An economic analysis of false alarms and no fault found events in air vehicles

2016 IEEE AUTOTESTCON Pub Date : 2016-09-01 DOI:10.1109/AUTEST.2016.7589571

M. Ilarslan, L. Ungar, Kenan Ilarslan

{"title":"An economic analysis of false alarms and no fault found events in air vehicles","authors":"M. Ilarslan, L. Ungar, Kenan Ilarslan","doi":"10.1109/AUTEST.2016.7589571","DOIUrl":null,"url":null,"abstract":"False Alarms (FAs) that occur in a fielded system and No Fault Found (NFF) events that are discovered after line replaceable units (LRUs) have been returned to repair are costly situations whose full impact is difficult to put into monetary terms. For that reason, pragmatic economic models of NFFs are difficult to develop. In this paper, we deal with the problem of having to differentiate between NFFs of good units under test (UUTs) and of faulty UUTs. While we cannot tell which UUT is good and which is faulty, we can determine using probabilities what percentage of the NFFs are faulty and what percentage are good. Based on these probabilities, we can evaluate various strategies. Assigning cost factors that are knowable, such as the cost of testing a UUT, the cost we incur for good UUTs vs. costs we incur for faulty UUTs and various test and repair costs, we can calculate the performance of various strategies and assumptions. In this paper, we formulate three strategies: 1) We assume all NFF UUTs are good and are willing to endure the cost of bad actors (i.e. faulty UUTs) sent back to the aircraft. 2) We assume all NFF UUTs are faulty and we environmentally stress all NFF UUTs, hoping to fix some and avoid bad actors. 3) We rely on the technician to reasonably select some NFF UUTs and perform appropriate repair. We formulate each of these strategies for a case when NFF is 70%. The formulation is similar with any NFF distribution, but the coefficients in each formula will be different. With proper cost data, we can actually decide which strategy works best. We conclude by tabulating the formulas and calculate NFF costs for an example situation. The numbers we picked for this example may be appropriate for some operations, but not for others. As a follow-up to this paper we would like to validate the model with real data, which may be available in some military and commercial avionics maintenance departments.","PeriodicalId":314357,"journal":{"name":"2016 IEEE AUTOTESTCON","volume":"6 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2016-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"4","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"2016 IEEE AUTOTESTCON","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1109/AUTEST.2016.7589571","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 4

Abstract

False Alarms (FAs) that occur in a fielded system and No Fault Found (NFF) events that are discovered after line replaceable units (LRUs) have been returned to repair are costly situations whose full impact is difficult to put into monetary terms. For that reason, pragmatic economic models of NFFs are difficult to develop. In this paper, we deal with the problem of having to differentiate between NFFs of good units under test (UUTs) and of faulty UUTs. While we cannot tell which UUT is good and which is faulty, we can determine using probabilities what percentage of the NFFs are faulty and what percentage are good. Based on these probabilities, we can evaluate various strategies. Assigning cost factors that are knowable, such as the cost of testing a UUT, the cost we incur for good UUTs vs. costs we incur for faulty UUTs and various test and repair costs, we can calculate the performance of various strategies and assumptions. In this paper, we formulate three strategies: 1) We assume all NFF UUTs are good and are willing to endure the cost of bad actors (i.e. faulty UUTs) sent back to the aircraft. 2) We assume all NFF UUTs are faulty and we environmentally stress all NFF UUTs, hoping to fix some and avoid bad actors. 3) We rely on the technician to reasonably select some NFF UUTs and perform appropriate repair. We formulate each of these strategies for a case when NFF is 70%. The formulation is similar with any NFF distribution, but the coefficients in each formula will be different. With proper cost data, we can actually decide which strategy works best. We conclude by tabulating the formulas and calculate NFF costs for an example situation. The numbers we picked for this example may be appropriate for some operations, but not for others. As a follow-up to this paper we would like to validate the model with real data, which may be available in some military and commercial avionics maintenance departments.

查看原文本刊更多论文

对飞行器误报和无故障事件的经济分析

在现场系统中发生的假警报(FAs)和在线路可更换单元(lru)返回维修后发现的无故障发现(NFF)事件都是代价高昂的情况，其全部影响难以用货币来衡量。因此，NFFs的实用经济模型很难建立。在本文中，我们处理了必须区分良好被测单元(uut)和故障被测单元的nff的问题。虽然我们无法分辨哪个UUT是好的，哪个是有缺陷的，但我们可以使用概率来确定nff有缺陷的百分比和良好的百分比。基于这些概率，我们可以评估各种策略。分配已知的成本因素，例如测试UUT的成本，我们为良好的UUT所产生的成本与我们为有缺陷的UUT所产生的成本以及各种测试和修复成本，我们可以计算各种策略和假设的性能。在本文中，我们制定了三种策略:1)我们假设所有的NFF uut都是好的，并且愿意忍受坏角色(即有故障的uut)送回飞机的成本。2)我们假设所有的NFF uut都是有缺陷的，我们对所有的NFF uut进行环境压力，希望修复一些并避免不良行为者。3)我们依靠技术人员合理选择一些NFF uut并进行适当的维修。我们在NFF为70%的情况下制定这些策略。公式与任何NFF分布相似，但每个公式中的系数会有所不同。有了适当的成本数据，我们就可以决定哪种策略最有效。最后，我们将公式制成表格，并计算一个示例情况下的NFF成本。我们为本例选择的数字可能适合某些操作，但不适合其他操作。作为本文的后续工作，我们希望用实际数据对模型进行验证，这些数据可能在一些军用和商用航空电子设备维修部门可用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

2016 IEEE AUTOTESTCON

自引率

0.00%

发文量