《孙维刚谈立志成才:全班55%怎样考上北大清华》是已故的全国特级教师孙维刚老师写给学生、教师、家长的。作者辩证地看待和解决了应试教育与素质教育的关系，辩证地解决了教书与育人间的关系，即“德育的成功，将有力地促进开发智育的进程；而德育的苍白或紊乱，将滞误智育工作顺利的进行”，坚持德、智、体全面发展，一切为了育人，培育出了一批批高素质的人才。

From the reviews: "Karoubi’s classic K-Theory, An Introduction … is ‘to provide advanced students and mathematicians in other fields with the fundamental material in this subject’. … K-Theory, An Introduction is a phenomenally attractive book: a fantastic introduction and then some. … serve as a fundamental reference and source of instruction for outsiders who would be fellow travelers." (Michael Berg, MAA Online, December, 2008)

小学数学基础知识手册，ISBN：9787530329689，作者：薛金星

《新东方·GMAT数学高分快速突破》具有以下几个特点：①透析出题规律，详尽梳理归纳数学考点，把握最新命题动向：完全按照ETS的数学考试大纲，全面系统地梳理、归纳、讲解GMAT数学考点，免去因某考点的生疏而寻读数学教科书之苦。②采用分项思维密集训练的方法，激发考生的数学潜力：在熟悉数学术语的基础之上，本书第二篇对各类数学考题进行分项密集强化训练。读者可通过考题进一步熟悉、掌握相关数学术语，并且熟悉相关题目的问法、句型及解题方法和技巧。③易错题、重点题与难题一览无遗：本书所选的所有题目全部来自于作者对新东方学员进行统计调查而产生的公认的易错题、重点题与难题，弥补了因新东方的课时限制而对数学讲解较少的缺陷。④数学术语、解题窍门全面总结：所有考试中遇到的或有可能遇到的数学术语均在附录中给出，并给出所有题目的详细讲解。⑤最新试题模拟：本书第三篇给出150道与GMAT机考难度相当且为机考可能重点考查的模拟试题，读者可在考前30天左右限时进行训练。⑥再也不用把过多的精力与时间浪费在简单无聊的数学题上：读者阅读本书必能起到事半功倍的功效，从而再也不用把过多的精力、时间浪费在简单无聊的数学题上。

During its first hundred years, Riemannian geometry enjoyed steady, but undistinguished growth as a field of mathematics. In the last fifty years of the twentieth century, however, it has exploded with activity. Berger marks the start of this period with Rauch’s pioneering paper of 1951, which contains the first real pinching theorem and an amazing leap in the depth of the connection between geometry and topology. Since then, the field has become so rich that it is almost impossible for the uninitiated to find their way through it. Textbooks on the subject invariably must choose a particular approach, thus narrowing the path. In this book, Berger provides a truly remarkable survey of the main developments in Riemannian geometry in the last fifty years. One of the most powerful features of Riemannian manifolds is that they have invariants of (at least) three different kinds. There are the geometric invariants: topology, the metric, various notions of curvature, and relationships among these. There are analytic invariants: eigenvalues of the Laplacian, wave equations, Schrödinger equations. There are the invariants that come from Hamiltonian mechanics: geodesic flow, ergodic properties, periodic geodesics. Finally, there are important results relating different types of invariants. To keep the size of this survey manageable, Berger focuses on five areas of Riemannian geometry: Curvature and topology; the construction of and the classification of space forms; distinguished metrics, especially Einstein metrics; eigenvalues and eigenfunctions of the Laplacian; the study of periodic geodesics and the geodesic flow. Other topics are treated in less detail in a separate section. While Berger’s survey is not intended for the complete beginner (one should already be familiar with notions of curvature and geodesics), he provides a detailed map to the major developments of Riemannian geometry from 1950 to 1999. Important threads are highlighted, with brief descriptions of the results that make up that thread. This supremely scholarly account is remarkable for its careful citations and voluminous bibliography. If you wish to learn about the results that have defined Riemannian geometry in the last half century, start with this book.