MEMS/NEMS Handbook Techniques and Applications Volume1 DesignMethods MEMS/NEMS Handbook Techniques and Applications Volume 1 Design Methods Edited by Cornelius T. Leondes UniversityofCalifornia LosAngeles,USA LibraryofCongressCataloging-in-PublicationData MEMS/NEMS;microelectromechanicalsystems/nanoelectromechanicalsystems/ EditedbyCorneliusT.Leondes p. cm. Includesbibliographicalreferencesandindex. Contents:v.1.DesignMethodsinMEMS/NEMS–v.2.FabricationtechniquesforMEMS/NEMS– v.3.ManufacturingmethodsinMEMS/NEMS–v.4.SensorsandactuatorsinMEMS/NEMS– v.5.MedicalapplicationsofMEMS/NEMSandMOEMS(microopticalelectromechanicalsystems) ISBN10 0-387-24520-0 Printedonacid-freepaper. ISBN10 0-387-25786-1(e-book) ISBN13 9780387245202 ISBN13 9780387257862 1.Microelectromechanicalsystems—Designandconstruction. 2.Nanotechnology, I.Leondes,CorneliusT. TK153.M4462005 620(cid:1).5—dc22 2005042621 (cid:2)C 2006SpringerScience+BusinessMedia,Inc. Allrightsreserved.Thisworkmaynotbetranslatedorcopiedinwholeorinpartwithoutthewritten permissionofthepublisher(SpringerScience+BusinessMedia,Inc.,233SpringStreet,NewYork,NY10013, USA),exceptforbriefexcerptsinconnectionwithreviewsorscholarlyanalysis.Useinconnectionwithany formofinformationstorageandretrieval,electronicadaptation,computersoftware,orbysimilarordissimilar methodologynowknoworhereafterdevelopedisforbidden. Theuseinthispublicationoftradenames,trademarks,servicemarksandsimilarterms,eveniftheyarenot identifiedassuch,isnottobetakenasanexpressionofopinionastowhetherornottheyaresubjectto proprietaryrights. PrintedintheUnitedStatesofAmerica 9 8 7 6 5 4 3 2 1 SPIN11357766 springeronline.com Contents Foreword ix Preface xiii Contributors xvii 1. ManufacturingAdvisoryServiceSystemforConcurrentandCollaborative DesignofMEMSDevices 1 XuanFZha 1. Introduction 2 2. CurrentStatusofResearch 4 3. ConcurrentCollaborativeDesignMethodologiesand FrameworkforMEMS 6 4. StrategyforMEMSManufacturingProcessand MaterialSelection 11 5. KnowledgeSupportforMEMSManufacturingProcessand MaterialSelection 14 6. MEMSManufacturingAdvisoryServiceSystem 18 7. UseofWebMEMS-MASS 26 8. ResultsandDiscussions 29 9. SummaryandFutureWork 31 10. DisclaimerandAcknowledgement 31 References 32 2. Web-EnabledKnowledge-IntensiveSupportFrameworkforCollaborative DesignofMEMS 35 XuanFZha 1. Introduction 36 2. CurrentStatusofResearch 37 3. KnowledgeIntensiveCollaborativeFramework forNetwork-CentricDesign 41 4. KS-WebDMMEFrameworkforCollaborativeDesignofMEMS 43 5. DevelopmentofWeb-BasedCollaborativeMEMSDesignSystem 46 6. CaseStudy:CollaborativeDesignforAMicrogripper 52 7. SummaryandFutureWork 60 8. Disclaimer 63 References 63 vi CONTENTS 3. Web-EnabledDatabaseSystemDevelopmentforDesignandManufacturing ofMicro-Electro-MechanicalSystems(MEMS) 73 XuanFZha,W.Y.Toh,andH.Du 1. Introduction 74 2. MEMSFabrication/ManufacturingTechnologies 75 3. DatabaseDesignFundamentals 84 4. DesignofMEMSManufacturingDatabases 91 5. DevelopmentoftheWebEnabledDatabaseSystemSoftware 96 6. IntegrationoftheWebDatabaseSystemwithMEMS CAD/CAM/CAESystem 103 7. DiscussionsandSummary 106 8. Disclaimer 107 References 107 4. TechniquesinProperOrthogonalDecompositionandComponent ModeSynthesisfortheDynamicSimulationofComplexMEMS DevicesandTheirApplications 111 W.Z.Lin,S.P.Lim,andY.C.Liang 1. Introduction 111 2. ProperOrthogonalDecomposition 113 3. GalerkinProcedure 116 4. ASingleStructuralMEMSDeviceandModelDescription 117 5. AComplexMEMSDeviceandModelDescription 131 6. ConcludingRemarks 148 7. Acknowledgement 149 References 149 5. TechniquesinGlobalOptimalDesignforMEMSand TheirApplications 151 AndojoOngkodjojoandFrancisE.H.Tay 1. Introduction 152 2. Single-ObjectiveOptimization 152 3. Multi-ObjectiveOptimization 152 4. ComparisonAmongtheSAandOtherAlgorithms 156 5. Applications 157 6. Conclusion 170 7. Acknowledgement 171 References 171 6. TheoryandDesignofMicromechanicalVibratoryGyroscopes 173 VladislavApostolyuk 1. Introduction 173 2. OperationPrincipleandClassification 174 3. DynamicErrorandBandwidth 191 4. DesignMethodology 195 CONTENTS vii 5. Resume 195 References 195 7. AHierarchicalDesignPlatformforMicroelectrofluidicSystems(MEFS) 197 TianhaoZhang,KrishnenduChakrabartyandRichardB.Fair 1. Introduction 197 2. HierarchicalDesignPlatform 203 3. PCRPerformanceEvaluationUsingtheUniversalHierarchical DesignPlatform 212 4. Conclusion 231 References 232 8. TechniquesinElectrostaticsAnalysisofMEMSandTheirApplications 235 E.T.Ong,K.M.Lim,andH.P.Lee 1. Introduction 235 2. ImprovingAccuracyofElectrostaticsAnalysis 237 3. ImprovingEfficiencyofSolutionMethod 272 References 288 9. TechniquesforEfficientAnalyticalandSimulationMethodsinthe PrototypingofMEMSSystems 293 Y.Su,C.S.Chong,Q.X.WangandHuaLi 1. Introduction 293 2. AutomaticMeshGeneration 294 3. AutomaticModelDecompositionandReduction 300 4. CoupledBEMandFEM 304 5. MeshlessMethodology 309 6. ApplicationsofMeshlessTechniques 324 7. Conclusions 330 References 332 Index 335 Foreword Over the next decade, major industrial and scientific trends that emerged during 1990s will influence not only how manufacturing will be done, but also what is manufactured. The size of many manufactured goods continues to decrease, resulting in ultra-miniature electronicdevicesandnewhybridtechnologies.Ithasbeenpredictedthatwithinthenext decadeatleasthalfofthenewlydesignedadvancedmaterialsandmanufacturingprocesses will be built at the nanoscale. MEMS/NEMS (Micro/Nano Electro-Mechanical Systems) isarapidlygrowingfieldbuildingupontheexistingsiliconprocessinginfrastructureand techniquestocreatemicro/nano-scaledevicesorsystems.MEMS/NEMSdevicesintegrate physical,chemical,andevenbiologicalprocessesinmicro-andmillimeter-scaletechnol- ogypackages.MEMS/NEMSdevicesnowareemergingasproductdifferentiatorsinmarket areassuchasautomotive,aerospace,electronicsinstrumentation,industrialprocesscontrol, appliances,biotechnology,healthcare,officeequipment,andtelecommunications.Unlike conventional integrated circuits, micro/nano devices can have many functions including sensing,communication,andactuation.MEMS/NEMStechnologyjustlikemicroelectron- icswillpermeateourdailylivesinthecomingdecades.Onthehorizonisthedevelopment of nanomanufacturing technologies that will support tailor-made products having func- tionallycriticalnanometer-scaledimensionsproducedusingmassivelyparallelsystemsor self-assembly.Thetrendinproductminiaturizationwillrequirenewtechniquesfordesign, fabrication/manufacturing,andprocessmeasurementandcontrolthatcanspanmillimeter, micrometer, and nanometer-size scales while accounting for the associated physics that governthedeviceandenvironmentinteractionateachspecificsizescale.Thiswillrequire newstandardizedarchitectures,advancedcomputationalrepresentations,andinnovativede- signmethodsandprocessesthatsupportmultiplephysics-basedmodelsandallowseamless transitionandtraversingthroughthesevariousmodels. MEMS/NEMS is a significant, extremely timely contribution to the MEMS and nanotechnology field. Edited by Professor Cornelius Leondes, a leading contributor to MEMS/NEMS,thissetoffivewell-integratedvolumesonthesubjectofMEMSandnan- otechnology provides a valuable reference for researchers and practitioners. This multi- volume major reference work features contributions from more than 100 of the world’s foremost MEMS/NEMS authorities in industry, government, and academia. It provides a wealthofthestate-of-the-arttechniquesandapplicationsinMEMS/NEMS.Incontrastto ordinary academic pedagogy, where abstraction and elegance are the guiding principles, practicaltechniquesandapplicationsrequiredetailedrelevantexamplesorcasestudiesthat canbeusedbypractitionerstosuccessfullyinnovatenewdesign,fabrication/manufacturing, andoperationalcapabilities.TheprogressoftheMEMSandnanotechnologydependson x FOREWORD the flow of these innovations, which requires multi-volume major reference works with carefullyselected,well-written,andwell-editedexamplesandapplications. The two most valuable features of this major reference work are the breadth of ma- terial and the depth of the topics covered. Each volume comprehensively treats a sig- nificant and specific subject area of fundamental importance to MEMS/NEMS: design, fabrication/manufacturing, and applications. Volume I addresses the design methods in MEMS/NEMS.Herethereadercanlearnfromsomeoftheleadingindividualsinthefield howtodesignanMEMS/NEMSdeviceorsystem.Ninechapterscomprehensivelydescribe emergingdesign,analysisandsimulation,synthesistechniquesandhowtoapplythemin realapplications.Theseincludeelectrostaticsanalysis,analyticalsimulation,synthesisand dynamic simulation, global optimal design, hierarchical design, knowledge intensive de- sign,concurrent&collaborativedesignmethodologiesandweb-enabledframeworksand systems. Volume II covers the fabrication techniques for MEMS/NEMS devices. In this volume the reader can see the methods and steps taken to effectively fabricate different typesofmicro/nanodevicesandstructures,includingmicrorotors,ultrasonictransducers, thermally-based micro devices, micro fluidic devices, nano-structures, micro-mechanism joints,etc.VolumeIIIdescribesmanufacturingmethods/techniquesforMEMS/NEMSout of micro/nano components or parts, including micro-machine tool prototypes and micro- factories,tool-basedmicro-machining,rapidprototypingandrapidtooling,injectionmold- ing, laser machining, acoustic microscopy scanning, production scheduling, etc. The last two volumes provide insight into developing and deploying micro/nano devices and sys- tems in a wide range of applications. Volume IV comprehensively discusses micro/nano sensorsandactuators,theirmodelingtechniquesandapplicationsinMEMS/NEMS.These includeaccelerometers,micro-humiditysensor,micro-pumpactuator,stressmeasurement sensor,micro-thermalactuator.VolumeVspecificallydescribesmedicalapplicationsof the state-of-the-artMEMS/NEMSandMOEMS(MicroOpticalMechanicalSystems)devices, including: biomedical devices, actuators and sensors for glaucoma treatment, electro- thermal MEMS mirrors, endo-vascular micro-tools, optical MEMS devices, optically integratedpressureandtemperaturesensors,opticalmicro-scanners,torsionmicro-mirrors, etc.Collectively,thismaterialprovidestremendousresourcesforemergingdesign,fabri- cation/manufacturingtechniquesandapplicationsofMEMS/NEMSandMOEMS. Tounderstandtheessenceofthismajorreferencework,wecanconsider/reviewitin thecontextoftheevolutionofMEMS/NEMStechniquesandtheirapplications.Theearly dayswerespentinsomewhatofaprobingfashion,whereresearcherslookedforwaysto designamicro/nanodeviceorsystemthatpromisestohavemultiplefunctionalitiesusing batchfabricationtechniquessimilartothewayintegratedcircuitsaremade.Armedwithan understandingofhowtodesignandfabricateamicro/nanodeviceorsystem,researcherscan continuouslydevelopnewdesign,fabrication/manufacturing,andevencontroltechniques and useful applications to solve real-world problems. The current research extensively covers design, analysis and simulation, synthesis, fabrication/manufacturing, and control techniquesofMEMS/NEMSandtheirapplications.Inparticular,thequantumcontrolled NEMSornanotechnologyisnowthefocalresearchareaallovertheworld.Thetopicsthat arebeingexploredarescalinglawsandprinciplesforNEMS,modelingofNEMSdevices, materialsandstructures,controlofNEMS,andapplicationsofNEMSincarbonnanotubes, nanowires,andmolecularelectronicsareas.Thus,thecurrenteffortcomprisestheresearch thrustsupportingmanufacturingattheatomic,molecular,andmicro-millimeter(nanometer) FOREWORD xi scalesandservesasthemechanismfordevelopmentofrelevantmodels,architectures,and methodsforMEMS/NEMSdesignandmanufacturingaswellascontrolsystems.However, the major challenges we are facing for developing MEMS and nanotechnology products are:lackofcomprehensive,reliablematerialproperties;difficultyinqualifyingnewprocess flowsanddesigntoolsthatmeettherequirementsofconcurrent&collaborativeengineering strategies;packagingdifferingsignificantlyfrommicroelectronics;lackofstandardsacross industry; lack of maturity for design methodologies and tools. Therefore, the emerging techniques,applications,andexamplesofMEMS/NEMScollectedbyProfessorLeondes inthisworkprovideawealthofpracticalideasandmethodologiesdesignedtotriggerthe developmentofinnovation.Thecontributorsinthismajorreferenceworkclearlyrevealthe effectivenessandgreatsignificanceofthetechniquesavailableandwithfurtherdevelopment theessentialrolethattheywillplayinthefuture. Alongthewaytherewereafewindividualswhopublishedorsawtheimportanceof publishingtheaccomplishmentstoprovideguidancetoadvancethefieldofMEMS/NEMS. AmongthissmallgroupIbelievethatProfessorLeondeshasmadethemostcomprehensive and important contribution to this effort. It has taken many decades of experience and unflagging hard work for him to accumulate the wisdom and judgment reflected in the editorial stewardship of this major reference work. The latest work discussed here is his most valuable contribution to date and should be on the desk of anyone involved in the field.Ibelievethatitspublicationwilldefinitelystimulateandpromotefurtherresearchand developmentofMEMS/NEMSandspeeduptheapplicationofMEMS/NEMS. XuanFZha NationalInstituteofStandardsandTechnology Gaithersburg,Maryland,USA July31,2005