:: $\sigma$-ring and $\sigma$-algebra of Sets
:: by Noboru Endou , Kazuhisa Nakasho and Yasunari Shidama
::
:: Received February 18, 2015
:: Copyright (c) 2015 Association of Mizar Users
:: (Stowarzyszenie Uzytkownikow Mizara, Bialystok, Poland).
:: This code can be distributed under the GNU General Public Licence
:: version 3.0 or later, or the Creative Commons Attribution-ShareAlike
:: License version 3.0 or later, subject to the binding interpretation
:: detailed in file COPYING.interpretation.
:: See COPYING.GPL and COPYING.CC-BY-SA for the full text of these
:: licenses, or see http://www.gnu.org/licenses/gpl.html and
:: http://creativecommons.org/licenses/by-sa/3.0/.
environ
vocabularies CARD_1, CARD_3, EQREL_1, FINSET_1, FINSUB_1, FUNCT_1, NUMBERS,
PROB_1, RELAT_1, SETFAM_1, SIMPLEX0, SRINGS_1, SUBSET_1, TARSKI,
XBOOLE_0, ZFMISC_1, ARYTM_1, ARYTM_3, XXREAL_0, PROB_2, FINSEQ_1, NAT_1,
ORDINAL4, INT_1, UPROOTS, SETLIM_2, SRINGS_3, MEASURE5, REAL_1, SUPINF_1,
XXREAL_1;
notations TARSKI, XBOOLE_0, SUBSET_1, PROB_1, EQREL_1, SETFAM_1, FINSET_1,
CARD_3, FINSUB_1, FUNCT_1, SIMPLEX0, SRINGS_1, ORDINAL1, NUMBERS,
XXREAL_0, RELSET_1, KURATO_0, XREAL_0, XXREAL_1, XCMPLX_0, NAT_D, PROB_2,
SETLIM_2, SUPINF_1, FINSEQ_1, RCOMP_1, MEASURE5;
constructors SRINGS_1, RELSET_1, PARTIT1, PROB_2, NAT_D, MESFUNC5, SETLIM_2,
KURATO_0, COHSP_1, SUPINF_1, RCOMP_1, MEASURE5;
registrations EQREL_1, FINSET_1, FINSUB_1, MEASURE1, PROB_1, SIMPLEX0,
SRINGS_1, SUBSET_1, XBOOLE_0, XTUPLE_0, ZFMISC_1, MEMBERED, NAT_1,
RELSET_1, XREAL_0, XXREAL_0, FUNCT_1, FINSEQ_1, ROUGHS_1, ORDINAL1,
COHSP_1, MEASURE5, XXREAL_1;
requirements BOOLE, SUBSET, ARITHM, NUMERALS, REAL;
equalities CARD_3, FINSEQ_1, RCOMP_1;
expansions TARSKI, XBOOLE_0, FINSUB_1, FINSEQ_1, MEASURE5;
theorems EQREL_1, FINSUB_1, PARTIT1, PROB_1, SETFAM_1, SRINGS_1, SUBSET_1,
TARSKI, XBOOLE_0, XBOOLE_1, ZFMISC_1, FUNCT_1, FUNCT_2, XREAL_0, XREAL_1,
XXREAL_0, NAT_1, FINSEQ_1, FINSEQ_3, NAT_D, NAT_2, PROB_2, FINSEQ_2,
DIST_2, MEASURE1, RELAT_1, SETLIM_2, SETLIM_1, PROB_4, SRINGS_2, NUMBERS,
MEASURE5, XXREAL_1;
schemes NAT_1, FINSEQ_1;
begin :: Preliminaries
theorem Lem10:
for f1,f2 be FinSequence, k be Nat st k in Seg (len f1 * len f2) holds
(k-'1) mod (len f2) + 1 in dom f2 &
(k-'1) div (len f2) + 1 in dom f1
proof
let f1,f2 be FinSequence;
let k be Nat;
reconsider i1 = (k-'1) div (len f2) + 1 as Nat;
reconsider i2 = (k-'1) mod (len f2) + 1 as Nat;
assume B1: k in Seg (len f1 * len f2); then
B2:1 <= k & k <= len f1 * len f2 by FINSEQ_1:1; then
B3:1 <= len f1 * len f2 by XXREAL_0:2;
B4:len f1 <> 0 & len f2 <> 0 by B1; then
(k-'1) mod (len f2) +1 <= len f2 by NAT_1:13,NAT_D:1;
hence (k-'1) mod (len f2) + 1 in dom f2 by NAT_1:11,FINSEQ_3:25;
1 <= len f1 & 1 <= len f2 by B4,NAT_1:14; then
B6:((len f1)*(len f2)-'1) div (len f2)
= (len f1)*(len f2) div (len f2) -1 by B3,NAT_2:15,NAT_D:def 3
.= len f1 - 1 by B4,NAT_D:18;
k-'1 <= len f1 * len f2 -'1 by B2,NAT_D:42; then
(k-'1) div (len f2) <= ((len f1)*(len f2)-'1) div (len f2)
by NAT_2:24; then
i1 <= len f1 -1+1 by B6,XREAL_1:6;
hence (k-'1) div (len f2) + 1 in dom f1 by NAT_1:11,FINSEQ_3:25;
end;
theorem CANFS:
for S be non empty finite set holds Union canFS S = union S
proof
let S be non empty finite set;
now let x be object;
assume x in union S; then
consider A be set such that
A2: x in A & A in S by TARSKI:def 4;
A in rng canFS S by A2,DIST_2:3;
hence x in union rng canFS S by A2,TARSKI:def 4;
end; then
union S c= union rng canFS S;
hence thesis by ZFMISC_1:77;
end;
theorem TTT1:
for x be object holds <*x*> is disjoint_valued FinSequence
proof
let x be object;
now let i,j be object;
assume A1: i <> j;
A2: dom <*x*> = {1} by FINSEQ_1:2,def 8;
per cases;
suppose i in dom <*x*>; then
i = 1 by A2,TARSKI:def 1; then
not j in {1} by A1,TARSKI:def 1; then
<*x*>.j = {} by A2,FUNCT_1:def 2;
hence <*x*>.i misses <*x*>.j;
end;
suppose not i in dom <*x*>; then
<*x*>.i = {} by FUNCT_1:def 2;
hence <*x*>.i misses <*x*>.j;
end;
end;
hence thesis by PROB_2:def 2;
end;
theorem Disjoint2:
for x,y be set, F be FinSequence st F = <*x,y*> & x misses y holds
F is disjoint_valued
proof
let x,y be set, F be FinSequence;
assume A1: F = <*x,y*> & x misses y;
now let i,j be object;
assume A6: i <> j;
per cases;
suppose not i in dom F or not j in dom F; then
F.i = {} or F.j = {} by FUNCT_1:def 2;
hence F.i misses F.j;
end;
suppose A7: i in dom F & j in dom F;
A8: len F = 2 & F.1 = x & F.2 = y by A1,FINSEQ_1:44; then
i in {1,2} & j in {1,2} by A7,FINSEQ_1:def 3,2; then
(i = 1 or i = 2) & (j = 1 or j = 2) by TARSKI:def 2;
hence F.i misses F.j by A1,A6,A8;
end;
end;
hence F is disjoint_valued by PROB_2:def 2;
end;
theorem TT1:
for f1,f2 be FinSequence
ex f be FinSequence st
Union f1 /\ Union f2 = Union f &
dom f = Seg (len f1 * len f2) &
for i be Nat st i in dom f holds
f.i = f1.((i-'1) div (len f2) + 1) /\ f2.((i-'1) mod (len f2) + 1)
proof
let f1,f2 be FinSequence;
A0:for k be Nat st k in Seg (len f1 * len f2) holds
(k-'1) mod (len f2) + 1 in dom f2 &
(k-'1) div (len f2) + 1 in dom f1 by Lem10;
defpred P[Nat,object] means
$2 = f1.(($1-'1) div (len f2) + 1) /\ f2.(($1-'1) mod (len f2) + 1);
A1:for k be Nat st k in Seg (len f1 * len f2) ex x be object st P[k,x];
consider f be FinSequence such that
A8: dom f = Seg (len f1 * len f2) &
for k be Nat st k in Seg (len f1 * len f2) holds P[k,f.k]
from FINSEQ_1:sch 1(A1);
take f;
now let x be object;
assume x in Union f1 /\ Union f2; then
A9: x in union rng f1 & x in union rng f2 by XBOOLE_0:def 4; then
consider F1 be set such that
A10: x in F1 & F1 in rng f1 by TARSKI:def 4;
consider F2 be set such that
A11: x in F2 & F2 in rng f2 by A9,TARSKI:def 4;
consider i be object such that
A12: i in dom f1 & F1 = f1.i by A10,FUNCT_1:def 3;
reconsider i as Nat by A12;
consider j be object such that
A13: j in dom f2 & F2 = f2.j by A11,FUNCT_1:def 3;
reconsider j as Nat by A13;
set k = (len f2)*(i-'1)+j;
E4: 1 <= i & i <= len f1 & 1 <= j & j <= len f2 by A12,A13,FINSEQ_3:25; then
F5: 1 <= k by NAT_1:12;
k-'1 = (len f2)*(i-'1) + j - 1 by E4,NAT_D:37; then
E5: k-'1 = (len f2)*(i-'1) + (j-1);
E7: i-1 = i-'1 & j-1 = j-'1 by E4,XREAL_1:48,XREAL_0:def 2; then
E8: (k-'1) div (len f2) = (j-'1) div (len f2) + (i-'1) by E4,E5,NAT_D:61;
j-'1 < j by E7,XREAL_1:44; then
F0: j-'1 < len f2 by E4,XXREAL_0:2; then
(j-'1) div (len f2) = 0 by NAT_D:27; then
F1: F1 = f1.((k-'1) div (len f2) + 1) by A12,E7,E8;
(k-'1) mod (len f2) = (j-'1) mod (len f2) by E5,E7,NAT_D:61; then
(k-'1) mod (len f2) = j-'1 by F0,NAT_D:24; then
F3: F2 = f2.((k-'1) mod (len f2) + 1) by A13,E7;
i-'1 <= len f1 -1 by E4,E7,XREAL_1:9; then
(i-'1)*(len f2) <= (len f1 -1)*(len f2) by XREAL_1:66; then
k <= (len f1 - 1)*(len f2) + len f2 by E4,XREAL_1:7; then
F4: k in Seg(len f1 * len f2) by F5; then
f.k = F1 /\ F2 by A8,F1,F3; then
x in f.k & f.k in rng f by A10,A11,F4,A8,FUNCT_1:3,XBOOLE_0:def 4;
hence x in Union f by TARSKI:def 4;
end; then
P1:Union f1 /\ Union f2 c= Union f;
now let x be object;
assume x in Union f; then
consider F be set such that
G1: x in F & F in rng f by TARSKI:def 4;
consider i be object such that
G2: i in dom f & F = f.i by G1,FUNCT_1:def 3;
reconsider i as Nat by G2;
F = f1.((i-'1) div (len f2) + 1) /\ f2.((i-'1) mod (len f2)+1)
by A8,G2; then
G3: x in f1.((i-'1) div (len f2) + 1) & x in f2.((i-'1) mod (len f2)+1)
by G1,XBOOLE_0:def 4;
f1.((i-'1) div (len f2) + 1) in rng f1 &
f2.((i-'1) mod (len f2)+1) in rng f2 by G2,A8,A0,FUNCT_1:3; then
x in union rng f1 & x in union rng f2 by G3,TARSKI:def 4;
hence x in Union f1 /\ Union f2 by XBOOLE_0:def 4;
end; then
Union f c= Union f1 /\ Union f2;
hence thesis by A8,P1;
end;
theorem TT2:
for f1,f2 be disjoint_valued FinSequence
ex f be disjoint_valued FinSequence st
Union f1 /\ Union f2 = Union f &
dom f = Seg (len f1 * len f2) &
for i be Nat st i in dom f holds
f.i = f1.((i-'1) div (len f2) + 1) /\ f2.((i-'1) mod (len f2) + 1)
proof
let f1,f2 be disjoint_valued FinSequence;
consider f be FinSequence such that
A1: Union f1 /\ Union f2 = Union f &
dom f = Seg (len f1 * len f2) &
for i be Nat st i in dom f holds
f.i = f1.((i-'1) div (len f2) + 1) /\ f2.((i-'1) mod (len f2) + 1)
by TT1;
now let i,j be object;
assume A2: i <> j;
per cases;
suppose A3: i in dom f & j in dom f; then
reconsider i1=i, j1=j as Nat;
f.i = f1.((i1-'1) div (len f2) + 1) /\ f2.((i1-'1) mod (len f2) + 1) &
f.j = f1.((j1-'1) div (len f2) + 1) /\ f2.((j1-'1) mod (len f2) + 1)
by A1,A3; then
B1: f.i c= f1.((i1-'1) div (len f2) + 1) &
f.j c= f1.((j1-'1) div (len f2) + 1) &
f.i c= f2.((i1-'1) mod (len f2) + 1) &
f.j c= f2.((j1-'1) mod (len f2) + 1) by XBOOLE_1:17;
A5: 0 < len f1 & 0 < len f2 or 0 > len f1 & 0 > len f2 by A1,A3;
A6: now assume
A7: (i1-'1) div (len f2) + 1 = (j1-'1) div (len f2) + 1 &
(i1-'1) mod (len f2) + 1 = (j1-'1) mod (len f2) + 1;
i1-'1 = (len f2) * ((j1-'1) div (len f2)) + ((i1-'1) mod (len f2))
by A7,A5,NAT_D:2
.= j1-'1 by A5,A7,NAT_D:2; then
(1 > i1 or i1 >= j1) & (1 > j1 or j1 >= i1) by NAT_D:56;
hence contradiction by A2,A1,A3,FINSEQ_1:1,XXREAL_0:1;
end;
per cases by A6;
suppose (i1-'1) div (len f2) + 1 <> (j1-'1) div (len f2) + 1;
hence f.i misses f.j by B1,XBOOLE_1:64,PROB_2:def 2;
end;
suppose (i1-'1) mod (len f2) + 1 <> (j1-'1) mod (len f2) + 1;
hence f.i misses f.j by B1,XBOOLE_1:64,PROB_2:def 2;
end;
end;
suppose not (i in dom f & j in dom f); then
f.i = {} or f.j = {} by FUNCT_1:def 2;
hence f.i misses f.j;
end;
end; then
reconsider f as disjoint_valued FinSequence by PROB_2:def 2;
take f;
thus thesis by A1;
end;
theorem NE:
for X be set, S be non empty diff-closed Subset-Family of X holds
{} in S
proof
let X be set, S be non empty diff-closed Subset-Family of X;
consider A be object such that
A1: A in S by XBOOLE_0:def 1;
reconsider A as set by TARSKI:1;
A \ A in S by A1,FINSUB_1:def 3;
hence {} in S by XBOOLE_1:37;
end;
registration let X be set;
cluster non empty diff-closed -> with_empty_element for Subset-Family of X;
coherence
proof
let S be Subset-Family of X;
assume A0: S is non empty diff-closed; then
consider A be object such that
A1: A in S;
reconsider A as set by TARSKI:1;
A \ A in S by A0,A1;
hence thesis by XBOOLE_1:37;
end;
end;
begin :: Classical Semi-ring, Ring and Sigma-ring of Sets
definition
let IT be set;
attr IT is semi-diff-closed means :DefSD:
for X,Y being set st X in IT & Y in IT holds
ex F be disjoint_valued FinSequence of IT st X \ Y = Union F;
end;
TV1:
for X be set holds bool X is semi-diff-closed
proof
let X be set;
set S = bool X;
thus S is semi-diff-closed
proof
let A,B be set;
assume A in S & B in S; then
A \ B c= X by XBOOLE_1:1; then
{ A \ B } c= S by ZFMISC_1:31; then
rng <* A \ B *> c= S by FINSEQ_1:38; then
reconsider F = <* A \ B *> as FinSequence of S by FINSEQ_1:def 4;
now let i,j be object;
assume A1: i <> j;
A2: now assume i in dom F & j in dom F; then
i in {1} & j in {1} by FINSEQ_1:2,38; then
i = 1 & j = 1 by TARSKI:def 1;
hence contradiction by A1;
end;
per cases by A2;
suppose not i in dom F; then
F.i = {} by FUNCT_1:def 2;
hence F.i misses F.j;
end;
suppose not j in dom F; then
F.j = {} by FUNCT_1:def 2;
hence F.i misses F.j;
end;
end; then
reconsider F as disjoint_valued FinSequence of S by PROB_2:def 2;
take F;
union rng F = union { A \ B } by FINSEQ_1:38;
hence A \ B = Union F;
end;
end;
registration let X be set;
cluster bool X -> semi-diff-closed;
coherence by TV1;
end;
registration
let X be set;
cluster non empty semi-diff-closed cap-closed for Subset-Family of X;
existence
proof
reconsider S = bool X as Subset-Family of X;
take S;
thus thesis;
end;
end;
:: Following cluster gives classical definition of a semiring of sets
registration let X be set;
cluster with_empty_element semi-diff-closed cap-closed
for Subset-Family of X;
existence
proof
bool X is non empty semi-diff-closed cap-closed Subset-Family of X;
hence thesis;
end;
end;
definition let X be set;
mode Semiring of X is with_empty_element semi-diff-closed cap-closed
Subset-Family of X;
end;
theorem Lm1:
for X be set, S be Subset-Family of X, S1,S2 be set st
S1 in S & S2 in S & S is semi-diff-closed holds
ex x be finite Subset of S st x is a_partition of S1 \ S2
proof
let X be set, S be Subset-Family of X, S1,S2 be set;
assume S1 in S & S2 in S & S is semi-diff-closed; then
consider F be disjoint_valued FinSequence of S such that
Y2: S1 \ S2 = Union F;
reconsider x = rng F \ {{}} as finite Subset of S;
take x;
now let p be object;
assume U1: p in x; then
p in S; then
reconsider p1 = p as Subset of X;
p in rng F & not p in {{}} by U1,XBOOLE_0:def 5; then
p1 c= S1 \ S2 by Y2,TARSKI:def 4;
hence p in bool (S1 \ S2);
end; then
Y5:x c= bool (S1 \ S2);
Y3:union x = S1 \ S2 by Y2,PARTIT1:2;
now let A be Subset of S1 \ S2;
assume A in x; then
Y6: A in rng F & not A in {{}} by XBOOLE_0:def 5;
hence A <> {} by TARSKI:def 1;
now let B be Subset of S1 \ S2;
assume B in x; then
B in rng F & not B in {{}} by XBOOLE_0:def 5; then
(ex i be Nat st i in dom F & F.i = A)
& (ex j be Nat st j in dom F & F.j = B) by Y6,FINSEQ_2:10;
hence A=B or A misses B by PROB_2:def 2;
end;
hence for B be Subset of S1 \ S2 st B in x holds A = B or A misses B;
end;
hence x is a_partition of S1 \ S2 by Y3,Y5,EQREL_1:def 4;
end;
theorem
for X be set, S be non empty Subset-Family of X st
S is semi-diff-closed holds S is diff-c=-finite-partition-closed
proof
let X be set, S be non empty Subset-Family of X;
assume S is semi-diff-closed; then
for S1,S2 be Element of S st S2 c= S1 holds
ex x be finite Subset of S st x is a_partition of S1 \ S2 by Lm1;
hence S is diff-c=-finite-partition-closed by SRINGS_1:def 3;
end;
theorem th10:
for X be set, S be Subset-Family of X st
S is with_empty_element & S is cap-finite-partition-closed
& S is diff-c=-finite-partition-closed
holds S is semi-diff-closed
proof
let X be set, S be Subset-Family of X;
assume that
A0: S is with_empty_element and
A1: S is cap-finite-partition-closed and
A2: S is diff-c=-finite-partition-closed;
now let S1,S2 be set;
assume A3: S1 in S & S2 in S;
per cases;
suppose X1: S1 \ S2 <> {}; then
consider x be finite Subset of S such that
L4: x is a_partition of S1 \ S2 by A1,A2,A3,SRINGS_1:def 2;
L8: union x = S1 \ S2
& for A be Subset of S1 \ S2 st A in x holds A <> {}
& for B be Subset of S1 \ S2 st B in x holds
A = B or A misses B by L4,EQREL_1:def 4;
L5: rng (canFS x) c= x;
rng (canFS x) c= S by XBOOLE_1:1; then
reconsider F = canFS x as FinSequence of S by FINSEQ_1:def 4;
now let i,j be object;
assume L6: i <> j;
per cases;
suppose L10: i in dom F & j in dom F; then
F.i in x & F.j in x by L5,FUNCT_1:3; then
F.i = F.j or F.i misses F.j by L4,EQREL_1:def 4;
hence F.i misses F.j by L6,L10,FUNCT_1:def 4;
end;
suppose not i in dom F or not j in dom F; then
F.i = {} or F.j = {} by FUNCT_1:def 2;
hence F.i misses F.j;
end;
end; then
reconsider F as disjoint_valued FinSequence of S by PROB_2:def 2;
take F;
thus Union F = S1 \ S2 by L4,X1,L8,CANFS;
end;
suppose T0: S1 \ S2 = {};
set F = canFS {{}};
{{}} c= S by A0,SETFAM_1:def 8,ZFMISC_1:31; then
rng F c= S; then
reconsider F as FinSequence of S by FINSEQ_1:def 4;
T3: F = <*{}*> by FINSEQ_1:94;
now let i,j be object;
assume i <> j;
i in dom F implies i=1 by T3,FINSEQ_1:90; then
F.i = {} by T3,FINSEQ_1:40,FUNCT_1:def 2;
hence F.i misses F.j;
end; then
reconsider F as disjoint_valued FinSequence of S by PROB_2:def 2;
take F;
Union F = union {{}} by CANFS;
hence S1 \ S2 = Union F by T0;
end;
end;
hence S is semi-diff-closed;
end;
registration
cluster diff-closed -> semi-diff-closed cap-closed for set;
correctness
proof
let R be set;
assume A1: R is diff-closed;
now let A,B be set;
assume A in R & B in R; then
A \ B in R by A1; then
reconsider F = <* A \ B *> as FinSequence of R by FINSEQ_1:74;
now let x,y be object;
assume A3: x <> y;
A4: dom F = {1} by FINSEQ_1:2,38;
per cases;
suppose x in dom F; then
x = 1 by A4,TARSKI:def 1; then
not y in dom F by A3,A4,TARSKI:def 1; then
F.y = {} by FUNCT_1:def 2;
hence F.x misses F.y;
end;
suppose not x in dom F; then
F.x = {} by FUNCT_1:def 2;
hence F.x misses F.y;
end;
end; then
A5: F is disjoint_valued by PROB_2:def 2;
rng F = { A \ B } by FINSEQ_1:38; then
Union F = A \ B;
hence ex F being disjoint_valued FinSequence of R st A \ B = Union F by A5;
end;
hence R is semi-diff-closed;
now let A,B be set;
assume A6: A in R & B in R; then
A \ B in R by A1; then
A \ (A \ B) in R by A1,A6;
hence A /\ B in R by XBOOLE_1:48;
end;
hence R is cap-closed;
end;
end;
registration
let X be set;
cluster non empty preBoolean for Subset-Family of X;
existence
proof
bool X is non empty preBoolean;
hence thesis;
end;
end;
registration
cluster non empty preBoolean -> with_empty_element for set;
correctness
proof
let X be set;
assume A1: X is non empty preBoolean; then
consider x be object such that
A2: x in X;
reconsider x1=x as set by A2;
{} = x1 \ x1 by XBOOLE_1:37; then
{} in X by A1,A2,FINSUB_1:def 3;
hence X is with_empty_element;
end;
end;
ExistRing:
for X being set, S being with_empty_element semi-diff-closed
cap-closed Subset-Family of X
ex Y being non empty preBoolean Subset-Family of X st
Y = meet {Z where Z is non empty preBoolean Subset-Family of X : S c= Z}
proof
let X be set,
S be with_empty_element semi-diff-closed cap-closed Subset-Family of X;
set V = {Z where Z is non empty preBoolean Subset-Family of X : S c= Z};
A1:bool X in V; then
reconsider Y = meet V as Subset-Family of X by SETFAM_1:3;
now let Z be set;
assume Z in V; then
ex S1 being non empty preBoolean Subset-Family of X st
Z = S1 & S c= S1;
hence {} in Z by SETFAM_1:def 8;
end; then
A2:Y is non empty by A1,SETFAM_1:def 1;
now let A,B be set;
assume B1: A in Y & B in Y;
for Z being set st Z in V holds A \/ B in Z
proof
let Z be set;
assume B2: Z in V; then
consider Z1 be non empty preBoolean Subset-Family of X such that
B3: Z = Z1 & S c= Z1;
A in Z1 & B in Z1 by B1,B2,B3,SETFAM_1:def 1;
hence A \/ B in Z by B3,FINSUB_1:def 1;
end;
hence A \/ B in Y by A1,SETFAM_1:def 1;
end; then
B4:Y is cup-closed;
now let A,B be set;
assume C1: A in Y & B in Y;
for Z being set st Z in V holds A \ B in Z
proof
let Z be set;
assume C2: Z in V; then
consider Z1 be non empty preBoolean Subset-Family of X such that
C3: Z = Z1 & S c= Z1;
A in Z1 & B in Z1 by C1,C2,C3,SETFAM_1:def 1;
hence A \ B in Z by C3,FINSUB_1:def 3;
end;
hence A \ B in Y by A1,SETFAM_1:def 1;
end; then
Y is diff-closed;
hence thesis by A2,B4;
end;
definition
let X be set, S be with_empty_element semi-diff-closed
cap-closed Subset-Family of X;
func Ring_generated_by S -> non empty preBoolean Subset-Family of X equals
meet {Z where Z is non empty preBoolean Subset-Family of X : S c= Z};
correctness
proof
consider Y be non empty preBoolean Subset-Family of X such that
A1: Y = meet {Z where Z is non empty preBoolean Subset-Family of X : S c= Z}
by ExistRing;
thus thesis by A1;
end;
end;
theorem RingGen1:
for X being set, P being with_empty_element semi-diff-closed
cap-closed Subset-Family of X
holds P c= Ring_generated_by P
proof
let X be set, P be with_empty_element semi-diff-closed
cap-closed Subset-Family of X;
set Y = {Z where Z is non empty preBoolean Subset-Family of X : P c= Z};
A1:bool X in Y;
for A being set st A in Y holds P c= A
proof
let A be set;
assume A in Y; then
ex Z being non empty preBoolean Subset-Family of X st A = Z & P c= Z;
hence P c= A;
end;
hence thesis by A1,SETFAM_1:5;
end;
lemma100:
for X being set, S being with_empty_element semi-diff-closed cap-closed
Subset-Family of X, P being set
st P = { A where A is Subset of X :
ex F be disjoint_valued FinSequence of S st A = Union F }
holds P is non empty Subset-Family of X & S c= P
proof
let X be set, S be with_empty_element semi-diff-closed cap-closed
Subset-Family of X, P be set;
assume A1: P = { A where A is Subset of X :
ex F be disjoint_valued FinSequence of S st A = Union F };
reconsider E0 = {} as Subset of X by XBOOLE_1:2;
reconsider g0 = <*E0*> as disjoint_valued FinSequence by TTT1;
now let i be Nat;
assume i in dom g0; then
i in Seg 1 by FINSEQ_1:38; then
i = 1 by TARSKI:def 1,FINSEQ_1:2; then
g0.i = E0 by FINSEQ_1:40;
hence g0.i in S by SETFAM_1:def 8;
end; then
reconsider g0 as disjoint_valued FinSequence of S by FINSEQ_2:12;
Union g0 = union {E0} by FINSEQ_1:38; then
A5:{} in P by A1;
now let x be object;
assume x in P; then
ex A be Subset of X st x = A &
ex F be disjoint_valued FinSequence of S st A = Union F by A1;
hence x in bool X;
end;
hence P is non empty Subset-Family of X by A5,TARSKI:def 3;
now let x be object;
assume A5: x in S; then
reconsider x1 = x as Subset of X;
set g = <*x1*>;
A3: rng <*x1*> = {x1} by FINSEQ_1:38;
reconsider g as disjoint_valued FinSequence by TTT1;
now let y be object;
assume y in rng g; then
consider i be object such that
B1: i in dom g & y = g.i by FUNCT_1:def 3;
reconsider i as Element of NAT by B1;
i in Seg 1 by B1,FINSEQ_1:38; then
i = 1 by TARSKI:def 1,FINSEQ_1:2;
hence y in S by B1,A5,FINSEQ_1:40;
end; then
rng g c= S; then
reconsider g as disjoint_valued FinSequence of S by FINSEQ_1:def 4;
Union g = x by A3;
hence x in P by A1;
end;
hence S c= P;
end;
definition
let X be set,
S be with_empty_element semi-diff-closed cap-closed Subset-Family of X;
func DisUnion S -> non empty Subset-Family of X equals
{ A where A is Subset of X :
ex F be disjoint_valued FinSequence of S st A = Union F };
coherence by lemma100;
end;
theorem
for X being set,
S be with_empty_element semi-diff-closed cap-closed Subset-Family of X
holds
S c= DisUnion S by lemma100;
theorem lemma101:
for X being set, S being with_empty_element semi-diff-closed cap-closed
Subset-Family of X holds DisUnion S is cap-closed
proof
let X be set, S be with_empty_element semi-diff-closed cap-closed
Subset-Family of X;
set P = DisUnion S;
now let x,y be set;
assume C1: x in P & y in P; then
consider x1 be Subset of X such that
C2: x = x1 &
ex g be disjoint_valued FinSequence of S st x1 = Union g;
consider g1 be disjoint_valued FinSequence of S such that
C3: x1 = Union g1 by C2;
consider y1 be Subset of X such that
C4: y = y1 &
ex g be disjoint_valued FinSequence of S st y1 = Union g by C1;
consider g2 be disjoint_valued FinSequence of S such that
C5: y1 = Union g2 by C4;
consider h be disjoint_valued FinSequence such that
C6: Union g1 /\ Union g2 = Union h &
dom h = Seg (len g1 * len g2) &
for i be Nat st i in dom h holds
h.i = g1.((i-'1) div (len g2) + 1) /\ g2.((i-'1) mod (len g2)+1)
by TT2;
x1 /\ y1 c= X; then
reconsider xy = x /\ y as Subset of X by C2,C4;
now let i be Nat;
assume C9: i in dom h; then
(i-'1) mod (len g2) + 1 in dom g2 &
(i-'1) div (len g2) + 1 in dom g1 by C6,Lem10; then
g1.((i-'1) div (len g2) + 1) in S &
g2.((i-'1) mod (len g2) + 1) in S by FINSEQ_2:11; then
g1.((i-'1) div (len g2) + 1) /\ g2.((i-'1) mod (len g2) + 1) in S
by FINSUB_1:def 2;
hence h.i in S by C9,C6;
end; then
reconsider h as disjoint_valued FinSequence of S by FINSEQ_2:12;
xy = Union h by C2,C4,C3,C5,C6;
hence x /\ y in P;
end;
hence P is cap-closed;
end;
theorem lemma102:
for X being set, S being with_empty_element semi-diff-closed cap-closed
Subset-Family of X, A,B,P being set
st P = DisUnion S & A in P & B in P & A misses B
holds A \/ B in P
proof
let X be set, S be with_empty_element semi-diff-closed cap-closed
Subset-Family of X, A,B,P be set;
assume that
A1: P = DisUnion S and
A2: A in P & B in P & A misses B;
consider A1 be Subset of X such that
A3: A = A1 &
ex g be disjoint_valued FinSequence of S st A1 = Union g by A1,A2;
consider g1 be disjoint_valued FinSequence of S such that
A4: A1 = Union g1 by A3;
consider B1 be Subset of X such that
A5: B = B1 &
ex g be disjoint_valued FinSequence of S st B1 = Union g by A1,A2;
consider g2 be disjoint_valued FinSequence of S such that
A6: B1 = Union g2 by A5;
set F = g1^g2;
now let n,m be object;
assume A7: n <> m;
per cases;
suppose A8: n in dom F & m in dom F; then
reconsider n1=n,m1=m as Nat;
A9: n1 in dom g1
or ex k being Nat st k in dom g2 & n1 = len g1 + k by A8,FINSEQ_1:25;
A10: m1 in dom g1
or ex k being Nat st k in dom g2 & m1 = len g1 + k by A8,FINSEQ_1:25;
per cases by A9,A10;
suppose n1 in dom g1 & m1 in dom g1; then
F.n = g1.n1 & F.m = g1.m1 by FINSEQ_1:def 7;
hence F.n misses F.m by A7,PROB_2:def 2;
end;
suppose A11: n1 in dom g1
& ex k being Nat st k in dom g2 & m1 = len g1 + k; then
consider k be Nat such that
A12: k in dom g2 & m1 = len g1 + k;
F.n = g1.n1 & F.m = g2.k by A11,A12,FINSEQ_1:def 7; then
A13: F.n in rng g1 & F.m in rng g2 by A11,A12,FUNCT_1:3;
now assume F.n meets F.m; then
consider x be object such that
A14: x in F.n & x in F.m by XBOOLE_0:3;
x in union rng g1 & x in union rng g2 by A13,A14,TARSKI:def 4;
hence contradiction by A2,A3,A5,A4,A6,XBOOLE_0:def 4;
end;
hence F.n misses F.m;
end;
suppose A15: m1 in dom g1
& ex k being Nat st k in dom g2 & n1 = len g1 + k; then
consider k be Nat such that
A16: k in dom g2 & n1 = len g1 + k;
F.n = g2.k & F.m = g1.m by A15,A16,FINSEQ_1:def 7; then
A17: F.n in rng g2 & F.m in rng g1 by A15,A16,FUNCT_1:3;
now assume F.n meets F.m; then
consider x be object such that
A18: x in F.n & x in F.m by XBOOLE_0:3;
x in union rng g1 & x in union rng g2 by A17,A18,TARSKI:def 4;
hence contradiction by A2,A3,A5,A4,A6,XBOOLE_0:def 4;
end;
hence F.n misses F.m;
end;
suppose A19: ex k being Nat st k in dom g2 & n1 = len g1 + k
& ex k being Nat st k in dom g2 & m1 = len g1 + k; then
consider k1 be Nat such that
A20: k1 in dom g2 & n1 = len g1 + k1;
consider k2 be Nat such that
A21: k2 in dom g2 & m1 = len g1 + k2 by A19;
F.n = g2.k1 & F.m = g2.k2 by A20,A21,FINSEQ_1:def 7;
hence F.n misses F.m by A7,A20,A21,PROB_2:def 2;
end;
end;
suppose not n in dom F or not m in dom F; then
F.n = {} or F.m = {} by FUNCT_1:def 2;
hence F.n misses F.m;
end;
end; then
reconsider F as disjoint_valued FinSequence of S by PROB_2:def 2;
rng F = rng g1 \/ rng g2 by FINSEQ_1:31; then
Union F = A1 \/ B1 by A4,A6,ZFMISC_1:78;
hence A \/ B in P by A1,A3,A5;
end;
theorem lemma103:
for X being set, S being with_empty_element semi-diff-closed cap-closed
Subset-Family of X, A,B being set st A in S & B in S
holds B \ A in DisUnion S
proof
let X be set, S be with_empty_element semi-diff-closed cap-closed
Subset-Family of X, A,B be set;
assume
A2: A in S & B in S;
reconsider A1=A,B1=B as Subset of X by A2;
ex F be disjoint_valued FinSequence of S st B\A = Union F by A2,DefSD; then
B1 \ A1 in DisUnion S;
hence thesis;
end;
theorem lemma104:
for X being set, S being with_empty_element semi-diff-closed cap-closed
Subset-Family of X, A,B being set
st A in S & B in DisUnion S
holds B \ A in DisUnion S
proof
let X be set, S be with_empty_element semi-diff-closed cap-closed
Subset-Family of X, A,B be set;
assume that
A2: A in S & B in DisUnion S;
reconsider A1=A as Subset of X by A2;
consider B1 be Subset of X such that
A5: B = B1 &
ex F be disjoint_valued FinSequence of S st B1 = Union F by A2;
consider g1 be disjoint_valued FinSequence of S such that
A6: B1 = Union g1 by A5;
reconsider R1=DisUnion S as non empty set;
defpred P[Nat,object] means $2 = g1.$1 \ A1;
A7:for k being Nat st k in Seg len g1
ex x being Element of R1 st P[k,x]
proof
let k be Nat;
assume k in Seg len g1; then
k in dom g1 by FINSEQ_1:def 3; then
g1.k in rng g1 & rng g1 c= S by FUNCT_1:3; then
g1.k \ A1 in DisUnion S by A2,lemma103;
hence ex x being Element of R1 st P[k,x];
end;
consider g2 be FinSequence of R1 such that
A8: dom g2 = Seg len g1 &
for k being Nat st k in Seg len g1 holds P[k,g2.k] from FINSEQ_1:sch 5(A7);
A11:for n,m being Nat st
n in dom g2 & m in dom g2 & n <> m holds g2.n misses g2.m
proof
let n,m be Nat;
assume A9: n in dom g2 & m in dom g2 & n <> m; then
A10:g2.n = g1.n \ A1 & g2.m = g1.m \ A1 by A8;
g1.n misses g2.m by A10,A9,PROB_2:def 2,XBOOLE_1:80;
hence g2.n misses g2.m by A10,XBOOLE_1:80;
end;
set R = DisUnion S;
defpred P2[Nat] means union rng (g2|$1) in R;
union rng(g2|0) in S & S c= R by lemma100,SETFAM_1:def 8,ZFMISC_1:2; then
A12: P2[0];
A13:for k being Nat st P2[k] holds P2[k+1]
proof
let k be Nat;
assume A14: P2[k];
per cases;
suppose A15: k+1 <= len g2; then
A20: k <= len g2 & k <= k+1 by NAT_1:13; then
len(g2|(k+1)) = k+1 & g2|k = (g2|(k+1))|k by A15,FINSEQ_1:59,82; then
g2|(k+1) = g2|k ^ <*(g2|(k+1)).(k+1) *> by FINSEQ_3:55; then
rng(g2|(k+1)) = rng(g2|k) \/ rng <*(g2|(k+1)).(k+1)*> by FINSEQ_1:31
.= rng(g2|k) \/ { (g2|(k+1)).(k+1) } by FINSEQ_1:38
.= rng(g2|k) \/ { g2.(k+1) } by FINSEQ_3:112; then
A16: union rng(g2|(k+1)) = union rng(g2|k) \/ union { g2.(k+1) } by ZFMISC_1:78
.= union rng(g2|k) \/ g2.(k+1);
A24: k+1 in dom g2 by A15,FINSEQ_3:25,NAT_1:11;
A25: now assume union rng(g2|k) meets g2.(k+1); then
consider x be object such that
A17: x in union rng(g2|k) & x in g2.(k+1) by XBOOLE_0:3;
consider Z be set such that
A18: x in Z & Z in rng(g2|k) by A17,TARSKI:def 4;
consider i be object such that
A19: i in dom(g2|k) & Z = (g2|k).i by A18,FUNCT_1:def 3;
reconsider i as Nat by A19;
i <= len (g2|k) by A19,FINSEQ_3:25; then
A21: i <= k by A20,FINSEQ_1:59; then
A22: Z = g2.i by A19,FINSEQ_3:112;
A23: dom(g2|k) c= dom g2 by RELAT_1:60;
i <> k+1 by A21,NAT_1:13; then
Z misses g2.(k+1) by A11,A22,A23,A19,A24;
hence contradiction by A17,A18,XBOOLE_0:def 4;
end;
g2.(k+1) in rng g2 & rng g2 c= R by A24,FUNCT_1:3;
hence union rng(g2|(k+1)) in R by A14,A16,A25,lemma102;
end;
suppose k+1 > len g2; then
g2|(k+1) = g2 & g2|k = g2 by FINSEQ_1:58,NAT_1:13;
hence union rng(g2|(k+1)) in R by A14;
end;
end;
for k being Nat holds P2[k] from NAT_1:sch 2(A12,A13); then
C1:P2[len g2];
now let x be object;
assume x in union rng g2; then
consider y be set such that
B1: x in y & y in rng g2 by TARSKI:def 4;
consider k be object such that
B2: k in dom g2 & y = g2.k by B1,FUNCT_1:def 3;
reconsider k as Nat by B2;
C3: g2.k = g1.k \ A1 by B2,A8; then
B3: x in g1.k & not x in A1 by B1,B2,XBOOLE_0:def 5;
k in dom g1 by B2,A8,FINSEQ_1:def 3; then
g1.k in rng g1 by FUNCT_1:3; then
x in union rng g1 by C3,B1,B2,TARSKI:def 4;
hence x in union rng g1 \ A1 by B3,XBOOLE_0:def 5;
end; then
B4:union rng g2 c= union rng g1 \ A1;
now let x be object;
assume C5: x in union rng g1 \ A1; then
B5: x in union rng g1 & not x in A1 by XBOOLE_0:def 5;
consider y be set such that
B6: x in y & y in rng g1 by C5,TARSKI:def 4;
consider k be object such that
B7: k in dom g1 & y = g1.k by B6,FUNCT_1:def 3;
reconsider k as Nat by B7;
B8: k in dom g2 by B7,A8,FINSEQ_1:def 3; then
g2.k = g1.k \ A1 by A8; then
x in g2.k & g2.k in rng g2 by B5,B6,B7,B8,XBOOLE_0:def 5,FUNCT_1:3;
hence x in union rng g2 by TARSKI:def 4;
end; then
union rng g1 \ A1 c= union rng g2; then
union rng g1 \ A1 = union rng g2 by B4;
hence B \ A in R by A5,A6,C1,FINSEQ_1:58;
end;
theorem lemma105:
for X being set, S being with_empty_element semi-diff-closed cap-closed
Subset-Family of X, A,B,R being set
st R = DisUnion S & A in R & B in R & A <> {}
holds B \ A in R
proof
let X be set, S be with_empty_element semi-diff-closed cap-closed
Subset-Family of X, A,B,R be set;
assume that
A1: R = DisUnion S and
A2: A in R & B in R & A <> {};
consider A1 be Subset of X such that
A3: A = A1 &
ex F be disjoint_valued FinSequence of S st A1 = Union F by A1,A2;
consider f1 be disjoint_valued FinSequence of S such that
A4: A1 = Union f1 by A3;
consider B1 be Subset of X such that
A5: B = B1 &
ex F be disjoint_valued FinSequence of S st B1 = Union F by A1,A2;
reconsider R1=R as non empty set by A2;
defpred P[Nat,object] means $2 = B1 \ f1.$1;
A7:for k being Nat st k in Seg len f1
ex x being Element of R1 st P[k,x]
proof
let k be Nat;
assume k in Seg len f1; then
k in dom f1 by FINSEQ_1:def 3; then
f1.k in rng f1 & rng f1 c= S by FUNCT_1:3; then
B1 \ f1.k in R1 by A1,A2,A5,lemma104;
hence thesis;
end;
consider F be FinSequence of R1 such that
A8: dom F = Seg len f1 &
for k being Nat st k in Seg len f1 holds P[k,F.k] from FINSEQ_1:sch 5(A7);
now let x be object;
assume C9: x in B \ A; then
x in B & not x in A by XBOOLE_0:def 5; then
A10:for Y being set holds not x in Y or not Y in rng f1 by A3,A4,TARSKI:def 4;
B1: for k being Nat st k in Seg len f1 holds x in F.k
proof
let k be Nat;
assume B2: k in Seg len f1; then
B3: F.k = B1 \ f1.k by A8;
k in dom f1 by B2,FINSEQ_1:def 3; then
not x in f1.k by A10,FUNCT_1:3;
hence thesis by A5,C9,B3,XBOOLE_0:def 5;
end;
dom f1 <> {} by A2,A3,A4,ZFMISC_1:2,RELAT_1:42; then
consider k be object such that
B4: k in dom f1 by XBOOLE_0:def 1;
reconsider k as Nat by B4;
k in Seg len f1 by B4,FINSEQ_1:def 3; then
B5: rng F <> {} by A8,FUNCT_1:3;
now let Y be set;
assume Y in rng F; then
consider k be object such that
B6: k in dom F & Y = F.k by FUNCT_1:def 3;
reconsider k as Nat by B6;
thus x in Y by A8,B6,B1;
end;
hence x in meet rng F by B5,SETFAM_1:def 1;
end; then
B7:B \ A c= meet rng F;
now let x be object;
assume B8: x in meet rng F; then
consider Y be object such that
B10: Y in rng F by SETFAM_1:1,XBOOLE_0:def 1;
consider k be object such that
B11: k in dom F & Y = F.k by B10,FUNCT_1:def 3;
reconsider k as Nat by B11;
x in F.k by B8,B10,B11,SETFAM_1:def 1; then
x in B1 \ f1.k by A8,B11; then
B12:x in B1 & not x in f1.k by XBOOLE_0:def 5;
now assume x in union rng f1; then
consider Y be set such that
B13: x in Y & Y in rng f1 by TARSKI:def 4;
consider k be object such that
B14: k in dom f1 & Y = f1.k by B13,FUNCT_1:def 3;
reconsider k as Nat by B14;
B15: k in dom F by B14,A8,FINSEQ_1:def 3; then
F.k in rng F by FUNCT_1:3; then
x in F.k by B8,SETFAM_1:def 1; then
x in B1 \ f1.k by B15,A8;
hence contradiction by B13,B14,XBOOLE_0:def 5;
end;
hence x in B \ A by A3,A4,A5,B12,XBOOLE_0:def 5;
end; then
meet rng F c= B \ A; then
B16:B \ A = meet rng F by B7;
defpred P[Nat] means meet rng(F|$1) in R;
meet rng(F|0) in S & S c= R by A1,lemma100,SETFAM_1:def 8,1; then
C1:P[0];
C2:for k being Nat st P[k] holds P[k+1]
proof
let k be Nat;
assume C3: P[k];
per cases;
suppose C4: k+1 <= len F;
F|k = (F|(k+1))|k by FINSEQ_1:82,NAT_1:11; then
F|(k+1) = F|k ^ <*(F|(k+1)).(k+1)*> by C4,FINSEQ_1:59,FINSEQ_3:55; then
C6: rng (F|(k+1)) = rng (F|k) \/ rng <*(F|(k+1)).(k+1)*> by FINSEQ_1:31
.= rng (F|k) \/ { (F|(k+1)).(k+1) } by FINSEQ_1:38
.= rng (F|k) \/ { F.(k+1) } by FINSEQ_3:112;
k+1 in dom F by C4,FINSEQ_3:25,NAT_1:11; then
C9: F.(k+1) in rng F & rng F c= R1 by FUNCT_1:3; then
C7: F.(k+1) in R;
per cases;
suppose rng(F|k) <> {}; then
C8: meet rng(F|(k+1)) = meet rng (F|k) /\ meet { F.(k+1) } by C6,SETFAM_1:9
.= meet rng (F|k) /\ F.(k+1) by SETFAM_1:10;
R is cap-closed by A1,lemma101;
hence meet rng (F|(k+1)) in R by C3,C9,C8;
end;
suppose rng(F|k) = {};
hence meet rng (F|(k+1)) in R by C6,C7,SETFAM_1:10;
end;
end;
suppose k+1 > len F; then
F|k = F & F|(k+1) = F by FINSEQ_1:58,NAT_1:13;
hence meet rng (F|(k+1)) in R by C3;
end;
end;
for k being Nat holds P[k] from NAT_1:sch 2(C1,C2); then
P[len F];
hence B \ A in R by B16,FINSEQ_1:58;
end;
theorem
for X being set, S being with_empty_element semi-diff-closed
cap-closed Subset-Family of X holds
Ring_generated_by S = DisUnion S
proof
let X be set, S be with_empty_element semi-diff-closed
cap-closed Subset-Family of X;
set R = DisUnion S;
reconsider R as non empty Subset-Family of X;
A0:S c= R by lemma100;
A1:R is cap-closed by lemma101;
A2:now let A,B be set;
assume A3: A in R & B in R; then
A <> {} implies B \ A in R by lemma105;
hence B \ A in R by A3;
end; then
A4:R is diff-closed;
now let A,B be set;
assume A in R & B in R; then
A5: A \ B in R & B \ A in R & A /\ B in R by A2,A1;
(A \ B) \/ (B \ A) in R by A5,lemma102,XBOOLE_1:82; then
A6: A \+\ B in R by XBOOLE_0:def 6;
(A \+\ B) \/ (A /\ B) in R by A5,A6,lemma102,XBOOLE_1:103;
hence A \/ B in R by XBOOLE_1:93;
end; then
R is cup-closed; then
reconsider R as non empty preBoolean Subset-Family of X by A4;
A10:R in {Z where Z is non empty preBoolean Subset-Family of X : S c= Z}
by A0;
now let x be object;
assume x in R; then
consider A be Subset of X such that
A8: x = A &
ex F being disjoint_valued FinSequence of S st A = Union F;
consider F be disjoint_valued FinSequence of S such that
A9: A = Union F by A8;
for Y being set st
Y in {Z where Z is non empty preBoolean Subset-Family of X : S c= Z}
holds x in Y
proof
let Y be set;
assume
Y in {Z where Z is non empty preBoolean Subset-Family of X: S c= Z}; then
consider Z be non empty preBoolean Subset-Family of X such that
A11: Y = Z & S c= Z;
defpred P[Nat] means union rng (F|$1) in Z;
X1: P[0] by SETFAM_1:def 8,ZFMISC_1:2;
X2: for k be Nat st P[k] holds P[k+1]
proof
let k be Nat;
assume X3: P[k];
per cases;
suppose C4: k+1 <= len F;
F|k = (F|(k+1))|k by NAT_1:11,FINSEQ_1:82; then
F|(k+1) = F|k ^ <*(F|(k+1)).(k+1)*> by C4,FINSEQ_1:59,FINSEQ_3:55; then
rng (F|(k+1)) = rng (F|k) \/ rng <*(F|(k+1)).(k+1)*> by FINSEQ_1:31
.= rng (F|k) \/ { (F|(k+1)).(k+1) } by FINSEQ_1:38
.= rng (F|k) \/ { F.(k+1) } by FINSEQ_3:112; then
C6: union rng (F|(k+1)) = union rng (F|k) \/ union {F.(k+1)} by ZFMISC_1:78
.= union rng (F|k) \/ F.(k+1);
k+1 in dom F by C4,NAT_1:11,FINSEQ_3:25; then
F.(k+1) in rng F & rng F c= S by FUNCT_1:3; then
F.(k+1) in Z by A11;
hence P[k+1] by X3,C6,FINSUB_1:def 1;
end;
suppose k+1 > len F; then
F|k = F & F|(k+1) = F by FINSEQ_1:58,NAT_1:13;
hence P[k+1] by X3;
end;
end;
for k be Nat holds P[k] from NAT_1:sch 2(X1,X2); then
P[len F];
hence x in Y by A8,A9,A11,FINSEQ_1:58;
end;
hence x in Ring_generated_by S by A10,SETFAM_1:def 1;
end; then
R c= Ring_generated_by S;
hence thesis by A10,SETFAM_1:7;
end;
definition
let X be set;
mode SigmaRing of X -> non empty preBoolean Subset-Family of X means
:DefSigmaRing:
for F be SetSequence of X st rng F c= it holds Union F in it;
existence
proof
take bool X;
thus thesis;
end;
end;
LemX:
for X be set, S be SigmaRing of X holds S is sigma-multiplicative
proof
let X be set, S be SigmaRing of X;
now let F be SetSequence of X;
assume A1: rng F c= S; then
A2: Union F in S by DefSigmaRing;
reconsider UF = Union F as Subset of X;
now let x be object;
assume BB: x in Intersection F;
B0: Intersection F c= UF by SETLIM_1:9;
now assume x in Union(UF (\) F); then
consider m be Nat such that
B1: x in (UF (\) F).m by PROB_1:12;
x in (UF \ F.m) by B1,SETLIM_2:def 7; then
not x in F.m by XBOOLE_0:def 5;
hence contradiction by BB,PROB_1:13;
end;
hence x in UF \ Union(UF (\) F) by BB,B0,XBOOLE_0:def 5;
end; then
B3: Intersection F c= UF \ Union(UF (\) F);
now let x be object;
assume x in UF \ Union(UF (\) F); then
C3: x in UF & not x in Union(UF (\) F) by XBOOLE_0:def 5;
hereby assume not x in Intersection F; then
consider n be Nat such that
C2: not x in F.n by PROB_1:13;
x in UF \ F.n by C3,C2,XBOOLE_0:def 5; then
x in (UF (\) F).n by SETLIM_2:def 7;
hence contradiction by C3,PROB_1:12;
end;
end; then
UF \ Union(UF (\) F) c= Intersection F; then
B5: Intersection F = Union F \ Union (UF (\) F) by B3;
now let x be object;
assume x in rng(UF (\) F); then
consider n be Element of NAT such that
D1: x = (UF (\) F).n by FUNCT_2:113;
D2: x = UF \ F.n by D1,SETLIM_2:def 7;
F.n in rng F by FUNCT_2:112;
hence x in S by A1,D2,A2,FINSUB_1:def 3;
end; then
rng (UF (\) F) c= S; then
Union (UF (\) F) in S by DefSigmaRing;
hence Intersection F in S by A2,B5,FINSUB_1:def 3;
end;
hence S is sigma-multiplicative by PROB_1:def 6;
end;
registration let X be set;
cluster -> sigma-multiplicative for SigmaRing of X;
coherence by LemX;
end;
definition let X be set, S be Subset-Family of X;
func sigmaring S -> SigmaRing of X means :Defsigmaring:
S c= it & for Z be set st S c= Z & Z is SigmaRing of X holds it c= Z;
existence
proof
set V = { Z where Z is Subset-Family of X : S c= Z & Z is SigmaRing of X };
set Y = meet V;
A1:now let A be set;
assume A in V;
then ex Z be Subset-Family of X st A = Z & S c= Z & Z is SigmaRing of X;
hence S c= A;
end;
for F be SetSequence of X st rng F c= bool X holds Union F in bool X; then
reconsider BX = bool X as SigmaRing of X by DefSigmaRing;
B1:BX in V;
A3:Y c= bool X by B1,SETFAM_1:def 1;
now let x,y be set;
assume C1: x in Y & y in Y;
now let A be set;
assume C3: A in V; then
consider Z be Subset-Family of X such that
C2: A = Z & S c= Z & Z is SigmaRing of X;
x in A & y in A by C1,C3,SETFAM_1:def 1;
hence x\y in A by C2,FINSUB_1:def 3;
end;
hence x \ y in Y by B1,SETFAM_1:def 1;
end; then
A4:Y is diff-closed;
now let x,y be set;
assume F1: x in Y & y in Y;
now let A be set;
assume F2: A in V; then
consider Z be Subset-Family of X such that
F3: A = Z & S c= Z & Z is SigmaRing of X;
x in A & y in A by F1,F2,SETFAM_1:def 1;
hence x \/ y in A by F3,FINSUB_1:def 1;
end;
hence x \/ y in Y by B1,SETFAM_1:def 1;
end; then
E1:Y is cup-closed;
A5:now let F be SetSequence of X;
assume D1: rng F c= Y;
now let A be set;
assume D2: A in V; then
consider Z be Subset-Family of X such that
D3: A = Z & S c= Z & Z is SigmaRing of X;
Y c= A by D2,SETFAM_1:3; then
rng F c= A by D1;
hence Union F in A by D3,DefSigmaRing;
end;
hence Union F in Y by B1,SETFAM_1:def 1;
end;
now let A be set;
assume A in V; then
ex Z be Subset-Family of X st A = Z & S c= Z & Z is SigmaRing of X;
hence {} in A by NE;
end; then
{} in Y by B1,SETFAM_1:def 1; then
reconsider Y as SigmaRing of X by E1,A3,A4,A5,DefSigmaRing;
take Y;
for F be SetSequence of X st rng F c= bool X holds Union F in bool X; then
reconsider BX = bool X as SigmaRing of X by DefSigmaRing;
BX in V;
hence S c= Y by A1,SETFAM_1:5;
hereby let Z be set;
assume S c= Z & Z is SigmaRing of X; then
Z in V;
hence Y c= Z by SETFAM_1:3;
end;
end;
correctness;
end;
theorem
for X be set, S be with_empty_element semi-diff-closed
cap-closed Subset-Family of X holds
sigmaring(Ring_generated_by S) = sigmaring S
proof
let X be set, S be with_empty_element semi-diff-closed
cap-closed Subset-Family of X;
A1:S c= Ring_generated_by S by RingGen1;
Ring_generated_by S c= sigmaring(Ring_generated_by S) by Defsigmaring; then
A2:S c= sigmaring(Ring_generated_by S) by A1;
now let x be object;
assume A3: x in Ring_generated_by S;
S c= sigmaring S by Defsigmaring; then
sigmaring S in {Z where Z is non empty preBoolean Subset-Family of X
: S c= Z};
hence x in sigmaring S by A3,SETFAM_1:def 1;
end; then
Ring_generated_by S c= sigmaring S;
hence thesis by A2,Defsigmaring;
end;
begin :: Semi-algebra, Algebra and Sigma-algebra of Sets
definition let X be set;
mode semialgebra_of_sets of X ->
with_empty_element semi-diff-closed cap-closed Subset-Family of X means
:Def1:
X in it;
existence
proof
bool X is with_empty_element semi-diff-closed cap-closed
Subset-Family of X & X c= X;
hence thesis;
end;
end;
theorem
for X being set, F being Field_Subset of X holds
F is semialgebra_of_sets of X by Def1,PROB_1:5;
ExistAlgebra:
for X being set, S being semialgebra_of_sets of X
ex Y being non empty Field_Subset of X st
Y = meet {Z where Z is Field_Subset of X : S c= Z}
proof
let X be set, S be semialgebra_of_sets of X;
set V = {Z where Z is Field_Subset of X : S c= Z};
A1:bool X in V; then
reconsider Y = meet V as Subset-Family of X by SETFAM_1:3;
now let Z be set;
assume Z in V; then
ex S1 being Field_Subset of X st
Z = S1 & S c= S1;
hence {} in Z by SETFAM_1:def 8;
end; then
A2:Y is non empty by A1,SETFAM_1:def 1;
now let A,B be set;
assume B1: A in Y & B in Y;
for Z being set st Z in V holds A \/ B in Z
proof
let Z be set;
assume B2: Z in V; then
consider Z1 be Field_Subset of X such that
B3: Z = Z1 & S c= Z1;
A in Z1 & B in Z1 by B1,B2,B3,SETFAM_1:def 1;
hence A \/ B in Z by B3,FINSUB_1:def 1;
end;
hence A \/ B in Y by A1,SETFAM_1:def 1;
end; then
B4:Y is cup-closed;
now let A be set;
assume C1: A in Y;
for Z being set st Z in V holds X \ A in Z
proof
let Z be set;
assume C2: Z in V; then
consider Z1 be Field_Subset of X such that
C3: Z = Z1 & S c= Z1;
A in Z1 & X in Z1 by Def1,C1,C2,C3,SETFAM_1:def 1;
hence X \ A in Z by C3,FINSUB_1:def 3;
end;
hence X \ A in Y by A1,SETFAM_1:def 1;
end; then
Y is compl-closed by MEASURE1:def 1;
hence thesis by A2,B4;
end;
definition
let X be set, S be semialgebra_of_sets of X;
func Field_generated_by S -> non empty Field_Subset of X equals
meet {Z where Z is Field_Subset of X : S c= Z};
correctness
proof
consider Y be non empty Field_Subset of X such that
A1: Y = meet {Z where Z is Field_Subset of X : S c= Z}
by ExistAlgebra;
thus thesis by A1;
end;
end;
theorem FieldGen1:
for X being set, P being semialgebra_of_sets of X holds
P c= Field_generated_by P
proof
let X be set, P be semialgebra_of_sets of X;
set Y = {Z where Z is Field_Subset of X : P c= Z};
A1:bool X in Y;
for A being set st A in Y holds P c= A
proof
let A be set;
assume A in Y; then
ex Z being Field_Subset of X st A = Z & P c= Z;
hence P c= A;
end;
hence thesis by A1,SETFAM_1:5;
end;
theorem
for X being set, S being semialgebra_of_sets of X holds
Field_generated_by S = DisUnion S
proof
let X be set, S be semialgebra_of_sets of X;
set R = DisUnion S;
reconsider R as non empty Subset-Family of X;
A0:S c= R by lemma100;
A1:R is cap-closed by lemma101;
A2:now let A,B be set;
assume A3: A in R & B in R; then
A <> {} implies B \ A in R by lemma105;
hence B \ A in R by A3;
end; then
A4:R is diff-closed;
now let A,B be set;
assume A in R & B in R; then
A5: A \ B in R & B \ A in R & A /\ B in R by A2,A1;
(A \ B) \/ (B \ A) in R by A5,lemma102,XBOOLE_1:82; then
A6: A \+\ B in R by XBOOLE_0:def 6;
(A \+\ B) \/ (A /\ B) in R by A5,A6,lemma102,XBOOLE_1:103;
hence A \/ B in R by XBOOLE_1:93;
end; then
R is cup-closed; then
reconsider R as non empty preBoolean Subset-Family of X
by A4;
now let A be set;
assume C1: A in R;
X in R by A0,Def1;
hence X \ A in R by C1,FINSUB_1:def 3;
end; then
K2:R is compl-closed by MEASURE1:def 1;
A10:R in {Z where Z is non empty Field_Subset of X : S c= Z} by A0,K2;
now let x be object;
assume x in R; then
consider A be Subset of X such that
A8: x = A &
ex F being disjoint_valued FinSequence of S st A = Union F;
consider F be disjoint_valued FinSequence of S such that
A9: A = Union F by A8;
for Y being set st
Y in {Z where Z is Field_Subset of X : S c= Z} holds x in Y
proof
let Y be set;
assume Y in {Z where Z is Field_Subset of X: S c= Z}; then
consider Z be Field_Subset of X such that
A11: Y = Z & S c= Z;
defpred P[Nat] means union rng (F|$1) in Z;
X1: P[0] by SETFAM_1:def 8,ZFMISC_1:2;
X2: for k be Nat st P[k] holds P[k+1]
proof
let k be Nat;
assume X3: P[k];
per cases;
suppose C4: k+1 <= len F;
F|k = (F|(k+1))|k by NAT_1:11,FINSEQ_1:82; then
F|(k+1) = F|k ^ <*(F|(k+1)).(k+1)*> by C4,FINSEQ_1:59,FINSEQ_3:55; then
rng (F|(k+1)) = rng (F|k) \/ rng <*(F|(k+1)).(k+1)*> by FINSEQ_1:31
.= rng (F|k) \/ { (F|(k+1)).(k+1) } by FINSEQ_1:38
.= rng (F|k) \/ { F.(k+1) } by FINSEQ_3:112; then
C6: union rng (F|(k+1)) = union rng (F|k) \/ union {F.(k+1)} by ZFMISC_1:78
.= union rng (F|k) \/ F.(k+1);
k+1 in dom F by C4,NAT_1:11,FINSEQ_3:25; then
F.(k+1) in rng F & rng F c= S by FUNCT_1:3; then
F.(k+1) in Z by A11;
hence P[k+1] by X3,C6,FINSUB_1:def 1;
end;
suppose k+1 > len F; then
F|k = F & F|(k+1) = F by FINSEQ_1:58,NAT_1:13;
hence P[k+1] by X3;
end;
end;
for k be Nat holds P[k] from NAT_1:sch 2(X1,X2); then
P[len F];
hence x in Y by A8,A9,A11,FINSEQ_1:58;
end;
hence x in Field_generated_by S by A10,SETFAM_1:def 1;
end; then
R c= Field_generated_by S;
hence thesis by A10,SETFAM_1:7;
end;
theorem
for X being non empty set, S being semialgebra_of_sets of X holds
sigma (Field_generated_by S) = sigma S
proof
let X be non empty set, S be semialgebra_of_sets of X;
A1:S c= Field_generated_by S by FieldGen1;
Field_generated_by S c= sigma(Field_generated_by S) by PROB_1:def 9; then
A2:S c= sigma(Field_generated_by S) by A1;
now let x be object;
assume A3: x in Field_generated_by S;
S c= sigma S by PROB_1:def 9; then
sigma S in {Z where Z is Field_Subset of X : S c= Z};
hence x in sigma S by A3,SETFAM_1:def 1;
end; then
Field_generated_by S c= sigma S;
hence thesis by A2,PROB_1:def 9;
end;
begin :: Mutual Relationship of between Sigma-ring and Sigma-algebra of Sets
theorem
for X be set, S be set st S is SigmaField of X holds S is SigmaRing of X
proof
let X be set, S be set;
assume A1: S is SigmaField of X; then
for F be SetSequence of X st rng F c= S holds Union F in S by PROB_4:4;
hence S is SigmaRing of X by A1,DefSigmaRing;
end;
theorem
for X be set, S be set st S is SigmaRing of X & X in S holds
S is SigmaField of X
proof
let X be set, S be set;
assume that
A1: S is SigmaRing of X and
A2: X in S;
reconsider S1 = S as non empty Subset-Family of X by A1;
A3:S1 is diff-closed by A1;
P1:now let A be Subset of X;
assume A in S1; then
X \ A in S1 by A2,A3;
hence A` in S1 by SUBSET_1:def 4;
end;
X c= X; then
reconsider X1 = X as Subset of X;
now let A be SetSequence of X;
assume P2: rng A c= S1;
now let a be object;
assume a in rng Complement A; then
consider n be Element of NAT such that
P3: a = (Complement A).n by FUNCT_2:113;
a = (A.n)` by P3,PROB_1:def 2; then
P4: a = X \ A.n by SUBSET_1:def 4;
A.n in rng A by FUNCT_2:4;
hence a in S1 by P4,P2,A1,A2,FINSUB_1:def 3;
end; then
rng Complement A c= S1; then
Union Complement A in S1 by A1,DefSigmaRing; then
X1 \ (Union Complement A) in S1 by A1,A2,FINSUB_1:def 3; then
(Union Complement A)` in S1 by SUBSET_1:def 4;
hence Intersection A in S1 by PROB_1:def 3;
end;
hence S is SigmaField of X by P1,PROB_1:def 1,def 6;
end;
theorem
for S be Subset-Family of REAL
st S = { I where I is Subset of REAL : I is left_open_interval }
holds S is with_empty_element semi-diff-closed cap-closed
proof
let S be Subset-Family of REAL;
assume S = { I where I is Subset of REAL : I is left_open_interval }; then
S is cap-closed & S is diff-finite-partition-closed with_empty_element &
S is with_countable_Cover by SRINGS_2:10;
hence thesis by th10;
end;
INTERVAL01:
for I be Subset of REAL st I = {} holds I is right_open_interval
proof
let I be Subset of REAL;
assume A1: I = {};
0 in REAL by NUMBERS:19; then
[.0,0.[ is right_open_interval by NUMBERS:31;
hence I is right_open_interval by A1;
end;
INTERVAL02:
for I,J be Subset of REAL
st I is right_open_interval & J is right_open_interval & I meets J holds
ex K,L be Subset of REAL st
K is right_open_interval & L is right_open_interval
& K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is right_open_interval & J is right_open_interval; then
consider p be Real, q be R_eal such that
A2: I = [.p,q.[;
consider r be Real, s be R_eal such that
A3: J = [.r,s.[ by A1;
assume A9: I meets J; then
A5: I \ J = [.p,r.[ \/ [.s,q.[ by A2,A3,XXREAL_1:198;
A10:q > r & s > p by A2,A3,A9,XXREAL_1:96;
A7:now assume s = -infty; then
s < r by XREAL_0:def 1,XXREAL_0:12; then
J = {} by A3,XXREAL_1:27;
hence contradiction by A9;
end;
per cases by A7,XXREAL_0:14;
suppose A8: s = +infty;
reconsider K = [.p,r.[ as Subset of REAL;
reconsider L = {} as Subset of REAL by XBOOLE_1:2;
take K,L;
p in REAL & r in REAL by XREAL_0:def 1;
hence K is right_open_interval by NUMBERS:31;
thus L is right_open_interval by INTERVAL01;
thus K misses L;
thus I \ J = K \/ L by A8,A5,XXREAL_1:215;
end;
suppose B1: s in REAL & r <= s; then
reconsider s1=s as Real;
reconsider K = [.p,r.[ as Subset of REAL;
reconsider L = [.s1,q.[ as Subset of REAL;
take K,L;
r in REAL by XREAL_0:def 1;
hence K is right_open_interval & L is right_open_interval
by NUMBERS:31;
thus K misses L by B1,XXREAL_1:96;
thus I \ J = K \/ L by A9,A2,A3,XXREAL_1:198;
end;
suppose C1: s in REAL & r > s;
C2: min(p,s) = p & max(r,q) = q by A2,A3,A9,XXREAL_1:96,XXREAL_0:def 9,def 10;
reconsider s1=s as Real by C1;
s1 < q by A2,A3,A9,XXREAL_1:96,C1,XXREAL_0:2; then
s1 in [.p,r.[ & s1 in [.s1,q.[ by A10,C1; then
C3: [.p,r.[ meets [.s,q.[ by XBOOLE_0:def 4;
reconsider K = [.p,q.[ as Subset of REAL;
reconsider L = {} as Subset of REAL by XBOOLE_1:2;
take K,L;
thus K is right_open_interval;
thus L is right_open_interval by INTERVAL01;
thus K misses L;
thus I \ J = K \/ L by C3,C2,A5,XXREAL_1:162;
end;
end;
OOdif:
for I,J be Subset of REAL
st I is open_interval & J is open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is open_interval & J is open_interval & I meets J; then
consider p,q being R_eal such that
A2: I = ].p,q.[;
consider r,s being R_eal such that
A3: J = ].r,s.[ by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r < s & p < s & r < q by A1,A2,A3,XXREAL_1:28,275;
A7:r <> +infty & s <> -infty by A1,A3,XXREAL_1:275,XXREAL_0:3,5;
per cases by A7,XXREAL_0:14;
suppose r in REAL & s in REAL; then
reconsider r1=r, s1=s as Real;
reconsider K = ].p,r1.], L = [.s1,q.[ as Subset of REAL;
K is left_open_interval & L is right_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:279,297;
end;
suppose A8: r = -infty & s in REAL; then
A9: ].p,r.] = {} & ].p,r.[ = {} by XXREAL_0:5,XXREAL_1:26,28;
reconsider s1=s as Real by A8;
reconsider K = ].p,r.[, L = [.s1,q.[ as Subset of REAL;
K is open_interval & L is right_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:297,A9;
end;
suppose A10: r in REAL & s = +infty; then
A11: [.s,q.[ = {} & ].s,q.[ = {} by XXREAL_0:3,XXREAL_1:27,28;
reconsider r1=r as Real by A10;
reconsider K = ].p,r1.], L = ].s,q.[ as Subset of REAL;
K is left_open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:297,A11;
end;
suppose r = -infty & s = +infty; then
A12: ].p,r.] = {} & ].p,r.[ = {} & [.s,q.[ = {} & ].s,q.[ = {}
by XXREAL_0:5,3,XXREAL_1:26,27,28;
reconsider K = ].p,r.[, L = ].s,q.[ as Subset of REAL;
K is open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:297,A12;
end;
end;
COdif:
for I,J be Subset of REAL
st I is closed_interval & J is open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is closed_interval & J is open_interval & I meets J; then
consider p,q being Real such that
A2: I = [.p,q.];
consider r,s being R_eal such that
A3: J = ].r,s.[ by A1;
I <> {} & J <> {} by A1; then
A4:p <= q & r < s & r < q & p < s by A1,A2,A3,XXREAL_1:29,28,89,93;
A7:r <> +infty & s <> -infty by A1,A3,XXREAL_1:89,93,XXREAL_0:3,5;
per cases by A7,XXREAL_0:14;
suppose r in REAL & s in REAL; then
reconsider r1=r, s1=s as Real;
reconsider K = [.p,r1.], L = [.s1,q.] as Subset of REAL;
K is closed_interval & L is closed_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:300,278;
end;
suppose A8: r = -infty & s in REAL;
r < p by A8,XREAL_0:def 1,XXREAL_0:12; then
A9: [.p,r.] = {} & ].p,r.[ = {} by XXREAL_1:28,29;
reconsider s1=s as Real by A8;
reconsider K = ].p,r.[, L = [.s1,q.] as Subset of REAL;
p is R_eal by XXREAL_0:def 1; then
K is open_interval & L is closed_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:300,A9;
end;
suppose A10:r in REAL & s = +infty; then
q < s by XREAL_0:def 1,XXREAL_0:9; then
A11: [.s,q.] = {} & ].s,q.[ = {} by XXREAL_1:28,29;
reconsider r1=r as Real by A10;
reconsider K = [.p,r1.], L = ].s,q.[ as Subset of REAL;
q is R_eal by XXREAL_0:def 1; then
K is closed_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:300,A11;
end;
suppose A13:r = -infty & s = +infty;
r < p & q < s by A13,XREAL_0:def 1,XXREAL_0:9,12; then
A12: [.p,r.] = {} & ].p,r.[ = {} & [.s,q.] = {} & ].s,q.[ = {}
by XXREAL_1:28,29;
reconsider K = ].p,r.[, L = ].s,q.[ as Subset of REAL;
p is R_eal & q is R_eal by XXREAL_0:def 1; then
K is open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:300,A12;
end;
end;
ROdif:
for I,J be Subset of REAL
st I is right_open_interval & J is open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is right_open_interval & J is open_interval & I meets J; then
consider p being Real, q being R_eal such that
A2: I = [.p,q.[;
consider r,s being R_eal such that
A3: J = ].r,s.[ by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r < s & r < q & p <= s by A1,A2,A3,XXREAL_1:27,28,94,273;
A7:r <> +infty & s <> -infty by A1,A3,XXREAL_1:94,273,XXREAL_0:3,5;
per cases by A7,XXREAL_0:14;
suppose r in REAL & s in REAL; then
reconsider r1=r, s1=s as Real;
reconsider K = [.p,r1.], L = [.s1,q.[ as Subset of REAL;
K is closed_interval & L is right_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:298,277;
end;
suppose A8: r = -infty & s in REAL; then
r < p by XREAL_0:def 1,XXREAL_0:12; then
A9: [.p,r.] = {} & ].p,r.[ = {} by XXREAL_1:28,29;
reconsider s1=s as Real by A8;
reconsider K = ].p,r.[, L = [.s1,q.[ as Subset of REAL;
p is R_eal by XXREAL_0:def 1; then
K is open_interval & L is right_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:298,A9;
end;
suppose A10:r in REAL & s = +infty; then
A11: [.s,q.[ = {} & ].s,q.[ = {} by XXREAL_0:3,XXREAL_1:27,28;
reconsider r1=r as Real by A10;
reconsider K = [.p,r1.], L = ].s,q.[ as Subset of REAL;
K is closed_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:298,A11;
end;
suppose r = -infty & s = +infty; then
r < p & q <= s by XREAL_0:def 1,XXREAL_0:3,12; then
A12: [.p,r.] = {} & ].p,r.[ = {} & [.s,q.[ = {} & ].s,q.[ = {}
by XXREAL_1:27,28,29;
reconsider K = ].p,r.[, L = ].s,q.[ as Subset of REAL;
p is R_eal & q is R_eal by XXREAL_0:def 1; then
K is open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:298,A12;
end;
end;
LOdif:
for I,J be Subset of REAL
st I is left_open_interval & J is open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is left_open_interval & J is open_interval & I meets J; then
consider p being R_eal, q being Real such that
A2: I = ].p,q.];
consider r,s being R_eal such that
A3: J = ].r,s.[ by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r < s & r < q & p < s by A1,A2,A3,XXREAL_1:26,28,276,91;
A7:r <> +infty & s <> -infty by A1,A3,XXREAL_1:276,91,XXREAL_0:3,5;
per cases by A7,XXREAL_0:14;
suppose r in REAL & s in REAL; then
reconsider r1=r, s1=s as Real;
reconsider K = ].p,r1.], L = [.s1,q.] as Subset of REAL;
K is left_open_interval & L is closed_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:299,280;
end;
suppose A8: r = -infty & s in REAL; then
A9: ].p,r.] = {} & ].p,r.[ = {} by XXREAL_0:5,XXREAL_1:26,28;
reconsider s1=s as Real by A8;
reconsider K = ].p,r.[, L = [.s1,q.] as Subset of REAL;
K is open_interval & L is closed_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:299,A9;
end;
suppose A10:r in REAL & s = +infty;
q < s by A10,XREAL_0:def 1,XXREAL_0:9; then
A11: [.s,q.] = {} & ].s,q.[ = {} by XXREAL_1:28,29;
reconsider r1=r as Real by A10;
reconsider K = ].p,r1.], L = ].s,q.[ as Subset of REAL;
q is R_eal by XXREAL_0:def 1; then
K is left_open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:299,A11;
end;
suppose A13:r = -infty & s = +infty;
r <= p & q < s by A13,XREAL_0:def 1,XXREAL_0:5,9; then
A12: ].p,r.] = {} & ].p,r.[ = {} & [.s,q.] = {} & ].s,q.[ = {}
by XXREAL_1:26,28,29;
reconsider K = ].p,r.[, L = ].s,q.[ as Subset of REAL;
p is R_eal & q is R_eal by XXREAL_0:def 1; then
K is open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:299,A12;
end;
end;
OCdif:
for I,J be Subset of REAL
st I is open_interval & J is closed_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is open_interval & J is closed_interval & I meets J; then
consider p,q being R_eal such that
A2: I = ].p,q.[;
consider r,s being Real such that
A3: J = [.r,s.] by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r <= s & p < s & r < q by A1,A2,A3,XXREAL_1:28,29,89,93;
reconsider K = ].p,r.[, L = ].s,q.[ as Subset of REAL;
r is R_eal & s is R_eal by XXREAL_0:def 1; then
K is open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:309,275;
end;
CCdif:
for I,J be Subset of REAL
st I is closed_interval & J is closed_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is closed_interval & J is closed_interval & I meets J; then
consider p,q being Real such that
A2: I = [.p,q.];
consider r,s being Real such that
A3: J = [.r,s.] by A1;
I <> {} & J <> {} by A1; then
A4:p <= q & r <= s & p <= s & r <= q by A1,A2,A3,XXREAL_1:29,278;
reconsider K = [.p,r.[, L = ].s,q.] as Subset of REAL;
r is R_eal & s is R_eal by XXREAL_0:def 1; then
K is right_open_interval & L is left_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:312,274;
end;
RCdif:
for I,J be Subset of REAL
st I is right_open_interval & J is closed_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is right_open_interval & J is closed_interval & I meets J; then
consider p be Real, q being R_eal such that
A2: I = [.p,q.[;
consider r,s being Real such that
A3: J = [.r,s.] by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r <= s & p <= s & r < q by A1,A2,A3,XXREAL_1:27,29,95,277;
reconsider K = [.p,r.[, L = ].s,q.[ as Subset of REAL;
r is R_eal & s is R_eal by XXREAL_0:def 1; then
K is right_open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:310,273;
end;
LCdif:
for I,J be Subset of REAL
st I is left_open_interval & J is closed_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is left_open_interval & J is closed_interval & I meets J; then
consider p be R_eal, q being Real such that
A2: I = ].p,q.];
consider r,s being Real such that
A3: J = [.r,s.] by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r <= s & p < s & r <= q by A1,A2,A3,XXREAL_1:26,29,90,280;
reconsider K = ].p,r.[, L = ].s,q.] as Subset of REAL;
r is R_eal & s is R_eal by XXREAL_0:def 1; then
K is open_interval & L is left_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:311,276;
end;
ORdif:
for I,J be Subset of REAL
st I is open_interval & J is right_open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is open_interval & J is right_open_interval & I meets J; then
consider p,q being R_eal such that
A2: I = ].p,q.[;
consider r be Real, s being R_eal such that
A3: J = [.r,s.[ by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r <= s & p < s & r <= q by A1,A2,A3,XXREAL_1:27,28,94,273;
A7:s <> -infty by A1,A3,XXREAL_1:273,XXREAL_0:5;
per cases by A7,XXREAL_0:14;
suppose s = +infty; then
A8: [.s,q.[ = {} & ].s,q.[ = {} by XXREAL_0:3,XXREAL_1:27,28;
reconsider K = ].p,r.[, L = ].s,q.[ as Subset of REAL;
r is R_eal by XXREAL_0:def 1; then
K is open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:301,A8;
end;
suppose s in REAL; then
reconsider s1 = s as Real;
reconsider K = ].p,r.[, L = [.s1,q.[ as Subset of REAL;
r is R_eal by XXREAL_0:def 1; then
K is open_interval & L is right_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,XXREAL_1:94,301,A2,A3;
end;
end;
CRdif:
for I,J be Subset of REAL
st I is closed_interval & J is right_open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is closed_interval & J is right_open_interval & I meets J; then
consider p,q being Real such that
A2: I = [.p,q.];
consider r be Real, s being R_eal such that
A3: J = [.r,s.[ by A1;
I <> {} & J <> {} by A1; then
A4:p <= q & r < s & p < s & r <= q by A1,A2,A3,XXREAL_1:29,27,95,277;
A7:s <> -infty by A1,A3,XXREAL_1:95,XXREAL_0:5;
per cases by A7,XXREAL_0:14;
suppose B1: s = +infty;
q < s by B1,XREAL_0:def 1,XXREAL_0:9; then
A8: [.s,q.] = {} & ].s,q.[ = {} by XXREAL_1:29,28;
reconsider K = [.p,r.[, L = ].s,q.[ as Subset of REAL;
r is R_eal & q is R_eal by XXREAL_0:def 1; then
K is right_open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:304,A8;
end;
suppose s in REAL; then
reconsider s1 = s as Real;
reconsider K = [.p,r.[, L = [.s1,q.] as Subset of REAL;
r is R_eal by XXREAL_0:def 1; then
K is right_open_interval & L is closed_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:304,95;
end;
end;
RRdif:
for I,J be Subset of REAL
st I is right_open_interval & J is right_open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume I is right_open_interval & J is right_open_interval
& I meets J; then
consider K,L be Subset of REAL such that
A2: K is right_open_interval & L is right_open_interval &
K misses L & I \ J = K \/ L by INTERVAL02;
reconsider K,L as Interval by A2;
thus thesis by A2;
end;
LRdif:
for I,J be Subset of REAL
st I is left_open_interval & J is right_open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is left_open_interval & J is right_open_interval
& I meets J; then
consider p be R_eal,q being Real such that
A2: I = ].p,q.];
consider r be Real, s being R_eal such that
A3: J = [.r,s.[ by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r <= s & p < s & r <= q by A1,A2,A3,XXREAL_1:26,27,274,279;
A7:s <> -infty by A1,A3,XXREAL_1:274,XXREAL_0:5;
per cases by A7,XXREAL_0:14;
suppose B1: s = +infty;
q < s by B1,XREAL_0:def 1,XXREAL_0:9; then
A8: [.s,q.] = {} & ].s,q.[ = {} by XXREAL_1:29,28;
reconsider K = ].p,r.[, L = ].s,q.[ as Subset of REAL;
r is R_eal & q is R_eal by XXREAL_0:def 1; then
K is open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:303,A8;
end;
suppose s in REAL; then
reconsider s1 = s as Real;
reconsider K = ].p,r.[, L = [.s1,q.] as Subset of REAL;
r is R_eal by XXREAL_0:def 1; then
K is open_interval & L is closed_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:303,93;
end;
end;
OLdif:
for I,J be Subset of REAL
st I is open_interval & J is left_open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is open_interval & J is left_open_interval & I meets J; then
consider p,q being R_eal such that
A2: I = ].p,q.[;
consider r be R_eal, s being Real such that
A3: J = ].r,s.] by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r < s & q > r & s > p by A1,A2,A3,XXREAL_1:28,26,276,91;
A7:r <> +infty by A1,A3,XXREAL_1:276,XXREAL_0:3;
per cases by A7,XXREAL_0:14;
suppose r = -infty; then
A8: ].p,r.] = {} & ].p,r.[ = {} by XXREAL_0:5,XXREAL_1:26,28;
reconsider K = ].p,r.[, L = ].s,q.[ as Subset of REAL;
s is R_eal by XXREAL_0:def 1; then
K is open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:305,A8;
end;
suppose r in REAL; then
reconsider r1 = r as Real;
reconsider K = ].p,r1.], L = ].s,q.[ as Subset of REAL;
s is R_eal by XXREAL_0:def 1; then
K is left_open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:305,91;
end;
end;
CLdif:
for I,J be Subset of REAL
st I is closed_interval & J is left_open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is closed_interval & J is left_open_interval & I meets J; then
consider p,q being Real such that
A2: I = [.p,q.];
consider r be R_eal, s being Real such that
A3: J = ].r,s.] by A1;
I <> {} & J <> {} by A1; then
A4:p <= q & r < s & q > r & s >= p by A1,A2,A3,XXREAL_1:29,26,90,280;
A7:r <> +infty by A1,A3,XXREAL_1:90,XXREAL_0:3;
per cases by A7,XXREAL_0:14;
suppose B1: r = -infty;
r < p by B1,XREAL_0:def 1,XXREAL_0:12; then
A8: [.p,r.] = {} & ].p,r.[ = {} by XXREAL_1:29,28;
reconsider K = ].p,r.[, L = ].s,q.] as Subset of REAL;
p is R_eal & s is R_eal by XXREAL_0:def 1; then
K is open_interval & L is left_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:308,A8;
end;
suppose r in REAL; then
reconsider r1 = r as Real;
reconsider K = [.p,r1.], L = ].s,q.] as Subset of REAL;
s is R_eal by XXREAL_0:def 1; then
K is closed_interval & L is left_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:308,90;
end;
end;
RLdif:
for I,J be Subset of REAL
st I is right_open_interval & J is left_open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is right_open_interval & J is left_open_interval
& I meets J; then
consider p be Real, q being R_eal such that
A2: I = [.p,q.[;
consider r be R_eal, s being Real such that
A3: J = ].r,s.] by A1;
I <> {} & J <> {} by A1; then
A4:p <= q & r < s & q > r & s >= p by A1,A2,A3,XXREAL_1:27,26,274,279;
A7:r <> +infty by A1,A3,XXREAL_1:274,XXREAL_0:3;
per cases by A7,XXREAL_0:14;
suppose B1: r = -infty;
r < p by B1,XREAL_0:def 1,XXREAL_0:12; then
A8: [.p,r.] = {} & ].p,r.[ = {} by XXREAL_1:29,28;
reconsider K = ].p,r.[, L = ].s,q.[ as Subset of REAL;
p is R_eal & s is R_eal by XXREAL_0:def 1; then
K is open_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:306,A8;
end;
suppose r in REAL; then
reconsider r1 = r as Real;
reconsider K = [.p,r1.], L = ].s,q.[as Subset of REAL;
s is R_eal by XXREAL_0:def 1; then
K is closed_interval & L is open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A2,A3,XXREAL_1:306,89;
end;
end;
LLdif:
for I,J be Subset of REAL
st I is left_open_interval & J is left_open_interval & I meets J
ex K,L be Interval st K misses L & I \ J = K \/ L
proof
let I,J be Subset of REAL;
assume A1: I is left_open_interval & J is left_open_interval
& I meets J; then
consider p be R_eal, q being Real such that
A2: I = ].p,q.];
consider r be R_eal, s being Real such that
A3: J = ].r,s.] by A1;
I <> {} & J <> {} by A1; then
A4:p < q & r < s & q > r & s > p by A1,A2,A3,XXREAL_1:26,92;
A7:r <> +infty by A1,A3,XXREAL_1:92,XXREAL_0:3;
per cases by A7,XXREAL_0:14;
suppose r = -infty; then
A8: ].p,r.] = {} & ].p,r.[ = {} by XXREAL_0:5,XXREAL_1:26,28;
reconsider K = ].p,r.[, L = ].s,q.] as Subset of REAL;
p is R_eal & s is R_eal by XXREAL_0:def 1; then
K is open_interval & L is left_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A8,A1,A2,A3,XXREAL_1:199;
end;
suppose r in REAL; then
reconsider r1 = r as Real;
reconsider K = ].p,r1.], L = ].s,q.]as Subset of REAL;
s is R_eal by XXREAL_0:def 1; then
K is left_open_interval & L is left_open_interval; then
reconsider K,L as Interval;
take K,L;
thus K misses L & I \ J = K \/ L by A4,A1,A2,A3,XXREAL_1:199,92;
end;
end;
INTERVAL03:
for I,J be Subset of REAL
st I is right_open_interval & J is right_open_interval
holds I /\ J is right_open_interval
proof
let I,J be Subset of REAL;
assume A1: I is right_open_interval & J is right_open_interval; then
consider p be Real, q be R_eal such that
A2: I = [.p,q.[;
consider r be Real, s be R_eal such that
A3: J = [.r,s.[ by A1;
A4:min(s,q) is R_eal by XXREAL_0:def 1;
I /\ J = [.max(r,p),min(s,q).[ by A2,A3,XXREAL_1:139;
hence I /\ J is right_open_interval by A4;
end;
OOmeet:
for I,J be Interval st I is open_interval & J is open_interval & I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is open_interval & J is open_interval & I meets J; then
consider p,q be R_eal such that
A2: I = ].p,q.[;
consider r,s be R_eal such that
A3: J = ].r,s.[ by A1;
A4:I /\ J = ].max(p,r),min(q,s).[ by A2,A3,XXREAL_1:142;
max(p,r) is R_eal & min(q,s) is R_eal by XXREAL_0:def 1; then
I /\ J is open_interval by A4;
hence I /\ J is Interval;
end;
OCmeet:
for I,J be Interval st I is open_interval & J is closed_interval & I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is open_interval & J is closed_interval & I meets J; then
consider p,q be R_eal such that
A2: I = ].p,q.[;
consider r,s be Real such that
A3: J = [.r,s.] by A1;
per cases;
suppose p < r & s < q;
hence I /\ J is Interval by A2,A3,XXREAL_1:47,XBOOLE_1:28;
end;
suppose p < r & q <= s; then
I /\ J = [.r,q.[ by A2,A3,XXREAL_1:148; then
I /\ J is right_open_interval;
hence I /\ J is Interval;
end;
suppose p >= r & q > s; then
I /\ J = ].p,s.] by A2,A3,XXREAL_1:149; then
I /\ J is left_open_interval;
hence I /\ J is Interval;
end;
suppose p >= r & q <= s;
hence I /\ J is Interval by A2,A3,XXREAL_1:37,XBOOLE_1:28;
end;
end;
ORmeet:
for I,J be Interval st I is open_interval & J is right_open_interval
& I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is open_interval & J is right_open_interval & I meets J; then
consider p,q being R_eal such that
A2: I = ].p,q.[;
consider r be Real, s being R_eal such that
A3: J = [.r,s.[ by A1;
per cases;
suppose p < r & q <= s; then
I /\ J = [.r,q.[ by A2,A3,XXREAL_1:154; then
I /\ J is right_open_interval;
hence I /\ J is Interval;
end;
suppose p < r & s <= q;
hence I /\ J is Interval by A2,A3,XXREAL_1:48,XBOOLE_1:28;
end;
suppose p >= r & q >= s; then
I /\ J = ].p,s.[ by A2,A3,XXREAL_1:155; then
I /\ J is open_interval;
hence I /\ J is Interval;
end;
suppose r <= p & q < s;
hence I /\ J is Interval by A2,A3,XXREAL_1:45,XBOOLE_1:28;
end;
end;
OLmeet:
for I,J be Interval
st I is open_interval & J is left_open_interval & I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is open_interval & J is left_open_interval & I meets J; then
consider p,q being R_eal such that
A2: I = ].p,q.[;
consider r be R_eal, s being Real such that
A3: J = ].r,s.] by A1;
per cases;
suppose p <= r & q <= s; then
I /\ J = ].r,q.[ by A2,A3,XXREAL_1:158; then
I /\ J is open_interval;
hence I /\ J is Interval;
end;
suppose p <= r & s < q;
hence I /\ J is Interval by A2,A3,XXREAL_1:49,XBOOLE_1:28;
end;
suppose p >= r & q > s; then
I /\ J = ].p,s.] by A2,A3,XXREAL_1:159; then
I /\ J is left_open_interval;
hence I /\ J is Interval;
end;
suppose p >= r & q <= s;
hence I /\ J is Interval by A2,A3,XXREAL_1:41,XBOOLE_1:28;
end;
end;
CCmeet:
for I,J be Interval
st I is closed_interval & J is closed_interval & I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is closed_interval & J is closed_interval & I meets J; then
consider p,q being Real such that
A2: I = [.p,q.];
consider r,s being Real such that
A3: J = [.r,s.] by A1;
A4:I /\ J = [.max(r,p),min(s,q).] by A2,A3,XXREAL_1:140;
I /\ J is closed_interval by A4;
hence I /\ J is Interval;
end;
CRmeet:
for I,J be Interval
st I is closed_interval & J is right_open_interval & I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is closed_interval & J is right_open_interval & I meets J; then
consider p,q being Real such that
A2: I = [.p,q.];
consider r be Real, s being R_eal such that
A3: J = [.r,s.[ by A1;
per cases;
suppose r <= p & s <= q; then
I /\ J = [.p,s.[ by A2,A3,XXREAL_1:144; then
I /\ J is right_open_interval;
hence I /\ J is Interval;
end;
suppose r <= p & s > q;
hence I /\ J is Interval by A2,A3,XXREAL_1:43,XBOOLE_1:28;
end;
suppose r > p & s <= q;
hence I /\ J is Interval by A2,A3,XXREAL_1:35,XBOOLE_1:28;
end;
suppose r > p & s > q; then
I /\ J = [.r,q.] by A2,A3,XXREAL_1:145; then
I /\ J is closed_interval;
hence I /\ J is Interval;
end;
end;
CLmeet:
for I,J be Interval
st I is closed_interval & J is left_open_interval & I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is closed_interval & J is left_open_interval & I meets J; then
consider p,q being Real such that
A2: I = [.p,q.];
consider r be R_eal, s being Real such that
A3: J = ].r,s.] by A1;
per cases;
suppose r < p & s <= q; then
I /\ J = [.p,s.] by A2,A3,XXREAL_1:146; then
I /\ J is closed_interval;
hence I /\ J is Interval;
end;
suppose r < p & q < s;
hence I /\ J is Interval by A2,A3,XXREAL_1:39,XBOOLE_1:28;
end;
suppose p <= r & q <= s; then
I /\ J = ].r,q.] by A2,A3,XXREAL_1:147; then
I /\ J is left_open_interval;
hence I /\ J is Interval;
end;
suppose p <= r & s < q;
hence I /\ J is Interval by A2,A3,XXREAL_1:36,XBOOLE_1:28;
end;
end;
RRmeet:
for I,J be Interval
st I is right_open_interval & J is right_open_interval & I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is right_open_interval & J is right_open_interval
& I meets J; then
consider p be Real, q being R_eal such that
A2: I = [.p,q.[;
consider r be Real, s being R_eal such that
A3: J = [.r,s.[ by A1;
A4:I /\ J = [.max(r,p),min(s,q).[ by A2,A3,XXREAL_1:139;
max(p,r) is Real & min(q,s) is R_eal by XXREAL_0:def 1; then
I /\ J is right_open_interval by A4;
hence I /\ J is Interval;
end;
RLmeet:
for I,J be Interval
st I is right_open_interval & J is left_open_interval & I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is right_open_interval & J is left_open_interval
& I meets J; then
consider p be Real, q being R_eal such that
A2: I = [.p,q.[;
consider r be R_eal, s being Real such that
A3: J = ].r,s.] by A1;
per cases;
suppose r < p & s < q; then
I /\ J = [.p,s.] by A2,A3,XXREAL_1:152; then
I /\ J is closed_interval;
hence I /\ J is Interval;
end;
suppose r < p & q <= s;
hence I /\ J is Interval by A2,A3,XXREAL_1:40,XBOOLE_1:28;
end;
suppose p <= r & q <= s; then
I /\ J = ].r,q.[ by A2,A3,XXREAL_1:153; then
I /\ J is open_interval;
hence I /\ J is Interval;
end;
suppose p <= r & s < q;
hence I /\ J is Interval by A2,A3,XXREAL_1:44,XBOOLE_1:28;
end;
end;
LLmeet:
for I,J be Interval
st I is left_open_interval & J is left_open_interval & I meets J
holds I /\ J is Interval
proof
let I,J be Interval;
assume A1: I is left_open_interval & J is left_open_interval
& I meets J; then
consider p be R_eal, q being Real such that
A2: I = ].p,q.];
consider r be R_eal, s being Real such that
A3: J = ].r,s.] by A1;
A4:I /\ J = ].max(p,r),min(q,s).] by A2,A3,XXREAL_1:141;
max(p,r) is R_eal & min(q,s) is Real by XXREAL_0:def 1; then
I /\ J is left_open_interval by A4;
hence I /\ J is Interval;
end;
theorem
for S be Subset-Family of REAL
st S = { I where I is Subset of REAL : I is right_open_interval }
holds S is with_empty_element semi-diff-closed cap-closed
proof
let S be Subset-Family of REAL;
assume A1: S = { I where I is Subset of REAL : I is right_open_interval };
0 in REAL by NUMBERS:19; then
[. 0,0 .[ is right_open_interval by NUMBERS:31; then
{} in S by A1;
hence S is with_empty_element;
now let A,B be set;
assume A2: A in S & B in S; then
consider I be Subset of REAL such that
A3: A = I & I is right_open_interval by A1;
consider J be Subset of REAL such that
A4: B = J & J is right_open_interval by A1,A2;
per cases;
suppose I meets J; then
consider K,L be Subset of REAL such that
A5: K is right_open_interval & L is right_open_interval
& K misses L & I \ J = K \/ L by A3,A4,INTERVAL02;
set F = <*K,L*>;
K in S & L in S by A1,A5; then
{K,L} c= S by ZFMISC_1:32; then
rng F c= S by FINSEQ_2:127; then
reconsider F as FinSequence of S by FINSEQ_1:def 4;
reconsider F as disjoint_valued FinSequence of S by A5,Disjoint2;
take F;
rng F = {K,L} by FINSEQ_2:127;
hence Union F = A \ B by A3,A4,A5,ZFMISC_1:75;
end;
suppose A13: I misses J;
set F = <*I*>;
{I} c= S by A2,A3,ZFMISC_1:31; then
dom F = Seg 1 & rng F c= S by FINSEQ_1:38; then
reconsider F as FinSequence of S by FINSEQ_1:def 4;
reconsider F as disjoint_valued FinSequence of S by TTT1;
take F;
rng F = {I} by FINSEQ_1:38;
hence Union F = A \ B by A13,A3,A4,XBOOLE_1:83;
end;
end;
hence S is semi-diff-closed;
now let A,B be set;
assume B2: A in S & B in S; then
consider I be Subset of REAL such that
B3: A = I & I is right_open_interval by A1;
consider J be Subset of REAL such that
B4: B = J & J is right_open_interval by A1,B2;
I /\ J is right_open_interval by B3,B4,INTERVAL03;
hence A /\ B in S by A1,B3,B4;
end;
hence S is cap-closed;
end;
theorem
the set of all I where I is Interval
is semialgebra_of_sets of REAL
proof
set S = the set of all I where I is Interval;
now let A be object;
assume A in S; then
consider I be Interval such that
A2: A = I;
thus A in bool REAL by A2;
end; then
S c= bool REAL; then
reconsider S as Subset-Family of REAL;
{} c= REAL; then
reconsider E = {} as Subset of REAL;
A3:E in S; then
A4:S is with_empty_element;
now let A,B be set;
assume A5: A in S & B in S; then
consider I be Interval such that
A6: A = I;
consider J be Interval such that
A7: B = J by A5;
per cases;
suppose A8: I misses J;
set F = <*A*>;
A9: rng F = {A} by FINSEQ_1:38; then
reconsider F as FinSequence of S by A5,ZFMISC_1:31,FINSEQ_1:def 4;
reconsider F as disjoint_valued FinSequence of S by TTT1;
take F;
thus Union F = A \ B by A6,A8,A7,XBOOLE_1:83,A9;
end;
suppose A10: I meets J;
(I is open_interval or I is closed_interval or
I is right_open_interval or I is left_open_interval) &
(J is open_interval or J is closed_interval or
J is right_open_interval or J is left_open_interval) by MEASURE5:1; then
consider K,L be Interval such that
A11: K misses L & I \ J = K \/ L by A10,OOdif,OCdif,ORdif,OLdif,
COdif,CCdif,CRdif,CLdif,ROdif,RCdif,RRdif,RLdif,
LOdif,LCdif,LRdif,LLdif;
set F = <*K,L*>;
K in S & L in S; then
{K,L} c= S by ZFMISC_1:32; then
rng F c= S by FINSEQ_2:127; then
reconsider F as FinSequence of S by FINSEQ_1:def 4;
reconsider F as disjoint_valued FinSequence of S by A11,Disjoint2;
take F;
rng F = {K,L} by FINSEQ_2:127;
hence Union F = A \ B by A6,A7,A11,ZFMISC_1:75;
end;
end; then
P2:S is semi-diff-closed;
now let A,B be set;
assume A12: A in S & B in S; then
consider I be Interval such that
A13: A = I;
consider J be Interval such that
A14: B = J by A12;
per cases;
suppose I misses J;
hence A /\ B in S by A3,A13,A14;
end;
suppose A15: I meets J;
(I is open_interval or I is closed_interval or
I is right_open_interval or I is left_open_interval) &
(J is open_interval or J is closed_interval or
J is right_open_interval or J is left_open_interval) by MEASURE5:1; then
I /\ J is Interval by A15,OOmeet,OCmeet,ORmeet,OLmeet,CCmeet,
CRmeet,CLmeet,RRmeet,RLmeet,LLmeet;
hence A /\ B in S by A13,A14;
end;
end; then
P3:S is cap-closed;
reconsider R = ].-infty,+infty.[ as Subset of REAL;
R is open_interval; then
REAL in S by XXREAL_1:224;
hence thesis by A4,P2,P3,Def1;
end;