Split (2)

validation · 185 rows

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Pugh\|exercise_2_41	Let $\\|\cdot\\|$ be any norm on $\mathbb{R}^{m}$ and let $B=\left\{x \in \mathbb{R}^{m}:\\|x\\| \leq 1\right\}$. Prove that $B$ is compact.	\begin{proof} Let us call $\\|\cdot\\|_E$ the Euclidean norm in $\mathbb{R}^m$. We start by claiming that there exist constants $C_1, C_2>0$ such that $$ C_1\\|x\\|_E \leq\\|x\\| \leq C_2\\|x\\|_E, \forall x \in \mathbb{R}^m . $$ Assuming (1) to be true, let us finish the problem. First let us show that $B$ is bounded w.r.t. $d_E$, which is how we call the Euclidean distance in $\mathbb{R}^m$. Indeed, given $x \in B,\\|x\\|_E \leq \frac{1}{C_1}\\|x\\| \leq \frac{1}{C_1}$. Hence $B \subset\left\{x \in \mathbb{R}^m: d_E(x, 0)<\frac{1}{C_1}+1\right\}$, which means $B$ is bounded w.r.t $d_E$. Now let us show that $B$ is closed w.r.t. $d_E$. Let $x_n \rightarrow x$ w.r.t. $d_E$, where $x_n \in B$. Notice that this implies that $x_n \rightarrow x$ w.r.t. $d(x, y)=\\|x-y\\|$, the distance coming from $\\|\cdot\\|$, since by (1) we have $$ d\left(x_n, x\right)=\left\\|x_n-x\right\\| \leq C_2\left\\|x_n-x\right\\|_E \rightarrow 0 . $$ Also, notice that $$ \\|x\\| \leq\left\\|x_n-x\right\\|+\left\\|x_n\right\\| \leq\left\\|x_n-x\right\\|+1, $$ hence passing to the limit we obtain that $\\|x\\| \leq 1$, therefore $x \in B$ and so $B$ is closed w.r.t. $d_E$. Since $B$ is closed and bounded w.r.t. $d_E$, it must be compact. Now we claim that the identity function, $i d:\left(\mathbb{R}^m, d_E\right) \rightarrow\left(\mathbb{R}^m, d\right)$ where $\left(\mathbb{R}^m, d_E\right)$ means we are using the distance $d_E$ in $\mathbb{R}^m$ and $\left(\mathbb{R}^m, d\right)$ means we are using the distance $d$ in $\mathbb{R}^m$, is a homeomorphism. This follows by (1), since $i d$ is always a bijection, and it is continuous and its inverse is continuous by (1) (if $x_n \rightarrow x$ w.r.t. $d_E$, then $x_n \rightarrow x$ w.r.t. $d$ and vice-versa, by (1)). By a result we saw in class, since $B$ is compact in $\left(\mathbb{R}^m, d_E\right)$ and $i d$ is a homeomorphism, then $i d(B)=B$ is compact w.r.t. $d$. We are left with proving (1). Notice that it suffices to prove that $C_1 \leq\\|x\\| \leq$ $C_2, \forall x \in \mathbb{R}^m$ with $\\|x\\|_E=1$. Indeed, if this is true, given $x \in \mathbb{R}^m$, either $\\|x\\|_E=0$ (which implies $x=0$ and (1) holds in this case), or $x /\\|x\\|_E=y$ is such that $\\|y\\|_E=1$, so $C_1 \leq\\|y\\| \leq C_2$, which implies $C_1\\|x\\|_E \leq\\|x\\| \leq C_2\\|x\\|_E$. We want to show now that $\\|\cdot\\|$ is continuous w.r.t. $d_E$, that is, given $\varepsilon>0$ and $x \in \mathbb{R}^m$, there exists $\delta>0$ such that if $d_E(x, y)<\delta$, then $\\|\mid x\\|-\\|y\\| \\|<\varepsilon$. By the triangle inequality, $\\|x\\|-\\|y\\| \leq\\|x-y\\|$, and $\\|y\\|-\\|x\\| \leq\\|x-y\\|$, therefore $$ \|\\|x\|\|-\\| y\|\\|\leq\\| x-y \\| . $$ Writing now $x=\sum_{i=1}^m a_i e_i, y=\sum_{i=1}^m b_i e_i$, where $e_i=(0, \ldots, 1,0, \ldots, 0)$ (with 1 in the i-th component), we obtain by the triangle inequality, $$ \begin{aligned} \\|x-y\\| & =\left\\|\sum_{i=1}^m\left(a_i-b_i\right) e_i\right\\| \leq \sum_{i=1}^m\left\|a_i-b_i\left\\|\left\|\left\\|e_i\right\\| \leq \max _{i=1, \ldots, m}\left\\|e_i\right\\| \sum_{i=1}^m\right\| a_i-b_i \mid\right.\right. \\ & =\max _{i=1, \ldots, m}\left\\|e_i\right\\| d_{s u m}(x, y) \leq \max _{i=1, \ldots, m}\left\\|e_i\right\\| m d_{\max }(x, y) \\ & \leq \max _{i=1, \ldots, m}\left\\|e_i\right\\| m d_E(x, y) . \end{aligned} $$ Let $\delta=\frac{\varepsilon}{m \max _{i=1, \ldots, m}\left\\|e_i\right\\|}$. Then if $d_E(x, y)<\delta,\\|x\\|-\\|y\\|\|\|<\varepsilon$. Since $\\|\cdot\\|$ is continuous w.r.t. $d_E$ and $K=\left\{x \in \mathbb{R}^m:\\|x\\|_E=1\right\}$ is compact w.r.t. $d_E$, then the function $\\|\cdot\\|$ achieves a maximum and a minimum value on $K$. Call $C_1=\min _{x \in K}\\|x\\|, C_2=\max _{x \in K}\\|x\\|$. Then $$ C_1 \leq\\|x\\| \leq C_2, \forall x \in \mathbb{R}^m \text { such that }\\|x\\|_E=1, $$ which is what we needed. \end{proof}	theorem exercise_2_41 (m : ℕ) {X : Type*} [normed_space ℝ ((fin m) → ℝ)] : is_compact (metric.closed_ball 0 1) :=	import .common open set real filter function ring_hom topological_space open_locale big_operators open_locale filter open_locale topology noncomputable theory
Pugh\|exercise_2_57	Show that if $S$ is connected, it is not true in general that its interior is connected.	\begin{proof} Consider $X=\mathbb{R}^2$ and $$ A=([-2,0] \times[-2,0]) \cup([0,2] \times[0,2]) $$ which is connected, while $\operatorname{int}(A)$ is not connected. To see this consider the continuous function $f: \mathbb{R}^2 \rightarrow \mathbb{R}$ is defined by $f(x, y)=x+y$. Let $U=f^{-1}(0,+\infty)$ which is open in $\mathbb{R}^2$ and so $U \cap \operatorname{int}(A)$ is open in $\operatorname{int}(A)$. Also, since $(0,0) \notin \operatorname{int}(A)$, so for all $(x, y) \in \operatorname{int}(A), f(x, y) \neq 0$ and $U \cap \operatorname{int}(A)=f^{-1}[0,+\infty) \cap \operatorname{int}(A)$ is closed in $\operatorname{int}(A)$. Furthermore, $(1,1)=f^{-1}(2) \in U \cap \operatorname{int}(A)$ shows that $U \cap \operatorname{int}(A) \neq \emptyset$ while $(-1,-1) \in \operatorname{int}(A)$ and $(-1,-1) \notin U$ shows that $U \cap \operatorname{int}(A) \neq \operatorname{int}(A)$. \end{proof}	theorem exercise_2_57 {X : Type*} [topological_space X] : ∃ (S : set X), is_connected S ∧ ¬ is_connected (interior S) :=	import .common open set real filter function ring_hom topological_space open_locale big_operators open_locale filter open_locale topology noncomputable theory
Pugh\|exercise_2_126	Suppose that $E$ is an uncountable subset of $\mathbb{R}$. Prove that there exists a point $p \in \mathbb{R}$ at which $E$ condenses.	\begin{proof} I think this is the proof by contrapositive that you were getting at. Suppose that $E$ has no limit points at all. Pick an arbitrary point $x \in E$. Then $x$ cannot be a limit point, so there must be some $\delta>0$ such that the ball of radius $\delta$ around $x$ contains no other points of $E$ : $$ B_\delta(x) \cap E=\{x\} $$ Call this "point 1 ". For the next point, take the closest element to $x$ and on its left; that is, choose the point $$ \max [E \cap(-\infty, x)] $$ if it exists (that is important - if not, skip to the next step). Note that by the argument above, this supremum, should it exist, cannot equal $x$ and is therefore a new point in $E$. Call this "point 2 ". Now take the first point to the right of $x$ for "point 3 ". Take the first point to the left of point 2 for "point 4 ". And so on, ad infinitum. This gives a countable list of unique points; we must show that it exhausts the entire set $E$. Suppose not. Suppose there is some element $a<x$ which is never included in the list (picking $a$ on the negative side of $x$ is arbitrary, and the same argument would work for the second case). Then the element closest and to the right of $a$ in $E$ (which exists, by the no-limit-points argument at the beginning) is also not in the list; if it was, $a$ would have been in one of the next two spots. And same with that point (call it $a_1$ ); there is a closest $a_2>a_1 \in E$ such that $a_2$ is not in the list. Repeating, we generate an infinite monotone-increasing sequence $\left\{a_i\right\}$ of elements in $E$ and not in the list, which is clearly bounded above by $x$. By the Monotone Convergence Theorem this sequence has a limit. But that means the sequence $\left\{a_i\right\} \subset E$ converges to a limit, and hence $E$ has a limit point, contradicting the assumption. Therefore our list exhausts $E$, and we have enumerated all its elements. \end{proof}	theorem exercise_2_126 {E : set ℝ} (hE : ¬ set.countable E) : ∃ (p : ℝ), cluster_pt p (𝓟 E) :=	import .common open set real filter function ring_hom topological_space open_locale big_operators open_locale filter open_locale topology noncomputable theory
Pugh\|exercise_3_4	Prove that $\sqrt{n+1}-\sqrt{n} \rightarrow 0$ as $n \rightarrow \infty$.	\begin{proof} $$ \sqrt{n+1}-\sqrt{n}=\frac{(\sqrt{n+1}-\sqrt{n})(\sqrt{n+1}+\sqrt{n})}{\sqrt{n+1}+\sqrt{n}}=\frac{1}{\sqrt{n+1}+\sqrt{n}}<\frac{1}{2 \sqrt{n}} $$ \end{proof}	theorem exercise_3_4 (n : ℕ) : tendsto (λ n, (sqrt (n + 1) - sqrt n)) at_top (𝓝 0) :=	import .common open set real filter function ring_hom topological_space open_locale big_operators open_locale filter open_locale topology noncomputable theory
Pugh\|exercise_3_63b	Prove that $\sum 1/k(\log(k))^p$ diverges when $p \leq 1$.	\begin{proof} Using the integral test, for a set $a$, we see $$ \lim _{b \rightarrow \infty} \int_a^b \frac{1}{x \log (x)^c} d x=\lim _{b \rightarrow \infty}\left(\frac{\log (b)^{1-c}}{1-c}-\frac{\log (a)^{1-c}}{1-c}\right) $$ which goes to infinity if $c \leq 1$ and converges if $c>1$. Thus, $$ \sum_{n=2}^{\infty} \frac{1}{n \log (n)^c} $$ converges if and only if $c>1$. \end{proof}	theorem exercise_3_63b (p : ℝ) (f : ℕ → ℝ) (hp : p ≤ 1) (h : f = λ k, (1 : ℝ) / (k * (log k) ^ p)) : ¬ ∃ l, tendsto f at_top (𝓝 l) :=	import .common open set real filter function ring_hom topological_space open_locale big_operators open_locale filter open_locale topology noncomputable theory
Herstein\|exercise_2_1_21	Show that a group of order 5 must be abelian.	\begin{proof} Suppose $G$ is a group of order 5 which is not abelian. Then there exist two non-identity elements $a, b \in G$ such that $a * b \neq$ $b * a$. Further we see that $G$ must equal $\{e, a, b, a * b, b * a\}$. To see why $a * b$ must be distinct from all the others, not that if $a $ $b=e$, then $a$ and $b$ are inverses and hence $a b=b * a$. Contradiction. If $a * b=a$ (or $=b$ ), then $b=e$ (or $a=e$ ) and $e$ commutes with everything. Contradiction. We know by supposition that $a * b \neq b * a$. Hence all the elements $\{e, a, b, a * b, b * a\}$ are distinct. Now consider $a^2$. It can't equal $a$ as then $a=e$ and it can't equal $a * b$ or $b * a$ as then $b=a$. Hence either $a^2=e$ or $a^2=b$. Now consider $a * b * a$. It can't equal $a$ as then $b * a=e$ and hence $a * b=b * a$. Similarly it can't equal $b$. It also can't equal $a * b$ or $b * a$ as then $a=e$. Hence $a * b * a=e$. So then we additionally see that $a^2 \neq e$ because then $a^2=e=$ $a * b * a$ and consequently $a=b * a$ (and hence $b=e$ ). So $a^2=b$. But then $a * b=a * a^2=a^2 * a=b * a$. Contradiction. Hence starting with the assumption that there exists an order 5 abelian group $G$ leads to a contradiction. Thus there is no such group. \end{proof}	theorem exercise_2_1_21 (G : Type*) [group G] [fintype G] (hG : card G = 5) : comm_group G :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_1_27	If $G$ is a finite group, prove that there is an integer $m > 0$ such that $a^m = e$ for all $a \in G$.	\begin{proof} Let $n_1, n_2, \ldots, n_k$ be the orders of all $k$ elements of $G=$ $\left\{a_1, a_2, \ldots, a_k\right\}$. Let $m=\operatorname{lcm}\left(n_1, n_2, \ldots, n_k\right)$. Then, for any $i=$ $1, \ldots, k$, there exists an integer $c$ such that $m=n_i c$. Thus $$ a_i^m=a_i^{n_i c}=\left(a_i^{n_i}\right)^c=e^c=e $$ Hence $m$ is a positive integer such that $a^m=e$ for all $a \in G$. \end{proof}	theorem exercise_2_1_27 {G : Type*} [group G] [fintype G] : ∃ (m : ℕ), ∀ (a : G), a ^ m = 1 :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_2_5	Let $G$ be a group in which $(a b)^{3}=a^{3} b^{3}$ and $(a b)^{5}=a^{5} b^{5}$ for all $a, b \in G$. Show that $G$ is abelian.	\begin{proof} We have $$ \begin{aligned} & (a b)^3=a^3 b^3, \text { for all } a, b \in G \\ \Longrightarrow & (a b)(a b)(a b)=a\left(a^2 b^2\right) b \\ \Longrightarrow & a(b a)(b a) b=a\left(a^2 b^2\right) b \\ \Longrightarrow & (b a)^2=a^2 b^2, \text { by cancellation law. } \end{aligned} $$ Again, $$ \begin{aligned} & (a b)^5=a^5 b^5, \text { for all } a, b \in G \\ \Longrightarrow & (a b)(a b)(a b)(a b)(a b)=a\left(a^4 b^4\right) b \\ \Longrightarrow & a(b a)(b a)(b a)(b a) b=a\left(a^4 b^4\right) b \\ \Longrightarrow & (b a)^4=a^4 b^4, \text { by cancellation law. } \end{aligned} $$ Now by combining two cases we have $$ \begin{aligned} & (b a)^4=a^4 b^4 \\ \Longrightarrow & \left((b a)^2\right)^2=a^2\left(a^2 b^2\right) b^2 \\ \Longrightarrow & \left(a^2 b^2\right)^2=a^2\left(a^2 b^2\right) b^2 \\ \Longrightarrow & \left(a^2 b^2\right)\left(a^2 b^2\right)=a^2\left(a^2 b^2\right) b^2 \\ \Longrightarrow & a^2\left(b^2 a^2\right) b^2=a^2\left(a^2 b^2\right) b^2 \\ \Longrightarrow & b^2 a^2=a^2 b^2, \text { by cancellation law. } \\ \Longrightarrow & b^2 a^2=(b a)^2, \text { since }(b a)^2=a^2 b^2 \\ \Longrightarrow & b(b a) a=(b a)(b a) \\ \Longrightarrow & b(b a) a=b(a b) a \\ \Longrightarrow & b a=a b, \text { by cancellation law. } \end{aligned} $$ It follows that, $a b=b a$ for all $a, b \in G$. Hence $G$ is abelian \end{proof}	theorem exercise_2_2_5 {G : Type} [group G] (h : ∀ (a b : G), (a b) ^ 3 = a ^ 3 * b ^ 3 ∧ (a * b) ^ 5 = a ^ 5 * b ^ 5) : comm_group G :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_3_17	If $G$ is a group and $a, x \in G$, prove that $C\left(x^{-1} a x\right)=x^{-1} C(a) x$	\begin{proof} Note that $$ C(a):=\{x \in G \mid x a=a x\} . $$ Let us assume $p \in C\left(x^{-1} a x\right)$. Then, $$ \begin{aligned} & p\left(x^{-1} a x\right)=\left(x^{-1} a x\right) p \\ \Longrightarrow & \left(p x^{-1} a\right) x=x^{-1}(a x p) \\ \Longrightarrow & x\left(p x^{-1} a\right)=(a x p) x^{-1} \\ \Longrightarrow & \left(x p x^{-1}\right) a=a\left(x p x^{-1}\right) \\ \Longrightarrow & x p x^{-1} \in C(a) . \end{aligned} $$ Therefore, $$ p \in C\left(x^{-1} a x\right) \Longrightarrow x p x^{-1} \in C(a) . $$ Thus, $$ C\left(x^{-1} a x\right) \subset x^{-1} C(a) x . $$ Let us assume $$ q \in x^{-1} C(a) x . $$ Then there exists an element $y$ in $C(a)$ such that $$ q=x^{-1} y x $$ Now, $$ y \in C(a) \Longrightarrow y a=a y . $$ Also, $$ q\left(x^{-1} a x\right)=\left(x^{-1} y x\right)\left(x^{-1} a x\right)=x^{-1}(y a) x=x^{-1}(y a) x=\left(x^{-1} y x\right)\left(x^{-1} a x\right)=\left(x^{-1} y x\right) q . $$ Therefore, $$ q\left(x^{-1} a x\right)=\left(x^{-1} y x\right) q $$ So, $$ q \in C\left(x^{-1} a x\right) . $$ Consequently we have $$ x^{-1} C(a) x \subset C\left(x^{-1} a x\right) . $$ It follows from the aforesaid argument $$ C\left(x^{-1} a x\right)=x^{-1} C(a) x . $$ This completes the proof. \end{proof}	theorem exercise_2_3_17 {G : Type} [has_mul G] [group G] (a x : G) : set.centralizer {x⁻¹ax} = (λ g : G, x⁻¹g*x) '' (set.centralizer {a}) :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_4_36	If $a > 1$ is an integer, show that $n \mid \varphi(a^n - 1)$, where $\phi$ is the Euler $\varphi$-function.	\begin{proof} Proof: We have $a>1$. First we propose to prove that $$ \operatorname{Gcd}\left(a, a^n-1\right)=1 . $$ If possible, let us assume that $\operatorname{Gcd}\left(a, a^n-1\right)=d$, where $d>1$. Then $d$ divides $a$ as well as $a^n-1$. Now, $d$ divides $a \Longrightarrow d$ divides $a^n$. This is an impossibility, since $d$ divides $a^n-1$ by our assumption. Consequently, $d$ divides 1 , which implies $d=1$. Hence we are contradict to the fact that $d>1$. Therefore $$ \operatorname{Gcd}\left(a, a^n-1\right)=1 . $$ Then $a \in U_{a^n-1}$, where $U_n$ is a group defined by $$ U_n:=\left\{\bar{a} \in \mathbb{Z}_n \mid \operatorname{Gcd}(a, n)=1\right\} . $$ We know that order of an element divides the order of the group. Here order of the group $U_{a^n-1}$ is $\phi\left(a^n-1\right)$ and $a \in U_{a^n-1}$. This follows that $\mathrm{o}(a)$ divides $\phi\left(a^n-1\right)$. \end{proof}	theorem exercise_2_4_36 {a n : ℕ} (h : a > 1) : n ∣ (a ^ n - 1).totient :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_5_30	Suppose that $\|G\| = pm$, where $p \nmid m$ and $p$ is a prime. If $H$ is a normal subgroup of order $p$ in $G$, prove that $H$ is characteristic.	\begin{proof} Let $G$ be a group of order $p m$, such that $p \nmid m$. Now, Given that $H$ is a normal subgroup of order $p$. Now we want to prove that $H$ is a characterestic subgroup, that is $\phi(H)=H$ for any automorphism $\phi$ of $G$. Now consider $\phi(H)$. Clearly $\|\phi(H)\|=p$. Suppose $\phi(H) \neq H$, then $H \cap \phi (H)=\{ e\}$. Consider $H \phi(H)$, this is a subgroup of $G$ as $H$ is normal. Also $\|H \phi(H)\|=p^2$. By lagrange's theorem then $p^2 \mid$ $p m \Longrightarrow p \mid m$ - contradiction. So $\phi(H)=H$, and $H$ is characterestic subgroup of $G$ \end{proof}	theorem exercise_2_5_30 {G : Type} [group G] [fintype G] {p m : ℕ} (hp : nat.prime p) (hp1 : ¬ p ∣ m) (hG : card G = pm) {H : subgroup G} [fintype H] [H.normal] (hH : card H = p): characteristic H :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_5_37	If $G$ is a nonabelian group of order 6, prove that $G \simeq S_3$.	\begin{proof} Suppose $G$ is a non-abelian group of order 6 . We need to prove that $G \cong S_3$. Since $G$ is non-abelian, we conclude that there is no element of order 6. Now all the nonidentity element has order either 2 or 3 . All elements cannot be order 3 .This is because except the identity elements there are 5 elements, but order 3 elements occur in pair, that is $a, a^2$, both have order 3 , and $a \neq a^2$. So, this is a contradiction, as there are only 5 elements. So, there must be an element of order 2 . All elements of order 2 will imply that $G$ is abelian, hence there is also element of order 3 . Let $a$ be an element of order 2 , and $b$ be an element of order 3 . So we have $e, a, b, b^2$, already 4 elements. Now $a b \neq e, b, b^2$. So $a b$ is another element distinct from the ones already constructed. $a b^2 \neq e, b, a b, b^2, a$. So, we have got another element distinct from the other. So, now $ G=\left\{e, a, b, b^2, a b, a b^2\right\}$. Also, ba must be equal to one of these elements. But $b a \neq e, a, b, b^2$. Also if $b a=a b$, the group will become abelian. so $b a=a b^2$. So what we finally get is $G=\left\langle a, b \mid a^2=e=b^3, b a=a b^2\right\rangle$. Hence $G \cong S_3$. \end{proof}	theorem exercise_2_5_37 (G : Type) [group G] [fintype G] (hG : card G = 6) (hG' : is_empty (comm_group G)) : G ≃ equiv.perm (fin 3) :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_5_44	Prove that a group of order $p^2$, $p$ a prime, has a normal subgroup of order $p$.	\begin{proof} We use the result from problem 40 which is as follows: Suppose $G$ is a group, $H$ is a subgroup and $\|G\|=n$ and $n \nmid\left(i_G(H)\right) !$. Then there exists a normal subgroup $K \neq \{ e \}$ and $K \subseteq H$. So, we have now a group $G$ of order $p^2$. Suppose that the group is cyclic, then it is abelian and any subgroup of order $p$ is normal. Now let us suppose that $G$ is not cyclic, then there exists an element $a$ of order $p$, and $A=\langle a\rangle$. Now $i_G(A)=p$, so $p^2 \nmid p$ ! , hence by the above result there is a normal subgroup $K$, non-trivial and $K \subseteq A$. But $\|A\|=p$, a prime order subgroup, hence has no non-trivial subgroup, so $K=A$. so $A$ is normal subgroup. \end{proof}	theorem exercise_2_5_44 {G : Type*} [group G] [fintype G] {p : ℕ} (hp : nat.prime p) (hG : card G = p^2) : ∃ (N : subgroup G) (fin : fintype N), @card N fin = p ∧ N.normal :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_6_15	If $G$ is an abelian group and if $G$ has an element of order $m$ and one of order $n$, where $m$ and $n$ are relatively prime, prove that $G$ has an element of order $mn$.	\begin{proof} Let $G$ be an abelian group, and let $a$ and $b$ be elements in $G$ of order $m$ and $n$, respectively, where $m$ and $n$ are relatively prime. We will show that the product $ab$ has order $mn$ in $G$, which will prove that $G$ has an element of order $mn$. To show that $ab$ has order $mn$, let $k$ be the order of $ab$ in $G$. We have $a^m = e$, $b^n = e$, and $(ab)^k = e$, where $e$ denotes the identity element of $G$. Since $G$ is abelian, we have $$(ab)^{mn} = a^{mn}b^{mn} = e \cdot e = e.$$ Thus, $k$ is a divisor of $mn$. Now, observe that $a^k = b^{-k}$. Since $m$ and $n$ are relatively prime, there exist integers $x$ and $y$ such that $mx + ny = 1$. Taking $kx$ on both sides of the equation, we get $a^{kx} = b^{-kx}$, or equivalently, $(a^k)^x = (b^k)^{-x}$. It follows that $a^{kx} = (a^m)^{xny} = e$, and similarly, $b^{ky} = (b^n)^{mxk} = e$. Therefore, $m$ divides $ky$ and $n$ divides $kx$. Since $m$ and $n$ are relatively prime, it follows that $mn$ divides $k$. Hence, $k = mn$, and $ab$ has order $mn$ in $G$. This completes the proof. \end{proof}	theorem exercise_2_6_15 {G : Type} [comm_group G] {m n : ℕ} (hm : ∃ (g : G), order_of g = m) (hn : ∃ (g : G), order_of g = n) (hmn : m.coprime n) : ∃ (g : G), order_of g = m n :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_8_12	Prove that any two nonabelian groups of order 21 are isomorphic.	\begin{proof} By Cauchy's theorem we have that if $G$ is a group of order 21 then it has an element $a$ of order 3 and an element $b$ of order 7. By exercise 2.5.41 we have that the subgroup generated by $b$ is normal, so there is some $i=0,1,2,3,4,5,6$ such that $a b a^{-1}=b^i$. We know $i \neq$ 0 since that implies $a b=a$ and so that $b=e$, a contradiction, and we know $i \neq 1$ since then $a b=b a$ and this would imply $G$ is abelian, which we are assuming is not the case. Now, $a$ has order 3 so we must have $b=a^3 b a^{-3}=b^{i^3}$ mod 7 , and so $i$ is restricted by the modular equation $i^3 \equiv 1 \bmod 7$ \begin{center} \begin{tabular}{\|c\|c\|} \hline$x$ & $x^3 \bmod 7$ \\ \hline 2 & 1 \\ \hline 3 & 6 \\ \hline 4 & 1 \\ \hline 5 & 6 \\ \hline 6 & 6 \\ \hline \end{tabular} \end{center} Therefore the only options are $i=2$ and $i=4$. Now suppose $G$ is such that $a b a^{-1}=b^2$ and let $G^{\prime}$ be another group of order 21 with an element $c$ of order 3 and an element $d$ of order 7 such that $c d c^{-1}=d^4$. We now prove that $G$ and $G^{\prime}$ are isomorphic. Define $$ \begin{aligned} \phi: G & \rightarrow G^{\prime} \\ a & \mapsto c^{-1} \\ b & \mapsto d \end{aligned} $$ since $a$ and $c^{-1}$ have the same order and $b$ and $d$ have the same order this is a well defined function. Since $$ \begin{aligned} \phi(a) \phi(b) \phi(a)^{-1} & =c^{-1} d c \\ & =\left(c d^{-1} c^{-1}\right)^{-1} \\ & =\left(d^{-4}\right)^{-1} \\ & =d^4 \\ & =\left(d^2\right)^2 \\ & =\phi(b)^2 \end{aligned} $$ $\phi$ is actually a homomorphism. For any $c^i d^j \in G^{\prime}$ we have $\phi\left(a^{-i} b^j\right)=c^i d^j$ so $\phi$ is onto and $\phi\left(a^i b^j\right)=c^{-i} d^j=e$ only if $i=j=0$, so $\phi$ is 1-to-l. Therefore $G$ and $G^{\prime}$ are isomorphic and so up to isomorphism there is only one nonabelian group of order 21 . \end{proof}	theorem exercise_2_8_12 {G H : Type} [fintype G] [fintype H] [group G] [group H] (hG : card G = 21) (hH : card H = 21) (hG1 : is_empty(comm_group G)) (hH1 : is_empty (comm_group H)) : G ≃ H :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_9_2	If $G_1$ and $G_2$ are cyclic groups of orders $m$ and $n$, respectively, prove that $G_1 \times G_2$ is cyclic if and only if $m$ and $n$ are relatively prime.	\begin{proof} The order of $G \times H$ is $n$. $m$. Thus, $G \times H$ is cyclic iff it has an element with order n. $m$. Suppose $\operatorname{gcd}(n . m)=1$. This implies that $g^m$ has order $n$, and analogously $h^n$ has order $m$. That is, $g \times h$ has order $n$. $m$, and therefore $G \times H$ is cyclic. Suppose now that $\operatorname{gcd}(n . m)>1$. Let $g^k$ be an element of $G$ and $h^j$ be an element of $H$. Since the lowest common multiple of $n$ and $m$ is lower than the product $n . m$, that is, $\operatorname{lcm}(n, m)<n$. $m$, and since $\left(g^k\right)^{l c m(n, m)}=e_G,\left(h^j\right)^{l c m(n, m)}=e_H$, we have $\left(g^k \times h^j\right)^{l c m(n, m)}=e_{G \times H}$. It follows that every element of $G \times H$ has order lower than $n . m$, and therefore $G \times H$ is not cyclic. \end{proof}	theorem exercise_2_9_2 {G H : Type*} [fintype G] [fintype H] [group G] [group H] (hG : is_cyclic G) (hH : is_cyclic H) : is_cyclic (G × H) ↔ (card G).coprime (card H) :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_11_6	If $P$ is a $p$-Sylow subgroup of $G$ and $P \triangleleft G$, prove that $P$ is the only $p$-Sylow subgroup of $G$.	\begin{proof} let $G$ be a group and $P$ a sylow-p subgroup. Given $P$ is normal. By sylow second theorem the sylow-p subgroups are conjugate. Let $K$ be any other sylow-p subgroup. Then there exists $g \in G$ such that $K=g P g^{-1}$. But since $P$ is normal $K=g P g^{-1}=P$. Hence the sylow-p subgroup is unique. \end{proof}	theorem exercise_2_11_6 {G : Type*} [group G] {p : ℕ} (hp : nat.prime p) {P : sylow p G} (hP : P.normal) : ∀ (Q : sylow p G), P = Q :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_2_11_22	Show that any subgroup of order $p^{n-1}$ in a group $G$ of order $p^n$ is normal in $G$.	\begin{proof} Proof: First we prove the following lemma. \textbf{Lemma:} If $G$ is a finite $p$-group with $\|G\|>1$, then $Z(G)$, the center of $G$, has more than one element; that is, if $\|G\|=p^k$ with $k\geq 1$, then $\|Z(G)\|>1$. \textit{Proof of the lemma:} Consider the class equation $$ \|G\|=\|Z(G)\|+\sum_{a \notin Z(G)}[G: C(a)], $$ where $C(a)$ denotes the centralizer of $a$ in $G$. If $G=Z(G)$, then the lemma is immediate. Suppose $Z(G)$ is a proper subset of $G$ and consider an element $a\in G$ such that $a\notin Z(G)$. Then $C(a)$ is a proper subgroup of $G$. Since $C(a)$ is a subgroup of a $p$-group, $[G:C(a)]$ is divisible by $p$ for all $a\notin Z(G)$. This implies that $p$ divides $\|G\|=\|Z(G)\|+\sum_{a\notin Z(G)} [G:C(a)]$. Since $p$ also divides $\|G\|$, it follows that $p$ divides $\|Z(G)\|$. Hence, $\|Z(G)\|>1$. $\Box$ This proves our \textbf{lemma}. We will prove the result by induction on $n$. If $n=1$, the $G$ is a cyclic group of prime order and hence every subgroup of $G$ is normal in $G$. Thus, the result is true for $n=1$. Suppose the result is true for all groups of order $p^m$, where $1 \leq m<n$. Let $H$ be a subgroup of order $p^{n-1}$. Consider $N(H)=\{g \in H: g H=H g\}$. If $H \neq N(H)$, then $\|N(H)\|>p^{n-1}$. Thus, $\|N(H)\|=p^n$ and $N(H)=G$. In this case $H$ is normal in $G$. Let $H=N(H)$. Then $Z(G)$, the center of $G$, is a subset of $H$ and $Z(G) \neq$ $\{e\}$. By Cauchy's theorem and the above Claim, there exists $a \in Z(G)$ such that $o(a)=p$. Let $K=\langle a\rangle$, a cyclic group generated by $a$. Then $K$ is a normal subgroup of $G$ of order $p$. Now, $\|H / K\|=p^{n-2}$ and $\|G / K\|=p^{n-1}$. Thus, by induction hypothesis, $H / K$ is a normal subgroup of $G / K$. \end{proof}	theorem exercise_2_11_22 {p : ℕ} {n : ℕ} {G : Type*} [fintype G] [group G] (hp : nat.prime p) (hG : card G = p ^ n) {K : subgroup G} [fintype K] (hK : card K = p ^ (n-1)) : K.normal :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_4_1_19	Show that there is an infinite number of solutions to $x^2 = -1$ in the quaternions.	\begin{proof} Let $x=a i+b j+c k$ then $$ x^2=(a i+b j+c k)(a i+b j+c k)=-a^2-b^2-c^2=-1 $$ This gives $a^2+b^2+c^2=1$ which has infinitely many solutions for $-1<a, b, c<1$. \end{proof}	theorem exercise_4_1_19 : infinite {x : quaternion ℝ \| x^2 = -1} :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_4_2_5	Let $R$ be a ring in which $x^3 = x$ for every $x \in R$. Prove that $R$ is commutative.	\begin{proof} To begin with $$ 2 x=(2 x)^3=8 x^3=8 x . $$ Therefore $6 x=0 \quad \forall x$. Also $$ (x+y)=(x+y)^3=x^3+x^2 y+x y x+y x^2+x y^2+y x y+y^2 x+y^3 $$ and $$ (x-y)=(x-y)^3=x^3-x^2 y-x y x-y x^2+x y^2+y x y+y^2 x-y^3 $$ Subtracting we get $$ 2\left(x^2 y+x y x+y x^2\right)=0 $$ Multiply the last relation by $x$ on the left and right to get $$ 2\left(x y+x^2 y x+x y x^2\right)=0 \quad 2\left(x^2 y x+x y x^2+y x\right)=0 . $$ Subtracting the last two relations we have $$ 2(x y-y x)=0 . $$ We then show that $3\left(x+x^2\right)=0 \forall x$. You get this from $$ x+x^2=\left(x+x^2\right)^3=x^3+3 x^4+3 x^5+x^6=4\left(x+x^2\right) . $$ In particular $$ 3\left(x+y+(x+y)^2\right)=3\left(x+x^2+y+y^2+x y+y x\right)=0 $$ we end-up with $3(x y+y x)=0$. But since $6 x y=0$, we have $3(x y-y x)=0$. Then subtract $2(x y-y x)=0$ to get $x y-y x=0$. \end{proof}	theorem exercise_4_2_5 {R : Type*} [ring R] (h : ∀ x : R, x ^ 3 = x) : comm_ring R :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_4_2_9	Let $p$ be an odd prime and let $1 + \frac{1}{2} + ... + \frac{1}{p - 1} = \frac{a}{b}$, where $a, b$ are integers. Show that $p \mid a$.	\begin{proof} First we prove for prime $p=3$ and then for all prime $p>3$. Let us take $p=3$. Then the sum $$ \frac{1}{1}+\frac{1}{2}+\ldots+\frac{1}{(p-1)} $$ becomes $$ 1+\frac{1}{3-1}=1+\frac{1}{2}=\frac{3}{2} . $$ Therefore in this case $\quad \frac{a}{b}=\frac{3}{2} \quad$ implies $3 \mid a$, i.e. $p \mid a$. Now for odd prime $p>3$. Let us consider $f(x)=(x-1)(x-2) \ldots(x-(p-1))$. Now, by Fermat, we know that the coefficients of $f(x)$ other than the $x^{p-1}$ and $x^0$ are divisible by $p$. So if, $$ \begin{array}{r} f(x)=x^{p-1}+\sum_{i=0}^{p-2} a_i x^i \\ \text { and } p>3 . \end{array} $$ Then $p \mid a_2$, and $$ f(p) \equiv a_1 p+a_0 \quad\left(\bmod p^3\right) $$ But we see that $$ f(x)=(-1)^{p-1} f(p-x) \text { for any } x, $$ so if $p$ is odd, $$ f(p)=f(0)=a_0, $$ So it follows that: $$ 0=f(p)-a_0 \equiv a_1 p \quad\left(\bmod p^3\right) $$ Therefore, $$ 0 \equiv a_1 \quad\left(\bmod p^2\right) . $$ Hence, $$ 0 \equiv a_1 \quad(\bmod p) . $$ Now our sum is just $\frac{a_1}{(p-1) !}=\frac{a}{b}$. It follows that $p$ divides $a$. This completes the proof. \end{proof}	theorem exercise_4_2_9 {p : ℕ} (hp : nat.prime p) (hp1 : odd p) : ∃ (a b : ℤ), (a / b : ℚ) = ∑ i in finset.range p, 1 / (i + 1) → ↑p ∣ a :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_4_3_25	Let $R$ be the ring of $2 \times 2$ matrices over the real numbers; suppose that $I$ is an ideal of $R$. Show that $I = (0)$ or $I = R$.	\begin{proof} Suppose that $I$ is a nontrivial ideal of $R$, and let $$ A=\left(\begin{array}{ll} a & b \\ c & d \end{array}\right) $$ where not all of $a, b, c d$ are zero. Suppose, without loss of generality -- our steps would be completely analogous, modulo some different placement of 1 s in our matrices, if we assumed some other element to be nonzero -- that $a \neq 0$. Then we have that $$ \left(\begin{array}{ll} 1 & 0 \\ 0 & 0 \end{array}\right)\left(\begin{array}{ll} a & b \\ c & d \end{array}\right)=\left(\begin{array}{ll} a & b \\ 0 & 0 \end{array}\right) \in I $$ and so $$ \left(\begin{array}{ll} a & b \\ 0 & 0 \end{array}\right)\left(\begin{array}{ll} 1 & 0 \\ 0 & 0 \end{array}\right)=\left(\begin{array}{ll} a & 0 \\ 0 & 0 \end{array}\right) \in I $$ so that $$ \left(\begin{array}{ll} x & 0 \\ 0 & 0 \end{array}\right) \in I $$ for any real $x$. Now, also for any real $x$, $$ \left(\begin{array}{ll} x & 0 \\ 0 & 0 \end{array}\right)\left(\begin{array}{ll} 0 & 1 \\ 0 & 0 \end{array}\right)=\left(\begin{array}{ll} 0 & x \\ 0 & 0 \end{array}\right) \in I . $$ Likewise $$ \left(\begin{array}{ll} 0 & 0 \\ 1 & 0 \end{array}\right)\left(\begin{array}{ll} 0 & x \\ 0 & 0 \end{array}\right)=\left(\begin{array}{ll} 0 & 0 \\ 0 & x \end{array}\right) \in I $$ and $$ \left(\begin{array}{ll} 0 & 0 \\ 0 & x \end{array}\right)\left(\begin{array}{ll} 0 & 0 \\ 1 & 0 \end{array}\right)=\left(\begin{array}{ll} 0 & 0 \\ x & 0 \end{array}\right) $$ Thus, as $$ \left(\begin{array}{ll} a & b \\ c & d \end{array}\right)=\left(\begin{array}{ll} a & 0 \\ 0 & 0 \end{array}\right)+\left(\begin{array}{ll} 0 & b \\ 0 & 0 \end{array}\right)+\left(\begin{array}{ll} 0 & 0 \\ c & 0 \end{array}\right)+\left(\begin{array}{ll} 0 & 0 \\ 0 & d \end{array}\right) $$ and since all the terms on the right side are in $I$ and $I$ is an additive group, it follows that $$ \left(\begin{array}{ll} a & b \\ c & d \end{array}\right) $$ for arbitrary $a, b, c, d$ is in $I$, i.e. $I=R$ Note that the intuition for picking these matrices is that, if we denote by $E_{i j}$ the matrix with 1 at position $(i, j)$ and 0 elsewhere, then $$ E_{i j}\left(\begin{array}{ll} a_{1,1} & a_{1,2} \\ a_{2,1} & a_{2,2} \end{array}\right) E_{n m}=a_{j, n} E_{i m} $$ \end{proof}	theorem exercise_4_3_25 (I : ideal (matrix (fin 2) (fin 2) ℝ)) : I = ⊥ ∨ I = ⊤ :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_4_5_16	Let $F = \mathbb{Z}_p$ be the field of integers $\mod p$, where $p$ is a prime, and let $q(x) \in F[x]$ be irreducible of degree $n$. Show that $F[x]/(q(x))$ is a field having at exactly $p^n$ elements.	\begin{proof} In the previous problem we have shown that any for any $p(x) \in F[x]$, we have that $$ p(x)+(q(x))=a_{n-1} x^{n-1}+\cdots+a_1 x+a_0+(q(x)) $$ for some $a_{n-1}, \ldots, a_0 \in F$, and that there are $p^n$ choices for these numbers, so that $F[x] /(q(x)) \leq p^n$. In order to show that equality holds, we have to show that each of these choices induces a different element of $F[x] /(q(x))$; in other words, that each different polynomial of degree $n-1$ or lower belongs to a different coset of $(q(x))$ in $F[x]$. Suppose now, then, that $$ a_{n-1} x^{n-1}+\cdots+a_1 x+a_0+(q(x))=b_{n-1} x^{n-1}+\cdots+b_1 x+b_0+(q(x)) $$ which is equivalent with $\left(a_{n-1}-b_{n-1}\right)^{n-1}+\cdots\left(a_1-b_1\right) x+\left(a_0-b_0\right) \in(q(x))$, which is in turn equivalent with there being a $w(x) \in F[x]$ such that $$ q(x) w(x)=\left(a_{n-1}-b_{n-1}\right)^{n-1}+\cdots\left(a_1-b_1\right) x+\left(a_0-b_0\right) . $$ Degree of the right hand side is strictly smaller than $n$, while the degree of the left hand side is greater or equal to $n$ except if $w(x)=0$, so that if equality is hold we must have that $w(x)=0$, but then since polynomials are equal iff all of their coefficient are equal we get that $a_{n-1}-b_{n-1}=$ $0, \ldots, a_1-b_1=0, a_0-b_0=0$, i.e. $$ a_{n-1}=b_{n-1}, \ldots, a_1=b_1, a_0=b_0 $$ which is what we needed to prove. \end{proof}	theorem exercise_4_5_16 {p n: ℕ} (hp : nat.prime p) {q : polynomial (zmod p)} (hq : irreducible q) (hn : q.degree = n) : ∃ is_fin : fintype $ polynomial (zmod p) ⧸ ideal.span ({q} : set (polynomial $ zmod p)), @card (polynomial (zmod p) ⧸ ideal.span {q}) is_fin = p ^ n ∧ is_field (polynomial $ zmod p):=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_4_5_25	If $p$ is a prime, show that $q(x) = 1 + x + x^2 + \cdots x^{p - 1}$ is irreducible in $Q[x]$.	\begin{proof} Lemma: Let $F$ be a field and $f(x) \in F[x]$. If $c \in F$ and $f(x+c)$ is irreducible in $F[x]$, then $f(x)$ is irreducible in $F[x]$. Proof of the Lemma: Suppose that $f(x)$ is reducible, i.e., there exist non-constant $g(x), h(x) \in F[x]$ so that $$ f(x)=g(x) h(x) . $$ In particular, then we have $$ f(x+c)=g(x+c) h(x+c) . $$ Note that $g(x+c)$ and $h(x+c)$ have the same degree at $g(x)$ and $h(x)$ respectively; in particular, they are non-constant polynomials. So our assumption is wrong. Hence, $f(x)$ is irreducible in $F[x]$. This proves our Lemma. Now recall the identity $$ \frac{x^p-1}{x-1}=x^{p-1}+x^{p-2}+\ldots \ldots+x^2+x+1 . $$ We prove that $f(x+1)$ is $\$$ \|textbffirreducible in $\mathbb{Q}[x]$ and then apply the Lemma to conclude that $f(x)$ is irreducible in $\mathbb{Q}[x] .3 \$$ Note that $$ \begin{aligned} & f(x+1)=\frac{(x+1)^p-1}{x} \\ & =\frac{x^p+p x^{p-1}+\ldots+p x}{x} \\ & =x^{p-1}+p x^{p-2}+\ldots .+p . \end{aligned} $$ Using that the binomial coefficients occurring above are all divisible by $p$, we have that $f(x+1)$ is irreducible $\mathbb{Q}[x]$ by Eisenstein's criterion applied with prime $p$. Then by the lemma $f(x)$ is irreducible $\mathbb{Q}[x]$. This completes the proof. \end{proof}	theorem exercise_4_5_25 {p : ℕ} (hp : nat.prime p) : irreducible (∑ i : finset.range p, X ^ p : polynomial ℚ) :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_4_6_3	Show that there is an infinite number of integers a such that $f(x) = x^7 + 15x^2 - 30x + a$ is irreducible in $Q[x]$.	\begin{proof} Via Eisenstein's criterion and observation that 5 divides 15 and $-30$, it is sufficient to find infinitely many $a$ such that 5 divides $a$, but $5^2=25$ doesn't divide $a$. For example $5 \cdot 2^k$ for $k=0,1, \ldots$ is one such infinite sequence. \end{proof}	theorem exercise_4_6_3 : infinite {a : ℤ \| irreducible (X^7 + 15X^2 - 30X + a : polynomial ℚ)} :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_5_2_20	Let $V$ be a vector space over an infinite field $F$. Show that $V$ cannot be the set-theoretic union of a finite number of proper subspaces of $V$.	\begin{proof} Assume that $V$ can be written as the set-theoretic union of $n$ proper subspaces $U_1, U_2, \ldots, U_n$. Without loss of generality, we may assume that no $U_i$ is contained in the union of other subspaces. Let $u \in U_i$ but $u \notin \bigcup_{j \neq i} U_j$ and $v \notin U_i$. Then, we have $(v + Fu) \cap U_i = \varnothing$, and $(v + Fu) \cap U_j$ for $j \neq i$ contains at most one vector, since otherwise $U_j$ would contain $u$. Therefore, we have $\|v + Fu\| \leq \|F\| \leq n-1$. However, since $n$ is a finite natural number, this contradicts the fact that the field $F$ is finite. Thus, our assumption that $V$ can be written as the set-theoretic union of proper subspaces is wrong, and the claim is proven. \end{proof}	theorem exercise_5_2_20 {F V ι: Type*} [infinite F] [field F] [add_comm_group V] [module F V] {u : ι → submodule F V} (hu : ∀ i : ι, u i ≠ ⊤) : (⋃ i : ι, (u i : set V)) ≠ ⊤ :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_5_3_10	Prove that $\cos 1^{\circ}$ is algebraic over $\mathbb{Q}$.	\begin{proof} Since $\left(\cos \left(1^{\circ}\right)+i \sin \left(1^{\circ}\right)\right)^{360}=1$, the number $\cos \left(1^{\circ}\right)+i \sin \left(1^{\circ}\right)$ is algebraic. And the real part and the imaginary part of an algebraic number are always algebraic numbers. \end{proof}	theorem exercise_5_3_10 : is_algebraic ℚ (cos (real.pi / 180)) :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Herstein\|exercise_5_5_2	Prove that $x^3 - 3x - 1$ is irreducible over $\mathbb{Q}$.	\begin{proof} Let $p(x)=x^3-3 x-1$. Then $$ p(x+1)=(x+1)^3-3(x+1)-1=x^3+3 x^2-3 $$ We have $3\|3,3\| 0$ but $3 \nmid 1$ and $3^2 \nmid 3$. Thus the polynomial is irreducible over $\mathbb{Q}$ by 3 -Eisenstein criterion. \end{proof}	theorem exercise_5_5_2 : irreducible (X^3 - 3*X - 1 : polynomial ℚ) :=	import .common open set function nat fintype real subgroup ideal polynomial submodule zsqrtd open char_p mul_aut matrix open_locale big_operators noncomputable theory
Artin\|exercise_2_2_9	Let $H$ be the subgroup generated by two elements $a, b$ of a group $G$. Prove that if $a b=b a$, then $H$ is an abelian group.	\begin{proof} Since $a$ and $b$ commute, for any $g, h\in H$ we can write $g=a^ib^j$ and $h = a^kb^l$. Then $gh = a^ib^ja^kb^l = a^kb^la^ib^j = hg$. Thus $H$ is abelian. \end{proof}	theorem exercise_2_2_9 {G : Type} [group G] {a b : G} (h : a b = b * a) : ∀ x y : closure {x \| x = a ∨ x = b}, xy = yx :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_2_4_19	Prove that if a group contains exactly one element of order 2 , then that element is in the center of the group.	\begin{proof} Let $x$ be the element of order two. Consider the element $z=y^{-1} x y$, we have: $z^2=\left(y^{-1} x y\right)^2=\left(y^{-1} x y\right)\left(y^{-1} x y\right)=e$. So: $z=x$, and $y^{-1} x y=x$. So: $x y=y x$. So: $x$ is in the center of $G$. \end{proof}	theorem exercise_2_4_19 {G : Type*} [group G] {x : G} (hx : order_of x = 2) (hx1 : ∀ y, order_of y = 2 → y = x) : x ∈ center G :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_2_11_3	Prove that a group of even order contains an element of order $2 .$	\begin{proof} Pair up if possible each element of $G$ with its inverse, and observe that $$ g^2 \neq e \Longleftrightarrow g \neq g^{-1} \Longleftrightarrow \text { there exists the pair }\left(g, g^{-1}\right) $$ Now, there is one element that has no pairing: the unit $e$ (since indeed $e=e^{-1} \Longleftrightarrow e^2=e$ ), so since the number of elements of $G$ is even there must be at least one element more, say $e \neq a \in G$, without a pairing, and thus $a=a^{-1} \Longleftrightarrow a^2=e$ \end{proof}	theorem exercise_2_11_3 {G : Type*} [group G] [fintype G] (hG : even (card G)) : ∃ x : G, order_of x = 2 :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_3_5_6	Let $V$ be a vector space which is spanned by a countably infinite set. Prove that every linearly independent subset of $V$ is finite or countably infinite.	\begin{proof} Let $A$ be the countable generating set, and let $U$ be an uncountable linearly independent set. It can be extended to a basis $B$ of the whole space. Now consider the subset $C$ of elements of $B$ that appear in the $B$-decompositions of elements of $A$. Since only finitely many elements are involved in the decomposition of each element of $A$, the set $C$ is countable. But $C$ also clearly generates the vector space $V$. This contradicts the fact that it is a proper subset of the basis $B$ (since $B$ is uncountable). \end{proof}	theorem exercise_3_5_6 {K V : Type} [field K] [add_comm_group V] [module K V] {S : set V} (hS : set.countable S) (hS1 : span K S = ⊤) {ι : Type} (R : ι → V) (hR : linear_independent K R) : countable ι :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_6_1_14	Let $Z$ be the center of a group $G$. Prove that if $G / Z$ is a cyclic group, then $G$ is abelian and hence $G=Z$.	\begin{proof} We have that $G / Z(G)$ is cyclic, and so there is an element $x \in G$ such that $G / Z(G)=\langle x Z(G)\rangle$, where $x Z(G)$ is the coset with representative $x$. Now let $g \in G$ We know that $g Z(G)=(x Z(G))^m$ for some $m$, and by definition $(x Z(G))^m=x^m Z(G)$. Now, in general, if $H \leq G$, we have by definition too that $a H=b H$ if and only if $b^{-1} a \in H$. In our case, we have that $g Z(G)=x^m Z(G)$, and this happens if and only if $\left(x^m\right)^{-1} g \in Z(G)$. Then, there's a $z \in Z(G)$ such that $\left(x^m\right)^{-1} g=z$, and so $g=x^m z$. $g, h \in G$ implies that $g=x^{a_1} z_1$ and $h=x^{a_2} z_2$, so $$ \begin{aligned} g h & =\left(x^{a_1} z_1\right)\left(x^{a_2} z_2\right) \\ & =x^{a_1} x^{a_2} z_1 z_2 \\ & =x^{a_1+a_2} z_2 z_1 \\ & =\ldots=\left(x^{a_2} z_2\right)\left(x^{a_1} z_1\right)=h g . \end{aligned} $$ Therefore, $G$ is abelian. \end{proof}	theorem exercise_6_1_14 (G : Type*) [group G] (hG : is_cyclic $ G ⧸ (center G)) : center G = ⊤ :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_6_4_3	Prove that no group of order $p^2 q$, where $p$ and $q$ are prime, is simple.	\begin{proof} We may as well assume $p<q$. The number of Sylow $q$-subgroups is $1 \bmod q$ and divides $p^2$. So it is $1, p$, or $p^2$. We win if it's 1 and it can't be $p$, so suppose it's $p^2$. But now $q \mid p^2-1$, so $q \mid p+1$ or $q \mid p-1$. Thus $p=2$ and $q=3$. But we know no group of order 36 is simple. \end{proof}	theorem exercise_6_4_3 {G : Type} [group G] [fintype G] {p q : ℕ} (hp : prime p) (hq : prime q) (hG : card G = p^2 q) : is_simple_group G → false :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_6_8_1	Prove that two elements $a, b$ of a group generate the same subgroup as $b a b^2, b a b^3$.	\begin{proof} Let $H = \langle bab^2, bab^3\rangle$. It is clear that $H\subset \langle a, b\rangle$. Note that $(bab^2)^{-1}(bab^3)=b$, therefore $b\in H$. This then implies that $b^{-1}(bab^2)b^{-2}=a\in H$. Thus $\langle a, b\rangle\subset H$. \end{proof}	theorem exercise_6_8_1 {G : Type} [group G] (a b : G) : closure ({a, b} : set G) = closure {bab^2, ba*b^3} :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_10_2_4	Prove that in the ring $\mathbb{Z}[x],(2) \cap(x)=(2 x)$.	\begin{proof} Let $f(x) \in(2 x)$. Then there exists some polynomial $g(x) \in \mathbb{Z}$ such that $$ f(x)=2 x g(x) $$ But this means that $f(x) \in(2)$ (because $x g(x)$ is a polynomial), and $f(x) \in$ $(x)$ (because $2 g(x)$ is a polynomial). Thus, $f(x) \in(2) \cap(x)$, and $$ (2 x) \subseteq(2) \cap(x) $$ On the other hand, let $p(x) \in(2) \cap(x)$. Since $p(x) \in(2)$, there exists some polynomial $h(x) \in \mathbb{Z}[x]$ such that $$ p(x)=2 h(x) $$ Furthermore, $p(x) \in(x)$, so $$ p(x)=x h_2(x) $$ So, $2 h(x)=x h_2(x)$, for some $h_2(x) \in \mathbb{Z}[x]$. This means that $h(0)=0$, so $x$ divides $h(x)$; that is, $$ h(x)=x q(x) $$ for some $q(x) \in \mathbb{Z}[x]$, and $$ p(x)=2 x q(x) $$ Thus, $p(x) \in(2 x)$, and $$ \text { (2) } \cap(x) \subseteq(2 x) $$ Finally, (2) $\cap(x)=(2 x)$, as required. \end{proof}	theorem exercise_10_2_4 : span ({2} : set $ polynomial ℤ) ⊓ (span {X}) = span ({2 * X} : set $ polynomial ℤ) :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_10_4_6	Let $I, J$ be ideals in a ring $R$. Prove that the residue of any element of $I \cap J$ in $R / I J$ is nilpotent.	\begin{proof} If $x$ is in $I \cap J, x \in I$ and $x \in J . R / I J=\{r+a b: a \in I, b \in J, r \in R\}$. Then $x \in I \cap J \Rightarrow x \in I$ and $x \in J$, and so $x^2 \in I J$. Thus $$ [x]^2=\left[x^2\right]=[0] \text { in } R / I J $$ \end{proof}	theorem exercise_10_4_6 {R : Type} [comm_ring R] [no_zero_divisors R] {I J : ideal R} (x : I ⊓ J) : is_nilpotent ((ideal.quotient.mk (IJ)) x) :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_10_7_10	Let $R$ be a ring, with $M$ an ideal of $R$. Suppose that every element of $R$ which is not in $M$ is a unit of $R$. Prove that $M$ is a maximal ideal and that moreover it is the only maximal ideal of $R$.	\begin{proof} Suppose there is an ideal $M\subset I\subset R$. If $I\neq M$, then $I$ contains a unit, thus $I=R$. Therefore $M$ is a maximal ideal. Suppose we have an arbitrary maximal ideal $M^\prime$ of $R$. The ideal $M^\prime$ cannot contain a unit, otherwise $M^\prime =R$. Therefore $M^\prime \subset M$. But we cannot have $M^\prime \subsetneq M \subsetneq R$, therefore $M=M^\prime$. \end{proof}	theorem exercise_10_7_10 {R : Type*} [ring R] (M : ideal R) (hM : ∀ (x : R), x ∉ M → is_unit x) : is_maximal M ∧ ∀ (N : ideal R), is_maximal N → N = M :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_11_4_1b	Prove that $x^3 + 6x + 12$ is irreducible in $\mathbb{Q}$.	\begin{proof} Apply Eisenstein's criterion with $p=3$. \end{proof}	theorem exercise_11_4_1b {F : Type} [field F] [fintype F] (hF : card F = 2) : irreducible (12 + 6 X + X ^ 3 : polynomial F) :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_11_4_6b	Prove that $x^2+1$ is irreducible in $\mathbb{F}_7$	\begin{proof} If $p(x)=x^2+1$ were reducible, its factors must be linear. But no $p(a)$ for $a\in\mathbb{F}_7$ evaluates to 0, therefore $x^2+1$ is irreducible. \end{proof}	theorem exercise_11_4_6b {F : Type*} [field F] [fintype F] (hF : card F = 31) : irreducible (X ^ 3 - 9 : polynomial F) :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_11_4_8	Let $p$ be a prime integer. Prove that the polynomial $x^n-p$ is irreducible in $\mathbb{Q}[x]$.	\begin{proof} Straightforward application of Eisenstein's criterion with $p$. \end{proof}	theorem exercise_11_4_8 {p : ℕ} (hp : prime p) (n : ℕ) : irreducible (X ^ n - p : polynomial ℚ) :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Artin\|exercise_13_4_10	Prove that if a prime integer $p$ has the form $2^r+1$, then it actually has the form $2^{2^k}+1$.	\begin{proof} In particular, we have $$ \frac{x^a+1}{x+1}=\frac{(-x)^a-1}{(-x)-1}=1-x+x^2-\cdots+(-x)^{a-1} $$ by the geometric sum formula. In this case, specialize to $x=2^{2^m}$ and we have a nontrivial divisor. \end{proof}	theorem exercise_13_4_10 {p : ℕ} {hp : nat.prime p} (h : ∃ r : ℕ, p = 2 ^ r + 1) : ∃ (k : ℕ), p = 2 ^ (2 ^ k) + 1 :=	import .common open function fintype subgroup ideal polynomial submodule zsqrtd char_p open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_1_1_3	Prove that the addition of residue classes $\mathbb{Z}/n\mathbb{Z}$ is associative.	\begin{proof} We have $$ \begin{aligned} (\bar{a}+\bar{b})+\bar{c} &=\overline{a+b}+\bar{c} \\ &=\overline{(a+b)+c} \\ &=\overline{a+(b+c)} \\ &=\bar{a}+\overline{b+c} \\ &=\bar{a}+(\bar{b}+\bar{c}) \end{aligned} $$ since integer addition is associative. \end{proof}	theorem exercise_1_1_3 (n : ℤ) : ∀ (a b c : ℤ), (a+b)+c ≡ a+(b+c) [ZMOD n] :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_1_1_5	Prove that for all $n>1$ that $\mathbb{Z}/n\mathbb{Z}$ is not a group under multiplication of residue classes.	\begin{proof} Note that since $n>1, \overline{1} \neq \overline{0}$. Now suppose $\mathbb{Z} /(n)$ contains a multiplicative identity element $\bar{e}$. Then in particular, $$ \bar{e} \cdot \overline{1}=\overline{1} $$ so that $\bar{e}=\overline{1}$. Note, however, that $$ \overline{0} \cdot \bar{k}=\overline{0} $$ for all k, so that $\overline{0}$ does not have a multiplicative inverse. Hence $\mathbb{Z} /(n)$ is not a group under multiplication. \end{proof}	theorem exercise_1_1_5 (n : ℕ) (hn : 1 < n) : is_empty (group (zmod n)) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_1_1_16	Let $x$ be an element of $G$. Prove that $x^2=1$ if and only if $\|x\|$ is either $1$ or $2$.	\begin{proof} $(\Rightarrow)$ Suppose $x^2=1$. Then we have $0<\|x\| \leq 2$, i.e., $\|x\|$ is either 1 or 2 . ( $\Leftarrow$ ) If $\|x\|=1$, then we have $x=1$ so that $x^2=1$. If $\|x\|=2$ then $x^2=1$ by definition. So if $\|x\|$ is 1 or 2 , we have $x^2=1$. \end{proof}	theorem exercise_1_1_16 {G : Type*} [group G] (x : G) (hx : x ^ 2 = 1) : order_of x = 1 ∨ order_of x = 2 :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_1_1_18	Let $x$ and $y$ be elements of $G$. Prove that $xy=yx$ if and only if $y^{-1}xy=x$ if and only if $x^{-1}y^{-1}xy=1$.	\begin{proof} If $x y=y x$, then $y^{-1} x y=y^{-1} y x=1 x=x$. Multiplying by $x^{-1}$ then gives $x^{-1} y^{-1} x y=1$. On the other hand, if $x^{-1} y^{-1} x y=1$, then we may multiply on the left by $x$ to get $y^{-1} x y=x$. Then multiplying on the left by $y$ gives $x y=y x$ as desired. \end{proof}	theorem exercise_1_1_18 {G : Type} [group G] (x y : G) : x y = y * x ↔ y⁻¹ * x * y = x ↔ x⁻¹ * y⁻¹ * x * y = 1 :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_1_1_22a	If $x$ and $g$ are elements of the group $G$, prove that $\|x\|=\left\|g^{-1} x g\right\|$.	\begin{proof} First we prove a technical lemma: {\bf Lemma.} For all $a, b \in G$ and $n \in \mathbb{Z},\left(b^{-1} a b\right)^n=b^{-1} a^n b$. The statement is clear for $n=0$. We prove the case $n>0$ by induction; the base case $n=1$ is clear. Now suppose $\left(b^{-1} a b\right)^n=b^{-1} a^n b$ for some $n \geq 1$; then $$ \left(b^{-1} a b\right)^{n+1}=\left(b^{-1} a b\right)\left(b^{-1} a b\right)^n=b^{-1} a b b^{-1} a^n b=b^{-1} a^{n+1} b . $$ By induction the statement holds for all positive $n$. Now suppose $n<0$; we have $$ \left(b^{-1} a b\right)^n=\left(\left(b^{-1} a b\right)^{-n}\right)^{-1}=\left(b^{-1} a^{-n} b\right)^{-1}=b^{-1} a^n b . $$ Hence, the statement holds for all integers $n$. Now to the main result. Suppose first that $\|x\|$ is infinity and that $\left\|g^{-1} x g\right\|=n$ for some positive integer $n$. Then we have $$ \left(g^{-1} x g\right)^n=g^{-1} x^n g=1, $$ and multiplying on the left by $g$ and on the right by $g^{-1}$ gives us that $x^n=1$, a contradiction. Thus if $\|x\|$ is infinity, so is $\left\|g^{-1} x g\right\|$. Similarly, if $\left\|g^{-1} x g\right\|$ is infinite and $\|x\|=n$, we have $$ \left(g^{-1} x g\right)^n=g^{-1} x^n g=g^{-1} g=1, $$ a contradiction. Hence if $\left\|g^{-1} x g\right\|$ is infinite, so is $\|x\|$. Suppose now that $\|x\|=n$ and $\left\|g^{-1} x g\right\|=m$ for some positive integers $n$ and $m$. We have $$ \left(g^{-1} x g\right)^n=g^{-1} x^n g=g^{-1} g=1, $$ So that $m \leq n$, and $$ \left(g^{-1} x g\right)^m=g^{-1} x^m g=1, $$ so that $x^m=1$ and $n \leq m$. Thus $n=m$. \end{proof}	theorem exercise_1_1_22a {G : Type} [group G] (x g : G) : order_of x = order_of (g⁻¹ x * g) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_1_1_25	Prove that if $x^{2}=1$ for all $x \in G$ then $G$ is abelian.	\begin{proof} Solution: Note that since $x^2=1$ for all $x \in G$, we have $x^{-1}=x$. Now let $a, b \in G$. We have $$ a b=(a b)^{-1}=b^{-1} a^{-1}=b a . $$ Thus $G$ is abelian. \end{proof}	theorem exercise_1_1_25 {G : Type} [group G] (h : ∀ x : G, x ^ 2 = 1) : ∀ a b : G, ab = b*a :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_1_1_34	If $x$ is an element of infinite order in $G$, prove that the elements $x^{n}, n \in \mathbb{Z}$ are all distinct.	\begin{proof} Solution: Suppose to the contrary that $x^a=x^b$ for some $0 \leq a<b \leq n-1$. Then we have $x^{b-a}=1$, with $1 \leq b-a<n$. However, recall that $n$ is by definition the least integer $k$ such that $x^k=1$, so we have a contradiction. Thus all the $x^i$, $0 \leq i \leq n-1$, are distinct. In particular, we have $$ \left\{x^i \mid 0 \leq i \leq n-1\right\} \subseteq G, $$ so that $\|x\|=n \leq\|G\|$ \end{proof}	theorem exercise_1_1_34 {G : Type*} [group G] {x : G} (hx_inf : order_of x = 0) (n m : ℤ) : x ^ n ≠ x ^ m :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_1_6_4	Prove that the multiplicative groups $\mathbb{R}-\{0\}$ and $\mathbb{C}-\{0\}$ are not isomorphic.	\begin{proof} Isomorphic groups necessarily have the same number of elements of order $n$ for all finite $n$. Now let $x \in \mathbb{R}^{\times}$. If $x=1$ then $\|x\|=1$, and if $x=-1$ then $\|x\|=2$. If (with bars denoting absolute value) $\|x\|<1$, then we have $$ 1>\|x\|>\left\|x^2\right\|>\cdots, $$ and in particular, $1>\left\|x^n\right\|$ for all $n$. So $x$ has infinite order in $\mathbb{R}^{\times}$. Similarly, if $\|x\|>1$ (absolute value) then $x$ has infinite order in $\mathbb{R}^{\times}$. So $\mathbb{R}^{\times}$has 1 element of order 1,1 element of order 2 , and all other elements have infinite order. In $\mathbb{C}^{\times}$, on the other hand, $i$ has order 4 . Thus $\mathbb{R}^{\times}$and $\mathbb{C}^{\times}$are not isomorphic. \end{proof}	theorem exercise_1_6_4 : is_empty (multiplicative ℝ ≃* multiplicative ℂ) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_1_6_17	Let $G$ be any group. Prove that the map from $G$ to itself defined by $g \mapsto g^{-1}$ is a homomorphism if and only if $G$ is abelian.	\begin{proof} $(\Rightarrow)$ Suppose $G$ is abelian. Then $$ \varphi(a b)=(a b)^{-1}=b^{-1} a^{-1}=a^{-1} b^{-1}=\varphi(a) \varphi(b), $$ so that $\varphi$ is a homomorphism. $(\Leftarrow)$ Suppose $\varphi$ is a homomorphism, and let $a, b \in G$. Then $$ a b=\left(b^{-1} a^{-1}\right)^{-1}=\varphi\left(b^{-1} a^{-1}\right)=\varphi\left(b^{-1}\right) \varphi\left(a^{-1}\right)=\left(b^{-1}\right)^{-1}\left(a^{-1}\right)^{-1}=b a, $$ so that $G$ is abelian. \end{proof}	theorem exercise_1_6_17 {G : Type} [group G] (f : G → G) (hf : f = λ g, g⁻¹) : ∀ x y : G, f x f y = f (xy) ↔ ∀ x y : G, xy = y*x :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_2_1_5	Prove that $G$ cannot have a subgroup $H$ with $\|H\|=n-1$, where $n=\|G\|>2$.	\begin{proof} Solution: Under these conditions, there exists a nonidentity element $x \in H$ and an element $y \notin H$. Consider the product $x y$. If $x y \in H$, then since $x^{-1} \in H$ and $H$ is a subgroup, $y \in H$, a contradiction. If $x y \notin H$, then we have $x y=y$. Thus $x=1$, a contradiction. Thus no such subgroup exists. \end{proof}	theorem exercise_2_1_5 {G : Type*} [group G] [fintype G] (hG : card G > 2) (H : subgroup G) [fintype H] : card H ≠ card G - 1 :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_2_4_4	Prove that if $H$ is a subgroup of $G$ then $H$ is generated by the set $H-\{1\}$.	\begin{proof} If $H=\{1\}$ then $H-\{1\}$ is the empty set which indeed generates the trivial subgroup $H$. So suppose $\|H\|>1$ and pick a nonidentity element $h \in H$. Since $1=h h^{-1} \in\langle H-\{1\}\rangle$ (Proposition 9), we see that $H \leq\langle H-\{1\}\rangle$. By minimality of $\langle H-\{1\}\rangle$, the reverse inclusion also holds so that $\langle H-\{1\}\rangle=$ $H$. \end{proof}	theorem exercise_2_4_4 {G : Type*} [group G] (H : subgroup G) : subgroup.closure ((H : set G) \ {1}) = ⊤ :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_2_4_16b	Show that the subgroup of all rotations in a dihedral group is a maximal subgroup.	\begin{proof} Fix a positive integer $n>1$ and let $H \leq D_{2 n}$ consist of the rotations of $D_{2 n}$. That is, $H=\langle r\rangle$. Now, this subgroup is proper since it does not contain $s$. If $H$ is not maximal, then by the previous proof we know there is a maximal subset $K$ containing $H$. Then $K$ must contain a reflection $s r^k$ for $k \in\{0,1, \ldots, n-1\}$. Then since $s r^k \in K$ and $r^{n-k} \in K$, it follows by closure that $$ s=\left(s r^k\right)\left(r^{n-k}\right) \in K . $$ But $D_{2 n}=\langle r, s\rangle$, so this shows that $K=D_{2 n}$, which is a contradiction. Therefore $H$ must be maximal. \end{proof}	theorem exercise_2_4_16b {n : ℕ} {hn : n ≠ 0} {R : subgroup (dihedral_group n)} (hR : R = subgroup.closure {dihedral_group.r 1}) : R ≠ ⊤ ∧ ∀ K : subgroup (dihedral_group n), R ≤ K → K = R ∨ K = ⊤ :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_3_1_3a	Let $A$ be an abelian group and let $B$ be a subgroup of $A$. Prove that $A / B$ is abelian.	\begin{proof} Lemma: Let $G$ be a group. If $\|G\|=2$, then $G \cong Z_2$. Proof: Since $G=\{e a\}$ has an identity element, say $e$, we know that $e e=e, e a=a$, and $a e=a$. If $a^2=a$, we have $a=e$, a contradiction. Thus $a^2=e$. We can easily see that $G \cong Z_2$. If $A$ is abelian, every subgroup of $A$ is normal; in particular, $B$ is normal, so $A / B$ is a group. Now let $x B, y B \in A / B$. Then $$ (x B)(y B)=(x y) B=(y x) B=(y B)(x B) . $$ Hence $A / B$ is abelian. \end{proof}	theorem exercise_3_1_3a {A : Type} [comm_group A] (B : subgroup A) : ∀ a b : A ⧸ B, ab = b*a :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_3_1_22b	Prove that the intersection of an arbitrary nonempty collection of normal subgroups of a group is a normal subgroup (do not assume the collection is countable).	\begin{proof} Let $\left\{H_i \mid i \in I\right\}$ be an arbitrary collection of normal subgroups of $G$ and consider the intersection $$ \bigcap_{i \in I} H_i $$ Take an element $a$ in the intersection and an arbitrary element $g \in G$. Then $g a g^{-1} \in H_i$ because $H_i$ is normal for any $i \in H$ By the definition of the intersection, this shows that $g a g^{-1} \in \bigcap_{i \in I} H_i$ and therefore it is a normal subgroup. \end{proof}	theorem exercise_3_1_22b {G : Type} [group G] (I : Type) (H : I → subgroup G) (hH : ∀ i : I, subgroup.normal (H i)) : subgroup.normal (⨅ (i : I), H i):=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_3_2_11	Let $H \leq K \leq G$. Prove that $\|G: H\|=\|G: K\| \cdot\|K: H\|$ (do not assume $G$ is finite).	\begin{proof} Proof. Let $G$ be a group and let $I$ be a nonempty set of indices, not necessarily countable. Consider the collection of subgroups $\left\{N_\alpha \mid \alpha \in I\right\}$, where $N_\alpha \unlhd G$ for each $\alpha \in I$. Let $$ N=\bigcap_{\alpha \in I} N_\alpha . $$ We know $N$ is a subgroup of $G$. For any $g \in G$ and any $n \in N$, we must have $n \in N_\alpha$ for each $\alpha$. And since $N_\alpha \unlhd G$, we have $g n g^{-1} \in N_\alpha$ for each $\alpha$. Therefore $g n g^{-1} \in N$, which shows that $g N g^{-1} \subseteq N$ for each $g \in G$. As before, this is enough to complete the proof. \end{proof}	theorem exercise_3_2_11 {G : Type} [group G] {H K : subgroup G} (hHK : H ≤ K) : H.index = K.index H.relindex K :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_3_2_21a	Prove that $\mathbb{Q}$ has no proper subgroups of finite index.	\begin{proof} Solution: We begin with a lemma. Lemma: If $D$ is a divisible abelian group, then no proper subgroup of $D$ has finite index. Proof: We saw previously that no finite group is divisible and that every proper quotient $D / A$ of a divisible group is divisible; thus no proper quotient of a divisible group is finite. Equivalently, $[D: A]$ is not finite. Because $\mathbb{Q}$ and $\mathbb{Q} / \mathbb{Z}$ are divisible, the conclusion follows. \end{proof}	theorem exercise_3_2_21a (H : add_subgroup ℚ) (hH : H ≠ ⊤) : H.index = 0 :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_3_4_1	Prove that if $G$ is an abelian simple group then $G \cong Z_{p}$ for some prime $p$ (do not assume $G$ is a finite group).	\begin{proof} Solution: Let $G$ be an abelian simple group. Suppose $G$ is infinite. If $x \in G$ is a nonidentity element of finite order, then $\langle x\rangle<G$ is a nontrivial normal subgroup, hence $G$ is not simple. If $x \in G$ is an element of infinite order, then $\left\langle x^2\right\rangle$ is a nontrivial normal subgroup, so $G$ is not simple. Suppose $G$ is finite; say $\|G\|=n$. If $n$ is composite, say $n=p m$ for some prime $p$ with $m \neq 1$, then by Cauchy's Theorem $G$ contains an element $x$ of order $p$ and $\langle x\rangle$ is a nontrivial normal subgroup. Hence $G$ is not simple. Thus if $G$ is an abelian simple group, then $\|G\|=p$ is prime. We saw previously that the only such group up to isomorphism is $\mathbb{Z} /(p)$, so that $G \cong \mathbb{Z} /(p)$. Moreover, these groups are indeed simple. \end{proof}	theorem exercise_3_4_1 (G : Type*) [comm_group G] [is_simple_group G] : is_cyclic G ∧ ∃ G_fin : fintype G, nat.prime (@card G G_fin) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_3_4_5a	Prove that subgroups of a solvable group are solvable.	\begin{proof} Let $G$ be a solvable group and let $H \leq G$. Since $G$ is solvable, we may find a chain of subgroups $$ 1=G_0 \unlhd G_1 \unlhd G_2 \unlhd \cdots \unlhd G_n=G $$ so that each quotient $G_{i+1} / G_i$ is abelian. For each $i$, define $$ H_i=G_i \cap H, \quad 0 \leq i \leq n . $$ Then $H_i \leq H_{i+1}$ for each $i$. Moreover, if $g \in H_{i+1}$ and $x \in H_i$, then in particular $g \in G_{i+1}$ and $x \in G_i$, so that $$ g x g^{-1} \in G_i $$ because $G_i \unlhd G_{i+1}$. But $g$ and $x$ also belong to $H$, so $$ g x g^{-1} \in H_i, $$ which shows that $H_i \unlhd H_{i+1}$ for each $i$. Next, note that $$ H_i=G_i \cap H=\left(G_i \cap G_{i+1}\right) \cap H=G_i \cap H_{i+1} . $$ By the Second Isomorphism Theorem, we then have $$ H_{i+1} / H_i=H_{i+1} /\left(H_{i+1} \cap G_i\right) \cong H_{i+1} G_i / G_i \leq G_{i+1} / G_i . $$ Since $H_{i+1} / H_i$ is isomorphic to a subgroup of the abelian group $G_{i+1} / G_i$, it follows that $H_{i+1} / H_i$ is also abelian. This completes the proof that $H$ is solvable. \end{proof}	theorem exercise_3_4_5a {G : Type*} [group G] (H : subgroup G) [is_solvable G] : is_solvable H :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_3_4_11	Prove that if $H$ is a nontrivial normal subgroup of the solvable group $G$ then there is a nontrivial subgroup $A$ of $H$ with $A \unlhd G$ and $A$ abelian.	\begin{proof} Suppose $H$ is a nontrivial normal subgroup of the solvable group $G$. First, notice that $H$, being a subgroup of a solvable group, is itself solvable. By exercise $8, H$ has a chain of subgroups $$ 1 \leq H_1 \leq \ldots \leq H $$ such that each $H_i$ is a normal subgroup of $H$ itself and $H_{i+1} / H_i$ is abelian. But then the first group in the series $$ H_1 / 1 \cong H $$ is an abelian subgroup of $H$. \end{proof}	theorem exercise_3_4_11 {G : Type} [group G] [is_solvable G] {H : subgroup G} (hH : H ≠ ⊥) [H.normal] : ∃ A ≤ H, A.normal ∧ ∀ a b : A, ab = b*a :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_3_26	Let $G$ be a transitive permutation group on the finite set $A$ with $\|A\|>1$. Show that there is some $\sigma \in G$ such that $\sigma(a) \neq a$ for all $a \in A$.	\begin{proof} Let $G$ be a transitive permutation group on the finite set $A,\|A\|>1$. We want to find an element $\sigma$ which doesn't stabilize anything, that is, we want a $\sigma$ such that $$ \sigma \notin G_a $$ for all $a \in A$. Since the group is transitive, there is always a $g \in G$ such that $b=g \cdot a$. Let us see in what relationship the stabilizers of $a$ and $b$ are. We find $$ \begin{aligned} G_b & =\{h \in G \mid h \cdot b=b\} \\ & =\{h \in G \mid h g \cdot a=g \cdot a\} \\ & =\left\{h \in G \mid g^{-1} h g \cdot a=a\right\} \end{aligned} $$ Putting $h^{\prime}=g^{-1} h g$, we have $h=g h^{\prime} g^{-1}$ and $$ \begin{aligned} G_b & =g\left\{h^{\prime} \in H \mid h^{\prime} \cdot a=a\right\} g^{-1} \\ & =g G_a g^{-1} \end{aligned} $$ By the above, the stabilizer subgroup of any element is conjugate to some other stabilizer subgroup. Now, the stabilizer cannot be all of $G$ (else $\{a\}$ would be a orbit). Thus it is a proper subgroup of $G$. By the previous exercise, we have $$ \bigcup_{a \in A} G_a=\bigcup_{g \in G} g G_a g^{-1} \subset G $$ (the union of conjugates of a proper subgroup can never be all of $G$ ). This shows there is an element $\sigma$ which is not in any stabilizer of any element of $A$. Then $\sigma(a) \neq a$ for all $a \in A$, as we wanted to show. \end{proof}	theorem exercise_4_3_26 {α : Type*} [fintype α] (ha : fintype.card α > 1) (h_tran : ∀ a b: α, ∃ σ : equiv.perm α, σ a = b) : ∃ σ : equiv.perm α, ∀ a : α, σ a ≠ a :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_2_14	Let $G$ be a finite group of composite order $n$ with the property that $G$ has a subgroup of order $k$ for each positive integer $k$ dividing $n$. Prove that $G$ is not simple.	\begin{proof} Solution: Let $p$ be the smallest prime dividing $n$, and write $n=p m$. Now $G$ has a subgroup $H$ of order $m$, and $H$ has index $p$. Then $H$ is normal in $G$. \end{proof}	theorem exercise_4_2_14 {G : Type*} [fintype G] [group G] (hG : ¬ (card G).prime) (hG1 : ∀ k ∣ card G, ∃ (H : subgroup G) (fH : fintype H), @card H fH = k) : ¬ is_simple_group G :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_4_6a	Prove that characteristic subgroups are normal.	\begin{proof} Let $H$ be a characterestic subgroup of $G$. By definition $\alpha(H) \subset H$ for every $\alpha \in \operatorname{Aut}(G)$. So, $H$ is in particular invariant under the inner automorphism. Let $\phi_g$ denote the conjugation automorphism by $g$. Then $\phi_g(H) \subset H \Longrightarrow$ $g H g^{-1} \subset H$. So, $H$ is normal. \end{proof}	theorem exercise_4_4_6a {G : Type*} [group G] (H : subgroup G) [subgroup.characteristic H] : subgroup.normal H :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_4_7	If $H$ is the unique subgroup of a given order in a group $G$ prove $H$ is characteristic in $G$.	\begin{proof} Let $G$ be group and $H$ be the unique subgroup of order $n$. Now, let $\sigma \in \operatorname{Aut}(G)$. Now Clearly $\|\sigma(G)\|=n$, because $\sigma$ is a one-one onto map. But then as $H$ is the only subgroup of order $n$, and because of the fact that a automorphism maps subgroups to subgroups, we have $\sigma(H)=$ $H$ for every $\sigma \in \operatorname{Aut}(G)$. Hence, $H$ is a characterestic subgroup of $G$. \end{proof}	theorem exercise_4_4_7 {G : Type*} [group G] {H : subgroup G} [fintype H] (hH : ∀ (K : subgroup G) (fK : fintype K), card H = @card K fK → H = K) : H.characteristic :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_5_1a	Prove that if $P \in \operatorname{Syl}_{p}(G)$ and $H$ is a subgroup of $G$ containing $P$ then $P \in \operatorname{Syl}_{p}(H)$.	\begin{proof} If $P \leq H \leq G$ is a Sylow $p$-subgroup of $G$, then $p$ does not divide $[G: P]$. Now $[G: P]=[G: H][H: P]$, so that $p$ does not divide $[H: P]$; hence $P$ is a Sylow $p$-subgroup of $H$. \end{proof}	theorem exercise_4_5_1a {p : ℕ} {G : Type*} [group G] {P : subgroup G} (hP : is_p_group p P) (H : subgroup G) (hH : P ≤ H) : is_p_group p H :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_5_14	Prove that a group of order 312 has a normal Sylow $p$-subgroup for some prime $p$ dividing its order.	\begin{proof} Since $\|G\|=351=3^{2}.13$, $G$ has $3-$Sylow subgroup of order $9$, as well as $13-$Sylow subgroup of order $13$. Now, we count the number of such subgroups. Let $n_{13}$ be the number of $13-$Sylow subgroup and $n_{3}$ be the number of $3-$Sylow subgroup. Now $n_{13}=1+13k$ where $1+13k\|9$. The choices for $k$ is $0$. Hence, there is a unique $13-$Sylow subgroup and hence is normal. \end{proof}	theorem exercise_4_5_14 {G : Type*} [group G] [fintype G] (hG : card G = 312) : ∃ (p : ℕ) (P : sylow p G), P.normal :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_5_16	Let $\|G\|=p q r$, where $p, q$ and $r$ are primes with $p<q<r$. Prove that $G$ has a normal Sylow subgroup for either $p, q$ or $r$.	\begin{proof} Let $\|G\|=p q r$. We also assume $p<q<r$. We prove that $G$ has a normal Sylow subgroup of $p$, $q$ or $r$. Now, Let $n_p, n_q, n_r$ be the number of Sylow-p subgroup, Sylow-q subgroup, Sylow-r subgroup resp. So, we have $n_r=1+r k$ such that $1+r k \mid p q$. So, in this case as $r$ is greatest $n_r$ can be 1 or $p q$. We assume $n_r=p q$. Now we have $n_q=1+q k$ such that $1+q k \mid p r$. Now,as $p<q<r, n_q$ can be 1 or $r$, or $p r$. Assume that $n_q=r$. Now we turn to $n_p$. Again my similar method we can conclude $n_p$ can be $1, q, r$, or $q r$. We assume that $n_p$ is $q$. Now we count the number of elements of order $p, q, r$. Since $n_r=p q$, the number of elements of order $r$ is $p q(r-1)$. Since $n_q=r$, the number of elements of order $q$ is $(q-1) r$. And as $n_p=q$, the number of elements of order $p$ is $(p-1) q$. So, in total we get $p q(r-1)+(q-1) r+(p-$ 1) $q=p q r+q r-r-q=p q r+r(q-1)-r$. But observe that as $q>1, r(q-1)-r>$ 0 . So the number of elements exceeds $p q r$. So, it proves that atleast $n_p$ or $n_q$ or $n_r$ is 1, which ultimately proves the result, because a unique Sylow-p subgroup is always normal. \end{proof}	theorem exercise_4_5_16 {p q r : ℕ} {G : Type} [group G] [fintype G] (hpqr : p < q ∧ q < r) (hpqr1 : p.prime ∧ q.prime ∧ r.prime)(hG : card G = pq*r) : nonempty (sylow p G) ∨ nonempty(sylow q G) ∨ nonempty(sylow r G) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_5_18	Prove that a group of order 200 has a normal Sylow 5-subgroup.	\begin{proof} Let $G$ be a group of order $200=5^2 \cdot 8$. Note that 5 is a prime not dividing 8 . Let $P \in$ $S y l_5(G)$. [We know $P$ exists since $S y l_5(G) \neq \emptyset$ by Sylow's Theorem] The number of Sylow 5-subgroups of $G$ is of the form $1+k \cdot 5$, i.e., $n_5 \equiv 1(\bmod 5)$ and $n_5$ divides 8 . The only such number that divides 8 and equals $1 (\bmod 5)$ is 1 so $n_5=1$. Hence $P$ is the unique Sylow 5-subgroup. Since $P$ is the unique Sylow 5-subgroup, this implies that $P$ is normal in $G$. \end{proof}	theorem exercise_4_5_18 {G : Type*} [fintype G] [group G] (hG : card G = 200) : ∃ N : sylow 5 G, N.normal :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_5_20	Prove that if $\|G\|=1365$ then $G$ is not simple.	\begin{proof} Since $\|G\|=1365=3.5.7.13$, $G$ has $13-$Sylow subgroup of order $13$. Now, we count the number of such subgroups. Let $n_{13}$ be the number of $13-$Sylow subgroup. Now $n_{13}=1+13k$ where $1+13k\|3.5.7$. The choices for $k$ is $0$. Hence, there is a unique $13-$Sylow subgroup and hence is normal. so $G$ is not simple. \end{proof}	theorem exercise_4_5_20 {G : Type*} [fintype G] [group G] (hG : card G = 1365) : ¬ is_simple_group G :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_5_22	Prove that if $\|G\|=132$ then $G$ is not simple.	\begin{proof} Since $\|G\|=132=2^{2}.3.11$, $G$ has $2-$Sylow subgroup of order $4$, as well as $11-$Sylow subgroup of order $11$, and $3-$Sylow subgroup of order $3$. Now, we count the number of such subgroups. Let $n_{11}$ be the number of $11-$Sylow subgroup and $n_{3}$ be the number of $3-$Sylow subgroup. Now $n_{11}=1+11k$ where $1+11k\|12$. The choices for $k$ are $0$ or $1$. If $k=0$, there is only one $11-$Sylow subgroup and hence normal. So, assume now, that there are $12$ $11-$Sylow subgroup(for $k=1$). Now we look at $3-$ Sylow subgroups. $n_{3}=1+3k\| 44$. So choice for $k$ are $0$, $1$, and $7$. If $k=0$, there is only one $3-$Sylow subgroup and hence normal. So, assume now, that there are $4$ $2-$Sylow subgroup (for $k=3$). Now we claim that simultaneously, there cannot be $12$ $11-$Sylow subgroup and $4$ $3-$Sylow subgroups provided there is more than one $2-$Sylow subgroups. So, either $2-$Sylow subgroup is normal or if not, then, either $11-$Sylow subgroup is normal being unique, or the $3-$Sylow subgroup is normal(We don't consider the possibility of $22$ $3-$Sylow subgroup because of obvious reason). Now, to prove the claim, we observe that there are $120$ elements of order $11$. Also there are $8$ elements of order $3$. So we already get $120+8+1=129$ distinct elements in the group. Let us count the number of $2-$Sylow subgroups in $G$. $n_{2}=1+2k\|33$. The possibilities for $k$ are $0$, $1$, $5$, $16$. Now, assume there is more than one $2-$Sylow subgroups. Let $H_{1}$ and $H_{2}$ be two distinct $2-$Sylow subgroup. Now $\|H_{1}\|=4$. So we already get $129+3=132$ distinct elements in the group. Now $H_{2}$ being distinct from $H_{1}$, has at least one element which is not in $H_{1}$. This adds one more element in the group, at the least. Now already we have number of elements in the group exceeding the number of element in $G$. This gives a contradiction and proves the claim. Hence $G$ is not simple. \end{proof}	theorem exercise_4_5_22 {G : Type*} [fintype G] [group G] (hG : card G = 132) : ¬ is_simple_group G :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_4_5_28	Let $G$ be a group of order 105. Prove that if a Sylow 3-subgroup of $G$ is normal then $G$ is abelian.	\begin{proof} Given that $G$ is a group of order $1575=3^2 .5^2 .7$. Now, Let $n_p$ be the number of Sylow-p subgroups. It is given that Sylow-3 subgroup is normal and hence is unique, so $n_3=1$. First we prove that both Sylow-5 subgroup and Sylow 7-subgroup are normal. Let $P$ be the Sylow3 subgroup. Now, Consider $G / P$, which has order $5^2 .7$. Now, the number of Sylow $-5$ subgroup of $G / P$ is given by $1+5 k$, where $1+5 k \mid 7$. Clearly $k=0$ is the only choice and hence there is a unique Sylow-5 subgroup of $G / P$, and hence normal. In the same way Sylow-7 subgroup of $G / P$ is also unique and hence normal. Consider now the canonical map $\pi: G \rightarrow G / P$. The inverse image of Sylow-5 subgroup of $G / P$ under $\pi$, call it $H$, is a normal subgroup of $G$, and $\|H\|=3^2 .5^2$. Similarly, the inverse image of Sylow-7 subgroup of $G / P$ under $\pi$ call it $K$ is also normal in $G$ and $\|K\|=3^2 .7$. Now, consider $H$. Observe first that the number of Sylow-5 subgroup in $H$ is $1+5 k$ such that $1+5 k \mid 9$. Again $k=0$ and hence $H$ has a unique Sylow-5 subgroup, call it $P_1$. But, it is easy to see that $P_1$ is also a Sylow-5 subgroup of $G$, because $\left\|P_1\right\|=25$. But now any other Sylow 5 subgroup of $G$ is of the form $g P_1 g^{-1}$ for some $g \in G$. But observe that since $P_1 \subset H$ and $H$ is normal in $G$, so $g P_1 g^1 \subset H$, and $g P_1 g^{-1}$ is also Sylow-5 subgroup of $H$. But, then as Sylow-5 subgroup of $H$ is unique we have $g P_1 g^{-1}=P_1$. This shows that Sylow-5 subgroup of $G$ is unique and hence normal in $G$. Similarly, one can argue the same for $K$ and deduce that Sylow-7 subgroup of $G$ is unique and hence normal. So, the first part of the problem is done. \end{proof}	theorem exercise_4_5_28 {G : Type*} [group G] [fintype G] (hG : card G = 105) (P : sylow 3 G) [hP : P.normal] : comm_group G :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_5_4_2	Prove that a subgroup $H$ of $G$ is normal if and only if $[G, H] \leq H$.	\begin{proof} $H \unlhd G$ is equivalent to $g^{-1} h g \in H, \forall g \in G, \forall h \in H$. We claim that holds if and only if $h^{-1} g^{-1} h g \in H, \forall g \in G, \forall h \in H$, i.e., $\left\{h^{-1} g^{-1} h g: h \in H, g \in G\right\} \subseteq H$. That holds by the following argument: If $g^{-1} h g \in H, \forall g \in G, \forall h \in H$, note that $h^{-1} \in H$, so multiplying them, we also obtain an element of $H$. On the other hand, if $h^{-1} g^{-1} h g \in H, \forall g \in G, \forall h \in H$, then $$ h h^{-1} g^{-1} h g=g^{-1} h g \in H, \forall g \in G, \forall h \in H . $$ Since $\left\{h^{-1} g^{-1} h g: h \in H, g \in G\right\} \subseteq H \Leftrightarrow\left\langle\left\{h^{-1} g^{-1} h g: h \in H, g \in G\right\}\right\rangle \leq H$, we've solved the exercise by definition of $[H, G]$. \end{proof}	theorem exercise_5_4_2 {G : Type*} [group G] (H : subgroup G) : H.normal ↔ ⁅(⊤ : subgroup G), H⁆ ≤ H :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_7_1_11	Prove that if $R$ is an integral domain and $x^{2}=1$ for some $x \in R$ then $x=\pm 1$.	\begin{proof} Solution: If $x^2=1$, then $x^2-1=0$. Evidently, then, $$ (x-1)(x+1)=0 . $$ Since $R$ is an integral domain, we must have $x-1=0$ or $x+1=0$; thus $x=1$ or $x=-1$. \end{proof}	theorem exercise_7_1_11 {R : Type*} [ring R] [is_domain R] {x : R} (hx : x^2 = 1) : x = 1 ∨ x = -1 :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_7_1_15	A ring $R$ is called a Boolean ring if $a^{2}=a$ for all $a \in R$. Prove that every Boolean ring is commutative.	\begin{proof} Solution: Note first that for all $a \in R$, $$ -a=(-a)^2=(-1)^2 a^2=a^2=a . $$ Now if $a, b \in R$, we have $$ a+b=(a+b)^2=a^2+a b+b a+b^2=a+a b+b a+b . $$ Thus $a b+b a=0$, and we have $a b=-b a$. But then $a b=b a$. Thus $R$ is commutative. \end{proof}	theorem exercise_7_1_15 {R : Type*} [ring R] (hR : ∀ a : R, a^2 = a) : comm_ring R :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_7_2_12	Let $G=\left\{g_{1}, \ldots, g_{n}\right\}$ be a finite group. Prove that the element $N=g_{1}+g_{2}+\ldots+g_{n}$ is in the center of the group ring $R G$.	\begin{proof} Let $M=\sum_{i=1}^n r_i g_i$ be an element of $R[G]$. Note that for each $g_i \in G$, the action of $g_i$ on $G$ by conjugation permutes the subscripts. Then we have the following. $$ \begin{aligned} N M &=\left(\sum_{i=1}^n g_i\right)\left(\sum_{j=1}^n r_j g_j\right) \\ &=\sum_{j=1}^n \sum_{i=1}^n r_j g_i g_j \\ &=\sum_{j=1}^n \sum_{i=1}^n r_j g_j g_j^{-1} g_i g_j \\ &=\sum_{j=1}^n r_j g_j\left(\sum_{i=1}^n g_j^{-1} g_i g_j\right) \\ &=\sum_{j=1}^n r_j g_j\left(\sum_{i=1}^n g_i\right) \\ &=\left(\sum_{j=1}^n r_j g_j\right)\left(\sum_{i=1}^n g_i\right) \\ &=M N . \end{aligned} $$ Thus $N \in Z(R[G])$. \end{proof}	theorem exercise_7_2_12 {R G : Type*} [ring R] [group G] [fintype G] : ∑ g : G, monoid_algebra.of R G g ∈ center (monoid_algebra R G) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_7_3_37	An ideal $N$ is called nilpotent if $N^{n}$ is the zero ideal for some $n \geq 1$. Prove that the ideal $p \mathbb{Z} / p^{m} \mathbb{Z}$ is a nilpotent ideal in the ring $\mathbb{Z} / p^{m} \mathbb{Z}$.	\begin{proof} First we prove a lemma. Lemma: Let $R$ be a ring, and let $I_1, I_2, J \subseteq R$ be ideals such that $J \subseteq I_1, I_2$. Then $\left(I_1 / J\right)\left(I_2 / J\right)=I_1 I_2 / J$. Proof: ( $\subseteq$ ) Let $$ \alpha=\sum\left(x_i+J\right)\left(y_i+J\right) \in\left(I_1 / J\right)\left(I_2 / J\right) . $$ Then $$ \alpha=\sum\left(x_i y_i+J\right)=\left(\sum x_i y_i\right)+J \in\left(I_1 I_2\right) / J . $$ Now let $\alpha=\left(\sum x_i y_i\right)+J \in\left(I_1 I_2\right) / J$. Then $$ \alpha=\sum\left(x_i+J\right)\left(y_i+J\right) \in\left(I_1 / J\right)\left(I_2 / J\right) . $$ From this lemma and the lemma to Exercise 7.3.36, it follows by an easy induction that $$ \left(p \mathbb{Z} / p^m \mathbb{Z}\right)^m=(p \mathbb{Z})^m / p^m \mathbb{Z}=p^m \mathbb{Z} / p^m \mathbb{Z} \cong 0 . $$ Thus $p \mathbb{Z} / p^m \mathbb{Z}$ is nilpotent in $\mathbb{Z} / p^m \mathbb{Z}$. \end{proof}	theorem exercise_7_3_37 {R : Type*} {p m : ℕ} (hp : p.prime) (N : ideal $ zmod $ p^m) : is_nilpotent N ↔ is_nilpotent (ideal.span ({p} : set $ zmod $ p^m)) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_8_1_12	Let $N$ be a positive integer. Let $M$ be an integer relatively prime to $N$ and let $d$ be an integer relatively prime to $\varphi(N)$, where $\varphi$ denotes Euler's $\varphi$-function. Prove that if $M_{1} \equiv M^{d} \pmod N$ then $M \equiv M_{1}^{d^{\prime}} \pmod N$ where $d^{\prime}$ is the inverse of $d \bmod \varphi(N)$: $d d^{\prime} \equiv 1 \pmod {\varphi(N)}$.	\begin{proof} Note that there is some $k \in \mathbb{Z}$ such that $M^{d d^{\prime}} \equiv M^{k \varphi(N)+1} \equiv\left(M^{\varphi(N)}\right)^k \cdot M \bmod N$. By Euler's Theorem we have $M^{\varphi(N)} \equiv 1 \bmod N$, so that $M_1^{d^{\prime}} \equiv M \bmod N$. \end{proof}	theorem exercise_8_1_12 {N : ℕ} (hN : N > 0) {M M': ℤ} {d : ℕ} (hMN : M.gcd N = 1) (hMd : d.gcd N.totient = 1) (hM' : M' ≡ M^d [ZMOD N]) : ∃ d' : ℕ, d' * d ≡ 1 [ZMOD N.totient] ∧ M ≡ M'^d' [ZMOD N] :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_8_3_4	Prove that if an integer is the sum of two rational squares, then it is the sum of two integer squares.	\begin{proof} Let $n=\frac{a^2}{b^2}+\frac{c^2}{d^2}$, or, equivalently, $n(b d)^2=a^2 d^2+c^2 b^2$. From this, we see that $n(b d)^2$ can be written as a sum of two squared integers. Therefore, if $q \equiv 3(\bmod 4)$ and $q^i$ appears in the prime power factorization of $n, i$ must be even. Let $j \in \mathbb{N} \cup\{0\}$ such that $q^j$ divides $b d$. Then $q^{i-2 j}$ divides $n$. But since $i$ is even, $i-2 j$ is even as well. Consequently, $n$ can be written as a sum of two squared integers. \end{proof}	theorem exercise_8_3_4 {R : Type*} {n : ℤ} {r s : ℚ} (h : r^2 + s^2 = n) : ∃ a b : ℤ, a^2 + b^2 = n :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_8_3_6a	Prove that the quotient ring $\mathbb{Z}[i] /(1+i)$ is a field of order 2.	\begin{proof} Let $a+b i \in \mathbb{Z}[i]$. If $a \equiv b \bmod 2$, then $a+b$ and $b-a$ are even and $(1+i)\left(\frac{a+b}{2}+\frac{b-a}{2} i\right)=a+b i \in\langle 1+i\rangle$. If $a \not \equiv b \bmod 2$ then $a-1+b i \in\langle 1+i\rangle$. Therefore every element of $\mathbb{Z}[i]$ is in either $\langle 1+i\rangle$ or $1+\langle 1+i\rangle$, so $\mathbb{Z}[i] /\langle 1+i\rangle$ is a finite ring of order 2 , which must be a field. \end{proof}	theorem exercise_8_3_6a {R : Type*} [ring R] (hR : R = (gaussian_int ⧸ ideal.span ({⟨0, 1⟩} : set gaussian_int))) : is_field R ∧ ∃ finR : fintype R, @card R finR = 2 :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_9_1_6	Prove that $(x, y)$ is not a principal ideal in $\mathbb{Q}[x, y]$.	\begin{proof} Suppose, to the contrary, that $(x, y)=p$ for some polynomial $p \in \mathbb{Q}[x, y]$. From $x, y \in$ $(x, y)=(p)$ there are $s, t \in \mathbb{Q}[x, y]$ such that $x=s p$ and $y=t p$. Then: $$ \begin{aligned} & 0=\operatorname{deg}_y(x)=\operatorname{deg}_y(s)+\operatorname{deg}_y(p) \text { so } \\ & 0=\operatorname{deg}_y(p) \\ & 0=\operatorname{deg}_x(y)=\operatorname{deg}_x(s)+\operatorname{deg}_x(p) \text { so } \\ & 0=\operatorname{deg}_x(p) \text { so } \end{aligned} $$ From : $\quad 0=\operatorname{deg}_y(p)=\operatorname{deg}_x(p)$ we get $\operatorname{deg}(p)=0$ and $p \in \mathbb{Q}$. But $p \in(p)=(x, y)$ so $p=a x+b y$ for some $a, b \in \mathbb{Q}[x, y]$ $$ \begin{aligned} \operatorname{deg}(p) & =\operatorname{deg}(a x+b y) \\ & =\min (\operatorname{deg}(a)+\operatorname{deg}(x), \operatorname{deg}(b)+\operatorname{deg}(y)) \\ & =\min (\operatorname{deg}(a)+1, \operatorname{deg}(b)+1) \geqslant 1 \end{aligned} $$ which contradicts $\operatorname{deg}(p)=0$. So we conclude that $(x, y)$ is not principal ideal in $\mathbb{Q}[x, y]$ \end{proof}	theorem exercise_9_1_6 : ¬ is_principal (ideal.span ({X 0, X 1} : set (mv_polynomial (fin 2) ℚ))) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_9_3_2	Prove that if $f(x)$ and $g(x)$ are polynomials with rational coefficients whose product $f(x) g(x)$ has integer coefficients, then the product of any coefficient of $g(x)$ with any coefficient of $f(x)$ is an integer.	\begin{proof} Let $f(x), g(x) \in \mathbb{Q}[x]$ be such that $f(x) g(x) \in \mathbb{Z}[x]$. By Gauss' Lemma there exists $r, s \in \mathbb{Q}$ such that $r f(x), s g(x) \in \mathbb{Z}[x]$, and $(r f(x))(s g(x))=r s f(x) g(x)=f(x) g(x)$. From this last relation we can conclude that $s=r^{-1}$. Therefore for any coefficient $f_i$ of $f(x)$ and $g_j$ of $g(x)$ we have that $r f_i, r^{-1} g_j \in$ $\mathbb{Z}$ and by multiplicative closure and commutativity of $\mathbb{Z}$ we have that $r f_i r^{-1} g_j=$ $f_i g_j \in \mathbb{Z}$ \end{proof}	theorem exercise_9_3_2 {f g : polynomial ℚ} (i j : ℕ) (hfg : ∀ n : ℕ, ∃ a : ℤ, (fg).coeff = a) : ∃ a : ℤ, f.coeff i g.coeff j = a :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_9_4_2b	Prove that $x^6+30x^5-15x^3 + 6x-120$ is irreducible in $\mathbb{Z}[x]$.	\begin{proof} $$ x^6+30 x^5-15 x^3+6 x-120 $$ The coefficients of the low order.: $30,-15,0,6,-120$ They are divisible by the prime 3 , but $3^2=9$ doesn 't divide $-120$. So this polynomial is irreducible over $\mathbb{Z}$. \end{proof}	theorem exercise_9_4_2b : irreducible (X^6 + 30X^5 - 15X^3 + 6*X - 120 : polynomial ℤ) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_9_4_2d	Prove that $\frac{(x+2)^p-2^p}{x}$, where $p$ is an odd prime, is irreducible in $\mathbb{Z}[x]$.	\begin{proof} $\frac{(x+2)^p-2^p}{x} \quad \quad p$ is on add pprime $Z[x]$ $$ \frac{(x+2)^p-2^p}{x} \quad \text { as a polynomial we expand }(x+2)^p $$ $2^p$ cancels with $-2^p$, every remaining term has $x$ as $a$ factor $$ \begin{aligned} & x^{p-1}+2\left(\begin{array}{l} p \\ 1 \end{array}\right) x^{p-2}+2^2\left(\begin{array}{l} p \\ 2 \end{array}\right) x^{p-3}+\ldots+2^{p-1}\left(\begin{array}{c} p \\ p-1 \end{array}\right) \\ & 2^k\left(\begin{array}{l} p \\ k \end{array}\right) x^{p-k-1}=2^k \cdot p \cdot(p-1) \ldots(p-k-1), \quad 0<k<p \end{aligned} $$ Every lower order coef. has $p$ as a factor but doesnt have $\$ \mathrm{p}^{\wedge} 2 \$$ as a fuction so the polynomial is irreducible by Eisensteins Criterion. \end{proof}	theorem exercise_9_4_2d {p : ℕ} (hp : p.prime ∧ p > 2) {f : polynomial ℤ} (hf : f = (X + 2)^p): irreducible (∑ n in (f.support \ {0}), (f.coeff n) * X ^ (n-1) : polynomial ℤ) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory
Dummit-Foote\|exercise_9_4_11	Prove that $x^2+y^2-1$ is irreducible in $\mathbb{Q}[x,y]$.	\begin{proof} $$ p(x)=x^2+y^2-1 \in Q[y][x] \cong Q[y, x] $$ We have that $y+1 \in Q[y]$ is prime and $Q[y]$ is an UFD, since $p(x)=x^2+y^2-1=x^2+$ $(y+1)(y-1)$ by the Eisenstein criterion $x^2+y^2-1$ is irreducibile in $Q[x, y]$. \end{proof}	theorem exercise_9_4_11 : irreducible ((X 0)^2 + (X 1)^2 - 1 : mv_polynomial (fin 2) ℚ) :=	import .common open set function nat int fintype real polynomial mv_polynomial open subgroup ideal submodule zsqrtd gaussian_int char_p mul_aut matrix open_locale pointwise open_locale big_operators noncomputable theory

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