X-Git-Url: http://gitweb.michael.orlitzky.com/?a=blobdiff_plain;f=mjo%2Feja%2FTODO;h=94fb172aba0dda1d601e7c70ccf4f991749a6fcc;hb=f02d09e53017ba3b3b5592a45be84487c580379d;hp=239f3e45b03a51adf0e772d967d48804f9cddf3a;hpb=d373c76a0ae0a1e7ba876d09359f84da40a7ea16;p=sage.d.git diff --git a/mjo/eja/TODO b/mjo/eja/TODO index 239f3e4..94fb172 100644 --- a/mjo/eja/TODO +++ b/mjo/eja/TODO @@ -1,14 +1,31 @@ -0. Add tests for orthogonality in the Peirce decomposition. - 1. Add CartesianProductEJA. -2. Check the axioms in the constructor when check != False? +2. Add references and start citing them. + +3. Implement the octonion simple EJA. + +4. Override random_instance(), one(), et cetera in DirectSumEJA. -3. Add references and start citing them. +5. Switch to QQ in *all* algebras for _charpoly_coefficients(). + This only works when we know that the basis can be rationalized... + which is the case at least for the concrete EJAs we provide, + but not in general. -4. Implement the octonion simple EJA. +6. Pass already_echelonized (default: False) and echelon_basis + (default: None) into the subalgebra constructor. The value of + already_echelonized can be passed to V.span_of_basis() to save + some time, and usinf e.g. FreeModule_submodule_with_basis_field + we may somehow be able to pass the echelon basis straight in to + save time. -5. Factor out the unit-norm basis (and operator symmetry) tests once - all of the algebras pass. + This may require supporting "basis" as a list of basis vectors + (as opposed to superalgebra elements) in the subalgebra constructor. -6. The EJA random element method only returns two summands by default. \ No newline at end of file +7. The inner product should be an *argument* to the main EJA + constructor. Afterwards, the basis normalization step should be + optional (and enabled by default) for ALL algebras, since any + algebra can have a nonstandard inner-product and its basis can be + normalized with respect to that inner- product. For example, the + HadamardEJA could be equipped with an inner- product that is twice + the usual one. Then for the basis to be orthonormal, we would need + to divide e.g. (1,0,0) by <(1,0,0),(1,0,0)> = 2 to normalize it.