Enhancing the chimp optimization algorithm to evolve deep LSTMs for accounting profit prediction using adaptive pair reinforced technique

IF 2.7 4区计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Evolving Systems Pub Date : 2023-11-05 DOI:10.1007/s12530-023-09547-4

Chengchen Yang, Tong Wu, Lingzhuo Zeng

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引用次数: 0

Abstract

Abstract Accurately predicting accounting profit (PAP) plays a vital role in financial analysis and decision-making for businesses. The analysis of a business’s financial achievements offers significant insights and aids in the formulation of strategic plans. This research paper focuses on improving the chimp optimization algorithm (CHOA) to evolve deep long short-term memory (LSTM) models specifically for financial accounting profit prediction. The proposed hybrid approach combines CHOA’s global search capabilities with deep LSTMs’ sequential modeling abilities, considering both the global and temporal aspects of financial data to enhance prediction accuracy. To overcome CHOA’s tendency to get stuck in local minima, a novel updating technique called adaptive pair reinforced (APR) is introduced, resulting in APRCHOA. In addition to well-known conventional prediction models, this study develops five deep LSTM-based models, namely conventional deep LSTM, CHOA (deep LSTM-CHOA), adaptive reinforcement-based genetic algorithm (deep LSTM-ARGA), marine predator algorithm (deep LSTM-MPA), and adaptive reinforced whale optimization algorithm (deep LSTM-ARWOA). To comprehensively evaluate their effectiveness, the developed deep LSTM-APRCHOA models are assessed using statistical error metrics, namely root mean square error (RMSE), bias, and Nash–Sutcliffe efficiency (NSEF). In the validation set, at a lead time of 1 h, the NSEF values for LSTM, LSTM-MPA, LSTM-CHOA, LSTM-ARGA, LSTM-ARWOA, and deep LSTM-APRCHOA were 0.9100, 0.9312, 0.9350, 0.9650, 0.9722, and 0.9801, respectively. The results indicate that among these models, deep LSTM-APRCHOA demonstrates the highest accuracy for financial profit prediction.

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利用自适应对增强技术改进黑猩猩优化算法，发展用于会计利润预测的深度lstm

摘要准确预测会计利润在企业财务分析和决策中起着至关重要的作用。对企业财务业绩的分析为制定战略计划提供了重要的见解和帮助。本文的研究重点是改进黑猩猩优化算法(CHOA)，进化出专门用于财务会计利润预测的深度长短期记忆(LSTM)模型。提出的混合方法结合了CHOA的全局搜索能力和深度lstm的顺序建模能力，同时考虑了金融数据的全局和时间方面，以提高预测精度。为了克服局部最小值问题，引入了一种新的自适应对增强(APR)更新技术，得到了自适应对增强(APRCHOA)。除了众所周知的传统预测模型外，本研究还开发了五种基于深度LSTM的模型，即传统的深度LSTM、CHOA (deep LSTM-CHOA)、基于自适应强化的遗传算法(deep LSTM- arga)、海洋捕食者算法(deep LSTM- mpa)和自适应强化鲸鱼优化算法(deep LSTM- arwoa)。为了全面评估其有效性，开发的深度LSTM-APRCHOA模型使用统计误差指标进行评估，即均方根误差(RMSE)，偏差和纳什-萨特克利夫效率(NSEF)。在验证集中，LSTM、LSTM- mpa、LSTM- choa、LSTM- arga、LSTM- arwoa和深度LSTM- aprchoa在提前1 h时的NSEF值分别为0.9100、0.9312、0.9350、0.9650、0.9722和0.9801。结果表明，深度LSTM-APRCHOA模型对财务利润预测的准确率最高。

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来源期刊

Evolving Systems COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-

CiteScore

7.80

自引率

6.20%

发文量

期刊介绍： Evolving Systems covers surveys, methodological, and application-oriented papers in the area of dynamically evolving systems. ‘Evolving systems’ are inspired by the idea of system model evolution in a dynamically changing and evolving environment. In contrast to the standard approach in machine learning, mathematical modelling and related disciplines where the model structure is assumed and fixed a priori and the problem is focused on parametric optimisation, evolving systems allow the model structure to gradually change/evolve. The aim of such continuous or life-long learning and domain adaptation is self-organization. It can adapt to new data patterns, is more suitable for streaming data, transfer learning and can recognise and learn from unknown and unpredictable data patterns. Such properties are critically important for autonomous, robotic systems that continue to learn and adapt after they are being designed (at run time). Evolving Systems solicits publications that address the problems of all aspects of system modelling, clustering, classification, prediction and control in non-stationary, unpredictable environments and describe new methods and approaches for their design. The journal is devoted to the topic of self-developing, self-organised, and evolving systems in its entirety — from systematic methods to case studies and real industrial applications. It covers all aspects of the methodology such as Evolving Systems methodology Evolving Neural Networks and Neuro-fuzzy Systems Evolving Classifiers and Clustering Evolving Controllers and Predictive models Evolving Explainable AI systems Evolving Systems applications but also looking at new paradigms and applications, including medicine, robotics, business, industrial automation, control systems, transportation, communications, environmental monitoring, biomedical systems, security, and electronic services, finance and economics. The common features for all submitted methods and systems are the evolving nature of the systems and the environments. The journal is encompassing contributions related to: 1) Methods of machine learning, AI, computational intelligence and mathematical modelling 2) Inspiration from Nature and Biology, including Neuroscience, Bioinformatics and Molecular biology, Quantum physics 3) Applications in engineering, business, social sciences.