Performance Evaluation of Training Algorithms in Backpropagation Neural Network Approach to Blast-Induced Ground Vibration Prediction

Clement Kweku Arthur, V. Temeng, Y. Ziggah
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引用次数: 17

Abstract

Abstract Backpropagation Neural Network (BPNN) is an artificial intelligence technique that has seen several applications in many fields of science and engineering. It is well-known that, the critical task in developing an effective and accurate BPNN model depends on an appropriate training algorithm, transfer function, number of hidden layers and number of hidden neurons. Despite the numerous contributing factors for the development of a BPNN model, training algorithm is key in achieving optimum BPNN model performance. This study is focused on evaluating and comparing the performance of 13 training algorithms in BPNN for the prediction of blast-induced ground vibration. The training algorithms considered include: Levenberg-Marquardt, Bayesian Regularisation, Broyden–Fletcher–Goldfarb–Shanno (BFGS) Quasi-Newton, Resilient Backpropagation, Scaled Conjugate Gradient, Conjugate Gradient with Powell/Beale Restarts, Fletcher-Powell Conjugate Gradient, Polak-Ribiere Conjugate Gradient, One Step Secant, Gradient Descent with Adaptive Learning Rate, Gradient Descent with Momentum, Gradient Descent, and Gradient Descent with Momentum and Adaptive Learning Rate. Using ranking values for the performance indicators of Mean Squared Error (MSE), correlation coefficient (R), number of training epoch (iteration) and the duration for convergence, the performance of the various training algorithms used to build the BPNN models were evaluated. The obtained overall ranking results showed that the BFGS Quasi-Newton algorithm outperformed the other training algorithms even though the Levenberg Marquardt algorithm was found to have the best computational speed and utilised the smallest number of epochs.   Keywords: Artificial Intelligence, Blast-induced Ground Vibration, Backpropagation Training Algorithms
爆炸诱发地面振动的反向传播神经网络训练算法性能评价
摘要:反向传播神经网络(BPNN)是一种人工智能技术,在许多科学和工程领域都有广泛的应用。众所周知,建立有效而准确的bp神经网络模型的关键在于合适的训练算法、传递函数、隐藏层数和隐藏神经元数。尽管影响bp神经网络模型发展的因素很多,但训练算法是实现最佳bp神经网络模型性能的关键。本文主要对13种训练算法在bp神经网络爆炸诱发地面振动预测中的性能进行了评价和比较。考虑的训练算法包括:Levenberg-Marquardt、贝叶斯正则化、Broyden-Fletcher-Goldfarb-Shanno (BFGS)准牛顿、弹性反向传播、缩放共轭梯度、Powell/Beale重新开始的共轭梯度、Fletcher-Powell共轭梯度、polakr - ribiere共轭梯度、一步切线、自适应学习率梯度下降、动量梯度下降、动量和自适应学习率梯度下降。利用均方误差(MSE)、相关系数(R)、训练历元数(迭代)和收敛时间等性能指标的排序值,对用于构建BPNN模型的各种训练算法的性能进行了评价。得到的综合排名结果表明,尽管Levenberg Marquardt算法具有最好的计算速度和最少的epoch数,但BFGS准牛顿算法优于其他训练算法。关键词:人工智能,爆炸诱发地面振动,反向传播训练算法
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