Learning Time Series Associated Event Sequences With Recurrent Point Process Networks

Many events occur in real-world and social networks. Events are related to the past and there are patterns in the evolution of event sequences. Understanding the patterns can help us better predict the type and arriving time of the next event. In the literature, both feature-based approaches and generative approaches are utilized to model the event sequence. Feature-based approaches extract a variety of features, and train a regression or classification model to make a prediction. Yet, their performance is dependent on the experience-based feature exaction. Generative approaches usually assume the evolution of events follow a stochastic point process (e.g., Poisson process or its complexer variants). However, the true distribution of events is never known and the performance depends on the design of stochastic process in practice. To solve the above challenges, in this paper, we present a novel probabilistic generative model for event sequences. The model is termed Variational Event Point Process (VEPP). Our model introduces variational auto-encoder to event sequence modeling that can better use the latent information and capture the distribution over inter-arrival time and types of event sequences. Experiments on real-world datasets prove effectiveness of our proposed model.

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The Vanishing Gradient Problem During Learning Recurrent Neural Nets and Problem Solutions

International Journal of Uncertainty Fuzziness and Knowledge-Based Systems ◽

10.1142/s0218488598000094 ◽

1998 ◽

Vol 06 (02) ◽

pp. 107-116 ◽

Cited By ~ 546

Author(s):

Sepp Hochreiter

Keyword(s):

Time Series ◽

Time Series Prediction ◽

Time Lag ◽

Neural Nets ◽

Alternative Methods ◽

Reasonable Time ◽

Practical Applications ◽

Learning Time ◽

Long Time ◽

Gradient Based

Recurrent nets are in principle capable to store past inputs to produce the currently desired output. Because of this property recurrent nets are used in time series prediction and process control. Practical applications involve temporal dependencies spanning many time steps, e.g. between relevant inputs and desired outputs. In this case, however, gradient based learning methods take too much time. The extremely increased learning time arises because the error vanishes as it gets propagated back. In this article the de-caying error flow is theoretically analyzed. Then methods trying to overcome vanishing gradients are briefly discussed. Finally, experiments comparing conventional algorithms and alternative methods are presented. With advanced methods long time lag problems can be solved in reasonable time.

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Learning Time-Series Similarity with a Neural Network by Combining Similarity Measures

Artificial Neural Networks – ICANN 2006 - Lecture Notes in Computer Science ◽

10.1007/11840930_13 ◽

2006 ◽

pp. 123-132 ◽

Cited By ~ 2

Author(s):

Maria Sagrebin ◽

Nils Goerke

Keyword(s):

Neural Network ◽

Time Series ◽

Similarity Measures ◽

Learning Time

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IoT Data Acquisition Node For Deep Learning Time Series Prediction

10.1109/ibdap52511.2021.9552096 ◽

2021 ◽

Author(s):

Li Xinyun ◽

Liu Huidan ◽

Yin Hang ◽

Cao Zilan ◽

Chen Bangdi ◽

...

Keyword(s):

Time Series ◽

Deep Learning ◽

Data Acquisition ◽

Time Series Prediction ◽

Learning Time

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Selective interaction between two independent stationary recurrent point processes

Journal of Applied Probability ◽

10.1017/s0021900200035099 ◽

1970 ◽

Vol 7 (02) ◽

pp. 476-482 ◽

Cited By ~ 1

Author(s):

S. K. Srinivasan ◽

G. Rajamannar

Keyword(s):

Point Process ◽

Point Processes ◽

Short Note ◽

Secondary Process ◽

Statistical Features ◽

Inhibitory Process ◽

Primary Event ◽

Recurrent Point ◽

Selective Interaction ◽

Interval Distribution

In an earlier contribution to this Journal, Ten Hoopen and Reuver [5] have studied selective interaction of two independent recurrent processes in connection with the unitary discharges of neuronal spikes. They have assumed that the primary process called excitatory is a stationary renewal point process characterised by the interval distribution ϕ(t). The secondary process called the inhibitory process also consists of a series of events governed by a stationary renewal point process characterised by the interval distribution Ψ(t). Each secondary event annihilates the next primary event. If there are two or more secondary events without a primary event, only one subsequent primary event is deleted. Every undeleted event gives rise to a response. For this reason, undeleted events may be called registered events. Ten Hoopen and Reuver have studied the interval distribution between two successive registered events. As is well-known, the interval distribution does not fully characterise a point process in general and in this case it would be interesting to obtain other statistical features like the moments of the number of undeleted events in a given interval as well as correlations of these events. The object of this short note is to point out that the point process consisting of the undeleted events can be studied directly by the recent techniques of renewal point processes ([1], [3]).

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