Server-Driven Video Streaming for Deep Learning Inference

Du, Kuntai; Pervaiz, Ahsan; Yuan, Xin; Chowdhery, Aakanksha; Zhang, Qizheng; Hoffmann, Henry; Jiang, Junchen

doi:10.1145/3387514.3405887

Cited by 135 publications

(98 citation statements)

References 41 publications

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“…Thereafter, for each cluster, it trains a hidden Markov model (HMM) to estimate the corresponding bandwidth. A number of other data-driven machine learning solutions have also emerged: AMP [4], CFA [18], PREM [39], LiveNAS [22], Pytheas [20] and DDS [12].…”

Section: Buffer Controllermentioning

confidence: 99%

Catching the Moment With LoL$^+$ in Twitch-Like Low-Latency Live Streaming Platforms

Bentaleb

Akcay

Lim

et al. 2022

IEEE Trans. Multimedia

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Our earlier Low-on-Latency (dubbed as LoL) solution offered an accurate bandwidth prediction and rate adaptation algorithm tailored for live streaming applications that targeted an end-to-end latency of up to two seconds. While LoL was a significant step forward in multi-bitrate low-latency live streaming, further experimentation and testing showed that there was room for improvement in three areas. First, LoL used hardcoded parameters computed from an offline training process in the rate adaptation algorithm and this was seen as a significant barrier in LoL's wide deployment. Second, LoL's objective was to maximize a collective QoE function. Yet, certain use cases have specific objectives besides the singular QoE and this had to be accommodated. Third, the adaptive playback speed control failed to produce satisfying results in some scenarios. Our goal in this paper is to address these areas and make LoL sufficiently robust to deploy. We refer to the enhanced solution as LoL + , which has been integrated to the official dash.js player in v3.2.0.

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Section: Buffer Controllermentioning

confidence: 99%

Catching the Moment With LoL$^+$ in Twitch-Like Low-Latency Live Streaming Platforms

Bentaleb

Akcay

Lim

et al. 2022

IEEE Trans. Multimedia

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“…This calls for alternative video streaming systems that forecast users’ requests, exploit correlation among video consumption patterns of the users and possible association of users with an access point or base station. As forecasting is central in these systems, machine learning methods have been proposed for both 360-degree video [ 127 , 128 , 129 , 130 , 131 ] and regular video [ 132 , 133 , 134 ].…”

Section: Learning-based Transmissionmentioning

confidence: 99%

“…A CNN is used to extract image features and an RNN to capture temporal features. A sender-driven video streaming system is employed in [ 133 ] for improved inference. A deep neural network is used to extract the areas of interest from a low-quality video.…”

Section: Learning-based Transmissionmentioning

confidence: 99%

“…For such problems, the difficulty naturally comes when several processing tasks are considered, or even worse, when the processing task is unknown at the encoding stage. Some works have been proposed for image compression [ 208 , 209 ] or video streaming protocol redefinition [ 133 ]. In [ 210 , 211 ], features-based compression algorithms aim at maximizing quality perceived both by humans and machines.…”

Section: Towards An End-to-end Learning-based Transmission Systemmentioning

confidence: 99%

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Machine Learning for Multimedia Communications

Thomos

Maugey

Toni

2022

Sensors

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Machine learning is revolutionizing the way multimedia information is processed and transmitted to users. After intensive and powerful training, some impressive efficiency/accuracy improvements have been made all over the transmission pipeline. For example, the high model capacity of the learning-based architectures enables us to accurately model the image and video behavior such that tremendous compression gains can be achieved. Similarly, error concealment, streaming strategy or even user perception modeling have widely benefited from the recent learning-oriented developments. However, learning-based algorithms often imply drastic changes to the way data are represented or consumed, meaning that the overall pipeline can be affected even though a subpart of it is optimized. In this paper, we review the recent major advances that have been proposed all across the transmission chain, and we discuss their potential impact and the research challenges that they raise.

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“…Li et al [76], on-camera filtering is performed for efficient realtime video analytics. In [77], an IoT camera analyzes the traffic flow using a low-resolution image and the edge server also analyzes the image, identifies an important part of the image (if any) in terms of data analytics, and requests an important part in high resolution from the device. IoT devices in a smart building can transfer their sensor readings to the IoT gateway on the same floor for efficient HVAC (Heating, Ventilation, and Air Conditioning).…”

mentioning

confidence: 99%

A Review of Efficient Real-Time Decision Making in the Internet of Things

Kang

2022

Technologies

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Emerging applications of IoT (the Internet of Things), such as smart transportation, health, and energy, are envisioned to greatly enhance the societal infrastructure and quality of life of individuals. In such innovative IoT applications, cost-efficient real-time decision-making is critical to facilitate, for example, effective transportation management and healthcare. In this paper, we formally define real-time decision tasks in IoT, review cutting-edge approaches that aim to efficiently schedule real-time decision tasks to meet their timing and data freshness constraints, review state-of-the-art approaches for efficient sensor data analytics in IoT, and discuss future research directions.

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Server-Driven Video Streaming for Deep Learning Inference

Cited by 135 publications

References 41 publications

Catching the Moment With LoL$^+$ in Twitch-Like Low-Latency Live Streaming Platforms

Catching the Moment With LoL$^+$ in Twitch-Like Low-Latency Live Streaming Platforms

Machine Learning for Multimedia Communications

A Review of Efficient Real-Time Decision Making in the Internet of Things

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