return (J0, J5, J1)
- def a_jordan_frame(self):
- r"""
- Generate a Jordan frame for this algebra.
-
- This implementation is based on the so-called "central
- orthogonal idempotents" implemented for (semisimple) centers
- of SageMath ``FiniteDimensionalAlgebrasWithBasis``. Since all
- Euclidean Jordan algebas are commutative (and thus equal to
- their own centers) and semisimple, the method should work more
- or less as implemented, if it ever worked in the first place.
- (I don't know the justification for the original implementation.
- yet).
-
- How it works: we loop through the algebras generators, looking
- for their eigenspaces. If there's more than one eigenspace,
- and if they result in more than one subalgebra, then we split
- those subalgebras recursively until we get to subalgebras of
- dimension one (whose idempotent is the unit element). Why does
- some generator have to produce at least two subalgebras? I
- dunno. But it seems to work.
-
- Beware that Koecher defines the "center" of a Jordan algebra to
- be something else, because the usual definition is stupid in a
- (necessarily commutative) Jordan algebra.
-
- SETUP::
-
- sage: from mjo.eja.eja_algebra import (random_eja,
- ....: JordanSpinEJA,
- ....: TrivialEJA)
-
- EXAMPLES:
-
- A Jordan frame for the trivial algebra has to be empty
- (zero-length) since its rank is zero. More to the point, there
- are no non-zero idempotents in the trivial EJA. This does not
- cause any problems so long as we adopt the convention that the
- empty sum is zero, since then the sole element of the trivial
- EJA has an (empty) spectral decomposition::
-
- sage: J = TrivialEJA()
- sage: J.a_jordan_frame()
- ()
-
- A one-dimensional algebra has rank one (equal to its dimension),
- and only one primitive idempotent, namely the algebra's unit
- element::
-
- sage: J = JordanSpinEJA(1)
- sage: J.a_jordan_frame()
- (e0,)
-
- TESTS::
-
- sage: J = random_eja()
- sage: c = J.a_jordan_frame()
- sage: all( x^2 == x for x in c )
- True
- sage: r = len(c)
- sage: all( c[i]*c[j] == c[i]*(i==j) for i in range(r)
- ....: for j in range(r) )
- True
-
- """
- if self.dimension() == 0:
- return ()
- if self.dimension() == 1:
- return (self.one(),)
-
- for g in self.gens():
- eigenpairs = g.operator().matrix().right_eigenspaces()
- if len(eigenpairs) >= 2:
- subalgebras = []
- for eigval, eigspace in eigenpairs:
- # Make sub-EJAs from the matrix eigenspaces...
- sb = tuple( self.from_vector(b) for b in eigspace.basis() )
- try:
- # This will fail if e.g. the eigenspace basis
- # contains two elements and their product
- # isn't a linear combination of the two of
- # them (i.e. the generated EJA isn't actually
- # two dimensional).
- s = FiniteDimensionalEuclideanJordanSubalgebra(self, sb)
- subalgebras.append(s)
- except ArithmeticError as e:
- if str(e) == "vector is not in free module":
- # Ignore only the "not a sub-EJA" error
- pass
-
- if len(subalgebras) >= 2:
- # apply this method recursively.
- return tuple( c.superalgebra_element()
- for subalgebra in subalgebras
- for c in subalgebra.a_jordan_frame() )
-
- # If we got here, the algebra didn't decompose, at least not when we looked at
- # the eigenspaces corresponding only to basis elements of the algebra. The
- # implementation I stole says that this should work because of Schur's Lemma,
- # so I personally blame Schur's Lemma if it does not.
- raise Exception("Schur's Lemma didn't work!")
-
-
def random_elements(self, count):
"""
Return ``count`` random elements as a tuple.
projects / sage.d.git / commitdiff