Bidirectional recurrent neural networks: Difference between revisions

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Line 1: {{short description\|Type of artificial neural network}} ~~{{Orphan\|date=March 2016}}~~ '''Bidirectional [[recurrent neural networks]]''' ('''BRNN''') connect two hidden layers of opposite directions to the same output. With this form of [[Generative model\|generative deep learning]], the output layer can get information from past (backwards) and future (forward) states simultaneously. Invented in 1997 by Schuster and Paliwal,<ref name="Schuster">Schuster, Mike, and Kuldip K. Paliwal. "[https://www.researchgate.net/profile/Mike_Schuster/publication/3316656_Bidirectional_recurrent_neural_networks/links/56861d4008ae19758395f85c.pdf Bidirectional recurrent neural networks]." Signal Processing, IEEE Transactions on 45.11 (1997): 2673-2681.2. Awni Hannun, Carl Case, Jared Casper, Bryan Catanzaro, Greg Diamos, Erich Elsen, Ryan</ref> BRNNs were introduced to increase the amount of input information available to the network. For example, [[multilayer perceptron]] (MLPs) and [[time delay neural network]] (TDNNs) have limitations on the input data flexibility, as they require their input data to be fixed. Standard [[recurrent neural network]] (RNNs) also have restrictions as the future input information cannot be reached from the current state. On the contrary, BRNNs do not require their input data to be fixed. Moreover, their future input information is reachable from the current state. <ref>{{Cite ~~document~~arXiv \|title=Recent Advances in Recurrent Neural Networks\|~~arxiv~~eprint = 1801.01078\|last1 = Salehinejad\|first1 = Hojjat\|last2 = Sankar\|first2 = Sharan\|last3 = Barfett\|first3 = Joseph\|last4 = Colak\|first4 = Errol\|last5 = Valaee\|first5 = Shahrokh\|year = 2017\|~~bibcode~~ class=cs.NE ~~2018arXiv180101078S~~}}</ref> BRNN are especially useful when the context of the input is needed. For example, in [[handwriting recognition]], the performance can be enhanced by knowledge of the letters located before and after the current letter. ==Architecture== [[File:Structural diagrams of unidirectional and bidirectional recurrent neural networks.png\|thumbnail\|Structure of RNN and BRNN<ref name="Schuster" />\|alt=\|350x350px]] The principle of BRNN is to split the neurons of a regular RNN into two directions, one for positive time direction (forward states), and another for negative time direction (backward states). Those two ~~states’~~states' output are not connected to inputs of the opposite direction states. The general structure of RNN and BRNN can be depicted in the right diagram. By using two time directions, input information from the past and future of the current time frame can be used unlike standard RNN which requires the delays for including future information.<ref name="Schuster" /> ==Training== Line 23: Translation<ref>Sundermeyer, Martin, et al. "[https://www.aclweb.org/anthology/D14-1003 Translation modeling with bidirectional recurrent neural networks]." Proceedings of the Conference on Empirical Methods on Natural Language Processing, October. 2014.</ref> Handwritten Recognition<ref>Liwicki, Marcus, et al. "[https://mediatum.ub.tum.de/doc/1289961/file.pdf A novel approach to on-line handwriting recognition based on bidirectional long short-term memory networks]." Proc. 9th Int. Conf. on Document Analysis and Recognition. Vol. 1. 2007.</ref> Industrial [[Soft sensor]]<ref>Lui, Chun Fai, et al. "[https://ieeexplore.ieee.org/ielx7/19/9717300/09718226.pdf A Supervised Bidirectional Long Short-Term Memory Network for Data-Driven Dynamic Soft Sensor Modeling]." IEEE Transactions on Instrumentation and Measurement 71 (2022): 1-13.</ref> Protein Structure Prediction<ref>Baldi, Pierre, et al. "[https://academic.oup.com/bioinformatics/article-pdf/15/11/937/693153/150937.pdf Exploiting the past and the future in protein secondary structure prediction]." Bioinformatics 15.11 (1999): 937-946.</ref><ref>Pollastri, Gianluca, and Aoife Mclysaght. "[https://academic.oup.com/bioinformatics/article/21/8/1719/250163 Porter: a new, accurate server for protein secondary structure prediction]." Bioinformatics 21.8 (2005): 1719-1720.</ref> Part-of-speech tagging Dependency Parsing<ref>{{Cite journal\|last1=Kiperwasser\|first1=Eliyahu\|last2=Goldberg\|first2=Yoav\|date=2016\|title=Simple and Accurate Dependency Parsing Using Bidirectional LSTM Feature Representations\|url=https://www.aclweb.org/anthology/Q16-1023/\|journal=Transactions of the Association for Computational Linguistics\|language=en-us\|volume=4\|pages=313–327\|doi=10.1162/tacl_a_00101\|arxiv=1603.04351\|bibcode=2016arXiv160304351K\|s2cid=1642392}}</ref> Entity Extraction<ref>{{Cite ~~arxiv~~arXiv\|last1=Dernoncourt\|first1=Franck\|last2=Lee\|first2=Ji Young\|last3=Szolovits\|first3=Peter\|date=2017-05-15\|title=NeuroNER: an easy-to-use program for named-entity recognition based on neural networks\|eprint=1705.05487\|class=cs.CL}}</ref> ==References== Line 34 ⟶ 35: [https://github.com/hycis/bidirectional_RNN] Implementation of BRNN/LSTM in Python with Theano [[Category:~~Artificial~~Neural ~~neural~~network ~~networks~~architectures]]