mathlib documentation

analysis.complex.basic

Normed space structure on . #

This file gathers basic facts on complex numbers of an analytic nature.

Main results #

This file registers as a normed field, expresses basic properties of the norm, and gives tools on the real vector space structure of . Notably, in the namespace complex, it defines functions:

They are bundled versions of the real part, the imaginary part, the embedding of in , and the complex conjugate as continuous -linear maps. The last two are also bundled as linear isometries in of_real_li and conj_lie.

We also register the fact that is an is_R_or_C field.

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@[protected, instance]
noncomputable def complex.has_norm  :
has_norm
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@[simp]
theorem complex.norm_eq_abs (z : ) :
z = complex.abs z
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theorem complex.norm_exp_of_real_mul_I (t : ) :
cexp (t * complex.I) = 1
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@[protected, instance]
noncomputable def complex.normed_add_comm_group  :
normed_add_comm_group
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@[protected, instance]
noncomputable def complex.normed_field  :
normed_field
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@[protected, instance]
noncomputable def complex.densely_normed_field  :
densely_normed_field
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@[protected, instance]
def complex.normed_algebra {R : Type u_1} [normed_field R] [normed_algebra R ] :
normed_algebra R
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@[protected, instance]
noncomputable def normed_space.complex_to_real {E : Type u_1} [normed_add_comm_group E] [normed_space E] :
normed_space E

The module structure from module.complex_to_real is a normed space.

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theorem complex.dist_eq (z w : ) :
has_dist.dist z w = complex.abs (z - w)
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theorem complex.dist_eq_re_im (z w : ) :
has_dist.dist z w = ((z.re - w.re) ^ 2 + (z.im - w.im) ^ 2)
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@[simp]
theorem complex.dist_mk (x₁ y₁ x₂ y₂ : ) :
has_dist.dist {re := x₁, im := y₁} {re := x₂, im := y₂} = ((x₁ - x₂) ^ 2 + (y₁ - y₂) ^ 2)
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theorem complex.dist_of_re_eq {z w : } (h : z.re = w.re) :
has_dist.dist z w = has_dist.dist z.im w.im
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theorem complex.nndist_of_re_eq {z w : } (h : z.re = w.re) :
has_nndist.nndist z w = has_nndist.nndist z.im w.im
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theorem complex.edist_of_re_eq {z w : } (h : z.re = w.re) :
has_edist.edist z w = has_edist.edist z.im w.im
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theorem complex.dist_of_im_eq {z w : } (h : z.im = w.im) :
has_dist.dist z w = has_dist.dist z.re w.re
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theorem complex.nndist_of_im_eq {z w : } (h : z.im = w.im) :
has_nndist.nndist z w = has_nndist.nndist z.re w.re
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theorem complex.edist_of_im_eq {z w : } (h : z.im = w.im) :
has_edist.edist z w = has_edist.edist z.re w.re
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theorem complex.dist_conj_self (z : ) :
has_dist.dist ((star_ring_end ) z) z = 2 * |z.im|
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theorem complex.nndist_conj_self (z : ) :
has_nndist.nndist ((star_ring_end ) z) z = 2 * real.nnabs z.im
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theorem complex.dist_self_conj (z : ) :
has_dist.dist z ((star_ring_end ) z) = 2 * |z.im|
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theorem complex.nndist_self_conj (z : ) :
has_nndist.nndist z ((star_ring_end ) z) = 2 * real.nnabs z.im
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@[simp]
theorem complex.comap_abs_nhds_zero  :
filter.comap complex.abs (nhds 0) = nhds 0
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theorem complex.norm_real (r : ) :
r = r
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@[simp]
theorem complex.norm_rat (r : ) :
r = |r|
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@[simp]
theorem complex.norm_nat (n : ) :
n = n
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@[simp]
theorem complex.norm_int {n : } :
n = |n|
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theorem complex.norm_int_of_nonneg {n : } (hn : 0 n) :
n = n
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@[continuity]
theorem complex.continuous_abs  :
continuous complex.abs
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@[continuity]
theorem complex.continuous_norm_sq  :
continuous complex.norm_sq
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@[simp, norm_cast]
theorem complex.nnnorm_real (r : ) :
r‖₊ = r‖₊
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@[simp, norm_cast]
theorem complex.nnnorm_nat (n : ) :
n‖₊ = n
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@[simp, norm_cast]
theorem complex.nnnorm_int (n : ) :
n‖₊ = n‖₊
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theorem complex.nnnorm_eq_one_of_pow_eq_one {ζ : } {n : } (h : ζ ^ n = 1) (hn : n 0) :
ζ‖₊ = 1
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theorem complex.norm_eq_one_of_pow_eq_one {ζ : } {n : } (h : ζ ^ n = 1) (hn : n 0) :
ζ = 1
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theorem complex.equiv_real_prod_apply_le (z : ) :
complex.equiv_real_prod z complex.abs z
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theorem complex.equiv_real_prod_apply_le' (z : ) :
complex.equiv_real_prod z 1 * complex.abs z
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theorem complex.lipschitz_equiv_real_prod  :
lipschitz_with 1 complex.equiv_real_prod
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theorem complex.antilipschitz_equiv_real_prod  :
antilipschitz_with (nnreal.sqrt 2) complex.equiv_real_prod
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theorem complex.uniform_embedding_equiv_real_prod  :
uniform_embedding complex.equiv_real_prod
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@[protected, instance]
def complex.complete_space  :
complete_space
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@[simp]
theorem complex.equiv_real_prod_clm_symm_apply_re (ᾰ : × ) :
((complex.equiv_real_prod_clm.symm) ᾰ).re = ᾰ.fst
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noncomputable def complex.equiv_real_prod_clm  :
≃L[] ×

The natural continuous_linear_equiv from to ℝ × ℝ.

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@[simp]
theorem complex.equiv_real_prod_clm_symm_apply_im (ᾰ : × ) :
((complex.equiv_real_prod_clm.symm) ᾰ).im = ᾰ.snd
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@[simp]
theorem complex.equiv_real_prod_clm_apply (ᾰ : ) :
complex.equiv_real_prod_clm = (ᾰ.re, ᾰ.im)
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@[protected, instance]
def complex.proper_space  :
proper_space
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theorem complex.tendsto_abs_cocompact_at_top  :
filter.tendsto complex.abs (filter.cocompact ) filter.at_top

The abs function on is proper.

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theorem complex.tendsto_norm_sq_cocompact_at_top  :
filter.tendsto complex.norm_sq (filter.cocompact ) filter.at_top

The norm_sq function on is proper.

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noncomputable def complex.re_clm  :
→L[]

Continuous linear map version of the real part function, from to .

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@[continuity]
theorem complex.continuous_re  :
continuous complex.re
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@[simp]
theorem complex.re_clm_coe  :
complex.re_clm = complex.re_lm
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@[simp]
theorem complex.re_clm_apply (z : ) :
complex.re_clm z = z.re
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noncomputable def complex.im_clm  :
→L[]

Continuous linear map version of the real part function, from to .

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@[continuity]
theorem complex.continuous_im  :
continuous complex.im
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@[simp]
theorem complex.im_clm_coe  :
complex.im_clm = complex.im_lm
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@[simp]
theorem complex.im_clm_apply (z : ) :
complex.im_clm z = z.im
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theorem complex.restrict_scalars_one_smul_right' {E : Type u_1} [normed_add_comm_group E] [normed_space E] (x : E) :
continuous_linear_map.restrict_scalars (1.smul_right x) = complex.re_clm.smul_right x + complex.I complex.im_clm.smul_right x
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theorem complex.restrict_scalars_one_smul_right (x : ) :
continuous_linear_map.restrict_scalars (1.smul_right x) = x 1
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def complex.conj_lie  :
≃ₗᵢ[]

The complex-conjugation function from to itself is an isometric linear equivalence.

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@[simp]
theorem complex.conj_lie_apply (z : ) :
complex.conj_lie z = (star_ring_end ) z
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@[simp]
theorem complex.conj_lie_symm  :
complex.conj_lie.symm = complex.conj_lie
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theorem complex.isometry_conj  :
isometry (star_ring_end )
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@[simp]
theorem complex.dist_conj_conj (z w : ) :
has_dist.dist ((star_ring_end ) z) ((star_ring_end ) w) = has_dist.dist z w
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@[simp]
theorem complex.nndist_conj_conj (z w : ) :
has_nndist.nndist ((star_ring_end ) z) ((star_ring_end ) w) = has_nndist.nndist z w
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theorem complex.dist_conj_comm (z w : ) :
has_dist.dist ((star_ring_end ) z) w = has_dist.dist z ((star_ring_end ) w)
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theorem complex.nndist_conj_comm (z w : ) :
has_nndist.nndist ((star_ring_end ) z) w = has_nndist.nndist z ((star_ring_end ) w)
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@[protected, instance]
def complex.has_continuous_star  :
has_continuous_star
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@[continuity]
theorem complex.continuous_conj  :
continuous (star_ring_end )
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theorem complex.ring_hom_eq_id_or_conj_of_continuous {f : →+* } (hf : continuous f) :
f = ring_hom.id f = star_ring_end

The only continuous ring homomorphisms from to are the identity and the complex conjugation.

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noncomputable def complex.conj_cle  :
≃L[]

Continuous linear equiv version of the conj function, from to .

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@[simp]
theorem complex.conj_cle_coe  :
complex.conj_cle.to_linear_equiv = complex.conj_ae.to_linear_equiv
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@[simp]
theorem complex.conj_cle_apply (z : ) :
complex.conj_cle z = (star_ring_end ) z
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def complex.of_real_li  :
→ₗᵢ[]

Linear isometry version of the canonical embedding of in .

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theorem complex.isometry_of_real  :
isometry coe
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@[continuity]
theorem complex.continuous_of_real  :
continuous coe
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theorem complex.ring_hom_eq_of_real_of_continuous {f : →+* } (h : continuous f) :
f = complex.of_real

The only continuous ring homomorphism from to is the identity.

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noncomputable def complex.of_real_clm  :
→L[]

Continuous linear map version of the canonical embedding of in .

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@[simp]
theorem complex.of_real_clm_coe  :
complex.of_real_clm = complex.of_real_am.to_linear_map
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@[simp]
theorem complex.of_real_clm_apply (x : ) :
complex.of_real_clm x = x
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@[protected, instance]
noncomputable def complex.is_R_or_C  :
is_R_or_C
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theorem is_R_or_C.re_eq_complex_re  :
is_R_or_C.re = complex.re
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theorem is_R_or_C.im_eq_complex_im  :
is_R_or_C.im = complex.im
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theorem complex.eq_coe_norm_of_nonneg {z : } (hz : 0 z) :
z = z
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@[simp]
theorem is_R_or_C.re_to_complex {x : } :
is_R_or_C.re x = x.re
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@[simp]
theorem is_R_or_C.im_to_complex {x : } :
is_R_or_C.im x = x.im
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@[simp]
theorem is_R_or_C.I_to_complex  :
is_R_or_C.I = complex.I
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@[simp]
theorem is_R_or_C.norm_sq_to_complex {x : } :
is_R_or_C.norm_sq x = complex.norm_sq x
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@[simp]
theorem is_R_or_C.abs_to_complex {x : } :
is_R_or_C.abs x = complex.abs x
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@[simp]
theorem is_R_or_C.has_sum_conj {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] {f : α 𝕜} {x : 𝕜} :
has_sum (λ (x : α), (star_ring_end 𝕜) (f x)) x has_sum f ((star_ring_end 𝕜) x)
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theorem is_R_or_C.has_sum_conj' {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] {f : α 𝕜} {x : 𝕜} :
has_sum (λ (x : α), (star_ring_end 𝕜) (f x)) ((star_ring_end 𝕜) x) has_sum f x
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@[simp]
theorem is_R_or_C.summable_conj {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] {f : α 𝕜} :
summable (λ (x : α), (star_ring_end 𝕜) (f x)) summable f
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theorem is_R_or_C.conj_tsum {α : Type u_1} {𝕜 : Type u_2} [is_R_or_C 𝕜] (f : α 𝕜) :
(star_ring_end 𝕜) (∑' (a : α), f a) = ∑' (a : α), (star_ring_end 𝕜) (f a)
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@[simp, norm_cast]
theorem is_R_or_C.has_sum_of_real {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] {f : α } {x : } :
has_sum (λ (x : α), (f x)) x has_sum f x
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@[simp, norm_cast]
theorem is_R_or_C.summable_of_real {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] {f : α } :
summable (λ (x : α), (f x)) summable f
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@[norm_cast]
theorem is_R_or_C.of_real_tsum {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] (f : α ) :
∑' (a : α), f a = ∑' (a : α), (f a)
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theorem is_R_or_C.has_sum_re {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] {f : α 𝕜} {x : 𝕜} (h : has_sum f x) :
has_sum (λ (x : α), is_R_or_C.re (f x)) (is_R_or_C.re x)
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theorem is_R_or_C.has_sum_im {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] {f : α 𝕜} {x : 𝕜} (h : has_sum f x) :
has_sum (λ (x : α), is_R_or_C.im (f x)) (is_R_or_C.im x)
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theorem is_R_or_C.re_tsum {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] {f : α 𝕜} (h : summable f) :
is_R_or_C.re (∑' (a : α), f a) = ∑' (a : α), is_R_or_C.re (f a)
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theorem is_R_or_C.im_tsum {α : Type u_1} (𝕜 : Type u_2) [is_R_or_C 𝕜] {f : α 𝕜} (h : summable f) :
is_R_or_C.im (∑' (a : α), f a) = ∑' (a : α), is_R_or_C.im (f a)
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theorem is_R_or_C.has_sum_iff {α : Type u_1} {𝕜 : Type u_2} [is_R_or_C 𝕜] (f : α 𝕜) (c : 𝕜) :
has_sum f c has_sum (λ (x : α), is_R_or_C.re (f x)) (is_R_or_C.re c) has_sum (λ (x : α), is_R_or_C.im (f x)) (is_R_or_C.im c)

We have to repeat the lemmas about is_R_or_C.re and is_R_or_C.im as they are not syntactic matches for complex.re and complex.im.

We do not have this problem with of_real and conj, although we repeat them anyway for discoverability and to avoid the need to unify 𝕜.

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@[simp]
theorem complex.has_sum_conj {α : Type u_1} {f : α } {x : } :
has_sum (λ (x : α), (star_ring_end ) (f x)) x has_sum f ((star_ring_end ) x)
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theorem complex.has_sum_conj' {α : Type u_1} {f : α } {x : } :
has_sum (λ (x : α), (star_ring_end ) (f x)) ((star_ring_end ) x) has_sum f x
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@[simp]
theorem complex.summable_conj {α : Type u_1} {f : α } :
summable (λ (x : α), (star_ring_end ) (f x)) summable f
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theorem complex.conj_tsum {α : Type u_1} (f : α ) :
(star_ring_end ) (∑' (a : α), f a) = ∑' (a : α), (star_ring_end ) (f a)
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@[simp, norm_cast]
theorem complex.has_sum_of_real {α : Type u_1} {f : α } {x : } :
has_sum (λ (x : α), (f x)) x has_sum f x
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@[simp, norm_cast]
theorem complex.summable_of_real {α : Type u_1} {f : α } :
summable (λ (x : α), (f x)) summable f
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@[norm_cast]
theorem complex.of_real_tsum {α : Type u_1} (f : α ) :
∑' (a : α), f a = ∑' (a : α), (f a)
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theorem complex.has_sum_re {α : Type u_1} {f : α } {x : } (h : has_sum f x) :
has_sum (λ (x : α), (f x).re) x.re
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theorem complex.has_sum_im {α : Type u_1} {f : α } {x : } (h : has_sum f x) :
has_sum (λ (x : α), (f x).im) x.im
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theorem complex.re_tsum {α : Type u_1} {f : α } (h : summable f) :
(∑' (a : α), f a).re = ∑' (a : α), (f a).re
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theorem complex.im_tsum {α : Type u_1} {f : α } (h : summable f) :
(∑' (a : α), f a).im = ∑' (a : α), (f a).im
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theorem complex.has_sum_iff {α : Type u_1} (f : α ) (c : ) :
has_sum f c has_sum (λ (x : α), (f x).re) c.re has_sum (λ (x : α), (f x).im) c.im