Learning.feedback_obliviousEnv
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feedback_obliviousEnv🔗
Learning.feedback_obliviousEnvNo docstring.
Learning.feedback_obliviousEnv.{u_1, u_2} {𝓐 : Type u_1} {𝓨 : Type u_2} {m𝓐 : MeasurableSpace 𝓐} {m𝓨 : MeasurableSpace 𝓨} (ν : ℕ → ProbabilityTheory.Kernel 𝓐 𝓨) [∀ (n : ℕ), ProbabilityTheory.IsMarkovKernel (ν n)] (n : ℕ) : Environment.feedback (obliviousEnv ν) n = ProbabilityTheory.Kernel.prodMkLeft (↥(Finset.Iic n) → 𝓐 × 𝓨) (ν (n + 1))Learning.feedback_obliviousEnv.{u_1, u_2} {𝓐 : Type u_1} {𝓨 : Type u_2} {m𝓐 : MeasurableSpace 𝓐} {m𝓨 : MeasurableSpace 𝓨} (ν : ℕ → ProbabilityTheory.Kernel 𝓐 𝓨) [∀ (n : ℕ), ProbabilityTheory.IsMarkovKernel (ν n)] (n : ℕ) : Environment.feedback (obliviousEnv ν) n = ProbabilityTheory.Kernel.prodMkLeft (↥(Finset.Iic n) → 𝓐 × 𝓨) (ν (n + 1))
Code
lemma feedback_obliviousEnv (ν : ℕ → Kernel 𝓐 𝓨) [∀ n, IsMarkovKernel (ν n)] (n : ℕ) :
(obliviousEnv ν).feedback n = (ν (n + 1)).prodMkLeft _Type uses (2)
Used by (1)
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Proof
by simp [obliviousEnv]
Dependency graph
Type dependencies (2)
obliviousEnv🔗
Learning.obliviousEnvAn oblivious environment, in which the distribution of the next feedback depends only on the last action, but in a possibly time-dependent manner.
Learning.obliviousEnv.{u_1, u_2} {𝓐 : Type u_1} {𝓨 : Type u_2} {m𝓐 : MeasurableSpace 𝓐} {m𝓨 : MeasurableSpace 𝓨} (ν : ℕ → ProbabilityTheory.Kernel 𝓐 𝓨) [∀ (n : ℕ), ProbabilityTheory.IsMarkovKernel (ν n)] : Environment 𝓐 𝓨Learning.obliviousEnv.{u_1, u_2} {𝓐 : Type u_1} {𝓨 : Type u_2} {m𝓐 : MeasurableSpace 𝓐} {m𝓨 : MeasurableSpace 𝓨} (ν : ℕ → ProbabilityTheory.Kernel 𝓐 𝓨) [∀ (n : ℕ), ProbabilityTheory.IsMarkovKernel (ν n)] : Environment 𝓐 𝓨
Code
def obliviousEnv (ν : ℕ → Kernel 𝓐 𝓨) [∀ n, IsMarkovKernel (ν n)] : Environment 𝓐 𝓨 where feedback n := (ν (n + 1)).prodMkLeft _ ν0 := ν 0
Type uses (1)
Used by (10)
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Environment🔗
Learning.EnvironmentA stochastic environment.
Learning.Environment.{u_4, u_5} (𝓐 : Type u_4) (𝓨 : Type u_5) [MeasurableSpace 𝓐] [MeasurableSpace 𝓨] : Type (max u_4 u_5)Learning.Environment.{u_4, u_5} (𝓐 : Type u_4) (𝓨 : Type u_5) [MeasurableSpace 𝓐] [MeasurableSpace 𝓨] : Type (max u_4 u_5)
Code
structure Environment (𝓐 𝓨 : Type*) [MeasurableSpace 𝓐] [MeasurableSpace 𝓨] where /-- Distribution of the next observation as function of the past history. -/ feedback : (n : ℕ) → Kernel ((Iic n → 𝓐 × 𝓨) × 𝓐) 𝓨 /-- The feedback kernels are Markov kernels. -/ [h_feedback : ∀ n, IsMarkovKernel (feedback n)] /-- Distribution of the first observation given the first action. -/ ν0 : Kernel 𝓐 𝓨 /-- The initial observation kernel is a Markov kernel. -/ [hp0 : IsMarkovKernel ν0]
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