TANGO: Toward a More Reliable Mobile Streaming through Cooperation between Cellular Network and Mobile Devices

Multimedia streaming is a major mobile application, accounting for more than half of total mobile traffic. Streaming applications usually have a static buffering strategy. For example, buffer size is limited to x minutes of the stream, where x is optimized to provide the best trade-off between minim...

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Bibliographic Details
Main Authors: Theera-Ampornpunt, Nawanol, Mangla, Tarun, Bagchi, Saurabh, Panta, Rajesh, Joshi, Kaustubh, Ammar, Mostafa, Zegura, Ellen
Format: Conference Proceeding
Language:English
Subjects:
Bandwidth
Cellular networks
Computer architecture
Global Positioning System
Microprocessors
Mobile handsets
Online Access:Request full text
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Summary:Multimedia streaming is a major mobile application, accounting for more than half of total mobile traffic. Streaming applications usually have a static buffering strategy. For example, buffer size is limited to x minutes of the stream, where x is optimized to provide the best trade-off between minimizing stalls and limiting waste of user's bandwidth and energy resulting from user abandonment. We show that such strategies based on information available on the mobile device alone do not work well when network conditions change dynamically, e.g., connectivity degrades due to congestion. We propose an alternative strategy using the framework called TANGO, based on a novel idea of cooperation between cellular network and mobile devices. By monitoring real-time network conditions and continuously predicting user location, our system is able to predict connectivity degradation in the near term. In such events, a notification is sent to the mobile device so that the streaming application can initiate a mitigation action, such as to pre-cache more content. In simulations based on real user traces, we found that TANGO reduces pause time by 13-72%, significantly outperforming DASH, which is the current state of the art.
ISSN:2575-8462
DOI:10.1109/SRDS.2016.047