class Field (R : Type) where zero : R one : R add : R → R → R mul : R → R → R opp : R → R add_comm : ∀ x y, add x y = add y x add_assoc : ∀ x y z, add (add x y) z = add x (add y z) add_zero : ∀ x, add x zero = x add_opp : ∀ x, add x (opp x) = zero mul_comm : ∀ x y, mul x y = mul y x mul_assoc : ∀ x y z, mul (mul x y) z = mul x (mul y z) mul_one : ∀ x, mul x one = x dist_l : ∀ a x y, mul a (add x y) = add (mul a x) (mul a y) namespace Lin variable {R : Type} [FR : Field R] open Field infixl:65 "+R" => Field.add infixl:70 "*R" => Field.mul prefix:100 "-R" => Field.opp class VSpace (R : Type) [Field R] (V : Type) where zeroV : V addV : V → V → V oppV : V → V smul : R → V → V addV_comm : ∀ u v, addV u v = addV v u addV_assoc : ∀ u v w, addV (addV u v) w = addV u (addV v w) addV_zero : ∀ u, addV u zeroV = u addV_opp : ∀ u, addV u (oppV u) = zeroV smul_addV : ∀ a u v, smul a (addV u v) = addV (smul a u) (smul a v) addR_smul : ∀ a b u, smul (a +R b) u = addV (smul a u) (smul b u) mul_smul : ∀ a b u, smul (a *R b) u = smul a (smul b u) one_smul : ∀ u, smul Field.one u = u smul_zero : ∀ a, smul a zeroV = zeroV attribute [simp] VSpace.addV_zero VSpace.smul_zero infixl:65 "+V" => VSpace.addV notation:70 a " •V " u => VSpace.smul a u structure LMap (V W : Type) [VSpace R V] [VSpace R W] where toFun : V → W map_add : ∀ u v, toFun (VSpace.addV (R:=R) u v) = VSpace.addV (R:=R) (toFun u) (toFun v) map_smul : ∀ a u, toFun (VSpace.smul (R:=R) a u) = VSpace.smul (R:=R) a (toFun u) attribute [simp] LMap.map_add LMap.map_smul variable {V W U : Type} variable [VSpace R V] [VSpace R W] [VSpace R U] def ker (L : LMap (R:=R) V W) : V → Prop := fun x => L.toFun x = VSpace.zeroV (R:=R) def im (L : LMap (R:=R) V W) : W → Prop := fun y => ∃ x, L.toFun x = y def comp (g : LMap (R:=R) W U) (f : LMap (R:=R) V W) : LMap (R:=R) V U := { toFun := fun x => g.toFun (f.toFun x) , map_add := by intro u v simp , map_smul := by intro a u simp } theorem ker_add {L : LMap (R:=R) V W} {x y : V} : ker L x → ker L y → ker L (VSpace.addV (R:=R) x y) := by intro hx hy unfold ker at hx hy ⊢ simp [hx, hy] theorem ker_smul {L : LMap (R:=R) V W} {a : R} {x : V} : ker L x → ker L (VSpace.smul (R:=R) a x) := by intro hx unfold ker at * simp [hx] theorem im_add {L : LMap (R:=R) V W} {y z : W} : im L y → im L z → im L (VSpace.addV (R:=R) y z) := by intro hy hz rcases hy with ⟨x, rfl⟩ rcases hz with ⟨x', rfl⟩ refine ⟨VSpace.addV (R:=R) x x', ?_⟩ simp theorem im_smul {L : LMap (R:=R) V W} {a : R} {y : W} : im L y → im L (VSpace.smul (R:=R) a y) := by intro hy; rcases hy with ⟨x, rfl⟩ refine ⟨VSpace.smul (R:=R) a x, ?_⟩ simp end Lin