ZTE Communications ›› 2019, Vol. 17 ›› Issue (1): 25-30.DOI: 10.12142/ZTECOM.201901005
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CHEN Jinling, XU Yiwen, LIU Yisang, HUANG Huiwen, ZHUANG Zhongwen
Received:
2018-08-13
Online:
2019-02-20
Published:
2019-11-14
About author:
CHEN Jinling received her bachelor of engineering from Fujian Agriculture and Forestry University, China in 2016. She is a master student at the College of Physics and Information Engineering, Fuzhou University, China. Her research interests include image/video processing and visual quality assessment.|XU Yiwen (xu yiwen@fzu.edu.cn) received his Ph.D. degree from Department of Electronic Engineering, Xiamen University, China in 2012. He has been an associate professor with the College of Physics and Information Engineering, Fuzhou University, China, since 2013. His research interests lie in multimedia information processing, video codec and transmission, and video quality assessment.|LIU Yisang received her bachelor of engineering from Fuzhou University, China in 2016. She is a master student at the College of Physics and Information Engineering, Fuzhou University. Her research interests lie in multimedia streaming, 3D video quality assessment, and 3D video streaming.|HUANG Huiwen received her bachelor of engineering from Fuzhou University, China in 2016. She is a master student at the College of Physics and Information Engineering, Fuzhou University. Her research interests lie in image/video processing and 360 degree video streaming.|ZHUANG Zhongwen received his bachelor of engineering from Fuzhou University, China in 2016. He is a master student at the College of Physics and Information Engineering, Fuzhou University. His research interest is video coding.
Supported by:
CHEN Jinling, XU Yiwen, LIU Yisang, HUANG Huiwen, ZHUANG Zhongwen. Quality of Experience Effects in Video Delivery[J]. ZTE Communications, 2019, 17(1): 25-30.
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URL: https://zte.magtechjournal.com/EN/10.12142/ZTECOM.201901005
Taxonomy | QoE influence factors | |
---|---|---|
Host | Content factors | Temporal/spatial requirements, color depth, texture, 2D/3D, content reliability, artifacts, etc. |
Media factors | Encoding, resolution, sampling rate, frame rate, media synchronization, etc. | |
Channel | Network factors | Delay, jitter, loss, error rate, bandwidth, throughput, path selection, resource requirements, scheduling, zapping time, hand-off, etc. |
Other factors | Pricing, etc. | |
Terminal | Device factors | Decoding, error concealment, zooming, rendering, display size, screen resolution, color depth, user interface, CPU and memory, battery, etc. |
Other factors | Luminance, viewing distance, movement, interactivity, personalization, security, mobility, etc. | |
User | Physiological factors | Gender, age, heart rate, electrodermal activity, etc. |
Psychological factors | Attention, interest, personality, mood, pre-conceptions, user expectation/goal, etc. |
Table 1. QoE influence factors at different taxonomies of a video transmission system
Taxonomy | QoE influence factors | |
---|---|---|
Host | Content factors | Temporal/spatial requirements, color depth, texture, 2D/3D, content reliability, artifacts, etc. |
Media factors | Encoding, resolution, sampling rate, frame rate, media synchronization, etc. | |
Channel | Network factors | Delay, jitter, loss, error rate, bandwidth, throughput, path selection, resource requirements, scheduling, zapping time, hand-off, etc. |
Other factors | Pricing, etc. | |
Terminal | Device factors | Decoding, error concealment, zooming, rendering, display size, screen resolution, color depth, user interface, CPU and memory, battery, etc. |
Other factors | Luminance, viewing distance, movement, interactivity, personalization, security, mobility, etc. | |
User | Physiological factors | Gender, age, heart rate, electrodermal activity, etc. |
Psychological factors | Attention, interest, personality, mood, pre-conceptions, user expectation/goal, etc. |
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