本研究首先以LED閱讀燈為設計改良載具，搜尋有關LED閱讀燈現有的期刊、專利、論文等知識文件資料，再將LED閱讀燈散熱性、整體結構設計與LED主體燈源之技術功能分類，每項方案包含兩種我們所針對LED閱讀燈散熱性、整體結構設計與LED燈源主體所改良的技術。此三種創新方案以修正式FUZZY ANP及ANP去比較決定三個創新方案的優先順序。本研究將常態化數值間比較的數值差距較大，採用較大的比例分配為一單位重要尺度。若常態化數值間比較的數值差距較小，則採用較小的比例來分配重要尺度。並將修正式FUZZY ANP搭配三角形歸屬函數，判定常態化數值之差距位於兩個三角形交集的模糊地帶，採用α-cut的觀念，若歸屬函數α≧0.5則其歸屬於1，若歸屬函數α<0.5則其歸屬於0，比較結果證實修正式FUZZY ANP所評比的結果優於ANP所決定出來的方案。故本文以修正式FUZZY ANP模糊分析網路程序法為決定創新方案的優先順序，並將載具LED立/桌燈沿用修正式FUZZY ANP方法。本研究案例初步擬定針對「LED立/桌燈」FUZZY ANP方案中欲改善「立/桌燈整體結構」、「立/桌燈散熱性」、「LED燈源主體」的三項技術中，將方案A分為「立/桌燈散熱性+立/桌燈整體結構」、方案B分為「立/桌燈整體結構+ LED燈源主體」、方案C分為「立/桌燈散熱性+ LED燈源主體」，經由立/桌燈產品之相關文獻探討及各項專利，將伸縮桿、連接頭、散熱鰭片、散熱座、發光源、燈泡造型、燈罩為評選產品設計方案時重要的評估準則，本研究將常態化數值加入位置權重概念計算，將原本的常態化數值改良，使創新方案的決策更為精準。首先將目標及評估準則屬性建立階層關係，同時考量各準則屬性之間相互影響的關係，展開成網路架構。接者修正式FUZZY ANP須考慮各評估準則間內部的相互依存關係，因此本研究採用專利技術字檢索中搜尋到的關鍵字與該項技術中所出現關鍵字出現的位置權重概念計算之常態化數值比例，並在相關技術專利中如有發現這相同專利關鍵字，由此來判斷評估準則間的相依性。最後再對各方案間內部相互依存關係做相對重要度比對。至於各方案間內部相互依存之相對重要尺度比例判斷，為將方案內的兩種創新技術針對所要比對的評估準則間具有內部相依性的關鍵技術字的位置權重概念計算之常態化數值比例加總，將加總後之值代入各項相對重要度比對所形成的成對比較矩陣，進一步所算出各權重值以及特徵向量。利用本文之修正式FUZZY ANP模糊分析網路程序法，將各項相對重要度比對的成對比較矩陣再代入其超級矩陣內，並計算出優先權重值，最後以各創新方案所計算出來的優先權重值，來進行產品方案的評選與決策，以決定創新方案的優先順序。最後演算後得三個技術設計方案之優先權值，重要優先順序為方案C＞方案B＞方案A；而權值最高者即為最佳選擇方案。也就是說，方案C為經評選後最符合LED立/桌燈之最佳產品設計方案。
經本文之研究結果顯示，本文再利用修正式TRIZ發明法做改良創新技術，針對方案C的兩項技術做改良創新，以節省開發人員開發產品所需的時程。

Taking LED reading lamp as a carrier of design correction, the study searches the related knowledge and information from the existing journals, patent documents and research thesises about LED reading lamp, and then classifies the techniques functions of LED reading lamp into heat dissipation, overall structural design and main structure of LED light source. Each plan contains two modified techniques for heat dissipation, overall structural design and main structure of LED light source of LED reading lamp respectively.The priority order of these three innovation plans is determined after comparison by modified fuzzy analytic network process (fuzzy ANP) and ANP. In this study,when the numerical difference between normalized numerical values is greater, a greater proportion for distribution is taken as the importance scale for one unit. If the numerical difference between normalized numerical values is smaller, a smaller proportion for distribution is taken as the importance scale. Having attached triangular membership function to modified fuzzy ANP, it is determined that normalized difference is situated at the fuzzy zone where two triangles intersect. Employing α-cut concept, if membership function is α≧0.5, it belongs to 1; and if membership function is α<0.5, it belongs to 0. As verified from the comparative results, the comparative result of modified fuzzy ANP is better than the plan determined by ANP. Therefore, the paper employs modified fuzzy ANP to determine the priority order of innovation plans, and hence uses modified fuzzy ANP for the carrier, LED standing/desk lamp. The case study preliminarily focuses on three techniques to be improved in fuzzy ANP plan of LED standing/desk lamp, namely overall structure of standing/desk lamp, heat dissipation of standing/desk lamp, and main structure of LED light source. Plan A is divided into “heat dissipation of standing/desk lamp + overall structure of standing/desk lamp.” Plan B is divided into “overall structure of standing/desk lamp + main structure of LED light source.” Plan C is divided into “heat dissipation of standing/desk lamp + main structure of LED light source.” After exploration of different references and patents about standing/desk lamp products, the study takes extendable rod, connector, heat dissipation fin, heat sink, light source, light bulb shape and lamp shade as the important evaluation standards for selection of product design plan. The study adds in position weight concept for calculation of normalized numerical values, improving the original normalized numerical values and making the decisions of innovation plan more precise. First of all, hierarchical relationship is established for objectives and evaluation criteria attributes. Meanwhile, the study considers the mutual effects of different criteria attributes, and develops them as a network structure. After that, modified fuzzy ANP has to consider the internal interdependence among the various evaluation criteria. Therefore, the study adopts the keywords searched from retrieval of patents’ technical words and the proportion normalized value calculated by position weight concept of the keywords appeared in this technique, and also the same patents’ keywords if found in the related technical patents. Then the study can use this way to judge the interdependence among the evaluation criteria. Finally, comparison of relative importance is made based on the internal interdependence among different plans. As to judgment of relative importance scale proportion of the internal interdependence among different plans, it adds up the proportions of normalized value, calculated by position weight concept, of the key technical words with internal interdependence among the evaluation criteria of two innovation techniques to be compared in the plan. The sum is substituted in the pairwise comparison matrix formed after comparing the relative importance of different items. Furthermore, each weight value and feature vector are calculated. Using the developed modified fuzzy ANP, the paper substitutes the pairwise comparison matrix, formed after comparing the relative importance of different items, in its supermatrix, and calculates the prioritized weight value. Finally, the paper uses the prioritized weight values calculated by different innovation plans to make selection and strategic decision for product plans, and decide the priority order of innovation plans. Finally, after calculation, the prioritized weight values of three technical design plans. The priority order of importance for the three plans is: Plan C > Plan B > Plan A. The plan with the highest weight value is just the best choice of plan. It implies that Plan C is the best product design plan for LED standing/desk lam after selection.
According to the above research results,this study further uses the modified TRIZ invention method to improve innovation techniques. Focusing on the two techniques of Plan C, improvement of innovation techniques can be made in order to save the time required by staff in development of new products.

[1].Holonyak, J. N. and Bevacqua, S. F. “Coherent (visible) light emission from Ga (As1-xPx) junctions,” Applied Physics Letters, Vol.1, Issue 4, pp.82-83 (1962).
[2].Steigerwald, D. A., Bhat, J. C., Collins, D., Fletcher, R. M., Holcomb, M.O., Ludowise, M. J., Martin, P. S., and Rudaz, S. L. “Illumination with Solid State Lighting Technology,” IEEE Journal of Selected Topics in Quantum Electronics, Vol.8, Issue 2, pp.310-320 (2002).
[3].McGlen, R.J., Jachuck, R., and Lin, S., “Integrated Thermal Management Techniques for High Power Electronic Devices,” Applied Thermal Engineering, Vol.24, Issue 8-9, pp.1143-1156 (2004).
[4].Jang, D., Yu, S.H., and Lee, K.S., “Multidisciplinary optimization of a pin-fin radial heat sink for LED lighting applications,” International Journal of Heat and Mass Transfer, Vol.55, Issue 4, pp.515-521 (2012).
[5].Culham, J. R. and Muzychka, Y. S., “Optimization of Plate Fin Heat Sinks Using Entropy Generation Minimization, ” IEEE Transactions on Components and Packaging Technologies, Vol.24, pp.159-165 (2001).
[6].呂豪文，「LED立燈」，台灣發明專利，D154316 (2013)。
[7].Wang, S. C., “Telescopic display stand,” U.S. Patent Application Publication, US7185868/7185868B2 (2007).
[8].沈峰民，「適用於發光二極體照明設備之調光電路與控制方法」，台灣發明專利，I434616 (2014)。
[9].黃献隆，「廣角照射LED燈具構造」，台灣發明專利，M389809 (2010)。
[10].Ma, Z., Wang, X., Zhu, D., and Liu, S., “Thermal analysis and modeling of LED arrays integrated with an innovative liquid-cooling module”, IEEE Journal of Electronic Packaging Technology,Issue 2, pp.1-4(2005).
[11].Arik, M. and Weaver, S., “Chip Scale Thermal Management of High Brightness LED Packages,” Proceedings of Society of Photographic Instrumentation Engineers, Vol.5530, pp.214-223 (2004).
[12].Hsieh, J. X., “LED Table Lamp with Heating Wind,”Utility Patent of Taiwan, TWM269418, (2004).
[13].林健國，「LED桌燈」，台灣發明專利，D116788 (2007)。
[14].蕭惠文，「支架結構改良」，台灣新型專利，M255923 (2005)。
[15].Cadena, R., Automated Lighting—The Art and Science of Moving Light in Theatre, Live Performance and Entertainment, Focal Press, Los Angeles (2010).
[16].Fredricks, D., “AQUARIUM LIGHT STRIP,” U.S. Patent Application Publication, US2011/0253056 (2011).
[17].Tai, C.Y., “Lighting system utilizing cylindrical lens and fluorescent lamps designed for specific use in aquarium and desk lighting applications,” U.S. Patent Application Publication, US2003/0025457 (2003).
[18].Goldfire Innovator, http://www.invention-machine.com/index.htm.
[19].Liu, C. C. and Chen, J. L., “Development of Product Green Innovation Design Method,” Proceedings of EcoDesign : Second International Symposium on Environmentally Conscious Design and Inverse Manufacturing, Tokyo, Japan, pp.168-173. (2001).
[20].Liu, C. C. and Chen, J. L., “A TRIZ Inventive Product Design Method without Contradiction Information,” The TRIZ Journal, http://www.triz-journal.com, September (2001).
[21].Chang, H. T. and Chen, J. L., “An Approach Combining Extension Method with TRIZ for Innovative Product Design,” Journal of the Chinese Society of Mechanical Engineers, Vol.25, pp.13-22 (2004).
[22].Low, M. T., Lamvik, K. W., and Myklebust, O., “Manufacturing a green service: engaging the TRIZ model of innovation,” IEEE Transactions on Electronics Packaging Manufacturing, Vol. 24, Issue 1, pp.10–17 (2001).
[23].Chang, H. T. and Chen, J. L., “The Conflict-Problem-Solving CAD Software Integrating TRIZ into Eco-Innovation,” Advances in Engineering Software, Vol.35, Issue 8-9, pp.553-566 (2004).
[24].Wang, H., Chen, G., Lin Z., and Wang, H., “Algorithm of Integrating QFD and TRIZ for the Innovative Design Process,” International Journal of Computer Applications in Technology, Vol.23, Issue 1, pp.41-52 (2005).
[25].Tong, L. H., He, C., and Shen, L., “Automatic Classification of Patent Documents for TRIZ Users,” World Patent Information, Vol.28, pp.6-13 (2006).
[26].Terninko, J., ”The QFD, TRIZ and Taguchi Connection : Customer– Driven Robust Innovation,” The Ninth Symposium on Quality Function Deployment, pp.374-380 (1997).
[27].Leon-Rovira, N. and Aguayo, H., “A new Model of the Conceptual Design Process using QFD/FA/TRIZ,” The TRIZ Journal, http://www.triz-journal.com/, July (1998).
[28].Apte, P. R. and Mann, D. L., “Taguchi and TRIZ: Comparisons and Opportunities,” The TRIZ Journal, http://www.triz-journal.com/, November, (2001).
[29].Mann, D. L., “Assessing the Accuracy of the Contradiction Matrix For Recent Mechanical Inventions,” The TRIZ Journal, http://www.triz-journal.com/, February, (2002).
[30].Fey, V. and Rivin, E., Innovation on Demand: New Product Development Using TRIZ, Cambridge University Press, UK, (2005).
[31].Savransky, S. D., Engineering of Creativity –Introduction to TRIZ Methodology of Inventive Problem Solving, CRC Press, New York, (2000).
[32].鄭振興，「利用知識工程技術進行支撐結構設計評估與設計改善之研究」，博士論文，國立台灣科技大學機械工程學系，民國100年。
[33].黃浩誠，「應用改良之TRIZ理論結合QFD於補償式化學機械拋光終點偵測及補償路徑之改善」，碩士論文，國立台灣科技大學機械工程學系，民國96年。
[34].張合，「乏晰理論及後傳播類神經網路在連續沖模設計之應用」，碩士論文，國立台灣科技大學機械工程學系，民國80年。
[35].黃文恕、梁高榮，「具不確定性因素之AHP輸送機專家系統設計」，碩士論文，國立交通大學工業工程研究所，民國79年。
[36].Seiler, R.K., “Reasoning about Uncertainty in Certain Expert System :Implications for Project Management Applications,” Project Management, Vol.8, Issue 1, pp.51~59 (1990).
[37].Lawrence, O.H., “On the Devication of Membership for Expert System, ” Information Science, pp.39~52 (1986).
[38].陳家豪、賴恩裕，「模糊理論於結構最佳設計與模型建立之研究」，碩士論文，國立成功大學機械研究所，民國79年。
[39].Feng, D.Y., “Application of Fuzzy Decision-Making in Earthquake Research, ” Fuzzy Sets and System, pp.15~26 (1990).
[40].Shinji, U., “The Complementary Process of Fuzzy Medical Diagnosis and Its Properties, ” Information Science, pp229~242 (1986).
[41].Partovi, F. Y., “An analytic model for locating facilities strategically,” Omega, Vol. 34,Issue 1, pp.41-55 (2006).
[42].杜瑞澤、徐傳瑛，「分析網路程序法運用於綠色產品開發之設計決策研究」，國立高雄師範大學，高雄師大學報，pp57-79 (2008)。
[43].Dağdeviren, M, Yuksel, İ., and Kurt, M., “A fuzzy analytic network process (ANP) model to identify faulty behavior risk (FBR) in work system,” Science Direct, Vol.46, pp.771~783 (2008).
[44].林吉仁，「應用Fuzzy DEMATEL與Fuzzy ANP建立供應商績效評估系統」，大華技術學院，第十一屆兩岸經貿暨管理國際學術研討會(2010)。
[45].Li, Q.D. and Lee, E.S., “On Random α-Cuts,” Journal of Mathematical Analysis and Applications, Vol. 190,Issue 2, pp.546~558 (1995).
[46].李惟萱、黃心慧、溫筑宜，「節能減碳新世代──LED 發光二極體」，工程技術類，台北 (2011)。
[47].賴威蒼，「結合修正式TRIZ及電腦輔助工程分析改善LED檯燈結構之研究」，碩士論文，國立台灣科技大學機械工程學系，民國100年。
[48].黃志銘，「LED水族燈之結構與散熱改良研究」，碩士論文，國立台灣科技大學機械工程學系，民國101年。
[49].Saaty, T. L. and Takizawa, M., “Dependence and independence: From linear hierarchies to nonlinear networks,” European Journal of Operational Research, Vol.26,Issue 2 , pp.229-237 (1986).
[50].陳啟銘，「結合修正式分析網路程序法與修正式TRIZ發明方法應用於LED閱讀燈創新設計方案優先次序評估」，碩士論文，國立台灣科技大學機械工程學系，民國102年。
[51].Altshuller, G., The 40 Principles, Technical Innovation Center, Inc. Worcester, MA, (1997).
[52].鄧振源，「計畫評估：方法與應用」，第二版，基隆：海洋大學運籌規劃與管理研究中心，台北 (2005)。
[53].鄧振源、曾國雄，「層級分析法的內涵特性與應用上，中國統計學報」，第27 卷第6 期，pp5-22 (1989)。
[54].余振銘，「提昇國內營造業競爭力關鍵因素之研究」，碩士論文，國立成功大學建築學系，民國89年。
[55].黃雪晴，2000「國內資訊電子業聯盟夥伴選擇模式之研究」，碩士論文，成功大學工業管理學系，民國89年。
[56].李允中、王小璠、蘇木春，「模糊理論及其應用」，全華，台北 (2012)。
[57].萬絢、林明毅、陳宏杰，「模糊理論應用與實務」，儒林，台北 (2006)。
[58].孫宗瀛、楊英魁，「Fuzzy控制理論、實作與應用」，全華，台北 (2007)。
[59].朱遠治，「轉軸扭力固定構造」，台灣發明專利，M456067 (2012)。