George Jones said:As n!kofeyn has stated, contents of differential geometry references vary widely. Another book worth looking at is Differential Geometry and Lie Groups for Physicists by Marian Fecko,
https://www.amazon.com/dp/0521845076/?tag=pfamazon01-20.
This book is not as rigorous as the books by Lee and Tu, but it more rigorous and comprehensive than the book by Schutz. Fecko treats linear connections and associated curvature, and connections and curvature for bundles. Consequently, Fecko can be used for a more in-depth treatment of the math underlying both GR and gauge firld theories than traditionally is presented in physics courses.
Fecko has an unusual format. From its Preface,
A specific feature of this book is its strong emphasis on developing the general theory through a large number of simple exercises (more than a thousand of them), in which the reader analyzes "in a hands-on fashion" various details of a "theory" as well as plenty of concrete examples (the proof of the pudding is in the eating).
The book is reviewed at the Canadian Association of Physicists website,
http://www.cap.ca/BRMS/Reviews/Rev857_554.pdf.
From the review
There are no problems at the end of each chapter, but that's because by the time you reached the end of the chapter, you feel like you've done your homework already, proving or solving every little numbered exercise, of which there can be between one and half a dozen per page. Fortunately, each chapter ends with a summary and a list of relevant equations, with references back to the text. ...
A somewhat idiosyncratic flavour of this text is reflected in the numbering: there are no numbered equations, it's the exercises that are numbered, and referred to later.
Personal observations based on my limited experience with my copy of the book:
1) often very clear, but sometimes a bit unclear;
2) some examples of mathematical imprecision/looseness, but these examples are not more densely distributed than in, say, Nakahara;
3) the simple examples are often effective.
Tensor Calculus is a branch of mathematics that deals with the manipulation and analysis of tensors, which are mathematical objects that describe linear relationships between vectors and other tensors. In physics, tensors are used to describe physical quantities and their relationships in a way that is independent of the coordinate system being used. This makes tensor calculus a powerful tool for solving problems in fields such as relativity, electromagnetism, and fluid dynamics.
Some examples of tensors in real life include stress tensors in materials, strain rate tensors in fluid dynamics, and the curvature tensor in general relativity. These tensors are used to describe physical properties and phenomena, such as the behavior of materials under stress, the flow of fluids, and the curvature of spacetime.
Tensor Calculus differs from other branches of mathematics in that it deals specifically with tensors, which are multidimensional arrays of numbers that represent physical quantities. Unlike other branches of mathematics that focus on specific types of numbers or operations, tensor calculus is a more general and abstract approach to mathematical analysis.
Yes, Tensor Calculus has applications in various fields such as engineering, computer science, and economics. In engineering, tensors are used to describe the properties of materials and structures. In computer science, tensors are used in machine learning algorithms. In economics, tensors are used to model and analyze complex systems.
Tensor Calculus can be challenging to learn, as it requires a strong understanding of linear algebra and multivariable calculus. However, with dedication and practice, anyone can learn the fundamentals of tensor calculus. It is important to have a solid foundation in mathematics before diving into this subject.