data | ||
docs | ||
src | ||
.gitignore | ||
adj_psl2_eigvals.jl | ||
Makefile | ||
Manifest.toml | ||
precomputed_reps_spectral_gap.jl | ||
Project.toml | ||
README.md | ||
runcomputations.jl |
The repository contains code for running experiments for Hyperbolic generalized triangle groups by Pierre-Emmanuel Caprace, Marston Conder, Marek Kaluba and Stefan Witzel.
There are two disjoint computations covered in this repository.
Eigenvalues computations for PSL₂(p)
This computations uses package RamanujanGraphs.jl which implements (projective, special) linear groups of degree 2 (PSL₂(p), SL₂(p), PGL₂(p) and GL₂(p)) and the irreducible representations for SL₂(p).
The script adj_psl2_eigvals.jl
computes a subset of irreps of SL₂(p) which
descend to (mostly irreducible) representations of PSL₂(p) in the following
fashion.
Principal Series
These representations are associated to the induced representations of B(p), the Borel subgroup (of upper triangular matrices) of SL₂(p). All representations of the Borel subgroup come from the representations of the torus inside (i.e. diagonal matrices), hence are 1-dimensional.
Therefore to define a matrix representation of SL₂(p) one needs to specify:
- a complex character of 𝔽ₚ (finite field of p elements)
- an explicit set of representatives of SL₂(p)/B(p).
In code this can be specified by
p = 109 # our choice of a prime
ζ = root_of_unity((p-1)÷2, ...) # ζ is (p-1)÷2 -th root of unity
# two particular generators of SL₂(109):
a = SL₂{p}([0 1; 108 11])
b = SL₂{p}([57 2; 52 42])
S = [a, b, inv(a), inv(b)] # symmetric generating set
SL2p, _ = RamanujanGraphs.generate_balls(S, radius = 21)
Borel_cosets = RamanujanGraphs.CosetDecomposition(SL2p, Borel(SL₂{p}))
# the generator of 𝔽ₚˣ
α = RamanujanGraphs.generator(RamanujanGraphs.GF{p}(0))
ν₅ = let k = 5 # k runs from 0 to (p-1)÷4, or (p-3)÷4 depending on p (mod 4)
νₖ = PrincipalRepr(
α => ζ^k, # character sending α ↦ ζᵏ
Borel_cosets
)
end
Discrete Series
These representations are associated with the action of SL₂(p) (or in more generality of GL₂(p)) on ℂ[𝔽ₚ], the vector space of complex valued functions on 𝔽ₚˣ. There are however multiple choices how to encode such action.
Let L = 𝔽ₚ(√α) be the unique quadratic extension of 𝔽ₚ by a square of a generator α of 𝔽ₚˣ. Comples characters of Lˣ can be separated into decomposable (the ones that take constant 1 value on the unique cyclic subgroup of order (p+1) in Lˣ) and nondecomposable. Each nondecomposable character corresponds to a representation of SL₂(p) in discrete series.
To define matrix representatives one needs to specify
- χ:𝔽ₚ⁺ → ℂ, a complex, non-trivial character of the additive group of 𝔽ₚ
- ν:Lˣ → ℂ, a complex indecomposable character of Lˣ
- a basis for ℂ[𝔽ₚ].
Continuing the snippet above we can write
α = RamanujanGraphs.generator(RamanujanGraphs.GF{p}(0)) # a generator of 𝔽ₚˣ
β = RamanujanGraphs.generator_min(QuadraticExt(α))
# a generator of _Lˣ_ of minimal "Euclidean norm"
ζₚ = root_of_unity(p, ...)
ζ = root_of_unity(p+1, ...)
ϱ₁₇ = let k = 17 # k runs from 1 to (p-1)÷4 or (p+1)÷4 depending on p (mod 4)
DiscreteRepr(
RamanujanGraphs.GF{p}(1) => ζₚ, # character of the additive group of 𝔽ₚ
β => ζ^k, # character of the multiplicative group of _L_
basis = [α^i for i in 1:p-1] # our choice for basis: the dual of
)
A priori ζ needs to be a complex (p²-1)-th root of unity, however one can show that a reduction to (p+1)-th Cyclotomic field is possible.
The script computing eigenvalues should be invoked by running
julia --project=. adj_psl2_eigvals.jl -p 109
The results will be written into log
directory.
Sum of squares approach to property (T)
Note
: This is mostly unsuccessful computation as for none of the groups we examined the computations returned positive result (with the exception of Ronan's examples of groups acting on Ã₂-buildings).
We try to find a sum of squares for various finitely presented groups using julia package PropertyT.jl. For full description of the method plesase refer to 1712.07167.
The groups available are in the ./data
directory in files
presentations*.txt
files (in Magma format). For example
G_8_40_54_2 := Group< a, b, c |
a^3, b^3, c^3,
b*a*b*a,
(c*b^-1*c*b)^2,
(c^-1*b^-1*c*b^-1)^2,
c*a*c^-1*a^-1*c^-1*a*c*a^-1,
(c*a*c^-1*a)^3>
specifies group G_8_40_54_2
as finitely presented group.
The script needs GAP to be installed on the system (one can set GAP_EXECUTABLE
environmental variable to point to gap
exec). and tries to find both an
automatic structure and a confluent Knuth-Bendix rewriting system on the given
presentation. To attempt sum of squares method for proving property (T) one can
execute
make 8_40_54_2
One can perform those computations in bulk by e.g. calling
make 2_4_4
to run all examples in presentations_2_4_4.txt
in parallel.