李群、李代數(shù)和表示論

出版時(shí)間:2007-10  出版社:世界圖書(shū)出版公司  作者:Brian C. Hall  頁(yè)數(shù):351  
Tag標(biāo)簽:無(wú)  

內(nèi)容概要

This book provides an introduction to Lie groups, Lie algebras, and representation theory, aimed at graduate students in mathematics and physics.Although there are already several excellent books that cover many of the same topics, this book has two distinctive features that I hope will make it a useful addition to the literature. First, it treats Lie groups (not just Lie alge bras) in a way that minimizes the amount of manifold theory needed. Thus,I neither assume a prior course on differentiable manifolds nor provide a con-densed such course in the beginning chapters. Second, this book provides a gentle introduction to the machinery of semisimple groups and Lie algebras by treating the representation theory of SU(2) and SU(3) in detail before going to the general case. This allows the reader to see roots, weights, and the Weyl group "in action" in simple cases before confronting the general theory.    The standard books on Lie theory begin immediately with the general case:a smooth manifold that is also a group. The Lie algebra is then defined as the space of left-invariant vector fields and the exponential mapping is defined in terms of the flow along such vector fields. This approach is undoubtedly the right one in the long run, but it is rather abstract for a reader encountering such things for the first time. Furthermore, with this approach, one must either assume the reader is familiar with the theory of differentiable manifolds (which rules out a substantial part of one's audience) or one must spend considerable time at the beginning of the book explaining this theory (in which case, it takes a long time to get to Lie theory proper).

書(shū)籍目錄

Part I General Theory  Matrix Lie Groups  1.1  Definition of a Matrix Lie Group      1.1.1  Counterexa~ples  1.2  Examples of Matrix Lie Groups      1.2.1  The general linear groups GL(n;R) and GL(n;C)      1.2.2 The special linear groups SL(n; R) and SL(n; C)      1.2.3  The orthogonal and special orthogonal groups, O(n) and SO(n)    1.2.4  The unitary and special unitary groups, U(n) and SU(n)    1.2.5 The complex orthogonal groups, O(n; C) and SO(n; C)     1.2.6  The generalized orthogonal and Lorentz groups    1.2.7 The symplectic groups Sp(n; R), Sp(n;C), and $p(n)     1.2.8  The Heisenberg group H  .    1.2.9  The groups R, C*, S1,  and Rn    1.2.10 The Euclidean and Poincaxd groups E(n) and P(n; 1)  1.3  Compactness    1.3.1  Examples of compact groups    1.3.2  Examples of noncompa groups  1.4  Connectedness  1.5  Simple Connectedness    1.6  Homomorpliisms and Isomorphisms    1.6.1 Example: SU(2) and S0(3)   1.7 The Polar Decomposition for S[(n; R) and SL(n; C)   1.8  Lie Groups   1.9  Exercises2   Lie Algebras and the Exponential Mapping   2.1  The Matrix Exponential   2.2  Computing the Exponential of a Matrix     2.2.1  Case 1: X is diagonalizable     2.2.2  Case 2: X is nilpotent     2.2.3  Case 3: X arbitrary  2.3  The Matrix Logarithm  2.4  Further Properties of the Matrix Exponential  2.5  The Lie Algebra of a Matrix Lie Group    2.5.1  Physicists' Convention    2.5.2  The general linear groups    2.5.3  The special linear groups    2.5.4  The unitary groups    2.5.5  The orthogonal groups    2.5.6  The generalized orthogonal groups    2.5.7  The symplectic groups    2.5.8  The Heisenberg group    2.5.9  The Euclidean and Poincar6 groups  2.6  Properties of the Lie Algebra  2.7  The Exponential Mapping  2.8  Lie Algebras    2.8.1  Structure constants    2.8.2  Direct sums  2.9  The Complexification of a Real Lie Algebra  2.10 Exercises3  The Baker-Campbell-Hausdorff Formula  3.1  The Baker-Campbell-Hausdorff Formula for the Heisenberg Group  3.2  The General Baker-Campbell-Hausdorff Formula  3.3  The Derivative of the Exponential Mapping  3.4  Proof of the Baker-Campbell-Hausdorff Formula    3.5  The Series Form of the Baker-Campbell-Hausdorff Formula   3.6  Group Versus Lie Algebra Homomorphisms  3.7  Covering Groups  3.8  Subgroups and Subalgebras  3.9  Exercises4  Basic Representation Theory    4.1  Representations    4.2  Why Study Representations?  4.3  Examples of Representations    4.3.1  The standard representation    4.3.2  The trivial representation    4.3.3  The adjoint representation    4.3.4  Some representations of S(,1(2)      4.3.5  Two unitary representations of S0(3)    4.3.6  A unitary representation of the reals  ……Part II Semistmple TheoryReferencesIndex

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    李群、李代數(shù)和表示論 PDF格式下載


用戶評(píng)論 (總計(jì)22條)

 
 

  •   Hall是表示論方向的大家幺
  •   和好書(shū)籍,有收獲的啊
  •   建議購(gòu)買!
  •   這個(gè)是老師推薦用書(shū),書(shū)很好。如果當(dāng)當(dāng)可以保證裝訂質(zhì)量就好了
  •   知識(shí)全面,幫助了解
  •   這本書(shū)很好,很經(jīng)典。比較適合初學(xué)者。
  •   挺好的,推薦一下!
  •   學(xué)習(xí)相關(guān)方向的數(shù)學(xué)系學(xué)生值得一看
  •   挺好,很清晰
  •   好書(shū),但比較容易,初學(xué)合適
  •   都17天了.書(shū)還沒(méi)收到.怎么評(píng)價(jià)
  •   這本書(shū)是從矩陣?yán)畲鷶?shù)講起的,因此前提知識(shí)就是矩陣論的一些基本知識(shí),很適合沒(méi)有系統(tǒng)學(xué)習(xí)過(guò)流形的看起。推薦給想要了解李群和李代數(shù)但是沒(méi)有太深背景的朋友閱讀。
  •   適合初學(xué)李群的人學(xué)習(xí),有很多線性李群的例子。
  •   價(jià)格合理,送貨挺快,也有發(fā)票!贊一個(gè)!
  •   只看了開(kāi)頭的一點(diǎn)兒,寫得簡(jiǎn)單、明了,適合初學(xué)者?;蛟S是非李群李代數(shù)專業(yè)的人作為了解性教材。GTM系列教材多是很經(jīng)典的。
  •   當(dāng)時(shí)看到這個(gè)比較適合初學(xué)者就買了,結(jié)果發(fā)現(xiàn)是英文版的,還是慢慢啃吧
  •   買了不少Lie group方面的書(shū),很多都寫得難懂!但這本書(shū)確實(shí)寫的深入淺出!所以對(duì)于初學(xué)者,我強(qiáng)烈推薦這本書(shū)!
  •   1、打開(kāi)封面,接下來(lái)的一頁(yè)破了個(gè)洞2、有的頁(yè)面墨跡深,有的頁(yè)面墨跡淺3、隨便一翻,就發(fā)現(xiàn)第79頁(yè)和第300頁(yè)有不明記號(hào)總之,是一本盜版書(shū)
  •   非常適合沒(méi)有學(xué)過(guò)流形的同學(xué), 比較初等的介紹矩陣群的性質(zhì)
  •   真不知道能不能看得懂?
  •   The arefully choosed contents and exercises, suitble size to be hold in one's hands and the comfortable English writting, all these features make this book into a perfect one... 閱讀更多
  •   李群比較難學(xué),這本書(shū)算是較簡(jiǎn)單的了。
 

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