Long short-term memory

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Long short-term memory (LSTM)[1] is a type of recurrent neural network (RNN) aimed at mitigating the vanishing gradient problem[2] commonly encountered by traditional RNNs. Its relative insensitivity to gap length is its advantage over other RNNs, hidden Markov models, and other sequence learning methods. It aims to provide a short-term memory for RNN that can last thousands of timesteps (thus "long short-term memory").[1] The name is made in analogy with long-term memory and short-term memory and their relationship, studied by cognitive psychologists since the early 20th century.

The Long Short-Term Memory (LSTM) cell can process data sequentially and keep its hidden state through time.

An LSTM unit is typically composed of a cell and three gates: an input gate, an output gate,[3] and a forget gate.[4] The cell remembers values over arbitrary time intervals, and the gates regulate the flow of information into and out of the cell. Forget gates decide what information to discard from the previous state, by mapping the previous state and the current input to a value between 0 and 1. A (rounded) value of 1 signifies retention of the information, and a value of 0 represents discarding. Input gates decide which pieces of new information to store in the current cell state, using the same system as forget gates. Output gates control which pieces of information in the current cell state to output, by assigning a value from 0 to 1 to the information, considering the previous and current states. Selectively outputting relevant information from the current state allows the LSTM network to maintain useful, long-term dependencies to make predictions, both in current and future time-steps.

LSTM has wide applications in classification,[5][6] data processing, time series analysis tasks,[7] speech recognition,[8][9] machine translation,[10][11] speech activity detection,[12] robot control,[13][14] video games,[15][16] and healthcare.[17]

Motivation

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In theory, classic RNNs can keep track of arbitrary long-term dependencies in the input sequences. The problem with classic RNNs is computational (or practical) in nature: when training a classic RNN using back-propagation, the long-term gradients which are back-propagated can "vanish", meaning they can tend to zero due to very small numbers creeping into the computations, causing the model to effectively stop learning. RNNs using LSTM units partially solve the vanishing gradient problem, because LSTM units allow gradients to also flow with little to no attenuation. However, LSTM networks can still suffer from the exploding gradient problem.[18]

The intuition behind the LSTM architecture is to create an additional module in a neural network that learns when to remember and when to forget pertinent information.[4] In other words, the network effectively learns which information might be needed later on in a sequence and when that information is no longer needed. For instance, in the context of natural language processing, the network can learn grammatical dependencies.[19] An LSTM might process the sentence "Dave, as a result of his controversial claims, is now a pariah" by remembering the (statistically likely) grammatical gender and number of the subject Dave, note that this information is pertinent for the pronoun his and note that this information is no longer important after the verb is.

Variants

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In the equations below, the lowercase variables represent vectors. Matrices   and   contain, respectively, the weights of the input and recurrent connections, where the subscript   can either be the input gate  , output gate  , the forget gate   or the memory cell  , depending on the activation being calculated. In this section, we are thus using a "vector notation". So, for example,   is not just one unit of one LSTM cell, but contains   LSTM cell's units.

See [20] for an empirical study of 8 architectural variants of LSTM.

LSTM with a forget gate

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The compact forms of the equations for the forward pass of an LSTM cell with a forget gate are:[1][4]

 

where the initial values are   and   and the operator   denotes the Hadamard product (element-wise product). The subscript   indexes the time step.

Variables

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Letting the superscripts   and   refer to the number of input features and number of hidden units, respectively:

  •  : input vector to the LSTM unit
  •  : forget gate's activation vector
  •  : input/update gate's activation vector
  •  : output gate's activation vector
  •  : hidden state vector also known as output vector of the LSTM unit
  •  : cell input activation vector
  •  : cell state vector
  •  ,   and  : weight matrices and bias vector parameters which need to be learned during training
  •  : sigmoid function.
  •  : hyperbolic tangent function.
  •  : hyperbolic tangent function or, as the peephole LSTM paper[21][22] suggests,  .

Peephole LSTM

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A peephole LSTM unit with input (i.e.  ), output (i.e.  ), and forget (i.e.  ) gates

The figure on the right is a graphical representation of an LSTM unit with peephole connections (i.e. a peephole LSTM).[21][22] Peephole connections allow the gates to access the constant error carousel (CEC), whose activation is the cell state.[21]   is not used,   is used instead in most places.

 

Each of the gates can be thought as a "standard" neuron in a feed-forward (or multi-layer) neural network: that is, they compute an activation (using an activation function) of a weighted sum.   and   represent the activations of respectively the input, output and forget gates, at time step  .

The 3 exit arrows from the memory cell   to the 3 gates   and   represent the peephole connections. These peephole connections actually denote the contributions of the activation of the memory cell   at time step  , i.e. the contribution of   (and not  , as the picture may suggest). In other words, the gates   and   calculate their activations at time step   (i.e., respectively,   and  ) also considering the activation of the memory cell   at time step  , i.e.  .

The single left-to-right arrow exiting the memory cell is not a peephole connection and denotes  .

The little circles containing a   symbol represent an element-wise multiplication between its inputs. The big circles containing an S-like curve represent the application of a differentiable function (like the sigmoid function) to a weighted sum.

Peephole convolutional LSTM

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Peephole convolutional LSTM.[23] The   denotes the convolution operator.

 

Training

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An RNN using LSTM units can be trained in a supervised fashion on a set of training sequences, using an optimization algorithm like gradient descent combined with backpropagation through time to compute the gradients needed during the optimization process, in order to change each weight of the LSTM network in proportion to the derivative of the error (at the output layer of the LSTM network) with respect to corresponding weight.

A problem with using gradient descent for standard RNNs is that error gradients vanish exponentially quickly with the size of the time lag between important events. This is due to   if the spectral radius of   is smaller than 1.[2][24]

However, with LSTM units, when error values are back-propagated from the output layer, the error remains in the LSTM unit's cell. This "error carousel" continuously feeds error back to each of the LSTM unit's gates, until they learn to cut off the value.

CTC score function

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Many applications use stacks of LSTM RNNs[25] and train them by connectionist temporal classification (CTC)[5] to find an RNN weight matrix that maximizes the probability of the label sequences in a training set, given the corresponding input sequences. CTC achieves both alignment and recognition.

Alternatives

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Sometimes, it can be advantageous to train (parts of) an LSTM by neuroevolution[7] or by policy gradient methods, especially when there is no "teacher" (that is, training labels).

Applications

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Applications of LSTM include:

2015: Google started using an LSTM trained by CTC for speech recognition on Google Voice.[50][51] According to the official blog post, the new model cut transcription errors by 49%.[52]

2016: Google started using an LSTM to suggest messages in the Allo conversation app.[53] In the same year, Google released the Google Neural Machine Translation system for Google Translate which used LSTMs to reduce translation errors by 60%.[10][54][55]

Apple announced in its Worldwide Developers Conference that it would start using the LSTM for quicktype[56][57][58] in the iPhone and for Siri.[59][60]

Amazon released Polly, which generates the voices behind Alexa, using a bidirectional LSTM for the text-to-speech technology.[61]

2017: Facebook performed some 4.5 billion automatic translations every day using long short-term memory networks.[11]

Microsoft reported reaching 94.9% recognition accuracy on the Switchboard corpus, incorporating a vocabulary of 165,000 words. The approach used "dialog session-based long-short-term memory".[62]

2018: OpenAI used LSTM trained by policy gradients to beat humans in the complex video game of Dota 2,[15] and to control a human-like robot hand that manipulates physical objects with unprecedented dexterity.[14][63]

2019: DeepMind used LSTM trained by policy gradients to excel at the complex video game of Starcraft II.[16][63]

History

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Development

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Aspects of LSTM were anticipated by "focused back-propagation" (Mozer, 1989),[64] cited by the LSTM paper.[1]

Sepp Hochreiter's 1991 German diploma thesis analyzed the vanishing gradient problem and developed principles of the method.[2] His supervisor, Jürgen Schmidhuber, considered the thesis highly significant.[65]

An early version of LSTM was published in 1995 in a technical report by Sepp Hochreiter and Jürgen Schmidhuber,[66] then published in the NIPS 1996 conference.[3]

The most commonly used reference point for LSTM was published in 1997 in the journal Neural Computation.[1] By introducing Constant Error Carousel (CEC) units, LSTM deals with the vanishing gradient problem. The initial version of LSTM block included cells, input and output gates.[20]

(Felix Gers, Jürgen Schmidhuber, and Fred Cummins, 1999)[67] introduced the forget gate (also called "keep gate") into the LSTM architecture in 1999, enabling the LSTM to reset its own state.[20] This is the most commonly used version of LSTM nowadays.

(Gers, Schmidhuber, and Cummins, 2000) added peephole connections.[21][22] Additionally, the output activation function was omitted.[20]

Development of variants

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(Graves, Fernandez, Gomez, and Schmidhuber, 2006)[5] introduce a new error function for LSTM: Connectionist Temporal Classification (CTC) for simultaneous alignment and recognition of sequences.

(Graves, Schmidhuber, 2005)[26] published LSTM with full backpropagation through time and bidirectional LSTM.

(Kyunghyun Cho et al., 2014)[68] published a simplified variant of the forget gate LSTM[67] called Gated recurrent unit (GRU).

(Rupesh Kumar Srivastava, Klaus Greff, and Schmidhuber, 2015) used LSTM principles[67] to create the Highway network, a feedforward neural network with hundreds of layers, much deeper than previous networks.[69][70][71] Concurrently, the ResNet architecture was developed. It is equivalent to an open-gated or gateless highway network.[72]

A modern upgrade of LSTM called xLSTM is published by a team leaded by Sepp Hochreiter (Maximilian et al, 2024).[73][74] One of the 2 blocks (mLSTM) of the architecture are parallelizable like the Transformer architecture, the other ones (sLSTM) allow state tracking.

Applications

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2004: First successful application of LSTM to speech Alex Graves et al.[75][63]

2001: Gers and Schmidhuber trained LSTM to learn languages unlearnable by traditional models such as Hidden Markov Models.[21][63]

Hochreiter et al. used LSTM for meta-learning (i.e. learning a learning algorithm).[76]

2005: Daan Wierstra, Faustino Gomez, and Schmidhuber trained LSTM by neuroevolution without a teacher.[7]

Mayer et al. trained LSTM to control robots.[13]

2007: Wierstra, Foerster, Peters, and Schmidhuber trained LSTM by policy gradients for reinforcement learning without a teacher.[77]

Hochreiter, Heuesel, and Obermayr applied LSTM to protein homology detection the field of biology.[37]

2009: Justin Bayer et al. introduced neural architecture search for LSTM.[78][63]

2009: An LSTM trained by CTC won the ICDAR connected handwriting recognition competition. Three such models were submitted by a team led by Alex Graves.[79] One was the most accurate model in the competition and another was the fastest.[80] This was the first time an RNN won international competitions.[63]

2013: Alex Graves, Abdel-rahman Mohamed, and Geoffrey Hinton used LSTM networks as a major component of a network that achieved a record 17.7% phoneme error rate on the classic TIMIT natural speech dataset.[28]

Researchers from Michigan State University, IBM Research, and Cornell University published a study in the Knowledge Discovery and Data Mining (KDD) conference.[81][82][83] Their Time-Aware LSTM (T-LSTM) performs better on certain data sets than standard LSTM.

See also

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References

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  1. ^ a b c d e Sepp Hochreiter; Jürgen Schmidhuber (1997). "Long short-term memory". Neural Computation. 9 (8): 1735–1780. doi:10.1162/neco.1997.9.8.1735. PMID 9377276. S2CID 1915014.
  2. ^ a b c Hochreiter, Sepp (1991). Untersuchungen zu dynamischen neuronalen Netzen (PDF) (diploma thesis). Technical University Munich, Institute of Computer Science.
  3. ^ a b Hochreiter, Sepp; Schmidhuber, Jürgen (1996-12-03). "LSTM can solve hard long time lag problems". Proceedings of the 9th International Conference on Neural Information Processing Systems. NIPS'96. Cambridge, MA, USA: MIT Press: 473–479.
  4. ^ a b c Felix A. Gers; Jürgen Schmidhuber; Fred Cummins (2000). "Learning to Forget: Continual Prediction with LSTM". Neural Computation. 12 (10): 2451–2471. CiteSeerX 10.1.1.55.5709. doi:10.1162/089976600300015015. PMID 11032042. S2CID 11598600.
  5. ^ a b c Graves, Alex; Fernández, Santiago; Gomez, Faustino; Schmidhuber, Jürgen (2006). "Connectionist temporal classification: Labelling unsegmented sequence data with recurrent neural networks". In Proceedings of the International Conference on Machine Learning, ICML 2006: 369–376. CiteSeerX 10.1.1.75.6306.
  6. ^ Karim, Fazle; Majumdar, Somshubra; Darabi, Houshang; Chen, Shun (2018). "LSTM Fully Convolutional Networks for Time Series Classification". IEEE Access. 6: 1662–1669. arXiv:1709.05206. doi:10.1109/ACCESS.2017.2779939. ISSN 2169-3536.
  7. ^ a b c d Wierstra, Daan; Schmidhuber, J.; Gomez, F. J. (2005). "Evolino: Hybrid Neuroevolution/Optimal Linear Search for Sequence Learning". Proceedings of the 19th International Joint Conference on Artificial Intelligence (IJCAI), Edinburgh: 853–858.
  8. ^ Sak, Hasim; Senior, Andrew; Beaufays, Francoise (2014). "Long Short-Term Memory recurrent neural network architectures for large scale acoustic modeling" (PDF). Archived from the original (PDF) on 2018-04-24.
  9. ^ Li, Xiangang; Wu, Xihong (2014-10-15). "Constructing Long Short-Term Memory based Deep Recurrent Neural Networks for Large Vocabulary Speech Recognition". arXiv:1410.4281 [cs.CL].
  10. ^ a b Wu, Yonghui; Schuster, Mike; Chen, Zhifeng; Le, Quoc V.; Norouzi, Mohammad; Macherey, Wolfgang; Krikun, Maxim; Cao, Yuan; Gao, Qin (2016-09-26). "Google's Neural Machine Translation System: Bridging the Gap between Human and Machine Translation". arXiv:1609.08144 [cs.CL].
  11. ^ a b Ong, Thuy (4 August 2017). "Facebook's translations are now powered completely by AI". www.allthingsdistributed.com. Retrieved 2019-02-15.
  12. ^ Sahidullah, Md; Patino, Jose; Cornell, Samuele; Yin, Ruiking; Sivasankaran, Sunit; Bredin, Herve; Korshunov, Pavel; Brutti, Alessio; Serizel, Romain; Vincent, Emmanuel; Evans, Nicholas; Marcel, Sebastien; Squartini, Stefano; Barras, Claude (2019-11-06). "The Speed Submission to DIHARD II: Contributions & Lessons Learned". arXiv:1911.02388 [eess.AS].
  13. ^ a b c Mayer, H.; Gomez, F.; Wierstra, D.; Nagy, I.; Knoll, A.; Schmidhuber, J. (October 2006). "A System for Robotic Heart Surgery that Learns to Tie Knots Using Recurrent Neural Networks". 2006 IEEE/RSJ International Conference on Intelligent Robots and Systems. pp. 543–548. CiteSeerX 10.1.1.218.3399. doi:10.1109/IROS.2006.282190. ISBN 978-1-4244-0258-8. S2CID 12284900.
  14. ^ a b "Learning Dexterity". OpenAI. July 30, 2018. Retrieved 2023-06-28.
  15. ^ a b Rodriguez, Jesus (July 2, 2018). "The Science Behind OpenAI Five that just Produced One of the Greatest Breakthrough in the History of AI". Towards Data Science. Archived from the original on 2019-12-26. Retrieved 2019-01-15.
  16. ^ a b Stanford, Stacy (January 25, 2019). "DeepMind's AI, AlphaStar Showcases Significant Progress Towards AGI". Medium ML Memoirs. Retrieved 2019-01-15.
  17. ^ Schmidhuber, Jürgen (2021). "The 2010s: Our Decade of Deep Learning / Outlook on the 2020s". AI Blog. IDSIA, Switzerland. Retrieved 2022-04-30.
  18. ^ Calin, Ovidiu (14 February 2020). Deep Learning Architectures. Cham, Switzerland: Springer Nature. p. 555. ISBN 978-3-030-36720-6.
  19. ^ Lakretz, Yair; Kruszewski, German; Desbordes, Theo; Hupkes, Dieuwke; Dehaene, Stanislas; Baroni, Marco (2019), "The emergence of number and syntax units in", The emergence of number and syntax units (PDF), Association for Computational Linguistics, pp. 11–20, doi:10.18653/v1/N19-1002, hdl:11245.1/16cb6800-e10d-4166-8e0b-fed61ca6ebb4, S2CID 81978369
  20. ^ a b c d Klaus Greff; Rupesh Kumar Srivastava; Jan Koutník; Bas R. Steunebrink; Jürgen Schmidhuber (2015). "LSTM: A Search Space Odyssey". IEEE Transactions on Neural Networks and Learning Systems. 28 (10): 2222–2232. arXiv:1503.04069. Bibcode:2015arXiv150304069G. doi:10.1109/TNNLS.2016.2582924. PMID 27411231. S2CID 3356463.
  21. ^ a b c d e f Gers, F. A.; Schmidhuber, J. (2001). "LSTM Recurrent Networks Learn Simple Context Free and Context Sensitive Languages" (PDF). IEEE Transactions on Neural Networks. 12 (6): 1333–1340. doi:10.1109/72.963769. PMID 18249962. S2CID 10192330.
  22. ^ a b c d Gers, F.; Schraudolph, N.; Schmidhuber, J. (2002). "Learning precise timing with LSTM recurrent networks" (PDF). Journal of Machine Learning Research. 3: 115–143.
  23. ^ Xingjian Shi; Zhourong Chen; Hao Wang; Dit-Yan Yeung; Wai-kin Wong; Wang-chun Woo (2015). "Convolutional LSTM Network: A Machine Learning Approach for Precipitation Nowcasting". Proceedings of the 28th International Conference on Neural Information Processing Systems: 802–810. arXiv:1506.04214. Bibcode:2015arXiv150604214S.
  24. ^ Hochreiter, S.; Bengio, Y.; Frasconi, P.; Schmidhuber, J. (2001). "Gradient Flow in Recurrent Nets: the Difficulty of Learning Long-Term Dependencies (PDF Download Available)". In Kremer and, S. C.; Kolen, J. F. (eds.). A Field Guide to Dynamical Recurrent Neural Networks. IEEE Press.
  25. ^ Fernández, Santiago; Graves, Alex; Schmidhuber, Jürgen (2007). "Sequence labelling in structured domains with hierarchical recurrent neural networks". Proc. 20th Int. Joint Conf. On Artificial Intelligence, Ijcai 2007: 774–779. CiteSeerX 10.1.1.79.1887.
  26. ^ a b Graves, A.; Schmidhuber, J. (2005). "Framewise phoneme classification with bidirectional LSTM and other neural network architectures". Neural Networks. 18 (5–6): 602–610. CiteSeerX 10.1.1.331.5800. doi:10.1016/j.neunet.2005.06.042. PMID 16112549. S2CID 1856462.
  27. ^ Fernández, S.; Graves, A.; Schmidhuber, J. (9 September 2007). "An Application of Recurrent Neural Networks to Discriminative Keyword Spotting". Proceedings of the 17th International Conference on Artificial Neural Networks. ICANN'07. Berlin, Heidelberg: Springer-Verlag: 220–229. ISBN 978-3540746935. Retrieved 28 December 2023.
  28. ^ a b Graves, Alex; Mohamed, Abdel-rahman; Hinton, Geoffrey (2013). "Speech recognition with deep recurrent neural networks". 2013 IEEE International Conference on Acoustics, Speech and Signal Processing. pp. 6645–6649. arXiv:1303.5778. doi:10.1109/ICASSP.2013.6638947. ISBN 978-1-4799-0356-6. S2CID 206741496.
  29. ^ Kratzert, Frederik; Klotz, Daniel; Shalev, Guy; Klambauer, Günter; Hochreiter, Sepp; Nearing, Grey (2019-12-17). "Towards learning universal, regional, and local hydrological behaviors via machine learning applied to large-sample datasets". Hydrology and Earth System Sciences. 23 (12): 5089–5110. arXiv:1907.08456. Bibcode:2019HESS...23.5089K. doi:10.5194/hess-23-5089-2019. ISSN 1027-5606.
  30. ^ Eck, Douglas; Schmidhuber, Jürgen (2002-08-28). "Learning the Long-Term Structure of the Blues". Artificial Neural Networks — ICANN 2002. Lecture Notes in Computer Science. Vol. 2415. Springer, Berlin, Heidelberg. pp. 284–289. CiteSeerX 10.1.1.116.3620. doi:10.1007/3-540-46084-5_47. ISBN 978-3540460848.
  31. ^ Schmidhuber, J.; Gers, F.; Eck, D.; Schmidhuber, J.; Gers, F. (2002). "Learning nonregular languages: A comparison of simple recurrent networks and LSTM". Neural Computation. 14 (9): 2039–2041. CiteSeerX 10.1.1.11.7369. doi:10.1162/089976602320263980. PMID 12184841. S2CID 30459046.
  32. ^ Perez-Ortiz, J. A.; Gers, F. A.; Eck, D.; Schmidhuber, J. (2003). "Kalman filters improve LSTM network performance in problems unsolvable by traditional recurrent nets". Neural Networks. 16 (2): 241–250. CiteSeerX 10.1.1.381.1992. doi:10.1016/s0893-6080(02)00219-8. PMID 12628609.
  33. ^ A. Graves, J. Schmidhuber. Offline Handwriting Recognition with Multidimensional Recurrent Neural Networks. Advances in Neural Information Processing Systems 22, NIPS'22, pp 545–552, Vancouver, MIT Press, 2009.
  34. ^ Graves, A.; Fernández, S.; Liwicki, M.; Bunke, H.; Schmidhuber, J. (3 December 2007). "Unconstrained Online Handwriting Recognition with Recurrent Neural Networks". Proceedings of the 20th International Conference on Neural Information Processing Systems. NIPS'07. USA: Curran Associates Inc.: 577–584. ISBN 9781605603520. Retrieved 28 December 2023.
  35. ^ Baccouche, M.; Mamalet, F.; Wolf, C.; Garcia, C.; Baskurt, A. (2011). "Sequential Deep Learning for Human Action Recognition". In Salah, A. A.; Lepri, B. (eds.). 2nd International Workshop on Human Behavior Understanding (HBU). Lecture Notes in Computer Science. Vol. 7065. Amsterdam, Netherlands: Springer. pp. 29–39. doi:10.1007/978-3-642-25446-8_4. ISBN 978-3-642-25445-1.
  36. ^ Huang, Jie; Zhou, Wengang; Zhang, Qilin; Li, Houqiang; Li, Weiping (2018-01-30). "Video-based Sign Language Recognition without Temporal Segmentation". arXiv:1801.10111 [cs.CV].
  37. ^ a b Hochreiter, S.; Heusel, M.; Obermayer, K. (2007). "Fast model-based protein homology detection without alignment". Bioinformatics. 23 (14): 1728–1736. doi:10.1093/bioinformatics/btm247. PMID 17488755.
  38. ^ Thireou, T.; Reczko, M. (2007). "Bidirectional Long Short-Term Memory Networks for predicting the subcellular localization of eukaryotic proteins". IEEE/ACM Transactions on Computational Biology and Bioinformatics. 4 (3): 441–446. doi:10.1109/tcbb.2007.1015. PMID 17666763. S2CID 11787259.
  39. ^ Malhotra, Pankaj; Vig, Lovekesh; Shroff, Gautam; Agarwal, Puneet (April 2015). "Long Short Term Memory Networks for Anomaly Detection in Time Series" (PDF). European Symposium on Artificial Neural Networks, Computational Intelligence and Machine Learning — ESANN 2015. Archived from the original (PDF) on 2020-10-30. Retrieved 2018-02-21.
  40. ^ Tax, N.; Verenich, I.; La Rosa, M.; Dumas, M. (2017). "Predictive Business Process Monitoring with LSTM Neural Networks". Advanced Information Systems Engineering. Lecture Notes in Computer Science. Vol. 10253. pp. 477–492. arXiv:1612.02130. doi:10.1007/978-3-319-59536-8_30. ISBN 978-3-319-59535-1. S2CID 2192354.
  41. ^ Choi, E.; Bahadori, M.T.; Schuetz, E.; Stewart, W.; Sun, J. (2016). "Doctor AI: Predicting Clinical Events via Recurrent Neural Networks". JMLR Workshop and Conference Proceedings. 56: 301–318. arXiv:1511.05942. Bibcode:2015arXiv151105942C. PMC 5341604. PMID 28286600.
  42. ^ Jia, Robin; Liang, Percy (2016). "Data Recombination for Neural Semantic Parsing". arXiv:1606.03622 [cs.CL].
  43. ^ Wang, Le; Duan, Xuhuan; Zhang, Qilin; Niu, Zhenxing; Hua, Gang; Zheng, Nanning (2018-05-22). "Segment-Tube: Spatio-Temporal Action Localization in Untrimmed Videos with Per-Frame Segmentation" (PDF). Sensors. 18 (5): 1657. Bibcode:2018Senso..18.1657W. doi:10.3390/s18051657. ISSN 1424-8220. PMC 5982167. PMID 29789447.
  44. ^ Duan, Xuhuan; Wang, Le; Zhai, Changbo; Zheng, Nanning; Zhang, Qilin; Niu, Zhenxing; Hua, Gang (2018). "Joint Spatio-Temporal Action Localization in Untrimmed Videos with Per-Frame Segmentation". 2018 25th IEEE International Conference on Image Processing (ICIP). 25th IEEE International Conference on Image Processing (ICIP). pp. 918–922. doi:10.1109/icip.2018.8451692. ISBN 978-1-4799-7061-2.
  45. ^ Orsini, F.; Gastaldi, M.; Mantecchini, L.; Rossi, R. (2019). Neural networks trained with WiFi traces to predict airport passenger behavior. 6th International Conference on Models and Technologies for Intelligent Transportation Systems. Krakow: IEEE. arXiv:1910.14026. doi:10.1109/MTITS.2019.8883365. 8883365.
  46. ^ Zhao, Z.; Chen, W.; Wu, X.; Chen, P.C.Y.; Liu, J. (2017). "LSTM network: A deep learning approach for Short-term traffic forecast". IET Intelligent Transport Systems. 11 (2): 68–75. doi:10.1049/iet-its.2016.0208. S2CID 114567527.
  47. ^ Gupta A, Müller AT, Huisman BJH, Fuchs JA, Schneider P, Schneider G (2018). "Generative Recurrent Networks for De Novo Drug Design". Mol Inform. 37 (1–2). doi:10.1002/minf.201700111. PMC 5836943. PMID 29095571.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  48. ^ Saiful Islam, Md.; Hossain, Emam (2020-10-26). "Foreign Exchange Currency Rate Prediction using a GRU-LSTM Hybrid Network". Soft Computing Letters. 3: 100009. doi:10.1016/j.socl.2020.100009. ISSN 2666-2221.
  49. ^ {{Cite Abbey Martin, Andrew J. Hill, Konstantin M. Seiler & Mehala Balamurali (2023) Automatic excavator action recognition and localisation for untrimmed video using hybrid LSTM-Transformer networks, International Journal of Mining, Reclamation and Environment, DOI: 10.1080/17480930.2023.2290364}}
  50. ^ Beaufays, Françoise (August 11, 2015). "The neural networks behind Google Voice transcription". Research Blog. Retrieved 2017-06-27.
  51. ^ Sak, Haşim; Senior, Andrew; Rao, Kanishka; Beaufays, Françoise; Schalkwyk, Johan (September 24, 2015). "Google voice search: faster and more accurate". Research Blog. Retrieved 2017-06-27.
  52. ^ "Neon prescription... or rather, New transcription for Google Voice". Official Google Blog. 23 July 2015. Retrieved 2020-04-25.
  53. ^ Khaitan, Pranav (May 18, 2016). "Chat Smarter with Allo". Research Blog. Retrieved 2017-06-27.
  54. ^ Metz, Cade (September 27, 2016). "An Infusion of AI Makes Google Translate More Powerful Than Ever | WIRED". Wired. Retrieved 2017-06-27.
  55. ^ "A Neural Network for Machine Translation, at Production Scale". Google AI Blog. 27 September 2016. Retrieved 2020-04-25.
  56. ^ Efrati, Amir (June 13, 2016). "Apple's Machines Can Learn Too". The Information. Retrieved 2017-06-27.
  57. ^ Ranger, Steve (June 14, 2016). "iPhone, AI and big data: Here's how Apple plans to protect your privacy". ZDNet. Retrieved 2017-06-27.
  58. ^ "Can Global Semantic Context Improve Neural Language Models? – Apple". Apple Machine Learning Journal. Retrieved 2020-04-30.
  59. ^ Smith, Chris (2016-06-13). "iOS 10: Siri now works in third-party apps, comes with extra AI features". BGR. Retrieved 2017-06-27.
  60. ^ Capes, Tim; Coles, Paul; Conkie, Alistair; Golipour, Ladan; Hadjitarkhani, Abie; Hu, Qiong; Huddleston, Nancy; Hunt, Melvyn; Li, Jiangchuan; Neeracher, Matthias; Prahallad, Kishore (2017-08-20). "Siri On-Device Deep Learning-Guided Unit Selection Text-to-Speech System". Interspeech 2017. ISCA: 4011–4015. doi:10.21437/Interspeech.2017-1798.
  61. ^ Vogels, Werner (30 November 2016). "Bringing the Magic of Amazon AI and Alexa to Apps on AWS. – All Things Distributed". www.allthingsdistributed.com. Retrieved 2017-06-27.
  62. ^ Xiong, W.; Wu, L.; Alleva, F.; Droppo, J.; Huang, X.; Stolcke, A. (April 2018). "The Microsoft 2017 Conversational Speech Recognition System". 2018 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP). IEEE. pp. 5934–5938. doi:10.1109/ICASSP.2018.8461870. ISBN 978-1-5386-4658-8.
  63. ^ a b c d e f Schmidhuber, Juergen (10 May 2021). "Deep Learning: Our Miraculous Year 1990-1991". arXiv:2005.05744 [cs.NE].
  64. ^ Mozer, Mike (1989). "A Focused Backpropagation Algorithm for Temporal Pattern Recognition". Complex Systems.
  65. ^ Schmidhuber, Juergen (2022). "Annotated History of Modern AI and Deep Learning". arXiv:2212.11279 [cs.NE].
  66. ^ Sepp Hochreiter; Jürgen Schmidhuber (21 August 1995), Long Short Term Memory, Wikidata Q98967430
  67. ^ a b c Gers, Felix; Schmidhuber, Jürgen; Cummins, Fred (1999). "Learning to forget: Continual prediction with LSTM". 9th International Conference on Artificial Neural Networks: ICANN '99. Vol. 1999. pp. 850–855. doi:10.1049/cp:19991218. ISBN 0-85296-721-7.
  68. ^ Cho, Kyunghyun; van Merrienboer, Bart; Gulcehre, Caglar; Bahdanau, Dzmitry; Bougares, Fethi; Schwenk, Holger; Bengio, Yoshua (2014). "Learning Phrase Representations using RNN Encoder-Decoder for Statistical Machine Translation". arXiv:1406.1078 [cs.CL].
  69. ^ Srivastava, Rupesh Kumar; Greff, Klaus; Schmidhuber, Jürgen (2 May 2015). "Highway Networks". arXiv:1505.00387 [cs.LG].
  70. ^ Srivastava, Rupesh K; Greff, Klaus; Schmidhuber, Juergen (2015). "Training Very Deep Networks". Advances in Neural Information Processing Systems. 28. Curran Associates, Inc.: 2377–2385.
  71. ^ Schmidhuber, Jürgen (2021). "The most cited neural networks all build on work done in my labs". AI Blog. IDSIA, Switzerland. Retrieved 2022-04-30.
  72. ^ He, Kaiming; Zhang, Xiangyu; Ren, Shaoqing; Sun, Jian (2016). Deep Residual Learning for Image Recognition. 2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR). Las Vegas, NV, USA: IEEE. pp. 770–778. arXiv:1512.03385. doi:10.1109/CVPR.2016.90. ISBN 978-1-4673-8851-1.
  73. ^ Beck, Maximilian; Pöppel, Korbinian; Spanring, Markus; Auer, Andreas; Prudnikova, Oleksandra; Kopp, Michael; Klambauer, Günter; Brandstetter, Johannes; Hochreiter, Sepp (2024-05-07). "xLSTM: Extended Long Short-Term Memory". arXiv:2405.04517 [cs.LG].
  74. ^ NX-AI/xlstm, NXAI, 2024-06-04, retrieved 2024-06-04
  75. ^ Graves, Alex; Beringer, Nicole; Eck, Douglas; Schmidhuber, Juergen (2004). Biologically Plausible Speech Recognition with LSTM Neural Nets. Workshop on Biologically Inspired Approaches to Advanced Information Technology, Bio-ADIT 2004, Lausanne, Switzerland. pp. 175–184.
  76. ^ Hochreiter, S.; Younger, A. S.; Conwell, P. R. (2001). "Learning to Learn Using Gradient Descent". Artificial Neural Networks — ICANN 2001 (PDF). Lecture Notes in Computer Science. Vol. 2130. pp. 87–94. CiteSeerX 10.1.1.5.323. doi:10.1007/3-540-44668-0_13. ISBN 978-3-540-42486-4. ISSN 0302-9743. S2CID 52872549.
  77. ^ Wierstra, Daan; Foerster, Alexander; Peters, Jan; Schmidhuber, Juergen (2005). "Solving Deep Memory POMDPs with Recurrent Policy Gradients". International Conference on Artificial Neural Networks ICANN'07.
  78. ^ Bayer, Justin; Wierstra, Daan; Togelius, Julian; Schmidhuber, Juergen (2009). "Evolving memory cell structures for sequence learning". International Conference on Artificial Neural Networks ICANN'09, Cyprus.
  79. ^ Graves, A.; Liwicki, M.; Fernández, S.; Bertolami, R.; Bunke, H.; Schmidhuber, J. (May 2009). "A Novel Connectionist System for Unconstrained Handwriting Recognition". IEEE Transactions on Pattern Analysis and Machine Intelligence. 31 (5): 855–868. CiteSeerX 10.1.1.139.4502. doi:10.1109/tpami.2008.137. ISSN 0162-8828. PMID 19299860. S2CID 14635907.
  80. ^ Märgner, Volker; Abed, Haikal El (July 2009). "ICDAR 2009 Arabic Handwriting Recognition Competition". 2009 10th International Conference on Document Analysis and Recognition. pp. 1383–1387. doi:10.1109/ICDAR.2009.256. ISBN 978-1-4244-4500-4. S2CID 52851337.
  81. ^ "Patient Subtyping via Time-Aware LSTM Networks" (PDF). msu.edu. Retrieved 21 Nov 2018.
  82. ^ "Patient Subtyping via Time-Aware LSTM Networks". Kdd.org. Retrieved 24 May 2018.
  83. ^ "SIGKDD". Kdd.org. Retrieved 24 May 2018.

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