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Draft:Ozgur Oyman

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Ozgur Oyman

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Education

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Ozgur Oyman received a B.S in 2000 from Cornell University, an MS in 2002 and a PhD in 2005 from Stanford University[1]

Professional Life

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Ozgur Oyman is currently employed by Apple Inc.[2] as engineering manager. From 2005 to 2021, he was a Principal Engineer at Intel Corporation[3] Santa Clara, CA, U.S.A. Between 2017 and 2021, he was a member of the Board of Directors at Virtual Reality Industry Forum (VR-IF)[4] He served as an Associate Editor for IEEE Transactions on Communications between 2010 and 2021[5]

Research

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Ozgur Oyman has published in the areas of multimedia, computer networks and wireless communications[6] He also holds over 100 issued U.S. patents, and over 500 issued patents globally[7] Ozgur Oyman's have D-index- 35, his research papers are cited approximately 5451, his total publications are 94, world ranking 4913 and national ranking 1691.[8] According to AD Scientific Index, Ozgur Oyman comes in 100 leading scientists at Apple Inc., with H-Index 40 (rank 26 at Apple Inc.), i10 Index 106 (rank 22 at Apple Inc) and citations 6,247 (rank 63 at Apple Inc.)[9]

Most Cited Work

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  1. Capacity scaling laws in MIMO relay networks (782 citations)[10]
  2. Quality of experience for HTTP adaptive streaming services (397 citations)[11]
  3. Characterizing the statistical properties of mutual information in MIMO channels (268 citations)[12]

Patents Granted

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Patent number: 12238158[13] Type: Grant

Filed: October 24, 2023

Date of Patent: February 25, 2025

Assignee: Intel Corporation

Inventors: Ozgur Oyman, Gang Shen, Wenqing Fu, Wei Zong, Juan Zhao

12155701[14] Type: Grant

Filed: August 23, 2023

Date of Patent: November 26, 2024

Assignee: Apple Inc.

Inventors: Ozgur Oyman, Jerome Parron, Thomas Luetzenkirchen, Sudhir Shankar Pola, Ralf Rossbach

12088959[15] Type: Grant

Filed: October 14, 2020

Date of Patent: September 10, 2024

Assignee: Intel Corporation

Inventors: Ozgur Oyman, Gang Shen, Wenqing Fu, Wei Zong, Juan Zhao

12004247[16] Type: Grant

Filed: June 25, 2020

Date of Patent: June 4, 2024

Assignee: Apple Inc.

Inventors: Jerome Parron, Yujian Zhang, Ozgur Oyman

11991233[17] Type: Grant

Filed: July 29, 2021

Date of Patent: May 21, 2024

Assignee: Intel Corporation

Inventors: Ozgur Oyman, Gang Shen

11751101[18] Type: Grant

Filed: September 2, 2022

Date of Patent: September 5, 2023

Assignee: Apple Inc.

Inventors: Hyung-Nam Choi, Ozgur Oyman, Jerome Parron, Marta Martinez Tarradell

11765404[19] Type: Grant

Filed: October 25, 2019

Date of Patent: September 19, 2023

Assignee: APPLE INC.

Inventors: Ching-Yu Liao, Ozgur Oyman

11770421[20] Type: Grant

Filed: November 3, 2022

Date of Patent: September 26, 2023

Assignee: Apple Inc.

Inventors: Ozgur Oyman, Jerome Parron, Thomas Luetzenkirchen, Sudhir Shankar Pola, Ralf Rossbach

11831861[21] Type: Grant

Filed: August 11, 2020

Date of Patent: November 28, 2023

Assignee: Intel Corporation

Inventors: Ozgur Oyman, Fai Yeung, Harleen Gill, Kimberly Loza

11838345[22] Type: Grant

Filed: December 4, 2020

Date of Patent: December 5, 2023

Assignee: Intel Corporation

Inventors: Ozgur Oyman, Gang Shen, Wenqing Fu, Wei Zong, Juan Zhao

11936707[23] Type: Grant

Filed: October 31, 2019

Date of Patent: March 19, 2024

Assignee: Apple Inc.

Inventors: Ozgur Oyman, Thomas Luetzenkirchen, Usharani Ayyalasomayajula, Sudhir Shankar Pola, Fabrice Plante, Ganesh Vijayan

11729243[24] Type: Grant

Filed: September 21, 2020

Date of Patent: August 15, 2023

Inventors: Ozgur Oyman, Fai Yeung, Harleen Gill, Kimberly Loza

10432692[25] Type: Grant

Filed: August 9, 2016

Date of Patent: October 1, 2019

Assignee: INTEL CORPORATION

Inventor: Ozgur Oyman

10455404[26] Type: Grant

Filed: October 29, 2018

Date of Patent: October 22, 2019

Assignee: INTEL CORPORATION

Inventor: Mohamed Rehan, Rana Morsi, Ozgur Oyman

10476930[27] Type: Grant

Filed: December 24, 2014

Date of Patent: November 12, 2019

Assignee: INTEL CORPORATION

Inventor: Mohamed Rehan, Rana Morsi, Ozgur Oyman, Vishwanath Ramamurthi

10491861[28] Type: Grant

Filed: August 3, 2017

Date of Patent: November 26, 2019

Assignee: INTEL CORPORATION

Inventor: Ozgur Oyman

10523982[29] Type: Grant

Filed: August 24, 2017

Date of Patent: December 31, 2019

Assignee: INTEL CORPORATION

Inventor: Ozgur Oyman

10581929[30] Type: Grant

Filed: February 5, 2018

Date of Patent: March 3, 2020

Assignee: Apple Inc.

Inventor: Ozgur Oyman

10681107[31] Type: Grant

Filed: December 23, 2015

Date of Patent: June 9, 2020

Assignee: Apple Inc.

Inventor: Ozgur Oyman

10701119[32] Type: Grant

Filed: December 22, 2015

Date of Patent: June 30, 2020

Assignee: Apple Inc.

Inventor: Ozgur Oyman

10721715[33] Type: Grant

Filed: December 22, 2015

Date of Patent: June 30, 2020

Assignee: Apple Inc.

Inventor: Ozgur Oyman

10721715[34] Type: Grant

Filed: February 27, 2014

Date of Patent: July 21, 2020

Assignee: Apple Inc.

Inventor: Vishwanath Ramamurthi, Ozgur Oyman

10778458[35] Type: Grant

Filed: January 26, 2018

Date of Patent: September 15, 2020

Assignee: Apple Inc.

Inventor: Ozgur Oyman

10791261[36] Type: Grant

Filed: October 4, 2018

Date of Patent: September 29, 2020

Assignee: Apple Inc.

Inventor: Ozgur Oyman, Jean-Pierre Giacalone, Ivan Fox

10812546[37] Type: Grant

Filed: December 24, 2014

Date of Patent: October 20, 2020

Assignee: INTEL CORPORATION

Inventor: Vishwanath Ramamurthi, Ozgur Oyman, Mohamed Rehan, Ahmed Ragab

10873579[38] Type: Grant

Filed: November 9, 2017

Date of Patent: December 22, 2020

Assignee: APPLE INC.

Inventor: Ozgur Oyman

10904798[39] Type: Grant

Filed: November 3, 2017

Date of Patent: January 26, 2021

Assignee: Apple Inc.

Inventors: Hyung-Nam Choi, Ozgur Oyman, Jerome Parron, Marta Martinez Tarradell

10911506[40] Type: Grant

Filed: July 16, 2015

Date of Patent: February 2, 2021

Assignee: APPLE INC.

Inventors: Ozgur Oyman, Yiting Liao, Jeffrey R. Foerster

11026147[41] Type: Grant

Filed: February 13, 2019

Date of Patent: June 1, 2021

Assignee: Apple Inc.

Inventor: Ozgur Oyman

11038944[42] Type: Grant

Filed: May 9, 2019

Date of Patent: June 15, 2021

Assignee: APPLE INC.

Inventors: Mohamed M. Rehan, Rana A. Morsi, Ozgur Oyman, Vishwanath Ramamurthi

11102267[43] Type: Grant

Filed: April 14, 2017

Date of Patent: August 24, 2021

Assignee: Apple Inc.

Inventors: Yifan Yu, Ozgur Oyman, Yuan Zhu

9246842[44] Type: Grant

Filed: November 29, 2012

Date of Patent: January 26, 2016

Assignee: INTEL CORPORATION

Inventors: Ozgur Oyman, Debdeep Chatterjee, Apostolos Tolis Papathanassiou

10785699[45] Type: Grant

Filed: March 27, 2019

Date of Patent: September 22, 2020

Assignee: Apple Inc.

Inventors: Alexander Sirotkin, Candy Yiu, Qian Li, Sudeep K. Palat, Song Noh, Geng Wu, Lili Wei, Hassan Ghozlan, Dawei Ying, Ozgur Oyman, Thomas Luetzenkirchen, Shankar Sudhir Pola, Usharani Ayyalasomayajula

11134538[46] Type: Grant

Filed: May 8, 2019

Date of Patent: September 28, 2021

Assignee: Intel Corporation

Inventors: Ozgur Oyman, Thomas Luetzenkirchen, Jerome Parron, Fabrice Plante, Marta Martinez Tarradell, Sudhir Shankar Pola, Usharani Ayyalasomayajula, Ganesh Vijayan

11140581[47] Type: Grant

Filed: May 9, 2019

Date of Patent: October 5, 2021

Assignee: Intel Corporation

Inventors: Ozgur Oyman, Thomas Luetzenkirchen, Fabrice Plante, Usharani Ayyalasomayajula, Ganesh Vijayan, Jerome Parron

11197345[48] Type: Grant

Filed: August 28, 2018

Date of Patent: December 7, 2021

Assignee: Intel Corporation

Inventors: Ozgur Oyman, Thomas Luetzenkirchen, Jerome Parron, Fabrice Plante, Marta Martinez Tarradell, Sudhir Shankar Pola, Usharani Ayyalasomayajula, Ganesh Vijayan

11388700[49] Type: Grant

Filed: December 24, 2013

Date of Patent: July 12, 2022

Assignee: APPLE INC.

Inventor: Ozgur Oyman

11477698[50] Type: Grant

Filed: December 30, 2020

Date of Patent: October 18, 2022

Assignee: Apple Inc.

Inventors: Hyung-Nam Choi, Ozgur Oyman, Jerome Parron, Marta Martinez Tarradell

11477257[51] Type: Grant

Filed: September 17, 2020

Date of Patent: October 18, 2022

Assignee: Intel Corporation

Inventors: Vishwanath Ramamurthi, Ozgur Oyman, Mohamed M. Rehan, Ahmed N. Ragab

11528312[52] Type: Grant

Filed: June 25, 2020

Date of Patent: December 13, 2022

Assignee: Apple Inc.

Inventor: Ozgur Oyman

11539763[53] Type: Grant

Filed: February 8, 2020

Date of Patent: December 27, 2022

Assignee: Apple Inc.

Inventors: Ozgur Oyman, Jerome Parron, Thomas Luetzenkirchen, Sudhir Shankar Pola, Ralf Rossbach

11588871[54] Type: Grant

Filed: July 16, 2020

Date of Patent: February 21, 2023

Assignee: Apple Inc.

Inventor: Ozgur Oyman

11611909[55] Type: Grant

Filed: September 9, 2019

Date of Patent: March 21, 2023

Assignee: Apple Inc.

Inventors: Ozgur Oyman, Thomas Luetzenkirchen, Sudhir Shankar Pola, Usharani Ayyalasomayajula

11652862[56] Type: Grant

Filed: August 19, 2022

Date of Patent: May 16, 2023

Assignee: Apple Inc.

Inventor: Ozgur Oyman

11704867[57] Type: Grant

Filed: September 25, 2020

Date of Patent: July 18, 2023

Assignee: Intel Corporation

Inventor: Ozgur Oyman

11711405[58] Type: Grant

Filed: February 12, 2020

Date of Patent: July 25, 2023

Assignee: Apple Inc.

Inventor: Ozgur Oyman

10433327[59] Type: Grant

Filed: Oct 4, 2017

Date of Patent: Oct 1, 2019

Patent Publication Number: 20180035450

Assignee: INTEL IP CORPORATION (Santa Clara, CA)

Inventor: Ozgur Oyman (Palo Alto, CA)

Primary Examiner: Glenford J Madamba

Application Number: 15/725,205

10320552[60] Type: Grant

Filed: Jul 22, 2016

Date of Patent: Jun 11, 2019

Patent Publication Number: 20170019263

Assignee: INTEL CORPORATION (Santa Clara, CA)

Inventor: Ozgur Oyman (San Jose, CA)

Primary Examiner: Benjamin R Bruckart

Assistant Examiner: Tien M Nguyen

Application Number: 15/216,993

10244434[61] Type: Grant

Filed: Jun 5, 2017

Date of Patent: Mar 26, 2019

Patent Publication Number: 20170272983

Assignee: INTEL IP CORPORATION (Santa Clara, CA)

Inventors: Ozgur Oyman (Palo Alto, CA), Muthaiah Venkatachalam (Beaverton, OR), Eric Siow (Beaverton, OR)

Primary Examiner: John M Macilwinen

Application Number: 15/613,785

10225817[62] Type: Grant

Filed: Aug 21, 2017

Date of Patent: Mar 5, 2019

Patent Publication Number: 20170374647

Assignee: Intel IP Corporation (Santa Clara, CA)

Inventor: Ozgur Oyman (San Jose, CA)

Primary Examiner: Gerald Gauthier

Application Number: 15/682,168

9438883[63] Type: Grant

Filed: Sep 27, 2012

Date of Patent: Sep 6, 2016

Patent Publication Number: 20130268577

Assignee: Intel Corporation (Santa Clara, CA)

Inventor: Ozgur Oyman (San Jose, CA)

Primary Examiner: Saket K Daftuar

Application Number: 13/628,340

Articles Published

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Capacity scaling laws in MIMO relay networks[64]

Quality of experience for HTTP adaptive streaming services[65]

Characterizing the statistical properties of mutual information in MIMO channels[66]

Multihop relaying for broadband wireless mesh networks: From theory to practice[67]

Resource management and interference mitigation techniques for relay-based wireless networks[68]

Toward enhanced mobile video services over WiMAX and LTE [WiMAX/LTE update][69]

Design and analysis of linear distributed MIMO relaying algorithms[70]

Quality-aware adaptive streaming over hypertext transfer protocol using quality attributes in manifest file[71]

Capacity scaling laws in MIMO wireless networks[72]

Quality of experience enhancements over wireless networks[73]

Video capacity and QoE enhancements over LTE[74]

Architecture, protocols and frame formats for wireless multi-hop relay networks[75]

Multimedia adaptation based on video orientation[76]

Session description protocol mechanisms for signaling radio access network capabilities in multimedia telephony sessions[77]

Opportunistic scheduling and spectrum reuse in relay-based cellular networks[78]

Tight lower bounds on the ergodic capacity of Rayleigh fading MIMO channels[79]

QoE-aware radio access network architecture for http-based video streaming[80]

Methods for switching between a MBMS download and an HTTP-based delivery of DASH formatted content over an IMS network[81]

Finite-SNR diversity-multiplexing tradeoffs in fading relay channels[82]

Signaling techniques for a multimedia-aware radio and network adaptation[83]

Routing in wireless mesh networks[84]

Cooperative communications techniques[85]

Cross-layer optimized adaptive HTTP streaming[86]

Device orientation capability exchange signaling and server adaptation of multimedia content in response to device orientation[87]

Bandwidth allocation base station and method for allocating uplink bandwidth using SDMA[88]

Quality of experience reporting for combined unicast-multicast/broadcast streaming of media content[89]

System and method for adapting video communications[90]

Video adaptation for content-aware wireless streaming[91]

A Shannon-theoretic perspective on fading multihop networks[92]

Distortion-aware multiple input multiple output precoding[93]

Opportunistic scheduling and spectrum reuse in relay-based cellular OFDMA networks[94]

Non-ergodic power-bandwidth tradeoff in linear multi-hop networks[95]

Applications and deployments of server and network assisted DASH (SAND)[96]

Power-bandwidth tradeoff in dense multi-antenna relay networks[97]

OFDM2A: A centralized resource allocation policy for cellular multi-hop networks[98]

Content URL authentication for dash[99]

References

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  1. ^ "Lockheed Martin Seminar Series - Ozgur Oyman". labs.ece.uw.edu. Retrieved 2025-05-11.
  2. ^ "Apple Invents an Immersive Teleconferencing & Telepresence system allowing participants to attend a meeting using an HMD". Patently Apple. Retrieved 2025-05-11.
  3. ^ "SMPTE 2020 10 - 12 November". 2020.smpte.org. Retrieved 2025-05-11.
  4. ^ "SMPTE 2020 10 - 12 November". 2020.smpte.org. Retrieved 2025-05-11.
  5. ^ Yang, Yan; Dang, Shuping; Wen, Miaowen; Mumtaz, Shahid; Guizani, Mohsen (December 2020). "Bayesian Beamforming for Mobile Millimeter Wave Channel Tracking in the Presence of DOA Uncertainty". IEEE Transactions on Communications. 68 (12): 7547–7562. doi:10.1109/TCOMM.2020.3026377. ISSN 1558-0857.
  6. ^ "Ozgur Oyman: Electronics and Electrical Engineering H-index & Awards - Academic Profile". Research.com. Retrieved 2025-05-11.
  7. ^ "Patent Public Search Basic | USPTO". ppubs.uspto.gov. Retrieved 2025-05-11.
  8. ^ "Ozgur Oyman: Electronics and Electrical Engineering H-index & Awards - Academic Profile". Research.com. Retrieved 2025-05-11.
  9. ^ "Ozgur Oyman - Apple Inc - AD Scientific Index 2025 - 2025". www.adscientificindex.com. Retrieved 2025-05-11.
  10. ^ "Ozgur Oyman: Electronics and Electrical Engineering H-index & Awards - Academic Profile". Research.com. Retrieved 2025-05-11.
  11. ^ "Ozgur Oyman: Electronics and Electrical Engineering H-index & Awards - Academic Profile". Research.com. Retrieved 2025-05-11.
  12. ^ "Ozgur Oyman: Electronics and Electrical Engineering H-index & Awards - Academic Profile". Research.com. Retrieved 2025-05-11.
  13. ^ US12238158B2, Oyman, Ozgur; Shen, Gang & Fu, Wenqing et al., "Session description protocol (SDP) based signaling of camera calibration parameters", issued 2025-02-25 
  14. ^ US12155701B2, Oyman, Ozgur; Parron, Jerome & Luetzenkirchen, Thomas et al., "Apparatus and method for Session Initiated Protocol (SIP) registration procedure for access network bitrate recommendation (ANBR) capability signaling", issued 2024-11-26 
  15. ^ US12088959B2, Oyman, Ozgur; Shen, Gang & Fu, Wenqing et al., "Session description protocol (SDP) based signaling of camera calibration", issued 2024-09-10 
  16. ^ US12004247B2, Parron, Jerome; Zhang, Yujian & Oyman, Ozgur, "User equipment assistance information for voice over cellular", issued 2024-06-04 
  17. ^ US11991233B2, Oyman, Ozgur & Shen, Gang, "QoE metrics reporting for RTP-based 360-degree video delivery", issued 2024-05-21 
  18. ^ US11751101B2, Choi, Hyung-Nam; Oyman, Ozgur & Parron, Jerome et al., "UE and devices for CODEC rate adaptation", issued 2023-09-05 
  19. ^ US11765404B2, LIAO, Ching-Yu & Oyman, Ozgur, "Systems, methods, and devices for enabling live media production services", issued 2023-09-19 
  20. ^ US11770421B2, Oyman, Ozgur; Parron, Jerome & Luetzenkirchen, Thomas et al., "Apparatus and method for session initiated protocol (SIP) registration procedure for access network bitrate recommendation (ANBR) capability signaling", issued 2023-09-26 
  21. ^ US11831861B2, Oyman, Ozgur; Yeung, Fai & Gill, Harleen et al., "Methods for viewport-dependent adaptive streaming of point cloud content", issued 2023-11-28 
  22. ^ US11838345B2, Oyman, Ozgur; Shen, Gang & Fu, Wenqing et al., "Session description protocol (SDP) based signaling of camera calibration parameters", issued 2023-12-05 
  23. ^ US11936707B2, Oyman, Ozgur; Luetzenkirchen, Thomas & Ayyalasomayajula, Usharani et al., "Signaling codec mode notifications for multimedia telephony sessions", issued 2024-03-19 
  24. ^ US11729243B2, Oyman, Ozgur; Yeung, Fai & Gill, Harleen et al., "Dash-based streaming of point cloud content based on recommended viewports", issued 2023-08-15 
  25. ^ US10432692B2, Oyman, Ozgur, "Streaming with coordination of video orientation (CVO)", issued 2019-10-01 
  26. ^ US10455404B2, Rehan, Mohamed; Morsi, Rana & Oyman, Ozgur, "Quality of experience aware multimedia adaptive streaming", issued 2019-10-22 
  27. ^ US10476930B2, Rehan, Mohamed M.; Morsi, Rana A. & Oyman, Ozgur et al., "Client/server signaling commands for dash", issued 2019-11-12 
  28. ^ US10491861B2, Oyman, Ozgur, "Interactive video conferencing", issued 2019-11-26 
  29. ^ US10523982B2, Oyman, Ozgur, "Multimedia adaptation based on video orientation", issued 2019-12-31 
  30. ^ US10581929B2, Oyman, Ozgur, "IP multimedia subsystem and method for MBMS file repair using HTTP servers", issued 2020-03-03 
  31. ^ US10681107B2, Oyman, Ozgur, "Adaptive video content for cellular communication", issued 2020-06-09 
  32. ^ US10701119B2, Oyman, Ozgur, "Adaptive video streaming using dynamic radio access network information", issued 2020-06-30 
  33. ^ US10721715B2, Ramamurthi, Vishwanath & Oyman, Ozgur, "Link-aware streaming adaptation", issued 2020-07-21 
  34. ^ US10721715B2, Ramamurthi, Vishwanath & Oyman, Ozgur, "Link-aware streaming adaptation", issued 2020-07-21 
  35. ^ US10778458B2, Oyman, Ozgur, "Methods for switching between a MBMS download and an HTPP-based delivery of DASH formatted content over an IMS network", issued 2020-09-15 
  36. ^ US10791261B2, Oyman, Ozgur; Giacalone, Jean-Pierre & FOX, Ivan, "Interactive video conferencing", issued 2020-09-29 
  37. ^ US10812546B2, Ramamurthi, Vishwanath; Oyman, Ozgur & Rehan, Mohamed M. et al., "Link-aware streaming adaptation", issued 2020-10-20 
  38. ^ US10873579B2, Oyman, Ozgur, "Dash-aware network application function (D-NAF)", issued 2020-12-22 
  39. ^ US10904798B2, Choi, Hyung-Nam; Oyman, Ozgur & Parron, Jerome et al., "UE and devices for codec rate adaptation", issued 2021-01-26 
  40. ^ US10911506B2, Oyman, Ozgur; Liao, Yiting & Foerster, Jeffrey R., "Methods for quality-aware adaptive streaming over hypertext transfer protocol and reporting quality of experience", issued 2021-02-02 
  41. ^ US11026147B2, Oyman, Ozgur, "Dynamic adaptation of maximum packet loss rate (PLR) for single radio voice call continuity (SRVCC) handover optimization using session description protocol (SDP)", issued 2021-06-01 
  42. ^ US11038944B2, Rehan, Mohamed M.; Morsi, Rana A. & Oyman, Ozgur et al., "Client/server signaling commands for dash", issued 2021-06-15 
  43. ^ US11102267B2, Yu, Yifan; Oyman, Ozgur & Zhu, Yuan, "Server- and network-assisted dynamic adaptive streaming over hypertext transport protocol signaling", issued 2021-08-24 
  44. ^ US9246842B2, Oyman, Ozgur; CHATTERJEE, Debdeep & Papathanassiou, Apostolos Tolis, "QoE-aware radio access network architecture for http-based video streaming", issued 2016-01-26 
  45. ^ US10785699B2, Sirotkin, Alexander; Yiu, Candy & Li, Qian et al., "Next generation node-B (GNB) for integrated access and backhaul (IAB) relay in new radio (NR) networks", issued 2020-09-22 
  46. ^ US11134538B2, Oyman, Ozgur; Luetzenkirchen, Thomas & Parron, Jerome et al., "Apparatuses for end-to-end coordination of voice over cellular data network communications", issued 2021-09-28 
  47. ^ US11140581B2, Oyman, Ozgur; Luetzenkirchen, Thomas & Plante, Fabrice et al., "Session description protocol mechanisms for signaling radio access network capabilities in multimedia telephony sessions", issued 2021-10-05 
  48. ^ US11197345B2, Oyman, Ozgur; Luetzenkirchen, Thomas & Parron, Jerome et al., "Apparatuses for end-to-end coordination of voice over cellular data network communications", issued 2021-12-07 
  49. ^ US11388700B2, Oyman, Ozgur, "Internet protocol (IP) multimedia subsystem (IMS) based peer-to-peer (P2P) content distribution", issued 2022-07-12 
  50. ^ US11477698B2, Choi, Hyung-Nam; Oyman, Ozgur & Parron, Jerome et al., "UE and devices for CODEC rate adaptation", issued 2022-10-18 
  51. ^ US11477257B2, Ramamurthi, Vishwanath; Oyman, Ozgur & Rehan, Mohamed M. et al., "Link-aware streaming adaptation", issued 2022-10-18 
  52. ^ US11528312B2, Oyman, Ozgur, "Immersive teleconferencing and telepresence", issued 2022-12-13 
  53. ^ US11539763B2, Oyman, Ozgur; Parron, Jerome & Luetzenkirchen, Thomas et al., "Apparatus and method for session initiated protocol (SIP) registration procedure for access network bitrate recommendation (ANBR) capability signaling", issued 2022-12-27 
  54. ^ US11588871B2, Oyman, Ozgur, "Streaming of volumetric point cloud content based on session description protocols and real time protocols", issued 2023-02-21 
  55. ^ US11611909B2, Oyman, Ozgur; Luetzenkirchen, Thomas & POLA, Sudhir SHANKAR et al., "Apparatus and method for signaling ran-assisted codec adaptation capabilities in IMS multimedia telephony sessions", issued 2023-03-21 
  56. ^ US11652862B2, Oyman, Ozgur, "Immersive teleconferencing and telepresence", issued 2023-05-16 
  57. ^ US11704867B2, Oyman, Ozgur, "Methods for timed metadata priority rank signaling for point clouds", issued 2023-07-18 
  58. ^ US11711405B2, Oyman, Ozgur, "Core network support for delay budget information (DBI) signaling in IMS multimedia sessions", issued 2023-07-25 
  59. ^ US10433327B2, Oyman, Ozgur, "Presence service using IMS based DASH service", issued 2019-10-01 
  60. ^ US10320552B2, Oyman, Ozgur, "Multicast broadcast multimedia service-assisted content distribution", issued 2019-06-11 
  61. ^ US10244434B2, Oyman, Ozgur; Venkatachalam, Muthaiah & Siow, Eric, "Delivery of targeted media content", issued 2019-03-26 
  62. ^ US10225817B2, Oyman, Ozgur, "MTSI based UE configurable for video region-of-interest (ROI) signaling", issued 2019-03-05 
  63. ^ US9438883B2, Oyman, Ozgur, "Quality of experience reporting for combined unicast-multicast/broadcast streaming of media content", issued 2016-09-06 
  64. ^ Makar, A. B.; McMartin, K. E.; Palese, M.; Tephly, T. R. (June 1975). "Formate assay in body fluids: application in methanol poisoning". Biochemical Medicine. 13 (2): 117–126. doi:10.1016/0006-2944(75)90147-7. ISSN 0006-2944. PMID 1.
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  66. ^ Smith, R. J.; Bryant, R. G. (1975-10-27). "Metal substitutions incarbonic anhydrase: a halide ion probe study". Biochemical and Biophysical Research Communications. 66 (4): 1281–1286. doi:10.1016/0006-291x(75)90498-2. ISSN 0006-291X. PMID 3.
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  74. ^ Singh, Sarabjot; Oyman, Ozgur; Papathanassiou, Apostolos; Chatterjee, Debdeep; Andrews, Jeffrey G. (2012). "Video capacity and QoE enhancements over LTE". 2012 IEEE International Conference on Communications (ICC). IEEE: 7071–7076.
  75. ^ Sandhu, Sumeet; Oyman, Ozgur (2013-06-04), Architecture, protocols and frame formats for wireless multi-hop relay networks, Google Patents, retrieved 2025-05-11
  76. ^ Oyman, Ozgur (2017-09-12), Multimedia adaptation based on video orientation, Google Patents, retrieved 2025-05-11
  77. ^ Oyman, Ozgur; Luetzenkirchen, Thomas; Plante, Fabrice; Ayyalasomayajula, Usharani; Vijayan, Ganesh; Parron, Jerome (2019-07-11), Session description protocol mechanisms for signaling radio access network capabilities in multimedia telephony sessions, Google Patents, retrieved 2025-05-11
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  81. ^ Oyman, Ozgur (2018-02-06), Methods for switching between a MBMS download and an HTTP-based delivery of DASH formatted content over an IMS network, Google Patents, retrieved 2025-05-11
  82. ^ Stauffer, Erik; Oyman, Ozgur; Narasimhan, Ravi; Paulraj, Arogyaswami (2007). "Finite-SNR diversity-multiplexing tradeoffs in fading relay channels". IEEE Journal on Selected Areas in Communications. 25 (2): 245–257. doi:10.1109/JSAC.2007.070202.{{cite journal}}: CS1 maint: ignored DOI errors (link)
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  85. ^ Oyman, Ozgur; Sydir, Jaroslaw J. (2014-01-21), Cooperative communications techniques, Google Patents, retrieved 2025-05-11
  86. ^ Oyman, Ozgur; Foerster, Jeffrey R. (2019-10-01), Cross-layer optimized adaptive HTTP streaming, Google Patents, retrieved 2025-05-11
  87. ^ "‪Device orientation capability exchange signaling and server adaptation of multimedia content in response to device orientation‬". scholar.google.com. Retrieved 2025-05-11.
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  96. ^ Van Deventer, M.O.; Champel, M.-L.; Oyman, O.; Stockhammer, T.; Begen, A.C.; Thomas, E. (2016). "Applications and deployments of server and network assisted DASH (SAND)". IBC 2016 Conference. Amsterdam, Netherlands: Institution of Engineering and Technology: 22 (8 .). doi:10.1049/ibc.2016.0022. ISBN 978-1-78561-343-2.
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