(* Title: HOL/ex/HarmonicSeries.thy
Author: Benjamin Porter, 2006
*)
header {* Divergence of the Harmonic Series *}
theory HarmonicSeries
imports Complex_Main
begin
subsection {* Abstract *}
text {* The following document presents a proof of the Divergence of
Harmonic Series theorem formalised in the Isabelle/Isar theorem
proving system.
{\em Theorem:} The series $\sum_{n=1}^{\infty} \frac{1}{n}$ does not
converge to any number.
{\em Informal Proof:}
The informal proof is based on the following auxillary lemmas:
\begin{itemize}
\item{aux: $\sum_{n=2^m-1}^{2^m} \frac{1}{n} \geq \frac{1}{2}$}
\item{aux2: $\sum_{n=1}^{2^M} \frac{1}{n} = 1 + \sum_{m=1}^{M} \sum_{n=2^m-1}^{2^m} \frac{1}{n}$}
\end{itemize}
From {\em aux} and {\em aux2} we can deduce that $\sum_{n=1}^{2^M}
\frac{1}{n} \geq 1 + \frac{M}{2}$ for all $M$.
Now for contradiction, assume that $\sum_{n=1}^{\infty} \frac{1}{n}
= s$ for some $s$. Because $\forall n. \frac{1}{n} > 0$ all the
partial sums in the series must be less than $s$. However with our
deduction above we can choose $N > 2*s - 2$ and thus
$\sum_{n=1}^{2^N} \frac{1}{n} > s$. This leads to a contradiction
and hence $\sum_{n=1}^{\infty} \frac{1}{n}$ is not summable.
QED.
*}
subsection {* Formal Proof *}
lemma two_pow_sub:
"0 < m \<Longrightarrow> (2::nat)^m - 2^(m - 1) = 2^(m - 1)"
by (induct m) auto
text {* We first prove the following auxillary lemma. This lemma
simply states that the finite sums: $\frac{1}{2}$, $\frac{1}{3} +
\frac{1}{4}$, $\frac{1}{5} + \frac{1}{6} + \frac{1}{7} + \frac{1}{8}$
etc. are all greater than or equal to $\frac{1}{2}$. We do this by
observing that each term in the sum is greater than or equal to the
last term, e.g. $\frac{1}{3} > \frac{1}{4}$ and thus $\frac{1}{3} +
\frac{1}{4} > \frac{1}{4} + \frac{1}{4} = \frac{1}{2}$. *}
lemma harmonic_aux:
"\<forall>m>0. (\<Sum>n\<in>{(2::nat)^(m - 1)+1..2^m}. 1/real n) \<ge> 1/2"
(is "\<forall>m>0. (\<Sum>n\<in>(?S m). 1/real n) \<ge> 1/2")
proof
fix m::nat
obtain tm where tmdef: "tm = (2::nat)^m" by simp
{
assume mgt0: "0 < m"
have "\<And>x. x\<in>(?S m) \<Longrightarrow> 1/(real x) \<ge> 1/(real tm)"
proof -
fix x::nat
assume xs: "x\<in>(?S m)"
have xgt0: "x>0"
proof -
from xs have
"x \<ge> 2^(m - 1) + 1" by auto
moreover with mgt0 have
"2^(m - 1) + 1 \<ge> (1::nat)" by auto
ultimately have
"x \<ge> 1" by (rule xtrans)
thus ?thesis by simp
qed
moreover from xs have "x \<le> 2^m" by auto
ultimately have
"inverse (real x) \<ge> inverse (real ((2::nat)^m))"
by (simp del: real_of_nat_power)
moreover
from xgt0 have "real x \<noteq> 0" by simp
then have
"inverse (real x) = 1 / (real x)"
by (rule nonzero_inverse_eq_divide)
moreover from mgt0 have "real tm \<noteq> 0" by (simp add: tmdef)
then have
"inverse (real tm) = 1 / (real tm)"
by (rule nonzero_inverse_eq_divide)
ultimately show
"1/(real x) \<ge> 1/(real tm)" by (auto simp add: tmdef)
qed
then have
"(\<Sum>n\<in>(?S m). 1 / real n) \<ge> (\<Sum>n\<in>(?S m). 1/(real tm))"
by (rule setsum_mono)
moreover have
"(\<Sum>n\<in>(?S m). 1/(real tm)) = 1/2"
proof -
have
"(\<Sum>n\<in>(?S m). 1/(real tm)) =
(1/(real tm))*(\<Sum>n\<in>(?S m). 1)"
by simp
also have
"\<dots> = ((1/(real tm)) * real (card (?S m)))"
by (simp add: real_of_card real_of_nat_def)
also have
"\<dots> = ((1/(real tm)) * real (tm - (2^(m - 1))))"
by (simp add: tmdef)
also from mgt0 have
"\<dots> = ((1/(real tm)) * real ((2::nat)^(m - 1)))"
by (auto simp: tmdef dest: two_pow_sub)
also have
"\<dots> = (real (2::nat))^(m - 1) / (real (2::nat))^m"
by (simp add: tmdef)
also from mgt0 have
"\<dots> = (real (2::nat))^(m - 1) / (real (2::nat))^((m - 1) + 1)"
by auto
also have "\<dots> = 1/2" by simp
finally show ?thesis .
qed
ultimately have
"(\<Sum>n\<in>(?S m). 1 / real n) \<ge> 1/2"
by - (erule subst)
}
thus "0 < m \<longrightarrow> 1 / 2 \<le> (\<Sum>n\<in>(?S m). 1 / real n)" by simp
qed
text {* We then show that the sum of a finite number of terms from the
harmonic series can be regrouped in increasing powers of 2. For
example: $1 + \frac{1}{2} + \frac{1}{3} + \frac{1}{4} + \frac{1}{5} +
\frac{1}{6} + \frac{1}{7} + \frac{1}{8} = 1 + (\frac{1}{2}) +
(\frac{1}{3} + \frac{1}{4}) + (\frac{1}{5} + \frac{1}{6} + \frac{1}{7}
+ \frac{1}{8})$. *}
lemma harmonic_aux2 [rule_format]:
"0<M \<Longrightarrow> (\<Sum>n\<in>{1..(2::nat)^M}. 1/real n) =
(1 + (\<Sum>m\<in>{1..M}. \<Sum>n\<in>{(2::nat)^(m - 1)+1..2^m}. 1/real n))"
(is "0<M \<Longrightarrow> ?LHS M = ?RHS M")
proof (induct M)
case 0 show ?case by simp
next
case (Suc M)
have ant: "0 < Suc M" by fact
{
have suc: "?LHS (Suc M) = ?RHS (Suc M)"
proof cases -- "show that LHS = c and RHS = c, and thus LHS = RHS"
assume mz: "M=0"
{
then have
"?LHS (Suc M) = ?LHS 1" by simp
also have
"\<dots> = (\<Sum>n\<in>{(1::nat)..2}. 1/real n)" by simp
also have
"\<dots> = ((\<Sum>n\<in>{Suc 1..2}. 1/real n) + 1/(real (1::nat)))"
by (subst setsum_head)
(auto simp: atLeastSucAtMost_greaterThanAtMost)
also have
"\<dots> = ((\<Sum>n\<in>{2..2::nat}. 1/real n) + 1/(real (1::nat)))"
by (simp add: eval_nat_numeral)
also have
"\<dots> = 1/(real (2::nat)) + 1/(real (1::nat))" by simp
finally have
"?LHS (Suc M) = 1/2 + 1" by simp
}
moreover
{
from mz have
"?RHS (Suc M) = ?RHS 1" by simp
also have
"\<dots> = (\<Sum>n\<in>{((2::nat)^0)+1..2^1}. 1/real n) + 1"
by simp
also have
"\<dots> = (\<Sum>n\<in>{2::nat..2}. 1/real n) + 1"
by (auto simp: atLeastAtMost_singleton')
also have
"\<dots> = 1/2 + 1"
by simp
finally have
"?RHS (Suc M) = 1/2 + 1" by simp
}
ultimately show "?LHS (Suc M) = ?RHS (Suc M)" by simp
next
assume mnz: "M\<noteq>0"
then have mgtz: "M>0" by simp
with Suc have suc:
"(?LHS M) = (?RHS M)" by blast
have
"(?LHS (Suc M)) =
((?LHS M) + (\<Sum>n\<in>{(2::nat)^M+1..2^(Suc M)}. 1 / real n))"
proof -
have
"{1..(2::nat)^(Suc M)} =
{1..(2::nat)^M}\<union>{(2::nat)^M+1..(2::nat)^(Suc M)}"
by auto
moreover have
"{1..(2::nat)^M}\<inter>{(2::nat)^M+1..(2::nat)^(Suc M)} = {}"
by auto
moreover have
"finite {1..(2::nat)^M}" and "finite {(2::nat)^M+1..(2::nat)^(Suc M)}"
by auto
ultimately show ?thesis
by (auto intro: setsum_Un_disjoint)
qed
moreover
{
have
"(?RHS (Suc M)) =
(1 + (\<Sum>m\<in>{1..M}. \<Sum>n\<in>{(2::nat)^(m - 1)+1..2^m}. 1/real n) +
(\<Sum>n\<in>{(2::nat)^(Suc M - 1)+1..2^(Suc M)}. 1/real n))" by simp
also have
"\<dots> = (?RHS M) + (\<Sum>n\<in>{(2::nat)^M+1..2^(Suc M)}. 1/real n)"
by simp
also from suc have
"\<dots> = (?LHS M) + (\<Sum>n\<in>{(2::nat)^M+1..2^(Suc M)}. 1/real n)"
by simp
finally have
"(?RHS (Suc M)) = \<dots>" by simp
}
ultimately show "?LHS (Suc M) = ?RHS (Suc M)" by simp
qed
}
thus ?case by simp
qed
text {* Using @{thm [source] harmonic_aux} and @{thm [source] harmonic_aux2} we now show
that each group sum is greater than or equal to $\frac{1}{2}$ and thus
the finite sum is bounded below by a value proportional to the number
of elements we choose. *}
lemma harmonic_aux3 [rule_format]:
shows "\<forall>(M::nat). (\<Sum>n\<in>{1..(2::nat)^M}. 1 / real n) \<ge> 1 + (real M)/2"
(is "\<forall>M. ?P M \<ge> _")
proof (rule allI, cases)
fix M::nat
assume "M=0"
then show "?P M \<ge> 1 + (real M)/2" by simp
next
fix M::nat
assume "M\<noteq>0"
then have "M > 0" by simp
then have
"(?P M) =
(1 + (\<Sum>m\<in>{1..M}. \<Sum>n\<in>{(2::nat)^(m - 1)+1..2^m}. 1/real n))"
by (rule harmonic_aux2)
also have
"\<dots> \<ge> (1 + (\<Sum>m\<in>{1..M}. 1/2))"
proof -
let ?f = "(\<lambda>x. 1/2)"
let ?g = "(\<lambda>x. (\<Sum>n\<in>{(2::nat)^(x - 1)+1..2^x}. 1/real n))"
from harmonic_aux have "\<And>x. x\<in>{1..M} \<Longrightarrow> ?f x \<le> ?g x" by simp
then have "(\<Sum>m\<in>{1..M}. ?g m) \<ge> (\<Sum>m\<in>{1..M}. ?f m)" by (rule setsum_mono)
thus ?thesis by simp
qed
finally have "(?P M) \<ge> (1 + (\<Sum>m\<in>{1..M}. 1/2))" .
moreover
{
have
"(\<Sum>m\<in>{1..M}. (1::real)/2) = 1/2 * (\<Sum>m\<in>{1..M}. 1)"
by auto
also have
"\<dots> = 1/2*(real (card {1..M}))"
by (simp only: real_of_card[symmetric])
also have
"\<dots> = 1/2*(real M)" by simp
also have
"\<dots> = (real M)/2" by simp
finally have "(\<Sum>m\<in>{1..M}. (1::real)/2) = (real M)/2" .
}
ultimately show "(?P M) \<ge> (1 + (real M)/2)" by simp
qed
text {* The final theorem shows that as we take more and more elements
(see @{thm [source] harmonic_aux3}) we get an ever increasing sum. By assuming
the sum converges, the lemma @{thm [source] series_pos_less} ( @{thm
series_pos_less} ) states that each sum is bounded above by the
series' limit. This contradicts our first statement and thus we prove
that the harmonic series is divergent. *}
theorem DivergenceOfHarmonicSeries:
shows "\<not>summable (\<lambda>n. 1/real (Suc n))"
(is "\<not>summable ?f")
proof -- "by contradiction"
let ?s = "suminf ?f" -- "let ?s equal the sum of the harmonic series"
assume sf: "summable ?f"
then obtain n::nat where ndef: "n = nat \<lceil>2 * ?s\<rceil>" by simp
then have ngt: "1 + real n/2 > ?s"
proof -
have "\<forall>n. 0 \<le> ?f n" by simp
with sf have "?s \<ge> 0"
by - (rule suminf_0_le, simp_all)
then have cgt0: "\<lceil>2*?s\<rceil> \<ge> 0" by simp
from ndef have "n = nat \<lceil>(2*?s)\<rceil>" .
then have "real n = real (nat \<lceil>2*?s\<rceil>)" by simp
with cgt0 have "real n = real \<lceil>2*?s\<rceil>"
by (auto dest: real_nat_eq_real)
then have "real n \<ge> 2*(?s)" by simp
then have "real n/2 \<ge> (?s)" by simp
then show "1 + real n/2 > (?s)" by simp
qed
obtain j where jdef: "j = (2::nat)^n" by simp
have "\<forall>m\<ge>j. 0 < ?f m" by simp
with sf have "(\<Sum>i\<in>{0..<j}. ?f i) < ?s" by (rule series_pos_less)
then have "(\<Sum>i\<in>{1..<Suc j}. 1/(real i)) < ?s"
apply -
apply (subst(asm) setsum_shift_bounds_Suc_ivl [symmetric])
by simp
with jdef have
"(\<Sum>i\<in>{1..< Suc ((2::nat)^n)}. 1 / (real i)) < ?s" by simp
then have
"(\<Sum>i\<in>{1..(2::nat)^n}. 1 / (real i)) < ?s"
by (simp only: atLeastLessThanSuc_atLeastAtMost)
moreover from harmonic_aux3 have
"(\<Sum>i\<in>{1..(2::nat)^n}. 1 / (real i)) \<ge> 1 + real n/2" by simp
moreover from ngt have "1 + real n/2 > ?s" by simp
ultimately show False by simp
qed
end