Normed space structure on ℂ. #
This file gathers basic facts on complex numbers of an analytic nature.
Main results #
This file registers ℂ as a normed field, expresses basic properties of the norm, and gives
tools on the real vector space structure of ℂ. Notably, in the namespace complex,
it defines functions:
re_clmim_clmof_real_clmconj_cle
They are bundled versions of the real part, the imaginary part, the embedding of ℝ in ℂ, and
the complex conjugate as continuous ℝ-linear maps. The last two are also bundled as linear
isometries in of_real_li and conj_lie.
We also register the fact that ℂ is an is_R_or_C field.
@[protected, instance]
Equations
@[protected, instance]
Equations
- complex.normed_add_comm_group = {to_fun := complex.abs.to_mul_hom.to_fun, map_zero' := complex.normed_add_comm_group._proof_1, add_le' := complex.normed_add_comm_group._proof_2, neg' := complex.normed_add_comm_group._proof_3, eq_zero_of_map_eq_zero' := complex.normed_add_comm_group._proof_4}.to_normed_add_comm_group
@[protected, instance]
Equations
- complex.normed_field = {to_has_norm := {norm := ⇑complex.abs}, to_field := {add := field.add complex.field, add_assoc := _, zero := field.zero complex.field, zero_add := _, add_zero := _, nsmul := field.nsmul complex.field, nsmul_zero' := _, nsmul_succ' := _, neg := field.neg complex.field, sub := field.sub complex.field, sub_eq_add_neg := _, zsmul := field.zsmul complex.field, zsmul_zero' := _, zsmul_succ' := _, zsmul_neg' := _, add_left_neg := _, add_comm := _, int_cast := field.int_cast complex.field, nat_cast := field.nat_cast complex.field, one := field.one complex.field, nat_cast_zero := _, nat_cast_succ := _, int_cast_of_nat := _, int_cast_neg_succ_of_nat := _, mul := field.mul complex.field, mul_assoc := _, one_mul := _, mul_one := _, npow := field.npow complex.field, npow_zero' := _, npow_succ' := _, left_distrib := _, right_distrib := _, mul_comm := _, inv := field.inv complex.field, div := field.div complex.field, div_eq_mul_inv := _, zpow := field.zpow complex.field, zpow_zero' := _, zpow_succ' := _, zpow_neg' := _, exists_pair_ne := _, rat_cast := field.rat_cast complex.field, mul_inv_cancel := _, inv_zero := _, rat_cast_mk := _, qsmul := field.qsmul complex.field, qsmul_eq_mul' := _}, to_metric_space := normed_add_comm_group.to_metric_space complex.normed_add_comm_group, dist_eq := complex.normed_field._proof_1, norm_mul' := complex.normed_field._proof_2}
@[protected, instance]
Equations
- complex.densely_normed_field = {to_normed_field := complex.normed_field, lt_norm_lt := complex.densely_normed_field._proof_1}
@[protected, instance]
Equations
@[protected, instance]
noncomputable
def
normed_space.complex_to_real
{E : Type u_1}
[normed_add_comm_group E]
[normed_space ℂ E] :
The module structure from module.complex_to_real is a normed space.
Equations
theorem
complex.dist_of_re_eq
{z w : ℂ}
(h : z.re = w.re) :
has_dist.dist z w = has_dist.dist z.im w.im
theorem
complex.nndist_of_re_eq
{z w : ℂ}
(h : z.re = w.re) :
has_nndist.nndist z w = has_nndist.nndist z.im w.im
theorem
complex.edist_of_re_eq
{z w : ℂ}
(h : z.re = w.re) :
has_edist.edist z w = has_edist.edist z.im w.im
theorem
complex.dist_of_im_eq
{z w : ℂ}
(h : z.im = w.im) :
has_dist.dist z w = has_dist.dist z.re w.re
theorem
complex.nndist_of_im_eq
{z w : ℂ}
(h : z.im = w.im) :
has_nndist.nndist z w = has_nndist.nndist z.re w.re
theorem
complex.edist_of_im_eq
{z w : ℂ}
(h : z.im = w.im) :
has_edist.edist z w = has_edist.edist z.re w.re
theorem
complex.nndist_conj_self
(z : ℂ) :
has_nndist.nndist (⇑(star_ring_end ℂ) z) z = 2 * ⇑real.nnabs z.im
theorem
complex.nndist_self_conj
(z : ℂ) :
has_nndist.nndist z (⇑(star_ring_end ℂ) z) = 2 * ⇑real.nnabs z.im
The abs function on ℂ is proper.
The norm_sq function on ℂ is proper.
Continuous linear map version of the real part function, from ℂ to ℝ.
Equations
- complex.re_clm = complex.re_lm.mk_continuous 1 complex.re_clm._proof_1
Continuous linear map version of the real part function, from ℂ to ℝ.
Equations
- complex.im_clm = complex.im_lm.mk_continuous 1 complex.im_clm._proof_1
theorem
complex.restrict_scalars_one_smul_right'
{E : Type u_1}
[normed_add_comm_group E]
[normed_space ℂ E]
(x : E) :
theorem
complex.restrict_scalars_one_smul_right
(x : ℂ) :
continuous_linear_map.restrict_scalars ℝ (1.smul_right x) = x • 1
The complex-conjugation function from ℂ to itself is an isometric linear equivalence.
Equations
@[simp]
theorem
complex.dist_conj_conj
(z w : ℂ) :
has_dist.dist (⇑(star_ring_end ℂ) z) (⇑(star_ring_end ℂ) w) = has_dist.dist z w
@[simp]
theorem
complex.nndist_conj_conj
(z w : ℂ) :
has_nndist.nndist (⇑(star_ring_end ℂ) z) (⇑(star_ring_end ℂ) w) = has_nndist.nndist z w
theorem
complex.dist_conj_comm
(z w : ℂ) :
has_dist.dist (⇑(star_ring_end ℂ) z) w = has_dist.dist z (⇑(star_ring_end ℂ) w)
theorem
complex.nndist_conj_comm
(z w : ℂ) :
has_nndist.nndist (⇑(star_ring_end ℂ) z) w = has_nndist.nndist z (⇑(star_ring_end ℂ) w)
@[simp]
The determinant of conj_lie, as a linear map.
@[simp]
The determinant of conj_lie, as a linear equiv.
theorem
complex.ring_hom_eq_id_or_conj_of_continuous
{f : ℂ →+* ℂ}
(hf : continuous ⇑f) :
f = ring_hom.id ℂ ∨ f = star_ring_end ℂ
The only continuous ring homomorphisms from ℂ to ℂ are the identity and the complex
conjugation.
Continuous linear equiv version of the conj function, from ℂ to ℂ.
Equations
@[simp]
Linear isometry version of the canonical embedding of ℝ in ℂ.
Equations
The only continuous ring homomorphism from ℝ to ℂ is the identity.
Continuous linear map version of the canonical embedding of ℝ in ℂ.
@[simp]
@[protected, instance]
Equations
- complex.is_R_or_C = {to_densely_normed_field := complex.densely_normed_field, to_star_ring := complex.star_ring, to_normed_algebra := complex.normed_algebra (normed_algebra.id ℝ), to_complete_space := complex.is_R_or_C._proof_1, re := {to_fun := complex.re, map_zero' := complex.zero_re, map_add' := complex.add_re}, im := {to_fun := complex.im, map_zero' := complex.zero_im, map_add' := complex.add_im}, I := complex.I, I_re_ax := complex.is_R_or_C._proof_2, I_mul_I_ax := complex.is_R_or_C._proof_3, re_add_im_ax := complex.is_R_or_C._proof_4, of_real_re_ax := complex.is_R_or_C._proof_5, of_real_im_ax := complex.is_R_or_C._proof_6, mul_re_ax := complex.is_R_or_C._proof_7, mul_im_ax := complex.is_R_or_C._proof_8, conj_re_ax := complex.is_R_or_C._proof_9, conj_im_ax := complex.is_R_or_C._proof_10, conj_I_ax := complex.is_R_or_C._proof_11, norm_sq_eq_def_ax := complex.is_R_or_C._proof_12, mul_im_I_ax := complex.is_R_or_C._proof_13, inv_def_ax := complex.is_R_or_C._proof_14, div_I_ax := complex.div_I}
The natural add_equiv from ℂ to ℝ × ℝ.
Equations
- complex.equiv_real_prod_add_hom = {to_fun := complex.equiv_real_prod.to_fun, inv_fun := complex.equiv_real_prod.inv_fun, left_inv := complex.equiv_real_prod_add_hom._proof_1, right_inv := complex.equiv_real_prod_add_hom._proof_2, map_add' := complex.equiv_real_prod_add_hom._proof_3}
@[simp]
theorem
complex.equiv_real_prod_add_hom_apply
(ᾰ : ℂ) :
⇑complex.equiv_real_prod_add_hom ᾰ = (ᾰ.re, ᾰ.im)
The natural linear_equiv from ℂ to ℝ × ℝ.
Equations
- complex.equiv_real_prod_add_hom_lm = {to_fun := complex.equiv_real_prod_add_hom.to_fun, map_add' := complex.equiv_real_prod_add_hom_lm._proof_1, map_smul' := complex.equiv_real_prod_add_hom_lm._proof_2, inv_fun := complex.equiv_real_prod_add_hom.inv_fun, left_inv := complex.equiv_real_prod_add_hom_lm._proof_3, right_inv := complex.equiv_real_prod_add_hom_lm._proof_4}
@[simp]
theorem
complex.equiv_real_prod_add_hom_lm_apply
(ᾰ : ℂ) :
⇑complex.equiv_real_prod_add_hom_lm ᾰ = (ᾰ.re, ᾰ.im)
The natural continuous_linear_equiv from ℂ to ℝ × ℝ.
@[simp]
@[simp]