Neuroevolution is one of the methodologies that can be used for learning optimal architecture during training. It uses evolutionary algorithms to generate the topology of artificial neural networks and its parameters. The main benefits are that it is scalable and can be fully or partially non gradient method. In this work, a modified neuroevolution technique is presented which incorporates multi-level optimisation. The presented approach adapts evolution strategies for evolving an ensemble model based on the bagging technique, using genetic operators for optimising single anomaly detection models, reducing the training dataset to speedup the search process and perform non-gradient fine tuning. Multivariate anomaly detection as an unsupervised learning task is the case study upon which the presented approach is tested. Single model optimisation is based on mutation and crossover operators and is focused on finding optimal window sizes, the number of layers, layer depths, hyperparameters etc. to boost the anomaly detection scores of new and already known models. The proposed framework and its protocol shows that it is possible to find architecture within a reasonable time frame which can boost all well known multivariate anomaly detection deep learning architectures. The work concentrates on improvements to the multi-level neuroevolution approach for anomaly detection. The main modifications are in the methods of mixing groups and single model evolution, non-gradient fine tuning and a voting mechanism. The presented framework can be used as an efficient learning network architecture method for any different unsupervised task where autoencoder architectures can be used. The tests were run on SWAT, WADI, MSL and SMAP datasets and the presented approach evolved the architectures that achieved the best scores among other deep learning models.
翻译:神经进化是用于在培训期间学习最佳架构的方法之一。 它使用进化算法来生成人工神经网络及其参数的表层学。 主要的好处是,它可以伸缩,可以完全或部分采用非梯度方法。 在这项工作中, 介绍了一个修改的神经进化技术, 其中包括多层次优化。 所介绍的方法调整进化战略, 以开发基于包装技术的混合模型, 使用基因操作器优化单一异常检测模型, 减少培训数据集以加快搜索进程并进行非梯度微调。 多变异异常检测作为非超常学习任务, 是测试所介绍的方法的案例研究。 单一模型优化的神经进化技术基于突变和交叉操作操作, 重点是寻找最佳窗口大小、 层数、 层深度、 超光度计等, 来提高新和已知模型的异常检测分数。 拟议的框架及其协议表明, 在合理的时间框架内找到结构, 能够推进所有已知的多变异性异常的异常异常异常现象检测, 用于进行多变动的系统测试。 用于进行最佳的多变换的系统测试。 最佳的系统, 用于进行系统, 最佳的演化, 最佳的演算方法是用来进行。