01108nam--2200385---450-99000124533020331620031106110718.00-521-27259-9000124533USA01000124533(ALEPH)000124533USA0100012453320031106d1985----km-y0itay0103----baengUKa|||||||001yyCeramic theory and cultural processDean E. ArnoldCambridge [etc.]Cambridge University Pressi1985XI, 268 p.ill.23 cmNew studies in archaeology2001New studies in archaeology2001001-------2001CeramicheTecnica738.1ARNOLD,Dean E.488149ITsalbcISBD990001245330203316VII S 45101982 L.M.VIIBKUMASIAV11020031106USA011107PATRY9020040406USA011729Ceramic theory and cultural process289216UNISA04009nam 22006255 450 99646661040331620230217110930.03-540-46867-610.1007/BFb0083581(CKB)1000000000437401(SSID)ssj0000325416(PQKBManifestationID)12049792(PQKBTitleCode)TC0000325416(PQKBWorkID)10321715(PQKB)10827809(DE-He213)978-3-540-46867-7(MiAaPQ)EBC5579578(Au-PeEL)EBL5579578(OCoLC)1066176829(MiAaPQ)EBC6842166(Au-PeEL)EBL6842166(OCoLC)1120881620(DE-He213)978-0-387-72831-5(PPN)155168193(EXLCZ)99100000000043740120100301d2008 u| 0engurnn|008mamaatxtccrAdvanced Linear Algebra[electronic resource] /by Steven Roman3rd ed. 2008.New York, NY :Springer New York :Imprint: Springer,2008.1 online resource (VIII, 228 p.) Graduate Texts in Mathematics,2197-5612 ;135Bibliographic Level Mode of Issuance: Monograph0-387-51970-X 3-540-51970-X Basic Linear Algebra -- Vector Spaces -- Linear Transformations -- The Isomorphism Theorems -- Modules I: Basic Properties -- Modules II: Free and Noetherian Modules -- Modules over a Principal Ideal Domain -- The Structure of a Linear Operator -- Eigenvalues and Eigenvectors -- Real and Complex Inner Product Spaces -- Structure Theory for Normal Operators -- Topics -- Metric Vector Spaces: The Theory of Bilinear Forms -- Metric Spaces -- Hilbert Spaces -- Tensor Products -- Positive Solutions to Linear Systems: Convexity and Separation -- Affine Geometry -- Singular Values and the Moore–Penrose Inverse -- An Introduction to Algebras -- The Umbral Calculus.For the third edition, the author has added a new chapter on associative algebras that includes the well known characterizations of the finite-dimensional division algebras over the real field (a theorem of Frobenius) and over a finite field (Wedderburn's theorem); polished and refined some arguments (such as the discussion of reflexivity, the rational canonical form, best approximations and the definitions of tensor products); upgraded some proofs that were originally done only for finite-dimensional/rank cases; added new theorems, including the spectral mapping theorem; considerably expanded the reference section with over a hundred references to books on linear algebra. From the reviews of the second edition: "In this 2nd edition, the author has rewritten the entire book and has added more than 100 pages of new materials....As in the previous edition, the text is well written and gives a thorough discussion of many topics of linear algebra and related fields...the exercises are rewritten and expanded....Overall, I found the book a very useful one....It is a suitable choice as a graduate text or as a reference book." Ali-Akbar Jafarian, ZentralblattMATH "This is a formidable volume, a compendium of linear algebra theory, classical and modern... The development of the subject is elegant...The proofs are neat...The exercise sets are good, with occasional hints given for the solution of trickier problems...It represents linear algebra and does so comprehensively." Henry Ricardo, MAA Online.Graduate Texts in Mathematics,2197-5612 ;135Algebras, LinearLinear AlgebraAlgebras, Linear.Linear Algebra.519.3Dolecki Szymon535043MiAaPQMiAaPQMiAaPQBOOK996466610403316Advanced Linear Algebra3091286UNISA04515nam 2200481z- 450 991055766200332120211118(CKB)5400000000044886(oapen)https://directory.doabooks.org/handle/20.500.12854/73704(oapen)doab73704(EXLCZ)99540000000004488620202111d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierShaping the Brain by Neuronal Cytoskeleton: From Development to Disease and RegenerationFrontiers Media SA20201 online resource (185 p.)2-88963-552-X The coordinated action of the different cytoskeletal polymers--microtubules, actin filaments and neurofilaments-- is essential for the establishment, remodeling and maintenance of neuronal architecture throughout the neuron lifetime. Neurons are among the most polarized cells, with a long thin axon and multiple thicker and shorter dendrites. Achieving this complex morphology, and the precise and accurate formation of an intricate network of synaptic contacts is critical for the proper transmission and reception of signals in the brain. Neuronal polarization precedes axon outgrowth and the subsequent differentiation of short neurites into dendrites, as part of the neuronal differentiation program that involves both intrinsic and extrinsic signals that converge at the cytoskeletal level. Growth cones, which are sensory and locomotor structures located at the tip of growing axons, are key elements in the transduction of extracellular cues into cytoskeletal changes, guiding axons to their right destinations. Neuronal migration, another crucial process during brain development, occurs in close coordination with neuronal differentiation. Migration involves as well an extensive rearrangement of neuronal cell shape that relies on cytoskeleton reorganization. Further processes, such as dendritic spine formation and growth, establishment of synaptic contacts or synaptic plasticity in mature neurons also depend on cytoskeletal dynamics. Fine-tune regulation of neuronal cytoskeleton is therefore crucial for the maintenance of neuronal integrity and functionality. Mutations in genes that code for cytoskeletal proteins often have deleterious effects in neurons, such as abnormal migration or differentiation, deficient axonal transport of organelles and synaptic vesicles, or impaired synaptic signaling. Several human Nervous System disorders, including neurodevelopmental, psychiatric, and neurodegenerative diseases, have been linked to cytoskeletal dysfunction. Cytoskeletal reorganization is also crucial to regulate nerve cell repair following Nervous System injury. Many of the pathways that control cell-intrinsic axon regeneration lead to axon cytoskeletal remodeling. Moreover, most extracellular cues that inhibit regeneration of damaged axons in Central Nervous System following traumatic injury or neurodegeneration, are known to modulate cytoskeletal dynamics and organization. Based on these findings, regulators of cytoskeleton dynamics have emerged as promising therapeutic targets in several brain disorders and in the context of regeneration of injured axons. Hence, remodeling of neuronal cytoskeleton underlies all the dramatic morphological changes that occur in developing and adult neurons. Understanding the specific molecular mechanisms that control cytoskeleton rearrangements in neurons is far from complete. This Frontiers Research Topic gathers a selection of articles focused on the diverse and key roles of cytoskeleton in neuronal biology.Shaping the Brain by Neuronal CytoskeletonNeurosciencesbicsscScience: general issuesbicsscactin cytoskeletonastrocyte cytoskeletonmicrotubules (MTs)neuronneuronal cytoskeletontauNeurosciencesScience: general issuesLaura Sayas Cedt1302165Mendes Sousa MonicaedtAvila JesusedtLaura Sayas CothMendes Sousa MonicaothAvila JesusothBOOK9910557662003321Shaping the Brain by Neuronal Cytoskeleton: From Development to Disease and Regeneration3026187UNINA