ballotlemfmpn

Description: ( FC ) finishes counting at ( M - N ) . (Contributed by Thierry Arnoux, 25-Nov-2016)

	Ref	Expression
Hypotheses	ballotth.m	$⊢ M \in ℕ$
	ballotth.n	$⊢ N \in ℕ$
	ballotth.o	$⊢ O = \{c \in 𝒫 (1 \dots M + N) \| \|c\| = M\}$
	ballotth.p	$⊢ P = (x \in 𝒫 O ⟼ \frac{\|x\|}{\|O\|})$
	ballotth.f	$⊢ F = (c \in O ⟼ (i \in ℤ ⟼ \|(1 \dots i) \cap c\| - \|(1 \dots i) ∖ c\|))$
Assertion	ballotlemfmpn	$⊢ C \in O \to F (C) (M + N) = M - N$

Proof

Step	Hyp	Ref	Expression
1		ballotth.m	$⊢ M \in ℕ$
2		ballotth.n	$⊢ N \in ℕ$
3		ballotth.o	$⊢ O = \{c \in 𝒫 (1 \dots M + N) \| \|c\| = M\}$
4		ballotth.p	$⊢ P = (x \in 𝒫 O ⟼ \frac{\|x\|}{\|O\|})$
5		ballotth.f	$⊢ F = (c \in O ⟼ (i \in ℤ ⟼ \|(1 \dots i) \cap c\| - \|(1 \dots i) ∖ c\|))$
6		id	$⊢ C \in O \to C \in O$
7		nnaddcl	$⊢ (M \in ℕ \land N \in ℕ) \to M + N \in ℕ$
8	1 2 7	mp2an	$⊢ M + N \in ℕ$
9	8	nnzi	$⊢ M + N \in ℤ$
10	9	a1i	$⊢ C \in O \to M + N \in ℤ$
11	1 2 3 4 5 6 10	ballotlemfval	$⊢ C \in O \to F (C) (M + N) = \|(1 \dots M + N) \cap C\| - \|(1 \dots M + N) ∖ C\|$
12		ssrab2	$⊢ \{c \in 𝒫 (1 \dots M + N) \| \|c\| = M\} \subseteq 𝒫 (1 \dots M + N)$
13	3 12	eqsstri	$⊢ O \subseteq 𝒫 (1 \dots M + N)$
14	13	sseli	$⊢ C \in O \to C \in 𝒫 (1 \dots M + N)$
15	14	elpwid	$⊢ C \in O \to C \subseteq (1 \dots M + N)$
16		sseqin2	$⊢ C \subseteq (1 \dots M + N) \leftrightarrow (1 \dots M + N) \cap C = C$
17	15 16	sylib	$⊢ C \in O \to (1 \dots M + N) \cap C = C$
18	17	fveq2d	$⊢ C \in O \to \|(1 \dots M + N) \cap C\| = \|C\|$
19		rabssab	$⊢ \{c \in 𝒫 (1 \dots M + N) \| \|c\| = M\} \subseteq \{c \| \|c\| = M\}$
20	19	sseli	$⊢ C \in \{c \in 𝒫 (1 \dots M + N) \| \|c\| = M\} \to C \in \{c \| \|c\| = M\}$
21	20 3	eleq2s	$⊢ C \in O \to C \in \{c \| \|c\| = M\}$
22		fveqeq2	$⊢ b = C \to (\|b\| = M \leftrightarrow \|C\| = M)$
23		fveqeq2	$⊢ c = b \to (\|c\| = M \leftrightarrow \|b\| = M)$
24	23	cbvabv	$⊢ \{c \| \|c\| = M\} = \{b \| \|b\| = M\}$
25	22 24	elab2g	$⊢ C \in O \to (C \in \{c \| \|c\| = M\} \leftrightarrow \|C\| = M)$
26	21 25	mpbid	$⊢ C \in O \to \|C\| = M$
27	18 26	eqtrd	$⊢ C \in O \to \|(1 \dots M + N) \cap C\| = M$
28		fzfi	$⊢ (1 \dots M + N) \in Fin$
29		hashssdif	$⊢ ((1 \dots M + N) \in Fin \land C \subseteq (1 \dots M + N)) \to \|(1 \dots M + N) ∖ C\| = \|(1 \dots M + N)\| - \|C\|$
30	28 15 29	sylancr	$⊢ C \in O \to \|(1 \dots M + N) ∖ C\| = \|(1 \dots M + N)\| - \|C\|$
31	8	nnnn0i	$⊢ M + N \in ℕ_{0}$
32		hashfz1	$⊢ M + N \in ℕ_{0} \to \|(1 \dots M + N)\| = M + N$
33	31 32	mp1i	$⊢ C \in O \to \|(1 \dots M + N)\| = M + N$
34	33 26	oveq12d	$⊢ C \in O \to \|(1 \dots M + N)\| - \|C\| = M + N - M$
35	1	nncni	$⊢ M \in ℂ$
36	2	nncni	$⊢ N \in ℂ$
37		pncan2	$⊢ (M \in ℂ \land N \in ℂ) \to M + N - M = N$
38	35 36 37	mp2an	$⊢ M + N - M = N$
39	38	a1i	$⊢ C \in O \to M + N - M = N$
40	30 34 39	3eqtrd	$⊢ C \in O \to \|(1 \dots M + N) ∖ C\| = N$
41	27 40	oveq12d	$⊢ C \in O \to \|(1 \dots M + N) \cap C\| - \|(1 \dots M + N) ∖ C\| = M - N$
42	11 41	eqtrd	$⊢ C \in O \to F (C) (M + N) = M - N$

Metamath Proof Explorer

Theorem ballotlemfmpn

Proof