Paravector Explained

The name paravector is used for the combination of a scalar and a vector in any Clifford algebra, known as geometric algebra among physicists.

This name was given by J. G. Maks in a doctoral dissertation at Technische Universiteit Delft, Netherlands, in 1989.

The complete algebra of paravectors along with corresponding higher grade generalizations, all in the context of the Euclidean space of three dimensions, is an alternative approach to the spacetime algebra (STA) introduced by David Hestenes. This alternative algebra is called algebra of physical space (APS).

Fundamental axiom

For Euclidean spaces, the fundamental axiom indicates that the product of a vector with itself is the scalar value of the length squared (positive)

vv=v ⋅ v

Writing

v=u+w,

and introducing this into the expression of the fundamental axiom

(u+w)^2
=uu+ uw+wu+ ww,

we get the following expression after appealing to the fundamental axiom again

u ⋅ u+ 2u ⋅ w+ w ⋅ w=u ⋅ u+ uw+wu+ w ⋅ w,

which allows toidentify the scalar product of two vectors as

u ⋅ w=

	1
	2

\left(uw+wu\right).

As an important consequence we conclude that two orthogonal vectors (with zero scalar product) anticommute

uw+wu=0

The three-dimensional Euclidean space

The following list represents an instance of a complete basis for the

C\ell₃

space,

\{1,\{e_1,e_2,e₃\},\{e₂₃,e₃₁,e₁₂\},e₁₂₃\},

which forms an eight-dimensional space, where the multiple indices indicate the product of the respective basis vectors, for example

e₂₃=e₂e₃.

The grade of a basis element is defined in terms of the vector multiplicity, such that

Grade	Type	Basis element/s
0	Unitary real scalar	1
1	Vector	\{e_1,e_2,e₃\}
2	Bivector	\{e₂₃,e₃₁,e₁₂\}
3	Trivector volume element	e₁₂₃

According to the fundamental axiom, two different basis vectors anticommute,

e_ie_j+e_je_i=2\delta_ij

or in other words,

e_ie_j=-e_je_i;i ≠ j

This means that the volume element

e₁₂₃

squares to

-1

	2
e
	123

=e₁e₂e₃e₁e₂e₃= e₂e₃e₂e₃= -e₃e₃=-1.

Moreover, the volume element

e₁₂₃

commutes with any other element of the

C\ell(3)

algebra, so that it can be identified with the complex number

, whenever there is no danger of confusion. In fact, the volume element

e₁₂₃

along with the real scalar forms an algebra isomorphic to the standard complex algebra. The volume element can be used to rewrite an equivalent form of thebasis as

Grade	Type	Basis element/s
0	Unitary real scalar	1
1	Vector	\{e_1,e_2,e₃\}
2	Bivector	\{ie₁,ie₂, ie₃\}
3	Trivector volume element	i

Paravectors

The corresponding paravector basis that combines a real scalar and vectors is

\{1,e_1,e_2,e₃\}

which forms a four-dimensional linear space. The paravector space in the three-dimensional Euclidean space

C\ell₃

can be used to represent the space-time of special relativity as expressed in the algebra of physical space (APS).

It is convenient to write the unit scalar as

1=e₀

, so thatthe complete basis can be written in a compact form as

\{e_\mu\},

where the Greek indices such as

\mu

run from

Antiautomorphism

Reversion conjugation

The Reversion antiautomorphism is denoted by

\dagger

. The action of this conjugation is to reverse the order of the geometric product (product between Clifford numbers in general).

(AB)^\dagger=B^\daggerA^\dagger

where vectors and real scalar numbers are invariant under reversion conjugation and are said to be real, for example:

a^\dagger=a

1^\dagger=1

On the other hand, the trivector and bivectors change sign under reversionconjugation and are said to be purely imaginary. The reversion conjugation applied to each basis element is givenbelow

Element	Reversion conjugation
1	1
e₁	e₁
e₂	e₂
e₃	e₃
e₁₂	-e₁₂
e₂₃	-e₂₃
e₃₁	-e₃₁
e₁₂₃	-e₁₂₃

Clifford conjugation

The Clifford Conjugation is denoted by a bar over the object

\bar{}

. This conjugation is also called bar conjugation.

Clifford conjugation is the combined action of grade involution and reversion.

The action of the Clifford conjugation on a paravector is to reverse the sign of thevectors, maintaining the sign of the real scalar numbers, for example

\bar{a

} = -\mathbf

\bar{1}=1

This is due to both scalars and vectors being invariant to reversion (it is impossible to reverse the order of one or no things) and scalars are of zero order and so are of even grade whilst vectors are of odd grade and so undergo a sign change under grade involution.

As antiautomorphism, the Clifford conjugation is distributed as

\overline{AB}=\overline{B}\overline{A}

The bar conjugation applied to each basis element is givenbelow

Element	Bar conjugation
1	1
e₁	-e₁
e₂	-e₂
e₃	-e₃
e₁₂	-e₁₂
e₂₃	-e₂₃
e₃₁	-e₃₁
e₁₂₃	e₁₂₃

Note.- The volume element is invariant under the bar conjugation.

Grade automorphism

The grade automorphism

\overline{AB}^\dagger=\overline{A}^\dagger\overline{B}^\dagger

is defined as the inversion of the sign of odd-grade multivectors, while maintaining the even-grade multivectors invariant:

Element	Grade involution
1	1
e₁	-e₁
e₂	-e₂
e₃	-e₃
e₁₂	e₁₂
e₂₃	e₂₃
e₃₁	e₃₁
e₁₂₃	-e₁₂₃

Invariant subspaces according to the conjugations

Four special subspaces can be defined in the

C\ell₃

spacebased on their symmetries under the reversion and Clifford conjugation

Scalar subspace: Invariant under Clifford conjugation.
Vector subspace: Reverses sign under Clifford conjugation.
Real subspace: Invariant under reversion conjugation.
Imaginary subspace: Reverses sign under reversion conjugation.

Given

as a general Clifford number, the complementary scalar and vector parts of

are given by symmetric and antisymmetric combinations with the Clifford conjugation

\langlep\rangle_S=

	1
	2

(p+\overline{p}),

\langlep\rangle_V=

	1
	2

(p-\overline{p})

In similar way, the complementary Real and Imaginary parts of

are givenby symmetric and antisymmetric combinations with the Reversion conjugation

\langlep\rangle_R=

	1
	2

(p+p^\dagger),

\langlep\rangle_I=

	1
	2

(p-p^\dagger)

It is possible to define four intersections, listed below

\langlep\rangle_RS=\langlep\rangle_SR\equiv\langle\langlep\rangle_R\rangle_S

\langlep\rangle_RV=\langlep\rangle_VR\equiv\langle\langlep\rangle_R\rangle_V

\langlep\rangle_IV=\langlep\rangle_VI\equiv\langle\langlep\rangle_I\rangle_V

\langlep\rangle_IS=\langlep\rangle_SI\equiv\langle\langlep\rangle_I\rangle_S

The following table summarizes the grades of the respective subspaces, where for example,the grade 0 can be seen as the intersection of the Real and Scalar subspaces

	Real	Imaginary
Scalar	0	3
Vector	1	2

Remark: The term "Imaginary" is used in the context of the

C\ell₃

algebra and does not imply the introduction of the standard complex numbers in any form.

Closed subspaces with respect to the product

There are two subspaces that are closed with respect to the product. They are the scalar space and the even space that are isomorphic with the well known algebras of complex numbers and quaternions.

The scalar space made of grades 0 and 3 is isomorphic with the standard algebra of complex numbers with the identification of

e₁₂₃=i.

The even space, made of elements of grades 0 and 2, is isomorphic with the algebra of quaternions with the identification of

-e₂₃=i

-e₃₁=j

-e₁₂=k.

Scalar product

Given two paravectors

and

, the generalization of the scalar product is

\langleu\bar{v}\rangle_S.

The magnitude square of a paravector

\langleu\bar{u}\rangle_S,

which is not a definite bilinear form and can be equal to zero even if the paravector is not equal to zero. It is very suggestive that the paravector space automatically obeys the metric of the Minkowski spacebecause

η_\mu\nu=\langlee_\mu\bar{e

}_\nu \rangle_S

and in particular:

η₀₀=\langlee₀\bar{e

}_0 \rangle = \langle 1 (1) \rangle_S = 1,

η₁₁=\langlee₁\bar{e

}_1 \rangle = \langle \mathbf_1 (-\mathbf_1) \rangle_S = - 1,

η₀₁=\langlee₀\bar{e

}_1 \rangle = \langle 1 (-\mathbf_1) \rangle_S = 0.

Biparavectors

Given two paravectors

and

, the biparavector B isdefined as:

B=\langleu\bar{v}\rangle_V

The biparavector basis can be written as

\{\langlee_\mu\bar{e

}_\nu \rangle_V \},

which contains six independent elements, including real and imaginary terms.Three real elements (vectors) as

\langlee₀\bar{e

}_k \rangle_V = -\mathbf_k,and three imaginary elements (bivectors) as

\langlee_j\bar{e

}_k \rangle_V = -\mathbf_where

j,k

run from 1 to 3.

In the Algebra of physical space,the electromagnetic field is expressed as a biparavector as

F=E+iB,

where both the electric and magnetic fields are real vectors

E^\dagger=E

B^\dagger=B

and

represents the pseudoscalar volume element.

Another example of biparavector is the representation of the space-time rotation rate that can be expressed as

W=i\theta^je_j+η^je_j,

with three ordinary rotation angle variables

\theta^j

and three rapidities

η^j

Triparavectors

Given three paravectors

and

, the triparavector T isdefined as:

T=\langleu\bar{v}w\rangle_I

The triparavector basis can be written as

\{\langlee_\mu\bar{e

}_\nu \mathbf_ \rangle_I \},

but there are only four independent triparavectors, so it can be reduced to

\{ie_\rho\}

Pseudoscalar

The pseudoscalar basis is

\{\langlee_\mu\bar{e

}_\nu \mathbf_ \bar_\rangle_ \},

but a calculation reveals that it contains only a single term. This term is the volume element

i=e₁e₂e₃

The four grades, taken in combination of pairs generate the paravector, biparavector and triparavector spaces as shown in the next table, where for example, we see that the paravector is made of grades 0 and 1

	1	3
0	Paravector	Scalar/Pseudoscalar
2	Biparavector	Triparavector

Paragradient

The paragradient operator is the generalization of the gradient operator in the paravector space. The paragradient in the standard paravector basis is

\partial=e₀\partial₀-e₁\partial₁-e₂\partial₂-e₃\partial_3,

which allows one to write the d'Alembert operator as

\square=\langle\bar{\partial}\partial\rangle_S=\langle\partial\bar{\partial}\rangle_S

The standard gradient operator can be defined naturally as

\nabla=e₁\partial₁+e₂\partial₂+e₃\partial_3,

so that the paragradient can be written as

\partial=\partial₀-\nabla,

where

e₀=1

The application of the paragradient operator must be done carefully, always respecting its non-commutative nature. For example, a widely used derivative is

\partial

	f(x)e₃
e

=(\partialf(x))

	f(x)e₃
e

e_3,

where

f(x)

is a scalar function of the coordinates.

The paragradient is an operator that always acts from the left if the function is a scalar function. However, if the function is not scalar, the paragradient can act from the right as well. For example, the following expression is expanded as

(L\partial)=e₀\partial₀L+(\partial₁L)e₁+ (\partial₂L)e₂+(\partial₃L)e₃

Null paravectors as projectors

Null paravectors are elements that are not necessarily zero but have magnitude identical to zero. For a null paravector

, this property necessarily implies the following identity

p\bar{p}=0.

In the context of Special Relativity they are also called lightlike paravectors.

Projectors are null paravectors of the form

P_k=

	1
	2

(1+\hat{k}),

where

\hat{k}

is a unit vector.

A projector

P_k

of this form has a complementary projector

\bar{P}_k

\bar{P}_k=

	1
	2

(1-\hat{k}),

such that

P_k+\bar{P}_k=1

As projectors, they are idempotent

P_k=P_kP_k=P_kP_kP_k=...

and the projection of one on the other is zero because they are null paravectors

P_k\bar{P}_k=0.

The associated unit vector of the projector can be extracted as

\hat{k

} = P_\mathbf - \bar_,

this means that

\hat{k

} is an operatorwith eigenfunctions

P_k

and

\bar{P}_k

, with respective eigenvalues

and

-1

From the previous result, the following identity is valid assuming that

f(\hat{k

}) is analytic around zero

f(\hat{k

}) = f(1) P_+f(-1) \bar_.

This gives origin to the pacwoman property, such that the following identities are satisfied

f(\hat{k

}) P_ = f(1) P_,

f(\hat{k

}) \bar_ = f(-1) \bar_.

Null basis for the paravector space

A basis of elements, each one of them null, can be constructed for the complete

C\ell₃

space. The basis of interest is the following

\{\bar{P}_3,P₃e_1,P_3,e₁P₃\}

so that an arbitrary paravector

p=p⁰e₀+p¹e₁+p²e₂+p³e₃

can be written as

p=(p^0+p

	3)P

	3

+(p⁰-

	3)\bar{P}
p
	3

+(p^1+ip

	2)e

	1

P₃+(p^1-ip

	2)P

	3

e₁

This representation is useful for some systems that are naturally expressed in terms of thelight cone variables that are the coefficients of

P₃

and

\bar{P}₃

respectively.

Every expression in the paravector space can be written in terms of the null basis. A paravector

is in general parametrized by two real scalars numbers

\{u,v\}

and a general scalar number

(including scalar and pseudoscalar numbers)

p=u\bar{P}₃+vP₃+we₁P₃+w^\daggerP₃e₁

the paragradient in the null basis is

\partial=2P₃\partial_u+2\bar{P}₃\partial_v-2e₁P₃

\partial
	w^\dagger

-2P₃e₁\partial_w

Higher dimensions

An n-dimensional Euclidean space allows the existence of multivectors of grade n (n-vectors). The dimension of the vector space is evidently equal to n and a simple combinatorial analysis shows that the dimension of the bivector space is

\begin{pmatrix}n\ 2\end{pmatrix}

. In general, the dimension of the multivector space of grade m is

\begin{pmatrix}n\ m\end{pmatrix}

and the dimension of the whole Clifford algebra

C\ell(n)

2ⁿ

A given multivector with homogeneous grade is either invariant or changes sign under the action of the reversion conjugation

\dagger

. The elements that remain invariant are defined as Hermitian and those that change sign are defined as anti-Hermitian. Grades can thus be classified as follows:

Grade	Classification
0	Hermitian
1	Hermitian
2	Anti-Hermitian
3	Anti-Hermitian
4	Hermitian
5	Hermitian
6	Anti-Hermitian
7	Anti-Hermitian
\vdots	\vdots

Matrix representation

The algebra of the

C\ell(3)

space is isomorphic to the Pauli matrix algebra such that

Matrix representation 3D

Explicit matrix

e₀


\sigma
	0

\begin{pmatrix} 1&&0\ 0&&1\end{pmatrix}

e₁


\sigma
	1

\begin{pmatrix} 0&&1\ 1&&0\end{pmatrix}

e₂


\sigma
	2

\begin{pmatrix} 0&&-i\ i&&0\end{pmatrix}

e₃


\sigma
	3

\begin{pmatrix} 1&&0\ 0&&-1\end{pmatrix}

from which the null basis elements become

{P_3}=\begin{pmatrix}1&0\ 0&0\end{pmatrix};\bar{P}₃=\begin{pmatrix}0&0\ 0&1\end{pmatrix};{P_3}e₁=\begin{pmatrix}0&1\ 0&0\end{pmatrix};e₁{P}₃= \begin{pmatrix}0&0\ 1&0\end{pmatrix}.

A general Clifford number in 3D can be written as

\Psi=\psi₁₁P₃-\psi₁₂P₃e₁+\psi₂₁e₁P₃+ \psi₂₂\bar{P}_3,

where the coefficients

\psi_jk

are scalar elements (including pseudoscalars). The indexes were chosen such that the representation of this Clifford number in terms of the Pauli matrices is

\Psi → \begin{pmatrix} \psi₁₁&\psi₁₂\ \psi₂₁&\psi₂₂\end{pmatrix}

Conjugations

The reversion conjugation is translated into the Hermitian conjugation and the bar conjugation is translated into the following matrix:

\bar{\Psi} → \begin{pmatrix} \psi₂₂&-\psi₁₂\ -\psi₂₁&\psi₁₁\end{pmatrix},

such that the scalar part is translated as

\langle\Psi\rangle_S →

	\psi₁₁+\psi₂₂
	2

\begin{pmatrix} 1&0\ 0&1 \end{pmatrix}=

	Tr[\psi]
	2

1_{2 x}

The rest of the subspaces are translated as

\langle\Psi\rangle_V → \begin{pmatrix} 0&\psi₁₂\ \psi₂₁&0 \end{pmatrix}

\langle\Psi\rangle_R →

	1
	2

\begin{pmatrix} \psi₁₁

	*
+\psi
	11

&\psi₁₂

	*
+\psi
	21

\ \psi₂₁

	*
+\psi
	12

&\psi₂₂

	*
+\psi
	22

\end{pmatrix}

\langle\Psi\rangle_I →

	1
	2

\begin{pmatrix} \psi₁₁

	*
-\psi
	11

&\psi₁₂

	*
-\psi
	21

\ \psi₂₁

	*
-\psi
	12

&\psi₂₂

	*
-\psi
	22

\end{pmatrix}

Higher dimensions

The matrix representation of a Euclidean space in higher dimensions can be constructed in terms of the Kronecker product of the Pauli matrices, resulting in complex matrices of dimension

2ⁿ

. The 4D representation could be taken as

	Matrix representation 4D
e₁	\sigma₃ ⊗ \sigma₁
e₂	\sigma₃ ⊗ \sigma₂
e₃	\sigma₃ ⊗ \sigma₃
e₄	\sigma₂ ⊗ \sigma₀

The 7D representation could be taken as

	Matrix representation 7D
e₁	\sigma₀ ⊗ \sigma₃ ⊗ \sigma₁
e₂	\sigma₀ ⊗ \sigma₃ ⊗ \sigma₂
e₃	\sigma₀ ⊗ \sigma₃ ⊗ \sigma₃
e₄	\sigma₀ ⊗ \sigma₂ ⊗ \sigma₀
e₅	\sigma₃ ⊗ \sigma₁ ⊗ \sigma₀
e₆	\sigma₁ ⊗ \sigma₁ ⊗ \sigma₀
e₇	\sigma₂ ⊗ \sigma₁ ⊗ \sigma₀

Lie algebras

Clifford algebras can be used to represent any classical Lie algebra.In general it is possible to identify Lie algebras of compact groups by using anti-Hermitian elements, which can be extended to non-compact groups by adding Hermitian elements.

The bivectors of an n-dimensional Euclidean space are Hermitian elements and can be used to represent the

spin(n)

Lie algebra.

The bivectors of the three-dimensional Euclidean space form the

spin(3)

Lie algebra, which is isomorphicto the

su(2)

Lie algebra. This accidental isomorphism allows to picture a geometric interpretation of thestates of the two dimensional Hilbert space by using the Bloch sphere. One of those systems is the spin 1/2 particle.

The

spin(3)

Lie algebra can be extended by adding the three unitary vectors to form a Lie algebra isomorphicto the

SL(2,C)

Lie algebra, which is the double cover of the Lorentz group

SO(3,1)

. This isomorphism allows the possibility to develop a formalism of special relativity based on

SL(2,C)

, which is carried outin the form of the algebra of physical space.

There is only one additional accidental isomorphism between a spin Lie algebra and a

su(N)

Lie algebra. This is the isomorphism between

spin(6)

and

su(4)

Another interesting isomorphism exists between

spin(5)

and

sp(4)

. So, the

sp(4)

Lie algebra can be used to generate the

USp(4)

group. Despite that this group is smaller than the

SU(4)

group, it is seen to be enough to span the four-dimensional Hilbert space.

References

Textbooks

Baylis, William (2002). Electrodynamics: A Modern Geometric Approach (2nd ed.). Birkhäuser.
Baylis, William, Clifford (Geometric) Algebras With Applications in Physics, Mathematics, and Engineering, Birkhauser (1999)
[H1999] David Hestenes: New Foundations for Classical Mechanics (Second Edition)., Kluwer Academic Publishers (1999)
Chris Doran and Antony Lasenby, Geometric Algebra for Physicists, Cambridge, 2003

Articles

Baylis . W E . Relativity in introductory physics . Canadian Journal of Physics . Canadian Science Publishing . 82 . 11 . 2004-11-01 . 0008-4204 . 10.1139/p04-058 . 853–873. physics/0406158. 2004CaJPh..82..853B . 35027499 .
Doran . C. . Hestenes . D. . Sommen . F. . Van Acker . N. . Lie groups as spin groups . Journal of Mathematical Physics . AIP Publishing . 34 . 8 . 1993 . 0022-2488 . 10.1063/1.530050 . 3642–3669. 1993JMP....34.3642D .
Cabrera . R. . Rangan . C. . Baylis . W. E. . Sufficient condition for the coherent control of n-qubit systems . Physical Review A . American Physical Society (APS) . 76 . 3 . 2007-09-04 . 1050-2947 . 10.1103/physreva.76.033401 . 033401. quant-ph/0703220. 2007PhRvA..76c3401C . 45060566 .
Vaz . Jayme . Mann . Stephen . Paravectors and the Geometry of 3D Euclidean Space . Advances in Applied Clifford Algebras . Springer Science and Business Media LLC . 28 . 5 . 2018 . 0188-7009 . 10.1007/s00006-018-0916-1 . 99. 1810.09389. 253600966 .

Paravector Explained

Fundamental axiom

The three-dimensional Euclidean space

Paravectors

Antiautomorphism

Reversion conjugation

Clifford conjugation

Grade automorphism

Invariant subspaces according to the conjugations

Closed subspaces with respect to the product

Scalar product

Biparavectors

Triparavectors

Pseudoscalar

Paragradient

Null paravectors as projectors

Null basis for the paravector space

Higher dimensions

Matrix representation

Conjugations

Higher dimensions

Lie algebras

See also

References

Textbooks

Articles