Homayoon Kazerooni

Homâyun Kâzeruni (Persian: همایون کازرونی, [hʊmɒːˈjuːn kʰɒːzeɾuːˈniː]) is a roboticist and professor of mechanical engineering at the University of California, Berkeley.[1]

همایون کازرونی
Homâyun Kâzeruni
Born
Alma materMassachusetts Institute of Technology
University of Wisconsin–Madison
Known forBLEEX
HULC
Scientific career
FieldsRobotics
Control theory
Mechatronics
InstitutionsUniversity of California, Berkeley

Kazerooni is the director of the Berkeley Robotics and Human Engineering Laboratory and also the Co-founder and Chief Scientist of Ekso Bionics.[2][3] The Berkeley Robotics and Human Engineering Laboratory is also known as "KAZ LAB".

Kazerooni’s work focuses on the control of human-machine systems specific to lower human extremities. After developing BLEEX, ExoHiker, and ExoClimber – three super-light, load-carrying exoskeletons – Berkeley Bionics and his team created HULC (Human Universal Load Carrier). It is the first energetically-autonomous, orthotic, lower extremity exoskeleton, providing the ability for its user to carry 200-pound weights over any sort of terrain for an extended period of time without undue effort.

These exoskeletons reduce the possibility of the wearer becoming fatigued and reaching their physiological endurance limit during critical military or industrial missions. HULC technology is currently licensed to Lockheed Martin for military applications. Kazerooni is currently working on extending this technology to aid persons who have experienced a stroke, spinal cord injuries or medical conditions that obligate them to use a wheelchair.

In 2011, the Berkeley Robotics and Human Engineering Laboratory enabled Austin Whitney, a paraplegic student at the University of California, Berkeley, to walk for commencement.[4] Kazerooni has started a project to develop low-cost exoskeleton systems to enable independence for individuals with gait deficiencies called the AUSTIN Project.[5] The Austin project is named after the first pilot for their medical exoskeleton.

Prior to his research work on lower extremity exoskeletons, Kazerooni led his team to successfully develop robotics systems that enhance human upper extremity strength. The results of this work led to a new class of intelligent assist devices currently being used by workers worldwide for manipulating heavy objects in distribution centers and factories. Kazerooni has also been conducting research on human performance in coordinated haptic-visual virtual environments under several contracts from NASA. Other research interests are biomimetic design, haptics, non-linear control systems, embedded systems, networked control systems, power regeneration, monopropellant and portable energy generation methods for mobile platforms.

Early in his career, Kazerooni was a recipient of the outstanding ASME Investigator Award, and has also won Discover Magazine’s Technological Innovation Award, and the McKnight-Land Grant Professorship. His research was recognized as the most innovative technology of the year in New York Times Magazine. He has served in a variety of leadership roles in the robotics community notably editor of two journals: ASME Journal of Dynamics Systems and Control and IEEE Transactions on Mechatronics.

Kazerooni holds a Doctorate in mechanical engineering from MIT and has over 30 years of mechanical engineering experience. He has published more than two hundred articles, delivered over 70 plenary lectures in the U.S. and internationally, and holds seventeen pertinent patents. As a noted authority on robotics, he is frequently profiled and quoted in the media.

Education

  • Ph.D., Massachusetts Institute of Technology, 1985, Design, Control Systems, Robotics, Human-Machine Systems, Manufacturing Machines.
  • MS, Massachusetts Institute of Technology, 1982, Design, Control Systems, Robotics, Manufacturing Machines.
  • MSME, University of WisconsinMadison, 1980, Design, Control Systems, Dynamics and Vibration.

Patents

  • Human power amplifier for lifting load with slack prevention apparatus [6]
  • Device and Method for Wireless Lifting Assist Devices [7]
  • Pneumatic human power amplifier module [8]
  • Mechanical grapple for grabbing and holding sacks and bags [9]
gollark: And a borrow checker, right?
gollark: Surely there must be side-channel-y vulnerabilities there.
gollark: This "tainted canvas" thing is... interesting. So you can fetch images from domains you can't normally access, and paint them onto canvases, but not read them back?
gollark: And have had various security issues because apparently the entire thing is designed by bees. Why do we even *have* SIM cards?
gollark: I think SIM cards actually run Java applications of some kind.

References

  1. Archived 2015-07-19 at the Wayback Machine, University of California, Berkeley
  2. "Archived copy". Archived from the original on 2011-08-31. Retrieved 2011-11-05.CS1 maint: archived copy as title (link), Berkeley Robotics and Human Engineering Laboratory
  3. "Archived copy". Archived from the original on 2011-10-31. Retrieved 2011-11-05.CS1 maint: archived copy as title (link), Ekso Bionics
  4. , CNN
  5. , Berkeley Robotics and Human Engineering Laboratory: Medical Exoskeletons
  6. Human power amplifier for lifting load with slack prevention apparatus
  7. Device and method for wireless lifting assist devices
  8. Pneumatic human power amplifier module
  9. Mechanical grapple for grabbing and holding sacks and bags
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.