Learning.IsAlgEnvSeq.condDistrib_feedback_stationaryEnv
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condDistrib_feedback_stationaryEnv๐
Learning.IsAlgEnvSeq.condDistrib_feedback_stationaryEnv
The conditional distribution of the feedback at time n given the action at time n is ฮฝ.
Learning.IsAlgEnvSeq.condDistrib_feedback_stationaryEnv.{u_1, u_2, u_3} {๐ : Type u_1} {๐จ : Type u_2} {m๐ : MeasurableSpace ๐} {m๐จ : MeasurableSpace ๐จ} {ฮฉ : Type u_3} {mฮฉ : MeasurableSpace ฮฉ} {alg : Algorithm ๐ ๐จ} {ฮฝ : ProbabilityTheory.Kernel ๐ ๐จ} [ProbabilityTheory.IsMarkovKernel ฮฝ] {P : MeasureTheory.Measure ฮฉ} [MeasureTheory.IsProbabilityMeasure P] {A : โ โ ฮฉ โ ๐} {Y : โ โ ฮฉ โ ๐จ} [StandardBorelSpace ๐จ] [Nonempty ๐จ] (h : IsAlgEnvSeq A Y alg (stationaryEnv ฮฝ) P) (n : โ) : โ๐[Y n | A n; P] =แต[MeasureTheory.Measure.map (A n) P] โฮฝLearning.IsAlgEnvSeq.condDistrib_feedback_stationaryEnv.{u_1, u_2, u_3} {๐ : Type u_1} {๐จ : Type u_2} {m๐ : MeasurableSpace ๐} {m๐จ : MeasurableSpace ๐จ} {ฮฉ : Type u_3} {mฮฉ : MeasurableSpace ฮฉ} {alg : Algorithm ๐ ๐จ} {ฮฝ : ProbabilityTheory.Kernel ๐ ๐จ} [ProbabilityTheory.IsMarkovKernel ฮฝ] {P : MeasureTheory.Measure ฮฉ} [MeasureTheory.IsProbabilityMeasure P] {A : โ โ ฮฉ โ ๐} {Y : โ โ ฮฉ โ ๐จ} [StandardBorelSpace ๐จ] [Nonempty ๐จ] (h : IsAlgEnvSeq A Y alg (stationaryEnv ฮฝ) P) (n : โ) : โ๐[Y n | A n; P] =แต[MeasureTheory.Measure.map (A n) P] โฮฝ
Code
lemma condDistrib_feedback_stationaryEnv [StandardBorelSpace ๐จ] [Nonempty ๐จ]
(h : IsAlgEnvSeq A Y alg (stationaryEnv ฮฝ) P) (n : โ) :
condDistrib (Y n) (A n) P =แต[P.map (A n)] ฮฝType uses (3)
Body uses (2)
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Proof
(hasCondDistrib_feedback_stationaryEnv h n).condDistrib_eq
Dependency graph
Type dependencies (3)
Algorithm๐
Learning.AlgorithmA stochastic, sequential algorithm.
Learning.Algorithm.{u_4, u_5} (๐ : Type u_4) (๐จ : Type u_5) [MeasurableSpace ๐] [MeasurableSpace ๐จ] : Type (max u_4 u_5)Learning.Algorithm.{u_4, u_5} (๐ : Type u_4) (๐จ : Type u_5) [MeasurableSpace ๐] [MeasurableSpace ๐จ] : Type (max u_4 u_5)
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structure Algorithm (๐ ๐จ : Type*) [MeasurableSpace ๐] [MeasurableSpace ๐จ] where /-- Policy or sampling rule: distribution of the next action. -/ policy : (n : โ) โ Kernel (Iic n โ ๐ ร ๐จ) ๐ /-- The policy is a Markov kernel. -/ [h_policy : โ n, IsMarkovKernel (policy n)] /-- Distribution of the first action. -/ p0 : Measure ๐ /-- The first action distribution is a probability measure. -/ [hp0 : IsProbabilityMeasure p0]
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IsAlgEnvSeq๐
Learning.IsAlgEnvSeqAn algorithm-environment sequence: a sequence of actions and feedbacks generated by an algorithm interacting with an environment.
Learning.IsAlgEnvSeq.{u_1, u_2, u_3} {๐ : Type u_1} {๐จ : Type u_2} {ฮฉ : Type u_3} {m๐ : MeasurableSpace ๐} {m๐จ : MeasurableSpace ๐จ} {mฮฉ : MeasurableSpace ฮฉ} (A : โ โ ฮฉ โ ๐) (Y : โ โ ฮฉ โ ๐จ) (alg : Algorithm ๐ ๐จ) (env : Environment ๐ ๐จ) (P : MeasureTheory.Measure ฮฉ) [MeasureTheory.IsFiniteMeasure P] : PropLearning.IsAlgEnvSeq.{u_1, u_2, u_3} {๐ : Type u_1} {๐จ : Type u_2} {ฮฉ : Type u_3} {m๐ : MeasurableSpace ๐} {m๐จ : MeasurableSpace ๐จ} {mฮฉ : MeasurableSpace ฮฉ} (A : โ โ ฮฉ โ ๐) (Y : โ โ ฮฉ โ ๐จ) (alg : Algorithm ๐ ๐จ) (env : Environment ๐ ๐จ) (P : MeasureTheory.Measure ฮฉ) [MeasureTheory.IsFiniteMeasure P] : Prop
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structure IsAlgEnvSeq
(A : โ โ ฮฉ โ ๐) (Y : โ โ ฮฉ โ ๐จ) (alg : Algorithm ๐ ๐จ) (env : Environment ๐ ๐จ)
(P : Measure ฮฉ) [IsFiniteMeasure P] : Prop where
/-- The action sequence is measurable. -/
measurable_action n : Measurable (A n) := by fun_prop
/-- The feedback sequence is measurable. -/
measurable_feedback n : Measurable (Y n) := by fun_prop
/-- The first action has the correct law. -/
hasLaw_action_zero : HasLaw (fun ฯ โฆ (A 0 ฯ)) alg.p0 P
/-- The first feedback has the correct conditional distribution. -/
hasCondDistrib_feedback_zero : HasCondDistrib (Y 0) (A 0) env.ฮฝ0 P
/-- The next action has the correct conditional distribution given the history. -/
hasCondDistrib_action n :
HasCondDistrib (A (n + 1)) (history A Y n) (alg.policy n) P
/-- The next feedback has the correct conditional distribution given the history and
next action. -/
hasCondDistrib_feedback n :
HasCondDistrib (Y (n + 1)) (fun ฯ โฆ (history A Y n ฯ, A (n + 1) ฯ))
(env.feedback n) PType uses (3)
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stationaryEnv๐
Learning.stationaryEnvA stationary environment, in which the distribution of the next feedback depends only on the last action.
Learning.stationaryEnv.{u_1, u_2} {๐ : Type u_1} {๐จ : Type u_2} {m๐ : MeasurableSpace ๐} {m๐จ : MeasurableSpace ๐จ} (ฮฝ : ProbabilityTheory.Kernel ๐ ๐จ) [ProbabilityTheory.IsMarkovKernel ฮฝ] : Environment ๐ ๐จLearning.stationaryEnv.{u_1, u_2} {๐ : Type u_1} {๐จ : Type u_2} {m๐ : MeasurableSpace ๐} {m๐จ : MeasurableSpace ๐จ} (ฮฝ : ProbabilityTheory.Kernel ๐ ๐จ) [ProbabilityTheory.IsMarkovKernel ฮฝ] : Environment ๐ ๐จ
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def stationaryEnv (ฮฝ : Kernel ๐ ๐จ) [IsMarkovKernel ฮฝ] : Environment ๐ ๐จ := obliviousEnv fun _ โฆ ฮฝ
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All dependencies, transitively (3)
Environment๐
Learning.EnvironmentA stochastic environment.
Learning.Environment.{u_4, u_5} (๐ : Type u_4) (๐จ : Type u_5) [MeasurableSpace ๐] [MeasurableSpace ๐จ] : Type (max u_4 u_5)Learning.Environment.{u_4, u_5} (๐ : Type u_4) (๐จ : Type u_5) [MeasurableSpace ๐] [MeasurableSpace ๐จ] : Type (max u_4 u_5)
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structure Environment (๐ ๐จ : Type*) [MeasurableSpace ๐] [MeasurableSpace ๐จ] where /-- Distribution of the next observation as function of the past history. -/ feedback : (n : โ) โ Kernel ((Iic n โ ๐ ร ๐จ) ร ๐) ๐จ /-- The feedback kernels are Markov kernels. -/ [h_feedback : โ n, IsMarkovKernel (feedback n)] /-- Distribution of the first observation given the first action. -/ ฮฝ0 : Kernel ๐ ๐จ /-- The initial observation kernel is a Markov kernel. -/ [hp0 : IsMarkovKernel ฮฝ0]
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history๐
Learning.history
History of the algorithm-environment sequence up to time n.
Learning.history.{u_1, u_2, u_3} {๐ : Type u_1} {๐จ : Type u_2} {ฮฉ : Type u_3} (A : โ โ ฮฉ โ ๐) (Y : โ โ ฮฉ โ ๐จ) (n : โ) (ฯ : ฮฉ) : โฅ(Finset.Iic n) โ ๐ ร ๐จLearning.history.{u_1, u_2, u_3} {๐ : Type u_1} {๐จ : Type u_2} {ฮฉ : Type u_3} (A : โ โ ฮฉ โ ๐) (Y : โ โ ฮฉ โ ๐จ) (n : โ) (ฯ : ฮฉ) : โฅ(Finset.Iic n) โ ๐ ร ๐จ
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def history (A : โ โ ฮฉ โ ๐) (Y : โ โ ฮฉ โ ๐จ) (n : โ) (ฯ : ฮฉ) : Iic n โ ๐ ร ๐จ := fun i โฆ (A i ฯ, Y i ฯ)
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obliviousEnv๐
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} {๐ : Type u_1} {๐จ : Type u_2} {m๐ : MeasurableSpace ๐} {m๐จ : MeasurableSpace ๐จ} (ฮฝ : โ โ ProbabilityTheory.Kernel ๐ ๐จ) [โ (n : โ), ProbabilityTheory.IsMarkovKernel (ฮฝ n)] : Environment ๐ ๐จLearning.obliviousEnv.{u_1, u_2} {๐ : Type u_1} {๐จ : Type u_2} {m๐ : MeasurableSpace ๐} {m๐จ : MeasurableSpace ๐จ} (ฮฝ : โ โ ProbabilityTheory.Kernel ๐ ๐จ) [โ (n : โ), ProbabilityTheory.IsMarkovKernel (ฮฝ n)] : Environment ๐ ๐จ
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def obliviousEnv (ฮฝ : โ โ Kernel ๐ ๐จ) [โ n, IsMarkovKernel (ฮฝ n)] : Environment ๐ ๐จ where feedback n := (ฮฝ (n + 1)).prodMkLeft _ ฮฝ0 := ฮฝ 0
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