Weapon Selection with Fuzzy AHP-TOPSIS for Capability-Based Risk-Based Defense Planning
Yıl 2024,
, 363 - 387, 01.11.2024
Serkan Aksoy
,
Memduh Begenirbaş
,
Kemal Gürol Kurtay
Öz
Capability-based planning (CAP) is a new paradigm that uses the concept of capability to provide an analytical framework for strategic or long-term planning. In this study, 6 different scenarios were created for the capabilities that can meet military objectives, and accordingly, the risk of occurrence for each scenario was calculated within the YTP. The sub-skills necessary for the success of the determined goals have been defined. For the weapon selection problem to meet military objectives, criterion weights were calculated with Fuzzy AHP, one of the Multi-Criteria Decision Making (MCDM) methods, and prioritized with the TOPSIS method. The main motivation of this study is to fill the gap in the literature regarding analytical evaluation of decision processes for identifying and evaluating scenario-based capabilities.
Kaynakça
- [1] Government, A. (2012). Defence capability development handbook 2012.
- [2] Gaidow, S. ve Boey, S. (2005). Australian Defence Risk Management Framework: A Comparative Study.
- [3] Barclay, C. ve Osei-Bryson, K. M. (2010). Project performance development framework: An approach for developing performance criteria & measures for information systems (IS) projects. International Journal of Production Economics, 124(1). https://doi.org/10.1016/j.ijpe.2009.11.025
- [4] Martinsuo, M. (2013). Project portfolio management in practice and in context.
International Journal of Project Management, 31(6). https://doi.org/10.1016/j.ijproman.2012.10.013
- [5] Davis, P. K. (2002). Analytic architecture for capabilities-based planning, mission-system analysis, and transformation. Rand Corporation.
- [6] Begenirbaş, M. (2022). Savunma yönetimi ve planlaması (1. Baskı). Nobel Akademik
Yayıncılık.
- [7] Stojkovic, D., Kankaras, M. ve Mitic, V. (2016). Determination of defence capability requirements. Vojno Delo, 68(8). https://doi.org/10.5937/vojdelo1608076s
- [8] Mezey, G. (2004). Defence planning of conventional forces. 3(5).
- [9] Campbell, A. (2010). Analytic implications of the NATO defence planning process. NATO C3 Agency.
- [10] Cimon, Y. (2017). Perspectives for the development of key industrial capabilities for Canada’s defence sector. Defense and Security Analysis, 33(4). https://doi.org/10.1080/14751798.2017.1377422
- [11] Palaz, H. (2008). Analitik hiyerarşi prosesi ve hedef programlama kullanılarak denizaltı kuvvet yapısının belirlenmesi (Yüksek Lisans Tezi). Hava Harp Okulu Komutanlığı Havacılık ve Uzay Teknolojileri Enstitüsü.
- [12] Bizkevelci, S. ve Çakmak, M. A. (2008).
Technology management model application in concept approval decision - Case study: Concept of operations and mission need assesment for a defence system. PICMET: Portland International Center for Management of Engineering and Technology, Proceedings.https://doi.org/10.1109/PICMET.2008.4599767
- [13] Hristov, N., Radulov, I., Iliev, P. ve
Andreeva, P. (2010). Prioritization methodology
for development of required operational
capabilities. Alındığı yer:
https://ssrn.com/abstract=3135696
- [14] Nesterenko, O., Netesin, I., Polischuk, V. ve
Trofymchuk, O. (2020). Development of a
procedure for expert estimation of capabilities in
defense planning under multicriterial conditions.
Eastern-European Journal of Enterprise
Technologies, 4(2-106): 33-43.
https://doi.org/10.15587/1729-
4061.2020.208603
- [15] Harrison, K. R., Elsayed, S., Garanovich, I.,
Weir, T., Galister, M., Boswell, S., Taylor, R. ve Sarker, R. (2020). Portfolio optimization for
defence applications. IEEE Access, 8: 60152-
60178.
https://doi.org/10.1109/ACCESS.2020.2983141
- [16] Kurtay, K. G., Dağıstanlı, H. A., & Erol, S.
(2021). Plastik Boru ve Kaynak Makinesi Seçim
Problemi için Analitik Hiyerarşi Prosesi ile Gri
İlişkisel Analiz Yöntemlerinin
Entegrasyonu. Savunma Bilimleri Dergisi, 2(40),
267-291.
https://doi.org/10.17134/khosbd.1001230
- [17] Desticioğlu, B., Kurtay, K. G., Altundaş, A.,
& Dağıstanlı, H. A. (2021). Hastanelere aşı
dağıtımı için uygun rotaların belirlenmesi:
Ankara ili örneği. Politeknik Dergisi, 26(1), 231-
241. https://doi.org/10.2339/politeknik.1014921
- [18] Dagistanli, H. A., & Üstün, Ö. (2023). An
integrated multi-criteria decision making and
multi-choice conic goal programming approach
for customer evaluation and manager
assignment. Decision Analytics Journal, 8,
100270.https://doi.org/10.1016/j.dajour.2023.100270
- [19] Altundaş, A., Kurtay, K. G., & Dağıstanlı, H.
A. (2023). KBRN Kiti Dağıtım Ağı Tasarımı
Optimizasyonu İçin Eş Zamanlı Topla Dağıt Araç
Rotalama Problemi Yaklaşımı. SAVSAD
Savunma ve Savaş Araştırmaları Dergisi, (1), 171-196.https://doi.org/10.54078/savsad.1370431
- [20] Dağistanli, H. A. (2023). Çok ürünlü çok
depolu araç rotalama problemi: askerî ilaç
fabrikası örneği. Politeknik Dergisi, 1-1.
https://doi.org/10.2339/politeknik.1224140
- [21] Desticioğlu, B., & Ayan, M. A. (2022).
Savunma Tedarik Konusunda Yapilan
Çalişmalarin Bibliyometrik Analizi. SAVSAD
Savunma ve Savaş Araştırmaları Dergisi, 32(1),
159-196.
https://doi.org/10.54078/savsad.1134266
- [22] Desticioglu Tasdemir, B., & Asilogullari
Ayan, M. (2023, May). Sustainable Supplier
Selection in the Defense Industry with Multicriteria Decision-Making Methods.
In International Symposium on Intelligent
Manufacturing and Service Systems (pp. 95-106).
Singapore: Springer Nature Singapore.
https://doi.org/10.1007/978-981-99-6062-0_10
- [23] Taliaferro, L. M., Gonzalez, M., Tillman, P.,
Ghosh, P., Clarke, W., Hinkle, A. C. ve John
Harvey, A. C. (2019a). Institute for defense
analyses defense governance and Management:
Improving the defense management capabilities
of foreign defense institutions A Guide to
Capability-Based Planning (CBP).
- [24] Petras, Z. (2017). Comparative analysis of
national approaches to military capability
planning. International Conference KnowledgeBased Organization, 23(1).
https://doi.org/10.1515/kbo-2017-0037
- [25] Ciocan, F. (2011). Perspectives on
interoperability integration within nato defense
planning process. Journal of Defense Resources
Management (JoDRM), 2(2).
- [26] NATO. (2003). Handbook on long term
defence planning work performed by the RTO
Studies, Analysis and Simulation Panel (SAS).
Distribution and Availability on Back Cover.
- [27] Holcombe, S. G., Johnston, N. C., Candreva,
P. ve Webb, N. J. (2008). Naval postgraduate
school monterey, california mba professional
report. Analysis of the PPBE Process in the
Current Dynamic Political Environment.
- [28] Church, A. T. W. (2009). DOD planning
programming budgeting and execution system.
JFQ Joint Force Quarterly, 53.
- [29] Nelson, D. (2002). Beyond defense
planning. Connections: The Quarterly Journal, 1(2). https://doi.org/10.11610/connections.01.2.08
- [30] Drew, D. M. ve Snow, D. M. (2006). Making
twenty-first-century strategy. An Introduction to
Modern National Security Processes and
Problems.
- [31] Par Malan, L. (2019). The process of defence
planning.
- [32] Saraçoğlu, İ., & Dağıstanlı, H. A. (2017).
Tedarikçi Seçiminde Bulanik Mantik-Ahp Ve
Vikor Yönteminin Bağlanti Elemanlari
Firmasinda Uygulanmasi. Yaşar Üniversitesi EDergisi, 12, 40-54.
- [33] Kurtay, K. G., Gökmen, Y., Altundaş, A., &
Dağıstanlı, H. A. (2021). Savunma Sanayii
Projelerinin Çok Kriterli Karar Verme
Yöntemleriyle Önceliklendirilmesi Ve
Karşilaştirilmasi: Karma Bir Model
Önerisi. Savsad Savunma ve Savaş Araştırmaları
Dergisi, 31(1), 1-24.
- [34] Erdal, H., Kurtay, K. G., Dagistanli, H. A.,
& Altundas, A. (2023). Evaluation of Anti-Tank
Guided Missiles: An integrated Fuzzy Entropy
and Fuzzy CoCoSo multi criteria methodology
using technical and simulation data. Applied Soft Computing, 137, 110145.
https://doi.org/10.1016/j.asoc.2023.110145
- [35] Begenirbaş, M., Kurtay, K. G., Dağistanli,
H. A., & Altundaş, A. (2023). Determining the
Importance Level of Effective Criteria in the
Employees in the Defense Acquisition Process
via Fuzzy DEMATEL Method. Journal of
Defense Sciences/Savunma Bilmleri
Dergisi, 2(43).
https://doi.org/10.17134/khosbd.1216154
- [36] Erdal, H., Kurtay, K. G., & Dağıstanlı, H. A.
(2024). Suggesting A Stochastic Measurement
Tool for Determining Crime and Safety Indexes:
Evidence from Turkey. Gazi University Journal
of Science, 37(1), 339-355.
https://doi.org/10.35378/gujs.1110735
- [37] Dağıstanlı, H. A., & Kurtay, K. G. (2024).
Facility Location Selection for Ammunition
Depots based on GIS and Pythagorean Fuzzy
WASPAS. Journal of Operations
Intelligence, 2(1), 36-49.
https://doi.org/10.31181/jopi2120247
- [38] Dağıstanlı, H. A., & Gencer, C. Hibrit Tehdit
Perspektifinden Orman Yangınları ve
Türkiye’nin Mücadele Politikası. SAVSAD
Savunma ve Savaş Araştırmaları Dergisi, (1), 35-
70. https://doi.org/10.54078/savsad.1377722
- [39] Dupuy, T. N. (1979). Using history to
evaluate combat factors and the outcome of
battles. numbers. Predictions and War.
- [40] Ciano, J. F. (1988). The Quantified
Judgment Model and historic ground combat.
Alındığı yer: http://hdl.handle.net/10945/23101
- [41] Hogg, D. (1993). Correlation of forces: The
quest for a standardized model. School of
Advanced Military Studles United States Ary
Command and General Staff College.
- [42] Erkut, E. ve Ingolfsson, A. (2005). Transport
risk models for hazardous materials: Revisited.
Operations Research Letters, 33(1).
https://doi.org/10.1016/j.orl.2004.02.006
- [43] Aaron, C., Taliaferro, L. M., Gonzalez, M.,
Tillman, P., Ghosh, P., Clarke, W., Hinkle, A. C.
ve John Harvey, A. C. (2019). Instıtute for
defense analyses defense governance and
management: Improving the defense
management capabilities of foreign defense
ınstitutions a guide to capability-based planning
(CBP).
- [44] Daǧdeviren, M., Yavuz, S. ve Kilinç, N.
(2009). Weapon selection using the AHP and
TOPSIS methods under fuzzy environment.
Expert Systems with Applications, 36(4).
https://doi.org/10.1016/j.eswa.2008.10.016
- [45] Lee, J., Kang, S. H., Rosenberger, J. ve Kim,
S. B. (2010). A hybrid approach of goal
programming for weapon systems selection.
Computers and Industrial Engineering, 58(3).
https://doi.org/10.1016/j.cie.2009.11.013
- [46] Cheng, C. H. (1999). Evaluating weapon
systems using ranking fuzzy numbers. Fuzzy Sets
and Systems, 107(1).
https://doi.org/10.1016/S0165-0114(97)00348-5
- [47] Yu, Z., Tan, Y. J., Yang, K. W. ve Yang, Z.
Y. (2012). Research on evolving capability
requirements oriented weapon system of systems
portfolio planning. Proceedings - 2012. 7th
International Conference on System of Systems
Engineering, SoSE 2012.
https://doi.org/10.1109/SYSoSE.2012.6384128
- [48] Zhang, S. T., Dou, Y. J. ve Zhao, Q. S.
(2014). Evaluation of capability of weapon
system of systems based on multi-scenario.
Advanced Materials Research, 926-930.
https://doi.org/10.4028/www.scientific.net/AMR
.926-930.3806
- [49] Kabak, M. (2011). Birlik hava savunma
önceliklerinin tespitine bulanık bir yaklaşım.
Savunma Bilimleri Dergisi, 10(2), 1-17.
- [50] https://www.unroca.org/categories
- [51] T.L. Saaty, A scaling method for priorities in
hierarchical structures, J. Math. Psych. 15 (3)
(1977) 234–281, http://dx.doi.org/10.1016/0022-
2496(77) 90033-5.
- [52] C.L. Hwang, K. Yoon, C.L. Hwang, K.
Yoon, Methods for multiple attribute decision
making, in: Multiple Attribute Decision Making:
Methods and Applications a State-of-the-Art
Survey, 1981, pp. 58–191,
Yetenek Temelli Risk Tabanlı Savunma Planlaması için Bulanık AHP-TOPSIS ile Silah Seçimi
Yıl 2024,
, 363 - 387, 01.11.2024
Serkan Aksoy
,
Memduh Begenirbaş
,
Kemal Gürol Kurtay
Öz
Yetenek temelli planlama (YTP), yeni bir paradigma olup stratejik veya uzun vadeli planlama için analitik bir çerçeve sunarak yetenek kavramını kullanmaktadır. Bu çalışmada askeri hedefleri sağlayabilecek yetenekler için 6 farklı senaryo oluşturulmuş ve buna göre YTP içerisinde her bir senaryo için meydana gelme riski hesabı yapılmıştır. Belirlenen hedeflerin başarılı olması için gerekli olan alt yetenekler tanımlanmıştır. Askeri hedeflerin karşılanmasına yönelik silah seçim problemi için Çok Kriterli Karar Verme (ÇKKV) yöntemlerinden Bulanık AHP ile kriter ağırlıkları hesaplanmış ve TOPSIS metodu ile önceliklendirilmesi yapılmıştır. Bu çalışmanın ana motivasyonu literatürdeki senaryo tabanlı yeteneklerin belirlenmesi ve değerlendirilmesi için karar süreçlerine ait analitik değerlendirmeye yönelik boşluğu doldurmaktır.
Kaynakça
- [1] Government, A. (2012). Defence capability development handbook 2012.
- [2] Gaidow, S. ve Boey, S. (2005). Australian Defence Risk Management Framework: A Comparative Study.
- [3] Barclay, C. ve Osei-Bryson, K. M. (2010). Project performance development framework: An approach for developing performance criteria & measures for information systems (IS) projects. International Journal of Production Economics, 124(1). https://doi.org/10.1016/j.ijpe.2009.11.025
- [4] Martinsuo, M. (2013). Project portfolio management in practice and in context.
International Journal of Project Management, 31(6). https://doi.org/10.1016/j.ijproman.2012.10.013
- [5] Davis, P. K. (2002). Analytic architecture for capabilities-based planning, mission-system analysis, and transformation. Rand Corporation.
- [6] Begenirbaş, M. (2022). Savunma yönetimi ve planlaması (1. Baskı). Nobel Akademik
Yayıncılık.
- [7] Stojkovic, D., Kankaras, M. ve Mitic, V. (2016). Determination of defence capability requirements. Vojno Delo, 68(8). https://doi.org/10.5937/vojdelo1608076s
- [8] Mezey, G. (2004). Defence planning of conventional forces. 3(5).
- [9] Campbell, A. (2010). Analytic implications of the NATO defence planning process. NATO C3 Agency.
- [10] Cimon, Y. (2017). Perspectives for the development of key industrial capabilities for Canada’s defence sector. Defense and Security Analysis, 33(4). https://doi.org/10.1080/14751798.2017.1377422
- [11] Palaz, H. (2008). Analitik hiyerarşi prosesi ve hedef programlama kullanılarak denizaltı kuvvet yapısının belirlenmesi (Yüksek Lisans Tezi). Hava Harp Okulu Komutanlığı Havacılık ve Uzay Teknolojileri Enstitüsü.
- [12] Bizkevelci, S. ve Çakmak, M. A. (2008).
Technology management model application in concept approval decision - Case study: Concept of operations and mission need assesment for a defence system. PICMET: Portland International Center for Management of Engineering and Technology, Proceedings.https://doi.org/10.1109/PICMET.2008.4599767
- [13] Hristov, N., Radulov, I., Iliev, P. ve
Andreeva, P. (2010). Prioritization methodology
for development of required operational
capabilities. Alındığı yer:
https://ssrn.com/abstract=3135696
- [14] Nesterenko, O., Netesin, I., Polischuk, V. ve
Trofymchuk, O. (2020). Development of a
procedure for expert estimation of capabilities in
defense planning under multicriterial conditions.
Eastern-European Journal of Enterprise
Technologies, 4(2-106): 33-43.
https://doi.org/10.15587/1729-
4061.2020.208603
- [15] Harrison, K. R., Elsayed, S., Garanovich, I.,
Weir, T., Galister, M., Boswell, S., Taylor, R. ve Sarker, R. (2020). Portfolio optimization for
defence applications. IEEE Access, 8: 60152-
60178.
https://doi.org/10.1109/ACCESS.2020.2983141
- [16] Kurtay, K. G., Dağıstanlı, H. A., & Erol, S.
(2021). Plastik Boru ve Kaynak Makinesi Seçim
Problemi için Analitik Hiyerarşi Prosesi ile Gri
İlişkisel Analiz Yöntemlerinin
Entegrasyonu. Savunma Bilimleri Dergisi, 2(40),
267-291.
https://doi.org/10.17134/khosbd.1001230
- [17] Desticioğlu, B., Kurtay, K. G., Altundaş, A.,
& Dağıstanlı, H. A. (2021). Hastanelere aşı
dağıtımı için uygun rotaların belirlenmesi:
Ankara ili örneği. Politeknik Dergisi, 26(1), 231-
241. https://doi.org/10.2339/politeknik.1014921
- [18] Dagistanli, H. A., & Üstün, Ö. (2023). An
integrated multi-criteria decision making and
multi-choice conic goal programming approach
for customer evaluation and manager
assignment. Decision Analytics Journal, 8,
100270.https://doi.org/10.1016/j.dajour.2023.100270
- [19] Altundaş, A., Kurtay, K. G., & Dağıstanlı, H.
A. (2023). KBRN Kiti Dağıtım Ağı Tasarımı
Optimizasyonu İçin Eş Zamanlı Topla Dağıt Araç
Rotalama Problemi Yaklaşımı. SAVSAD
Savunma ve Savaş Araştırmaları Dergisi, (1), 171-196.https://doi.org/10.54078/savsad.1370431
- [20] Dağistanli, H. A. (2023). Çok ürünlü çok
depolu araç rotalama problemi: askerî ilaç
fabrikası örneği. Politeknik Dergisi, 1-1.
https://doi.org/10.2339/politeknik.1224140
- [21] Desticioğlu, B., & Ayan, M. A. (2022).
Savunma Tedarik Konusunda Yapilan
Çalişmalarin Bibliyometrik Analizi. SAVSAD
Savunma ve Savaş Araştırmaları Dergisi, 32(1),
159-196.
https://doi.org/10.54078/savsad.1134266
- [22] Desticioglu Tasdemir, B., & Asilogullari
Ayan, M. (2023, May). Sustainable Supplier
Selection in the Defense Industry with Multicriteria Decision-Making Methods.
In International Symposium on Intelligent
Manufacturing and Service Systems (pp. 95-106).
Singapore: Springer Nature Singapore.
https://doi.org/10.1007/978-981-99-6062-0_10
- [23] Taliaferro, L. M., Gonzalez, M., Tillman, P.,
Ghosh, P., Clarke, W., Hinkle, A. C. ve John
Harvey, A. C. (2019a). Institute for defense
analyses defense governance and Management:
Improving the defense management capabilities
of foreign defense institutions A Guide to
Capability-Based Planning (CBP).
- [24] Petras, Z. (2017). Comparative analysis of
national approaches to military capability
planning. International Conference KnowledgeBased Organization, 23(1).
https://doi.org/10.1515/kbo-2017-0037
- [25] Ciocan, F. (2011). Perspectives on
interoperability integration within nato defense
planning process. Journal of Defense Resources
Management (JoDRM), 2(2).
- [26] NATO. (2003). Handbook on long term
defence planning work performed by the RTO
Studies, Analysis and Simulation Panel (SAS).
Distribution and Availability on Back Cover.
- [27] Holcombe, S. G., Johnston, N. C., Candreva,
P. ve Webb, N. J. (2008). Naval postgraduate
school monterey, california mba professional
report. Analysis of the PPBE Process in the
Current Dynamic Political Environment.
- [28] Church, A. T. W. (2009). DOD planning
programming budgeting and execution system.
JFQ Joint Force Quarterly, 53.
- [29] Nelson, D. (2002). Beyond defense
planning. Connections: The Quarterly Journal, 1(2). https://doi.org/10.11610/connections.01.2.08
- [30] Drew, D. M. ve Snow, D. M. (2006). Making
twenty-first-century strategy. An Introduction to
Modern National Security Processes and
Problems.
- [31] Par Malan, L. (2019). The process of defence
planning.
- [32] Saraçoğlu, İ., & Dağıstanlı, H. A. (2017).
Tedarikçi Seçiminde Bulanik Mantik-Ahp Ve
Vikor Yönteminin Bağlanti Elemanlari
Firmasinda Uygulanmasi. Yaşar Üniversitesi EDergisi, 12, 40-54.
- [33] Kurtay, K. G., Gökmen, Y., Altundaş, A., &
Dağıstanlı, H. A. (2021). Savunma Sanayii
Projelerinin Çok Kriterli Karar Verme
Yöntemleriyle Önceliklendirilmesi Ve
Karşilaştirilmasi: Karma Bir Model
Önerisi. Savsad Savunma ve Savaş Araştırmaları
Dergisi, 31(1), 1-24.
- [34] Erdal, H., Kurtay, K. G., Dagistanli, H. A.,
& Altundas, A. (2023). Evaluation of Anti-Tank
Guided Missiles: An integrated Fuzzy Entropy
and Fuzzy CoCoSo multi criteria methodology
using technical and simulation data. Applied Soft Computing, 137, 110145.
https://doi.org/10.1016/j.asoc.2023.110145
- [35] Begenirbaş, M., Kurtay, K. G., Dağistanli,
H. A., & Altundaş, A. (2023). Determining the
Importance Level of Effective Criteria in the
Employees in the Defense Acquisition Process
via Fuzzy DEMATEL Method. Journal of
Defense Sciences/Savunma Bilmleri
Dergisi, 2(43).
https://doi.org/10.17134/khosbd.1216154
- [36] Erdal, H., Kurtay, K. G., & Dağıstanlı, H. A.
(2024). Suggesting A Stochastic Measurement
Tool for Determining Crime and Safety Indexes:
Evidence from Turkey. Gazi University Journal
of Science, 37(1), 339-355.
https://doi.org/10.35378/gujs.1110735
- [37] Dağıstanlı, H. A., & Kurtay, K. G. (2024).
Facility Location Selection for Ammunition
Depots based on GIS and Pythagorean Fuzzy
WASPAS. Journal of Operations
Intelligence, 2(1), 36-49.
https://doi.org/10.31181/jopi2120247
- [38] Dağıstanlı, H. A., & Gencer, C. Hibrit Tehdit
Perspektifinden Orman Yangınları ve
Türkiye’nin Mücadele Politikası. SAVSAD
Savunma ve Savaş Araştırmaları Dergisi, (1), 35-
70. https://doi.org/10.54078/savsad.1377722
- [39] Dupuy, T. N. (1979). Using history to
evaluate combat factors and the outcome of
battles. numbers. Predictions and War.
- [40] Ciano, J. F. (1988). The Quantified
Judgment Model and historic ground combat.
Alındığı yer: http://hdl.handle.net/10945/23101
- [41] Hogg, D. (1993). Correlation of forces: The
quest for a standardized model. School of
Advanced Military Studles United States Ary
Command and General Staff College.
- [42] Erkut, E. ve Ingolfsson, A. (2005). Transport
risk models for hazardous materials: Revisited.
Operations Research Letters, 33(1).
https://doi.org/10.1016/j.orl.2004.02.006
- [43] Aaron, C., Taliaferro, L. M., Gonzalez, M.,
Tillman, P., Ghosh, P., Clarke, W., Hinkle, A. C.
ve John Harvey, A. C. (2019). Instıtute for
defense analyses defense governance and
management: Improving the defense
management capabilities of foreign defense
ınstitutions a guide to capability-based planning
(CBP).
- [44] Daǧdeviren, M., Yavuz, S. ve Kilinç, N.
(2009). Weapon selection using the AHP and
TOPSIS methods under fuzzy environment.
Expert Systems with Applications, 36(4).
https://doi.org/10.1016/j.eswa.2008.10.016
- [45] Lee, J., Kang, S. H., Rosenberger, J. ve Kim,
S. B. (2010). A hybrid approach of goal
programming for weapon systems selection.
Computers and Industrial Engineering, 58(3).
https://doi.org/10.1016/j.cie.2009.11.013
- [46] Cheng, C. H. (1999). Evaluating weapon
systems using ranking fuzzy numbers. Fuzzy Sets
and Systems, 107(1).
https://doi.org/10.1016/S0165-0114(97)00348-5
- [47] Yu, Z., Tan, Y. J., Yang, K. W. ve Yang, Z.
Y. (2012). Research on evolving capability
requirements oriented weapon system of systems
portfolio planning. Proceedings - 2012. 7th
International Conference on System of Systems
Engineering, SoSE 2012.
https://doi.org/10.1109/SYSoSE.2012.6384128
- [48] Zhang, S. T., Dou, Y. J. ve Zhao, Q. S.
(2014). Evaluation of capability of weapon
system of systems based on multi-scenario.
Advanced Materials Research, 926-930.
https://doi.org/10.4028/www.scientific.net/AMR
.926-930.3806
- [49] Kabak, M. (2011). Birlik hava savunma
önceliklerinin tespitine bulanık bir yaklaşım.
Savunma Bilimleri Dergisi, 10(2), 1-17.
- [50] https://www.unroca.org/categories
- [51] T.L. Saaty, A scaling method for priorities in
hierarchical structures, J. Math. Psych. 15 (3)
(1977) 234–281, http://dx.doi.org/10.1016/0022-
2496(77) 90033-5.
- [52] C.L. Hwang, K. Yoon, C.L. Hwang, K.
Yoon, Methods for multiple attribute decision
making, in: Multiple Attribute Decision Making:
Methods and Applications a State-of-the-Art
Survey, 1981, pp. 58–191,