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English Information

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Authors
# Name
1 Marta Noronha(martadmnoronha@gmail.com)
2 Luis Enrique Zarate(zarate@pucminas.br)

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Reference
# Reference
1 Bowen, C. Brown’s stages of syntactic and morphological development. www.speech-languagetherapy.com/index.php?option=com_content &view=article&id=33, 1998.
2 Busygin, S., Prokopyev, O., and Pardalos, P. Feature selection for consistent biclustering via fractional 0-1 programming. Journal of combinatorial optimization 10 (1): 7–21, 2005.
3 Cheng, Y. and Church, G. M. Biclustering of expression data. In Proceedings of the Eighth International Conference on Intelligent Systems for Molecular Biology. AAAI Press, California, USA, pp. 93–103, 2000.
4 Eren, K., Deveci, M., Küçüktunç, O., and Çatalyürek, Ü. V. A comparative analysis of biclustering algorithms for gene expression data. Briefings in bioinformatics 14 (3): 279–292, 2012.
5 Gabani, K., Solorio, T., Liu, Y., Hassanali, K.-n., and Dollaghan, C. A. Exploring a corpus-based approach for detecting language impairment in monolingual english-speaking children. Artificial Intelligence in Medicine 53 (3): 161–170, 2011.
6 Gillam, R. B., Cowan, N., and Marler, J. A. Information processing by school-age children with specific language impairment: Evidence from a modality effect paradigm. Journal of Speech, Language, and Hearing Research 41 (4): 913–926, 1998.
7 Hayward, D., Schneider, P., and Gillam, R. B. Age and task-related effects on young children’s understanding of a complex picture story. Alberta Journal of Educational Research 55 (1): 54–72, 2009.
8 Hinneburg, A., Aggarwal, C. C., and Keim, D. A. What is the nearest neighbor in high dimensional spaces? In Proceedings of the 26th International Conference on Very Large Data Bases. VLDB ’00. Morgan Kaufmann Publishers Inc., San Francisco, CA, USA, pp. 506–515, 2000.
9 Huang, G., Cheng, A., and Gao, Y. Machine learning improvements to the accuracy of predicting specific language impairment. In 2022 International Conference on Image Processing, Computer Vision and Machine Learning (ICICML). IEEE, Xi’an, China, pp. 553–566, 2022.
10 Huang, Q., Jin, L., and Tao, D. An unsupervised feature ranking scheme by discovering biclusters. In 2009 IEEE International Conference on Systems, Man and Cybernetics. IEEE, San Antonio, TX, USA, pp. 4970–4975, 2009.
11 Madeira, S. C. and Oliveira, A. L. Biclustering algorithms for biological data analysis: A survey. IEEE/ACM Trans. Comput. Biol. Bioinformatics 1 (1): 24–45, Jan., 2004.
12 Noronha, M. D., Henriques, R., Madeira, S. C., and Zárate, L. E. Impact of metrics on biclustering solution and quality: A review. Pattern Recognition vol. 127, pp. 108612, 2022.
13 Sharma, Y. and Singh, B. K. One-dimensional convolutional neural network and hybrid deep-learning paradigm for classification of specific language impaired children using their speech. Computer Methods and Programs in Biomedicine vol. 213, pp. 106487, 2022.
14 Zhao, H., Liew, A., Wang, D., and Yan, H. Biclustering analysis for pattern discovery: Current techniques, comparative studies and applications. Current Bioinformatics 7 (1): 43–55, 3, 2012.