一种自注意力序列模型的视频流长期预测方法

doi:10.19665/j.issn1001-2400.20240202

Abstract

Abstract:

Video traffic prediction is a key technology to achieve accurate transmission bandwidth allocation and improve the quality of the Internet service.However,the inherent high rate variability,long-term dependence and short-term dependence of video traffic make it difficult to make a quick,accurate and long-term prediction:because existing models for predicting sequence dependencies have a high complexity and prediction models fail quickly.Aiming at the problem of long-term prediction of video streams,a sequential self-attention model with frame structure feature embedding is proposed.The sequential self-attention model has a strong modeling ability for the nonlinear relationship of discrete data.Based on the difference of correlation between video frames,this paper applies the time series self-attention model to the long-term prediction of video traffic for the first time.The existing time series self-attention model cannot effectively represent the category features of video frames.By introducing an embedding layer based on the frame structure,the frame structure information is effectively embedded into the time series to improve the accuracy of the model.The results show that,compared with the existing long short-term memory network model and convolutional neural network model,the proposed sequential self-attention model based on frame structure feature embedding has a fast inference speed,and that the prediction accuracy is reduced by at least 32% in the mean absolute error.

Key words: forecasting, time series analysis, network management, video streaming

CLC Number:

TN915.03

GE Yunfeng, LI Hongyan, SHI Keyi. A self-attention sequential model for long-term prediction of video streams[J].Journal of Xidian University, 2024, 51(3): 88-102.

Figures/Tables 17

References 53

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	所有P帧B帧相关系数的均值	所有B帧间相关系数的均值
NBC新闻	0.572 0	0.728 3
沉默的羔羊	0.713 5	0.700 2
星球大战	0.613 2	0.746 1
东京奥林匹克运动会	0.606 0	0.606 1
蓝色星球	0.056 2	0.480 2
大象的梦	0.033 7	0.627 6

参数	参数值
编码器层数	2
解码器层数	2
Dropout	0.05
学习率	10^-4
优化器	Adam
模型映射维度	512
激活函数	Gelu

编码器层数	解码器层数	推理时间/s	均方误差
2	2	11.91	0.053 9
4	4	13.47	0.054 5
6	6	13.57	0.055 8
8	8	20.72	0.057 6

	时间复杂度O(·)	模型参数量/个	最长计算路径O(·)
自注意力序列	n×n×m+n×m×d	21 528 583	1
线性回归模型	n×m×d	77 896	1
卷积神经网络	(k+1)×n×m×d	84 040	n/k
长短记忆网络	n×m×(m+d)	4 284 488	n

视频流	TOL	SOL	NBC	SW	BP	ED
线性回归模型	8.27	6.25	5.21	9.07	9.16	26.66
长短期记忆网络	2.31	0.23	1.02	0.40	1.55	5.68
卷积神经网络	2.64	0.55	1.34	0.73	1.84	6.11
Auto former	3.32	0.12	0.07	0.05	1.26	0.06
Auto former-GOP	1.67	0.01	0.06	0.04	0.98	0.05

A self-attention sequential model for long-term prediction of video streams

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Figures/Tables 17

References 53

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视频流	TOL	SOL	NBC	SW	BP	ED
线性回归模型	1.63	1.30	1.89	2.08	2.23	3.48
长短期记忆网络	0.72	0.27	0.73	0.41	0.53	1.46
卷积神经网络	0.82	0.38	0.84	0.52	0.64	1.52
Auto former	0.82	0.19	0.13	0.12	0.29	0.10
Auto former-GOP	0.48	0.04	0.11	0.09	0.25	0.07

视频流	TOL	SOL	NBC	SW	BP	ED
线性回归模型	5.58	4.34	5.82	4.05	2.82	0.99
长短期记忆网络	1.85	1.21	1.96	1.00	1.00	0.76
卷积神经网络	2.79	2.57	3.95	4.05	1.02	0.74
Auto former	1.59	0.43	1.01	0.85	0.33	0.36
Auto former-GOP	0.82	0.19	0.88	0.84	0.32	0.21

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