01185cam--2200397---450-99000354006020331620121005135928.00-19-928640-X000354006USA01000354006(ALEPH)000354006USA0100035400620110614d2006----km-y0itay50------baengGB||||||||001yyCanonical forms in prosodic morphologyLaura J. DowningOxfordOxford University press2006X, 284 p.24 cmOxford studies in theoretical linguistics12Oxford studies in theoretical linguistics1220012001001-------2001LinguisticaMorfologia415.9DOWNING,Laura J.610142ITsalbcISBD990003540060203316I.8.B.3257 DIPSUMBKDSLLDSLL9020110614USA011023CHIARA9020121005USA011357CHIARA9020121005USA011359Canonical forms in prosodic morphology1113755UNISA03896nam a2200361Ii 4500991003242949707536070806s2003 enka sb 001 0 eng d97819039963791903996376b13654263-39ule_instBibl. Dip.le Aggr. Ingegneria Innovazione - Sez. Ingegneria Innovazioneeng624.122Motro, René,1946-596330Tensegrity[e-book] :structural systems for the future /René MotroLondon ;Sterling, VA :Kogan Page Science,2003xvii, 238 p. :ill. ;24 cmIncludes bibliographical references (p. [228]-236) and index1. Introduction -- 2. History and definitions -- 2-1. Introduction; 2-2. History; 2-3. Definitions; 2-4. Conclusion -- 3. Fundamental concepts -- 3-1. Introduction; 3-2. Relational structure; 3-3. Geometry and stability; 3-4. Selfstress states and mechanisms; 3-5. Conclusion -- 4. Typologies -- 4-1. Introduction; 4-2. Typology criteria and codification; 4-3. Elementary cells or spherical cells; 4-4. Assemblies of cells; 4-5. Conclusion -- 5. Models -- 5-1. Introduction; 5-2. Problems to solve; 5-3. Form finding; 5-4. Selfstress and mechanisms; 5-5. Selftress qualification; 5-6. Designing tensegrity systems; 5-7. Active control; 5-8. Conclusion -- 6. Foldable tensegrities -- 6-1. Introduction; 6-2. Folding principle; 6-3. Foldable modules; 6-4. Foldable assemblies; 6-5. Folding design; 6-6. Simulation of the folding process; 6-7. Modelling the contact of two struts; 6-8. Conclusion -- 7. Tensegrity: Latest And future developments -- 7-1. Introduction; 7-2. New tensegrity grids; 7-3. Other projects; 7-4. Tensegrity as a structural principle; 7-5. Conclusion -- 8. Bibliography -- 9. AppendicesThe word tensegrity results from the contraction of tensional and integrity, a word created by Richard Buckminster Fuller. He went on to describe tensegrity structures as islands of compression in an ocean of tension, and Reň Motro has developed a comprehensive definition which is systems in a stable self equilibriated system comprising a discontinuous set of compressed components inside a continuum of tensioned components. This publication represents the life work of a leading exponent of a revolutionary and exciting method of structural design. * Represents the life work of a leading exponent of a revolutionary and exciting method of structural design * Applicable to architecture as an established structural system, can also be applied to other fields * Design professionals will be able to design better structures. Interested non-professionals will experience the great pleasure of being able to say "I understand why the Hisshorn tower stands up"Electronic reproduction.Amsterdam :Elsevier Science & Technology,2007.Mode of access: World Wide Web.System requirements: Web browser.Title from title screen (viewed on Aug. 2, 2007).Access may be restricted to users at subscribing institutionsGeodesic domesStructural analysis (Engineering)Electronic books.localOriginal19039963769781903996379(DLC) 2003007305(OCoLC)53325359Referexhttp://www.sciencedirect.com/science/book/9781903996379An electronic book accessible through the World Wide Web; click for informationTable of contents onlyhttp://catdir.loc.gov/catdir/toc/ecip042/2003007305.htmlBook review (E-STREAMS)http://www.e-streams.com/es0805/es0805%5F4106.htmlPublisher descriptionhttp://catdir.loc.gov/catdir/enhancements/fy0614/2003007305-d.html.b1365426303-03-2224-01-08991003242949707536Tensegrity990831UNISALENTOle02624-01-08m@ -engenk00