Python library to support Decision Making with Intuitionistic Fuzzy Sets
Project description
pyifdm
Python 3 package to perform Multi-Criteria Decision Analysis in the Intuitionistic Fuzzy environment
Installation
The package can be download using pip:
pip install pyifdm
Testing
The modules performance can be verified with pytest library
pip install pytest
pytest tests
Modules and functionalities
- MCDA methods based on Intuitionistic Fuzzy Sets (IFS):
| Abbreviation | Full name | Reference |
|---|---|---|
| ARAS | Additive Ratio ASsessment | [1] |
| CODAS | COmbinative Distance-based ASsessment | [2] |
| COPRAS | COmplex PRoportional ASsessment | [3] |
| EDAS | Evaluation based on Distance from Average Solution | [4] |
| MABAC | Multi-Attributive Border Approximation area Comparison | [5] |
| MAIRCA | MultiAttributive Ideal-Real Comparative Analysis | [6] |
| MOORA | Multi-Objective Optimization Method by Ratio Analysis | [7] |
| TOPSIS | Technique for the Order of Prioritisation by Similarity to Ideal Solution | [8] |
| VIKOR | VIseKriterijumska Optimizacija I Kompromisno Resenje | [9] |
- Weighting methods:
| Name | Reference |
|---|---|
| Burillo entropy weights | [25] |
| Equal weights | [10] |
| Entropy weights | [9] |
| Liu entropy weights | [27] |
| Szmidt entropy weights | [26] |
| Thakur entropy weights | [3] |
| Ye entropy weights | [24] |
- Normalization methods:
| Name | Reference |
|---|---|
| Ecer normalization | [10] |
| Min-Max normalization | [6] |
| Supriya normalization | [11] |
| Swap normalization | [2] |
- Score functions:
| Name | Reference |
|---|---|
| Chen score 1 | [29] |
| Chen score 2 | [29] |
| Kharal score 1 | [15] |
| Kharal score 2 | [15] |
| Liu Wang score | [28] |
| Supriya score | [11] |
| Thakur score | [3] |
| Wan Dong score 1 | [13] |
| Wan Dong score 2 | [13] |
| Wei score | [12] |
| Zhang Xu score 1 | [14] |
| Zhang Xu score 2 | [14] |
- Distance measures:
| Name | Reference |
|---|---|
| Euclidean distance | [16] |
| Grzegorzewski distance | [17] |
| Hamming distance | [16] |
| Luo Distance | [9] |
| Normalized Euclidean distance | [16] |
| Normalized Hamming distance | [16] |
| Wang Xin distance 1 | [18] |
| Wang Xin distance 2 | [18] |
| Yang Chiclana distance | [19] |
- Correlation coefficients:
| Name | Reference |
|---|---|
| Pearson correlation coefficient | [21] |
| Spearman correlation coefficient | [20] |
| Weighted Spearman correlation coefficient | [22] |
| WS Rank Similarity coefficient | [23] |
- Helpers methods
- rank
- generate ifs matrix
Usage example
Below the sample example of the Intuitionistic Fuzzy EDAS method application is presented. More examples of package functionalities can be found in Jupyter examples.
from pyifdm.methods import ifEDAS
from pyifdm.helpers import rank
import numpy as np
if __name__ == '__main__':
matrix = np.array([
[[0.4745, 0.5255], [0.4752, 0.5248], [0.2981, 0.7019], [0.4374, 0.5627]],
[[0.5346, 0.4654], [0.5532, 0.4468], [0.6300, 0.3700], [0.5901, 0.4099]],
[[0.4324, 0.5676], [0.4030, 0.5970], [0.4298, 0.5702], [0.4361, 0.5639]],
[[0.5235, 0.4765], [0.4808, 0.5192], [0.5667, 0.4333], [0.2913, 0.7087]],
[[0.4168, 0.5832], [0.4923, 0.5077], [0.4732, 0.5268], [0.4477, 0.5523]]
])
weights = np.array([0.2, 0.3, 0.15, 0.35])
types = np.array([1, -1, 1, 1])
if_edas = ifEDAS()
pref = if_edas(matrix, weights, types)
print(f'IF-EDAS preferences: {pref}')
print(f'IF-EDAS ranking: {rank(pref)}')
Output:
IF-EDAS preferences: 0.276 0.259 0.523 0.995 0.322
IF-EDAS ranking: 4 5 2 1 3
References
[1] Raj Mishra, A., Sisodia, G., Raj Pardasani, K., & Sharma, K. (2020). Multi-criteria IT personnel selection on intuitionistic fuzzy information measures and ARAS methodology. Iranian Journal of Fuzzy Systems, 17(4), 55-68.
[2] Buyukozkan, G., & Göçer, F. (2019, August). Prioritizing the strategies to enhance smart city logistics by intuitionistic fuzzy CODAS. In 11th Conference of the European Society for Fuzzy Logic and Technology (EUSFLAT 2019) (pp. 805-811). Atlantis Press.
[3] Thakur, P., Kizielewicz, B., Gandotra, N., Shekhovtsov, A., Saini, N., Saeid, A. B., & Sałabun, W. (2021). A New Entropy Measurement for the Analysis of Uncertain Data in MCDA Problems Using Intuitionistic Fuzzy Sets and COPRAS Method. Axioms, 10(4), 335.
[4] Liang, Y. (2020). An EDAS method for multiple attribute group decision-making under intuitionistic fuzzy environment and its application for evaluating green building energy-saving design projects. Symmetry, 12(3), 484.
[5] Li, Y. (2021). IF-MABAC Method for Evaluating the Intelligent Transportation System with Intuitionistic Fuzzy Information. Journal of Mathematics, 2021.
[6] Ecer, F. (2022). An extended MAIRCA method using intuitionistic fuzzy sets for coronavirus vaccine selection in the age of COVID-19. Neural Computing and Applications, 34(7), 5603-5623.
[7] Pérez-Domínguez, L., Alvarado-Iniesta, A., Rodríguez-Borbón, I., & Vergara-Villegas, O. (2015). Intuitionistic fuzzy MOORA for supplier selection. Dyna, 82(191), 34-41.
[8] Boran, F. E., Boran, K. U. R. T. U. L. U. Ş., & Menlik, T. (2012). The evaluation of renewable energy technologies for electricity generation in Turkey using intuitionistic fuzzy TOPSIS. Energy Sources, Part B: Economics, Planning, and Policy, 7(1), 81-90.
[9] Ying-Yu, W., & De-Jian, Y. (2011, September). Extended VIKOR for multi-criteria decision making problems under intuitionistic environment. In 2011 International Conference on Management Science & Engineering 18th Annual Conference Proceedings (pp. 118-122). IEEE.
[10] Ecer, F., & Pamucar, D. (2021). MARCOS technique under intuitionistic fuzzy environment for determining the COVID-19 pandemic performance of insurance companies in terms of healthcare services. Applied Soft Computing, 104, 107199.
[11] De, S. K., Biswas, R., & Roy, A. R. (2000). Some operations on intuitionistic fuzzy sets. Fuzzy sets and Systems, 114(3), 477-484.
[12] Wei P, Gao ZH, Guo TT (2012) An intuitionistic fuzzy entropy measure based on the trigonometric function. Control Decis 27:571–574
[13] Wan, S., & Dong, J. (2020). A selection method based on MAGDM with interval-valued intuitionistic fuzzy sets. In Decision Making Theories and Methods Based on Interval-Valued Intuitionistic Fuzzy Sets (pp. 115-137). Springer, Singapore.
[14] Zhang, X., & Xu, Z. (2012). A new method for ranking intuitionistic fuzzy values and its application in multi-attribute decision making. Fuzzy Optimization and Decision Making, 11(2), 135-146.
[15] Kharal, A. (2009). Homeopathic drug selection using intuitionistic fuzzy sets. Homeopathy, 98(1), 35-39.
[16] Çalı, S., & Balaman, Ş. Y. (2019). A novel outranking based multi criteria group decision making methodology integrating ELECTRE and VIKOR under intuitionistic fuzzy environment. Expert Systems with Applications, 119, 36-50.
[17] Grzegorzewski, P. (2004). Distances between intuitionistic fuzzy sets and/or interval-valued fuzzy sets based on the Hausdorff metric. Fuzzy sets and systems, 148(2), 319-328.
[18] Wang, W., & Xin, X. (2005). Distance measure between intuitionistic fuzzy sets. Pattern recognition letters, 26(13), 2063-2069.
[19] Yang, Y., & Chiclana, F. (2012). Consistency of 2D and 3D distances of intuitionistic fuzzy sets. Expert Systems with Applications, 39(10), 8665-8670.
[20] Spearman, C. (1910). Correlation calculated from faulty data. British Journal of Psychology, 1904‐1920, 3(3), 271-295.
[21] Pearson, K. (1895). VII. Note on regression and inheritance in the case of two parents. proceedings of the royal society of London, 58(347-352), 240-242.
[22] Dancelli, L., Manisera, M., & Vezzoli, M. (2013). On two classes of Weighted Rank Correlation measures deriving from the Spearman’s ρ. In Statistical Models for Data Analysis (pp. 107-114). Springer, Heidelberg.
[23] Sałabun, W., & Urbaniak, K. (2020, June). A new coefficient of rankings similarity in decision-making problems. In International Conference on Computational Science (pp. 632-645). Springer, Cham.
[24] Ye, J. Two effective measures of intuitionistic fuzzy entropy. Computing 2010, 87, 55–62.
[25] Burillo, P.; Bustince, H. Entropy on intuitionistic fuzzy sets and on interval-valued fuzzy sets. Fuzzy Sets Syst. 1996, 78, 305–316.
[26] Szmidt, E.; Kacprzyk, J. Entropy for intuitionistic fuzzy sets. Fuzzy Sets Syst. 2001, 118, 467–477.
[27] Liu, M.; Ren, H. A new intuitionistic fuzzy entropy and application in multi-attribute decision making. Information 2014, 5, 587–601.
[28] Liu, H. W., & Wang, G. J. (2007). Multi-criteria decision-making methods based on intuitionistic fuzzy sets. European Journal of Operational Research, 179(1), 220-233.
[29] Chen, T. Y. (2011). A comparative analysis of score functions for multiple criteria decision making in intuitionistic fuzzy settings. Information Sciences, 181(17), 3652-3676.
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