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A First Course in General Relativity

A First Course in General Relativity

  • Downloads:9096
  • Type:Epub+TxT+PDF+Mobi
  • Create Date:2022-06-25 08:52:15
  • Update Date:2025-09-07
  • Status:finish
  • Author:Bernard F. Schutz
  • ISBN:1108492673
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Summary

Clarity, readability, and rigor combine in the third edition of this widely used textbook to provide the first step into general relativity for advanced undergraduates with a minimal background in mathematics。 Topics within relativity that fascinate astrophysics researchers and students alike are covered with Schutz's characteristic ease and authority, from black holes to relativistic objects, from pulsars to the study of the Universe as a whole。 This third edition contains discoveries by astronomers that require general relativity for their explanation; two chapters on gravitational waves, including direct detections of gravitational waves and their observations' impact on cosmological measurements; new information on black holes and neutron stars; and greater insight into the expansion of the Universe。 Over 300 exercises, many new to this edition, give students the confidence to work with general relativity and the necessary mathematics, while the informal writing style and worked examples make the subject matter easily accessible。

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Reviews

Timothy Morrison

The way in which special relativity is taught at an elementary undergraduate level – thelevel at which the reader is assumed competent – is usually close in spirit to the way it wasfirst understood by physicists。 This is an algebraic approach, based on the Lorentz transformation (§ 1。7 below)。 At this basic level, we learn how to use the Lorentz transformation toconvert between one observer’s measurements and another’s, to verify and understand suchremarkable phenomena as time dilation and Loren The way in which special relativity is taught at an elementary undergraduate level – thelevel at which the reader is assumed competent – is usually close in spirit to the way it wasfirst understood by physicists。 This is an algebraic approach, based on the Lorentz transformation (§ 1。7 below)。 At this basic level, we learn how to use the Lorentz transformation toconvert between one observer’s measurements and another’s, to verify and understand suchremarkable phenomena as time dilation and Lorentz contraction, and to make elementarycalculations of the conversion of mass into energy。 。。。more

Eric Holzman

I have a PhD in electrical engineering from UCLA。 20 years ago, just out of my desire to better understand cosmology, I spent a year studying this book and working the problems on my own。 I learned a lot about General Relativity。 Having a solution set with at least the answers to each chapter’s problems would help a lot。

Ami Iida

excellent book

Lulu

General relativity — for when you get serious

WarpDrive

This is an informative, very readable, gentle introduction to general relativity, perfectly suitable to advanced undergraduates (it has been designed, and often used, as a reference text to one-year general relativity courses at senior undergraduate level)。 The book assumes the minimum of pre-requisites, without watering down the subject matter, and without compromising on mathematical depth and rigour。 The approach of the book is pedagogically excellent: after a good speedy review of the main c This is an informative, very readable, gentle introduction to general relativity, perfectly suitable to advanced undergraduates (it has been designed, and often used, as a reference text to one-year general relativity courses at senior undergraduate level)。 The book assumes the minimum of pre-requisites, without watering down the subject matter, and without compromising on mathematical depth and rigour。 The approach of the book is pedagogically excellent: after a good speedy review of the main concepts of special relativity, the author develops, in a gentle and highly intuitive manner, tensor calculus in special relativity, and in curvilinear coordinates in Euclidean and Minkowski spaces; he then deals with differential geometry in curved manifolds, and once all this necessary mathematical apparatus is properly explained, the book addresses the concepts of physics in a curved spacetime, until we finally get to the beautiful field equations of general relativity。 Remarkable conceptual lucidity, mathematical rigour and a stress on physical intuition all contribute to an excellent level of readability, supported also by a relativity low number of typos (all very easily identifiable anyway)。 The concept of tensor is developed with an emphasis more on geometric aspects rather than on transformation properties, an approach that I previously saw employed with some good degree of success by Roger Penrose in his masterpiece (the “Road To Reality”), but to which I personally prefer the more algebraic approach that puts the priority on transformation properties。Non-Euclidean geometry is similarly introduced in a “constructive”, “applied” way rather than starting as abstract mathematical idealizations, which again is a question of personal tastes and objectives。 On the other hand, I really liked how the author adopted the "perfect fluid" model analogy, which I found quite effective in gaining a more “physical” understanding of the stress-energy tensor which is a fundamental concept, as it describes the density and flux of energy and momentum in spacetime, thus representing the source of gravitational field in Einstein's field equations。 In more general terms, critical concepts and items such as equivalence principles, the metric tensor, parallel transport, covariant derivative, Christoffel symbols, curvature, geodesics and many others, are all explained in a concise but mathematically rigorous manner, with derivations that never leave too many missing steps to the reader, who can always complete such derivations with a very reasonable level of effort。 I particularly enjoyed the progression with which the mathematical machinery for dealing with curvature is explored, and how and its associated Riemann curvature tensor (and its contractions: Ricci Tensor, Ricci scalar, Einstein tensor) are all addressed in a very effective way。The only issue that I have with the author's overall approach is that occasionally too much material is left as exercise to be read and completed in the problem section of each chapter – I strongly recommend that such sections be investigated as thoroughly as the main text, in order to get the maximum benefits out of this book。 Once the field equations are treated, the last few chapters of the book shift the focus to astrophysics and cosmology: gravitational waves, general solution for static spherically symmetric spacetimes, the all-important Schwarzschild metric, quantum mechanical pressure inside a star。 All these subjects are treated with concise clarity too。 Chapter 11 (which I skipped, as not of primary interest to me at the moment, because of their very specific, technical astrophysical/cosmological nature) deals with black holes, perihelion shift and gravitational lensing。 Overall , this is a very good introductory book to general relativity。 A good, solid starting point, an helpful and informative stepping stone recommended to readers who then want to get into more comprehensive treatments of the subject, and an accessible and rewarding read。 4 stars - definitely recommended。 。。。more

Rhonald Lua

This was our textbook in a course on General Relativity and Cosmology taught by Professor Chien at the University of Minnesota in the early 2000s。 Love it。 My first exposure to GR in "modern" notation。 I first borrowed a copy from the old British Council Library in New Manila when I was in highschool。 Good times。 This was our textbook in a course on General Relativity and Cosmology taught by Professor Chien at the University of Minnesota in the early 2000s。 Love it。 My first exposure to GR in "modern" notation。 I first borrowed a copy from the old British Council Library in New Manila when I was in highschool。 Good times。 。。。more

Chris Dessert

The explanations were often unclear with vague examples。 I learned 80% from class lectures。

Herjuno Nindhito

A really good book! I recommend this book for everyone who want to know how genius Einstein was。 By the structure point of view, this book is spot on。 It starts with mathematical tools to work with a curved space like vectors, one-forms, dual space, and tensor algebra。 Then it proceeds to the redshift experiment and the importance of curved space by introducing Riemann tensor with Ricci and Einstein tensor afterwards。Fun things start to happen when one start to work with physics in curved space。 A really good book! I recommend this book for everyone who want to know how genius Einstein was。 By the structure point of view, this book is spot on。 It starts with mathematical tools to work with a curved space like vectors, one-forms, dual space, and tensor algebra。 Then it proceeds to the redshift experiment and the importance of curved space by introducing Riemann tensor with Ricci and Einstein tensor afterwards。Fun things start to happen when one start to work with physics in curved space。 Gravitational waves come into play here and suddenly one can work with fascinating stuff like Schwarzchild metric and black holes。 At this points, one can overlook to recent infamous paper like holographic principle, Hawking radiation, or Alcubierre drive。The last chapter of the book tells us about cosmology and upcoming issues with general relativity like Robertson-Walker metric, accelerating universe, etc。This book is one of the best books that I can recommend to all physics enthusiasts (or nerds)。 Glad midsommar! 。。。more

Chris Dessert

The problems weren't that great。 They were mostly just asking you to explore derivations in the text more fully rather than asking interesting questions about the material。 I didn't find his explanations very clear either, although in class we used a different notation so that's probably the source of that issue。 The problems weren't that great。 They were mostly just asking you to explore derivations in the text more fully rather than asking interesting questions about the material。 I didn't find his explanations very clear either, although in class we used a different notation so that's probably the source of that issue。 。。。more

Erickson

Very good book to start general relativity。 The first four chapters carefully work out the necessary mathematics, in more geometric forms than just emphasizing transformation rules。 The fluid analogy was especially helpful for understanding stress-energy tensor which is the source of gravitational field。The next four chapters brought the readers to the real essence of general relativity - the physics and mathematics of curvature itself。 Somehow he managed to bring out the flavour really clearly。 Very good book to start general relativity。 The first four chapters carefully work out the necessary mathematics, in more geometric forms than just emphasizing transformation rules。 The fluid analogy was especially helpful for understanding stress-energy tensor which is the source of gravitational field。The next four chapters brought the readers to the real essence of general relativity - the physics and mathematics of curvature itself。 Somehow he managed to bring out the flavour really clearly。 While the chapters on cosmology and gravitational waves are not as useful unless explicit astronomical calculations related to interferometry and telescopes are needed, the book itself has presented good overview and detail of the theory。 The closure using Schwarzschild black hole was a good one, good enough to launch readers to the next subsequent books with more details。Skipped gravitational radiation chapter for the time being, while reading cosmology as introduction。 Overall, this book really is good especially if you bother to do the exercises - very instructive among them being computing by hand Einstein tensor, Riemann tensor, Ricci scalar, etc。 which will take very long time but doing once helps。 For example, it becomes clear how Christoffel symbol takes part in computation of these quantities and why GR is a computationally intensive subject。 It was also clear by doing manual computation why Bianchi identities implies only 20 out of 256 components of curvature tensor are independent。 。。。more

Matt

Well written from a mathematics viewpoint。 Not 100% application but still a good text。 Chapter 6 on Curved Manifolds was my favorite。

Dylan

very good introduction to general relativity, i think。 the introduction to tensors is especially great。 i didn't read very much on gravitational radiation, and some of the later chapters were not as good as the earlier ones。 but overall, very good。 and though i don't have the most qualified opinion, i think it prepares you pretty well for MTW (if you're into that)。 very good introduction to general relativity, i think。 the introduction to tensors is especially great。 i didn't read very much on gravitational radiation, and some of the later chapters were not as good as the earlier ones。 but overall, very good。 and though i don't have the most qualified opinion, i think it prepares you pretty well for MTW (if you're into that)。 。。。more

Bhuvanesh

Easy-to-read undergrad-level introduction to general relativity (with a review of special relativity)。

Sumeet Pradhan

As the title indicates, a handy introduction to GR。 A grasp of high school mechanics, college level calculus and linear algebra is all that you need to start digging into this book。 The books starts with a refresher chapter on SR with importance laid on the geometric construct of SR rather than the analytic way that is read in high school。 Few chapters familiarizes the reader with 4-vector concepts before delving into the equivalence principle that forms the core of GR。 Non-euclidean geometry is As the title indicates, a handy introduction to GR。 A grasp of high school mechanics, college level calculus and linear algebra is all that you need to start digging into this book。 The books starts with a refresher chapter on SR with importance laid on the geometric construct of SR rather than the analytic way that is read in high school。 Few chapters familiarizes the reader with 4-vector concepts before delving into the equivalence principle that forms the core of GR。 Non-euclidean geometry is introduced later in more of an applied way rather than starting as abstract mathematical construct。 I haven't gone through the last two chapters that are dedicated to gravitational waves and application to cosmology。 。。。more

Ian Durham

The best introductory text on the subject that exists。 One of the best texts I've ever read。 The best introductory text on the subject that exists。 One of the best texts I've ever read。 。。。more

Bria

Dude, I know everyone makes typos, but in complex physical theories the difference between a 1 and a 0 or a + and a - can be kind of significant。

Chris

I said a while back that Shankar's "Principles of Quantum Mechanics" was the best textbook I ever used, I want to amend that and put this on top。 Very clear and extremely interesting (But manageable!) exercises。 Although he assumes nothing beyond vector calculus and linear algebra, I can't help but come to the conclusion that I would have had a lot harder time had I no differential geometry background。Highly recommended! Edit 2016: I really liked this book as an introduction to SR/GR and definit I said a while back that Shankar's "Principles of Quantum Mechanics" was the best textbook I ever used, I want to amend that and put this on top。 Very clear and extremely interesting (But manageable!) exercises。 Although he assumes nothing beyond vector calculus and linear algebra, I can't help but come to the conclusion that I would have had a lot harder time had I no differential geometry background。Highly recommended! Edit 2016: I really liked this book as an introduction to SR/GR and definitely still recommend it。 Although, I've found its not something that I refer to that much anymore。 There are much more in-depth treatments of the topics covered (i。e。 MTW, Carroll, Wald etc。) 。。。more

Erik

Probably not a good textbook (as it is advertised) but a good reference and guide for physical clarity and intuition。 Builds from SR to GR step by step。

Huyen

usually, physics/ math textbooks give me giant yawns, but this one is definitely exceptional, I enjoyed reading it a lot。 thank god Bernard Schutz skips all that torturous index gymnastics of differential geometry and jumps straight into special and general relativity (where half of the quantities in diff geom happily die and leave us in peace)。 his introduction to tensor calculus is very helpful。 lots of clear explanations, for example why mutual length contraction or time dilation is not a con usually, physics/ math textbooks give me giant yawns, but this one is definitely exceptional, I enjoyed reading it a lot。 thank god Bernard Schutz skips all that torturous index gymnastics of differential geometry and jumps straight into special and general relativity (where half of the quantities in diff geom happily die and leave us in peace)。 his introduction to tensor calculus is very helpful。 lots of clear explanations, for example why mutual length contraction or time dilation is not a contradiction at all (this one has ALWAYS got me), or how Einstein followed his particular line of reasoning find analogy of Newton's gravity- no preferred coordinate system- local conservation of energy- special relativity in the locally inertial frame to develop the field equation。 gets a bit more technical when it comes to black holes and neutron stars, but bearable。 fascinating book! 。。。more

Lluvia Zuniga

Too dense。

Jamie

This is where I started learning modern mathematics (as well as GR)。

Reference

google book https://www.google.com/search?tbm=bks&q=A First Course in General Relativity

hathitrust digital library https://babel.hathitrust.org/cgi/ls?q1=A First Course in General Relativity&field1=ocr&a=srchls&ft=ft&lmt=ft

The British Library https://bll01.primo.exlibrisgroup.com/discovery/search?query=any,contains,A First Course in General Relativity&tab=LibraryCatalog&search_scope=Not_BL_Suppress&vid=44BL_INST:BLL01&lang=en&offset=0