Cognitive superiority of athletic sports expert and its formation mechanisms: A perspective from automaticity and abstraction

doi:10.3724/SP.J.1042.2024.00689

Abstract

Abstract:

At present, the mechanism by which athletic sports expert acquires and transfers, refines and updates their professional knowledge and skills through long-term training has not been clearly elaborated. Based on the expert-novice paradigm, the cognitive superiority of athletic sports expert from the perspective of representation learning is mainly embodied in attention superiority and memory superiority, and the key reasons for the cognitive superiority are the automaticity and abstraction of the knowledge and skills of athletic sports expert. Although the knowledge superiority of competitive sports expert is manifested in both procedural knowledge and declarative knowledge, skill learning is more manifested in the automatic extraction of procedural memory. The characteristics of automaticity and deliberate practice partly explain how athletes extract and update professional knowledge and skills from long-term training, while the abstract representation helps athletes acquire and transfer professional knowledge and skills. Moreover, the abstract representation is not only reflected in the schema stored in the expert’s long-term memory system, but also shows that the expert pay more attention to the overall characteristics of the stimulus information, which has the overall perceptual superiority, such as the memorization of the board by the Go master and the recognition of the stance pattern by the football player.

Then, from the perspective of generative model, the abstract representation mechanism of competitive sports expert’s knowledge and skills is discussed. In particular, the latest research results of Bayesian cognitive model and deep generative model are used for reference, and the mechanism of competitive sports expert’s acquisition and transfer of professional knowledge and skills from long-term training is deeply discussed, so as to construct a more complete competitive sports expert knowledge system. Research based on Bayesian cognitive model shows that the information contained in the motor schema of the expert is more abstract than that of the novice, which is speculated to be because the abstract task representation is conducive to the acquisition and transfer of professional knowledge and skills. The core motor schema stored in the expert memory is reconstructed by deliberate practice under different task rules in order to better match the characteristics of the task, which may help athletes to form high-level special skills closely related to the task rules. As a result, the abstraction of knowledge representation mechanism of athletic sports expert is discussed from the perspective of generative model, which provides a new theoretical basis for understanding the cognitive superiority of athletic sports expert and helping them break through the cognitive limitations.

It is interesting that, from the perspective of feature representation theory, athletes compress the information in similar task situations through long-term training and competition, extract semantic features to construct core motor schema and store them in long-term memory, and then generate specific motor program based on core motor schema in new tasks. From the perspective of prototype theory, if the expected goal is not achieved, the athlete then compares the executed exercise program with the best action example representation in memory according to the feedback execution error, and improves the motor program.

In recent years, with the wide application of neuroscience technology, such as EEG, near infrared, functional magnetic resonance imaging, etc., the research on the cognitive superiority of competitive sports expert has accumulated a lot of cognitive neural evidence, and researchers have also made a lot of active exploration in the embodied cognitive view of motor skill acquisition. To sum up, the existing studies have explored the automaticity characteristics and abstract representation of the knowledge and skills of competitive sports expert from the aspects of cognitive neural evidence and embodied cognition theory. In the future, sports psychologists should make more use of the technical means of neuroscience and the theoretical basis of cognitive psychology to understand the formation mechanism of cognitive superiority of competitive sports expert more deeply and comprehensively.

Key words: knowledge-based system of sports expert, representational learning, automaticity, abstraction, generative model

CLC Number:

B849: G804

CHU Xin-Yu, WANG Ze-Jun. Cognitive superiority of athletic sports expert and its formation mechanisms: A perspective from automaticity and abstraction[J]. Advances in Psychological Science, 2024, 32(4): 689-699.

Figures/Tables 1

References 67

[1]	陈玉田, 陈睿, 李鹏. (2022). 工作记忆中“组块”概念的演化及理论模型. 心理科学进展, 30(12), 2708-2717. doi: 10.3724/SP.J.1042.2022.02708
[2]	程勇民. (2006). 运动水平、知识表征及其年龄对羽毛球竞赛情景中直觉性运动决策的影响. 体育科学, 26(1), 86-95.
[3]	杜建政, 李明. (2006). CLARION模型:内隐与外显技能学习的整合. 心理科学进展, 24(6), 844-850.
[4]	杜鹏飞, 李小勇, 高雅丽. (2021). 多模态视觉语言表征学习研究综述. 软件学报, 32(2), 327-348.
[5]	付全. (2005). 信息量与认知风格对击剑运动员决策速度和准确性的影响. 体育科学, 25(8), 33-38.
[6]	梁宁建. (2014). 当代认知心理学 (修订版). 上海: 上海教育出版社.
[7]	刘扬, 孙彦. (2014). 行为决策中框架效应研究新思路——从风险决策到跨期决策, 从言语框架到图形框架. 心理科学进展, 22(8), 1205-1217. doi: 10.3724/SP.J.1042.2014.01205
[8]	陆颖之, 王小春, 周成林. (2023). 认知神经科学视角下冬奥心理科技攻关服务新体系的构建与应用. 上海体育学院学报, 47(11), 57-67.
[9]	吕慧青, 王进. (2014). 运动技能学习效率的顿悟解释模型探索. 体育科学, 34(4), 30-40.
[10]	孟繁莹, 耿家先, 李安民. (2022). 运动经验对乒乓球运动员无意识加工的影响:来自ERP和行为实验的证据. 中国体育科技, 58(6), 32-40.
[11]	苗浩飞, 迟立忠. (2023). 动作视频游戏专业玩家的认知神经特征. 心理科学进展, 31(1), 127-144. doi: 10.3724/SP.J.1042.2023.00127
[12]	漆昌柱, 贺梦阳, 王浩宇. (2021). 运动专长的记忆痕迹:基于注意竞争优势的脑机制研究. 武汉体育学院学报, 55(2), 68-75.
[13]	任占兵, 胡琳琳, 张远超, 徐敏, 李论雄, 夏丰光, 黄瑞旺. (2019). 运动技能专家脑可塑性研究进展:来自核磁共振成像的证据. 中国体育科技, 55(2), 3-18.
[14]	史鹏, 王国动, 魏征, 孙金月, 章冬杨, 张铎耀. (2023). 足球运动员进攻战术预判决策的视觉搜索特征:空间工作记忆容量的影响. 中国体育科技, 59(5), 27-34.
[15]	孙文芳, 王馨悦, 王长生, 赵明, 王斌. (2018). 专家运动员的视觉搜索特征:基于眼动研究的Meta分析. 天津体育学院学报, 33(4), 321-328.
[16]	王晓莎, 毕彦超. (2019). 抽象概念语义表征的认知神经基础研究. 生理学报, 71(1), 117-126.
[17]	王莹莹, 陆颖之, 杨甜甜, 顾楠, 周成林. (2020). 概念经验对乒乓球运动员动作加工的影响——一项ERP研究. 上海体育学院学报, 44(7), 69-76.
[18]	魏高峡, 李佑发. (2012). 21世纪中国运动心理学的新方向:运动认知神经科学研究. 体育科学, 32(1), 54-63.
[19]	叶浩生. (2021). 身体的意义:从现象学的视角看体育运动的认识论价值. 体育科学, 41(1), 83-88.
[20]	殷融, 叶浩生. (2014). 多元表征假设:概念表征机制的新观点. 心理科学, 37(2), 483-489.
[21]	于志华, 章建成, 黄银华, 李岩峰. (2011). 类比学习与外显学习的不同组合方式对不同性质网球技能学习的影响——从闭锁性和开放性技能的视角. 体育科学, 31(5), 65-74.
[22]	张恩涛, 方杰, 林文毅, 罗俊龙. (2013). 抽象概念表征的具身认知观. 心理科学进展, 21(3), 429-436. doi: 10.3724/SP.J.1042.2013.00429
[23]	张怡, 周成林. (2012). 网球运动员击球线路预判能力及ERP特征研究. 体育科学, 32(12), 24-34.
[24]	赵冰洁, 张琪涵, 陈怡馨, 章鹏, 白学军. (2022). 智力运动专家领域内知觉与记忆的加工特点及其机制. 心理科学进展, 30(9), 1993-2003. doi: 10.3724/SP.J.1042.2022.01993
[25]	赵祁伟, 陆颖之, 周成林. (2020). 新兴技术融合发展下竞技运动心理学研究进展、实践与展望. 上海体育学院学报, 44(11), 18-27.
[26]	周成林, 刘微娜. (2010). 竞技比赛过程中认知优势现象的诠释与思考. 体育科学, 30(10), 13-22.
[27]	Al-Tahan, H., & Mohsenzadeh, Y. (2021). Reconstructing feedback representations in the ventral visual pathway with a generative adversarial autoencoder. PLoS Computational Biology, 17(3), e1008775.
[28]	Bhandari, A., & Badre, D. (2018). Learning and transfer of working memory gating policies. Cognition, 172, 89-100. doi: S0010-0277(17)30303-7 pmid: 29245108
[29]	Bilalić, M. (2017). The neuroscience of expertise. Cambridge, United Kingdom: Cambridge University Press.
[30]	Craik, F. I. M. (2020). Remembering: An activity of mind and brain. Annual Review of Psychology, 71, 1-24. doi: 10.1146/annurev-psych-010419-051027 pmid: 31283427
[31]	Dasgupta, I., & Gershman, S. J. (2021). Memory as a computational resource. Trends in Cognitive Sciences, 25(3), 240-251. doi: 10.1016/j.tics.2020.12.008 pmid: 33454217
[32]	Du, Y., Krakauer, J. W., & Haith, A. M. (2022). The relationships between habits and motor skills in humans. Trends in Cognitive Sciences, 26(5), 371-387. doi: 10.1016/j.tics.2022.02.002 URL
[33]	Ericsson, K. A., Hoffman, R. R., Kozbelt, A., & Williams, A. M. (2018). The Cambridge handbook of expertise and expert performance. Cambridge, United Kingdom: Cambridge University Press.
[34]	Ericsson, K. A., & Kintsch, W. (1995). Long-term working memory. Psychological Review, 102, 211-245. pmid: 7740089
[35]	Ericsson, K. A., Krampe, R. T., & Tesch-Römer, C. (1993). The role of deliberate practice in the acquisition of expert performance. Psychological Review, 100(3), 363-406. doi: 10.1037/0033-295X.100.3.363 URL
[36]	Garner, K. G., & Dux, P. E. (2023). Knowledge generalization and the costs of multitasking. Nature Reviews Neuroscience, 24(2), 98-112. doi: 10.1038/s41583-022-00653-x
[37]	Gershman, S. J. (2019). The generative adversarial brain. Frontiers in Artificial Intelligence, 2, 18. doi: 10.3389/frai.2019.00018 pmid: 33733107
[38]	Gerson, S. A., Meyer, M., Hunnius, S., & Bekkering, H. (2017). Unravelling the contributions of motor experience and conceptual knowledge in action perception: A training study. Scientific Reports, 7, 46761. doi: 10.1038/srep46761 pmid: 28440338
[39]	Gilboa, A., & Marlatte, H. (2017). Neurobiology of schemas and schema-mediated memory. Trends in Cognitive Sciences, 21(8), 618-630. doi: S1364-6613(17)30086-4 pmid: 28551107
[40]	Haith, A. M., & Krakauer, J. W. (2018). The multiple effects of practice: Skill, habit and reduced cognitive load. Current Opinion in Behavioral Sciences, 20, 196-201. doi: 10.1016/j.cobeha.2018.01.015 pmid: 30944847
[41]	Helsen, W. F., Starkes, J. L., & Hodges, N. J. (1998). Team sports and the theory of deliberate practice. Journal of Sport & Exercise Psychology, 20(1), 12-34.
[42]	Ho, M. K., Abel, D., Correa, C. G., Littman, M. L., Cohen, J. D., & Griffiths, T. L. (2022). People construct simplified mental representations to plan. Nature, 606(7912), 129-136. doi: 10.1038/s41586-022-04743-9
[43]	Huys, Q. J. M., Lally, N., Faulkner, P., Eshel, N., Seifritz, E., Gershman, S. J., … Roiser, J. P. (2015). Interplay of approximate planning strategies. Proceedings of the National Academy of Sciences USA, 112(10), 3098-3103. doi: 10.1073/pnas.1414219112 URL
[44]	Jordan, M. I., & Mitchell, T. M. (2015). Machine learning: Trends, perspectives, and prospects. Science, 349(6245), 255-260. doi: 10.1126/science.aaa8415 pmid: 26185243
[45]	Kemp, C., & Tenenbaum, J. B. (2008). The discovery of structural form. Proceedings of the National Academy of Sciences USA, 105(31), 10687-10692. doi: 10.1073/pnas.0802631105 URL
[46]	Kemp, C., & Tenenbaum, J. B. (2009). Structured statistical models of inductive reasoning. Psychological Review, 116(1), 20-58. doi: 10.1037/a0014282 pmid: 19159147
[47]	Krakauer, J. W. (2019). The intelligent reflex. Philosophical Psychology, 32(5), 823-831. doi: 10.1080/09515089.2019.1607281
[48]	Lake, B. M., Salakhutdinov, R., & Tenenbaum, J. B. (2015). Human-level concept learning through probabilistic program induction. Science, 350(6266), 1332-1338. doi: 10.1126/science.aab3050 pmid: 26659050
[49]	Lake, B. M., Ullman, T. D., Tenenbaum, J. B., & Gershman, S. J. (2017). Building machines that learn and think like people. Behavioral & Brain Sciences, 40, e253.
[50]	Lansdell, B. J., & Kording, K. P. (2019). Towards learning- to-learn. Current Opinion in Behavioral Sciences, 29, 45-50. doi: 10.1016/j.cobeha.2019.04.005 URL
[51]	LeCun, Y., Bengio, Y., & Hinton, G. (2015). Deep learning. Nature, 521(7553), 436-444. doi: 10.1038/nature14539
[52]	Macnamara, B. N., Hambrick, D. Z., & Oswald, F. L. (2014). Deliberate practice and performance in music, games, sports, education, and professions: A meta-analysis. Psychological Science, 25(8), 1608-1618. doi: 10.1177/0956797614535810 pmid: 24986855
[53]	Macnamara, B. N., Moreau, D., & Hambrick, D. Z. (2016). The relationship between deliberate practice and performance in sports: A meta-analysis. Perspectives on Psychological Science, 11(3), 333-350. doi: 10.1177/1745691616635591 pmid: 27217246
[54]	Mattar, M. G., & Lengyel, M. (2022). Planning in the brain. Neuron, 110(6), 914-934. doi: 10.1016/j.neuron.2021.12.018 pmid: 35041804
[55]	McClelland, J. L. (2022). Capturing advanced human cognitive abilities with deep neural networks. Trends in Cognitive Sciences, 26(12), 1047-1050. doi: 10.1016/j.tics.2022.09.018 pmid: 36335015
[56]	Myers, N. E., Stokes, M. G., & Nobre, A. C. (2017). Prioritizing information during working memory: Beyond sustained internal attention. Trends in Cognitive Sciences, 21(6), 449-461. doi: S1364-6613(17)30053-0 pmid: 28454719
[57]	Pulvermüller, F. (2005). Brain mechanisms linking language and action. Nature Reviews of Neuroscience, 6(7), 576-582. doi: 10.1038/nrn1706
[58]	Radulescu, A., Niv, Y., & Ballard, I. (2019). Holistic reinforcement learning: The role of structure and attention. Trends in Cognitive Sciences, 23(4), 278-292. doi: S1364-6613(19)30036-1 pmid: 30824227
[59]	Radulescu, A., Shin, Y. S., & Niv, Y. (2021). Human representation learning. Annual Review of Neuroscience, 44, 253-273. doi: 10.1146/annurev-neuro-092920-120559 pmid: 33730510
[60]	Sabah, K., Meiran, N., & Dreisbach, G. (2021). Examining the trainability and transferability of working-memory gating policies. Journal of Cognitive Enhancement, 5, 330-342. doi: 10.1007/s41465-021-00205-8
[61]	Tenenbaum, J. B., Kemp, C., Griffiths, T. L., & Goodman, N. D. (2011). How to grow a mind: Statistics, structure, and abstraction. Science, 331(6022), 1279-1285.
[62]	Tsetsos, K. (2023). Unlocking a new dimension in the speed-accuracy trade-off. Trends in Cognitive Sciences, 27(6), 510-511. doi: 10.1016/j.tics.2023.03.005 URL
[63]	Vaidya, A. R., & Badre, D. (2022). Abstract task representations for inference and control. Trends in Cognitive Sciences, 26(6), 484-498. doi: 10.1016/j.tics.2022.03.009 pmid: 35469725
[64]	Ward, P., Hodges, N. J., Starkes, J. L., & Williams, M. A. (2007). The road to excellence: Deliberate practice and the development of expertise. High Ability Studies, 18(2), 119-153. doi: 10.1080/13598130701709715 URL
[65]	Williams, A. M., & Ford, P. R. (2008). Expertise and expert performance in sport. International Review of Sport & Exercise Psychology, 1(1), 4-18.
[66]	Yamins, D. L. K., & DiCarlo, J. J. (2016). Using goal-driven deep learning models to understand sensory cortex. Nature Neuroscience, 19(3), 356-365. doi: 10.1038/nn.4244 pmid: 26906502
[67]	Yarrow, K., Brown, P., & Krakauer, J. W. (2009). Inside the brain of an elite athlete: The neural processes that support high achievement in sports. Nature Reviews of Neuroscience, 10(8), 585-596. doi: 10.1038/nrn2672