00930nam a2200277 i 450099100136750970753620020507124951.0991025s1998 it ||| | ita 8815060073b10210854-39ule_instLE02984660ExLISUFI - Sett. Diritti e Politiche Euromediterraneeita343.072Pera, Alberto83965Concorrenza e antitrust /Alberto PeraBologna :Il Mulino,c1998127 p. ;20 cmFarsi un'idea ;28AntitrustConcorrenza.b1021085417-02-1727-06-02991001367509707536LE029 343.072 PER01.01 A.T.1LE029-1272le029-E0.00-no 00000.i1025943027-06-02Concorrenza e antitrust46052UNISALENTOle02901-01-99ma -itait 0104758nam 2201165z- 450 991058021060332120220706(CKB)5690000000011982(oapen)https://directory.doabooks.org/handle/20.500.12854/87427(oapen)doab87427(EXLCZ)99569000000001198220202207d2022 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierSymmetry in Structural Health MonitoringBaselMDPI - Multidisciplinary Digital Publishing Institute20221 online resource (310 p.)3-0365-4237-X 3-0365-4238-8 In this Special Issue on symmetry, we mainly discuss the application of symmetry in various structural health monitoring. For example, considering the health monitoring of a known structure, by obtaining the static or dynamic response of the structure, using different signal processing methods, including some advanced filtering methods, to remove the influence of environmental noise, and extract structural feature parameters to determine the safety of the structure. These damage diagnosis methods can also be effectively applied to various types of infrastructure and mechanical equipment. For this reason, the vibration control of various structures and the knowledge of random structure dynamics should be considered, which will promote the rapid development of the structural health monitoring. Among them, signal extraction and evaluation methods are also worthy of study. The improvement of signal acquisition instruments and acquisition methods improves the accuracy of data. A good evaluation method will help to correctly understand the performance with different types of infrastructure and mechanical equipment.History of engineering & technologybicsscTechnology: general issuesbicsscARMAartificial neutral networkBPNNcable clampcollision responseconcrete surfaceconstruction processconvolutional neural networkcoupling modelcrack detectioncurved surface fittingcurvedcontinuous girder bridgedamperdata anomaly detectiondeep learningdigital twindynamic responsefinite element methodflatness calculation datumforce analysisfrequency domainfrequency-domain integration approach (FDIA)genetic algorithmH∞ controlheavy-duty vehiclehigh formworkHilbert-Huang transform (HHT)improved YOLOv4integration algorithmintelligent constructionmicro inertial measurement unit (MIMU)mixed sensitivitymultiple square loops (MSL)-stringnear and far fieldoffshore oil platformpounding mitigation and unseating preventionprestressed steel structurereal-time hybrid simulationRGBroadsafety assessmentseismic excitationseismic mitigationseismic pulseself-anchored suspension bridgeslippagestress trend predictionstructural health monitoringstructural health monitoring (SHM)substructure shake table testingsurface flatness of initial support of tunneltechnical codesterrestrial laser scanningthree-dimensional laser scanningtime delaytime domaintime-frequency domaintime-frequency extractiontorsion angle calculationvariational mode decomposition (VMD)vibrationHistory of engineering & technologyTechnology: general issuesYang Yangedt710870Lei YingedtMeng XiaolinedtLi JunedtYang YangothLei YingothMeng XiaolinothLi JunothBOOK9910580210603321Symmetry in Structural Health Monitoring3033336UNINA