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https://github.com/kalmarek/SmallHyperbolic
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add eigenvalues computations
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adj_psl2_eigvals.jl
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127
adj_psl2_eigvals.jl
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@ -0,0 +1,127 @@
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using RamanujanGraphs
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using LinearAlgebra
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using Nemo
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include("src/nemo_utils.jl")
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const p = try
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@assert length(ARGS) == 2 && ARGS[1] == "-p"
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p = parse(Int, ARGS[2])
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RamanujanGraphs.Primes.isprime(p)
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@assert p % 4 == 1
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catch ex
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@error "You need to provide a prime `-p` which is congruent to 1 mod 4."
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rethrow(ex)
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end
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const CC = AcbField(256)
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SL2p = let
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if p == 109
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a,b = let
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a = SL₂{p}([ 0 1; 108 11])
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b = SL₂{p}([57 2; 52 42])
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@assert isone(a^10)
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@assert isone(b^10)
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a, b
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end
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elseif p == 131
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a,b = let
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a = SL₂{p}([-58 -24; -58 46])
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b = SL₂{p}([0 -3; 44 -12])
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@assert isone(a^10)
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@assert isone(b^10)
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a, b
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end
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else
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@warn "no special set of generators for prime $p"
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a,b = let
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a = SL₂{p}(1, 0, 1, 1)
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b = SL₂{p}(1, 1, 0, 1)
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a, b
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end
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end
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E, sizes = RamanujanGraphs.generate_balls([a,b, inv(a), inv(b)], radius=21);
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@assert sizes[end] == RamanujanGraphs.order(SL₂{p})
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E
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end
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let Borel_cosets = Bcosets = RamanujanGraphs.CosetDecomposition(SL2p, Borel(SL₂{p})),
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α = RamanujanGraphs.generator(RamanujanGraphs.GF{p}(0))
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for j in 0:(p-1)÷4
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try
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h = PrincipalRepr(
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α => root_of_unity(CC, (p-1)÷2, j),
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Borel_cosets)
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@time adjacency = let
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A = matrix(CC, h(SL2p[2]))
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B = matrix(CC, h(SL2p[3]))
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sum(A^i for i in 1:4) + sum(B^i for i in 1:4)
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end
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@time ev = let evs = safe_eigvals(adjacency)
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_count_multiplicites(evs)
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end
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if length(ev) == 1
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@info "Principal Series Representation $j" ev[1]
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else
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@info "Principal Series Representation $j" ev[1:2] ev[end]
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end
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catch ex
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@error "Principal Series Representation $j failed" ex
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ex isa InterruptException && rethrow(ex)
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end
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end
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end
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let α = RamanujanGraphs.generator(RamanujanGraphs.GF{p}(0)),
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β = RamanujanGraphs.generator_min(QuadraticExt(α))
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for j = 1:(p-1)÷4
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try
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h = DiscreteRepr(
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RamanujanGraphs.GF{p}(1) => root_of_unity(CC, p),
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β => root_of_unity(CC, (p+1)÷2, j*(p-1)÷4))
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@time adjacency = let
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A = matrix(CC, h(SL2p[2]))
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B = matrix(CC, h(SL2p[3]))
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sum(A^i for i in 1:4) + sum(B^i for i in 1:4)
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end
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@time ev = let evs = safe_eigvals(adjacency)
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_count_multiplicites(evs)
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end
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@info "Discrete Series Representation $j" ev[1:2] ev[end]
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catch ex
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@error "Discrete Series Representation $j : failed" ex
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ex isa InterruptException && rethrow(ex)
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end
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end
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end
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# using RamanujanGraphs.LightGraphs
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# using Arpack
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#
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# Γ, eigenvalues = let q = 109
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# a = RamanujanGraphs.PSL₂{q}([ 0 1
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# 108 11])
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# b = RamanujanGraphs.PSL₂{q}([57 2
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# 52 42])
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#
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# S = unique([[a^i for i in 1:4]; [b^i for i in 1:4]])
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#
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# @info "Generating set S of $(eltype(S))" S
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# @time Γ, verts, vlabels, elabels = RamanujanGraphs.cayley_graph((q^3 - q)÷2, S)
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# @assert all(LightGraphs.degree(Γ,i) == length(S) for i in vertices(Γ))
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# A = adjacency_matrix(Γ)
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# @time eigenvalues, _ = eigs(A, nev=5)
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# @show Γ eigenvalues
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# Γ, eigenvalues
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# end
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