Gregory Raleigh

Gregory “Greg” Raleigh (born 1961 in Orange, California), is an American radio scientist, inventor, and entrepreneur who has made contributions in the fields of wireless communication, information theory, mobile operating systems, medical devices, and network virtualization. His discoveries and inventions include the first wireless communication channel model to accurately predict the performance of advanced antenna systems,[1] the MIMO-OFDM technology used in contemporary Wi-Fi and 4G wireless networks and devices, higher accuracy radiation beam therapy for cancer treatment, improved 3D surgery imaging, and a cloud-based Network Functions Virtualization platform for mobile network operators that enables users to customize and modify their smartphone services.

Gregory G. Raleigh
Born1961
NationalityAmerican
Alma materStanford University, California Polytechnic State University
Known forInventor of the MIMO technology used in Wi-Fi, 4G and 5G wireless standards
Scientific career
FieldsTelecommunications

Biography

Raleigh received a B.S.E.E. degree from the California Polytechnic State University, an M.S.E.E. degree from Stanford University, and a Ph.D. from Stanford University. He joined Watkins-Johnson Company in 1984 as a Radio Engineer and rose to Chief Scientist and Vice President of Research and Development. Raleigh subsequently co-founded five companies: Clarity Wireless, Airgo Networks, Headwater Research, ItsOn, and Chilko Capital.

In wireless communications, Raleigh developed a comprehensive and precise channel model that works with multiple antennas.[2] He employed the model to develop smart antenna signal processing techniques for rapid fading, multipath propagation, and frequency-division duplex environments.[3][4][5][6][7][8] As a result of this research, Raleigh found that multipath propagation could be exploited to greatly increase the capacity of wireless communications, enabling data rates competitive with wire-based networks.[9] In a paper prepared for the 1996 GLOBECOM conference in London, Raleigh presented the first rigorous mathematical proof that in the presence of naturally occurring multipath propagation multiple antennas may be used with special signal processing techniques to transmit multiple data streams at the same time on the same frequency, multiplying the information-carrying capacity (data rate) of wireless links.[10] From the time of Guglielmo Marconi, multipath propagation had always been treated as a problem to be overcome. The discovery that multipath can be harnessed to increase performance reversed a century of radio engineering practice.[1] In subsequent papers, Raleigh proposed a series of enhancements including the use of OFDM with MIMO and techniques for space-frequency coding, space-frequency-time channel estimation, and MIMO synchronization.[11][12][13][14][15] These inventions were incorporated into the LTE, WiMAX, 802.11n and 802.11ac standards.

Raleigh, V.K. Jones, and Michael Pollack founded Clarity Wireless in 1996. Clarity built a MIMO demonstration link and developed a related technology, vector orthogonal frequency division multiplexing (V-OFDM). Clarity Wireless was acquired by Cisco Systems in 1998. Raleigh, Jones, and David Johnson founded Airgo Networks in 2001 to develop MIMO-OFDM chipsets for wireless LANs. Airgo Networks proposed MIMO as the best technology for meeting the performance goals of next-generation wireless LANs and contributed to the development of the IEEE 802.11n standard.[16] The company began shipping the world’s first MIMO-OFDM chipsets in 2003.[17] While at Airgo Networks, Raleigh was named to Network World’s “The 50 most powerful people in networking.”[18] Airgo Networks was purchased by Qualcomm in 2006.

Raleigh co-founded the technology innovation firm Headwater Research in late 2008 with Charles Giancarlo and became Lead Director of its board. Raleigh’s inventions at Headwater have spanned the wireless and medical device fields. The inventions include mobile device operating system enhancements, improvements to radiation beam therapy for cancer treatment, enhanced 3-D imaging systems for surgery, and cloud-based network function virtualization (NFV) advances.[19][20][21][22][23][24][25] Mobile OS controls and NFV are now widely deployed.[26]

In late 2009, Raleigh and Giancarlo spun out ItsOn to license and commercialize wireless technology, with Raleigh serving as the firm’s first CEO. ItsOn developed a cloud-based network function virtualization (NFV) platform that enables operators to implement intelligent, user context-aware policies including the ability for users to customize and manage their mobile phone services.[27] ItsOn’s service, called Zact, launched in May 2013.[28]

Raleigh holds more than 200 US patents[29] and over 150 international patents [30] in the fields of radio communications, medical devices, mobile device operating systems, radar systems, and mobile network function virtualization.

References

  1. Brodsky, Ira (2008). The History of Wireless: How Creative Minds Produced Technology for the Masses. Telescope Books. pp. 208–217. ISBN 978-0-980-03830-9.
  2. Raleigh, Gregory; et al. (1994). Characterization of fast fading vector channels for multi-antenna communication systems. Conference Record of the Twenty-Eighth Asilomar Conference on Signals, Systems and Computers. Pacific Grove, CA 31 Oct-2 Nov 1994. pp. 853–857 vol. 2. doi:10.1109/ACSSC.1994.471582.
  3. Raleigh, Gregory; Paulraj, A. (1995). Time varying vector channel estimation for adaptive spatial equalization. Global Telecommunications Conference, 1995. Singapore November 14–16, 1995. pp. 218–224 vol. 1. doi:10.1109/GLOCOM.1995.500355.
  4. Raleigh, Gregory; Diggavi, S.N.; Jones, V.K.; Paulraj, A. (1995). A blind adaptive transmit antenna algorithm for wireless communication. IEEE International Conference on Communications, 1995. Seattle, WA June 18–22, 1995. pp. 1494–1499 vol. 3. doi:10.1109/ICC.1995.524451.
  5. Bores, T.; Raleigh, G.G.; Pollack, M.A. (1996). Adaptive space-time equalization for rapidly fading communication channels. IEEE Global Telecommunications Conference, 1996. London November 18–22, 1996. pp. 984–989 vol. 2. doi:10.1109/GLOCOM.1996.587578.
  6. Raleigh, G.G.; Jones, V.K. (1997). Adaptive antenna transmission for frequency duplex digital wireless communication. IEEE International Conference on Communications, 1997. Montreal June 8–12, 1997. pp. 641–646 vol. 2. doi:10.1109/ICC.1997.609909.
  7. Raleigh, G.G.; Bores, T. (November 1998). "Joint space-time parameter estimation for wireless communication channels". IEEE Transactions on Signal Processing. 46 (5): 1333–1343. Bibcode:1998ITSP...46.1333R. doi:10.1109/78.668795.
  8. Pati, Y.C.; Raleigh, G.G.; Paulraj, A. (1995). Estimation of co-channel FM signals with multitarget adaptive phase-locked loops and antenna arrays. IEEE International Conference on Acoustics, Speech, and Signal Processing, 1995. Detroit, MI May 9–12, 1995. pp. 1741–1744 vol. 3. doi:10.1109/ICASSP.1995.480034.
  9. Marriott, Michel (19 September 2005). "A Company Looks to Wean Computers Off the Wires". The New York Times. Retrieved 12 November 2013.
  10. Raleigh, Gregory G.; Cioffi, John M. (1996). Spatio-temporal coding for wireless communications (PDF). Global Telecommunications Conference, 1996. London, UK November 18–22, 1996.
  11. Raleigh, G.G.; Jones, V.K. (1998). Multivariate modulation and coding for wireless communication. IEEE Global Telecommunications Conference, 1998. Sydney, Australia November 8–12, 1998. pp. 3261–3269 vol. 6. doi:10.1109/GLOCOM.1998.775808.
  12. Raleigh, G.G.; Jones, V.K. (November 1999). "Multivariate modulation and coding for wireless communication". IEEE Journal on Selected Areas in Communications. 17 (5): 851–866. doi:10.1109/49.768200.
  13. Raleigh, G.G.; Cioffi, J.M. (March 1998). "Spatio-temporal coding for wireless communication". IEEE Transactions on Communications. 46 (3): 357–366. doi:10.1109/26.662641.
  14. Jones, V.K.; Raleigh, G.G. (1998). Channel estimation for wireless OFDM systems. IEEE Global Telecommunications Conference, 1998. Sydney, Australia November 8–12, 1998. pp. 980–985 vol. 2. doi:10.1109/GLOCOM.1998.776875.
  15. Raleigh, G.G.; Cioffi, J.M. (1996). Spatio-temporal coding for wireless communications. IEEE Global Telecommunications Conference, 1996. London November 18–22, 1996. pp. 1809–1814 vol. 3. doi:10.1109/GLOCOM.1996.591950.
  16. O'Shea, Dan (28 February 2005). "Fast Forward". Connected Planet. Penton Media. Archived from the original on 16 November 2013. Retrieved 12 November 2013.
  17. "Airgo promises breakthrough in mobile-call quality". USA Today. Gannett Co. 18 August 2003. Retrieved 15 November 2013.
  18. Bort, Julie; Schultz, Beth (26 December 2005). "The 50 most powerful people in networking". Network World. IDG. Retrieved 12 November 2013.
  19. B2 US 9232403 B2, "Mobile device with common secure wireless message service serving multiple applications"
  20. B2 US 8351898 B2, "Verifiable device assisted service usage billing with integrated accounting, mediation accounting, and multi-account"
  21. B2 US 8900113 B2, "Tracking of tumor location for targeted radiation treatment"
  22. B2 US 8948842 B2, "Radiation treatment with multiple imaging elements"
  23. B2 US 8774903 B2, "Medical imaging apparatus and method"
  24. B2 US 9706061 B2, "Service design center for device assisted services"
  25. B2 US 9094868 B2, "User equipment link quality estimation based on positioning"
  26. Hill, Kelly (9 May 2013). "ABI: Flat, virtualized networks to shake up market". RCR Wireless. Arden Media. Retrieved 15 November 2013.
  27. Kim, Ryan (30 October 2012). "With $15M from Andreessen Horowitz, ItsOn wants to arm operators with options". GIGAOM. Retrieved 12 November 2013.
  28. Kharif, Olga (16 May 2013). "Innovator: Greg Raleigh's Zact, Pay-as-You-Go Custom Wireless". Bloomberg BusinessWeek. Retrieved 12 November 2013.
  29. "Results of Search in US Patent Collection (Gregory Raleigh)". United States Patent and Trademark Office. Retrieved 15 November 2013.
  30. "Results of Search in Free Patents Online (Gregory Raleigh)". Retrieved 3 December 2017.
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