Please wait a minute...
浙江大学学报(工学版)
浙江大学学报(工学版)  2022, Vol. 56 Issue (12): 2367-2378    DOI: 10.3785/j.issn.1008-973X.2022.12.006
机械工程     
基于单值中智集和云聚类的产品造型设计决策方法
裴卉宁1(),谭昭芸1,刘鑫宇1,田保珍2
1. 河北工业大学 建筑与艺术设计学院,天津 300401
2. 太原科技大学 机械工程学院,山西 太原 030027
Decision method for product styling design based on single-valued neutrosophic sets and cloud clustering
Hui-ning PEI1(),Zhao-yun TAN1,Xin-yu LIU1,Bao-zhen TIAN2
1. School of Architecture and Art Design, Hebei University of Technology, Tianjin 300401, China
2. School of Mechanical Engineering, Taiyuan University of Science and Technology, Taiyuan 030027, China
 全文: PDF(1464 KB)   HTML
摘要:

为了获得客观、合理的权重分配,综合考虑有限理性心理行为特征和策略操控行为,把决策专家进行科学聚类,提出基于单值中智集(SVNS)和云模型聚类的产品造型设计多属性决策方法. 决策专家构造标准属性和备选方案的成对比较比率平方矩阵获得SVNS,映射真、假、不确定3个隶属度值到单值中智立方体(SVNC)中,筛选各标准属性下备选方案的评估结果,获得标准属性的相对权重. 利用融合多粒度语言的云模型聚类方法集群决策专家,淘汰存在冲突和非理性的决策专家,获得有效的设计决策专家权重. 由标准属性权重和决策专家权重,综合计算各备选方案的总体优先级得分并进行排序. 以汽车造型设计方案为例,验证所提方法的可行性和有效性. 结果表明,所提方法避免了恶意策略操作,有效地解决了复杂和不确定情况下的汽车造型设计多属性决策问题.
关键词: 产品造型设计单值中智集(SVNS)云模型聚类多属性决策多粒度语言    
Abstract:

A multi-attribute decision method for product styling design based on single-valued neutrosophic sets (SVNS) and cloud model clustering was proposed, in order to obtain an objective and reasonable weight distribution. Decision-making experts were scientifically clustered, considering the limited rational psychological behavior characteristics and strategic manipulation behaviors. The square matrix of the pairwise comparison ratios of the standard attributes and the alternatives was constructed by the decision-making experts to obtain the SVNS. Mapping the three membership values of true, false, and uncertain in the single-valued neutrosophic cube (SVNC), the relative weight of the standard attributes was obtained by screening the evaluation results of the alternatives under each standard attribute. The cloud model clustering method fused with multi-granularity language was used to cluster decision-making experts, conflicting and unreasonable decision-making experts were eliminated to obtain effective design decision-making expert weights. The overall priority score of each alternative was calculated and sorted through the standard attribute weights and the weights of decision-making experts. The feasibility and effectiveness of the proposed method was verified by an example of car styling design scheme. Results show that using the proposed method, dishonest strategic manipulation is avoided and the multiple attribute decision making problem for car styling design in complex and uncertain situations is effectively solved.
Key words: product styling design    single-valued neutrosophic sets (SVNS)    cloud model clustering    multiple attribute decision making    multi-granularity language
收稿日期: 2021-12-29 出版日期: 2023-01-03
CLC:  C 934  
基金资助: 教育部人文社会科学基金资助项目(21YJCZH113);河北省高等学校科学研究资助项目(SD201091)
作者简介: 裴卉宁(1986—),女,讲师,博士,从事认知工效学、智能设计研究. orcid.org/0000-0002-4741-7175. E-mail: peihuining@hebut.edu.cn
服务  
把本文推荐给朋友
加入引用管理器
E-mail Alert
作者相关文章  
裴卉宁
谭昭芸
刘鑫宇
田保珍

引用本文:

裴卉宁,谭昭芸,刘鑫宇,田保珍. 基于单值中智集和云聚类的产品造型设计决策方法[J]. 浙江大学学报(工学版), 2022, 56(12): 2367-2378.

Hui-ning PEI,Zhao-yun TAN,Xin-yu LIU,Bao-zhen TIAN. Decision method for product styling design based on single-valued neutrosophic sets and cloud clustering. Journal of ZheJiang University (Engineering Science), 2022, 56(12): 2367-2378.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2022.12.006        https://www.zjujournals.com/eng/CN/Y2022/V56/I12/2367

图 1  基于单值中智集(SVNS)的产品造型设计多属性决策框架
图 2  单值中智集(SVNC)空间划分
图 3  基于云模型聚类的决策专家权重分配框架
图 4  汽车前视图造型设计方案
图 5  汽车前视图造型设计方案的评估标准图例
A $x_i^{(j,m)} / x_l^{(j,m)}$
A1 A2 A3 A4 A5 A6
A1 1 1/5 3 1/2 1/3 4
A2 5 1 7 3 2 9
A3 1/3 1/7 1 1/3 1/5 1/2
A4 2 1/3 3 1 1/2 5
A5 3 1/2 5 2 1 6
A6 1/4 1/9 2 1/5 1/6 1
表 1  备选方案成对比较比率平方矩阵
${D_{\rm{M}}}$ $x_1^m, S_1^m$ $x_2^m, S_2^m$ $x_3^m, S_3^m$ $x_4^m, S_4^m$ $x_5^m, S_5^m$ $x_6^m, S_6^m$ $x_7^m, S_7^m$ $x_8^m, S_8^m$ ${\text{C} }{\text{.r} }.\left( {{\boldsymbol{R}}_{J \times J}^m} \right)$/%
$D_{\rm{M}}^1$ 0.028 3, 90 0.158 8, 85 0.041 8, 100 0.020 4, 80 0.330 6, 100 0.250 9, 95 0.070 4, 85 0.098 9, 90 3.46
$D_{\rm{M}}^2$ 0.067 7, 100 0.153 1, 85 0.030 7, 80 0.022 2, 95 0.345 9, 100 0.231 8, 90 0.045 6, 100 0.103 0, 85 2.49
$D_{\rm{M}}^3$ 0.066 7, 85 0.173 8, 75 0.029 9, 80 0.022 3, 70 0.358 8, 85 0.218 3, 70 0.043 4, 90 0.086 8, 75 5.61
$D_{\rm{M}}^4$ 0.067 1, 85 0.108 3, 90 0.019 7, 80 0.027 8, 90 0.349 2, 85 0.230 2, 75 0.047 1, 95 0.150 6, 95 4.10
$D_{\rm{M}}^6$ 0.063 8, 75 0.106 7, 80 0.018 9, 70 0.028 9, 85 0.359 5, 80 0.225 8, 70 0.048 7, 90 0.147 6, 90 5.20
$\vdots $ $\vdots $ $\vdots $ $\vdots $ $\vdots $ $\vdots $ $\vdots $ $\vdots $ $\vdots $ $\vdots $
$D_{\rm{M}}^{20}$ 0.068 5, 100 0.148 1, 80 0.030 6, 75 0.021 0, 95 0.367 1, 90 0.221 9, 85 0.044 5, 100 0.098 4, 90 3.15
表 2  各决策专家对各标准的权重、一致性比率和置信度得分
$B$ $x_1^{\left( {j, 1} \right)}, S_1^{\left( {j, 1} \right)}$ $x_2^{\left( {j, 1} \right)}, S_2^{\left( {j, 1} \right)}$ $x_3^{\left( {j, 1} \right)}, S_3^{\left( {j, 1} \right)}$ $x_4^{\left( {j, 1} \right)}, S_4^{\left( {j, 1} \right)}$ $x_5^{\left( {j, 1} \right)}, S_5^{\left( {j, 1} \right)}$ $x_6^{\left( {j, 1} \right)}, S_6^{\left( {j, 1} \right)}$ ${\text{C} }{\text{.r} }.\left( {{\boldsymbol{R}}_{J \times J}^1} \right)$/%
B1 0.102 5, 100 0.413 2, 95 0.050 6, 80 0.152 8, 85 0.247 9, 100 0.032 9, 90 1.99
B2 0.095 5, 85 0.410 6, 65 0.049 1, 45 0.150 5, 60 0.254 6, 75 0.039 6, 75 5.13
B3 0.087 8, 85 0.424 0, 80 0.051 7, 85 0.143 8, 95 0.255 4, 65 0.037 3, 100 3.28
B4 0.096 4, 80 0.411 9, 85 0.049 6, 75 0.145 1, 80 0.255 9, 70 0.041 1, 75 4.96
B5 0.100 8, 95 0.425 6, 100 0.039 1, 90 0.138 4, 85 0.253 7, 95 0.042 5, 70 3.46
B6 0.090 8, 60 0.432 0, 65 0.047 0, 85 0.136 2, 75 0.255 6, 50 0.038 5, 45 7.32
B7 0.096 1, 65 0.424 6, 70 0.049 4, 65 0.142 2, 60 0.255 5, 75 0.032 3, 80 2.76
B8 0.096 3, 85 0.418 4, 100 0.049 4, 80 0.151 5, 90 0.251 2, 60 0.033 2, 85 1.54
表 3  决策专家 $D_{\rm{M}}^1$对各备选方案在各标准下的一致性比率和置信度得分
图 6  单值中智集空间映射
B ${\psi ^ * }_i^j$
A1 A2 A3 A4 A5 A6
B1 0.101 2 0.370 5 0.034 5 0.173 6 0.264 9 0.069 5
B2 0.100 3 0.367 3 0.034 9 0.175 5 0.264 7 0.069 9
B3 0.100 7 0.364 0 0.036 0 0.178 0 0.268 3 0.068 6
B4 0.111 0 0.357 5 0.035 0 0.166 4 0.268 6 0.064 5
B5 0.106 1 0.364 2 0.034 4 0.138 4 0.261 2 0.071 6
B6 0.103 4 0.355 7 0.033 9 0.175 1 0.274 9 0.071 9
B7 0.105 6 0.367 3 0.034 1 0.166 9 0.264 0 0.070 6
B8 0.105 7 0.365 4 0.035 3 0.171 3 0.263 2 0.069 4
$ x_i^G $ 0.104 3 0.363 2 0.034 5 0.161 4 0.265 9 0.070 7
表 4  所有备选方案在各标准下的总体优先级得分
A hxy
$ {A_1} $ $ {A_2} $ $ {A_3} $
A1 0.5 0.4, 0.3, 0.5 0.5, 0.6, 0.7
A2 0.6, 0.7, 0.5 0.5 0.7, 0.8, 0.9
A3 0.5, 0.4, 0.3 0.3, 0.2, 0.1 0.5
A4 0.5, 0.6, 0.7 0.2, 0.3, 0.4 0.5, 0.8, 0.7
A5 0.6, 0.8, 0.5 0.3, 0.4, 0.5 0.7, 0.8, 0.9
A6 0.3, 0.2, 0.4 0.1, 0.3, 0.2 0.4, 0.2, 0.3
表 5  决策专家 $ D_M^1 $的部分原始犹豫模糊偏好关系数据
${D_{\rm{M}}}$ $O\left( {{\boldsymbol{R}}_1^{ {H_\gamma } } } \right)$ $O\left( {{\boldsymbol{R}}_2^{ {H_\gamma } } } \right)$ $O\left( {{\boldsymbol{R}}_3^{ {H_\gamma } } } \right)$ $ {\vartheta _\gamma } $ $D_{\rm{L}}^\gamma$ $r$
$D_{\rm{M}}^1$ 0 ?0.333 0 1 0.049 0.071
$D_{\rm{M}}^2$ 0 0 0 0 0.052 0.068
$D_{\rm{M}}^3$ 0 0 ?1 1 0.056 0.064
$D_{\rm{M}}^4$ 0 ?1.333 0 1 0.071 0.049
$\vdots $ $\vdots $ $\vdots $ $\vdots $ $\vdots $ $\vdots $ $\vdots $
$D_{\rm{M}}^{20}$ 0 0 ?0.667 1 0.042 0.078
表 6  决策专家的意见可靠性推导值
B $g_i^l $
A1 A2 A3 A4 A5 A6
$ {B_1} $ $ g_3^3 $ $ g_5^3 $ $ g_2^3 $ $ g_4^3 $ $ g_4^3 $ $ g_2^3 $
$ {B_2} $ $ g_6^3 $ $ g_7^3 $ $ g_6^3 $ $ g_7^3 $ $ g_7^3 $ $ g_5^3 $
$ {B_3} $ $ g_4^3 $ $ g_5^3 $ $ g_4^3 $ $ g_5^3 $ $ g_5^3 $ $ g_3^3 $
$ {B_4} $ $ g_2^3 $ $ g_4^3 $ $ g_1^3 $ $ g_3^3 $ $ g_3^3 $ $ g_0^3 $
$ {B_5} $ $ g_7^3 $ $ g_8^3 $ $ g_7^3 $ $ g_8^3 $ $ g_8^3 $ $ g_7^3 $
$ {B_6} $ $ g_7^3 $ $ g_8^3 $ $ g_6^3 $ $ g_7^3 $ $ g_8^3 $ $ g_6^3 $
$ {B_7} $ $ g_5^3 $ $ g_6^3 $ $ g_4^3 $ $ g_5^3 $ $ g_6^3 $ $ g_4^3 $
$ {B_8} $ $ g_5^3 $ $ g_7^3 $ $ g_5^3 $ $ g_6^3 $ $ g_6^3 $ $ g_4^3 $
表 7  决策专家对各备选方案在各标准下决策专家的云模型数据
A ${\boldsymbol{R}}$ $t_{xy}^c $
$ {A_1} $ $ {A_2} $ $ {A_3} $ $ {A_4} $ $ {A_5} $ $ {A_6} $
$ {A_1} $ R1 0.128 0 0.162 7 0.097 2 0.139 2 0.170 1 0.093 2
R2 0 0.181 4 0.075 2 0.150 1 0.160 4 0.086 3
R3 0 0.164 2 0.092 5 0.151 5 0.171 3 0.096 1
$\vdots$
$ {A_6} $ R1 0.162 8 0.184 6 0.109 4 0.156 2 0.174 0 0.128 0
R2 0.169 6 0.187 0 0.116 1 0.148 7 0.156 4 0
R3 0.159 9 0.189 2 0.111 0 0.146 3 0.172 1 0
表 8  3个模糊偏好关系下的群决策矩阵
图 7  不同决策方法的总体得分结果对比图
决策方法 e/% t/min
4个备选方案 6个备选方案 4个备选方案 6个备选方案
本研究 4.82 6.91 1.37 1.91
SVNS 5.07 9.30 1.19 1.75
VIKOR 11.13 18.62 0.53 0.84
BWM 12.29 20.46 0.78 0.95
表 9  决策性能结果对比
1 赵萌, 秦金磊, 潘一如, 等 基于策略权重的模糊多属性决策方法[J]. 控制与决策, 2021, 36 (5): 1259- 1267
ZHAO Meng, QIN Jin-lei, PAN Yi-ru, et al Strategic weight manipulation in fuzzy multiple attribute decision making[J]. Control and Decision, 2021, 36 (5): 1259- 1267
doi: 10.13195/j.kzyjc.2019.0542
2 OCAMPO L A, LABRADOR J J T, JUMAO-AS A M B, et al Integrated multiphase sustainable product design with a hybrid quality function deployment-multi-attribute decision-making (QFD-MADM) framework[J]. Sustainable Production and Consumption, 2020, 24: 62- 78
doi: 10.1016/j.spc.2020.06.013
3 陈六新, 罗南方 基于前景理论的勾股模糊多属性决策[J]. 系统工程理论与实践, 2020, 40 (3): 726- 735
CHEN Liu-xin, LUO Nan-fang Pythagorean fuzzy multi-criteria decision-making based on prospect theory[J]. Systems Engineering-Theory and Practice, 2020, 40 (3): 726- 735
doi: 10.12011/1000-6788-2018-2422-10
4 杨涛, 杨育, 薛承梦, 等 考虑客户需求偏好的产品创新设计方案多属性决策评价[J]. 计算机集成制造系统, 2015, 21 (2): 417- 426
YANG Tao, YANG Yu, XUE Cheng-meng, et al Multi-attribute decision-making evaluation method for product innovation design scheme with demand preferences of customers[J]. Computer Integrated Manufacturing Systems, 2015, 21 (2): 417- 426
doi: 10.13196/j.cims.2015.02.014
5 CHEN Z, YANG L, RODRÍGUEZ R M, et al Power-average-operator-based hybrid multiattribute online product recommendation model for consumer decision-making[J]. International Journal of Intelligent Systems, 2021, 36 (6): 2572- 2617
doi: 10.1002/int.22394
6 MAO L X, LIU R, MOU X, et al New approach for quality function deployment using linguistic Z-numbers and EDAS method[J]. Informatica, 2021, 32 (3): 565- 582
7 MOHANTY P P, MAHAPATRA S S, MOHANTY A, et al A novel multi-attribute decision making approach for selection of appropriate product conforming ergonomic considerations[J]. Operations Research Perspectives, 2018, 5: 82- 93
doi: 10.1016/j.orp.2018.01.004
8 JAIN R, RANA K B, MEENA M L. An integrated multi-criteria decision-making approach for identifying the risk level of musculoskeletal disorders among handheld device users [J/OL]. Soft Computing, 2021: 1-11[2021-02-03]. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7856850/pdf/500_2021_Article_5592.pdf.
9 ARIFIN Z, PRASETYO S D, PRABOWO A R, et al Preliminary design for assembling and manufacturing sports equipment: a study case on aerobic walker[J]. International Journal of Mechanical Engineering and Robotics Research, 2021, 10 (3): 107- 115
10 ZADEH L A Fuzzy sets[J]. Information and Control, 1965, 8 (3): 338- 353
doi: 10.1016/S0019-9958(65)90241-X
11 ATANASSOV K T Intuitionistic fuzzy sets[J]. Fuzzy Sets and Systems, 1986, 20 (1): 87- 96
doi: 10.1016/S0165-0114(86)80034-3
12 TORRA V Hesitant fuzzy sets[J]. International Journal of Intelligent Systems, 2010, 25 (1): 529- 539
13 SMARANDACHE F. A unifying field in logics [M]. [S.l.]: American Research Press, 2003.
14 WANG H, SMARANDACHE F, ZHANG Y, et al Q-single valued neutrosophic soft sets[J]. Journal of New Theory, 2016, (13): 10- 25
15 LI J, FANG H, SONG W Sustainable supplier selection based on SSCM practices: a rough cloud TOPSIS approach[J]. Journal of Cleaner Production, 2019, 222: 606- 621
doi: 10.1016/j.jclepro.2019.03.070
16 WANG P, HUANG S, CAI C Dual linguistic term set and its application based on the normal cloud model[J]. IEEE Transactions on Fuzzy Systems, 2021, 29 (8): 2180- 2194
doi: 10.1109/TFUZZ.2020.2994994
17 MA Z, ZHANG S Risk-based multi-attribute decision-making for normal cloud model considering pre-evaluation information[J]. IEEE Access, 2020, 8: 153891- 153904
doi: 10.1109/ACCESS.2020.3018153
18 WANG P, XU X, HUANG S, et al A linguistic large group decision making method based on the cloud model[J]. IEEE Transactions on Fuzzy Systems, 2018, 26 (6): 3314- 3326
doi: 10.1109/TFUZZ.2018.2822242
19 GRZYBOWSKI A Z Note on a new optimization based approach for estimating priority weights and related consistency index[J]. Expert Systems with Applications, 2012, 39 (14): 11699- 11708
doi: 10.1016/j.eswa.2012.04.051
20 SAATY T L, VARGAS L G. Decision making with the analytic network process [M]. [S.l.]: Springer, 2006.
21 XU Y, XI Y, CABRERIZO F J, et al An alternative consensus model of additive preference relations for group decision making based on the ordinal consistency[J]. International Journal of Fuzzy Systems, 2019, 21 (6): 1818- 1830
doi: 10.1007/s40815-019-00696-w
22 PENG H G, ZHANG H Y, WANG J Q, et al An uncertain Z-number multicriteria group decision-making method with cloud models[J]. Information Sciences, 2019, 501: 136- 154
doi: 10.1016/j.ins.2019.05.090
23 WANG H, FANG Z G, WANG D A, et al An integrated fuzzy QFD and grey decision-making approach for supply chain collaborative quality design of large complex products[J]. Computers and Industrial Engineering, 2020, 140: 106212
doi: 10.1016/j.cie.2019.106212
24 LI S, MA X, YANG C A combined thermal power plant investment decision-making model based on intelligent fuzzy grey model and ito stochastic process and its application[J]. Energy, 2018, 159: 1102- 1117
doi: 10.1016/j.energy.2018.06.184
25 TSENG M L, WU K J, HU J Y, et al Decision-making model for sustainable supply chain finance under uncertainties[J]. International Journal of Production Economics, 2018, 205: 30- 36
doi: 10.1016/j.ijpe.2018.08.024
[1] 裴植, 鲁建厦, 郑力. 广义直觉模糊数在集装箱堆场选择中的应用[J]. J4, 2012, 46(12): 2274-2279.