Book contents
- Frontmatter
- Contents
- Preface
- Notation
- 1 Introduction
- 2 Geometric algebra in two and three dimensions
- 3 Classical mechanics
- 4 Foundations of geometric algebra
- 5 Relativity and spacetime
- 6 Geometric calculus
- 7 Classical electrodynamics
- 8 Quantum theory and spinors
- 9 Multiparticle states and quantum entanglement
- 10 Geometry
- 11 Further topics in calculus and group theory
- 12 Lagrangian and Hamiltonian techniques
- 13 Symmetry and gauge theory
- 14 Gravitation
- Bibliography
- Index
6 - Geometric calculus
Published online by Cambridge University Press: 05 January 2013
- Frontmatter
- Contents
- Preface
- Notation
- 1 Introduction
- 2 Geometric algebra in two and three dimensions
- 3 Classical mechanics
- 4 Foundations of geometric algebra
- 5 Relativity and spacetime
- 6 Geometric calculus
- 7 Classical electrodynamics
- 8 Quantum theory and spinors
- 9 Multiparticle states and quantum entanglement
- 10 Geometry
- 11 Further topics in calculus and group theory
- 12 Lagrangian and Hamiltonian techniques
- 13 Symmetry and gauge theory
- 14 Gravitation
- Bibliography
- Index
Summary
Geometric algebra provides us with an invertible product for vectors. In this chapter we investigate the new insights this provides for the subject of vector calculus. The familiar gradient, divergence and curl operations all result from the action of the vector operator, ∇. Since this operator is vector-valued, we can now form its geometric product with other multivectors. We call this the vector derivative. Unlike the separate divergence and curl operations, the vector derivative has the important property of being invertible. That is to say, Green's functions exist for ∇ which enable initial conditions to be propagated off a surface.
The synthesis of vector differentiation and geometric algebra described in this chapter is called ‘geometric calculus’. We will see that geometric calculus provides new insights into the subject of complex analysis and enables the concept of an analytic function to be extended to arbitrary dimensions. In three dimensions this generalisation gives rise to the angular eigenstates of the Pauli theory, and the spacetime generalisation of an analytic function defines the wavefunction for a massless spin-1/2 particle. Clearly there are many insights to be gained from a unified treatment of calculus based around the geometric product.
The early sections of this chapter discuss the vector derivative, and its associated Green's functions, in flat spaces. This way we can quickly assemble a number of results of central importance in later chapters.
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- Chapter
- Information
- Geometric Algebra for Physicists , pp. 167 - 227Publisher: Cambridge University PressPrint publication year: 2003