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Mathlib.Analysis.SpecialFunctions.Trigonometric.Inverse

Inverse trigonometric functions. #

See also Analysis.SpecialFunctions.Trigonometric.Arctan for the inverse tan function. (This is delayed as it is easier to set up after developing complex trigonometric functions.)

Basic inequalities on trigonometric functions.

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noncomputable def Real.arcsin :

Inverse of the sin function, returns values in the range -π / 2 ≤ arcsin x ≤ π / 2. It defaults to -π / 2 on (-∞, -1) and to π / 2 to (1, ∞).

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Instances For
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    theorem Real.arcsin_mem_Icc (x : ) :
    arcsin x Set.Icc (-(Real.pi / 2)) (Real.pi / 2)
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    @[simp]
    theorem Real.range_arcsin :
    Set.range arcsin = Set.Icc (-(Real.pi / 2)) (Real.pi / 2)
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    theorem Real.arcsin_le_pi_div_two (x : ) :
    arcsin x Real.pi / 2
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    theorem Real.neg_pi_div_two_le_arcsin (x : ) :
    -(Real.pi / 2) arcsin x
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    theorem Real.arcsin_projIcc (x : ) :
    arcsin (Set.projIcc (-1) 1 x) = arcsin x
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    theorem Real.sin_arcsin' {x : } (hx : x Set.Icc (-1) 1) :
    sin (arcsin x) = x
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    theorem Real.sin_arcsin {x : } (hx₁ : -1 x) (hx₂ : x 1) :
    sin (arcsin x) = x
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    theorem Real.arcsin_sin' {x : } (hx : x Set.Icc (-(Real.pi / 2)) (Real.pi / 2)) :
    arcsin (sin x) = x
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    theorem Real.arcsin_sin {x : } (hx₁ : -(Real.pi / 2) x) (hx₂ : x Real.pi / 2) :
    arcsin (sin x) = x
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    theorem Real.strictMonoOn_arcsin :
    StrictMonoOn arcsin (Set.Icc (-1) 1)
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    theorem Real.arcsin_lt_arcsin {x y : } (hx : -1 x) (hlt : x < y) (hy : y 1) :
    arcsin x < arcsin y
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    theorem Real.monotone_arcsin :
    Monotone arcsin
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    theorem Real.arcsin_le_arcsin {x y : } (h : x y) :
    arcsin x arcsin y
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    theorem Real.injOn_arcsin :
    Set.InjOn arcsin (Set.Icc (-1) 1)
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    theorem Real.arcsin_inj {x y : } (hx₁ : -1 x) (hx₂ : x 1) (hy₁ : -1 y) (hy₂ : y 1) :
    arcsin x = arcsin y x = y
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    theorem Real.continuous_arcsin :
    Continuous arcsin
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    theorem Real.continuousAt_arcsin {x : } :
    ContinuousAt arcsin x
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    theorem Real.arcsin_eq_of_sin_eq {x y : } (h₁ : sin x = y) (h₂ : x Set.Icc (-(Real.pi / 2)) (Real.pi / 2)) :
    arcsin y = x
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    @[simp]
    theorem Real.arcsin_zero :
    arcsin 0 = 0
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    @[simp]
    theorem Real.arcsin_one :
    arcsin 1 = Real.pi / 2
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    theorem Real.arcsin_of_one_le {x : } (hx : 1 x) :
    arcsin x = Real.pi / 2
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    theorem Real.arcsin_neg_one :
    arcsin (-1) = -(Real.pi / 2)
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    theorem Real.arcsin_of_le_neg_one {x : } (hx : x -1) :
    arcsin x = -(Real.pi / 2)
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    @[simp]
    theorem Real.arcsin_neg (x : ) :
    arcsin (-x) = -arcsin x
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    theorem Real.arcsin_le_iff_le_sin {x y : } (hx : x Set.Icc (-1) 1) (hy : y Set.Icc (-(Real.pi / 2)) (Real.pi / 2)) :
    arcsin x y x sin y
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    theorem Real.arcsin_le_iff_le_sin' {x y : } (hy : y Set.Ico (-(Real.pi / 2)) (Real.pi / 2)) :
    arcsin x y x sin y
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    theorem Real.le_arcsin_iff_sin_le {x y : } (hx : x Set.Icc (-(Real.pi / 2)) (Real.pi / 2)) (hy : y Set.Icc (-1) 1) :
    x arcsin y sin x y
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    theorem Real.le_arcsin_iff_sin_le' {x y : } (hx : x Set.Ioc (-(Real.pi / 2)) (Real.pi / 2)) :
    x arcsin y sin x y
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    theorem Real.arcsin_lt_iff_lt_sin {x y : } (hx : x Set.Icc (-1) 1) (hy : y Set.Icc (-(Real.pi / 2)) (Real.pi / 2)) :
    arcsin x < y x < sin y
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    theorem Real.arcsin_lt_iff_lt_sin' {x y : } (hy : y Set.Ioc (-(Real.pi / 2)) (Real.pi / 2)) :
    arcsin x < y x < sin y
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    theorem Real.lt_arcsin_iff_sin_lt {x y : } (hx : x Set.Icc (-(Real.pi / 2)) (Real.pi / 2)) (hy : y Set.Icc (-1) 1) :
    x < arcsin y sin x < y
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    theorem Real.lt_arcsin_iff_sin_lt' {x y : } (hx : x Set.Ico (-(Real.pi / 2)) (Real.pi / 2)) :
    x < arcsin y sin x < y
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    theorem Real.arcsin_eq_iff_eq_sin {x y : } (hy : y Set.Ioo (-(Real.pi / 2)) (Real.pi / 2)) :
    arcsin x = y x = sin y
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    @[simp]
    theorem Real.arcsin_nonneg {x : } :
    0 arcsin x 0 x
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    @[simp]
    theorem Real.arcsin_nonpos {x : } :
    arcsin x 0 x 0
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    @[simp]
    theorem Real.arcsin_eq_zero_iff {x : } :
    arcsin x = 0 x = 0
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    @[simp]
    theorem Real.zero_eq_arcsin_iff {x : } :
    0 = arcsin x x = 0
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    @[simp]
    theorem Real.arcsin_pos {x : } :
    0 < arcsin x 0 < x
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    @[simp]
    theorem Real.arcsin_lt_zero {x : } :
    arcsin x < 0 x < 0
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    @[simp]
    theorem Real.arcsin_lt_pi_div_two {x : } :
    arcsin x < Real.pi / 2 x < 1
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    @[simp]
    theorem Real.neg_pi_div_two_lt_arcsin {x : } :
    -(Real.pi / 2) < arcsin x -1 < x
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    @[simp]
    theorem Real.arcsin_eq_pi_div_two {x : } :
    arcsin x = Real.pi / 2 1 x
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    @[simp]
    theorem Real.pi_div_two_eq_arcsin {x : } :
    Real.pi / 2 = arcsin x 1 x
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    @[simp]
    theorem Real.pi_div_two_le_arcsin {x : } :
    Real.pi / 2 arcsin x 1 x
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    @[simp]
    theorem Real.arcsin_eq_neg_pi_div_two {x : } :
    arcsin x = -(Real.pi / 2) x -1
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    @[simp]
    theorem Real.neg_pi_div_two_eq_arcsin {x : } :
    -(Real.pi / 2) = arcsin x x -1
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    @[simp]
    theorem Real.arcsin_le_neg_pi_div_two {x : } :
    arcsin x -(Real.pi / 2) x -1
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    @[simp]
    theorem Real.pi_div_four_le_arcsin {x : } :
    Real.pi / 4 arcsin x 2 / 2 x
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    theorem Real.mapsTo_sin_Ioo :
    Set.MapsTo sin (Set.Ioo (-(Real.pi / 2)) (Real.pi / 2)) (Set.Ioo (-1) 1)
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    def Real.sinPartialHomeomorph :
    OpenPartialHomeomorph

    Real.sin as an OpenPartialHomeomorph between (-π / 2, π / 2) and (-1, 1).

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    Instances For
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      theorem Real.cos_arcsin_nonneg (x : ) :
      0 cos (arcsin x)
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      theorem Real.cos_arcsin (x : ) :
      cos (arcsin x) = (1 - x ^ 2)
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      theorem Real.tan_arcsin (x : ) :
      tan (arcsin x) = x / (1 - x ^ 2)
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      noncomputable def Real.arccos (x : ) :

      Inverse of the cos function, returns values in the range 0 ≤ arccos x and arccos x ≤ π. It defaults to π on (-∞, -1) and to 0 to (1, ∞).

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      Instances For
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        theorem Real.arccos_eq_pi_div_two_sub_arcsin (x : ) :
        arccos x = Real.pi / 2 - arcsin x
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        theorem Real.arcsin_eq_pi_div_two_sub_arccos (x : ) :
        arcsin x = Real.pi / 2 - arccos x
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        theorem Real.arccos_le_pi (x : ) :
        arccos x Real.pi
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        theorem Real.arccos_nonneg (x : ) :
        0 arccos x
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        @[simp]
        theorem Real.arccos_pos {x : } :
        0 < arccos x x < 1
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        theorem Real.cos_arccos {x : } (hx₁ : -1 x) (hx₂ : x 1) :
        cos (arccos x) = x
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        theorem Real.arccos_cos {x : } (hx₁ : 0 x) (hx₂ : x Real.pi) :
        arccos (cos x) = x
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        theorem Real.arccos_eq_of_eq_cos {x y : } (hy₀ : 0 y) (hy₁ : y Real.pi) (hxy : x = cos y) :
        arccos x = y
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        theorem Real.strictAntiOn_arccos :
        StrictAntiOn arccos (Set.Icc (-1) 1)
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        theorem Real.arccos_lt_arccos {x y : } (hx : -1 x) (hlt : x < y) (hy : y 1) :
        arccos y < arccos x
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        theorem Real.arccos_le_arccos {x y : } (hlt : x y) :
        arccos y arccos x
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        theorem Real.antitone_arccos :
        Antitone arccos
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        theorem Real.arccos_injOn :
        Set.InjOn arccos (Set.Icc (-1) 1)
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        theorem Real.arccos_inj {x y : } (hx₁ : -1 x) (hx₂ : x 1) (hy₁ : -1 y) (hy₂ : y 1) :
        arccos x = arccos y x = y
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        @[simp]
        theorem Real.arccos_zero :
        arccos 0 = Real.pi / 2
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        @[simp]
        theorem Real.arccos_one :
        arccos 1 = 0
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        @[simp]
        theorem Real.arccos_neg_one :
        arccos (-1) = Real.pi
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        @[simp]
        theorem Real.arccos_eq_zero {x : } :
        arccos x = 0 1 x
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        @[simp]
        theorem Real.arccos_eq_pi_div_two {x : } :
        arccos x = Real.pi / 2 x = 0
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        @[simp]
        theorem Real.arccos_eq_pi {x : } :
        arccos x = Real.pi x -1
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        theorem Real.arccos_neg (x : ) :
        arccos (-x) = Real.pi - arccos x
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        theorem Real.arccos_of_one_le {x : } (hx : 1 x) :
        arccos x = 0
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        theorem Real.arccos_of_le_neg_one {x : } (hx : x -1) :
        arccos x = Real.pi
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        theorem Real.sin_arccos (x : ) :
        sin (arccos x) = (1 - x ^ 2)
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        @[simp]
        theorem Real.arccos_le_pi_div_two {x : } :
        arccos x Real.pi / 2 0 x
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        @[simp]
        theorem Real.arccos_lt_pi_div_two {x : } :
        arccos x < Real.pi / 2 0 < x
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        @[simp]
        theorem Real.arccos_le_pi_div_four {x : } :
        arccos x Real.pi / 4 2 / 2 x
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        theorem Real.continuous_arccos :
        Continuous arccos
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        theorem Real.tan_arccos (x : ) :
        tan (arccos x) = (1 - x ^ 2) / x
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        theorem Real.arccos_eq_arcsin {x : } (h : 0 x) :
        arccos x = arcsin (1 - x ^ 2)
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        theorem Real.arcsin_eq_arccos {x : } (h : 0 x) :
        arcsin x = arccos (1 - x ^ 2)

        Convenience dot notation lemmas #

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        theorem Filter.Tendsto.arcsin {α : Type u_1} {l : Filter α} {x : } {f : α} (h : Tendsto f l (nhds x)) :
        Tendsto (fun (x : α) => Real.arcsin (f x)) l (nhds (Real.arcsin x))
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        theorem Filter.Tendsto.arcsin_nhdsLE {α : Type u_1} {l : Filter α} {x : } {f : α} (h : Tendsto f l (nhdsWithin x (Set.Iic x))) :
        Tendsto (fun (x : α) => Real.arcsin (f x)) l (nhdsWithin (Real.arcsin x) (Set.Iic (Real.arcsin x)))
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        theorem Filter.Tendsto.arcsin_nhdsGE {α : Type u_1} {l : Filter α} {x : } {f : α} (h : Tendsto f l (nhdsWithin x (Set.Ici x))) :
        Tendsto (fun (x : α) => Real.arcsin (f x)) l (nhdsWithin (Real.arcsin x) (Set.Ici (Real.arcsin x)))
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        theorem Filter.Tendsto.arccos {α : Type u_1} {l : Filter α} {x : } {f : α} (h : Tendsto f l (nhds x)) :
        Tendsto (fun (x : α) => Real.arccos (f x)) l (nhds (Real.arccos x))
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        theorem Filter.Tendsto.arccos_nhdsLE {α : Type u_1} {l : Filter α} {x : } {f : α} (h : Tendsto f l (nhdsWithin x (Set.Iic x))) :
        Tendsto (fun (x : α) => Real.arccos (f x)) l (nhdsWithin (Real.arccos x) (Set.Ici (Real.arccos x)))
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        theorem Filter.Tendsto.arccos_nhdsGE {α : Type u_1} {l : Filter α} {x : } {f : α} (h : Tendsto f l (nhdsWithin x (Set.Ici x))) :
        Tendsto (fun (x : α) => Real.arccos (f x)) l (nhdsWithin (Real.arccos x) (Set.Iic (Real.arccos x)))
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        theorem ContinuousWithinAt.arcsin {X : Type u_1} [TopologicalSpace X] {f : X} {s : Set X} {x : X} (h : ContinuousWithinAt f s x) :
        ContinuousWithinAt (fun (x : X) => Real.arcsin (f x)) s x
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        theorem ContinuousWithinAt.arccos {X : Type u_1} [TopologicalSpace X] {f : X} {s : Set X} {x : X} (h : ContinuousWithinAt f s x) :
        ContinuousWithinAt (fun (x : X) => Real.arccos (f x)) s x
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        theorem ContinuousAt.arcsin {X : Type u_1} [TopologicalSpace X] {f : X} {x : X} (h : ContinuousAt f x) :
        ContinuousAt (fun (x : X) => Real.arcsin (f x)) x
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        theorem ContinuousAt.arccos {X : Type u_1} [TopologicalSpace X] {f : X} {x : X} (h : ContinuousAt f x) :
        ContinuousAt (fun (x : X) => Real.arccos (f x)) x
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        theorem ContinuousOn.arcsin {X : Type u_1} [TopologicalSpace X] {f : X} {s : Set X} (h : ContinuousOn f s) :
        ContinuousOn (fun (x : X) => Real.arcsin (f x)) s
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        theorem ContinuousOn.arccos {X : Type u_1} [TopologicalSpace X] {f : X} {s : Set X} (h : ContinuousOn f s) :
        ContinuousOn (fun (x : X) => Real.arccos (f x)) s
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        theorem Continuous.arcsin {X : Type u_1} [TopologicalSpace X] {f : X} (h : Continuous f) :
        Continuous fun (x : X) => Real.arcsin (f x)
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        theorem Continuous.arccos {X : Type u_1} [TopologicalSpace X] {f : X} (h : Continuous f) :
        Continuous fun (x : X) => Real.arccos (f x)