《史丹佛資料探勘教程(第3版)》完整參考文獻
第1章
(1) L. Breiman, “Statistical modeling: the two cultures,” Statistical Science 16:3, pp. 199–215, 2001.
(2) A. Broder, R. Kumar, F. Maghoul, P. Raghavan, S. Rajagopalan, R. Stata, A. Tomkins, and J. Weiner, “Graph structure in the web,” Computer Networks 33:1–6, pp. 309–320, 2000.
(3) M.M. Gaber, Scientific Data Mining and Knowledge Discovery – Principlesand Foundations, Springer, New York, 2010.
(4) H. Garcia-Molina, J.D. Ullman, and J. Widom, Database Systems: The Complete Book Second Edition, Prentice-Hall, Upper Saddle River, NJ, 2009.
(5) D.E. Knuth, The Art of Computer Programming Vol. 3 (Sorting and Searching), Second Edition, Addison-Wesley, Upper Saddle River, NJ, 1998.
(6) C.P. Manning, P. Raghavan, and H. Schüutze, Introduction to Information Retrieval, Cambridge University Press, 2008.
(7) R.K. Merton, “The Matthew effect in science,” Science 159:3810, pp. 56–63, Jan. 5, 1968.
(8) P.-N. Tan, M. Steinbach, and V. Kumar, Introduction to Data Mining, Addison-Wesley, Upper Saddle River, NJ, 2005.
第2章
(1) F.N. Afrati, V. Borkar, M. Carey, A. Polyzotis, and J.D. Ullman, “Cluster computing, recursion, and Datalog,” to appear in Proc. Datalog 2.0 Workshop, Elsevier, 2011.
(2) F.N. Afrati, A. Das Sarma, S. Salihoglu, and J.D. Ullman, “Upper and lower bounds on the cost of a MapReduce computation.” to appear in Proc. Intl. Conf. on Very Large Databases, 2013. Also available as CoRR, abs/1206.4377.
(3) F.N. Afrati and J.D. Ullman, “Optimizing joins in a MapReduce environment,”Proc. Thirteenth Intl. Conf. on Extending Database Technology, 2010.
(4) F.N. Afrati and J.D. Ullman, “Matching bounds for the all-pairs MapReduce problem,” IDEAS 2013, pp. 3–4.
(5) A. Alexandrov, R. Bergmann, S. Ewen, J.-C. Freytag, F. Hueske, A. Heise O. Kao,M. Leich, U. Leser, V. Markl, F. Naumann, M. Peters, A. Rheinlander, M.J. Sax, S. Schelter, M. Hoger, K. Tzoumas, and D. Warneke, “The Stratosphere platform for big data analytics,” VLDB J. 23:6, pp. 939–964, 2014.
(6) V.R. Borkar, M.J. Carey, R, Grover, N. Onose, and R. Vernica, “Hyracks: A flexible and extensible foundation for data-intensive computing,” Intl. Conf. on Data Engineering, pp. 1151–1162, 2011.
(7) Y. Bu, B. Howe, M. Balazinska, and M. Ernst, “HaLoop: efficient itera76 MapReduce and the New Software Stack tive data processing on large clusters,” Proc. Intl. Conf. on Very Large Databases, 2010.
(8) F. Chang, J. Dean, S. Ghemawat, W.C. Hsieh, D.A. Wallach, M. Burrows, T. Chandra, A. Fikes, and R.E. Gruber, “Bigtable: a distributed storage system for structured data,” ACM Transactions on Computer Systems 26:2, pp. 1–26, 2008.
(9) B.F. Cooper, R. Ramakrishnan, U. Srivastava, A. Silberstein, P. Bohannon, H.-A. Jacobsen, N. Puz, D. Weaver, and R. Yerneni, “Pnuts: Yahoo!’s hosted data serving platform,” PVLDB 1:2, pp. 1277–1288, 2008.
(10) J. Dean and S. Ghemawat, “Mapreduce: simplified data processing on large clusters,” Comm. ACM 51:1, pp. 107–113, 2008.
(11) D.J. DeWitt, E. Paulson, E. Robinson, J.F. Naughton, J. Royalty, S. Shankar, and A. Krioukov, “Clustera: an integrated computation and data management system,” PVLDB 1:1, pp. 28–41, 2008.
(12) flink.apache.org, Apache Foundation.
(13) S. Ghemawat, H. Gobioff, and S.-T. Leung, “The Google file system,” 19th ACM Symposium on Operating Systems Principles, 2003.
(14) giraph.apache.org, Apache Foundation.
(15) hadoop.apache.org, Apache Foundation.
(16) hadoop.apache.org/hive, Apache Foundation.
(17) M. Isard, M. Budiu, Y. Yu, A. Birrell, and D. Fetterly. “Dryad: distributed data-parallel programs from sequential building blocks,” Proceedings of the 2nd ACM SIGOPS/EuroSys European Conference on Computer Systems, pp. 59–72, ACM, 2007.
(18) Y. Low, D. Bickson, J. Gonzalez, C. Guestrin, A. Kyrola, and J.M. Hellerstein, “Distributed GraphLab: a framework for machine learning and data mining in the cloud,” —em Proc. VLDB Endowment 5:8, pp. 716–727, 2012.
(19) G. Malewicz, M.N. Austern, A.J.C. Sik, J.C. Denhert, H. Horn, N. Leiser, and G. Czajkowski, “Pregel: a system for large-scale graph processing,”Proc. ACM SIGMOD Conference, 2010.
(20) C. Olston, B. Reed, U. Srivastava, R. Kumar, and A. Tomkins, “Pig latin: a not-so-foreign language for data processing,” Proc. ACM SIGMOD Conference, pp. 1099–1110, 2008.
(21) spark.apache.org, Apache Foundation.
(22) spark.apache.org/graphx, Apache Foundation.
(23) spark.apache.org/sql, Apache Foundation.
(24) www.tensorflow.org.
(25) J.D. Ullman and J. Widom, A First Course in Database Systems, Third Edition, Prentice-Hall, Upper Saddle River, NJ, 2008.
(26) Y. Yu, M. Isard, D. Fetterly, M. Budiu, I. Erlingsson, P.K. Gunda, and J. Currey, “DryadLINQ: a system for general-purpose distributed dataparallel computing using a high-level language,” OSDI, pp. 1–14, USENIX Association, 2008.
(27) M. Zaharia, M. Chowdhury, T. Das, A. Dave, J. Ma, M. McCauley, M.J. Franklin, S. Shenker, and I. Stoica, “Resilient distributed datasets: A faulttolerant abstraction for in-memory cluster computing,” Proc. 9th USENIX conference on Networked Systems Design and Implementation, USENIX Association, 2012.
第3章
(1) A. Andoni and P. Indyk, “Near-optimal hashing algorithms for approximate nearest neighbor in high dimensions,” Comm. ACM 51:1, pp. 117–122, 2008.
(2) A.Z. Broder, “On the resemblance and containment of documents,” Proc.Compression and Complexity of Sequences*, pp. 21–29, Positano Italy, 1997.
(3) A.Z. Broder, M.Charikar,A.M. Frieze, and M. Mitzenmacher, “Min-wise independent permutations,” ACM Symposium on Theory of Computing, pp.327–336, 1998.
(4) M.S. Charikar, “Similarity estimation techniques from rounding algorithms,” ACM Symposium on Theory of Computing, pp. 380–388, 2002.
(5) S. Chaudhuri, V. Ganti, and R. Kaushik, “A primitive operator for similarity joins in data cleaning,” Proc. Intl. Conf. on Data Engineering, 2006.
(6) M. Datar, N. Immorlica, P. Indyk, and V.S. Mirrokni, “Locality-sensitive hashing scheme based on p-stable distributions,” Symposium on Computational Geometry pp. 253–262, 2004.
(7) A. Gionis, P. Indyk, and R. Motwani, “Similarity search in high dimensions via hashing,” Proc. Intl. Conf. on Very Large Databases, pp. 518–529, 1999.
(8) M. Henzinger, “Finding near-duplicate web pages: a large-scale evaluation of algorithms,” Proc. 29th SIGIR Conf., pp. 284–291, 2006.
(9) P. Indyk and R. Motwani. “Approximate nearest neighbor: towards removing the curse of dimensionality,” ACM Symposium on Theory of Computing, pp. 604–613, 1998.
(10) P. Li, A.B. Owen, and C.H. Zhang. “One permutation hashing,” Conf. on Neural Information Processing Systems 2012, pp. 3122–3130.
(11) U. Manber, “Finding similar files in a large file system,” Proc. USENIX Conference, pp. 1–10, 1994.
(12) M. Theobald, J. Siddharth, and A. Paepcke, “SpotSigs: robust and efficient near duplicate detection in large web collections,” 31st Annual ACM SIGIR Conference, July, 2008, Singapore.
(13) C. Xiao, W. Wang, X. Lin, and J.X. Yu, “Efficient similarity joins for near duplicate detection,” Proc. WWW Conference, pp. 131–140, 2008.
第4章
(1) N. Alon, Y. Matias, and M. Szegedy, “The space complexity of approximating frequency moments,” 28th ACM Symposium on Theory of Computing, pp. 20–29, 1996.
(2) B. Babcock, S. Babu, M. Datar, R. Motwani, and J. Widom, “Models and issues in data stream systems,” Symposium on Principles of Database Systems, pp. 1–16, 2002.
(3) B.H. Bloom, “Space/time trade-offs in hash coding with allowable errors,”Comm. ACM 13:7, pp. 422–426, 1970.
(4) M. Datar, A. Gionis, P. Indyk, and R. Motwani, “Maintaining stream statistics over sliding windows,” SIAM J. Computing 31, pp. 1794–1813, 2002.
(5) P. Flajolet and G.N. Martin, “Probabilistic counting for database applications,”24th Symposium on Foundations of Computer Science, pp. 76–82,1983.
(6) M. Garofalakis, J. Gehrke, and R. Rastogi (editors), Data Stream Management, Springer, 2009.
(7) P.B. Gibbons, “Distinct sampling for highly-accurate answers to distinct values queries and event reports,” Intl. Conf. on Very Large Databases, pp. 541–550, 2001.
(8) H.V. Jagadish, I.S. Mumick, and A. Silberschatz, “View maintenance issues for the chronicle data model,” Proc. ACM Symp. on Principles of Database Systems, pp. 113–124, 1995.
(9) W.H. Kautz and R.C. Singleton, “Nonadaptive binary superimposed codes,” IEEE Transactions on Information Theory 10, pp. 363–377, 1964.
(10) J. Vitter, “Random sampling with a reservoir,” ACM Transactions on Mathematical Software 11:1, pp. 37–57, 1985.
第5章
(1) S. Brin and L. Page, “Anatomy of a large-scale hypertextual web search engine,” Proc. 7th Intl. World-Wide-Web Conference, pp. 107–117, 1998.
(2) A. Broder, R. Kumar, F. Maghoul, P. Raghavan, S. Rajagopalan, R. Stata, A. Tomkins, and J. Weiner, “Graph structure in the web,” Computer Networks 33:1–6, pp. 309–320, 2000.
(3) Z. Gyöngi, P. Berkhin, H. Garcia-Molina, and J. Pedersen, “Link spam detection based on mass estimation,” Proc. 32nd Intl. Conf. on Very Large Databases, pp. 439–450, 2006.
(4) Z. Gyöngi, H. Garcia-Molina, and J. Pedersen, “Combating link spam with trustrank,” Proc. 30th Intl. Conf. on Very Large Databases, pp. 576–587,2004.
(5) T.H. Haveliwala, “Efficient computation of PageRank,” Stanford Univ. Dept.of Computer Science technical report, Sept., 1999. Available as
http://infolab.stanford.edu/~taherh/papers/efficient-pr.pdf
(6) T.H. Haveliwala, “Topic-sensitive PageRank,” Proc. 11th Intl. World-Wide-Web Conference, pp. 517–526, 2002
(7) J.M. Kleinberg, “Authoritative sources in a hyperlinked environment,” J.ACM 46:5, pp. 604–632, 1999.
第6章
(1) R. Agrawal, T. Imielinski, and A. Swami, “Mining associations between sets of items in massive databases,” Proc. ACM SIGMOD Intl. Conf. on Management of Data, pp. 207–216, 1993.
(2) R. Agrawal and R. Srikant, “Fast algorithms for mining association rules,”Intl. Conf. on Very Large Databases, pp. 487–499, 1994.
(3) M. Fang, N. Shivakumar, H. Garcia-Molina, R. Motwani, and J.D. Ullman, “Computing iceberg queries efficiently,” Intl. Conf. on Very Large Databases, pp. 299-310, 1998.
(4) J.S. Park, M.-S. Chen, and P.S. Yu, “An effective hash-based algorithm formining association rules,” Proc. ACM SIGMOD Intl. Conf. on Management of Data, pp. 175–186, 1995.
(5) A. Savasere, E. Omiecinski, and S.B. Navathe, “An efficient algorithm formining association rules in large databases,” Intl. Conf. on Very Large Databases, pp. 432–444, 1995.
(6) H. Toivonen, “Sampling large databases for association rules,” Intl. Conf. on Very Large Databases, pp. 134–145, 1996.
第7章
(1) B. Babcock, M. Datar, R. Motwani, and L. O’Callaghan, “Maintaining variance and k-medians over data stream windows,” Proc. ACM Symp. on Principles of Database Systems, pp. 234–243, 2003.
(2) P.S. Bradley, U.M. Fayyad, and C. Reina, “Scaling clustering algorithms to large databases,” Proc. Knowledge Discovery and Data Mining, pp. 9–15,1998.
(3) V. Ganti, R. Ramakrishnan, J. Gehrke, A.L. Powell, and J.C. French:, “Clustering large datasets in arbitrary metric spaces,” Proc. Intl. Conf. on Data Engineering, pp. 502–511, 1999.
(4) H. Garcia-Molina, J.D. Ullman, and J. Widom, Database Systems: The Complete Book Second Edition, Prentice-Hall, Upper Saddle River, NJ, 2009.
(5) S. Guha, R. Rastogi, and K. Shim, “CURE: An efficient clustering algorithm for large databases,” Proc. ACM SIGMOD Intl. Conf. on Management of Data, pp. 73–84, 1998.
(6) T. Zhang, R. Ramakrishnan, and M. Livny, “BIRCH: an efficient data clustering method for very large databases,” Proc. ACM SIGMOD Intl. Conf. on Management of Data, pp. 103–114, 1996.
第8章
(1) N. Craswell, O. Zoeter, M. Taylor, and W. Ramsey, “An experimental comparison of click- position bias models,” Proc. Intl. Conf. on Web Search and Web Data Mining,pp. 87–94, 2008.
(2) B. Kalyanasundaram and K.R. Pruhs, “An optimal deterministic algorithm for b-matching,” Theoretical Computer Science 233:1–2, pp. 319–325, 2000.
(3) A Mehta, A. Saberi, U. Vazirani, and V. Vazirani, “Adwords and generalized on-line matching,” IEEE Symp. on Foundations of Computer Science, pp. 264–273, 2005.
第9章
(1) G. Adomavicius and A. Tuzhilin, “Towards the next generation of recommendersystems: a survey of the state-of-the-art and possible extensions,” IEEE Trans. on Data and Knowledge Engineering 17:6, pp. 734–749, 2005.
(2) C. Anderson,
http://www.wired.com/wired/archive/12.10/tail.html
2004.
(3) C. Anderson, The Long Tail: Why the Future of Business is Selling Less of More, Hyperion Books, New York, 2006.
(4) Y. Koren, “The BellKor solution to the Netflix grand prize,”
www.netflixprize.com/assets/GrandPrize2009_BPC_BellKor.pdf
2009.
(5) G. Linden, B. Smith, and J. York, “Amazon.com recommendations: item-to-item collaborative filtering,” Internet Computing 7:1, pp. 76–80, 2003.
(6) M. Piotte and M. Chabbert, “The Pragmatic Theory solution to the Netflix grand prize,”
www.netflixprize.com/assets/GrandPrize2009 BPC PragmaticTheory.pdf
2009.
(7) A. Toscher, M. Jahrer, and R. Bell, “The BigChaos solution to the Netflix grand prize,”
www.netflixprize.com/assets/GrandPrize2009_BPC_BigChaos.pdf
2009.
(8) L. von Ahn, “Games with a purpose,” IEEE Computer Magazine, pp. 96–98, June 2006.
第10章
(1) F. N. Afrati, D. Fotakis, and J. D. Ullman, “Enumerating subgraph instancesby map-reduce,” http://ilpubs.stanford.edu:8090/1020.
(2) F.N. Afrati and J.D. Ullman, “Transitive closure and recursive Datalog implemented on clusters,” in Proc. EDBT (2012).
(3) L. Backstrom and J. Leskovec, “Supervised random walks: predicting and recommending links in social networks,” Proc. Fourth ACM Intl. Conf. on Web Search and Data Mining (2011), pp. 635–644.
(4) P. Boldi, M. Rosa, and S. Vigna, “HyperANF: approximating the neighbourhood function of very large graphs on a budget,” Proc. WWW Conference (2011), pp. 625–634.
(5) S. Fortunato, “Community detection in graphs,” Physics Reports 486:3–5(2010), pp. 75–174.
(6) M. Girvan and M.E.J. Newman, “Community structure in social and biological networks,” Proc. Natl. Acad. Sci. 99 (2002), pp. 7821–7826.
(7) Y.E. Ioannidis, “On the computation of the transitive closure of relational operators,” Proc. 12th Intl. Conf. on Very Large Data Bases, pp. 403–411.
(8) G. Jeh and J. Widom, “Simrank: a measure of structural-context similarity,” Proceedings of the eighth ACM SIGKDD Intl. Conf. on Knowledge Discovery and Data Mining (2002), pp. 538–543.
(9) R. Kumar, P. Raghavan, S. Rajagopalan, and A. Tomkins, “Trawling the Web for emerging cyber-communities,” Computer Networks 31:11–16 (May,1999), pp. 1481–1493.
(10) J. Leskovec, K.J. Lang, A. Dasgupta, and M.W. Mahoney, “Community structure in large networks: natural cluster sizes and the absence of large well-defined clusters,” http://arxiv.org/abs/0810.1355.
(11) S. Melnik, H. Garcia-Molina, and E. Rahm, “Similarity flooding: a versatile graph matching algorithm and its application to schema matching,” Proc.Intl. Conf. on Data Engineering (2002), pp. 117–128.
(12) C.R. Palmer, P.B. Gibbons, and C. Faloutsos, “ANF: a fast and scalable tool for data mining in massive graphs,” Proc. Eighth ACM SIGKDD Intl.Conf. on Knowledge Discovery and Data Mining (2002), pp. 81–90.
(13) J. Shi and J. Malik, “Normalized cuts and image segmentation,” IEEE Trans. on Pattern Analysis and Machine Intelligence 22:8 (2000), pp. 888–905.
(14) Stanford Network Analysis Platform, http://snap.stanford.edu.
(15) S. Suri and S. Vassilivitskii, “Counting triangles and the curse of the last reducer,” Proc. WWW Conference (2011).
(16) H. Tong, C. Faloutsos, and J.-Y. Pan, “Fast random walk with restart and its applications,” ICDM 2006, pp. 613–622.
(17) C.E. Tsourakakis, U. Kang, G.L. Miller, and C. Faloutsos, “DOULION: counting triangles in massive graphs with a coin,” Proc. Fifteenth ACMSIGKDD Intl. Conf. on Knowledge Discovery and Data Mining (2009).
(18) P. Valduriez and H. Boral, “Evaluation of recursive queries using join indices,” Expert Database Conf. (1986), pp. 271–293.
(19) U. von Luxburg, “A tutorial on spectral clustering,” Statistics and Computing 17:4 (2007), 2007, pp. 395–416.
(20) J. Yang and J. Leskovec, “Overlapping community detection at scale: a nonnegative matrix factorization approach,” ACM Intl. Conf. on Web Search and Data Mining, 2013.
(21) J. Yang, J. McAuley, J. Leskovec, “Detecting cohesive and 2-mode communities in directed and undirected networks,” ACM Intl. Conf. on Web Search and Data Mining, 2014.
(22) J. Yang, J. McAuley, J. Leskovec, “Community detection in networks with node attributes,” IEEE Intl. Conf. on Data Mining, 2013.
第11章
(1) S. Deerwester, S.T. Dumais, G.W. Furnas, T.K. Landauer, and R. Harshman, “Indexing by latent semantic analysis,” J. American Society for Information Science 41:6 (1990).
(2) P. Drineas, R. Kannan, and M.W. Mahoney, “Fast Monte Carlo algorithms for matrices III: Computing a compressed approximate matrix decomposition,” SIAM J. Computing 36:1 (2006), pp. 184–206.
(3) G.H. Golub and W. Kahan, “Calculating the singular values and pseudo inverse of a matrix,” J. SIAM Series B 2:2 (1965), pp. 205–224.
(4) G.H. Golub and C.F. Van Loan, Matrix Computations, JHU Press, 1996.
(5) M.W. Mahoney, M. Maggioni, and P. Drineas, “Tensor-CUR decompositions for tensor-based data,” SIGKDD, pp. 327–336, 2006.
(6) K. Pearson, “On lines and planes of closest fit to systems of points in space,” Philosophical Magazine 2:11 (1901), pp. 559–572.
(7) J. Sun, Y. Xie, H. Zhang, and C. Faloutsos, “Less is more: compact matrix decomposition for large sparse graphs,” Proc. SIAM Intl. Conf. on Data Mining, 2007.
(8) M.E. Wall, A. Reichtsteiner and L.M. Rocha, “Singular value decomposition and principal component analysis,” in A Practical Approach to Microarray Data Analysis (D.P. Berrar, W. Dubitzky, and M. Granzow, eds.), pp. 91–109, Kluwer, Norwell, MA, 2003.
第12章
(1) H. Blockeel and L. De Raedt, “Top-down induction of first-order logical decision trees,” Artificial intelligence 101:1–2 (1998), pp. 285–297.
(2) A. Blum, “Empirical support for winnow and weighted-majority algorithms: results on a calendar scheduling domain,” Machine Learning 26 (1997), pp. 5–23.
(3) L. Bottou, “Large-scale machine learning with stochastic gradient descent,” Proc. 19th Intl. Conf. on Computational Statistics (2010), pp. 177–187, Springer.
(4) L. Bottou, “Stochastic gradient tricks, neural networks,” in Tricks of the Trade, Reloaded, pp. 430–445, edited by G. Montavon, G.B. Orr and K.-R. Mueller, Lecture Notes in Computer Science (LNCS 7700), Springer, 2012.
(5) C.J.C. Burges, “A tutorial on support vector machines for pattern recognition,” Data Mining and Knowledge Discovery 2 (1998), pp. 121–167.
(6) N. Cristianini and J. Shawe-Taylor, An Introduction to Support Vector Machines and Other Kernel-Based Learning Methods, Cambridge University Press, 2000.
(7) C. Cortes and V.N. Vapnik, “Support-vector networks,” Machine Learning 20 (1995), pp. 273–297.
(8) Y. Freund and R.E. Schapire, “Large margin classification using the perceptron algorithm,” Machine Learning 37 (1999), pp. 277–296.
(9) H. Garcia-Molina, J.D. Ullman, and J. Widom, Database Systems: the Complete Book, Prentice Hall, Upper Saddle River NJ, 2009.
(10) T. Joachims, “Training linear SVMs in linear time.” Proc. 12th ACM SIGKDD (2006), pp. 217–226.
(11) N. Littlestone, “Learning quickly when irrelevant attributes abound: a new linear-threshold algorithm,” Machine Learning 2 (1988), pp. 285–318.
(12) M. Minsky and S. Papert, Perceptrons: An Introduction to Computational Geometry (2nd edition), MIT Press, Cambridge MA, 1972.
(13) J. R. Quinlan, “Induction of decision trees,” Machine Learning 1 (1986), pp. 81–106.
(14) F. Rosenblatt, “The perceptron: a probabilistic model for information storage and organization in the brain,” Psychological Review 65:6 (1958), pp. 386–408.
第13章
(1) http://caffe2.ai
(2) Fukushima, K., “Neocognitron, a self-organizing neural network model for a mechanism of pattern recognition unaffected by shift of position,” Biological Cybernetics 36:1 (1980), pp. 193–202.
(3) Hochreiter, S. and J. Schmidhuber, “Long Short-Term Memory,” Neural Computation 9:8 (1997), pp. 1735–1780.
(4) J.J. Hopfield, “Neural networks and physical systems with emergent collective computational abilities,” Proceedings of the National Academy of Sciences 79:8 (1982), pp. 2554–2558.
(6) Krizhevsky, A, I. Sutskever, and G.E. Hinton, “Image classification with deep convolutional neural networks,” Advances in Neural Information Processing Systems 25, 1097–1105, (2012).
(7) LeCun, Y. and Y. Bengio, “Convolutional networks for images, speech, and time series,” The Handbook of Brain Theory and Neural Networks (M. Arbib, ed.), MIT Press, (1995).
(8) LeCun, Y., B. Boser, J.S. Denker, D. Henderson, R.E. Howard, and W. Hubbard, “Backpropagation applied to handwritten zip code recognition,” Neural Computation 1:4 (1989) pp. 541–551.
(9) LeCun, Y., C. Cortes, and C.J.C. Burges, “The MNIST database of handwritten digits,” http://http://yann.lecun.com/exdb/mnist/
(10) http://pytorch.org
(11) Rumelhart, D.E., G.E. Hinton, and R.J. Williams, “Learning representations by back-propagating errors,” Nature 323 (1986), pp. 533–536.
(12) http://www.tensorflow.org
(13) Waibel, A., T. Hanazawa, G.E. Hinton, K. Shikano, and K.J. Lang, “Phoneme recognition using time-delay neural networks,” IEEE Transactions on Acoustics, Speech, and Signal Processing 37:3 (1989), pp. 328–339.
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