Your search keyword '"Huang, Chenn-Jung"' showing total 6 results

1. Supporting Differentiated Streaming Services in Heterogeneous Vehicle-to-Everything Networks.

Author

Huang, Chenn-Jung, Hu, Kai-Wen, Cheng, Hao-Wen, Jian, Mei-En, and Tsamarah, Muhammad Inas Farras

Subjects

*BANDWIDTH allocation, *ELECTRIC vehicles, *USER experience, *BANDWIDTHS, *ALGORITHMS

Abstract

Advancements in assisted driving technologies are expected to enable future passengers to use a wide range of multimedia applications in electric vehicles (EVs). To address the bandwidth demands for high-resolution and immersive videos during peak traffic, this study introduces a bandwidth-management algorithm to support differentiated streaming services in heterogeneous vehicle-to-everything (V2X) networks. By leveraging cellular 6G base stations, along with Cell-Free (CF) Massive Multi-Input Multi-Output (mMIMO) Wi-Fi 7 access points, the algorithm aims to provide a high-coverage, high-speed, and low-interference V2X network environment. Additionally, Li-Fi technology is employed to supply extra bandwidth to vehicles with limited connectivity via V2V communication. Importantly, the study addresses the urgency and prioritization of different applications to ensure the smooth execution of emergency applications and introduces a pre-downloading mechanism specifically for non-real-time applications. Through simulations, the algorithm's effectiveness in meeting EV users' bandwidth needs for various multimedia streaming applications is demonstrated. During peak-bandwidth-demand periods, users experienced an average increase in bandwidth of 47%. Furthermore, bandwidth utilization across the V2X landscape is significantly improved. [ABSTRACT FROM AUTHOR]

Published

2024

2. Supporting Immersive Video Streaming via V2X Communication.

Author

Huang, Chenn-Jung, Hu, Kai-Wen, Jian, Mei-En, Lien, Yi-Hung, and Cheng, Hao-Wen

Subjects

SINGLE-degree-of-freedom systems, TRAFFIC congestion, STREAMING video & television, WIRELESS communications, TELECOMMUNICATION, BANDWIDTH allocation, TERAHERTZ technology

Abstract

With the rapid advancement of autonomous driving and network technologies, future vehicles will function as network nodes, facilitating information transmission. Concurrently, in-vehicle entertainment systems will undergo substantial enhancements. Beyond traditional broadcasting and video playback, future systems will integrate immersive applications featuring 360-degree views and six degrees of freedom (6DoF) capabilities. As autonomous driving technology matures, vehicle passengers will be able to engage in a broader range of entertainment activities while on the move. However, this evolution in video applications will significantly increase bandwidth demand for vehicular networks, potentially leading to bandwidth shortages in congested traffic areas. This paper presents a method for bandwidth allocation for vehicle video applications within the landscape of vehicle-to-everything (V2X) networks. By utilizing a millimeter-wave (mmWave), terahertz (THz) frequency band, and cell-free (CF) extremely large-scale multiple-input multiple-output (XL-MIMO) wireless communication technologies, we provide vehicle passengers with the necessary bandwidth resources. Additionally, we address bandwidth contention issues in congested road segments by incorporating communication methods tailored to the characteristics of vehicular environments. By classifying users and adjusting according to the unique requirements of various multimedia applications, we ensure that real-time applications receive adequate bandwidth. Simulation experiments validate the proposed method's effectiveness in managing bandwidth allocation for in-vehicle video applications within V2X networks. It increases the available bandwidth during peak hours by 32%, demonstrating its ability to reduce network congestion and ensure smooth playback of various video application types. [ABSTRACT FROM AUTHOR]

Published

2024

3. Application of Bidirectional Long Short-Term Memory to Adaptive Streaming for Internet of Autonomous Vehicles.

Author

Huang, Chenn-Jung, Hu, Kai-Wen, and Cheng, Hao-Wen

Subjects

*BANDWIDTH allocation, *INTERNET, *TELECOMMUNICATION, *VIDEO excerpts, *WIRELESS communications, *AUTONOMOUS vehicles, *BANDWIDTHS

Abstract

It is expected that interconnected networks of autonomous vehicles, especially during peak traffic, will face congestion challenges. Moreover, the existing literature lacks discussions on integrating next-generation wireless communication technologies into connected vehicular networks. Hence, this paper introduces a tailored bandwidth management algorithm for streaming applications of autonomous vehicle passengers. It leverages cutting-edge 6G wireless technology to create a network with high-speed transmission and broad coverage, ensuring smooth streaming application performance. The key features of bandwidth allocation for diverse streaming applications in this work include bandwidth relay and pre-loading of video clips assisted by vehicle-to-vehicle communication. Through simulations, this research effectively showcases the algorithm's ability to fulfill the bandwidth needs of diverse streaming applications for autonomous vehicle passengers. Specifically, during periods of peak user bandwidth demand, it notably increases the bandwidth accessible for streaming applications. On average, users experience a substantial 55% improvement in the bandwidth they can access. This validation affirms the viability and promise of the proposed approach in efficiently managing the intricate complexities of bandwidth allocation issues for streaming services within the connected autonomous vehicular networks. [ABSTRACT FROM AUTHOR]

Published

2023

4. An Adaptive Bandwidth Management Algorithm for Next-Generation Vehicular Networks.

Author

Huang, Chenn-Jung, Hu, Kai-Wen, and Cheng, Hao-Wen

Subjects

*TERAHERTZ technology, *BANDWIDTH allocation, *IN-vehicle entertainment equipment, *OPTICAL communications, *BANDWIDTHS, *ALGORITHMS, *VEHICULAR ad hoc networks, *NEXT generation networks

Abstract

The popularity of video services such as video call or video on-demand has made it impossible for people to live without them in their daily lives. It can be anticipated that the explosive growth of vehicular communication owing to the widespread use of in-vehicle video infotainment applications in the future will result in increasing fragmentation and congestion of the wireless transmission spectrum. Accordingly, effective bandwidth management algorithms are demanded to achieve efficient communication and stable scalability in next-generation vehicular networks. To the best of our current knowledge, a noticeable gap remains in the existing literature regarding the application of the latest advancements in network communication technologies. Specifically, this gap is evident in the lack of exploration regarding how cutting-edge technologies can be effectively employed to optimize bandwidth allocation, especially in the realm of video service applications within the forthcoming vehicular networks. In light of this void, this paper presents a seamless integration of cutting-edge 6G communication technologies, such as terahertz (THz) and visible light communication (VLC), with the existing 5G millimeter-wave and sub-6 GHz base stations. This integration facilitates the creation of a network environment characterized by high transmission rates and extensive coverage. Our primary aim is to ensure the uninterrupted playback of real-time video applications for vehicle users. These video applications encompass video conferencing, live video, and on-demand video services. The outcomes of our simulations convincingly indicate that the proposed strategy adeptly addresses the challenge of bandwidth competition among vehicle users. Moreover, it notably boosts the efficient utilization of bandwidth from less crowded base stations, optimizes the fulfillment of bandwidth prerequisites for various video applications, and elevates the overall video quality experienced by users. Consequently, our findings serve as a successful validation of the practicality and effectiveness of the proposed methodology. [ABSTRACT FROM AUTHOR]

Published

2023

5. A self-adaptive joint bandwidth allocation scheme for heterogeneous wireless networks.

Author

Huang, Chenn-Jung, Guan, Chih-Tai, Chen, Heng-Ming, Wang, Yu-Wu, Chien, Sheng-Yuan, Jian, Jui-Jiun, and Liao, Jia-Jian

Subjects

WIRELESS sensor networks, PREDICTION models, ALGORITHMS, GENETIC algorithms, BANDWIDTHS, COMPUTER simulation

Abstract

Recently, people have been able to connect with different types of networks anytime, anywhere using advanced network technologies. In order to properly distribute wireless network resources among different clients, this work proposed a user mobility prediction algorithm, which takes the coverage of different kinds of base stations, and the volatile mobility of pedestrians, vehicles, and mass transportation, into consideration. In addition, a novel bandwidth utilization optimization technique is proposed in the algorithm to allocate bandwidth more efficiently. The Hybrid Genetic Algorithm, which combines the Genetic Algorithm and local searches to improve the frequency of finding a Pareto set, is used to realize the optimization problem as well. Compared with our previous work and the other four methods in the literature, the simulation results show that our proposed work can achieve desirable performance by network utilization, throughput, and QoS quality in the heterogeneous wireless networks. [ABSTRACT FROM AUTHOR]

Published

2015

6. An Adaptive Live Streaming Mechanism for Heterogeneous Vehicular Networks.

Author

Huang, Chenn-Jung, Chang, Shun-Chih, Guan, Chi-Tai, Wang, Yu-Wu, Chen, Heng-Ming, Weng, Chuan-Hsiang, and Chien, Sheng-Yuan

Subjects

*VEHICULAR ad hoc networks, *STREAMING technology, *BANDWIDTH allocation, *ROAMING (Telecommunication), *QUALITY of service, *COMPUTER simulation

Abstract

With the popularity of vehicular networks, how to maintain high quality of the seamless live streaming service is a great challenge. In this work, an adaptive seamless live streaming dissemination system for heterogeneous vehicular networks to tackle this challenging issue is presented. First, differential service is presented in this work to ensure that paid users can satisfy the live steaming service. Based on users’ service-level agreement, an adaptive bandwidth allocation policy is proposed in this work to attain seamless handoff. In addition, because vehicles enter into the areas of hotspots, we also present a mechanism not only to prevent the insufficient bandwidth in advance, but also to make sure the paid users have higher priority than free users to obtain the seamless streaming service. When an unavoidable congestion occurs, we compress the streaming videos with a Region of Interest approach based on the content and characters of the video in order to maintain the service quality of paid users and reduce the required bandwidth for the streaming services. A series of simulation results show that our mechanism achieves better performance in terms of bandwidth utilization, packet loss ratio, and blocking probability. The capability of self-adaption in volatile real-time vehicular environment assists in the effectiveness and practicability of our proposed approach. [ABSTRACT FROM PUBLISHER]

Published

2015