完整後設資料紀錄
DC 欄位語言
dc.contributor.author彭政傑en_US
dc.contributor.authorPeng, Jeng-Jieen_US
dc.contributor.author柯明道en_US
dc.contributor.authorKer, Ming-Douen_US
dc.date.accessioned2014-12-12T02:29:35Z-
dc.date.available2014-12-12T02:29:35Z-
dc.date.issued2001en_US
dc.identifier.urihttp://140.113.39.130/cdrfb3/record/nctu/#NT901706011en_US
dc.identifier.urihttp://hdl.handle.net/11536/69642-
dc.description.abstract雖然新的封裝技術不斷地推陳出新,線銲封裝仍是今日積體電路產品封裝型式的主流。本論文提出三種相連貫的方法以解決在積體電路產品的應用上,銲墊所面臨的問題。 首先,在線銲封裝過程中,常會發生銲線脫落或斷裂的問題。經實驗證實,將銲墊的最上層金屬保持不變,藉由選用適當的第二上層金屬層及連接第二上層金屬層的連接栓的佈局圖案,即可改善線銲封裝時,銲墊固著度的問題。 再者,銲墊本身所存在的寄生電容效應,已使得在高頻電路上的設計遇到瓶頸。在前述改善銲墊固著度問題的過程中,觸發了一個想法:改變銲墊金屬層的佈局圖案為骨架式的佈局形式,並在金屬層下方加上擴散層,將可降低銲墊的寄生電容效應。經實驗證實此法可以有效降低銲墊本身的寄生電容值。這個結果已經實際應用到許多的積體電路產品上。 最後,由於系統晶片時代的來臨,不僅晶片上電路的集積度愈來愈高,銲墊的個數也愈來愈多。這使得銲墊所佔全晶片的面積比例居高不下。為提昇晶片上的有效面積使用率,將主動元件置放於前述具骨架式金屬層佈局圖案的銲墊正下方,以節省晶片總面積將是一個可行的方法。經本研究之實驗證實,置放於銲墊下方的N型金氧半導體電晶體,在經過不同銲線打線力道之試驗與封裝後,其元件直流特性仍能維持在合理且可接受的範圍內。這除了有效地節省了晶片的總面積,也使得未來靜電放電保護電路或輸出/輸入元件的設計與擺置更加具有彈性。zh_TW
dc.description.abstractWire bond package is still the mainstream of IC packages although different advanced package technologies, such as chip on board (COB), flip chip, chip scale package (CSP), and multi-chip module (MCM), are available today. In this thesis, there are three correlated approaches of bond pad designs of wire bond IC products proposed for reliability improvement, parasitic capacitance reduction, and layout area saving for system-on-a-chip (SOC) applications. During manufacture of wire bonding in packaged IC products, the breaking of bond wires and the peeling of bond pads occur frequently, which results open-circuit failure in IC products. There were several prior methods reported to overcome these problems by using additional process flows or special materials but all with additional cost. In this thesis, a layout method is proposed to improve the bond wire reliability in general CMOS processes. By changing the layout patterns of bond pads, the reliability of bond wires on bond pads can be improved. The proposed layout method for bond pad design is fully process-compatible to general CMOS processes. Large parasitic capacitance of conventional bond pad structure is a serious problem in high frequency IC application. A new structure design of bond pad is proposed to reduce its parasitic capacitance in general CMOS processes without extra process modification. The proposed bond pad, which is modified from the layout method for improving bond wire reliability, is constructed by connecting multi-layer metals and inserting additional diffusion layers into the substrate below the metal layers. The experimental results show that the proposed low-capacitance bond pad has a capacitance less than 50% of that in the traditional bond pad. The proposed bond pads can also keep the same good bonding reliability as that of traditional bond pad. To save layout area for electrostatic discharge (ESD) protection design in the SOC era, test chip with large size NMOS devices, which are designed under bond pads with different layout pattern designs of metal layers, was fabricated for verification. Threshold voltage, off-state drain current, and gate leakage current of these devices under bond pads were measured. After assembled in the wire bond package, the measurement results show that there are only little variations between devices under bond pads and devices beside bond pads. This discovery can be applied on saving layout area for on-chip ESD protection devices or I/O devices of IC products, especially when the IC’s have high pin counts.en_US
dc.language.isoen_USen_US
dc.subject銲墊zh_TW
dc.subject銲線固著度zh_TW
dc.subject拉線測試zh_TW
dc.subject推球測試zh_TW
dc.subject佈局zh_TW
dc.subject低電容銲墊zh_TW
dc.subject漏電流zh_TW
dc.subject熱衝擊試驗zh_TW
dc.subjectbond paden_US
dc.subjectbond wire reliabilityen_US
dc.subjectwire pull testen_US
dc.subjectball shear testen_US
dc.subjectlayouten_US
dc.subjectlow capacitance paden_US
dc.subjectleakage currenten_US
dc.subjectthermal shock testen_US
dc.title積體電路之高可靠度與低寄生電容銲墊設計zh_TW
dc.titleHigh-Reliability and Low-Capacitance Bond Pad Design for CMOS Integrated Circuitsen_US
dc.typeThesisen_US
dc.contributor.department電機學院電子與光電學程zh_TW
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