PSS Evaluation Based on Vague Assessment Big Data: Hybrid Model of Multi-Weight Combination and Improved TOPSIS by Relative Entropy
Article Information
Abstract
Abstract: Driven by the vague assessment big data, a product service system (PSS) evaluation method is developed based on a hybrid model of multi-weight combination and improved TOPSIS by relative entropy. The index values of PSS alternatives are solved by the integration of the stakeholders’ vague assessment comments presented in the form of trapezoidal fuzzy numbers. Multi-weight combination method is proposed for index weight solving of PSS evaluation decision-making. An improved TOPSIS by relative entropy (RE) is presented to overcome the shortcomings of traditional TOPSIS and related modified TOPSIS and then PSS alternatives are evaluated. A PSS evaluation case in a printer company is given to test and verify the proposed model. The RE closeness of seven PSS alternatives are 0.3940, 0.5147, 0.7913, 0.3719, 0.2403, 0.4959, and 0.6332 and the one with the highest RE closeness is selected as the best alternative. The results of comparison examples show that the presented model can compensate for the shortcomings of existing traditional methods.
Keywords: Big Data, E Product-Service System, Evaluation Decision-Making, Index System, Multi-Weight Combination, Relative Entropy, TOPSIS
1. Introduction
As manufacturing enterprises gradually shift their business focus from providing industrial products to offering a combination of products and services, and rely on services to enhance profitability, business models or strategies focused on solutions are becoming mainstream. This transformation, which is from selling products and basic services to selling solutions or product service systems (PSSs), is regarded as service-oriented. Many manufacturing enterprises view service-oriented services as an important way to create customer value, improve customer satisfaction, generate differentiated competitive advantages, improve business performance, and promote economic development. PSS [1], as an emerging concept of maintaining product functionality for customers, has appeared. It can optimize resource utilization and improve enterprise competitiveness [2,3]. Scheme evaluation is a key part of the PSS design and development course [4,5], and the rationality of the evaluation results directly influences the success or failure of the design. Due to the subjectivity and uncertainty of services, PSS scheme evaluation is a typical mixed multi-attribute decision-making problem. Under the era of big data, the application of big data methods [6,7] in decision-making processes also can provide support for the optimization of PSS evaluation decisions.
Due to the complexity of PSS evaluation problems, traditional methods [8-10] are powerless to make PSS evaluation decisions, which is mainly reflected as following aspects:
1) The process of selecting the indexes in the establishment of the PSS evaluation index system is subjective. The comprehensiveness of indexes is also low.
2) When calculating the index weights, subjective or objective weighting methods are always adopted separately, which has certain limitations.
3) The convenient calculation method for index values is lacked. In response to these shortcomings in existing research, this article proposes a PSS evaluation method based on big data, which is a hybrid model of multi weight combination and improved TOPSIS by relative entropy (RE).
2. Holistic Framework
The holistic framework of PSS evaluation based on big data is shown in Fig. 1.
The holistic framework is divided into three layers which are big data layer, evaluation approach layer and PSS alternative layer. The business logic within and between the three layers of the holistic framework is shown in Fig. 1.
3. Index System
The opinions of stakeholders on PSS evaluation decisions mainly exist in forums, online discussions, user comments, and other channels. Using web crawlers can obtain these big data. This article uses text analysis to conceptualize and segment these big data, and conducts word frequency statistics. The words which have no actual meaning or clear direction need to be excluded in order to obtain a true highfrequency word directory. The relative relationship between two high-frequency words is generally represented by their co-occurrence matrix. In a co-occurrence matrix, if the matrix value of is larger, the correlation between two high-frequency words is stronger. Based on the analysis of high-frequency words, its semantic network diagram can be obtained through social network analysis. The semantic network diagram example of high-frequency words is shown in Fig. 2.
According to Fig. 2, this article classifies high-frequency words based on logical relationships and interrelationships. The obtained category is the secondary index for PSS evaluation. Finally, this article reclassifies the secondary indicators and obtains the primary indicators. A tree shaped and multi-level PSS evaluation decision index system has been constructed, as shown in Table 1.
In Table 1, there are 6 first-level index and 19 second-level index. Here, I1 means customer expectation degree, I2 means customer acceptance degree, I3 means system convenience degree, I4 means service quality degree, I5 means product quality degree, I6 means degree of employment opportunities provided, I7 means profit ability degree, I8 means employee working environment, I9 means service cost degree of providing PSS, I10 means service positioning degree, I11 means market size degree, I12 means investment cost degree, I13 means relationship with competitors, I14 means government financial support degree, I15 means support degree of government laws and regulations, I16 means user health and safety assurance degree, I17 means CO2 emission degree, I18 means harmful substance emission degree, and I19 means resource consumption degree.
4. Index Value Determination
There are p PSS schemes and q stakeholders. The evaluation value (TFN) of scheme s(1≤s≤p) given by stakeholder r(1≤r≤q) on index Ii is ˜xrs,i=(ars,i,brs,i,crs,i,drs,i). Then, the integrated value of all stakeholders can be solved as follows:
(1)
˜xs,i=(as,i,bs,i,cs,i,ds,i)=(q∑r=1ars,i/q,bs,i=q∑r=1brs,i/q,cs,i=q∑r=1crs,i/q,ds,i=q∑r=1drs,i/q).While calculating the index value of scheme s on index Ii, the index value is evaluated by four stakeholders. The vague comments contain nine level scales: extremely good (L1), strongly good (L2), obviously good (L3), slightly good (L4), middle (L5), slightly bad (L6), obviously bad (L7), strongly bad (L8) and extremely bad (L9). The four stakeholders evaluated the index value using a vague comment as shown in Table 2.
The fuzzy values corresponding to the vague comments of four stakeholders are ˜x1s,i=(7/3,3,17/3,9), ˜x2s,i=(3/7,7/13,9/11,1), ˜x3s,i=(1,11/9,13/7,7/3), and ˜x4s,i=(3/2,13/7,3,4). Then the group decision evaluation value is obtained as ˜xs,i=(as,i,bs,i,cs,i,ds,i), here as,i=(7/3+3/7+1+3/2)/4=1.3155,bs,i=(3+7/13+11/9+13/7)/4=1.6545,cs,i=(17/3+9/11+13/7+3)/4=2.8355, and ds,i=(9+1+7/3+4)/4=4.0833.
By the gravity center formula of TFN, the real number form of ˜xs,i is obtained as follows:
For ˜xs,i=(1.3155,1.6545,2.8355,4.0833), its corresponded real number is xs,i=2.5026.
5. PSS Scheme Alternative Evaluation
5.1 Multi-Weight Combination
A single weighting method often leads to unstable evaluation results. In order to make the weighting of evaluation indexed more fair, scientific and reasonable, a multi-weight combination approach was developed, as shown in Fig. 3.
By ℎ different weighting methods, the weight vectors are obtained are as follows:
In the multi-weight combination process, there are ℎ − 1 combination operations. In the first combination operation (w1 and w2), the combination weight vector w1⋅2 is shown as follows.
where τ1 and τ2 are the combination coefficients corresponding to w1 and w2, and τ1≥0,τ2≥0,τ1+τ2=1.
The total weight contribution discrepancy (TWCD) of w1 and w2 is defined as follows.
Therefore, a multi-weight combination approach is built to make the weight contributions of w1 and w2 balanced, which is as following.
Two combination coefficients are obtained as follows:
(7)
\left\{\begin{array}{l} \tau_1=\frac{\sum_{s=1}^p \sum_{i=1}^N\left(x_{s, i}\right)^2 w_i^2\left(w_i^1+w_i^2\right)}{\sum_{s=1}^p \sum_{i=1}^N\left(x_{s, i}\right)^2\left(w_i^1+w_i^2\right)} \\ \tau_2=1-\tau_1 \end{array}\right..Then w^{1 \cdot 2} \text { and } w^3 are combined and their combination weight is w^{1 \cdot 2 \cdot 3}. At last the combination weight vector is obtained as follows.
(8)
w^{1 \cdot 2 \cdot \ldots \cdot h}=\left[w_1^{1 \cdot 2 \cdot \ldots \cdot h}, w_2^{1 \cdot 2 \cdot \ldots \cdot h}, \ldots, w_N^{1 \cdot 2 \cdot \ldots \cdot h}\right]^{\mathrm{T}}.5.2 Improved TOPSIS by RE
Between two n-dimensional uncertainty systems \theta^A=\left(\theta_1^A, \theta_2^A, \ldots, \theta_n^A\right) and \theta^B=\left(\theta_1^B, \theta_2^B, \ldots, \theta_n^B\right), the difference degree can be expressed by RE [11-13] as follows:
(9)
R E^{A, B}=\sum_{k=1}^n\left[\theta_k^A \log \frac{\theta_k^A}{\theta_k^B}+\left(1-\theta_k^A\right) \log \frac{1-\theta_k^A}{1-\theta_k^B}\right],where \theta_k^A \text { and } \theta_k^B are the occurrence chance of uncertain state k in systems \theta^A \text { and } \theta^B.
RE has two features: (1) R E^{A, B} \geq 0, (2) only if A=B, R E^{A, B}=0.
According to the calculation in the previous text, the index value matrix is X=\left[x_{s, i}\right]_{p \times N}, and the weight vector is w^{1 \cdot 2 \cdot \ldots \cdot h}. Then the weighted index value matrix can be solved as T=\left[t_{s, i}\right]_{p \times N}, where t_{s, i}=w_i^{1 \cdot 2 \cdot \ldots \cdot h} t_{s, i}. The positive and negative ideal point (PIP and NIP) can be solved as:
(10)
\begin{aligned} &T^{+}=\left[t_1^{+}, t_2^{+}, \ldots, t_i^{+}, \ldots, t_N^{+}\right] \\ &T^{-}=\left[t_1^{-}, t_2^{-}, \ldots, t_i^{-}, \ldots, t_N^{-}\right] \end{aligned}where t_i^{+}=\max \left\{t_{1, i}, t_{2, i}, \ldots, t_{p, i}\right\} and t_i^{-}=\min \left\{t_{1, i}, t_{2, i}, \ldots, t_{p, i}\right\}
The index value of PSS scheme s is solved as T^s=\left[t_{s, 1}, t_{s, 2}, \ldots, t_{s, i}, \ldots, t_{s, N}\right]. Then the RE from T^s to PIP T^{+} is calculated as:
(11)
R E^{s,+}=\sum_{i=1}^N\left[t_{s, i} \log \frac{t_{s, i}}{t_i^{+}}+\left(1-t_{s, i}\right) \log \frac{1-t_{s, i}}{1-t_i^{+}}\right] .The RE from T^s to NIP T^{-} is calculated as:
(12)
R E^{s,-}=\sum_{i=1}^N\left[t_{s, i} \log \frac{t_{s, i}}{t_i^{-}}+\left(1-t_{s, i}\right) \log \frac{1-t_{s, i}}{1-t_i^{-}}\right] .For PSS scheme s, the RE closeness is calculated as:
Here RE closeness \varphi^S has three characteristics: (1) if T^s=T^{+}, \varphi^s=1; (2) if T^s=T^{-}, \varphi^s=0; (3) if T^{-} \neq T^s \neq T^{+} \text {and } T^s \rightarrow T^{+}, \varphi^s \rightarrow 1.
6. Case Study
Here shows a PSS evaluation case in a printer company. It is assumed that there are seven PSS schemes (P1, P2, P3, P4, P5, P6 and P7), and there are 60 persons in the stakeholder group, namely PSS customers (12 persons), customer demand analysts (12 persons), PSS entrepreneurs (12 persons), social and environmental researchers (12 persons) and PSS design engineers (12 persons).
Taking the performance of PSS scheme P1 on index I_1 as an example, six stakeholders thinks L_1, one stakeholder thinks L_2, eight stakeholders think L_3, fifteen stakeholders think L_4, six stakeholder thinks L_5, fourteen stakeholders think L_6, three stakeholders think L_7, no stakeholder thinks L_8 and seven stakeholders think L_9. The fuzzy opinion of P1 on the19 indexes is counted as shown in Table 3.
Then the index value of P1 in TFN form is solved and then we convert it to the real number form as follows (Tables 4 and 5).
By the same way, the index values of other six PSS schemes can be obtained (Table 6).
By entropy approach, CRITIC method and standard deviation approach, the corresponding weight vectors are obtained as w^1, w^2 \text { and } w^3, respectively. Based on multi-weight combination, the combination weight vector w^{1 \cdot 2 \cdot 3} is obtained as shown in Table 7.
Then the weighted index value matrix is obtained as T=\left[t_{s, i}\right]_{6 \times 19} (Table 8). Therefore, PIP and NIP are obtained (Table 8).
The REs to PIP and NIP and RE closeness are calculated in Table 9.
Based on RE closeness, the ranking result of seven PSS alternatives is also shown in Table 9, in which P3 is the best PSS alternative.
7. Discussion
Due to the shortcomings of traditional TOPSIS, several modified TOPSIS methods have been presented by scholars through replacing Euclidean distance with other concepts [14,15]. We compared the results of the proposed model (modified TOPSIS by RE), traditional TOPSIS, modified TOPSISs [14,15] as shown in Table 10.
As shown in Table 10, the evaluation results of the proposed model and traditional TOPSIS are identical, which can prove the correctness and effectiveness of the proposed model. Because the existing literature have proved that traditional TOPSIS has obvious and clear shortcomings, traditional TOPSIS is not advisable. The overall evaluation trend of the four models is generally consistent, and P3, P7 and P2 are better than P1, P4 and P5, while P6 is about in the middle. However, by modified TOPSIS in Reference [14] the evaluation result of P2 and P3 is obviously different from other three models, and the opposite evaluation result appears. By modified TOPSIS in Reference [15] the closeness of P1 and P6 are completely equal and the evaluation of them cannot be executed. Therefore, modified TOPSIS models [14,15] cannot meet the evaluation requirements in some special scenarios. Based on the data in Table 10, the proposed model in which TOSIS is modified by changing Euclidean distance as RE can compensate for the shortcomings of existing modified TOPSIS methods.
8. Conclusion
To achieve rapid evaluation of personalized PSS schemes, this paper proposes a new method. The feasibility, effectiveness and simplicity of the proposed method for complex evaluation problems in mixed uncertain environments were verified through implementation examples. The next step of the research will consider the impact of uncertainty in user satisfaction evaluation information on PSS scheme evaluation.
Biography
References
- 1 . K. Li, T. Zhou, and B. Liu, "Internet-based intelligent and sustainable manufacturing: developments and challenges," International Journal of Advanced Manufacturing Technology, vol. 108, pp. 1767-1791, 2020. https://doi.org/10.1007/s00170-020-05445-0 Cited By
- 2 . R. Rabetino, W. Harmsen, M. Kohtamaki, and J. Sihvonen, "Structuring servitization-related research," International Journal of Operations & Production Management, vol. 38, no. 2, pp. 350-371, 2018. https://doi.org/10.1108/IJOPM-03-2017-0175 Cited By
- 3 . L. Li and C. Mao, "Big data supported PSS evaluation decision in service-oriented manufacturing," IEEE Access, vol. 8, pp. 154663-154670, 2020. https://doi.org/10.1109/ACCESS.2020.3018667 Cited By
- 4 . Z. Zhang, D. Xu, E. Ostrosi, L. Y u, and B. Fan, "A systematic decision-making method for evaluating design alternatives of product service system based on variable precision rough set," Journal of Intelligent Manufacturing, vol. 30, pp. 1895-1909, 2019. https://doi.org/10.1007/s10845-017-1359-6 Cited By
- 5 . K. Ding, J. Li, F. Zhang, J. Hui, and Q. Liu, "Service satisfaction evaluation of customer preference-driven public warehousing product service systems for small- and medium-sized enterprises in an industrial park," IEEE Access, vol. 7, pp. 98197-98207, 2019. https://doi.org/10.1109/ACCESS.2019.2924190 Cited By
- 6 . X. Li, J. Zhou, and W. Pedrycz, "Linking granular computing, big data and decision making: a case study in urban path planning," Soft Computing, vol. 24, pp. 2020 ,7435-7450 . https://doi.org/10.1007/s00500-01904369-6 Cited By
- 7 . A. Alhroob, W. Alzyadat, I. Almukahel, G. Jaradat, "Adaptive Fuzzy Map Approach for Accruing V elocity of Big Data Relies on Fireflies Algorithm for Decentralized Decision Making," IEEE Access, vol. 8, pp. 21401-21410, 2020. https://doi.org/10.1109/ACCESS.2020.2969204 Cited By
- 8 . L. Li, B. Lei, and C. Mao, "Digital twin in smart manufacturing," Journal of Industrial Information Integration, vol. 26, article no. 100289, 2022. https://doi.org/10.1016/j.jii.2021.100289 Cited By
- 9 . C. P. Grag and A. Sharma, "Sustainable outsourcing partner selection and evaluation using an integrated BWM-VIKOR framework," Environment Development and Sustainability, vol. 22, pp. 1529-1557, 2020. https://doi.org/10.1007/s10668-018-0261-5 Cited By
- 10 . L. Li, C. Mao, H. Sun, Y . Y uan, and B. Lei, "Digital twin driven green performance evaluation methodology of intelligent manufacturing: hybrid model based on fuzzy rough-sets AHP, multistage weight synthesis, and PROMETHEE II," Complexity, vol. 2020, article no. 3853925, 2020. https://doi.org/10.1155/2020/3853925 Cited By
- 11 . W. Song, J. Zhu, S. Zhang, and Y . Chen, "Decision Making method for dual uncertain information based on grey incidence analysis and grey relative entropy optimization," Journal of Grey System, vol. 29, no. 3, pp. 78-98, 2017. Cited By
- 12 . L. Li, T. Qu, Y . Liu, R. Y . Zhong, G. Xu, H. Sun, et al., "Sustainability assessment of intelligent manufacturing supported by digital twin," IEEE Access, vol. 8, pp. 174988-175008, 2020. https://doi.org/10.1109/ACCESS. 2020.3026541 Cited By
- 13 . Q. Li, X. Zhao, R. Lin, and B. Chen, "Relative entropy method for fuzzy multiple attribute decision making and its application to software quality evaluation," Journal of Intelligent & Fuzzy Systems, vol. 26, no. 4, pp. 1693 - 1687 , 2014 . https://doi.org/10.3233/IFS-130848 Cited By
- 14 . S. L. Liu and W. H. Qiu, "The TOPSIS angle measure evaluation method for MADM," System Engineering - Theory & Practice, vol. 16, no. 7, pp. 12-17, 1996. https://sysengi.cjoe.ac.cn/EN/10.12011/1000-6788(19 96)7-12 Cited By
- 15 . X. Y . Hua and J. X. Tan, "Revised TOPSIS method based on vertical projection distance-vertical projection method," System Engineering - Theory & Practice, vol. 24, no. 1, pp. 114-119, 2004. https://sysengi.cjoe.ac. cn/EN/10.12011/1000-6788(2004)1-114 Cited By
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