mirror of
https://github.com/kalmarek/PropertyT.jl.git
synced 2024-11-27 01:10:28 +01:00
Change names: kappa -> lambda, A -> P
This commit is contained in:
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028979bfd1
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5876998cba
@ -20,14 +20,14 @@ function pmΔfilenames(name::String)
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return pm_filename, Δ_coeff_filename
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end
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function κSDPfilenames(name::String)
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function λSDPfilenames(name::String)
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if !isdir(name)
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mkdir(name)
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end
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prefix = name
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κ_filename = joinpath(prefix, "kappa.jld")
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SDP_filename = joinpath(prefix, "SDPmatrixA.jld")
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return κ_filename, SDP_filename
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λ_filename = joinpath(prefix, "lambda.jld")
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SDP_filename = joinpath(prefix, "SDPmatrix.jld")
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return λ_filename, SDP_filename
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end
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function ΔandSDPconstraints(name::String)
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@ -63,18 +63,19 @@ function ΔandSDPconstraints(name::String, generating_set::Function, radius::Int
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end
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end
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function κandA(name::String)
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κ_fname, SDP_fname = κSDPfilenames(name)
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f₁ = isfile(κ_fname)
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function λandP(name::String)
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λ_fname, SDP_fname = λSDPfilenames(name)
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f₁ = isfile(λ_fname)
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f₂ = isfile(SDP_fname)
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if f₁ && f₂
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info(logger, "Loading precomputed κ, A...")
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κ = load(κ_fname, "κ")
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A = load(SDP_fname, "A")
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info(logger, "Loading precomputed λ, P...")
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λ = load(λ_fname, "λ")
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P = load(SDP_fname, "P")
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else
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throw(ArgumentError("You need to precompute κ and SDP matrix A to load it!"))
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throw(ArgumentError("You need to precompute λ and SDP matrix P to load it!"))
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end
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return κ, A
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return λ, P
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end
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function timed_msg(t)
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@ -87,32 +88,32 @@ function timed_msg(t)
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end
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function κandA(name::String, opts...)
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function λandP(name::String, opts...)
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try
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return κandA(name)
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return λandP(name)
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catch err
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if isa(err, ArgumentError)
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if isfile("$name/solver.log")
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rm("$name/solver.log")
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if isfile(joinpath(name, "solver.log"))
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rm(joinpath(name, "solver.log"))
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end
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add_handler(solver_logger, DefaultHandler("./$name/solver.log", DefaultFormatter("{date}| {msg}")), "solver_log")
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add_handler(solver_logger, DefaultHandler(joinpath(name, "solver.log"), DefaultFormatter("{date}| {msg}")), "solver_log")
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info(logger, "Creating SDP problem...")
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κ, A = compute_κandA(opts...)
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λ, P = compute_λandP(opts...)
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remove_handler(solver_logger, "solver_log")
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κ_fname, A_fname = κSDPfilenames(name)
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λ_fname, P_fname = λSDPfilenames(name)
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if κ > 0
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save(κ_fname, "κ", κ)
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save(A_fname, "A", A)
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if λ > 0
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save(λ_fname, "λ", λ)
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save(P_fname, "P", P)
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else
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throw(ErrorException("Solver $solver did not produce a valid solution!: κ = $κ"))
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throw(ErrorException("Solver $solver did not produce a valid solution!: λ = $λ"))
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end
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return κ, A
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return λ, P
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else
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# throw(err)
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@ -121,21 +122,21 @@ function κandA(name::String, opts...)
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end
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end
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function compute_κandA(sdp_constraints, Δ::GroupAlgebraElement, solver::AbstractMathProgSolver, upper_bound=Inf)
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function compute_λandP(sdp_constraints, Δ::GroupAlgebraElement, solver::AbstractMathProgSolver, upper_bound=Inf)
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t = @timed SDP_problem = create_SDP_problem(sdp_constraints, Δ; upper_bound=upper_bound)
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info(logger, timed_msg(t))
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κ = 0.0
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A = nothing
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while κ == 0.0
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λ = 0.0
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P = nothing
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while λ == 0.0
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try
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κ, A = solve_SDP(SDP_problem, solver)
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λ, P = solve_SDP(SDP_problem, solver)
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catch y
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warn(solver_logger, y)
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end
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end
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return κ, A
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return λ, P
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end
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Kazhdan_from_sgap(λ,N) = sqrt(2*λ/N)
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@ -160,29 +161,29 @@ function check_property_T(name::String, generating_set::Function,
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info(logger, "length(Δ) = $(length(Δ))")
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info(logger, "size(Δ.product_matrix) = $(size(Δ.product_matrix))")
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κ, A = κandA(name, sdp_constraints, Δ, solver, upper_bound)
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λ, P = λandP(name, sdp_constraints, Δ, solver, upper_bound)
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info(logger, "κ = $κ")
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info(logger, "sum(A) = $(sum(A))")
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info(logger, "maximum(A) = $(maximum(A))")
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info(logger, "minimum(A) = $(minimum(A))")
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info(logger, "λ = $λ")
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info(logger, "sum(P) = $(sum(P))")
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info(logger, "maximum(P) = $(maximum(P))")
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info(logger, "minimum(P) = $(minimum(P))")
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if κ > 0
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spectral_gap = check_distance_to_positive_cone(Δ, κ, A, tol=tol, rational=false)
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if λ > 0
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spectral_gap = check_distance_to_positive_cone(Δ, λ, P, tol=tol, rational=false)
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if isa(spectral_gap, Interval)
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spectral_gap = spectral_gap.lo
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end
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if spectral_gap > 0
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@show spectral_gap
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Kazhdan_const = Kazhdan_from_sgap(spectral_gap, S)
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Kazhdan_const = Float64(trunc(Kazhdan_const, 12))
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info(logger, "κ($name, S) ≥ $Kazhdan_const: Group HAS property (T)!")
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Kazhdan_κ = Kazhdan_from_sgap(spectral_gap, S)
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Kazhdan_κ = Float64(trunc(Kazhdan_κ, 12))
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info(logger, "κ($name, S) ≥ $Kazhdan_κ: Group HAS property (T)!")
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else
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spectral_gap = Float64(trunc(spectral_gap, 12))
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info(logger, "λ($name, S) ≥ $spectral_gap: Group may NOT HAVE property (T)!")
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end
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else
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info(logger, "κ($name, S) ≥ $κ < 0: Tells us nothing about property (T)")
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info(logger, "κ($name, S) ≥ $λ < 0: Tells us nothing about property (T)")
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end
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end
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@ -6,8 +6,8 @@ ValidatedNumerics.setrounding(Interval, :correct)
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ValidatedNumerics.setformat(:standard)
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# setprecision(Interval, 53) # slightly faster than 256
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function EOI{T<:Number}(Δ::GroupAlgebraElement{T}, κ::T)
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return Δ*Δ - κ*Δ
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function EOI{T<:Number}(Δ::GroupAlgebraElement{T}, λ::T)
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return Δ*Δ - λ*Δ
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end
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function algebra_square(vector, elt)
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@ -62,69 +62,69 @@ end
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ℚ(x, tol::Real) = rationalize(BigInt, x, tol=tol)
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function distance_to_cone{T<:Rational}(κ::T, sqrt_matrix::Array{T,2}, Δ::GroupAlgebraElement{T})
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function distance_to_cone{T<:Rational}(λ::T, sqrt_matrix::Array{T,2}, Δ::GroupAlgebraElement{T})
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SOS = compute_SOS(sqrt_matrix, Δ)
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SOS_diff = EOI(Δ, κ) - SOS
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SOS_diff = EOI(Δ, λ) - SOS
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eoi_SOS_L₁_dist = norm(SOS_diff,1)
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info(logger, "κ = $κ (≈$(@sprintf("%.10f", float(κ)))")
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info(logger, "λ = $λ (≈$(@sprintf("%.10f", float(λ)))")
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ɛ_dist = GroupAlgebras.ɛ(SOS_diff)
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if ɛ_dist ≠ 0//1
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warn(logger, "The SOS is not in the augmentation ideal, number below are meaningless!")
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end
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info(logger, "ɛ(Δ² - κΔ - ∑ξᵢ*ξᵢ) = $ɛ_dist")
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info(logger, "‖Δ² - κΔ - ∑ξᵢ*ξᵢ‖₁ = $(@sprintf("%.10f", float(eoi_SOS_L₁_dist)))")
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info(logger, "ɛ(Δ² - λΔ - ∑ξᵢ*ξᵢ) = $ɛ_dist")
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info(logger, "‖Δ² - λΔ - ∑ξᵢ*ξᵢ‖₁ = $(@sprintf("%.10f", float(eoi_SOS_L₁_dist)))")
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distance_to_cone = κ - 2^3*eoi_SOS_L₁_dist
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distance_to_cone = λ - 2^3*eoi_SOS_L₁_dist
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return distance_to_cone
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end
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function distance_to_cone{T<:Rational, S<:Interval}(κ::T, sqrt_matrix::Array{S,2}, Δ::GroupAlgebraElement{T})
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function distance_to_cone{T<:Rational, S<:Interval}(λ::T, sqrt_matrix::Array{S,2}, Δ::GroupAlgebraElement{T})
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SOS = compute_SOS(sqrt_matrix, Δ)
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info(logger, "ɛ(∑ξᵢ*ξᵢ) ∈ $(GroupAlgebras.ɛ(SOS))")
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κⁱⁿᵗ = @interval(κ)
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λⁱⁿᵗ = @interval(λ)
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Δⁱⁿᵗ = GroupAlgebraElement([@interval(c) for c in Δ.coefficients], Δ.product_matrix)
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SOS_diff = EOI(Δⁱⁿᵗ, κⁱⁿᵗ) - SOS
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SOS_diff = EOI(Δⁱⁿᵗ, λⁱⁿᵗ) - SOS
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eoi_SOS_L₁_dist = norm(SOS_diff,1)
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info(logger, "κ = $κ (≈≥$(@sprintf("%.10f",float(κ))))")
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info(logger, "λ = $λ (≈≥$(@sprintf("%.10f",float(λ))))")
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ɛ_dist = GroupAlgebras.ɛ(SOS_diff)
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info(logger, "ɛ(Δ² - κΔ - ∑ξᵢ*ξᵢ) ∈ $(ɛ_dist)")
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info(logger, "‖Δ² - κΔ - ∑ξᵢ*ξᵢ‖₁ ∈ $(eoi_SOS_L₁_dist)")
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info(logger, "ɛ(Δ² - λΔ - ∑ξᵢ*ξᵢ) ∈ $(ɛ_dist)")
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info(logger, "‖Δ² - λΔ - ∑ξᵢ*ξᵢ‖₁ ∈ $(eoi_SOS_L₁_dist)")
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distance_to_cone = κ - 2^3*eoi_SOS_L₁_dist
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distance_to_cone = λ - 2^3*eoi_SOS_L₁_dist
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return distance_to_cone
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end
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function distance_to_cone{T<:AbstractFloat}(κ::T, sqrt_matrix::Array{T,2}, Δ::GroupAlgebraElement{T})
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function distance_to_cone{T<:AbstractFloat}(λ::T, sqrt_matrix::Array{T,2}, Δ::GroupAlgebraElement{T})
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SOS = compute_SOS(sqrt_matrix, Δ)
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SOS_diff = EOI(Δ, κ) - SOS
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SOS_diff = EOI(Δ, λ) - SOS
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eoi_SOS_L₁_dist = norm(SOS_diff,1)
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info(logger, "κ = $κ")
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info(logger, "λ = $λ")
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ɛ_dist = GroupAlgebras.ɛ(SOS_diff)
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info(logger, "ɛ(Δ² - κΔ - ∑ξᵢ*ξᵢ) ≈ $(@sprintf("%.10f", ɛ_dist))")
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info(logger, "‖Δ² - κΔ - ∑ξᵢ*ξᵢ‖₁ ≈ $(@sprintf("%.10f", eoi_SOS_L₁_dist))")
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info(logger, "ɛ(Δ² - λΔ - ∑ξᵢ*ξᵢ) ≈ $(@sprintf("%.10f", ɛ_dist))")
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info(logger, "‖Δ² - λΔ - ∑ξᵢ*ξᵢ‖₁ ≈ $(@sprintf("%.10f", eoi_SOS_L₁_dist))")
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distance_to_cone = κ - 2^3*eoi_SOS_L₁_dist
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distance_to_cone = λ - 2^3*eoi_SOS_L₁_dist
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return distance_to_cone
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end
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function check_distance_to_positive_cone(Δ::GroupAlgebraElement, κ, A;
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function check_distance_to_positive_cone(Δ::GroupAlgebraElement, λ, P;
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tol=1e-7, rational=false)
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isapprox(eigvals(A), abs(eigvals(A)), atol=tol) ||
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isapprox(eigvals(P), abs(eigvals(P)), atol=tol) ||
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warn("The solution matrix doesn't seem to be positive definite!")
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@assert A == Symmetric(A)
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A_sqrt = real(sqrtm(A))
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@assert P == Symmetric(P)
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Q = real(sqrtm(P))
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info(logger, "------------------------------------------------------------")
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info(logger, "")
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info(logger, "Checking in floating-point arithmetic...")
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t = @timed fp_distance = distance_to_cone(κ, A_sqrt, Δ)
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t = @timed fp_distance = distance_to_cone(λ, Q, Δ)
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info(logger, timed_msg(t))
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info(logger, "Floating point distance (to positive cone) ≈ $(@sprintf("%.10f", fp_distance))")
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info(logger, "------------------------------------------------------------")
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@ -133,17 +133,17 @@ function check_distance_to_positive_cone(Δ::GroupAlgebraElement, κ, A;
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# return fpdistance
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# end
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info(logger, "Projecting columns of rationalized A_sqrt to the augmentation ideal...")
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δ = eps(κ)
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A_sqrt_ℚ = ℚ(A_sqrt, δ)
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t = @timed A_sqrt_ℚ_aug = correct_to_augmentation_ideal(A_sqrt_ℚ)
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info(logger, "Projecting columns of rationalized Q to the augmentation ideal...")
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δ = eps(λ)
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Q_ℚ = ℚ(Q, δ)
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t = @timed Q_ℚω = correct_to_augmentation_ideal(Q_ℚ)
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info(logger, timed_msg(t))
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κ_ℚ = ℚ(κ, δ)
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λ_ℚ = ℚ(λ, δ)
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Δ_ℚ = ℚ(Δ, δ)
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info(logger, "Checking in interval arithmetic")
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A_sqrt_ℚ_augⁱⁿᵗ = Float64.(A_sqrt_ℚ_aug) ± δ
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t = @timed Interval_dist_to_Σ² = distance_to_cone(κ_ℚ, A_sqrt_ℚ_augⁱⁿᵗ, Δ_ℚ)
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Q_ℚωⁱⁿᵗ = Float64.(Q_ℚω) ± δ
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t = @timed Interval_dist_to_Σ² = distance_to_cone(λ_ℚ, Q_ℚωⁱⁿᵗ, Δ_ℚ)
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info(logger, timed_msg(t))
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info(logger, "The Augmentation-projected actual distance (to positive cone) ∈ $(Interval_dist_to_Σ²)")
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info(logger, "------------------------------------------------------------")
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@ -152,7 +152,7 @@ function check_distance_to_positive_cone(Δ::GroupAlgebraElement, κ, A;
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return Interval_dist_to_Σ²
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else
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info(logger, "Checking Projected SOS decomposition in exact rational arithmetic...")
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t = @timed ℚ_dist_to_Σ² = distance_to_cone(κ_ℚ, A_sqrt_ℚ_aug, Δ_ℚ)
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t = @timed ℚ_dist_to_Σ² = distance_to_cone(λ_ℚ, Q_ℚω, Δ_ℚ)
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info(logger, timed_msg(t))
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@assert isa(ℚ_dist_to_Σ², Rational)
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info(logger, "Augmentation-projected rational distance (to positive cone) ≥ $(Float64(trunc(ℚ_dist_to_Σ²,8)))")
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20
src/sdps.jl
20
src/sdps.jl
@ -52,21 +52,21 @@ function create_SDP_problem(matrix_constraints, Δ::GroupAlgebraElement; upper_b
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Δ² = Δ*Δ
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@assert length(Δ) == length(matrix_constraints)
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m = JuMP.Model();
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JuMP.@variable(m, A[1:N, 1:N], SDP)
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JuMP.@SDconstraint(m, A >= 0)
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JuMP.@constraint(m, sum(A[i] for i in eachindex(A)) == 0)
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JuMP.@variable(m, P[1:N, 1:N], SDP)
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JuMP.@SDconstraint(m, P >= 0)
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JuMP.@constraint(m, sum(P[i] for i in eachindex(P)) == 0)
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if upper_bound < Inf
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JuMP.@variable(m, 0.0 <= κ <= upper_bound)
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JuMP.@variable(m, 0.0 <= λ <= upper_bound)
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else
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JuMP.@variable(m, κ >= 0)
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JuMP.@variable(m, λ >= 0)
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end
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for (pairs, δ², δ) in zip(matrix_constraints, Δ².coefficients, Δ.coefficients)
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JuMP.@constraint(m, sum(A[i,j] for (i,j) in pairs) == δ² - κ*δ)
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JuMP.@constraint(m, sum(P[i,j] for (i,j) in pairs) == δ² - λ*δ)
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end
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JuMP.@objective(m, Max, κ)
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JuMP.@objective(m, Max, λ)
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return m
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end
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@ -95,7 +95,7 @@ function solve_SDP(SDP_problem, solver)
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end
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info(logger, solution_status)
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κ = JuMP.getvalue(JuMP.getvariable(SDP_problem, :κ))
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A = JuMP.getvalue(JuMP.getvariable(SDP_problem, :A))
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return κ, A
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λ = JuMP.getvalue(JuMP.getvariable(SDP_problem, :λ))
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P = JuMP.getvalue(JuMP.getvariable(SDP_problem, :P))
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return λ, P
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end
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