LeanMachineLearning exposition

Learning.exists_pullCount_eq🔗

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Minimal Lean file

exists_pullCount_eq🔗

LemmaLearning.exists_pullCount_eq

No docstring.

🔗theorem
Learning.exists_pullCount_eq.{u_1, u_3} {𝓐 : Type u_1} {Ω : Type u_3} [DecidableEq 𝓐] {A : Ω 𝓐} {a : 𝓐} {m : } {ω : Ω} (h' : stepsUntil A a m ω ) : s, pullCount A a (s + 1) ω = m
Learning.exists_pullCount_eq.{u_1, u_3} {𝓐 : Type u_1} {Ω : Type u_3} [DecidableEq 𝓐] {A : Ω 𝓐} {a : 𝓐} {m : } {ω : Ω} (h' : stepsUntil A a m ω ) : s, pullCount A a (s + 1) ω = m

Code

lemma exists_pullCount_eq (h' : stepsUntil A a m ω ≠ ⊤) :
    ∃ s, pullCount A a (s + 1) ω = m
Type uses (2)
Body uses (1)
Used by (5)

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Proof
by
  by_contra! h_contra
  rw [← stepsUntil_eq_top_iff] at h_contra
  simp [h_contra] at h'

Dependency graph

Type dependencies (2)

stepsUntil🔗

DefinitionLearning.stepsUntil

Number of steps until action a was pulled exactly m times.

🔗def
Learning.stepsUntil.{u_1, u_3} {𝓐 : Type u_1} {Ω : Type u_3} [DecidableEq 𝓐] (A : Ω 𝓐) (a : 𝓐) (m : ) (ω : Ω) : ℕ∞
Learning.stepsUntil.{u_1, u_3} {𝓐 : Type u_1} {Ω : Type u_3} [DecidableEq 𝓐] (A : Ω 𝓐) (a : 𝓐) (m : ) (ω : Ω) : ℕ∞

Code

noncomputable
def stepsUntil (A : ℕ → Ω → 𝓐) (a : 𝓐) (m : ℕ) (ω : Ω) : ℕ∞ :=
  sInf ((↑) '' {s | pullCount A a (s + 1) ω = m})
Body uses (1)
Used by (46)

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pullCount🔗

DefinitionLearning.pullCount

Number of times action a was chosen up to time t (excluding t).

🔗def
Learning.pullCount.{u_1, u_3} {𝓐 : Type u_1} {Ω : Type u_3} [DecidableEq 𝓐] (A : Ω 𝓐) (a : 𝓐) (t : ) (ω : Ω) :
Learning.pullCount.{u_1, u_3} {𝓐 : Type u_1} {Ω : Type u_3} [DecidableEq 𝓐] (A : Ω 𝓐) (a : 𝓐) (t : ) (ω : Ω) :

Code

noncomputable
def pullCount (A : ℕ → Ω → 𝓐) (a : 𝓐) (t : ℕ) (ω : Ω) : ℕ :=
  #(filter (fun s ↦ A s ω = a) (range t))
Used by (146)

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