3D holographic display and its data transmission requirement

Xu, Xuewu; Pan, Yuechao; Lwin, Phyu Phyu Mar Yi; Liang, Xinan

doi:10.1109/ipoc.2011.6122872

Cited by 45 publications

(31 citation statements)

References 14 publications

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“…Combined with there are several holographic technologies, both stereoscopic (with glasses) and auto-sterioscopic (glasses free) appearing on the market. The streaming 3D colour holographic video of a dancing bear at 60 fps over a network has been successfully demonstrated by the authors of [16] .…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Consideration of IEEE 802.11p and proposed 5G for holograms in vehicular communication.

Thomas¹,

Edwards²,

Wang³

2018

12th European Conference on Antennas and Propagation (EuCAP 2018)

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Vehicular communication is the technology that allows vehicles to exchange information with other cars and its surroundings to enhance safety and efficiency of transportation systems. Informative communication, which includes vehicle's position, velocity, and location, enables the sensing of hazards and traffic congestion. In this paper, two vehicular communication standards, Institute of Electrical and Electronics Engineers (IEEE) 802.11p and the proposed nextgeneration cellular network 5G are compared for vehicular networking. A detailed comparative study of the standards concerning latency, coverage, scalability, and mobility. The results indicate that IEEE 802.11p offers acceptable performance with limited mobility support. Whereas, 5G meets most of the vehicular application requirements regarding latency, coverage, scalability, and mobility. 3D holographic communication in 5G would allow users to experience live and interactive meetings. The bandwidth requirement of 3D holograms is predicted to be in terabyte level. With compression techniques, the delivery of real-time holograms has been researched to require 10Gbps or higher.

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Section: Discussionmentioning

confidence: 99%

“…Xuewu Xu [16] et al computed the total data bandwidth of a holographic video to be 9.44 Gbps at 60 object frames per second (1440 binary holograms per second). The hologram data packages transmitted using TCP/IP data stream via the network can be reliably played back as a holographic video at 60 fps with the display system developed.…”

Section: Related Workmentioning

confidence: 99%

Consideration of IEEE 802.11p and proposed 5G for holograms in vehicular communication.

Thomas¹,

Edwards²,

Wang³

2018

12th European Conference on Antennas and Propagation (EuCAP 2018)

View full text Add to dashboard Cite

show abstract

“…Holographic Telepresence (Teleportation): The human tendency to connect remotely with increasing fidelity will pose severe communication challenges in 6G networks. [4] details the datarate requirements of a 3D holographic display: a raw hologram, without any compression, with colors, full parallax, and 30 fps, would require 4.32 Tbps. The latency requirement will hit the sub-ms, and thousands of synchronized view angles will be necessary, as opposed to the few required for VR/AR.…”

Section: G Use Casesmentioning

confidence: 99%

Toward 6G Networks: Use Cases and Technologies

et al. 2020

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Reliable data connectivity is vital for the ever increasingly intelligent, automated and ubiquitous digital world. Mobile networks are the data highways and, in a fully connected, intelligent digital world, will need to connect everything, from people to vehicles, sensors, data, cloud resources and even robotic agents. Fifth generation (5G) wireless networks (that are being currently deployed) offer significant advances beyond LTE, but may be unable to meet the full connectivity demands of the future digital society. Therefore, this article discusses technologies that will evolve wireless networks towards a sixth generation (6G), and that we consider as enablers for several potential 6G use cases. We provide a full-stack, system-level perspective on 6G scenarios and requirements, and select 6G technologies that can satisfy them either by improving the 5G design, or by introducing completely new communication paradigms.

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“…Holoportation 100 Gbps to 1 Tbps (raw) [7] 30 to 50 Mbps (compressed) [8] Virtual/Augmented Reality (4K x 4K, 60 fps) → 20+ Mbps [9] (8K x 8K, 120 fps) → 85+ Mbps [10] (16K x 16K, 240 fps) → 300+ Mbps [9] • Processing power: as mentioned earlier, future applications generate and consume tremendous amounts of data that, depending on the application requirements, need to be processed at run-time before or after their transmission or even on their way to the destination. Naturally, the type of processing will mainly depend on the application type (e.g., object recognition, movement detection, data compression, data mining, video manipulation, video rendering, encryption).…”

Section: Application Bandwidthmentioning

confidence: 99%

FlexNGIA: A Flexible Internet Architecture for the Next-Generation Tactile Internet

Zhani

Elbakoury

2020

J Netw Syst Manage

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From virtual reality and telepresence, to augmented reality, holoportation, and remotely controlled robotics, these future network applications promise an unprecedented development for society, economics and culture by revolutionizing the way we live, learn, work and play. In order to deploy such futuristic applications and to cater to their performance requirements, recent trends stressed the need for the "Tactile Internet", an Internet that, according to the International Telecommunication Union (ITU), combines ultra low latency with extremely high availability, reliability and security [1]. Unfortunately, todays Internet falls short when it comes to providing such stringent requirements due to several fundamental limitations in the design of the current network architecture and communication protocols. This brings the need to rethink the network architecture and protocols, and efficiently harness recent technological advances in terms of virtualization and network softwarization to design the Tactile Internet of the future.In this paper, we start by analyzing the characteristics and requirements of future networking applications. We then highlight the limitations of the traditional network architecture and protocols and their inability to cater to these requirements. Afterward, we put forward a novel network architecture adapted to the Tactile Internet called FlexNGIA, a Flexible Next-Generation Internet Architecture 1 . We then describe some use-cases where we discuss the potential mechanisms and control loops that could be offered by FlexNGIA in order to ensure the required performance and reliability guarantees for future applications. Finally, we identify the key research challenges to further develop FlexNGIA towards a full-fledged architecture for the future Tactile Internet.

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3D holographic display and its data transmission requirement

Cited by 45 publications

References 14 publications

Consideration of IEEE 802.11p and proposed 5G for holograms in vehicular communication.

Consideration of IEEE 802.11p and proposed 5G for holograms in vehicular communication.

Toward 6G Networks: Use Cases and Technologies

FlexNGIA: A Flexible Internet Architecture for the Next-Generation Tactile Internet

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