Deep Learning and Autoregressive Approach for Prediction of Time Series Data
Journal: Journal of Autonomous Intelligence DOI: 10.32629/jai.v3i2.207
Abstract
A deep neural network based approach for prediction of non-stationary data has been proposed in this work. A new
regression scheme has been used in the proposed model. Any non-stationary data can be used to test the efficiency of
the proposed model, however in this work stock data has been used due to the fact that stock data has a property
of being nonlinear or non-stationary in nature. Beside using proposed model, predictions were also obtained using some
statistical models and artificial neural networks. Traditional statistical models did not yield any expected results;
artificial neural networks resulted into high time complexity. Therefore, deep learning approach seemed to be the best
method as of today in dealing with such problems wherein time complexity and excellent predictions are of concern.
Keywords
Artificial Neural Networks; Autoregressive Model; Deep Learning; Time series; Keras
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1. Adhikari, R., & Agrawal, R. (2014). A combination of artificial neural network and random walk models for financial time series forecasting. Neural Computing and Applications, 24 , 1441–1449.
2. Arajo, R., Oliveira, A., & Meira, S. (2015). A hybrid model for high-frequency stock market forecasting. Expert Systems with Applications, 42 , 4081–4096.
3. Araujo, R. (2010). A hybrid intelligent morphological approach for stock market forecasting. Neural Processing Letters, 31 , 195–217.
4. Asadi, S., Hadavandi, E., Mehmanpazir, F., & Nakhostin, M. (2012). Hybridization of evolutionary levenbergmarquardt neural networks and data pre-processing for stock market predictionl. Knowledge-Based Systems, 35 , 245–258.
5. Bollerslev, T. (1986). Generalized autoregressive conditional heteroskedasticity. Journal of Econometrics, 31 , 307–327.
6. Box, G., & Jenkins, G. (1970). Time series analysis, forecasting and control. San Francisco: Holden-Day.
7. Brown, R. (2004). Smoothing, forecasting and prediction of discrete time series. Mineola, N.Y.: Courier Dover Publications.
8. Bryson, A., Ho, Y., & Siouris, G. (1979). Applied optimal control: Optimization, estimation, and control. IEEE Transactions on Systems, Man, and Cybernetics, 9 , 366–367.
9. Burges, C. (1998). A tutorial on support vector machines for pattern recognition. Data Mining and Knowledge Discovery, 2 , 121–167.
10. Chang, C. (2015). Deep and shallow architecture of multilayer neural networks. IEEE Transactions on Neural Networks and Learning Systems, 26 , 2477– 2486.
11. Chen, M., & Chen, B. (2015). A hybrid fuzzy time series model based on granular computing for stock price forecasting. Information Sciences, 294 , 227–241.
12. Chen, M., Chen, D. R., Fan, M. H., & Huang, T. Y. (2013). International transmission of stock market movements: an adaptive neuro-fuzzy inference system for analysis of TAIEX forecasting. Neural Computing and Applications, 23 , 369–378.
13. Chen, Y., Cheng, C., & Tsai, W. (2014). Modeling fitting-function-based fuzzy time series patterns for evolving stock index forecasting. Applied Intelligence, 41 , 327–347.
14. Chong, E., Han, C., & Park, F. (2017). Deep learning networks for stock market analysis and prediction: Methodology, data representations, and case studies. Expert Systems with Applications, 83 , 187–205.
15. Coelho, L., Coelho, V., Luz, E., Ochi, L., & Frederico, G. (2017). A gpu deep learning metaheuristic based model for time series forecasting. Applied Energy, 201 , 412–418.
16. D.Ravi, Szczotka, A. B., Shakir, D., Pereira, S., & Vercauteren, T. (2018). Effective deep learning training for single-image super-resolution in endomicroscopy exploiting video-registration-based reconstruction. International Journal of Computer Assisted Radiology and Surgery, 13 , 917–924.
17. Engle, R. (1982). Autoregressive conditional heteroscedasticity with estimates of the variance of united kingdom inflation. Econometrica, 50 , 987–1007.
18. Fang, Y. (2018). Feature selection, deep neural network and trend prediction. Journal of Shanghai Jiaotong University (Science), 23 , 297–307.
19. Freitas, F., de Souza, A., & de Almeida, A. (2009). Prediction-based portfolio optimization using neural networks. Neurocomputing, 72 , 2155–2170.
20. Haykin, S. (1994). Neural networks: A comprehensive foundation. Saddle River: Prentice-Hall.
21. Holland, J. H. (1992). Adaptation in natural and artificial systems: an introductory analysis with applications to biology, control and artificial intelligence. Cambridge, MA, USA: MIT Press.
22. Hsieh, T., Hsiao, H., & Yeh, W. (2011). Forecasting stock markets using wavelet transforms and recurrent neural networks: An integrated system based on artificial bee colony algorithm. Applied Soft Computing, 11 , 2510– 2525.
23. Hsu, V. M. (2013). A hybrid procedure with feature selection for resolving stock/futures price forecasting problems. Neural Computing and Applications, 22 , 651–671.
24. Huang, C., & Tsai, C. (2009). A hybrid sofm-svr with a filter-based feature selection for stock market forecasting. Expert Systems with Applications, 36 , 1529–1539.
25. Huang, X., Sun, J., & Sun, J. (2018). A car-following model considering asymmetric driving behavior based on long short-term memory neural networks. Transportation Research Part C: Emerging Technologies, 95 , 346–362.
26. Kao, L., Chiu, C., Lu, C., & Chang, C. (2013). A hybrid approach by integrating wavelet-based feature extraction with mars and svr for stock index forecasting. Decision Support Systems, 54 , 1228–1244.
27. Kappeler, A., Yoo, S., Dai, Q., & Katsaggelos, A. (2016). Video superresolution with convolutional neural networks. IEEE Transactions on Computational Imaging, 2 , 109–122.
28. Khashei, M., & Bijari, M. (2010). An artificial neural network (p, d, q) model for timeseries forecasting. Expert Systems with Applications, 37 , 479–489.
29. Kim, J., Kim, H., Huh, S., Lee, J., & Choi, K. (2018). Deep neural networks with weighted spikes. Neurocomputing, 311 , 273–386.
30. Kim, K., & Lee, W. (2004). Stock market prediction using artificial neural networks with optimal feature transformation. Neural Computing & Applications, 13 , 255–260.
31. Kim, K. J., & Ahn, H. (2012). Simultaneous optimization of artificial neural networks for financial forecasting. Applied Intelligence, 36 , 887–898.
32. Kim, M., Han, I., & Lee, K. (2004). Hybrid knowledge integration using the fuzzy genetic algorithm: prediction of the korea stock price index. Intelligent Systems in Accounting, Finance and Managemen, 12 , 43–60.
33. Kollias, D., Tagaris, A., Stafylopatis, A., Kollias, S., & Tagaris, G. (2018). Deep neural architectures for prediction in healthcare. Complex & Intelligent Systems, 4 , 119–131.
34. Kraus, M., & Feuerriegel, S. (2017). Decision support from financial disclosures with deep neural networks and transfer learning. Decision Support Systems, 104 , 38–48.
35. Kwon, Y., & Moon, B. (2007). A hybrid neurogenetic approach for stock forecasting. IEEE Transactions on Neural Networks, 18 , 851–864.
36. Lachiheb, O., & Gouider, M. (2018). A hierarchical deep neural network design for stock returns prediction. Procedia Computer Science, 126 , 264–272.
37. Lin, Q., Hong, J., Liu, Z., Li, B., & Wangl, J. (2018). Investigation into the topology optimization for conductive heat transfer based on deep learning approach. International Communications in Heat and Mass Transfer , 97 , 103–109.
38. Liu, D., Wang, Z., Fan, Y., Liu, X., Wang, Z., Chang, S., Wang, X., & Huang, T. (2018). Learning temporal dynamics for video super-resolution: A deep learning approach. IEEE Transactions on Image Processing, 27 , 3432–3445.
39. Lu, C. (2013). Hybridizing nonlinear independent component analysis and support vector regression with particle swarm optimization for stock index forecasting. Neural Computing and Applications, 23 , 2417–2427.
40. McCulloch, W. S., & Pitts, W. (1943). A logical calculus of the ideas immanent in nervous activity. The bulletin of mathematical biophysics, 5 , 115–133.
41. Moghaddam, A., Moghaddam, M., & Esfandyari, M. (2016). Stock market index prediction using artificial neural network. Journal of Economics, Finance and Administrative Science, 21 , 89–93.
42. Pai, P., & Lin, C. (2005). A hybrid arima and support vector machines model in stock price forecasting. Omega, 33 , 497–505.
43. Pathak, A., Pandey, M., & Rautaray, S. (2018). Application of deep learning for object detection. Procedia Computer Science, 132 , 1706–1717.
44. Purushotham, S., Meng, C., Che, Z., & Liu, Y. (2018). Benchmarking deep learning models on large healthcare datasets. Journal of Biomedical Informatics, 83 , 112–134.
45. Rather, A. (2014). A hybrid intelligent method of predicting stock returns. Advances in Artificial Neural Systems, 2014.
46. Rather, A., Agarwal, A., & Sastry, V. (2015). Recurrent neural network and a hybrid model for prediction of stock returns. Expert Systems with Applications, 42 , 3234–3241.
47. Sannino, G., & Pietro, G. (2018). A deep learning approach for ecg-based heartbeat classification for arrhythmia detection. Future Generation Computer Systems, 86 , 446–455.
48. Shao, L., Wu, D., & Li, X. (2014). Learning deep and wide: A spectral method for learning deep networks. IEEE Transactions on Neural Networks and Learning Systems, 25 , 2303–2308.
49. Tsumoto, S., Kimura, T., Iwata, H., & Hirano, S. (2017). Mining text for disease diagnosis. Procedia Computer Science, 122 , 1133–1140.
50. Wang, J., & Wang, J. (2015). Forecasting stock market indexes using principle component analysis and stochastic time effective neural networks. Neurocomputing, 156 , 68–78.
51. Wang, J. J., Wang, J. Z., Zhang, Z. G., & Guo, S. P. (2012). Stock index forecasting based on a hybrid model. Omega, 40 , 758–766.
52. Wang, L., Yang, Y., Min, R., & Chakradhar, S. (2017). Accelerating deep neural network training with inconsistent stochastic gradient descent. Neural Networks, 93 , 219–229.
53. Wang, Y., & Xu, W. (2018). Leveraging deep learning with lda-based text analytics to detect automobile insurance fraud. Decision Support Systems, 105 , 87–95.
54. Wold, H. (1938). A study in the analysis of stationary time series. Stockholm: Almqvist and Wiksells.
55. Yu, Y., Guan, H., & Ji, Z. (2015). Rotation-invariant object detection in high-resolution satellite imagery using superpixel-based deep hough forests. IEEE Geoscience and Remote Sensing Letters, 12 , 2183–2187.
56. Yule, G. (1926). Why do we sometimes get nonsense correlations between time series? a study in sampling and the nature of time series. Journal of the Royal Statistical Society, 89 , 30–41.
57. Zadeh, L. (1965). Fuzzy sets. Information and Control, 8 , 338–353.
58. Zhang, G. (2003a). Time series forecasting using a hybrid arima and neural network model. Neurocomputing, 50 , 159–175.
59. Zhang, G. P. (2003b). Time series forecasting using a hybrid arima and neural network model. Neurocomputing, 50 , 159–175.
60. Zheng, Y., Lin, Z., & Tay, D. (2001). State-dependent vector hybrid linear and nonlinear arma modeling: Applications. Circuits, Systems and Signal Processing, 20 , 575–597.
2. Arajo, R., Oliveira, A., & Meira, S. (2015). A hybrid model for high-frequency stock market forecasting. Expert Systems with Applications, 42 , 4081–4096.
3. Araujo, R. (2010). A hybrid intelligent morphological approach for stock market forecasting. Neural Processing Letters, 31 , 195–217.
4. Asadi, S., Hadavandi, E., Mehmanpazir, F., & Nakhostin, M. (2012). Hybridization of evolutionary levenbergmarquardt neural networks and data pre-processing for stock market predictionl. Knowledge-Based Systems, 35 , 245–258.
5. Bollerslev, T. (1986). Generalized autoregressive conditional heteroskedasticity. Journal of Econometrics, 31 , 307–327.
6. Box, G., & Jenkins, G. (1970). Time series analysis, forecasting and control. San Francisco: Holden-Day.
7. Brown, R. (2004). Smoothing, forecasting and prediction of discrete time series. Mineola, N.Y.: Courier Dover Publications.
8. Bryson, A., Ho, Y., & Siouris, G. (1979). Applied optimal control: Optimization, estimation, and control. IEEE Transactions on Systems, Man, and Cybernetics, 9 , 366–367.
9. Burges, C. (1998). A tutorial on support vector machines for pattern recognition. Data Mining and Knowledge Discovery, 2 , 121–167.
10. Chang, C. (2015). Deep and shallow architecture of multilayer neural networks. IEEE Transactions on Neural Networks and Learning Systems, 26 , 2477– 2486.
11. Chen, M., & Chen, B. (2015). A hybrid fuzzy time series model based on granular computing for stock price forecasting. Information Sciences, 294 , 227–241.
12. Chen, M., Chen, D. R., Fan, M. H., & Huang, T. Y. (2013). International transmission of stock market movements: an adaptive neuro-fuzzy inference system for analysis of TAIEX forecasting. Neural Computing and Applications, 23 , 369–378.
13. Chen, Y., Cheng, C., & Tsai, W. (2014). Modeling fitting-function-based fuzzy time series patterns for evolving stock index forecasting. Applied Intelligence, 41 , 327–347.
14. Chong, E., Han, C., & Park, F. (2017). Deep learning networks for stock market analysis and prediction: Methodology, data representations, and case studies. Expert Systems with Applications, 83 , 187–205.
15. Coelho, L., Coelho, V., Luz, E., Ochi, L., & Frederico, G. (2017). A gpu deep learning metaheuristic based model for time series forecasting. Applied Energy, 201 , 412–418.
16. D.Ravi, Szczotka, A. B., Shakir, D., Pereira, S., & Vercauteren, T. (2018). Effective deep learning training for single-image super-resolution in endomicroscopy exploiting video-registration-based reconstruction. International Journal of Computer Assisted Radiology and Surgery, 13 , 917–924.
17. Engle, R. (1982). Autoregressive conditional heteroscedasticity with estimates of the variance of united kingdom inflation. Econometrica, 50 , 987–1007.
18. Fang, Y. (2018). Feature selection, deep neural network and trend prediction. Journal of Shanghai Jiaotong University (Science), 23 , 297–307.
19. Freitas, F., de Souza, A., & de Almeida, A. (2009). Prediction-based portfolio optimization using neural networks. Neurocomputing, 72 , 2155–2170.
20. Haykin, S. (1994). Neural networks: A comprehensive foundation. Saddle River: Prentice-Hall.
21. Holland, J. H. (1992). Adaptation in natural and artificial systems: an introductory analysis with applications to biology, control and artificial intelligence. Cambridge, MA, USA: MIT Press.
22. Hsieh, T., Hsiao, H., & Yeh, W. (2011). Forecasting stock markets using wavelet transforms and recurrent neural networks: An integrated system based on artificial bee colony algorithm. Applied Soft Computing, 11 , 2510– 2525.
23. Hsu, V. M. (2013). A hybrid procedure with feature selection for resolving stock/futures price forecasting problems. Neural Computing and Applications, 22 , 651–671.
24. Huang, C., & Tsai, C. (2009). A hybrid sofm-svr with a filter-based feature selection for stock market forecasting. Expert Systems with Applications, 36 , 1529–1539.
25. Huang, X., Sun, J., & Sun, J. (2018). A car-following model considering asymmetric driving behavior based on long short-term memory neural networks. Transportation Research Part C: Emerging Technologies, 95 , 346–362.
26. Kao, L., Chiu, C., Lu, C., & Chang, C. (2013). A hybrid approach by integrating wavelet-based feature extraction with mars and svr for stock index forecasting. Decision Support Systems, 54 , 1228–1244.
27. Kappeler, A., Yoo, S., Dai, Q., & Katsaggelos, A. (2016). Video superresolution with convolutional neural networks. IEEE Transactions on Computational Imaging, 2 , 109–122.
28. Khashei, M., & Bijari, M. (2010). An artificial neural network (p, d, q) model for timeseries forecasting. Expert Systems with Applications, 37 , 479–489.
29. Kim, J., Kim, H., Huh, S., Lee, J., & Choi, K. (2018). Deep neural networks with weighted spikes. Neurocomputing, 311 , 273–386.
30. Kim, K., & Lee, W. (2004). Stock market prediction using artificial neural networks with optimal feature transformation. Neural Computing & Applications, 13 , 255–260.
31. Kim, K. J., & Ahn, H. (2012). Simultaneous optimization of artificial neural networks for financial forecasting. Applied Intelligence, 36 , 887–898.
32. Kim, M., Han, I., & Lee, K. (2004). Hybrid knowledge integration using the fuzzy genetic algorithm: prediction of the korea stock price index. Intelligent Systems in Accounting, Finance and Managemen, 12 , 43–60.
33. Kollias, D., Tagaris, A., Stafylopatis, A., Kollias, S., & Tagaris, G. (2018). Deep neural architectures for prediction in healthcare. Complex & Intelligent Systems, 4 , 119–131.
34. Kraus, M., & Feuerriegel, S. (2017). Decision support from financial disclosures with deep neural networks and transfer learning. Decision Support Systems, 104 , 38–48.
35. Kwon, Y., & Moon, B. (2007). A hybrid neurogenetic approach for stock forecasting. IEEE Transactions on Neural Networks, 18 , 851–864.
36. Lachiheb, O., & Gouider, M. (2018). A hierarchical deep neural network design for stock returns prediction. Procedia Computer Science, 126 , 264–272.
37. Lin, Q., Hong, J., Liu, Z., Li, B., & Wangl, J. (2018). Investigation into the topology optimization for conductive heat transfer based on deep learning approach. International Communications in Heat and Mass Transfer , 97 , 103–109.
38. Liu, D., Wang, Z., Fan, Y., Liu, X., Wang, Z., Chang, S., Wang, X., & Huang, T. (2018). Learning temporal dynamics for video super-resolution: A deep learning approach. IEEE Transactions on Image Processing, 27 , 3432–3445.
39. Lu, C. (2013). Hybridizing nonlinear independent component analysis and support vector regression with particle swarm optimization for stock index forecasting. Neural Computing and Applications, 23 , 2417–2427.
40. McCulloch, W. S., & Pitts, W. (1943). A logical calculus of the ideas immanent in nervous activity. The bulletin of mathematical biophysics, 5 , 115–133.
41. Moghaddam, A., Moghaddam, M., & Esfandyari, M. (2016). Stock market index prediction using artificial neural network. Journal of Economics, Finance and Administrative Science, 21 , 89–93.
42. Pai, P., & Lin, C. (2005). A hybrid arima and support vector machines model in stock price forecasting. Omega, 33 , 497–505.
43. Pathak, A., Pandey, M., & Rautaray, S. (2018). Application of deep learning for object detection. Procedia Computer Science, 132 , 1706–1717.
44. Purushotham, S., Meng, C., Che, Z., & Liu, Y. (2018). Benchmarking deep learning models on large healthcare datasets. Journal of Biomedical Informatics, 83 , 112–134.
45. Rather, A. (2014). A hybrid intelligent method of predicting stock returns. Advances in Artificial Neural Systems, 2014.
46. Rather, A., Agarwal, A., & Sastry, V. (2015). Recurrent neural network and a hybrid model for prediction of stock returns. Expert Systems with Applications, 42 , 3234–3241.
47. Sannino, G., & Pietro, G. (2018). A deep learning approach for ecg-based heartbeat classification for arrhythmia detection. Future Generation Computer Systems, 86 , 446–455.
48. Shao, L., Wu, D., & Li, X. (2014). Learning deep and wide: A spectral method for learning deep networks. IEEE Transactions on Neural Networks and Learning Systems, 25 , 2303–2308.
49. Tsumoto, S., Kimura, T., Iwata, H., & Hirano, S. (2017). Mining text for disease diagnosis. Procedia Computer Science, 122 , 1133–1140.
50. Wang, J., & Wang, J. (2015). Forecasting stock market indexes using principle component analysis and stochastic time effective neural networks. Neurocomputing, 156 , 68–78.
51. Wang, J. J., Wang, J. Z., Zhang, Z. G., & Guo, S. P. (2012). Stock index forecasting based on a hybrid model. Omega, 40 , 758–766.
52. Wang, L., Yang, Y., Min, R., & Chakradhar, S. (2017). Accelerating deep neural network training with inconsistent stochastic gradient descent. Neural Networks, 93 , 219–229.
53. Wang, Y., & Xu, W. (2018). Leveraging deep learning with lda-based text analytics to detect automobile insurance fraud. Decision Support Systems, 105 , 87–95.
54. Wold, H. (1938). A study in the analysis of stationary time series. Stockholm: Almqvist and Wiksells.
55. Yu, Y., Guan, H., & Ji, Z. (2015). Rotation-invariant object detection in high-resolution satellite imagery using superpixel-based deep hough forests. IEEE Geoscience and Remote Sensing Letters, 12 , 2183–2187.
56. Yule, G. (1926). Why do we sometimes get nonsense correlations between time series? a study in sampling and the nature of time series. Journal of the Royal Statistical Society, 89 , 30–41.
57. Zadeh, L. (1965). Fuzzy sets. Information and Control, 8 , 338–353.
58. Zhang, G. (2003a). Time series forecasting using a hybrid arima and neural network model. Neurocomputing, 50 , 159–175.
59. Zhang, G. P. (2003b). Time series forecasting using a hybrid arima and neural network model. Neurocomputing, 50 , 159–175.
60. Zheng, Y., Lin, Z., & Tay, D. (2001). State-dependent vector hybrid linear and nonlinear arma modeling: Applications. Circuits, Systems and Signal Processing, 20 , 575–597.
Copyright © 2021 Akhter Mohiuddin Rather
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