The Orientation Congruent Algebra and the Native Exterior Calculus of Twisted Differential Forms

Introduction

This webpage by Diane G. Demers explains the orientation congruent algebra and the native exterior calculus of twisted differential forms, provides my draft papers on these concepts, and links some related webpages.

The orientation congruent algebra (or OC algebra for short) is a nonassociative, Clifford-like algebra that is essential to the computation of the exterior and Clifford products of twisted multivectors in their natural, or native representation. The native exterior calculus is the exterior calculus of twisted differential forms in their native representation.

Here we use the generic term geometric object, or simply object, to refer to both the twisted and untwisted varieties of multivectors, multicovectors, multivector fields, and differential forms, even though this usage may differ from that of differential geometry. Following de Rham, twisted objects are also commonly described as impair (French) or odd (English); while ordinary, untwisted (straight) objects are also commonly described as pair (French) or even (English). Polar and axial vectors, as well as ordinary tensors and tensor densities, are related concepts which we will also discuss. To quickly get an intuitive feeling for twisted differential forms see Rob Salgado's richly illustrated conference poster "Visualizing Tensors."

Just as Cartan's exterior calculus is based on Grassmann's exterior algerbra, the native exterior calculus is based on the native exterior algebra which, in turn, is based on the orientation congruent algebra. The native exterior calculus was developed to generalize Cartan's exterior calculus and treat twisted differential forms in their native representation.

Controversies

Controversies Are Resolved in This Framework

This framework of the native represetation of twisted objects using the orientation congruent algebra applies to manifolds of any finite dimension n. It ends the confusing manual sign choices required by, other, previously known approaches. We will see that, by clearing up the many misunderstandings engendered by the usual techniques, this natural and general formulation for twisted geometric objects powerfully resolves many smoldering controversies that repeatedly appear in the mathematics and physics literature.

The latest example of such a controversy is provided by the following series of papers (the last two of which cite this website and my works):

• Roldão da Rocha and Waldyr Alves Rodrigues, Jr., "Pair and impair, even and odd form fields and electromagnetism;" vs.
• Yakov Itin, Yuri N. Obukhov, and Friedrich W. Hehl, "An electric charge has no screw sense—a comment on the twistfree formulation of electrodynamics by da Rocha & Rodrigues;" vs.
• Roldão da Rocha and Waldyr Alves Rodrigues, Jr., "Reply to Itin, Obukhov and Hehl paper ‘An electric charge has no screw sense - a comment on the twist-free formulation of electrodynamics by da Rocha & Rodrigues’."

My paper, titled "Reply to da Rocha & Rodrigues' Comments on the Orientation Congruent Algebra & Twisted Forms in Electrodynamics," has been submitted to Annalen der Physik (Berlin). It refutes those authors' inaccurate statement in the third paper listed above that the orientation congruent algebra, and by implication the native Clifford algebra, because of their nonassociativity, are incompatible with their Clifford bundle approach. Quite the contrary, the usual Clifford algebra and bundle that is these authors expertise is subsumed by the new native Clifford algebra and bundle and leads to a new physical principle of "nonassociative irrelevance" for judging whether an equation is physically meaningful. In addition, I argue that the adoption of formalisms that respect the native representation of twisted (or odd) physical quantities is required for the advancement of mathematics, physics, and engineering because they allow equations to be written in sign-invariant form and resolve controversies that continue to occur in the literature—such as the papers listed above.

Download paper submitted to Annalen der Physik (Berlin):  Reply to da Rocha & Rodrigues' Comments on the Orientation Congruent Algebra & Twisted Forms in Electrodynamics
  Typos corrected version, January 7, 2010:  Adobe Acrobat PDF file (175,888 bytes), AdPreply_100107.pdf

Unoriented and Twisted Space vs. Oriented Vectors

These controversies about twisted physical quantities, although sometimes couched in powerful abstract formalisms, are all rooted in the simple, prototypical clash of two sets of concepts:  unoriented and twisted space vs. oriented vectors. Our first natural conception of space is, both in physics as well as everyday life and commerce, unoriented.

For example, one would not, I think, approach an appliance salesperson and ask to see some refrigerators having a capacity of "546 liters with a right-hand screw sense," rather than simply "546 liters." (This raises the tangential question of whether perhaps some day extremely precise measurements may reveal that the volume of a stationary or moving cube determined by measurements taken in the order of, say, height, width, and then depth is different from its volume determined by measurements taken in a different order.)

However, it is meaningful to assign a positive or negative sign to capacity so that gains and losses in volume may be accounted; therefore space may be also be naturally considered as being oriented as an odd or twisted trivector (also called a three-vector or 3-vector). On the other hand, vectors and their higher grade analogs, such as bivectors and trivectors, are all patently oriented (in the common sense). They are thus examples of what we call even or straight vectors, bivectors, and trivectors.

The Native Representation of Geometric Objects:  The Architecture of Orientation

The Geometric Sign of a Geometric (Clifford) Number

The axioms for geometric (Clifford) algebra that Hestenes and Sobczyk give in their book Clifford Algebra to Geometric Calculus were apparently constructed to be directly analogous to those for the real numbers (perhaps, in part, to entice physicists into studying them). We may also recall that there is a long tradition of calling the elements of Clifford algebras Clifford numbers. (Similarly, we have the terms complex numbers, double numbers, and, generally, hypercomplex numbers.)

The next step is to extend the current conception of geometric (Clifford) numbers by considering how sign fits into this analogy. That is, we have in the geometric (Clifford) numbers a geometric generalization of the real numbers, but only the most primitive generalization of signed real numbers: namely, that in which the geometric sign has the same attitude as (this phrase is explained shortly below, but for now it may be roughly read as is parallel with) the geometric absolute value or magnitude (which we call the gauge.)

By entertaining the further possibility that the geometric sign of a geometric number may be transverse (in a nonmetric setting) or orthogonally complementary (in a metric setting) to its geometric magnitude we obtain the twisted multivectors. These twisted geometric numbers have both mathematical and physical implications. And this new theory of the native represetation of twisted geometric objects provides an adequate foundation for the investigation of those implications.

The Two-Part Decomposition of Geometric Objects

In their native representation twisted geometric objects are directly decomposable into a generalized, geometric sign, or g-sign for short, and a generalized, geometric measure or content, that we call the gauge. The same two-part decomposition also applies to ordinary (or straight) geometric objects. However, a first explanation of these concepts is more easily given in terms of straight objects.

In the native representation the g-sign represents a geometric object's orientation only; it is devoid of any measure or content. For example, the g-sign of a vector may be pictured as a ray parallel to it and pointing in the same direction. This ray represents an oriented subspace of the enveloping vector space; it may also be regarded as "living" in the associated oriented projective space where it represents an oriented point. On the other hand, in the native representation the gauge of an object represents its measure, content, weight, or magnitude combined with its attitude. The attitude of an object, in turn, represents the unoriented line, plane, or higher-dimensional subspace in which it lies. For our vector example, the gauge may be pictured as an unoriented line segment parallel to it.

Two other representations will also be needed below. The definitions of g-sign and gauge given above for the native representation are different for them; however it is convenient to use the two terms g-sign and gauge in a generic sense to apply to all three representations.

The native representation (and the two others to be introduced shortly) of a geometric object can also be given a precise symbolic expression as an equivalence class of ordered pairs determined by calculations in the orientation congruent algebra (and its associated Grassmann or exterior algebra). Although there is only one truly native representation of odd objects, in pratice two types of expressions are required to carry out calculations:  the native and the correlated. This is analogous to the representation of complex numbers in both polar and rectangular forms with the polar form most suited to the multiplication of complex numbers and the rectangular form to addition. In our case, it is the native form that is used to multiply both even and odd objects, while the correlated form is used to add and differentiate them. The correlated form is so named because its two components' grades are correlated:  either directly so that they are equal, or inversely so that they sum to n, the dimension of the manifold or space. However, the native form also shares this property. The native and correlated forms are then distinguished by certain fundamental sign rules given below.

Finally, to connect with the usual differential geometry notation for odd differential forms we need one more representation, the extremum. The extremum form is so named because its first component's grade is always either the smallest possible grade grade 0, or the largest possible grade n. That is, the first component of the extremum form is always an arbitrary non-zero scalar multiple of either 1 or Ω_±. For an explanation of the meaning and significance of the symbols Ω_± and Ω₊ used here and below in this section, please see the section on the two types of OC algebras.

The symbols for these three representations consist of ordered pairs that are written within doubled brackets. They are given in the following table along with some odd and even examples of each type for a manifold or space of dimension 3. The first component of all three brackets in this table is the g-sign, written generically as s; the second component is the gauge, written generically as g.

The symbolic correlated and extremum representations of geometric objects were originally presented on this webpage in a text file that I continue to include here for historical purposes:  NatRep.txt. As is evident, the terminology and square bracket notation used in this file has been changed to that used above in the current version of this webpage and also in the draft paper on the native exterior calculus.

As suggested by the above notation, these three forms will henceforth generally be called the native, correlated, and extremum brackets. They are further distinguished by the fundamental sign rules given in the following table. These fundamental sign rules are divided into two types:  migratory and unbinding. Note that there is no unbinding sign rule for the correlated bracket since it is bound (at least temporarily during any one calculation) to some particular sign-wise, but not magnitude-wise, fixed value of an arbitrary positive scalar multiple of 1 (for even objects) or an arbitrary non-zero scalar multiple of Ω_± (for odd objects) that is equal to s_c @ g_c, where the at sign @ symbolizes the orientation congruent product.

To Be Developed Further

The Native Exterior Algebra

To Be Added

The Native Clifford Algebra

To Be Added

The Native Exterior Calculus

I am currently writing a paper on the native exterior calculus of twisted differential forms. As mentioned above in the introduction to this webpage, the orientation congruent algebra is integral to developing the native exterior calculus. This paper, "Exterior Calculus in the Image of Odd Forms with the Orientation Congruent Algebra," will treat two problems in electrodynamics as examples.

An abstract of this draft paper:  ExtCalc.pdf.

The Orientation Congruent Algebra

The Initial Motivating Application

This section also needs more work. For the moment, we simply state that the author's initial motivating application of the orientation congruent algebra was to directly calculate the exterior product of straight and twisted multivectors in their native representation. This required the development of the native exterior algebra which, in turn, is the algebraic basis of the native exterior calculus.

Some Properties of the OC Algebra

Properties of the OC algebra include the following:

1. It is a noncommutative Jordan algebra.
2. It is a structurally-hyperbolic Clifford algebra.
3. It provides natural expressions for the Hodge star dual operator and its inverse.
4. And, as suggested by the section on Macfarlane's hyperbolic quaternions, the orientation congruent algebra also provides a natural expression for the Lorentz boost in the four-dimensional spacetime of special relativity; more about this will be added later.

The Two Types of OC Algebras:  Perfect and Imperfect

The orientation congruent algebras naturally divide into two classes depending on the commutation properties of the unit-magnitude, maximum-grade multivector. This division is exactly mirrored by the parity of the underlying vector space of grade 1 multivectors, or base space. The unit-magnitude, maximum-grade multivector of an OC algebra with an odd-dimensional base space commutes with all other multivectors just as the identity or unit element 1 does. On the other hand, the unit-magnitude, maximum-grade multivector of an OC algebra with an even-dimensional base space does not possess this propery.

In both types of orientation congruent algebras the unit-magnitude, maximum-grade multivector has a grade which is complementary to that of the unit element since n + 0 = n. And so we call it a counit. For OC algebras with an odd-dimensional base space we call it a perfect counit, while for OC algebras with an even-dimensional base space we call it an imperfect counit. An orientation congruent algebra with a perfect (resp., imperfect) counit is called a perfect (resp., imperfect) OC algebra.

These facts are reflected by the multiplication tables presented in the section below:  The most symmetrical multiplication tables are those for which the OC algebras have odd-dimensional base spaces and perfect counits.

In these tables the perfect counit for those orientation congruent algebras with an odd-dimensional base space is represented by the symbol bold capital Omega Ω (similar to differential geometry's usage). Thus the bold capital Omega in the table for OC₃ is equal to e₁₂₃ while that in the table for OC₅ is equal to e₁₂₃₄₅. On the other hand, the imperfect counit for those orientation congruent algebras with an even-dimensional base space is represented by the symbol upside-down bold capital Omega ℧ (\mho in AMS LaTeX). Thus the inverted bold Omega in the table for OC₄ is equal to e₁₂₃₄. An inverted bold Omega is used to alert the reader that, as explained just above, the counit in OC algebras with an even-dimensional base space, unlike the odd-dimensional case, is imperfect, and so does not generally commute with other multivectors under OC multiplication.

In contrast to these tables (for which the niceties of LaTeX typography are available) in the text of this webpage (and perhaps also on the blackboard) we modify the above conventions for counit symbols. Thus we also use the symbol bold capital Omega with a plus sign subscript Ω₊ for the perfect counit of an orientation congruent algebra with an odd-dimensional base space but a not necessarily specified dimension or signature. On the other hand, we use the symbol bold capital Omega with a negative sign subscript Ω₋ for the imperfect counit of an orientation congruent algebra with an even-dimensional base space but a not necessarily specified dimension or signature.

Here we also introduce the term indefinite counit for the counit of an OC algebra with both a not necessarily specified base space parity and a not necessarily specified signature. In LaTeX documents we indicate an indefinite counit with a symbol that is a stylized version a superimposed noninverted and inverted bold Omega. However, in the text of this webpage we indicate an indefinite counit with the symbol bold capital Omega with a "plus or minus sign" subscript Ω_±.

The Multiplication Tables for Three Important OC Algebras

The most direct understanding of an algebra is obtained by studying its multiplication table. By multiplication table we mean, more formally, the partial Cayley table of the group induced by an associative algebra, or the partial Latin square of the quasigroup induced by a nonassociative algebra. These tables are partial in that they contain only products whose factors have a positive sign in some standard representation.

We next present the multiplication tables of three OC algebras that are particularly important in our exposition. Note that in the multiplication tables (displayed or downloadable below) for the orientation congruent algebras OC₃ and OC₅, but not OC₄, the products which have a sign which is opposite to that of the corresponding Clifford algebra products have been underlined. Also note that some symmetries of these tables have been made more visible by tinting red the cells which contain negative entries.

The multiplication table for the orientation congruent algebra OC₃ (or OC_3,0) displayed as a PNG graphic:

The multiplication table for the orientation congruent algebra OC₄ (or OC_4,0) downloadable as an Adobe Acrobat PDF file (22,652 bytes), January 3, 2010:  OC40MultTab1-2.pdf

The multiplication table for the orientation congruent algebra OC₅ (or OC_5,0) downloadable as an Adobe Acrobat PDF file (49,525 bytes), June 23, 2005:  OC50MultTab1-3.pdf

A Noncommutative Jordan Algebra

The orientation congruent algebra is a member of the large class of algebras known as noncommutative Jordan algebras. I have proved this by a brute force case-by-case examination using Wolfram Research's Mathematica software. Although the code executes in a reasonable time, it would be good to have an analytical proof. The Mathematica code and its explanation are available upon request.

The Naturalness of the OC Algebra Expression for the Hodge Star Operator

An intriguing aspect of the OC algebra:  In contrast to the Clifford algebra it provides a simple and natural expression for the Hodge star dual operator * and its inverse *⁻¹. Although I have not yet written up my notes for a proof of this fact, the formulas for the Hodge star dual operator and its inverse are

* u = (Ω_±)⁻¹ @ u, and
*⁻¹ u = u @ Ω_±.

Here we have used the symbol convention laid down in the above section on the two types of OC algebras to represent the volume form by a bold capital Omega with a plus or minus sign subscript Ω_±. Differentiating between perfect and imperfect couints by using a bold capital Omega with a plus sign subscript and one with a negative sign subscript, Ω₊ and Ω₋, respectively, is not necessary in these formulas since they are generally valid for both odd- and even-dimensional manifolds (and both Riemannian and pseudo-​Riemannian metrics). Note, however, that for pseudo-​Riemannian metrics the definition of the Hodge star and its inverse may need to be interchanged depending on which of the two possible conventions is observed.

This property of naturally expressing the Hodge star operator and its inverse is illustrated in the multiplication tables for the orientation congruent algebras OC₃, OC₄, and OC₅.

Now the Hodge star operator was actually pioneered by Hermann Grassmann as his Ergänzung or complement operator. Grassmann's contribution is acknowledged in the following two quotes from John Browne's Grassmann Algebra book.

On page 750 of the Grassmann Algebra book is the citation:

Hodge W V D 1952
Theory and Applications of Harmonic Integrals
Cambridge
The "star" operator defined by Hodge is of similar nature to Grassmann's complement operator.

And on page 341 Browne makes this allusion:

In more modern works the Ergänzung for general metrics has become known as the Hodge Star operator. But we do not use the term here since our aim is to develop the concept by showing how it can be built straightforwardly on the foundations laid by Grassmann.

Along this line we also provide this quotation from page 7, section 6, "Grassmann-Hodge stars (Kocik 1979)," of the paper "Isometry from reflections versus isometry from bivector" by Zbigniew Oziewicz (2009, Online First, Adv. Appl. Clifford Alg.):

The concept of a ‘Hodge-star’ was introduced by Hermann Grassmann in his second monograph in 1862, under the name ‘Ergänzung’ (supplement) [Grassmann 1862, § 3.4 ]. The present-day star-notation, *, was introduced by Hermann Weyl in 1945.

Based on this precedence I suppose then that one could call the orientation congruent algebra the Clifford-Grassmann algebra (or CG algebra for short). But that is perhaps too confusing given current terminology. The possibility is also raised that the full orientation congruent algebra is also cryptically or, at least, implicitly contained in Grassmann's work.

The OC Algebra Generalizes Macfarlane's Hyperbolic Quaternions

The OC₂ algebra is isomorphic to the hyperbolic quaternions of Alexander Macfarlane. Macfarlane published a paper "Hyperbolic Quaternions" (1989-1900, Proc. Royal Society of Edinburgh 23:169-181) on his discovery of "a system of quaternions complementary to that of Hamilton, which is capable of expressing trigonometry on the surface of the equilateral hyperboloids."

According to this brief biographical essay on Macfarlane, Emil Borel later observed that the 3D hyperboloid model of hyperbolic space describes the kinematic velocity space of special relativity. Also see the webpage "Alexander Macfarlane and the Ring of Hyperbolic Quaternions" and the Wikipedia webpage "Hyperbolic quaternion."

The series of orientation congruent algebras OC_n starting with n = 1 and increasing are isomorphic to the the double or split-complex numbers for n = 1, the hyperbolic quaternions for n = 2, and their generalizations to higher dimensions for n > 2. These generalizations are part of the sequence of structurally-hyperbolic Cayley-Dickson algebras that are dual in a natural sense to the usual Cayley-Dickson algebras, which may then be called structurally-elliptic. See the section on the structurally-hyperbolic algebras.

Paper:  "The Orientation Congruent Algebra:  A Nonassociative Clifford-Like Algebra"

Version 1.3

Title:  The Orientation Congruent Algebra:  A Nonassociative Clifford-Like Algebra
Abstract.  The correlated grade form of twisted blades (twisted simple multivectors) faithfully renders in symbols their native geometric structure. The discovery of this paper's nonassociative Clifford-like algebra was driven by trying to calculate exterior products of straight and twisted multivectors directly in a basis of this form. The key was found to be the orientation congruent (OC) algebra. This paper is being published electronically in about ten sections, each offered as soon as written. In this first section we axiomatize the orientation congruent algebra by generators and relations. The next section derives the sign factor function sigma and proves that the Clifford product times it is the multiplication of an explicitly Clifford-like algebra isomorphic to the orientation congruent algebra. Later sections are planned to show how to calculate the OC product in Mathematica and Clical; to define the orientation congruent contraction operators, deduce their properties, derive other expressions for them, and use them to compute the OC product within the exterior algebra using a modified Cartan decomposition formula; to develop the algebra's product sequence graph with labeled edges; to derive a predictor of a null associator as a function of the grades of the three elements in it; to prove the associomediative property of the algebra's counit; to develop matrix representations (under a nonassociative matrix product) of the orientation congruent product; and to discuss the motivating application per se and as inspiration for the first set of axioms.

This paper is available for downloading or reading online. It will be split by section into separate PDF files. Each file will be offered as soon as it is written. As the paper approaches completion the finished sections may be combined into one file. Revisions may occur so be sure to get the latest versions of each section.

Section 1:  An Axiom System for the OC Algebra
  Version 1.3, June 27, 2005:  Adobe Acrobat PDF file (295,623 bytes), OriCon013ch01.pdf

Note:  Contrary to the above plan, this paper will not be posted section-by-section and may possibly not be developed further beyond version 1.5 below. But some essential material from this paper will incorporated into the newer paper on the native exterior calculus

Version 1.5

Title:  The Orientation Congruent Algebra
            Part I:  A Nonassociative Clifford-Like Algebra
Abstract.  Similar to Version 1.3.
Table of Contents

1. Introduction
2. An Axiom System for the Orientation Congruent Algebra
3. The Clifford-Likeness of the Orientation Congruent Algebra
4. Computer Software Implemetations of the Orientation Congruent Algebra
5. The Clifford and Orientation Congruent Contraction Operators:  To Be Developed Further
6. Some Algebras, Graphs, and Theory:  To Be Developed Further
7. Multiplication Tables: Symmetries, Matrices, and Functions:  To Be Developed Further
8. Specifc Associativity and Associomediativity:  To Be Developed Further
9. Matrix Representations of the Orientation Congruent Algebra:  To Be Developed Further

Complete paper:  The Orientation Congruent Algebra:  A Nonassociative Clifford-Like Algebra
  Version 1.5, December 4, 2005:  Adobe Acrobat PDF file (865,403 bytes), OriCon015ch01-09.pdf

Note:  There are few errors in this draft; but none of them is fatal to the thrust of this research. An errata sheet or a revised draft paper will eventually be posted here.

Latest Developments

December 9, 2009

December 10, 2009:  small changes in wording and formatting

This section added rather hastily on December 9, 2009 puts the cart before the horse since the fundamental sections on the native Clifford and native exterior algebras are currently empty. However, my research has picked up dramatically in the last 2-3 months. And although at present this work resides only in my notes and memory, I will here describe some more recent investigations.

I now know how to use the orientation congruent algebra in even-dimensional spaces—which has been a problem since the beginning many years ago. It requires in part using a "nonmetric" approach.

I put quotation marks around the word nonmetric above because in this approach we apply a peculiar kind of Clifford algebra (or, actually, its related orientation congruent algebra) which may be called variously a nonmetric Clifford algebra, or a formally metric Clifford algebra or, using perhaps the best choice of words, a Clifford algebra of multivecfors (please note, not multivectors) following the terminology of the paper by W. A. Rodrigues, Jr. and Q. A. G. de Souza at http://arxiv.org/abs/math-ph/0703053.

This type of Clifford algebra has also been developed for manifolds using a bundle-theoretic approach by M. P. Burlakov in the very last section of his paper "Clifford structures on manifolds." The original Russian version is at http://mi.mathnet.ru/eng/into27 and an English translation is at http://dx.doi.org/10.1007/BF02414874.

Reviews are at http://www.ams.org/mathscinet-getitem?mr=1619716 and http://www.zentralblatt-math.org/zmath/en/search/?q=an:0930.53030&format=complete.

In addition, a further interesting complication is that while odd-dimensional spaces require the orientation congruent algebra derived from the (rather more standard) orthogonal version of the Clifford algebra of multivecfors (that is, with the split-Euclidean metric of signature (n, n), for an n-dimensional space), on the other hand, the even-dimensional spaces require a Clifford algebra of an arbitrary, nonsymmetric bilinear form in the terminology of Bertfried Fauser and Rafal Ablamowicz in http://arxiv.org/abs/math.QA/9911180

This is also known as a quantum Clifford algebra to use the terminology of Bertfried Fauser in http://arxiv.org/abs/math.QA/0202059

See also Rafal Ablamowicz and Pertti Lounesto's book chapter "On Clifford algebras of a bilinear form with an antisymmetric part" at http://books.google.com/books?id=OpbY_abijtwC&pg=PA167

I have seen the need to use this generalized type of Clifford algebra several times over the years. However, that was still within a metrical context. And then the bilinear form involved was truly a generally nonsymmetric bilinear form, that is, neither purely symmetric nor antisymmetric. However, the situation is much simplified by using the nonmetric Clifford algebra of multivecfors which combines the space of multivectors with the dual space of multicovectors into one space.

Then the nonsymmetric bilinear form involved is not so arbitrary, but is properly the symplectic bilinear form associated with a symplectic vector space. For an n-dimensional physical space this symplectic vector space requires a 2n-dimensional (Wick) basis of vectors and covectors. Then, for example, the matrix representation of the symplectic bilinear form for a 2-dimensional physical space may be written in the standard form

[ 0 1 0 0]
[-1 0 0 0]
[ 0 0 0 1]
[0 0 -1 0].

Then it is the case that for an even-dimensional physical space (e.g., 4-dimensional spacetime), the final algebra that is used is the orientation congruent analog of the Clifford algebra of multivecfors, which, in turn, is the analog of the Clifford algebra of a symplectic bilinear form.

Also, apparently, the Clifford algebra of multivecfors can be nicely explained in the abstract language of mathematical category theory and it appears to be based on the biproduct of a module. See the books reviewed at http://www.ams.org/mathscinet-getitem?mr=941522 and http://www.ams.org/mathscinet-getitem?mr=1712872.

I could go further here and tie the notion of a correlation in projective geometry into this phenomenon that odd- and even-dimensional spaces, respectively, must be treated by algebras associated with bilinear forms that are either split-Euclidean or canonically symplectic, respectively. However, I will only add that these new concepts create a naturally nonmetrical setting for projective geometry. They then provide a true nonmetrical foundation for projective geometry which the cobasis used by John Browne in his Grassmann Algebra book does not.

I also think that implied in this new work may be a foundation for Hestenes and Sobczyk's geometric calculus of multivectors. But that is a long-term project. I am now busy writing up this new material and integrating it with my earlier results.

The Structurally-Hyperbolic Algebras

As mentioned in the above section on the properties of the OC algebra, the orientation congruent algebra may be viewed as a structurally-hyperbolic Clifford algebra, a generalization of the usual Clifford algebra. That is because the foundation of the orientation congruent algebra lies within the new algebraic theory of structurally-elliptic and structurally-hyperbolic algebras.

In this framework, the usual Clifford algebra, which we call structurally-elliptic, is the dual of the orientation congruent algebra, which we call structurally-hyperbolic. This terminology has its origin in the fact that the Clifford algebras are naturally suited to represent elliptic (ordinary) rotations in the prototypical spaces with Euclidean signature (n, 0) while the orientation congruent algebras are naturally suited to represent hyperbolic rotations (boosts) in the prototypical spaces with Lorentzian signature (n-1, 1). More about this will be added later.

This Clifford algebra dualization leads naturally to the dualization of the structurally-elliptic Cayley-Dickson algebras (i.e., the usual Cayley-Dickson algebras) to the structurally-hyperbolic Cayley-Dickson algebras. These new algebras are partly illustrated in the section on Macfarlane's hyperbolic quaternions (which we may more systematically call the structurally-hyperbolic quaternions).

The loops (quasigroups with identity) induced by the structurally-hyperbolic Cayley-Dickson algebras are characterized by some interesting new identities. In particular, it turns out that the structurally-hyperbolic octonions are neither Bol nor Moufang loops, but a kind of hybrid of the two. More details on this will be forthcoming as time permits.

"Structurally-Hyperbolic Algebras Dual to the Cayley-Dickson and Clifford Algebras or Nested Snakes Bite Their Tails" is the title of a draft paper on this theory. The unusual subtitle is an allusion to an exclamation written into an early paper by the knot theorist Louis H. Kauffman. A particular formula in that early paper of Kauffman inspired a more general formula for the product of the structurally-hyperbolic Cayley-Dickson algebras. In fact, this draft paper mostly establishes basic terminology and the fundamental formulas relating the two kinds of Cayley-Dickson algebra products—structurally-elliptic and structurally-hyperbolic.

An abstract of this draft paper:  Nested_080715_abs.pdf.
The latest draft of this paper from July 15, 2008:  Nested_080715.pdf.

Twisted Differential Forms Links

1. "Alain Bossavit at TUT":  Contains many works on the theory and practice of engineering electromagnetism using twisted differential forms and differential geometry, some very mathematical.
2. William L. Burke (deceased):  "Bill Burke's Home Page." Contains several innovative tutorial papers on twisted differential forms, as well as some Mathematica code for forms. Among his many other works Burke treats electromagnetism using twisted differential forms in the paper "Manifestly parity invariant electromagnetic theory and twisted tensors," J. Math. Phys. 24(1): 65-69 (Jan. 1983). In his book, Applied Differential Geometry, Cambridge University Press, Cambridge, 1985, Burke uses twisted differential forms very naturally while applying differential geometry to physics (including electrodynamics).
3. Roldão da Rocha and Waldyr A. Rodrigues, Jr.:  "Pair and impair, even and odd form fields and electromagnetism," preprint arXiv:0811.1713v6 [math-ph], journal Annalen der Physik, DOI:  10.1002/andp.200910374. This paper has been the subject of criticism by Friedrich W. Hehl and colleagues; see the next item. The authors da Rocha and Rodrigues have rejoined with the preprint "Reply to Itin, Obukhov and Hehl paper ‘An electric charge has no screw sense - a comment on the twist-free formulation of electrodynamics by da Rocha & Rodrigues’," arXiv:0912.2127v1 [math-ph].
4. "Prof. Dr. Friedrich W. Hehl (i.R.)":  Contains a free sample of his book coauthored with Yuri N. Obukhov, Foundations of Classical Electrodynamics:  Charge, Flux, and Metric, Birkhauser, Boston, 2003. The use of twisted differential forms is essential to the thesis of this book which builds up to a sophisticated differential geometric and general relativistic treatment and includes Reduce code for symbolic computation. The paper by Yakov Itin, Yuri N. Obukhov, and Friedrich W. Hehl, "An electric charge has no screw sense—a comment on the twistfree formulation of electrodynamics by da Rocha & Rodrigues," preprint arXiv:0911.5175v1 [physics.class-ph], journal Annalen der Physik, DOI:  10.1002/andp.200910408, criticises one of the papers linked in the previous item.
5. Robert M. Kiehn:  "Cartan's Corner." Some papers on this very interesting site emphasize not only the geometrical difference between straight and twisted differential forms but also their behavior under mappings.
6. "Rob Salgado":  See especially (as linked by "posters and slides") "Visualizing Tensors and their Algebra with applications for Electromagnetism and Relativity," Gordon Research Conference (Visualization in Science and Education, 2007). This poster provides an excellent pictorial introduction to straight and twisted tensors, the fundamental operations on them, and their use to express Maxwell's equations of electromagnetism.
7. sci.physics.research newsgroup:  "D vs. E in vacuum," "Densitized Pseudo Twisted Forms," and "Fancy-Schmancy Forms in EM." Variously named threads starting October 23, 2001 with "Re: D vs. E in vacuum" by John Baez and continuing through April 16, 2002 with "Re: Densitized Pseudo Twisted Forms" by Eric Alan Forgy contain a lively discussion of twisted differential forms. Frequent posters include John Baez, Toby Bartels, and Eric Alan Forgy. Also available on-line without fancy formatting from the Cornell University archive starting with the above mentioned John Baez' post.
8. Christopher Tiee:  "Contravariance, Covariance, Densities, and All That: An Informal Discussion on Tensor Calculus." This paper gives one math grad student's interesting take on twisted tensors (and more).
9. "Enzo Tonti":  Contains many works on the discrete formulation of engineering electromagnetism using twisted differential forms, as well as a general formulation for the mathematical structure of diverse physical theories.

Clifford Algebra Links

1. Advances in Applied Clifford Algebras:  An online journal. The title says it all.
2. University of Amsterdam Geometric Algebra Group:  Leo Dorst and colleagues. Also see the book by Leo Dorst, Daniel Fontijne, and Stephen Mann Geometric Algebra For Computer Science:  An Object-Oriented Approach to Geometry, Morgan Kaufmann Publishers Inc., San Francisco, 2007 and 2009 (revised).
3. Ian Bell:  "Maths for (Games) Programmers:  Section 5 - Multivector Methods." Contains an extensive exposition of some of the—very sophisticated in parts, but accessibly presented—mathematics of Clifford algebra and geometric calculus, and its application to game programming and physics.
4. James E. Beichler:  Editor of the journal YGGDRASIL (archive). Contains an essay about Clifford's math and paraphysics "Twist til' we tear the house down!" (archive).
5. John Browne:  Grassmann Algebra:  Exploring Extended Vector Algebra with Mathematica (book draft). Chapter 12 is "Exploring Clifford Algebra." Browne also provides a Mathematica package for Grassmann algebra.
6. Cambridge University Geometric Algebra Research Group:  Anthony Lasenby, Joan Lasenby, Chris Doran, Stephen Gull and colleagues. Chris Doran and Anthony Lasenby are authors of the book "Geometric Algebra for Physicists," Cambridge University Press, Cambridge, 2003.
7. Clyde Davenport:  Author of the privately published book A Commutative Hypercomplex Calculus with Applications to Special Relativity, 1991.
8. Bertfried Fauser:  "Site of Extension." Contains his papers, talks, and links to "Clifford people" (many broken). He applies a Hopf gebraic formulation of the Clifford algebra of a not necessarily symmetric bilinear form to quantum physics using commutative and tangle diagrams.
9. Ghent University Clifford Research Group:  Richard Delanghe, Frank Sommen, Fred Brackx and colleagues. Delanghe and other group members authored the book Clifford Algebra and Spinor-Valued Functions:  A Function Theory for the Dirac Operator, Kluwer Academic Publishers, Dordrecht, 1992.
10. David Hestenes:  "Geometric Calculus Research and Development." Contains many papers and book drafts on the application of Clifford algebra to physics and math. This tireless promoter of applied Clifford algebra is coauthor with Garret Sobczyk of the classic book Clifford Algebra to Geometric Calculus:  A Unified Language for Mathematics and Physics, D. Reidel Pub. Co., Dordrecht, 1984.
11. International Clifford Algebra Society:  Contains abstracts, bulletins, and notices of conferences.
12. Pertti Lounesto (deceased):  A mirror of Lounesto's last website maintained by Perttu Puska. Lounesto is the author of many papers on Clifford algebra and the classic book Clifford Algebras and Spinors, Cambridge University Press, Cambridge, 2001.
13. Perttu Puska:  "Algebras of electromagnetics." Contains a Clifford algebra section.
14. Patrick Reany:  "Clifford Algebra Papers" (archive). Contains his papers on Clifford algebra, as well as the algebra of unipodal numbers (the reals extended by both the hyperbolic and imaginary units) and its applications, and also some links. This defunct website has no known primary replacement. Is there another, faster and more reliable archive somewhere?
15. Garret Sobczyk:  Contains papers on the Cliffordian approach to linear algebra and many other works on the application of Clifford algebra to math and physics. Coauthor with David Hestenes of the classic book Clifford Algebra to Geometric Calculus:  A Unified Language for Mathematics and Physics, D. Reidel Pub. Co., Dordrecht, 1984.

Projective Geometry Links

1. John Browne:  Grassmann Algebra:  Exploring Extended Vector Algebra with Mathematica (book draft). Section 4.11 is "Projective Space." Browne also provides a Mathematica package for Grassmann algebra.
2. Leo Dorst, Daniel Fontijne, and Stephen Mann:  Geometric Algebra For Computer Science:  An Object-Oriented Approach to Geometry, Morgan Kaufmann Publishers Inc., San Francisco, 2007 and 2009 (revised). This book treats projective and other geometries with Clifford algebra. It also notably embraces the non-linear meet and join operations of projective geometry.
3. David Hestenes and Renatus Ziegler:  "Projective Geometry with Clifford Algebra," Acta Appl. Math. 23(1): 25-63. Hestenes has posted an on-line preprint version. This paper treats projective geometry with Clifford algebra.
4. Kevin G. Kirby:  "Beyond the Celestial Sphere:  Oriented Projective Geometry and Computer Graphics," Math. Mag. 75(5): 351-366. This accessible paper treats oriented projective geometry as applied to computer graphics. It has been reviewed in Zentralblatt 01911063.
5. Haigang Lu:  "Unification on Gauge Invariance and Relativity," preprint arXiv:hep-ph/0211092, excerpt from abstract:  "The universal U(1) gauge invariance of elementary fermions is attributed to its nature of complex line in three dimensional projective geometry."
6. Haigang Lu:  "Geometric Interpretation of Spinor and Gauge Vector," preprint arXiv:hep-ph/0312026, excerpt from abstract:  "In the standard model, electroweak theory is based on chiral gauge symmetry, which only contains massless fermions and gauge vectors. So the fundamental field equations are Weyl equations including gauge vectors. We deduced these Weyl equations without gauge vector from quadric surface in three dimensional oriented projective geometry."
8. Jorge Stolfi:  Primitives for Computational Geometry. This distinctively illustrated dissertation (published as a corporate technical report) treats oriented projective geometry, but without Clifford algebra. It is essentially the same as Stolfi's classic out-of-print book Oriented Projective Geometry:  A Framework for Geometric Computations, Academic Press, Boston, 1991. This book has been reviewed in Zentralblatt 00051258.

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