Jack W. Judy

Associate Professor

Department of Electrical Engineering

University of California, Los Angeles

6731E Boelter Hall

420 Westwood Plaza

Los Angeles, CA 90095-1594

Citizenship: US

 

Office:	(310) 206-1371	Home:	(310) 209-5771
FAX:	(310) 861-5055	Email:	jjudy@ucla.edu
Mobile:	(310) 663-6679	Web:	www.ee.ucla.edu/~jjudy/

 

Education:

            Ph.D.      University of California, Berkeley, Electrical Engineering, December, 1996
Thesis: “Batch Fabricated Ferromagnetic Microactuators with Silicon Flexures”
Thesis Committee: Prof. R. S. Muller (advisor), R. M. White, S. Sanders, and T. Sands

            M.S.        University of California, Berkeley, Electrical Engineering, December, 1994
M. S. Report - “Magnetic Microactuation of Polysilicon Flexure Structures” (Advisor: R. S. Muller)

            B.E.E.     University of Minnesota, Minneapolis, Electrical Engineering, December, 1989 (summa cum laude) Honors Project Report - “Design of a Piezoelectric-Stepper Motor” (Advisor: D. L. Polla)

 

Research Interests:

-    Fabrication technologies, design methods, and applications for MEMS

-    Microsensors, microactuators, and magnetic materials

-    Low-power sensors for wireless sensor networks

-    Biomedical applications of MEMS - particularly neuroscientific instruments and prostheses

 

Research Experience:

 

University of California, Los Angeles (Associate Professor) – 2003 to present

-    Micromachined Patch-Clamp Arrays with Integrated Microfluidics for Single-Cell Dose-Response Measurements (NASA)

-    Restoration of Ocular Motility with a Closed-Loop Eye-Movement Control System (NIH/NEI)

-    Closed-Loop Control of Neural Activity (proposal to NIH)

-    Self-Clearing Micromachined Shunt for Hydrocephalus (proposal to Medtronic)

-    Nanoscale Tunable Frequency-Selective Surfaces (proposal to NSF)

-    Fully Implantable and Inductively Powered Wireless Neural Transceiver (proposal to NIH)

 

University of California, Los Angeles (Assistant Professor) – 1997 to 2003 (projects are still on-going)

-    IC-Compatible Ferromagnetic MEMS (NSF)

-    Micromachined Low-Power Magnetometers (DARPA)

-    MEMS Tunable Frequency-Selective Surfaces (NSF)

-    Development on High Density Electrode Arrays for Retinal Prostheses (NIH)

-    Microstimulator System for Chronic Stimulation of the STN (NIH)

-    Spinal Cord Recording and Stimulation Technologies (Roman Reed Foundation, proposal to NIH)

 

Silicon Light Machines, Sunnyvale (Member of the Technical Staff) – 1996 to 1997.

-   Designed and tested electrostatic microactuators (deformable diffraction gratings) for use in a MEMS-based projection display system

 

University of California, Berkeley (Graduate-Student Researcher) – 1991 to 1996.

-   Designed, fabricated, and tested magnetic microactuators with polysilicon flexures.

-   Present research is focused on improving flexure-based magnetic microactuators and applying them to microphotonic systems.

 

IBM Almaden Research Laboratory, Almaden, California (Summer Student) – 1991.

-   Investigated the application of magnetic materials to MEMS and compared the scaling issues of magnetic and electrostatic microactuators.

-   The processes used to fabricate thin-film magnetic recording heads were used to construct magnetic microactuators.

 

University of California, Berkeley (Graduate-Student Researcher) – 1990 to 1991.

-   Joined the Berkeley Sensor & Actuator Center and investigated various methods of microactuation.

 

University of Minnesota, Minneapolis (Graduate-Student Researcher) – 1989 to 1990.

-   Designed, constructed, and tested thermal microactuators and surface-micromachined membrane pumps.

 

University of Minnesota, Minneapolis (Undergraduate Honor Student) – 1988 to 1989.

-   Designed, constructed, and tested cm-scale piezoelectric-stepper motors with sub-mm step size.

 

Control Data Corporation, Arden Hills, Minnesota (Co-op Student) – Fall 1987, Summers of 1988-89.

-   Designed a test board for Control Data's version of the high-speed channel.

-   Wrote computer programs to greatly enhance the speed of digital-circuit design simulations.

 

Teaching Experience:

 

            University of California, Los Angeles - 1997 to present.

 

Students Advised:

 

-    Advising 8 Ph.D. students in Biomedical Engineering with an emphasis in NeuroEngineering (Jason Clevenger, Alejandro Covalin, Gene Fridman, Andy Hung, Selene Lee, George Scarlatis, Debra Strick, Calvin Yang)

 

Advisees who have completed their M.S. in Biomedical Engineering with my guidance:

-    Andy Hung (2003)

-    Jason Clevenger (2003)

-    Alejandro Covalin (2004) – expected

 

Advisees who have completed their Ph.D. in Biomedical Engineering with my guidance:

-    Pedro Irazoqui-Pastor (2003)

 

-    Advising 10 Ph.D. students in Electrical Engineering with an emphasis in MEMS
(Beverley Eyre, Dohyun Kim, Brian Matthews, Shahin Farshchi, Paulo Motta, Janet Stillman, Jeff Yee, Frank Zee, Joe Zendejas)

 

Advisees who have completed their M.S. in Electrical Engineering with my guidance:

-    Brian Matthews (2002)

-    Paulo Motta (2002)

-    Willem Ouborg (2002)

-    Henry Yang (2003)

-    Jeff Yee (2003)

-    Dan Vasquez (2003) – expected

-    Joe Zendejas (2003) – expected

Courses Created:

 

-   EE M150: Introduction to Micromachining and MEMS
(taught in the following terms: Winter 1998 to 1999, Fall 1999 to 2003):

A 10-week 30-hour lecture course on micromachining and microelectromechanical systems (MEMS). The lecture topics include scaling properties, photolithography, isotropic and anisotropic wet etching, MEMS release etching, stiction, dry etching, physical and chemical vapor deposition, electroplating, metrology, statistical design of experiments, and MEMS device testing. Combined with the laboratory course below (EE M150L), this course prepares students to be active participants in the growing MEMS and microsystems industry.

 

-   EE M150L: Introduction to Micromachining and MEMS Laboratory
(taught in the following terms: Winter 1998 to 1999, Fall 1999 to 2003):

A 10-week 40-hour hands-on laboratory course on micromachining and microelectromechanical systems (MEMS). The laboratory is designed to give students an understanding and hands-on experience with photolithography, isotropic and anisotropic wet etching, MEMS release etching, stiction, dry etching, physical and chemical vapor deposition, electroplating, metrology, and MEMS device testing. The layout of the course chip enables students to produce over 100 different devices using both bulk micromachining and surface micromachining. The layout of the chip includes microsensors (accelerometers, pressure sensor, resonant magnetometers), microactuators (torsional magnetic microactuators, optical switches, thermal microactuators), and microstructures (cantilever beams, bridges, neural probes, needles, thin-film stress test structures, bulk micromachining test structures, electrical test structures). Combined with the above lecture course (EE M150), this course prepares students to be active participants in the growing MEMS and microsystems industry.

 

-   NeuroEngineering Training Program and Curriculum (Fall 1999 to present):

The objectives of the NeuroEngineering Training Program are: (1) to enable students with a background in biological science to develop and execute projects that make use of state-of-the-art technology, such as microelectromechanical systems (MEMS); (2) to enable students with a background in engineering to develop and execute projects that address problems that have a neuroscientific base, such as locomotion and pattern generation, central control of movement, and the processing of sensory information; and (3) to enable all trainees to develop the capacity for the multidisciplinary teamwork that will be necessary for new scientific insights and dramatic technological progress. The goal of the UCLA NeuroEngineering Training Program is to prepare graduate students to be leaders in the revolutionary technology developments that will affect neuroscience in the 21st Century. Thus far, the excitement and energy of the neuroengineering students and faculty indicate we are off to a tremendous start.

 

-   BME260: NeuroEngineering (Spring 2000 to, 2003):

Covers the primary engineering technologies being used in neuroscience now and those new and evolving engineering technologies that are likely to be useful for neuroscience in the future. In addition, we described several of the neuroscientific issues that are currently being addressed (e.g., deafness, epilepsy, etc.) and those we hope to address in the future (e.g., blindness, Parkinson’s disease, paralysis, etc.).

 

Courses Taught:

 

-    EE100: Electrical and Electronic Circuits (Spring 2002)

This is a core course for the Electrical Engineering Department that is intended for non-EE majors.

 

-   EE250A: MEMS Fabrication (Fall 1998, 1999, Winter 2000-2003)

    A graduate-level course on MEMS fabrication that builds upon the basic concepts and processes introduced in EE150L.

 

-   EE250B: MEMS Device Physics and Design (Winter 1999)

    A graduate-level course on the physical principles exploited by MEMS as well as their design methods and methodologies.

 

-   EE250C: Microsensors and Microinstruments (Spring 1999)

    The integration of MEMS into complete sensor and instrument systems with an emphasis on system-level issues.

 

-   Neuroscience210B: Introduction to Current Literature in Neuroscience (Winter 1999)

 

-   BME 261 / Neuroscience212A: Evaluation of Research Literature in Neuroengineering (Fall 2000 to 2003)

The literature in neuroengineering and related fields are critically review by all participants. It is a valuable experience where the different backgrounds and perspectives of the neuroengineers are clearly observed and useful when discussing highly challenging and multidisciplinary issues.

 

National Technological University (NTU) / University of California, Berkeley - Spring 1996.
Course Consultant for NTU IC 731CA / UCB: EE 243: Advanced IC Processing and Layout, a graduate course in electrical engineering taught by Prof. Nathan Cheung, Prof. Andy Neureuther, and Prof. Costos Spanos. The number of IC-processing related subjects covered in this course is extensive. This course, like other NTU courses, is broadcast to participating industrial sites where students, typically engineers working in the field of IC processing, watch the classes and mail in homework and exams. Responsibilities included grading homework and exams, answering student questions with frequent phone conversations that replaced office hours, holding conference calls with the professors before exams, and improving the course materials, most notably creating the web-page interface to simplify the process for students to gain access and use the required CAD programs SAMPLE and SPALT.

 

University of California, Berkeley - Fall 1994.
Head Graduate-Student Instructor of EECS 143: Processing and Design of Integrated Circuits, an undergraduate course in electrical engineering taught by Prof. Andy Neureuther. This course has its own dedicated clean room for the microfabrication of integrated circuits during laboratory sessions. Responsibilities included organizing the labs, instructing a lab session, maintaining process quality, updating the course materials, and directing review sessions.

 

University of California, Berkeley - Fall 1991.
Graduate-Student Instructor of EECS 105: Microelectronic Devices and Circuits, an undergraduate course in electrical engineering taught by Prof. Richard S. Muller and Dr. Gani Jusuf. Responsibilities included instructing a laboratory session and a discussion section.

 

Professional Service:

-   Chair: IEEE Magnetics Society, Los Angeles Council, 2003 to 2004.

-   Technical Program Committee: Solid-State Sensors and Actuators Workshop, 2001 to 2004

-   Session Chair: International Solid-State Sensors and Actuators Conference, 1999 to 2001

-   Technical Program Committee: International Solid-State Circuits Conference, 2000 to 2001

-   Session Chair: International Solid-State Circuits Conference, 2000

-   Program Committee: International Symposium on Smart Structures and Microsystems 2000

-   Program Committee: SPIE: Micromachining and Microfabrication: MEMS Reliability for Critical Applications, 1999 to 2000

-   Organizer, Invited Speaker Session at the APS Meeting, Los Angeles, 1998

 

Awards, Fellowships, and Honors

-   Okawa Foundation - 2002

-   NSF Career Award - 1998

-   IBM Fellowship - 1991

-   Rosemount Instrumentation Award - 1989

 

Academic Organizations:

-    Member of Eta Kappa Nu, Tau Beta Pi, and Phi Kappa Phi

 

Professional Memberships:

-   IEEE – Member (1987 to 2002), Senior Member (2002 to present)
Societies: Magnetics, Electron Devices, Engineering in Medicine and Biology

-   Electrochemical Society – Member

-   Society for Neuroscience – Member

 

List of Publications

Refereed Journals:

 

1.        Jack W. Judy, Dennis L. Polla, William P. Robbins, “A linear piezoelectric stepper motor with sub-micrometer step size and centimeter travel range,” IEEE Transaction on Ultrasonics, Ferroelectrics and Frequency Control, vol. UFFC-37, no. 5, September 1990, pp. 428-437. (pdf)

2.        Jack W. Judy, Richard. S. Muller, and Hans. H. Zappe, “Magnetic microactuation of polysilicon flexure structures,” IEEE Journal of Microelectromechanical Systems, vol. 4, no. 4, December 1995, pp. 162-169. (pdf)

3.        Jack W. Judy and Richard. S. Muller, “Magnetic microactuation of torsional polysilicon structures,” Sensors and Actuators A (Physical), vol. A53, no. 1-4, May 1996, pp. 392-396. (pdf)

4.        Jack W. Judy and Richard. S. Muller, “Magnetically Actuated, Addressable Microstructures” IEEE Journal of Microelectromechanical Systems, vol. 6, no. 3, September 1997, pp. 249-256. (pdf)

5.        Juno Kim, Yongxi Qian, Guojin Feng, Pingxi Ma, Jack Judy, M. Frank Chang, and Tatsuo Itoh, “A Novel Low-Los Low-Crosstalk Interconnect for Broad-Band Mixed-Signal Silicon MMIC’s”, IEEE Trans. Microwave Theory and Techniques, vol. 47, no. 9, September 1999, pp. 1830-1835. (pdf)

6.        Frank Zee, Jack W. Judy, “Micromachined polymer-based chemical gas sensor array”, Sensors and Actuators B: Chemical, vol. 72, no. 2, January 2001, pp. 120-128. (pdf)

7.        Jack W. Judy, “Microelectromechanical Systems (MEMS) - Their Design, Fabrication, and Broad Range of Application”, Journal of Smart Materials, vol. 10, no. 6, December 2001, pp. 1115-1134. (pdf)

8.        Xianwen Fang, Nosang Myung, Ken Nobe, and Jack W. Judy, “Modeling the Effect of Etch Holes on Ferromagnetic MEMS”, IEEE Transactions on Magnetics, vol. 37, no. 4, pt. 1, July 2001, pp. 2637-2639. (pdf)

9.        Brian Matthews, Jing Li, Steven Sunshine, Lee Lerner, and Jack W. Judy, “Effects of Electrode Configuration on Polymer Carbon-Black Composite Chemical Vapor Sensor Performance”, IEEE Sensors Journal, June, vol. 2, no. 3, June 2002, pp. 160-168. (pdf)

10.     Henry Yang, Nosang Myung, Jeff Yee, D.-Y. Park, Bongyoung Yoo, Morton Schwartz, Ken Nobe, and Jack W. Judy, “Ferromagnetic Micromechanical Magnetometer”, Sensors and Actuators, A (Physical), vol. A97-A98, July 2002, pp. 88-97. (pdf)

11.     Jeffrey K. Yee, Henry H. Yang, and Jack W. Judy, “Shock Resistance of Ferromagnetic Micromechanical Magnetometers”, Sensors and Actuators, A (Physical), vol. A103, no. 1-2, January 2003, pp. 242-252. (pdf)

12.     John P. Gianvittorio, Joe Zendejas, Yahya Rahmat-Samii, and Jack W. Judy, “Reconfigurable MEMS-Enabled Frequency Selective Surfaces”, Electronics Letters, vol. 38, no. 25, December 2002, pp. 1627-1628. (pdf)

13.     Submitted – Pedro Irazoqui-Pastor, Istvan Mody, and Jack W. Judy, “Inductive Powering in Miniature Implantable Neural Recording Devices”, IEEE Transaction on Biomedical Engineering, September 2002.

 

Refereed Conferences:

 

1.        Jack W. Judy, Dennis L. Polla, William P. Robbins, “Experimental model and IC-process design of a nanometer linear piezoelectric stepper motor,” ASME Winter Meeting, Dallas, 1990. (pdf)

2.        Jack W. Judy, Takashi Tamagawa, Dennis, L. Polla, “Micromachined linear thermal microactuator,” International Electron Devices Meeting Technical Digest, San Francisco, CA (December 9-12, 1990), pp. 629-632. (pdf)

3.        Jack W. Judy, Takashi Tamagawa, and Dennis, L. Polla, “Micromechanical membrane pump,” Proceedings IEEE Micro Electro Mechanical Systems, Nara, Japan (January 30 - February 2, 1991), pp. 182-186. (pdf)

4.        William P. Robbins, Dennis L. Polla, Takashi Tamagawa, Daniel. E. Glumac, and Jack W. Judy, “Linear motion microactuators using piezoelectric thin films,” International Solid-State Sensor and Actuator Conference Digest of Technical Papers (Transducers `91), San Francisco, CA (June 24-27, 1991), pp. 55-58. (pdf)

5.        Jack W. Judy, Richard. S. Muller, and Hans. H. Zappe, “Magnetic microactuation of polysilicon flexure structures”, Tech. Dig. Solid-State Sensor and Actuator Workshop (Hilton Head `94), Hilton Head Island, SC (June 13-16, 1994), pp. 43-48. (pdf)

6.        Jack. W. Judy and Richard. S. Muller, “Magnetic microactuation of torsional polysilicon structures,” International Solid-State Sensor and Actuator Conference Digest of Technical Papers (Transducers `95), Stockholm, Sweden (June 25-29, 1995), vol. 1, pp. 332-335. (pdf)

7.        Jack. W. Judy and Richard. S. Muller, “Fabrication of magnetic microactuators with polysilicon flexures,” Proceedings of the Second International Symposium on Magnetic Materials, Processes, and Devices, Chicago, IL (October 9-13, 1995), pp. 451-460. (pdf)

8.        Jack W. Judy and Richard. S. Muller, “Batch-Fabricated, Addressable, Magnetically Actuated Microstructures”, Tech. Dig. Solid-State Sensor and Actuator Workshop (Hilton Head `96), Hilton Head Island, SC (June 3-6, 1996), pp. 187-190. (pdf)

9.        Frank Zee and Jack W. Judy, “Micromachined MEMS Chemical Gas Sensor using a Polymer-Based Array”, International Solid-State Sensor and Actuator Conference Digest of Technical Papers (Transducers `99), Sendai, Japan (June 7-10, 1999), pp. 680-683. (pdf)

10.     Frank Zee and Jack W. Judy, “MEMS Chemical Gas Sensor”, 13^th Biennial University / Government / Industry Microelectronics Symposium (UGIM `99), Minneapolis, MN (June 20-23, 1999), pp. 150-152. (pdf)

11.     Frank Zee and Jack W. Judy, “Miniaturization of A Carbon Black/Polymer Array Electronic Nose”, 6^th International Symposium - Olfaction and Electronic Nose, (ISOEN `99), Tübingen, Germany (September 20-22, 1999), pp. TBD. (pdf)

12.     Frank Zee and Jack W. Judy, “Miniature electronic noise system based on polymer/carbon black films”, 4^th East Asian Conference on Chemical Sensors, Hsinchu, Taiwan (November, 23-26, 1999), pp. 153-156. (pdf)

13.     Jack W. Judy, “Biomedical Applications of MEMS”, Measurement Science and Technology Conference, Anaheim, CA (January 20-22, 2000), pp. 403-414 – Invited Talk. (pdf)

14.     Jack W. Judy, Henry Yang, Pedro Irazoqui-Pastor, Ken Yang, Nosang Myung, Morton Schwartz, and Ken Nobe, “Ferromagnetic Micromechanical Magnetometers”, Late News Tech. Dig. Solid-State Sensor and Actuator Workshop (Hilton Head 2000), Hilton Head Island, SC (June 4-8, 2000), pp. 15-16. (pdf)

15.     Nosang V. Myung, Henry Yang, Morton Schwartz, Jack W. Judy, Ken C.-K. Yang, and Ken Nobe, “Electrodeposited Magnetic Thin Films for MEMS Applications”, Proceedings of the Fifth International Symposium on Magnetic Materials, Processes, and Devices, 198th Meeting of the Electrochemical Society, Phoenix, AZ (October 22-27, 2000), pp. 506-520. (pdf)

16.     Jack W. Judy, Henry Yang, Nosang V. Myung, Ken C.-K. Yang, Morton Schwartz, and Ken Nobe, “Integrated Ferromagnetic Microsensors and Microactuators”, Proceedings of the Fifth International Symposium on Magnetic Materials, Processes, and Devices, 198th Meeting of the Electrochemical Society, Phoenix, AZ (October 22-27, 2000), pp. 456-468. (pdf)

17.     Xianwen Fang, Nosang Myung, Ken Nobe, and Jack W. Judy, “Modeling the Effect of Etch Holes on Ferromagnetic MEMS”, 8^th Joint MMM-Intermag Conference, San Antonio, TX, January 8-11, 2001, pp. 455-456. (pdf)

18.     Jack W. Judy, “ Magnetic MEMS – An Introduction and Review”, 8^th Joint MMM-Intermag Conference, San Antonio, TX, January 8-11, 2001, pp. 9-10. (pdf) – Invited Talk

19.     Henry Yang, Nosang Myung, Jeff Yee, Morton Schwartz, Ken Nobe, and Jack W. Judy, “Ferromagnetic Micromechanical Magnetometers”, International Conference on Solid-State Sensor and Actuators (Transducers 2001), Munich, Germany, (June 10-14, 2001), pp. 164-167. (pdf)

20.     Jeff Yee, Henry Yang, and Jack W. Judy, “Shock Resistance and Dynamic Response of Ferromagnetic Micromechanical Magnetometers”, IEEE Micro Electro Mechanical Systems Workshop (MEMS 2002), Las Vegas, Nevada, (January 20-24, 2002), pp. 308-311. (pdf)

21.     Andy Hung, David Zhou, Robert Greenberg, and Jack W. Judy, “Micromachined Electrodes for High Density Neural Stimulation Systems”, IEEE Micro Electro Mechanical Systems Workshop (MEMS 2002), Las Vegas, Nevada, (January 20-24, 2002), pp. 56-59. (pdf)

22.     Jack W. Judy and Nosang Myung, “Magnetic Materials for MEMS”, MRS Workshop on MEMS Materials, San Francisco, California, (April 5-6, 2002), pp. 23-26. (pdf)

23.     Andy Hung, David Zhou, Robert Greenberg, and Jack W. Judy, “Micromachined Electrodes for High Density Neural Stimulation Systems”, 2nd Annual International, IEEE-EMBS Special Topic Conference on Microtechnologies in Medicine & Biology, Madison, Wisconsin, (May 2-4, 2002), pp. 76‑79. (pdf)

24.     Paulo Motta and Jack W. Judy, “Micromachined Probes for Deep-Brain Stimulation”, 2nd Annual International, IEEE-EMBS Special Topic Conference on Microtechnologies in Medicine & Biology, Madison, Wisconsin, (May 2-4, 2002), pp. 251‑254. (pdf)

25.     Paulo Motta and Jack W. Judy, “Multielectrode Microprobes for Deep-Brain Stimulation Fabricated using a Novel 3-D Shaping Electroplating Process”, Dig. Solid-State Sensor and Actuator Workshop (Hilton Head 2002), Hilton Head Island, SC (June 2-6, 2002). (pdf)

26.     Joe Zendejas, John Gianvittorio, Yahya Rahmat-Samii, and Jack W. Judy, “Micromachined Magnetically Reconfigurable Frequency-Selective Surfaces”, Dig. Solid-State Sensor and Actuator Workshop (Hilton Head 2002), Hilton Head Island, SC (June 2-6, 2002). (pdf)

27.     Jack W. Judy and Paulo Motta, “Introduction to Micromachining and MEMS: A Lecture and Hands-On Laboratory Course for Undergraduate and Graduate Students from all Backgrounds”, International Conference on Engineering Education, Manchester, England (Aug 18-21, 2002). (pdf)

28.     Gianvittorio, John P., Joe Zendejas, Yahya Rahmat-Samii and Jack W. Judy. “MEMS Enabled Reconfigurable Frequency Selective Surfaces: Design, Simulation, Fabrication, and Measurement”, IEEE International Symposium on Antennas & Propagation, San Antonio, Texas (June 16-21), 2002, pp. 404-407. (pdf)

29.     Willem-Jan Ouborg, Nosang Myung, Ken Nobe, and Jack W. Judy, “Effect of Etch Holes on the Performance of Ferromagnetic MEMS”, Proceedings of the Seventh International Symposium on Magnetic Materials, Processes, and Devices, 202^nd Meeting of the Electrochemical Society, Salt Lake City, UT (October 20-25, 2002). (pdf - abstract)

30.     Joe Zendejas, John Gianvittorio, Bongyoung Yoo, Yahya Rahmat-Samii, Ken Nobe, and Jack W. Judy, “Ferromagnetic MEMS Arrays for Reconfigurable Frequency Selective Surfaces”, Proceedings of the Seventh International Symposium on Magnetic Materials, Processes, and Devices, 202^nd Meeting of the Electrochemical Society, Salt Lake City, UT (October 20-25, 2002). (pdf - abstract)

31.     Pedro Irazoqui-Pastor, Istvan Mody, and Jack W. Judy, “Transcutaneous RF-Powered Neural Recording Device”, 24^th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Houston, TX (Oct 23-26, 2002). (pdf)

32.     Jack W. Judy, “UCLA NeuroEngineering Program”, 32^nd Annual Meeting of the Society for Neuroscience, Orlando, FL (Nov 2-7, 2002). (pdf - abstract)

33.     Paulo Motta and Jack W. Judy, “Multielectrode Microprobes for Deep-Brain Stimulation”, 32^nd Annual Meeting of the Society for Neuroscience, Orlando, FL (Nov 2-7, 2002). (pdf - abstract)

34.     Pedro Irazoqui-Pastor, Istvan Mody, and Jack W. Judy, “Wireless Recording Device for Chronic Monitoring of EEG and Single-Unit Activity”, 32^nd Annual Meeting of the Society for Neuroscience, Orlando, FL (Nov 2-7, 2002). (pdf - abstract)

35.     Pedro Irazoqui-Pastor, Istvan Mody, and Jack W. Judy, “In-Vivo EEG Recording Using a Wireless Implantable Neural Transceiver”, 1^st International IEEE EMBS Neural Engineering Conference, Capri, Italy (March 20-22, 2003). (pdf)

36.     Brian Matthews and Jack W. Judy, “Characterization of a Micromachined Planar Patch Clamp for Cellular Electrophysiology”, 1^st International IEEE EMBS Neural Engineering Conference, Capri, Italy (March 20-22, 2003). (pdf)

37.     Andy Hung, David Zhou, Robert Greenberg, and Jack W. Judy, “Dynamic Electrochemical Simulation of Micromachined Electrodes for Neural-Stimulation Systems”, 1^st International IEEE EMBS Neural Engineering Conference, Capri, Italy (March 20-22, 2003). (pdf)

38.     Jack W. Judy and Allan J. Tobin, “UCLA Neuroengineering Research and Training Program”, 1^st International IEEE EMBS Neural Engineering Conference, Capri, Italy (March 20-22, 2003). (pdf)

39.     Jack W. Judy and Paulo Motta, “A Lecture and Hands-On Laboratory Course: Introduction to Micromachining and MEMS”, University/Government/Industry Microelectronics Symposium, Boise, Idaho, (June 30 – July 2, 2003). (pdf)

40.     Jack W. Judy and Allan J. Tobin, “NeuroEngineering - The Integration of Neuroscience with Engineering”, International Conference on Engineering Education, Valencia, Spain, (July 21-25, 2003). (pdf)

41.     Invited –Jack Judy, “Microelectrode Technologies for Neuroengineered Systems”, 25^th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Cancun, Mexico (Sep 17-21, 2003). (pdf)

42.     Alejandro Covalin, V. Reggie Edgerton, Niranjala Tillakaratne, Jack Judy, and Alan Garfinkel, “A Nonlinear Quantitative Method for Assessing Locomotor Performance”, 25^th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Cancun, Mexico (Sep 17-21, 2003). (pdf)

43.     Brian Matthews and Jack W. Judy, “Towards a Fully Automated Planar Patch Clamp Dose-Response Measurement System”, 7^th International Conference on Miniaturized Chemical and BioChemical Analysis Systems, Squaw Valley, California (October 5-9, 2003), pp. 1235-1238. (pdf)

44.     Dan Vasquez and Jack W. Judy, “Zero-Power Magnetometers with Remote Optical Interrogation”, 17^th IEEE International Conference on Micro Electro Mechanical Systems (MEMS 2004), Maastricht, The Netherlands, (January 25-29, 2004), pp. 109-112.

 

Masters Theses:

 

1.        Jack. W. Judy, “Magnetic microactuators with polysilicon flexures”, M.S. Thesis, EECS Department, University of California, Berkeley, (August 1994). (pdf)

2.        Xianwen Fang, “Design, Fabrication and Modeling of Magnetic Microelectromechanical System (MEMS) Components for Sensor, Actuator Applications”, M.S. Thesis, Electrical Engineering Department, University of California, Los Angeles, (2000). (pdf)

3.        Brian Matthews, “Effects of Electrode Configuration on Polymer Carbon Black Composite Chemical Vapor Sensor Performance”, M.S. Thesis, Electrical Engineering Department, University of California, Los Angeles, (March 2002). (pdf)

4.        Paulo S. Motta, “Mobile Miniature Deep-Brain Stimulator for Parkinson's Disease Research”, M.S. Thesis, Electrical Engineering Department, University of California, Los Angeles, (May 2002). (pdf)

5.        Jeff Yee, “Shock Resistance of Ferromagnetic Micromechanical Magnetometers”, M.S. Thesis, Electrical Engineering Department, University of California, Los Angeles, (May 2003). (pdf)

6.        Henry Yang, “Novel Ferromagnetic Micromechanical Magnetometers”, M.S. Thesis, Electrical Engineering Department, University of California, Los Angeles, (May 2003). (pdf)

7.        Andy Hung, "Micromachined High-Density Electrodes for Retinal Prosthesis", M.S. Thesis, Electrical Engineering Department, University of California, Los Angeles, (May 2003). (pdf)

8.        Jason Clevenger, “Development of a Unique Laboratory and Setup to Study the Recovery of Ocular Motility”, M.S. Thesis, Biomedical Engineering Interdepartmental Program, University of California, Los Angeles, (May 2003). (pdf)

 

Ph.D. Dissertations:

 

1.        Jack. W. Judy, “Batch-fabricated ferromagnetic microactuators with silicon flexures”, Ph.D. Thesis, EECS Department, University of California, Berkeley, (December 1996). (pdf)

2.        Pedro Irazoqui-Pastor, “Transcutaneous Inductively Powered Neural Recording System”, Ph.D. Thesis, Biomedical Engineering Interdepartmental Program, University of California, Los Angeles, (May 2003). (pdf)

 

Patents and Disclosures:

 

1.        US Patent 5,945,898: “Magnetic Microactuator”, granted August 31, 1999 (licensed).

2.        US Patent 6,593,130: “Method and Apparatus for Ex Vivo and In Vivo Cellular Electroporation of Gene Protein or Drug Therapy”, granted July 15, 2003.

3.        US Patent Disclosure: “Magnetically Reconfigurable Frequency Selective Surface”, submitted June 2003.

4.        US Patent Disclosure: “Planar Patch Clamp for Cellular Electrophysiology”, submitted January 2004.