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dc.contributor.authorTosello, Guido*
dc.date.accessioned2021-02-12T00:02:51Z
dc.date.available2021-02-12T00:02:51Z
dc.date.issued2019*
dc.date.submitted2019-06-26 08:44:06*
dc.identifier33665*
dc.identifier.urihttps://directory.doabooks.org/handle/20.500.12854/57091
dc.description.abstractThe continuous miniaturization of products and the growing complexity of their embedded multifunctionalities necessitates continuous research and development efforts regarding micro components and related micro manufacturing technologies. Highly miniaturized systems, manufactured using a wide variety of materials, have found application in key technological fields, such as healthcare devices, micro implants, mobility, communications, optics, and micro electromechanical systems. Innovations required for the high-precision manufacturing of micro components can specifically be achieved through optimizations using post-process (i.e., offline) and in-process (i.e., online) metrology of both process input and output parameters, as well as geometrical features of the produced micro parts. However, it is of critical importance to reduce the metrology and optimization efforts, since process and product quality control can represent a significant portion of the total production time in micro manufacturing. To solve this fundamental challenge, research efforts have been undertaken in order to define, investigate, implement, and validate the so-called “product/process manufacturing fingerprint” concept. The “product manufacturing fingerprint” concept refers to those unique dimensional outcomes (e.g., surface topography, form error, critical dimensions, etc.) on the produced component that, if kept under control and within specifications, ensure that the entire micro component complies to its specifications. The “process manufacturing fingerprint” is a specific process parameter or feature to be monitored and controlled, in order to maintain the manufacture of products within the specified tolerances. By integrating both product and process manufacturing fingerprint concepts, the metrology and optimization efforts are highly reduced. Therefore, the quality of the micro products increases, with an obvious improvement in production yield. Accordingly, this Special Issue seeks to showcase research papers, short communications, and review articles that focus on novel methodological developments and applications in micro- and sub-micro-scale manufacturing, process monitoring and control, as well as micro and sub-micro product quality assurance. Focus will be on micro manufacturing process chains and their micro product/process fingerprint, towards full process optimization and zero-defect micro manufacturing.*
dc.languageEnglish*
dc.subjectT1-995*
dc.subject.othern/a*
dc.subject.otherFresnel lenses*
dc.subject.otherElectro sinter forging*
dc.subject.othermicro-injection moulding*
dc.subject.othersurface roughness*
dc.subject.othercharge relaxation time*
dc.subject.otheroptimization*
dc.subject.othergratings*
dc.subject.otherplasma-electrolytic polishing*
dc.subject.othermicro structures replication*
dc.subject.othermicro-grinding*
dc.subject.otherelectrical discharge machining*
dc.subject.otherinjection molding*
dc.subject.otherquality control*
dc.subject.othercommercial control hardware*
dc.subject.otherelectrical current*
dc.subject.otherdamping*
dc.subject.otherprocess monitoring*
dc.subject.otherfingerprints*
dc.subject.otherimpact analysis*
dc.subject.othercurrent monitoring*
dc.subject.otherprocess control*
dc.subject.otherquality assurance*
dc.subject.othersurface integrity*
dc.subject.othermicrofabrication*
dc.subject.othermicroinjection moulding*
dc.subject.otherelectro chemical machining*
dc.subject.othersuperhydrophobic surface*
dc.subject.othersurface modification*
dc.subject.otherhaptic actuator*
dc.subject.otherelectrical discharge machining (EDM)*
dc.subject.othersurface morphology*
dc.subject.otherinline metrology*
dc.subject.otheroptical quality control*
dc.subject.otherfinishing*
dc.subject.otherflow length*
dc.subject.otherprecision injection molding*
dc.subject.otherlaser ablation*
dc.subject.othermicro metrology*
dc.subject.otherHalbach linear motor*
dc.subject.other2-step analysis*
dc.subject.othercomputer holography*
dc.subject.otherPeP*
dc.subject.othersatellite drop*
dc.subject.otherprocess fingerprint*
dc.subject.othermaterials characterisation*
dc.subject.othercurrent density*
dc.subject.othermicro drilling*
dc.subject.othermulti-spectral imaging*
dc.subject.otherlithography*
dc.subject.othermanufacturing signature*
dc.subject.otherartificial compound eye*
dc.subject.otherelectrohydrodynamic jet printing*
dc.subject.otherECM*
dc.subject.otherpositioning platform*
dc.subject.otherdiffractive optics*
dc.subject.otherbioceramics*
dc.subject.otherresistance sintering*
dc.subject.otheruncertainty budget*
dc.subject.otherproduct fingerprint*
dc.subject.otherconfocal microscopy*
dc.subject.otherspectral splitting*
dc.subject.otherdental implant*
dc.subject.otherdesirability function*
dc.subject.otherinjection compression molding*
dc.subject.otherelectrochemical machining (ECM)*
dc.subject.otherhigh strain rate effect*
dc.subject.otherprocess fingerprints*
dc.titleProduct/Process Fingerprint in Micro Manufacturing*
dc.typebook
oapen.identifier.doi10.3390/books978-3-03921-035-0*
oapen.relation.isPublishedBy46cabcaa-dd94-4bfe-87b4-55023c1b36d0*
virtual.oapen_relation_isPublishedBy.publisher_nameMDPI - Multidisciplinary Digital Publishing Institute
virtual.oapen_relation_isPublishedBy.publisher_websitewww.mdpi.com/books
oapen.relation.isbn9783039210343*
oapen.relation.isbn9783039210350*
oapen.pages274*
oapen.edition1st*


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