Detection of Potential Audit Doubts Based on Improved Leaders Operator

doi:10.3969/j.issn.10062475.2018.04.015

Abstract

Abstract: Database query method audit doubts discovery relies on the prior knowledge of the auditors, but when the auditors have not enough audit experience and the amount of audit data is huge, it is difficult to take advantage of big data and find the audit doubts from the massive data. And so, in order to solve this problem, a method based on improved Leaders operator and iterative clustering is proposed. In the absence of prior knowledge, Leaders algorithm is used for automatic initial clustering of large audit data, and then, the random sampling fusion method is introduced to optimize the clustering results based on that initial clustering center, finally, the multiple iterative clustering method is used to further find the small clusters with fewer or doubtful instances and thus the accurate clustering of large audit data is achieved. The data clusters with fewer instances or obviously abnormal behavior are identified as potential audit doubts, which can cooperate with audit experience to assist auditors to locate audit doubtful points quickly and accurately. Experimental results verify the effectiveness of the proposed algorithm, and show that the proposed algorithm is helpful to find out the audit doubts from the mass data, narrow the scope of doubts screening and improve the audit efficiency.

Key words: computer aided audit, detection of potential audit doubts, improved Leaders operator, data sampling and fusion, iterative clustering

CLC Number:

TP391

SHAO Jinwei1, LIN Jun2, LIU Yating3, XIAO Jiali4. Detection of Potential Audit Doubts Based on Improved Leaders Operator[J]. Computer and Modernization, 2018, 0(04): 79-.

References

［1］程平,陈珊. 大数据时代基于DBSCAN聚类方法的审计抽样［J］. 中国注册会计师, 2016(4):7679.
［2］卢志茂,冯进玫,范冬梅,等. 面向大数据处理的划分聚类新方法［J］. 系统工程与电子技术, 2014,36(5):10101015.
［3］余晓东,雷英杰,岳韶华,等. 基于粒子群优化的直觉模糊核聚类算法研究［J］. 通信学报, 2015,36(5):7480.
［4］王会金. 中观信息系统审计风险控制体系研究——以COBIT框架与数据挖掘技术相结合为视角［J］. 审计与经济研究, 2012,27(1):1623.
［5］秦志光,王士雨,赵洋,等. 云存储服务的动态数据完整性审计方案［J］. 计算机研究与发展, 2015,52(10):21922199.
［6］秦荣生. 大数据、云计算技术对审计的影响研究［J］. 审计研究, 2014(6):2328.
［7］程平,范珂. 云会计环境下基于COBIT标准的“互联网+审计”模式研究［J］. 财务与会计, 2016(8):5961.
［8］〖JP3〗Ng R T, Han Jiawei. CLARANS: A method for clustering objects for spatial data mining［J］. IEEE Transactions on Knowledge and Data Engineering, 2002,14(5):10031016. 
［9］ Guha S, Rastogi R, Shim K. CURE: An efficient clustering algorithm for large databases［J］. Information Systems, 2001,26(1):3558.
［10］Vijaya P A, Murty M N, Subramanian D K. Leaderssubleaders: An efficient hierarchical clustering algorithm for large data sets［J］. Pattern Recognition Letters, 2004,25(4):505513.
［11］Viswanath P, Babu V S. RoughDBSCAN: A fast hybrid density based clustering method for large data sets［J］. Pattern Recognition Letters, 2009,30(16):14771488.
［12］杨蕴毅,孙中和,卢靖. 基于迭代式聚类的审计疑点发现——以上市公司财报数据为例［J］. 审计研究, 2015(4):6066.
［13］张琼,张莹,白清源,等. 一种新的基于粗糙集的leader聚类算法［J］. 计算机科学, 2008,35(3):177179.
［14］张燕平,张娟,何成刚,等. 基于佳点集与Leader方法的改进Kmeans聚类算法［J］. 计算机应用, 2011,31(5):13591362.
［15］隋玉敏,孙秀芳,武优西,等. 负投影梯度的特征权重Leader聚类算法［J］. 小型微型计算机系统, 2014,35(9):21472150.
［16］李斌,王劲松,黄玮. 一种大数据环境下的新聚类算法［J］. 计算机科学, 2015,42(12):247250.
［17］HPC Lab. Frequent Set Counting［EB/OL］. http://miles.cnuce.cnr.it/~palmeri/datam/DCI/datasets.php, 20130824.

[1]	HE Sida, CHEN Pinghua. Intent-based Lightweight Self-Attention Network for Sequential Recommendation [J]. Computer and Modernization, 2024, 0(12): 1-9.
[2]	ZHENG Jiuchao, ZHAO Xinyuan. Entity Linking Method Based on Topics and Description Information [J]. Computer and Modernization, 2024, 0(12): 10-14.
[3]	ZHAO Chenyang, XUE Tao, LIU Junhua. Fashion Clothing Pattern Generation Based on Improved Stable Diffusion [J]. Computer and Modernization, 2024, 0(12): 15-23.
[4]	HUANG Tingpei1, MA Lubiao1, LI Shibao2, LIU Jianhang1. Gesture Recognition Method Based on WiFi and Prototypical Network [J]. Computer and Modernization, 2024, 0(12): 34-39.
[5]	LIU Yunhai1, Feng Guang1, WU Xiaoting2, YANG Qun2 . Safety Helmet Wearing Detection Algorithm for Complex Construction Scenes [J]. Computer and Modernization, 2024, 0(12): 66-71.
[6]	WANG Yanyuan, MAO Zhengchong. Detection and Recognition Algorithms for Chinese and English Scene Text Images [J]. Computer and Modernization, 2024, 0(12): 84-90.
[7]	ZHANG Kun1, ZHANG Yongwei1, WU Yongcheng1, ZHANG Xiaowen2, ZHAI Shichen2. An LLM-based Method for Automatic Construction of Equipment Failure Knowledge Graphs [J]. Computer and Modernization, 2024, 0(11): 46-53.
[8]	ZHANG Zhixia, QIN Zhiyi. Network Public Opinion Prediction Based on Variational Mode Decomposition and IGJO-SVR [J]. Computer and Modernization, 2024, 0(11): 77-83.
[9]	WAN Hongwei, CHEN Pinghua. Polyp Segmentation Based on Involution and Coordinate Reverse Attention [J]. Computer and Modernization, 2024, 0(11): 84-90.
[10]	ZHANG Yu1, 2, LI Jing1, 2, MA Ming1, 2, WANG Zhongxiang1, 2, SUN Yan1, 2. YOLOLW: A Novel Lightweight Object Detection Model [J]. Computer and Modernization, 2024, 0(11): 91-98.
[11]	DONG Yuwen. Multi-scale Moving Object Detection Algorithm Based on Improved YOLOv7-tiny [J]. Computer and Modernization, 2024, 0(11): 99-105.
[12]	QI Xian, LIU Daming, CHANG Jiaxin. Multi-view 3D Reconstruction Based on Improved Self-attention Mechanism [J]. Computer and Modernization, 2024, 0(11): 106-112.
[13]	CHEN Kai1, LI Yiting1, 2, QUAN Huafeng1. A River Discarded Bottles Detection Method Based on Improved YOLOv8 [J]. Computer and Modernization, 2024, 0(11): 113-120.
[14]	YANG Qingwu, LUO Xiaohui, LIU Xin. Industrial Image Circle Detection Algorithm Based on Edge Drawing [J]. Computer and Modernization, 2024, 0(11): 121-126.
[15]	ZHOU Anda, TANG Chaoying. Semantic Segmentation Algorithm for Rainy Road Scene and Its Mobile Deployment [J]. Computer and Modernization, 2024, 0(10): 7-13.