespread Fatigue Damage (WFD). Crack growth data from testing was gathered from
`the Remote Control Crack Monitoring System.
`
` I
`
` designed, built, and delivered The Remote Control Crack Monitoring System consisting of a pair of
`cameras with two different fields of view manipulative by with a large gantry robot. The cameras ‘fly’
`over the fuselage surface to identify and track cracks using processed camera images to generate the
`feedback signal
`
`
`
`Laser Wave for Textron
`
`
`Textron Inc.’s LaserWave® products integrated advanced signal processing techniques, robust software
`algorithms, lasers, optics and ultrasonic technology. The LaserWave Instrument could measure material
`characteristics such as density, hardness, temperature, thickness, elastic constants and more. LaserWave
`was developed to measure the temperature of Silicon Wafers undergoing rapid thermal processing and
`evolved to become a general system for material characterization.
`
` A
`
` pulse laser system is used to initiate a circular thermo-elastic Lamb wave. I developed propagation
`models describing the propagation of the collapsing circular, thermo-elastic, transient Lamb waves. I
`developed real-time inversion routines using a time-frequency wavelet decomposition to extract and
`identify group velocity mode shapes. The LaserWave products use models and algorithms that I
`developed to invert the measured temporal signals in order to estimate elastic constants and material
`thickness of thin layers.
`
`This product line didn’t fit Textron’s business mode. They transferred the technology to Brown
`University.
`
`http://investor.textron.com/newsroom/news-releases/press-release-details/2003/Textron-Donates-Laser-
`Technology-to-Brown-University-Research-Foundation/default.aspx
`
`
`Motion Tools for Photron Inc
`
`
`
`0008
`
`FITBIT, Ex. 1004
`
`

`

`
`
`
`
` I designed Photron Motion Tools to operate high-speed PCI cameras. Photron Motion Tools provides
`users with manual and automatic tracking capabilities. By simply selecting the point of interest within
`the recorded image sequence, Motion Tools automatically tracks the points-motion within the sequence.
`
`http://www.photron.com/index.php?cmd=product_general&product_id=17
`
`
`i-Speed for Olympus
`
`
`Capable of capturing images at speeds from 60 to 150,000 frames per second in 'normal' mode (down to
`1 second/frame in 'timelapse' mode) i-SPEED cameras are an effective method of locating problems
`quickly and easily. The user can evaluate designs, increase productivity and reduce maintenance costs.
`Video images are digitally captured onto its onboard memory, where they can be written to compact
`flash card or downloaded via Ethernet connection to a laptop or PC.
`
`I designed custom software to provide the operator with the ability to analyze and enhance images.
`Velocity and distance measurement can also be calculated. The i-SPEED Software Suite was designed
`to mirror the ease-of-use and high specification power of the camera range.
`
`http://www.olympus-ims.com/en/ispeed-software/
`
`
`
`Swing Vision for CBS
`
`
`
`
`
`
`http://xcitex.com/html/midas_description.php
`
`I designed and built the Swing Vision camera system, camera control system, camera mounts, the server
`architecture, and the analysis software. Two high-speed cameras record a golfer t-shot. A 2000 fps
`camera records the full view of the golfer. A 12500 frame per second camera is used to record the ball-
`club interaction. As the 2000 fps video is broadcast in slow motion, the 12500 fps video (gigabytes of
`raw video data) is automatically analyzed (in under 20 seconds). The ball is located, used for
`calibration, and tracked, the club is identified and tracked – all under highly variable condition (variable
`lighting from shadows, grass, occlusions, etc). The calculated speeds, back spin, and launch angle are
`sent to the broadcast truck. The results are broadcast in a graphic.
`
` won an Emmy for this system in 2005.
`
` I
`
`
`MiDAS - Xcitex
`
`As Xcitex’s first engineer, I developed the core of the flagship products - MiDAS and ProAnalyst. And
`as CTO and Vice-President of Xcitex, I developed and directed the development of products and
`solutions for the industrial and scientific video markets.
`
`MiDAS is now the the standard for controlling, synchronizing, and automating digital high-speed and
`industrial video cameras. With thousands of installations worldwide, MiDAS software is used by
`researchers, production line engineers, scientists, doctors, and military range operators to convert their
`video cameras into easy-to-use motion capture systems.
`
`MiDAS includes intelligent triggering, autonomous recording, synchronized video/data collection, large
`file organization tools. Features such as distance and velocity measurement calipers, auto-tracking, and
`video triggering are included.
`
`0009
`
`FITBIT, Ex. 1004
`
`

`

`
`ProAnalyst - Xcitex
`
`
`As Xcitex’s first engineer, I developed the core of the flagship products - MiDAS and ProAnalyst. And
`as CTO and Vice-President of Xcitex, I developed and directed the development of products and
`solutions for the industrial and scientific video markets.
`
`ProAnalyst is a software package for automatically measuring moving objects with video. It is used
`extensively by NASA, engineers, broadcasters, researchers and athletes. ProAnalyst allows users to
`measure and track velocity, position, size, acceleration, location and other characteristics. Results can
`be instantly graphed and reviewed, compared against external data, and exported to a variety of output
`formats for further analysis or presentation purposes.
`
`http://xcitex.com/html/proanalyst_description.php
`
`
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`C. Companies
`
`Xcitex – CoFounder, formerly CTO, formerly Vice-President, Board of Directors
`
`
`Xcitex was self-funded and grew through solid product development and consistent execution of our
`business strategy. As Xcitex’s first engineer, I developed the core of the flagship products - MiDAS
`and Pro Analyst. I also describe these products in a document that I include as supplemental material.
`As CTO and Vice-President of Xcitex, I built the technical team, architected and directed the
`development of products and solutions for the industrial and scientific video markets. Our products
`alone fueled our growth from startup to dominant market leader.
`
`
`dRNOME – CoFounder, Investor, Board of Director
`
`
`CueVue is a cloud computing and storage service for the scientific video industry - enabling video
`content query and generalized motion analysis in video content management systems. We provide
`tools for managing, manipulating, archiving, and searching your scientific video. It removes the
`necessity for its customers to make heavy investments in expensive hardware and software solutions,
`removes the overhead required to manage high-volume video needs, and we back this with a service
`level guarantee.
`
`Dynamic Time and Space Warping (DTSW), an algorithm that I developed for part of my doctoral work
`is core technology for CueVue - enabling video content query and generalized motion analysis in video
`content management systems.
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`dRNOME Inc. (CueVue.com – Launched in February 2011, sold technology in 2014). Our core
`technologies can be used to perform automated feature recognition of multiple streaming telemetry
`sources and to extract metadata and make this information available for ongoing operations, forensics,
`
`and security. Our products enable multi-camera real‐time feature recognition, extraction & tagging
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`automation.
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`0010
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`FITBIT, Ex. 1004
`
`

`

`Publications of Brian W. Anthony
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`1. Books:
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`2. Papers in Referred Journals:
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`N/A
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`2.1. B. Anthony, A. Abbate, D. Klimek, P. Kotidis., "Analysis of Ultrasonic Waves in Arbitrarily Oriented
`or Rotating Anisotropic Thin Materials", Quantitative Nondestructive Evaluation. Vol 18. pgs 215 -
`222. (1999).
`2.2 A. Abbate, B. Anthony, D. Klimek, P. Kotidis., "Analysis of Dispersive Ultrasonic Signals by the
`Ridges of the Analysitc Wavelet Transform", Quantitative Nondestructive Evaluation. Vol 18. pgs 703
`- 710. (1999).
`2.3 Dan Klimek, Brian Anthony, Agostino Abbate, Petros Kotidis, "Laser Ultrasonic Instrumentation for
`Accurate Temperature Measurement of Silicon Wafers in Rapid Thermal Processing Systems", Rapid
`Thermal and Integrated Processing VII, Materials Research Society, Volume 525, pg 135. (1999)
`2.4 Hardt, D.E., Anthony, B.W., Tor S.B., "A teaching factory for polymer microfabrication - µFac,"
`International Journal of Nanomanufacturing, 2010, Vol. 6, No.1/2/3/4, pp. 137 - 151.
`2.5 Shih-Yu Sun, Matthew Gilbertson, and Brian W. Anthony, "Probe Localization for Freehand 3D
`Ultrasound by Tracking Skin Features", Book Section, Medical Image Computing and Computer-
`Assisted Intervention - MICCAI 2014, Springer, 2014, Vol. 8674. Lecture Notes in Computer Science,
`Pages 365-372.
`2.6 Xian Du, Brian W. Anthony, Nigel C. Kojimoto, “Grid-based matching for full-field large-area
`deformation measurement”, Optics and Lasers in Engineering, Volume 66, March 2015, Pages 307-
`319.
`2.7 Xian Du, Nigel C. Kojimoto, Brian W. Anthony, “Concentric circular trajectory sampling for super-
`resolution and image mosaicing”, Journal of the Optical Society of America A, Volume 32, No. 2,
`February 2015, Pages 293-304.
`2.8 M. Gilbertson, B. Anthony. "A Force and Position Control System for Freehand Ultrasound", IEEE
`Transactions on Robotics, Volume 31, Issue 4. 2015.
`2.9 Andrey Kuzmin, Aaron Zakrzewski, Brian Anthony, Victor Lempitsky, "Multi-frame Elastography
`Using Handheld Force-Controlled Ultrasound Probe". Transactions on Ultrasonics, Ferroelectrics, and
`Frequency Control, Volume 62 , Issue 8, Pages 1486 – 1500, 2015.
`2.10 Xian Du and Brian Anthony, "Concentric circle scanning system for large-area and high-precision
`imaging," Optics Express, Vol 23, Issue 15, Pages 20014-20029, 2015.
`2.11 Du, X.., Anthony, B., “Controlled angular and radial scanning for super resolution concentric circular
`imaging,” Opt. Express 24(20), 22581, United States (2016).
`2.12 Jimenez, X., Shukla, S. K., Ortega, I., Illana, F. J., Castro-González, C., Marti-Fuster, B., Butterworth,
`I., Arroyo, M., Anthony, B., et al., “Quantification of Very Low Concentrations of Leukocyte
`Suspensions In Vitro by High-Frequency Ultrasound,” Ultrasound Med. Biol. 42(7), 1568–1573,
`England (2016).
`2.13 Koppaka, S., Shklyar, I., Rutkove, S. B., Darras, B. T., Anthony, B. W., Zaidman, C. M.., Wu, J. S.,
`“Quantitative Ultrasound Assessment of Duchenne Muscular Dystrophy Using Edge Detection
`Analysis,” J. Ultrasound Med. 35(9), 1889–1897, United States (2016).
`2.14 Lee, J., Boning, D., Anthony, B., "Measuring the Absolute Concentration of Microparticles in
`Suspension using High Frequency B-mode Ultrasound Imaging", Ultrasound in Medicine and
`Biology, Submitted, 2016
`2.15 Correa-de-Araujo, R., Harris-Love, M., Miljkoviv, I., Fragala, M.S., Anthony, B.W., Manini, T.,
`Newman, A.B., "The Need for Standardized Assessment of Muscle Quality in Skeletal Muscle
`
`0011
`
`FITBIT, Ex. 1004
`
`

`

`Publications of Brian W. Anthony
`
`Function Deficit and Other Aging-Related Muscle Dysfunctions: A Symposium Report", Frontiers in
`Physiology, Section on Striated Muscle Physiology, Submitted, 2016
`2.16 Zakrzewski, Aaron M., Anthony, Brian W., Non-Invasive Blood Pressure Estimation Using
`Ultrasound and Simple Finite Element Models, IEEE Transacations on Biomedical Engineering,
`Submitted, 2016.
`
`3. Proceedings of Refereed Conferences:
`
`
`3.1. Dipen N. Sinha, Brian W. Anthony, David C. Lizon, "Swept Frequency Acoustic Interferometery
`Techniques for Chemical Weapons Verification and Monitoring", Third International Conference
`On-Site Analysis, (1995).
`3.2. David E. Hardt, Brian W. Anthony and Shu Beng Tor, "A Teaching Factory for Polymer
`Microfabrication – muFac”, Proc. 5th International Symposium on Nano-Manufacturing (ISNM),
`Athens, November 12-15, 2008.
`3.3. Gilbertson, M., Anthony, B., and Sun, S.Y., "Handheld Force Controlled Ultrasound Probe", J. Med.
`Devices 4, 027540 (2010)
`3.4. Ljubicic, D. M., Anthony, B., "Development of a high-speed profilometer for manufacturing
`inspection," Proceedings of SPIE Vol. 7767, 776705 (2010).
`3.5. Sun, S., Anthony, B. W., Gilbertson, M. W., "Trajectory-based deformation correction in ultrasound
`images," Proceedings of SPIE Vol. 7629, 76290A (2010).
`3.6. Anthony, B. W., Hardt, D. E., Hale, M., et al., "A research factory for polymer microdevices: muFac,"
`Proceedings of SPIE Vol. 7593, 75930A (2010).
`3.7. Gilbertson, M. W., Anthony, B. W., "Impedance-controlled ultrasound probe," Proceedings of SPIE
`Vol. 7968, 796816 (2011).
`3.8. Ljubicic, D. M., Anthony, B. W., "3D high-speed profilometer for inspection of micro-manufactured
`transparent parts," Proceedings of SPIE Vol. 8082, 808211 (2011).
`3.9. Anthony, B.W, Hardt, D.E., "Revitalizing US Manufacturing to Capitalize on Innovation – Through
`Education" 119th ASEE Annual Conference, San Antonio TX, June 10-13, (2012)
`3.10. Anthony, B. W., Namvari, K., "Dimensional variation of polymer substrate electrode production,"
`Proceedings of SPIE Vol. 8251, 82510G (2012).
`3.11. Selvakumar, S., Linares, R., Oppenheimer, A., Anthony, B., "Variation analysis of flow rate delivered
`using a blister pump," Proceedings of SPIE Vol. 8251, 82510I (2012).
`3.12. Donoghue, L., Anthony, B. W., "Design for manufacture of a micro-interdigitated electrode for
`impedance measurement in a biochemical assay," Proceedings of SPIE Vol. 8251, 82510Y (2012).
`3.13. Holmes, J., Anthony, B. W., "Robustness and repeatability test of interdigitated electrodes on a
`polymer substrate in an aqueous environment," Proceedings of SPIE Vol. 8251, 825110 (2012).
`3.14. Sun, S.-Y, Anthony, B. W. “Freehand 3D ultrasound volume imaging using a miniature-mobile 6-
`DOF camera tracking system”. 2012 IEEE International Symposium on Biomedical Imaging (ISBI),
`2-5 May, (2012).
`3.15. Gilbertson, M.W., Anthony, B.A., 2012. "Ergonomic Controls Strategies for a Handheld Force-
`Controlled Ultrasound Probe," 2012 IEEE/RSJ Intelligent Robots and Systems (IROS) Conference.
`Vilamoura, Portugal. (2012)
`3.16. Sun, S.-Y, Gilbertson, M., Anthony, B. W. “6-DoF Probe Tracking via Skin Mapping for Freehand 3D
`Ultrasound”. 2013 IEEE International Symposium on Biomedical Imaging (ISBI), (2013).
`3.17. Sun, S.-Y, Gilbertson, M., Anthony, B. W. “Computer-Guided Ultrasound Probe Realignment by
`Optical Tracking”. 2013 IEEE International Symposium on Biomedical Imaging (ISBI), (2013).
`
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`
`
`0012
`
`FITBIT, Ex. 1004
`
`

`

`Publications of Brian W. Anthony
`
`3.18. Inamdar, T., Anthony, B. W., “Characterizing fluidic seals for on-board reagent delivery,"
`Proceedings of SPIE (2013).
`3.19. Zakrzewski, A., Anthony, B. W. “Quantitative Elastography and its Application to Blood Pressure
`Estimation: Theoretical and Experimental Results”. 2013 IEEE Engineering in Medicine and
`Biology Society (EMBS), (2013).
`3.20. Gilbertson, M. Anthony, B.W., “An Ergonomic, Instrumented Ultrasound Probe for 6-Axis
`Force/Torque Measurement”. 2013 IEEE Engineering in Medicine and Biology Society (EMBS),
`(2013).
`3.21. Dhyani, M, Gilbertson, M., Samir, A., Anthony, B.W., "Precise Quantification of Sonographic Forces:
`A First Step Toward Reducing Ergonomic Injury", 2014 AIUM Annual Convention, (2014).
`3.22. Koppaka, S., Gilbertson, M., Wu, J., Rutkove, S., Anthony, B. W. “Assessing Duchenne Muscular
`Dystrophy With Force-controlled Ultrasound”. 2014 IEEE International Symposium on Biomedical
`Imaging (ISBI), (2014).
`3.23. Koppaka, S., Gilbertson, M., Rutkove, S., Anthony, B. W. “Evaluating the Clinical Relevance of
`Force-correlated Ultrasound”. 2014 IEEE International Symposium on Biomedical Imaging (ISBI),
`(2014).
`3.24. J. H. Lee, C. M. Schoellhammer, G. Traverso, D. Blankschtein, R. Langer, K. E. Thomenius, D. S.
`Boning, B. Anthony, "Towards Wireless Capsule Endoscopic Ultrasound (WCEU)," IEEE
`International Ultrasonics Symposium (IUS), Chicago, IL, 2014, pp. 734-7.
`3.25. Zhang, Xiang; Fincke, Jonathan; Kuzmin, Andrey; Lempitsky, Victor; Anthony, Brian, "A single
`element 3D ultrasound tomography system," in Engineering in Medicine and Biology Society
`(EMBC), 2015 37th Annual International Conference of the IEEE , vol., no., pp.5541-5544, 25-29
`Aug. 2015.
`3.26. Ranger, Bryan J.; Feigin, Micha; Pestrov, Nikita; Zhang, Xiang; Lempitsky, Victor; Herr, Hugh M.;
`Anthony, Brian W., "Motion compensation in a tomographic ultrasound imaging system: Toward
`volumetric scans of a limb for prosthetic socket design," in Engineering in Medicine and Biology
`Society (EMBC), 2015 37th Annual International Conference of the IEEE , vol., no., pp.7

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