研究生: |
黃智達 Jr-da Huang |
---|---|
論文名稱: |
熱超音波覆晶接合技術用於發光二極體製程參數最佳化之研究 Optimization of Light Emitting Diode Processing Parameters Using Thermo-Ultrasonic Flip-Chip Bonding Technology |
指導教授: |
郭中豐
Chung-feng Jeffrey Kuo |
口試委員: |
黃昌群
Chang-chiun Huang 張嘉德 Chia-de Chang 蘇德利 Te-li Su |
學位類別: |
碩士 Master |
系所名稱: |
工程學院 - 材料科學與工程系 Department of Materials Science and Engineering |
論文出版年: | 2008 |
畢業學年度: | 96 |
語文別: | 中文 |
論文頁數: | 109 |
中文關鍵詞: | Levenberg-Marquardt 演算法 、倒傳遞類神經網路 、灰關聯分析 、主成份分析法 、覆晶接合 、田口直交表 、發光二極體 |
外文關鍵詞: | Levenberg-Marquardt Algorithm, Back-Propagation Neural Network, Grey Relational Theory, Principal Component Analysis, Taguchi Orthogonal Array Table, Flip-chip Bonding, Light Emitting Diode |
相關次數: | 點閱:612 下載:0 |
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發光二極體(Light Emitting Diode;LED),為21世紀的新型光源,具高效率、壽命長以及不易破損等優點。在要求高品質與高效率的時代中,晶片封裝製程技術為影響LED 的品質與效能之關鍵。
覆晶接合(Flip-Chip Bonding)具備輕、薄、短、小封裝優勢,為封裝製程技術發展之焦點。熱超音波覆晶接合(Thermo-Ultrasonic Flip Chip Bonding)製程,直接將晶片上的金墊(Gold Pad)與基板上的金凸塊(Gold Bump)接合在一起,金/金介面具有較佳的接合強度、電性及可靠度,且製程簡單、無鉛污染問題,並可在較低溫度及壓力下進行接合,具備高精度及細間距(Fine Pitch)的發展潛力。
本論文在研究LED 熱超音波覆晶接合製程,研究其多重品質特性之製程參數最佳化。因各品質特性間的相關性大及品質特性數目多,要決定最佳因子水準組合有其困難性,因為在取捨各因子水準時,可能會造成各品質特性之間相互衝突的問題。
本研究使用田口直交表(Taguchi Orthogonal Array Table)規劃實驗,實驗完成後,以主成份分析法(Principal Component Analysis)去除品質特性間的關聯性,再以灰關聯分析(Grey Relational Theory)找出最佳因子水準組合。最後結合倒傳遞類神經網路(Back-Propagation Neural Network)與Levenberg-Marquardt 演算法建構LED 覆晶接合製程之預測系統,將控制因子設為網路之輸入參數,而品質特性設為輸出參數,經過網路學習訓練,本系統預測誤差率在5% 以內,證明本預測系統有極佳的預測能力。
The light emitting diode (LED), a new light source in the twenty-first century, contains many advantages, such as high efficiency, long lifespan, and bold structure. The technology for chip packing is the focal point to increase LED quality and performance.
Flip-chip bonding, a kind of chip packing technology, allows produced chip to be lighter and smaller. Thermo-ultrasonic flip chip bonding is a way that directly joins gold pad and gold bump. The gold-gold connecting interface has better strength and electric reliability along with simple production process with no lead pollution. This kind of packaging also can be done in low pressure and low temperature with high accuracy and fine pitch.
This study focuses on LED thermo-ultrasonic flip chip bonding process to find the multi-quality properties with the optimization of LED processing parameters. The process will be more complex as qualities have strong correlation to each other. With many different quality characteristics, we will have to determine the combination of processing factors to yield best performance.
We first used the Taguchi orthogonal array table and then the principal component analysis to remove the relativity of each quality characteristics. We then used grey relational theory to obtain the best LED processing parameter and then used the back-propagation neural network and Levenberg-Marquardt algorithm to establish the LED Flip-Chip Bonding processing-quality predicting system. The error of the result is within 5%, indicating a high forecast capability.
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