852 錫林右軸承座組件工藝及夾具設計
852 錫林右軸承座組件工藝及夾具設計,錫林,軸承,組件,工藝,夾具,設計
外文翻譯資料1Monolithically integrated MEMS technology單片集成 MEMS 技術In the past 20 years, CMOS technology has become a major integrated circuit manufacturing technology, manufacturing costs decline at the same time, yield and production has also been greatly improved, COMS technology will continue to increase integration and reduce development of a special size. Today, CMOS integrated process not only be used in the design of integrated circuits, but also to be used in many micro-sensors and micro-actuator, so it can be integrated circuits and micro-sensor integrated with a powerful, intelligent sensors. With micro-sensor constantly expanding the scope of application of the sensor increasingly high demands of the future microsensor the main requirements are: miniaturization and integration of low-power and low-cost high-precision and long life; - and intelligent. Micromachined silicon integrated circuits and the integration of integration, to meet the above-mentioned requirements. At present, the majority of products integrated sensor using hybrid integrated, monolithic integration of a very small percentage. And the realization of single-chip integration is the key to achieving intelligent sensors, in particular monolithic integrated MEMS sensor technology is today's system-on-chip can achieve one of the key technologies. Clearly, monolithic integration of the various technical difficulties analysis of MEMS and have already given the various monolithic integration of MEMS technology is essential.在過去的 20 年中,CMOS 技術已成為集成電路主要制造工藝,制造成本下降的同時,成品率和產量也得到很大提高,COMS 工藝將繼續(xù)以增加集成度和減小特制尺寸向前發(fā)展。當今,CMOS 集成工藝不僅被利用在集成電路設計上,而且,也被利用在很多微傳感器和微執(zhí)行器上,這樣可以把微傳感器與集成電路集成在一起,構成功能強大的智能傳感器。隨著微傳感應用范圍的不斷擴大,對傳感器的要求也越來越高,對未來微傳感器的主要要求是:微型化和集成化;低功耗和低成本;高精度和長壽命;多功能和智能化。硅微機械和集成電路的一體化集成,可以滿足上述要求。目前,集成傳感器的產品多數采用混合集成,單片集成的比例很小。而實現單片集成是實現傳感器智能化的關鍵,特別是單片集成 MEMS 傳感器技術也是當今片上系統(tǒng)芯片能否實現的關鍵技術之一??梢?,對各種單片集成 MEMS 技術難點進行分析以及給出目前已有的各種單片集成 MEMS 技術是非常必要的。1.Monolithic integration of MEMS technology advantages and the challenges facing。1.單片集成 MEMS 技術的優(yōu)勢和面臨的挑戰(zhàn)外文翻譯資料2MEMS and CMOS achieve working together, the separate manufacturing CMOS MEMS sensors and integrated circuits, and then cut from their chips, fixed in a common substrate, and, bonded connection, thereby bringing the two integration, This is the so-called mixed (hybrid) method. This method does not produce MEMS manufacturing process for CMOS circuits pollution At the same time, both the production process Noninterference. However, due to signal bonding point and fuses, resulting in high-frequency applications, decline in the quality of signal transmission, and to develop two production lines to increase the cost of the product. In order to address some performance issues, and lower manufacturing costs, and proposed to do in the part of MEMS and CMOS circuits with a substrate, which is produced compatible with CMOS technology or monolithic integrated MEMS technology called CMOS-MEMS technology. This method relative hybrid method generally have the following advantages: First, the performance can be greatly improved, because parasitic capacitance and crosstalk phenomenon can be significantly reduced; second, hybrid method requires sophisticated technology to reduce packaging Sensor Interface affected, and monolithic integration requires packaging technology is relatively simple and therefore, lower cost sensors; third, monolithic integrated sensor array sensor technology is the need to overcome the array sensor and external decoding circuit an effective interconnect bottleneck; Fourth, the development of monolithic integrated mixed development of MEMS products than MEMS products for a short time, and to develop low cost.實現 MEMS 和 CMOS 共同工作是分別制造 MEMS 傳感器和 CMOS 集成電路,然后,從各自的晶片切開,固定在一個共同的襯底上,并且,連線鍵合,這樣就實現兩者的集成,這就是所謂的混合(hybrid)方法。這種方法不會產生 MEMS 制造過程對 CMOS 電路的污染,同時,兩者生產過程互不干擾。但是,由于信號經過鍵合點和引線,導致在高頻應用時,信號傳輸質量下降,并且,開發(fā)兩套生產線增加了產品的成本。為了解決一些性能問題,并降低制造成本,提出把 MEMS 部分做在和 CMOS 電路同一塊襯底上,也就是產生了與 CMOS 工藝兼容單片集成 MEMS 技術或叫 CMOS-MEMS 技術。這種方法相對混合方法總的來說有如下優(yōu)勢:第一,性能能得到很大的提高,因為寄生電容和串擾現象可以顯著減小;第二,混合方法需要復雜的封裝技術以減小傳感器接口的影響,而單片集成方法需要的封裝技術相對簡單,所以,降低傳感器成本;第三,單片集成傳感器技術也是陣列傳感器的需要,是克服陣列傳感器與外圍譯碼電路互連瓶頸的一種有效方法;第四,開發(fā)單片集成 MEMS 產品比開發(fā)混合 MEMS 產品所需的時間短,而且,開發(fā)成本低。外文翻譯資料3Monolithic integration of MEMS technology under some of MEMS devices and CMOS circuit can be divided into different order processing before CMOS (pre-CMOS), mixed CMOS (intermediate-CMOS), and after the CMOS (post-CMOS) integrated approach.單片集成 MEMS 技術根據 MEMS 器件部分與 CMOS 電路部分加工順序不同可以分為前CMOS(pre-CMOS)、混合 CMOS(intermediate-CMOS)及后 CMOS(post-CMOS)集成方法。Post-CMOS approach is in the processing of silicon CMOS circuits End, through some additional MEMS micro-processing technology to achieve monolithic integrated MEMS system, at present, monolithic integration of MEMS technology in this way mainly based. Post-CMOS approach is the main issue on MEMS processing temperature CMOS circuit performance in front of an impact on more serious is that the technology behind high-temperature MEMS processing temperature and metal CMOS process ahead of incompatibility. In the present study as the most polysilicon layer structure of the MEMS example, the densification of phosphorus glass annealing temperature is 950 ℃ due to a structural polysilicon layer of stress annealing temperature reached 1050 ℃ , which will enable CMOS devices junction depth migration occurred. In particular 800 ℃ shallow junction devices junction depth migration will affect device performance. On the other hand, the conventional aluminum metallization process, when the temperature reaches 400-450 ℃, the reliability of CMOS circuits will be severely affected. From the above we can see that: how to overcome behind high-temperature MEMS processing temperature on the micro-structure of the front end processing has been the impact of CMOS circuits integrated MEMS single-chip solution is key to the system. At present, the international community is essential to resolve this issue through three ways: First is the interconnection of refractory metals instead of aluminum metal interconnect, for example, the University of Berkeley to replace tungsten aluminum metal interconnect programmes, such follow-up increased tolerance MEMS processing for high temperature; The second is produced by finding low temperature mechanical properties and excellent substitute materials as structural polysilicon layer; third way is to use its existing structure CMOS MEMS layer as a layer structure.post-CMOS 方法是在加工完 CMOS 電路的硅片上,通過一些附加 MEMS 微細加工技術以實現單片集成 MEMS 系統(tǒng),目前,單片集成 MEMS 技術主要以這種方法為主。post-CMOS 方法主要問題是 MEMS 加工工藝溫度會對前面的 CMOS 電路性能產生影響,更為嚴重的是后面高溫MEMS 加工工藝溫度與前面 CMOS 工藝金屬化不兼容。以目前研究最多的多晶硅作為結構層的MEMS 為例,使磷硅玻璃致密化退火溫度為 950℃,而使作為結構層多晶硅的應力退火溫度則達到 1050℃,這將使 CMOS 器件結深發(fā)生遷移。特別是 800℃時淺結器件的結深遷移就會影外文翻譯資料4響器件的性能。另一方面,采用常規(guī)鋁金屬化工藝時,當溫度達到 400-450℃時,CMOS 電路可靠性將受到嚴重的影響。從以上可以看出:如何克服后面高溫 MEMS 微結構加工溫度對前面的已加工完的 CMOS 電路影響是解決單片集成 MEMS 系統(tǒng)關鍵所在。目前,國際上解決這個問題基本是通過 3 種方式:第一種是以難熔金屬化互連代替鋁金屬化互連,如,伯克利大學的以鎢代替鋁金屬互連方案,這樣提高容忍后續(xù)加工 MEMS 所需的高溫;第二種方式是通過尋找低制作溫度且機械性能優(yōu)良的材料代替多晶硅作為結構層材料;第三種方式是利用CMOS 本身已有結構層作為 MEMS 結構層。Pre-CMOS integrated approach is to create structure MEMS manufacturing CMOS circuits, although this integrated CMOS technology to overcome post-CMOS method of high-temperature MEMS Technology on CMOS circuits affected, but because of the existence of micro-vertical structure, and therefore, there sensor and circuit interconnection level coverage, but also in the process of CMOS circuits on the micro-structure protection is also a need to consider the issue. Even fine-tune the optimization of CMOS process, such as: gate oxide may be heavily doped layer impact of the structure. In addition, the MEMS technology can not process any of the metal or other materials, such as piezoelectric polymers, and so on, makes this method only suitable for some special applications.pre-CMOS 集成方法是先制造 MEMS 結構后制造 CMOS 電路,這種集成 CMOS 技術雖然克服post-CMOS 方法中 MEMS 高溫工藝對 CMOS 電路的影響,但由于存在垂直的微結構,所以,存在傳感器與電路互連臺階覆蓋性問題,而且,在 CMOS 電路工藝過程中對微結構的保護也是一個需要考慮的問題。甚至已優(yōu)化微調的 CMOS 工藝流程,例如:柵氧化可能被重摻雜的結構層影響。另外,MEMS 工藝過程中不能有任何的金屬或其他的材料,如壓電材料聚合物等,使得這種方法只適合一些特殊應用。Intermediate-CMOS circuits in the CMOS production process to insert some MEMS micro-processing technology to achieve monolithic integrated MEMS approach. This approach has been very mature and have a lot of commercialization of products, is the first study of a single-chip integration method is to solve the pre - and post-CMOS CMOS method effective method problems, but due to the need for the existing standard CMOS or larger BiCMOS process changes, therefore, the use of this method is limited.intermediate-CMOS 是在 CMOS 電路生產過程中插入一些 MEMS 微細加工工藝來實現單片集成 MEMS 的方法。這種方法已很成熟,并已有很多商品化產品,也是研究最早一種單片集成方法,是解決 pre-CMOS 和 post-CMOS 方法存在問題有效方法,但是,由于需要對現有的標準 CMOS 或 BiCMOS 工藝進行較大的修改,因此,這種方法的使用有一定限制。外文翻譯資料51.The main monolithic integrated MEMS technology status單片集成 MEMS 的主要技術現狀At present, the monolithic integration of MEMS technology mainly to post-CMOS technologies, through a series of compatible with CMOS process on the surface micro-machining and processing to achieve monolithic integration of MEMS. Can be divided into two kinds: one is in the top layer CMOS structure to a structure layer deposition micro-machining; the other is directly CMOS layer structure as the original structure of the MEMS micro-machined.目前,單片集成 MEMS 技術主要以 post-CMOS 技術為主,通過一系列的與 CMOS 工藝兼容的表面微細加工和體加工實現單片集成 MEMS。又可分為 2 種:一種是在 CMOS 結構層上面再淀積一層結構層的微加工;另一種是直接以 CMOS 原有的結構層作為 MEMS 結構層的微加工。2.1Deposition of new structural materials for the structure of integrated MEMS technology2.1 淀積新的結構材料作 MEMS 結構的集成技術2.1.1Polysilicon layer structure as the surface micro-machining technology integration2.1.1 多晶硅作為結構層的集成表面微細加工技術This process is typical of modules developed at the University of Berkeley Integrated CMOS and MEMS Technology (modular integration of CMOS with micro-structures, MICS), this method is for the micro-structural polysilicon layer, phosphorus silicon glass (PSG) as a sacrificial layer The surface micro-machining technology. A refractory metal tungsten metal interconnect instead of aluminum metal interconnect to bear behind the polysilicon production needs of micro-structure of high-temperature, but at 600 ℃, tungsten and silicon form easily response by the University of Berkeley in the Contacts release a TiN barrier layer to address this problem. MICS process is the basic process: the completion of tungsten metal CMOS process, the deposition of 300 × 10-10nm low-temperature oxide (LTO), and then, low pressure chemical vapor deposition 200 × 10-10nm protection of the silicon nitride film has been produced CMOS circuits, micro-structure and corrosion End CMOS circuit contact hole, No. 1 layer deposition scene doped polysilicon (350 × 10-10), as CMOS circuits and micro-structure of interconnection lines, in the above deposition to a um PSG thick as a sacrificial layer thickness and deposition of 2 um polysilicon layer structure. No. 2 through another layer polysilicon deposition of a layer of 0.5 um PSG, as well as nitrogen environment in the 1000 ℃ rapid thermal annealing for 1 min as a structure to reduce stress polysilicon layer. Finally, the structure of graphics and polysilicon etching out its corrosion layer below the sacrifices (PSG) for the release of micro-structure.外文翻譯資料6這種工藝典型代表是伯克利大學開發(fā)模塊集成 CMOS 與 MEMS 工藝(modular integration of CMOS with micro-structures,MICS),這種方法是以多晶硅為微結構層,磷硅玻璃(PSG)作為犧牲層的表面微細加工技術。采用難熔金屬鎢的金屬化互連代替鋁金屬化互連以承受后面的生產多晶硅微結構所需要的高溫,但是,在 600℃時,鎢容易與硅形成反應,伯克利大學是通過在接觸孔上放一層 TiN 阻擋層來解決這一問題的。MICS 工藝基本流程是:完成鎢金屬化的 CMOS 工藝后,淀積 300×10-10nm 低溫氧化物(LTO),然后,低壓化學氣相淀積 200×10-10nm 的氮化硅薄膜保護已生產的 CMOS 電路,腐蝕完微結構與CMOS 電路的接觸孔后,淀積第 1 層現場摻雜多晶硅(350×10-10)作為 CMOS 電路與微結構的互連線,再在上面淀積 1um 厚的 PSG 作為犧牲層以及淀積厚度為 2um 多晶硅結構層。通過在第 2 層多晶硅上再淀積一層 0.5um 的 PSG,以及在氮氣環(huán)境下的 1000℃快速退火 1min 來降低作為結構層的多晶硅應力。最后,刻蝕多晶硅結構圖形以及腐蝕掉其下面的犧牲層(PSG)以釋放微結構。2.1.2Other materials for the structure of the surface micro-machining technology integration2.1.2 以其他材料作結構層集成表面微細加工技術Polycrystalline silicon germanium polysilicon not only with the excellent mechanical properties similar, and, low temperature deposition compatible with the CMOS process, therefore, is being extensively studied. Developed at the University of Berkeley-based structural layer of silicon germanium technology and MICS technology similar. Major technological innovations: First, the protective layer using different materials, before 835 ℃ MICS process is the LPCVD silicon nitride, and now it is using a two-tier LTO and intermediate folder is not a stereotypical silicon (a-Si) as a CMOS circuit protective layer, in which the two-step deposition of a-Si, the first step in the deposition 450 ℃; step deposition in the 410 ℃, this will not damage the temperature of aluminum metal CMOS circuit; Second, the low amylin plot structure as a temperature polysilicon layer of germanium materials, the low pressure chemical vapor deposition (LPCVD) temperature only 400 ℃ using rapid thermal annealing temperature of only 5.5 ℃ for 30 s. MICS and the temperature polysilicon deposition of more than 600 ℃. From the above two points, we can see that the whole follow-up MEMS processing temperature does not exceed 450 ℃, therefore, not of aluminum metal interconnect CMOS circuits have greatly affected.多晶硅鍺不僅有與多晶硅相似的優(yōu)良機械性能,而且,淀積溫度低與 CMOS 工藝兼容,所以,目前被廣泛研究。伯克利大學開發(fā)的基于硅鍺結構層的工藝與 MICS 工藝基本相似。主要技術革新:第一,保護層采用不同的材料,以前 MICS 工藝采用 835℃的 LPCVD 氮化硅,而現在則是采用兩層 LTO 和中間夾一層不定型硅(a-Si)作為 CMOS 電路保護層,其中,a-外文翻譯資料7Si 分兩步淀積,第一步淀積在 450℃;第二步淀積則在 410℃,這樣溫度是不會損壞鋁金屬化 CMOS 電路;第二,采用低淀積溫度多晶硅鍺作為結構層材料,其低壓化學氣相淀積(LPCVD)溫度只有 400℃,采用快速退火溫度也僅為 550℃,時間為 30s。而 MICS 工藝淀積多晶硅結構溫度則超過 600℃。從以上兩點可知,由于整個后續(xù) MEMS 加工溫度不超過450℃,所以,不會對鋁金屬化互連 CMOS 電路產生很大的影響。Aluminum used as a structural material will be a great success, the most successful is the Texas Instruments developed cryogenic surface micro-machining technology, and use this technology successfully produced digital micromirror device (DMD). Technical innovation in the use of sputtering performance as aluminum structural material, and using photoresist as a sacrificial layer, which makes low-temperature post-processing production has been below the SRAM cells were not damaged.采用鋁作為結構層材料也會獲得很大成功,最為成功的是德州儀器開發(fā)低溫表面微細加工技術,并用這種技術成功生產了數字微鏡設備(DMD)。技術革新主要表現在采用濺射鋁作為結構層材料,并且,采用光致抗蝕劑作為犧牲層,這種低溫后處理使得已生產的下面SRAM 單元不被破壞 。Lead zirconate titanate (PZT) of the material has an excellent result piezoelectric properties, pyroelectric properties of ferroelectric properties and dielectric properties and is widely used in ferroelectric memory, as well as high-dielectric materials. At the same time, we can also use lead zirconate titanate piezoelectric effect produced micro-sensors and micro-actuators. PZT thin film silicon technology and integration technology compatible, such as the present based on the metal-organic chemical vapor deposition (OCVD) Methods PZT thin films temperature has been reduced to 430 to 75 ℃, the temperature is lower, therefore, use of such materials as structural layer is a very hopeful and CMOS process integration.鋯鈦酸鉛(PZT)電材料因具有優(yōu)良的壓電性能、熱釋電性能、鐵電性能和介電性能而被廣泛應用在鐵電存儲器中以及作為高介質材料。同時,還可以利用鋯鈦酸鉛壓電效應制作微傳感器以及微執(zhí)行器。PZT 薄膜工藝與硅集成工藝兼容,如,目前的基于金屬有機化學氣相淀積(OCVD)方法制作 PZT 薄膜溫度已降低到 430~75℃,這個溫度還在降低,因此,采用這種材料作為結構層是很有希望與 CMOS 工藝集成的。2.2 CMOS structure to the original layer to the structure of integrated MEMS technology2.2 以原 CMOS 結構層作 MEMS 結構的集成技術2.2.1Sacrifice aluminum micro-machining technology2.2.1 犧牲鋁的微加工技術外文翻譯資料8If CMOS metal compounds used for the expense of materials, there may be fully compatible with CMOS technology and surface micro-machining small art, this method is called sacrifice aluminum etching (sacrificial aluminum etching, SALE). In many CMOS process, use two layers of aluminum alloy by a metal layer. No. 1 as a sacrificial layer of metal was removed, can create metal dielectric compounds; Layer 2 and passivation of the metal component, 2-layer metal between two dielectric between appropriate structure, they could serve as a mirror electrodes, heat or electric resistance regulator. The basic process include: (1) the protection of electrical contacts are not connected etching (2) corrosion sacrifice aluminum layer; (3) removal rinsed Boundary structure inside the etching agent; (4)-drying bodies.如果 CMOS 金屬化合物用作犧牲材料,則可能存在和 CMOS 工藝完全兼容的表面微細加工丁藝,這種方法被稱作犧牲鋁蝕刻(sacrificial aluminum etching,SALE)。在許多CMOS 工藝過程中,都采用了兩層由鋁合金構成的金屬層。第 1 層金屬作為犧牲層被清除,可以制造出電介質金屬化合物;第 2 層由金屬和鈍化物組成,第 2 層金屬介于兩個電介質之間,適當結構化后,便可以作為反射鏡、電極、熱電阻或電熱調節(jié)器。其基本工藝過程包括:(1)保護電氣連接觸點不受到蝕刻;(2)腐蝕犧牲鋁層;(3)涮洗清除徼結構里面的蝕刻劑;(4)烘干微機構。2.2.2Monocrystal silicon etching and metal activation method.2.2.2 單晶體硅活化蝕刻和金屬化法Monomer silicon etching and metal activation method (single crystal reactiveetching and metallization, SCREAM) can be used for manufacturing, beam, the bridge structure, and even silicon can be used to create more complex structures. This approach starts at the End manufacture silicon CMOS circuits, first of all, a layer of coverage deposition contact hole silicon oxide, oxide layer to protect it from the back of CMOS circuits affected, and through reactive ion etching (RIE) of this graphics Oxide layer shielding layer; then RIE etching silicon trench, the depth of up to 10 um, silicon oxide thin film deposition down, and the level of coverage in the side surface. By reactive ion etching of the oxide surface level off due to a vertical surface to be protected, the second reactive ion etching silicon; Finally, the isotropic etch silicon, the release of the microstructure of a suspension, at the same time, etching contact hole oxides, and Sputtering metal, this layer of metal deposition to the aspect ratio of the beam into a capacitive elements with thick resist masking agent for the graphics mode of metal layers. As each step of SCREAM are below 300 ℃ under the temperature and, therefore, is compatible with CMOS circuits.外文翻譯資料9單體硅活化蝕刻和金屬化法(single crystal reactiveetching and metallization,SCREAM)可用于制造,梁、橋這樣的結構,甚至可以用單晶硅制造更復雜的結構。這種方法始于制造完的 CMOS 電路硅片,首先,淀積一層覆蓋接觸孔的氧化硅,這層氧化物保護 CMOS 電路免受后面工藝影響,并通過反應離子蝕刻(RIE)圖形化這層氧化物遮蔽層;然后,RIE 蝕刻硅溝槽,深度可達到 10um,氧化硅薄膜淀積下來,覆蓋在側面和水平面上。通過反應離子蝕刻掉水平面上的氧化物,而使豎直面受到保護,第二次反應離子蝕刻硅;最后,各向同性蝕刻硅,釋放出懸浮的微結構,同時,蝕刻接觸孔氧化物,并濺射金屬,這層金屬化淀積物使大縱橫比的粱變成電容性元素,用厚的抗蝕劑作掩蔽模圖形化金屬層。由于 SCREAM 的每一步均在低于 300℃的溫度下進行的,因此,是與 CMOS 電路兼容的。2.2.3Large aspect ratio of CMOS-MEMS Technology2.2.3 大縱橫比的 CMOS-MEMS 工藝Gamegle Melloa University and the development of CMOS-compatible dry etching method, which isotropic silicon etch applications have insulation film, CMOS dielectric and metal layers in this process, not only for the metal interconnect, but also as a micro-mechanical structure tail. Basic process: First, the standard CMOS process using three-metal process to achieve 0.5 upmN Well, secondly, metal layers 1 and 2 were used as electrical activity layer, and layer 3 as a micro-machining etching mask. Application of the compound CHF3/O2 reactive ion etching (RIE), the entire chip passivation layer to be removed, in the three-tier regional disconnect metal, CMOS laminated film has been etched to the basement, and above covered with Layer 3 CMOS metal thin film laminated retained intact; Finally, the use of SP6/O2 plasma etching in the micro-structural wall not under isotropic etch silicon substrate. Narrow insulating layer and conductive layer fused to create beams and bridges, such as: Comb drive the micro-structure.Gamegle Melloa 大學開發(fā)的與 CMOS 兼容干法蝕刻方法,它應用各向同性硅蝕刻產生絕緣薄膜,CMOS 介質和金屬化層在這個工藝中不僅用作金屬互連,而且,還作為微機械結構尾?;竟に囘^程為:首先,標準的 CMOS 工藝采用三層金屬 0.5upmN 阱工藝實現;其次,金屬層 1 和 2 被用作電活性層,而第 3 層作為微機械加工的蝕刻掩模。應用化合物CHF3/O2 的反應離子蝕刻(RIE),使整個芯片上的鈍化層被清除掉,在第 3 層金屬斷開區(qū)域,CMOS 薄膜夾層被一直蝕刻至基底,而上面覆蓋有第 3 層金屬的 CMOS 薄膜夾層則保留完好;最后,采用 SP6/O2 等離子在不蝕刻微結構側壁情況下各向同性蝕刻硅襯底。狹窄的絕緣層和導電層融為一體制造出梁和橋,例如:梳狀驅動器這樣的微結構。2.2.4 Processing CMOS-MEMS Technology2.2.4 體加工 CMOS-MEMS 工藝外文翻譯資料10Mainly through the etching of silicon substrates, such as processing technology to form the necessary MEMS structure, the technology mainly to the University of Zurich-based. Can be viewed in a positive etching silicon substrate, but also from negative etching silicon substrate, using anisotropic etc
收藏