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EVALUATION OF INNOVATIVE CULTURE STRUCTURE OF THE MACHINE MANUFACTURING FIRM BY AXIOMATIC DESIGN

Yıl 2009, Sayı: 020, 45 - 62, 15.12.2009

Öz

Axiomatic Design (AD) is one of the multi-criteria
decision-making methods that can be used for solving problems involving both quantitative
and qualitative criteria in decision-making process. In this study is
investigated the innovative culture structures of machine manufacturers. Firstly,
the attributes and the criteria of innovative culture structure are determined.
Following that, a questionnaire is prepared and applied to 16 distinct machine
manufacturers. Afterwards, on the basis of the information axiom of AD, the evaluation
of firms’ innovative culture structures is proposed.  For the case that there are priorities among
the criteria, weighted AD method is applied and the results of AD and weigted
AD methods are compared.



 

Kaynakça

  • [1] Arıkan, C., Aksoy, M., Durgut, M. ve Göker, A., (2003), Ulusual İnovasyon Sistemi Kavramsal Çerçeve, Türkiye İncelemesi ve Ülke Örnekleri, Yayın No. TÜSİAT-T/2003/10/362, İstanbul.
  • [2] Onuk K., (2004), Entwicklung Eines Softwaresystems Zur Innovationssteigerung von KMU’s, İstanbul.
  • [3] Dağdeviren, M. ve Eraslan, E., “PROMETHEE sıralama yöntemi ile tedarikçi seçimi”, Gazi Üniversitesi Mühendislik Mimarlık Fakültesi Dergisi,Cilt 23, No 1, 69-75 (2008).
  • [4] Eldem C. ve Ercan F., “Tasarımda Kalite Anlayışı ve Kalite Kontrolü” 9. Uluslararası Makina Tasarım ve İmalat Kongresi (2000).
  • [5] Shigley, J.E., and L.D. Mitchell, “Mechanical Engineering Design”, 4th ed., Mc Graw Hill,(1983).
  • [6] Ertaş, B., Jones, J., C.,”The Engineering Design Process”, John Wiley and Sons Inc., (1993).
  • [7] Norton, R., L., “Machine Design, An Integrated Approach”, Prentice Hall Inc., (1996).
  • [8] Kanbur, F. ve Birgün, S., “Yeni Kariyere Geçiş Danışmanlığı İçin Kavramsal Bir Model : FATRA”, İstanbul Ticaret Üniversitesi Fen Bilimleri Dergisi Yıl:7 Sayı:13, 117-137 (2008).
  • [9] Kahraman C. and Cebi S., “A new multi-attribute decision making method: Hierarchical fuzzy axiomatic design”, Expert Systems with Applications, 36: 4848–4861 (2009).
  • [10] Çelik M. and Er I.D., “Fuzzy axiomatic design extension for managing model selection paradigm in decision science”, Expert Systems with Applications 36: 6477–6484 (2009).
  • [11] Çelik M., Cebi S., Kahraman C. and Er I.D., “Application of axiomatic design and TOPSIS methodologies under fuzzy environment for proposing competitive strategies on Turkish container ports in maritime transportation network”, Energy and Buildings 41:146–153 (2009).
  • [12] Çelik M., Kahraman C., Cebi S. and Er I.D., “Fuzzy axiomatic design-based performance evaluation model for docking facilities in shipbuilding industry: The case of Turkish shipyards”, Expert Systems with Applications 36: 599–615 (2009).
  • [13] Bang I.C. and Heo G., “An axiomatic design approach in development of nanofluid coolants”, Applied Thermal Engineering 29: 75–90 (2009).
  • [14] Togay C., Doğru A.H. and Tanik J.U., “Systematic Component-Oriented development with Axiomatic Design”, The Journal of Systems and Software 81: 1803–1815 (2008).
  • [15] Durmuşoğlu M.B. and Kulak O., “Amethodology for the design of office cells using axiomatic design principles”, Omega 36: 633 – 652 (2008).
  • [16] Gonçalves-Coelho A.M. and Mourao A.J.F., “Axiomatic design as support for decision-making in a design for manufacturing context: A case study”, Int. J. Production Economics 109: 81–89 (2007).
  • [17] Stiassnie E. and Shpitalni M., “Incorporating Lifecycle Considerations in Axiomatic Design”, Annals of the CIRP Vol. 56/1 (2007).
  • [18] Kulak O., Durmuşoğlu M.B. and Tüfekçi S., “A complete cellular manufacturing system design methodology based on axiomatic design principles”, Computers & Industrial Engineering 48: 765–787 (2005).
  • [19] Thielmana J., Gea P., Wub Q. and Parmec L., “Evaluation and optimization of General Atomics’ GT-MHR reactor cavity cooling system using an axiomatic design approach”, Nuclear Engineering and Design 235: 1389–1402 (2005).
  • [20] Pappalardo M. and Naddeo A., “Failure mode analysis using axiomatic design and non-probabilistic information”, Journal of Materials Processing Technology 164–165 : 1423–1429 (2005).
  • [21] Brown C.A., “Teaching Axiomatic Design to Engineers - Theory, Applications, and Software”, Journal of Manufacturing Systems Vol. 24/No.3 (2005).
  • [22] Yia J.W. and Park G.J., “Development of a design system for EPS cushioning package of a monitor using axiomatic design”, Advances in Engineering Software 36: 273–284 (2005).
  • [23] Kulak O. and Kahraman C., “Multi-attribute comparison ofadvanced manufacturing systems using fuzzy vs. crisp axiomatic design approach”, Int. J. Production Economics 95: 415–424 (2005).
  • [24] Kulak O. and Kahraman C., “Fuzzy multi-attribute selection among transportation companies using axiomatic design and analytic hierarchy process”, Information Sciences 170: 191–210 (2005).
  • [25] Bae S., Lee J.M. and Chu C.N., “Axiomatic Design of Automotive Suspension Systems”, CIRP Annals - Manufacturing Technology, Volume 51, Issue 1, 2002, Pages 115-118
  • [26] Lee K.D., Suh N.P and Oh J.H., “Axiomatic Design of Machine Control System”, CIRP Annals - Manufacturing Technology, Volume 50, Issue 1, 2001, Pages 109-114
  • [27] Gu P., Rao H. A. and Tseng M. M., “Systematic Design of Manufacturing Systems Based on Axiomatic Design Approach”, CIRP Annals - Manufacturing Technology, Volume 50, Issue 1, 2001, Pages 299-304
  • [28] Suh N.P. and Do S.H., “Axiomatic Design of Software Systems”, Annals of the ClRP Vol. 49/1 (2000).
  • [29] Suh, N.P., The Principles of Design. Oxford University Press, New York, (1990)
  • [30] Suh, N.P., Axiomatic Design—Advances and Applications, Oxford University Press, New York (2001)
  • [31] Özel B. ve Özyörük B., Bulanık Aksiyomatik Tasarım ile Tedarikçi Firma Seçimi, Gazi Üniv. Müh. Mim. Fak. Der. Cilt 22, No 3, 415-423 (2007)
  • [32] Suh, N.P., “Axiomatic Design Theory for Systems”, Research in Engineering Design Cilt 10, 189–209 (1998)
  • [33] Saaty, T., The Analytic Hierarchy Process, McGraw-Hill International Book Company, USA (1980)
  • [34] Houshmand, M. and Jamshidnezhad, B., “Conceptual Design of Lean Production Systems through an Axiomatic Design”, Proceedings of ICAT 2002, Second International Conference on Axiomatic Design, Cambridge, MA (ICAT033), 1-12 (2002)
  • [35] Dane, A., “İlköğretim Matematik 3. Sınıf Öğrencilerinin Tanım, Aksiyom ve Teorem Kavramlarını Anlama Düzeyleri”, Kastamonu Eğitim Dergisi, Cilt:16, No:2, 495-506 (2008).
  • [36] Lumpkin,G.T and Dess,G.G., “Linking two dimensions of entrepreneurial orientation to firm performance: the moderating role of environment and industry life cycle”, Journal of Business Venturing, Vol:16, 429-451 ( 2001)
  • [37] Menon,A., Bharadwaj,S.G.Adidam,P.T. and Edison,S.W, “ Antecedents and consequences of Marketing strategy making: a model and a test”, Journal of Marketing, Vol.63 (April), 18-40 (1999).
  • [38] Slater,S.F. and Narver,J.C., ”Market Orientation And The Learning Organization”, Journal of Marketing, Vol.59 (July), 63-74 (1995).
  • [39] Akman, G, Bilişim Sektöründe Pazar Odaklılık, Yenilik Stratejileri Ve Yenilik Kabiliyeti Arasındaki İlişkiler Ve Bunların Şirket Performansı Üzerindeki Etkileri, Basılmamış Doktora Tezi, GebzeYüksek Teknoloji Enstitüsü, İşletme ABD.2003.
  • [40] Venkatraman,N., ”Strategic orientation of business enterprises: the construct , dimensionality and measurement” Management Science, Vol.35, No.8, 942-962 (1989).
  • [41] Bluedorn, A. C., Johnson, R. A., Cartwright, D. K., And Barringer, B. R., “The interface and convergence of the strategic management and organizational environment domains”, Journal of Management, Vol.20, 201–262 (1994).
  • [42] Kandampully,J. and Duddy,R., “Competitive advantage through anticipation, innovation and relations”, Management Decision, Vol.37/1, 51-56 (1999)
  • [43] Miller,D. and Friesen,P., ”Archetypes of strategy formulation”, Management Science, Vol.24, 921-933 (1978).
  • [44] Lyon, D.W., Lumpkin, G.T. and Dess, G.G., “Enhancing entrepreneurial Orientation research operationalizing and measuring a key strategic decision making process”, Journal of Management, Vol. 6, No.5, 1055-1085 (2000).
  • [45] Entrialgo, M., Ferna´ndez ,E., and Va´zquez,C.J., ”Linking entrepreneurship and strategic management: evidence from Spanish SMEs “, Technovation, Vol.20, 427-436 (2000).
  • [46] Morgan,R.E. and Strong,C.A., “Market orientation and dimensions of strategic orientation”, European Journal of Marketing .Vol.32,No:11/12 , 1051-1073 (1998).
  • [47] Ho,C.H., ”A contingency theoretical model of manufacturing strategy”, International Journal of Operations&Production Management, Vol.16, No.5, 74-98 (1996).
  • [48] Celuch, K.G., Kasoug, C.J. and Peruvemba,V., “The effects of perceived market and learning orientation on assessed organizational capabilities”, Industrial Marketing Management, Vol.31, 545-554 (2002).
  • [49] Baker, W.E. And Sinkula, J. M., ”Learning orientation, market orientation and innovation: integrating and extending models of organizational performance”, Journal of Market Focused Management, Vol.4, 295-308 (1999).
  • [50] Un,C.A., Innovative capability development in U.S. and Japanese firms”, Academy of Management Proceedings, 1-6 (2002).
  • [51] Szeto,E., ”Innovation capacity: working towards a mechanism for improving innovation within an inter-organizational network”, The TQM Magazine, Vol.12, No.2, 149-157 (2000).
  • [52] Romijn,H. And Albaladojo,M., “Determinants of innovation capability in small electronics and software firms in southeast England”, Research Policy, Vol.21, 1053-1067 (2002).

MAKİNE İMALATI YAPAN FİRMALARIN YENİLİKÇİ KÜLTÜR YAPILARININ AKSİYOMATİK TASARIM İLE DEĞERLENDİRİLMESİ

Yıl 2009, Sayı: 020, 45 - 62, 15.12.2009

Öz

Aksiyomlarla Tasarım (AT) karar verme
sürecinde hem nicel hem de nitel kriterlerin dikkate alınmasını gerektiren
problemlerin çözümünde kullanılabilen çok ölçütlü karar verme yöntemlerinden
birisidir. Bu çalışmada, makine imalatı yapan firmaların yenilikçi kültür
yapıları değerlendirilmiştir. Öncelikle, yenilikçi kültür özellikleri ve
kriterleri belirlenmiş, sonra bu kriterleri içeren bir anket formu
hazırlanmıştır. Anket 16 makine üreticisi firmaya uygulanmıştır. Daha sonra,
AT’nin bilgi aksiyomuna dayanarak alternatif firmaların yenilikçi kültür
yapılarının değerlendirmesi yapılmıştır. 
Ayrıca, kriterlerin kendi aralarında önceliklerinin olduğu durum göz
önüne alınarak Ağırlıklı AT kullanılmış ve her iki yöntemin sonuçları
karşılaştırılmıştır.

Kaynakça

  • [1] Arıkan, C., Aksoy, M., Durgut, M. ve Göker, A., (2003), Ulusual İnovasyon Sistemi Kavramsal Çerçeve, Türkiye İncelemesi ve Ülke Örnekleri, Yayın No. TÜSİAT-T/2003/10/362, İstanbul.
  • [2] Onuk K., (2004), Entwicklung Eines Softwaresystems Zur Innovationssteigerung von KMU’s, İstanbul.
  • [3] Dağdeviren, M. ve Eraslan, E., “PROMETHEE sıralama yöntemi ile tedarikçi seçimi”, Gazi Üniversitesi Mühendislik Mimarlık Fakültesi Dergisi,Cilt 23, No 1, 69-75 (2008).
  • [4] Eldem C. ve Ercan F., “Tasarımda Kalite Anlayışı ve Kalite Kontrolü” 9. Uluslararası Makina Tasarım ve İmalat Kongresi (2000).
  • [5] Shigley, J.E., and L.D. Mitchell, “Mechanical Engineering Design”, 4th ed., Mc Graw Hill,(1983).
  • [6] Ertaş, B., Jones, J., C.,”The Engineering Design Process”, John Wiley and Sons Inc., (1993).
  • [7] Norton, R., L., “Machine Design, An Integrated Approach”, Prentice Hall Inc., (1996).
  • [8] Kanbur, F. ve Birgün, S., “Yeni Kariyere Geçiş Danışmanlığı İçin Kavramsal Bir Model : FATRA”, İstanbul Ticaret Üniversitesi Fen Bilimleri Dergisi Yıl:7 Sayı:13, 117-137 (2008).
  • [9] Kahraman C. and Cebi S., “A new multi-attribute decision making method: Hierarchical fuzzy axiomatic design”, Expert Systems with Applications, 36: 4848–4861 (2009).
  • [10] Çelik M. and Er I.D., “Fuzzy axiomatic design extension for managing model selection paradigm in decision science”, Expert Systems with Applications 36: 6477–6484 (2009).
  • [11] Çelik M., Cebi S., Kahraman C. and Er I.D., “Application of axiomatic design and TOPSIS methodologies under fuzzy environment for proposing competitive strategies on Turkish container ports in maritime transportation network”, Energy and Buildings 41:146–153 (2009).
  • [12] Çelik M., Kahraman C., Cebi S. and Er I.D., “Fuzzy axiomatic design-based performance evaluation model for docking facilities in shipbuilding industry: The case of Turkish shipyards”, Expert Systems with Applications 36: 599–615 (2009).
  • [13] Bang I.C. and Heo G., “An axiomatic design approach in development of nanofluid coolants”, Applied Thermal Engineering 29: 75–90 (2009).
  • [14] Togay C., Doğru A.H. and Tanik J.U., “Systematic Component-Oriented development with Axiomatic Design”, The Journal of Systems and Software 81: 1803–1815 (2008).
  • [15] Durmuşoğlu M.B. and Kulak O., “Amethodology for the design of office cells using axiomatic design principles”, Omega 36: 633 – 652 (2008).
  • [16] Gonçalves-Coelho A.M. and Mourao A.J.F., “Axiomatic design as support for decision-making in a design for manufacturing context: A case study”, Int. J. Production Economics 109: 81–89 (2007).
  • [17] Stiassnie E. and Shpitalni M., “Incorporating Lifecycle Considerations in Axiomatic Design”, Annals of the CIRP Vol. 56/1 (2007).
  • [18] Kulak O., Durmuşoğlu M.B. and Tüfekçi S., “A complete cellular manufacturing system design methodology based on axiomatic design principles”, Computers & Industrial Engineering 48: 765–787 (2005).
  • [19] Thielmana J., Gea P., Wub Q. and Parmec L., “Evaluation and optimization of General Atomics’ GT-MHR reactor cavity cooling system using an axiomatic design approach”, Nuclear Engineering and Design 235: 1389–1402 (2005).
  • [20] Pappalardo M. and Naddeo A., “Failure mode analysis using axiomatic design and non-probabilistic information”, Journal of Materials Processing Technology 164–165 : 1423–1429 (2005).
  • [21] Brown C.A., “Teaching Axiomatic Design to Engineers - Theory, Applications, and Software”, Journal of Manufacturing Systems Vol. 24/No.3 (2005).
  • [22] Yia J.W. and Park G.J., “Development of a design system for EPS cushioning package of a monitor using axiomatic design”, Advances in Engineering Software 36: 273–284 (2005).
  • [23] Kulak O. and Kahraman C., “Multi-attribute comparison ofadvanced manufacturing systems using fuzzy vs. crisp axiomatic design approach”, Int. J. Production Economics 95: 415–424 (2005).
  • [24] Kulak O. and Kahraman C., “Fuzzy multi-attribute selection among transportation companies using axiomatic design and analytic hierarchy process”, Information Sciences 170: 191–210 (2005).
  • [25] Bae S., Lee J.M. and Chu C.N., “Axiomatic Design of Automotive Suspension Systems”, CIRP Annals - Manufacturing Technology, Volume 51, Issue 1, 2002, Pages 115-118
  • [26] Lee K.D., Suh N.P and Oh J.H., “Axiomatic Design of Machine Control System”, CIRP Annals - Manufacturing Technology, Volume 50, Issue 1, 2001, Pages 109-114
  • [27] Gu P., Rao H. A. and Tseng M. M., “Systematic Design of Manufacturing Systems Based on Axiomatic Design Approach”, CIRP Annals - Manufacturing Technology, Volume 50, Issue 1, 2001, Pages 299-304
  • [28] Suh N.P. and Do S.H., “Axiomatic Design of Software Systems”, Annals of the ClRP Vol. 49/1 (2000).
  • [29] Suh, N.P., The Principles of Design. Oxford University Press, New York, (1990)
  • [30] Suh, N.P., Axiomatic Design—Advances and Applications, Oxford University Press, New York (2001)
  • [31] Özel B. ve Özyörük B., Bulanık Aksiyomatik Tasarım ile Tedarikçi Firma Seçimi, Gazi Üniv. Müh. Mim. Fak. Der. Cilt 22, No 3, 415-423 (2007)
  • [32] Suh, N.P., “Axiomatic Design Theory for Systems”, Research in Engineering Design Cilt 10, 189–209 (1998)
  • [33] Saaty, T., The Analytic Hierarchy Process, McGraw-Hill International Book Company, USA (1980)
  • [34] Houshmand, M. and Jamshidnezhad, B., “Conceptual Design of Lean Production Systems through an Axiomatic Design”, Proceedings of ICAT 2002, Second International Conference on Axiomatic Design, Cambridge, MA (ICAT033), 1-12 (2002)
  • [35] Dane, A., “İlköğretim Matematik 3. Sınıf Öğrencilerinin Tanım, Aksiyom ve Teorem Kavramlarını Anlama Düzeyleri”, Kastamonu Eğitim Dergisi, Cilt:16, No:2, 495-506 (2008).
  • [36] Lumpkin,G.T and Dess,G.G., “Linking two dimensions of entrepreneurial orientation to firm performance: the moderating role of environment and industry life cycle”, Journal of Business Venturing, Vol:16, 429-451 ( 2001)
  • [37] Menon,A., Bharadwaj,S.G.Adidam,P.T. and Edison,S.W, “ Antecedents and consequences of Marketing strategy making: a model and a test”, Journal of Marketing, Vol.63 (April), 18-40 (1999).
  • [38] Slater,S.F. and Narver,J.C., ”Market Orientation And The Learning Organization”, Journal of Marketing, Vol.59 (July), 63-74 (1995).
  • [39] Akman, G, Bilişim Sektöründe Pazar Odaklılık, Yenilik Stratejileri Ve Yenilik Kabiliyeti Arasındaki İlişkiler Ve Bunların Şirket Performansı Üzerindeki Etkileri, Basılmamış Doktora Tezi, GebzeYüksek Teknoloji Enstitüsü, İşletme ABD.2003.
  • [40] Venkatraman,N., ”Strategic orientation of business enterprises: the construct , dimensionality and measurement” Management Science, Vol.35, No.8, 942-962 (1989).
  • [41] Bluedorn, A. C., Johnson, R. A., Cartwright, D. K., And Barringer, B. R., “The interface and convergence of the strategic management and organizational environment domains”, Journal of Management, Vol.20, 201–262 (1994).
  • [42] Kandampully,J. and Duddy,R., “Competitive advantage through anticipation, innovation and relations”, Management Decision, Vol.37/1, 51-56 (1999)
  • [43] Miller,D. and Friesen,P., ”Archetypes of strategy formulation”, Management Science, Vol.24, 921-933 (1978).
  • [44] Lyon, D.W., Lumpkin, G.T. and Dess, G.G., “Enhancing entrepreneurial Orientation research operationalizing and measuring a key strategic decision making process”, Journal of Management, Vol. 6, No.5, 1055-1085 (2000).
  • [45] Entrialgo, M., Ferna´ndez ,E., and Va´zquez,C.J., ”Linking entrepreneurship and strategic management: evidence from Spanish SMEs “, Technovation, Vol.20, 427-436 (2000).
  • [46] Morgan,R.E. and Strong,C.A., “Market orientation and dimensions of strategic orientation”, European Journal of Marketing .Vol.32,No:11/12 , 1051-1073 (1998).
  • [47] Ho,C.H., ”A contingency theoretical model of manufacturing strategy”, International Journal of Operations&Production Management, Vol.16, No.5, 74-98 (1996).
  • [48] Celuch, K.G., Kasoug, C.J. and Peruvemba,V., “The effects of perceived market and learning orientation on assessed organizational capabilities”, Industrial Marketing Management, Vol.31, 545-554 (2002).
  • [49] Baker, W.E. And Sinkula, J. M., ”Learning orientation, market orientation and innovation: integrating and extending models of organizational performance”, Journal of Market Focused Management, Vol.4, 295-308 (1999).
  • [50] Un,C.A., Innovative capability development in U.S. and Japanese firms”, Academy of Management Proceedings, 1-6 (2002).
  • [51] Szeto,E., ”Innovation capacity: working towards a mechanism for improving innovation within an inter-organizational network”, The TQM Magazine, Vol.12, No.2, 149-157 (2000).
  • [52] Romijn,H. And Albaladojo,M., “Determinants of innovation capability in small electronics and software firms in southeast England”, Research Policy, Vol.21, 1053-1067 (2002).
Toplam 52 adet kaynakça vardır.

Ayrıntılar

Birincil Dil Türkçe
Konular Mühendislik
Bölüm Makaleler
Yazarlar

Mümtaz Karataş

Gülşen Akman

Yayımlanma Tarihi 15 Aralık 2009
Yayımlandığı Sayı Yıl 2009 Sayı: 020

Kaynak Göster

APA Karataş, M., & Akman, G. (2009). MAKİNE İMALATI YAPAN FİRMALARIN YENİLİKÇİ KÜLTÜR YAPILARININ AKSİYOMATİK TASARIM İLE DEĞERLENDİRİLMESİ. Journal of Science and Technology of Dumlupınar University(020), 45-62.