ballotlemscr

Description: The image of ( RC ) by ( SC ) . (Contributed by Thierry Arnoux, 21-Apr-2017)

	Ref	Expression
Hypotheses	ballotth.m	\|- M e. NN
	ballotth.n	\|- N e. NN
	ballotth.o	\|- O = { c e. ~P ( 1 ... ( M + N ) ) \| ( # ` c ) = M }
	ballotth.p	\|- P = ( x e. ~P O \|-> ( ( # ` x ) / ( # ` O ) ) )
	ballotth.f	\|- F = ( c e. O \|-> ( i e. ZZ \|-> ( ( # ` ( ( 1 ... i ) i^i c ) ) - ( # ` ( ( 1 ... i ) \ c ) ) ) ) )
	ballotth.e	\|- E = { c e. O \| A. i e. ( 1 ... ( M + N ) ) 0 < ( ( F ` c ) ` i ) }
	ballotth.mgtn	\|- N < M
	ballotth.i	\|- I = ( c e. ( O \ E ) \|-> inf ( { k e. ( 1 ... ( M + N ) ) \| ( ( F ` c ) ` k ) = 0 } , RR , < ) )
	ballotth.s	\|- S = ( c e. ( O \ E ) \|-> ( i e. ( 1 ... ( M + N ) ) \|-> if ( i <_ ( I ` c ) , ( ( ( I ` c ) + 1 ) - i ) , i ) ) )
	ballotth.r	\|- R = ( c e. ( O \ E ) \|-> ( ( S ` c ) " c ) )
Assertion	ballotlemscr	\|- ( C e. ( O \ E ) -> ( ( S ` C ) " ( R ` C ) ) = C )

Proof

Step	Hyp	Ref	Expression
1		ballotth.m	\|- M e. NN
2		ballotth.n	\|- N e. NN
3		ballotth.o	\|- O = { c e. ~P ( 1 ... ( M + N ) ) \| ( # ` c ) = M }
4		ballotth.p	\|- P = ( x e. ~P O \|-> ( ( # ` x ) / ( # ` O ) ) )
5		ballotth.f	\|- F = ( c e. O \|-> ( i e. ZZ \|-> ( ( # ` ( ( 1 ... i ) i^i c ) ) - ( # ` ( ( 1 ... i ) \ c ) ) ) ) )
6		ballotth.e	\|- E = { c e. O \| A. i e. ( 1 ... ( M + N ) ) 0 < ( ( F ` c ) ` i ) }
7		ballotth.mgtn	\|- N < M
8		ballotth.i	\|- I = ( c e. ( O \ E ) \|-> inf ( { k e. ( 1 ... ( M + N ) ) \| ( ( F ` c ) ` k ) = 0 } , RR , < ) )
9		ballotth.s	\|- S = ( c e. ( O \ E ) \|-> ( i e. ( 1 ... ( M + N ) ) \|-> if ( i <_ ( I ` c ) , ( ( ( I ` c ) + 1 ) - i ) , i ) ) )
10		ballotth.r	\|- R = ( c e. ( O \ E ) \|-> ( ( S ` c ) " c ) )
11	1 2 3 4 5 6 7 8 9 10	ballotlemrval	\|- ( C e. ( O \ E ) -> ( R ` C ) = ( ( S ` C ) " C ) )
12	11	imaeq2d	\|- ( C e. ( O \ E ) -> ( ( S ` C ) " ( R ` C ) ) = ( ( S ` C ) " ( ( S ` C ) " C ) ) )
13	1 2 3 4 5 6 7 8 9	ballotlemsf1o	\|- ( C e. ( O \ E ) -> ( ( S ` C ) : ( 1 ... ( M + N ) ) -1-1-onto-> ( 1 ... ( M + N ) ) /\ `' ( S ` C ) = ( S ` C ) ) )
14	13	simprd	\|- ( C e. ( O \ E ) -> `' ( S ` C ) = ( S ` C ) )
15	14	imaeq1d	\|- ( C e. ( O \ E ) -> ( `' ( S ` C ) " ( ( S ` C ) " C ) ) = ( ( S ` C ) " ( ( S ` C ) " C ) ) )
16	13	simpld	\|- ( C e. ( O \ E ) -> ( S ` C ) : ( 1 ... ( M + N ) ) -1-1-onto-> ( 1 ... ( M + N ) ) )
17		f1of1	\|- ( ( S ` C ) : ( 1 ... ( M + N ) ) -1-1-onto-> ( 1 ... ( M + N ) ) -> ( S ` C ) : ( 1 ... ( M + N ) ) -1-1-> ( 1 ... ( M + N ) ) )
18	16 17	syl	\|- ( C e. ( O \ E ) -> ( S ` C ) : ( 1 ... ( M + N ) ) -1-1-> ( 1 ... ( M + N ) ) )
19		eldifi	\|- ( C e. ( O \ E ) -> C e. O )
20	1 2 3	ballotlemelo	\|- ( C e. O <-> ( C C_ ( 1 ... ( M + N ) ) /\ ( # ` C ) = M ) )
21	20	simplbi	\|- ( C e. O -> C C_ ( 1 ... ( M + N ) ) )
22	19 21	syl	\|- ( C e. ( O \ E ) -> C C_ ( 1 ... ( M + N ) ) )
23		f1imacnv	\|- ( ( ( S ` C ) : ( 1 ... ( M + N ) ) -1-1-> ( 1 ... ( M + N ) ) /\ C C_ ( 1 ... ( M + N ) ) ) -> ( `' ( S ` C ) " ( ( S ` C ) " C ) ) = C )
24	18 22 23	syl2anc	\|- ( C e. ( O \ E ) -> ( `' ( S ` C ) " ( ( S ` C ) " C ) ) = C )
25	12 15 24	3eqtr2d	\|- ( C e. ( O \ E ) -> ( ( S ` C ) " ( R ` C ) ) = C )

Metamath Proof Explorer

Theorem ballotlemscr

Proof