:: Transitive Closure of Fuzzy Relations
:: by Takashi Mitsuishi and Grzegorz Bancerek
::
:: Received November 23, 2003
:: Copyright (c) 2003-2019 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 NUMBERS, XBOOLE_0, VALUED_0, FUZZY_1, FUZZY_2, LATTICE3,
SUBSET_1, FUNCT_1, XXREAL_0, RELAT_1, ZFMISC_1, TARSKI, VALUED_1,
RELAT_2, FUZZY_4, CARD_1, LATTICES, PARTFUN1, LFUZZY_0, EQREL_1,
XXREAL_1, SEQ_4, FUNCT_3, FUNCT_7, FUNCT_2, ARYTM_3, STRUCT_0, QC_LANG1,
CARD_3, FUNCOP_1, REWRITE1, WAYBEL_0, NEWTON, ORDINAL2, LATTICE2,
WAYBEL_1, NAT_1, LFUZZY_1, REAL_1, XCMPLX_0;
notations TARSKI, XBOOLE_0, ZFMISC_1, RELAT_1, FUNCT_1, FUNCT_2, ORDINAL1,
NUMBERS, XCMPLX_0, DOMAIN_1, PARTFUN1, CARD_3, RELAT_2, BINOP_1, FUNCT_3,
RFUNCT_1, SUBSET_1, XREAL_0, NAT_1, SEQ_4, VALUED_0, RCOMP_1, RELSET_1,
STRUCT_0, LATTICE3, YELLOW_0, WAYBEL_0, YELLOW_1, WAYBEL_1, WAYBEL_3,
FUZZY_1, FUZZY_2, FUZZY_4, FUNCOP_1, LFUZZY_0, XXREAL_0;
constructors DOMAIN_1, SQUARE_1, RFUNCT_1, MONOID_0, WAYBEL_3, FUZZY_2,
FUZZY_4, LFUZZY_0, SEQ_4, RELSET_1, FUNCOP_1, FUZZY_1;
registrations XBOOLE_0, SUBSET_1, XREAL_0, NAT_1, MEMBERED, STRUCT_0,
LATTICE3, MONOID_0, YELLOW_1, WAYBEL10, WAYBEL17, LFUZZY_0, RELAT_1,
FUNCT_2, NUMBERS, FUZZY_1, RELSET_1, VALUED_0, ORDINAL1, CARD_1;
requirements BOOLE, SUBSET, NUMERALS, REAL, ARITHM;
definitions TARSKI, XBOOLE_0, FUZZY_1;
equalities BINOP_1;
expansions FUZZY_1;
theorems XBOOLE_0, ZFMISC_1, WAYBEL_1, RELAT_1, LATTICE3, YELLOW_0, TARSKI,
SEQ_4, YELLOW_2, WAYBEL_3, CARD_3, YELLOW_1, FUNCOP_1, FUZZY_2, FUZZY_4,
FUNCT_3, FUZZY_1, PARTFUN1, LFUZZY_0, RELAT_2, ORDINAL1, XXREAL_0,
BINOP_1, RELSET_1, FUNCT_2;
schemes FRAENKEL, RECDEF_1, NAT_1, LFUZZY_0;
begin :: Inclusion of fuzzy relations
reserve X, Y for non empty set;
registration
let X;
cluster -> real-valued for Membership_Func of X;
coherence;
end;
definition
let X,Y;
let f,g be RMembership_Func of X,Y;
redefine pred f is_less_than g means
for x being Element of X, y being Element of Y holds f.(x,y) <= g.(x,y);
compatibility
proof
thus f is_less_than g iff for x being Element of X, y being Element of Y
holds f.(x,y) <= g.(x,y)
proof
hereby
assume
A1: f is_less_than g;
thus for x being Element of X, y being Element of Y holds f.(x,y) <= g
.(x,y )
proof
let x be Element of X, y be Element of Y;
dom f = [:X,Y:] & [x,y] in [:X,Y:] by FUNCT_2:def 1;
hence thesis by A1;
end;
end;
assume
A2: for x being Element of X, y being Element of Y holds f.(x,y) <= g.(x,y);
A3: for c being set st c in dom f holds f.c <= g.c
proof
let c be set;
assume
A4: c in dom f;
then consider x,y being object such that
A5: [x,y] = c by RELAT_1:def 1;
reconsider y as Element of Y by A4,A5,ZFMISC_1:87;
reconsider x as Element of X by A4,A5,ZFMISC_1:87;
f.(x,y) <= g.(x,y) by A2;
hence thesis by A5;
end;
dom g = [:X,Y:] by FUNCT_2:def 1;
hence thesis by A3;
end;
end;
end;
theorem Th1:
for R,S being Membership_Func of X st for x being Element of X
holds R.x = S.x holds R = S
proof
let R,S be Membership_Func of X;
assume for x being Element of X holds R.x = S.x;
then
A1: for x being Element of X st x in dom R holds R.x = S.x;
dom R = X & dom S = X by FUNCT_2:def 1;
hence thesis by A1,PARTFUN1:5;
end;
theorem Th2:
for R,S being RMembership_Func of X,Y st for x being Element of X
, y being Element of Y holds R.(x,y) = S.(x,y) holds R = S
proof
let R,S be RMembership_Func of X,Y;
assume
A1: for x being Element of X, y being Element of Y holds R.(x,y) = S.(x, y);
A2: for x,y being object st [x,y] in dom R holds R.(x,y) = S.(x,y)
proof
let x,y be object;
assume
A3: [x,y] in dom R;
then reconsider x as Element of X by ZFMISC_1:87;
reconsider y as Element of Y by A3,ZFMISC_1:87;
R.(x,y) = S.(x,y) by A1;
hence thesis;
end;
dom R = [:X,Y:] & dom S = [:X,Y:] by FUNCT_2:def 1;
hence thesis by A2,BINOP_1:20;
end;
theorem Th3:
for R,S being Membership_Func of X holds R = S iff R c= S & S c= R
proof
let R,S be Membership_Func of X;
thus R=S implies R c= S & S c= R;
assume
A1: R c= S & S c= R;
for x being Element of X holds R.x = S.x
proof
let x be Element of X;
R.x <= S.x & S.x <= R.x by A1;
hence thesis by XXREAL_0:1;
end;
hence thesis by Th1;
end;
theorem
for R being Membership_Func of X holds R c= R;
theorem Th5:
for R,S,T being Membership_Func of X holds R c= S & S c= T implies R c= T
proof
let R,S,T be Membership_Func of X;
assume
A1: R c= S & S c= T;
for x being Element of X holds R.x <= T.x
proof
let x be Element of X;
R.x <= S.x & S.x <= T.x by A1;
hence thesis by XXREAL_0:2;
end;
hence thesis;
end;
theorem Th6:
for X,Y,Z being non empty set, R,S being RMembership_Func of X,Y,
T,U being RMembership_Func of Y,Z holds R c= S & T c= U implies R(#)T c= S(#)U
proof
let X,Y,Z be non empty set;
let R,S be RMembership_Func of X,Y;
let T,U be RMembership_Func of Y,Z;
assume
A1: R c= S & T c= U;
for c being Element of [:X,Z:] holds (R(#)T).c <= (S(#)U).c
proof
let c be Element of [:X,Z:];
consider x,z being object such that
A2: [x,z] = c by RELAT_1:def 1;
A3: x in X & z in Z by A2,ZFMISC_1:87;
for y be set st y in Y holds R. [x,y] <= S. [x,y] & T. [y,z] <= U. [y, z]
proof
let y be set;
assume y in Y;
then [x,y] in [:X,Y:] & [y,z] in [:Y,Z:] by A3,ZFMISC_1:87;
hence thesis by A1;
end;
hence thesis by A2,A3,FUZZY_4:18;
end;
hence thesis;
end;
definition
let X be non empty set;
let f,g be Membership_Func of X;
redefine func min(f,g);
commutativity;
redefine func max(f,g);
commutativity;
end;
theorem
for f,g being Membership_Func of X holds min(f,g) c= f
proof
let f,g be Membership_Func of X;
let x be Element of X;
min(f,g).x = min(f.x,g.x) by FUZZY_1:def 3;
hence min(f,g).x <= f.x by XXREAL_0:17;
end;
theorem
for f,g being Membership_Func of X holds f c= max(f,g)
proof
let f,g be Membership_Func of X;
let x be Element of X;
max(f,g).x = max(f.x,g.x) by FUZZY_1:def 4;
hence thesis by XXREAL_0:25;
end;
begin :: Properties of fuzzy relations
definition
let X be non empty set;
let R be RMembership_Func of X,X;
attr R is reflexive means
Imf(X,X) c= R;
end;
definition
let X be non empty set;
let R be RMembership_Func of X,X;
redefine attr R is reflexive means
for x being Element of X holds R.( x,x) = 1;
compatibility
proof
hereby
assume R is reflexive;
then
A1: Imf(X,X) c= R;
thus for x being Element of X holds R.(x,x) = 1
proof
let x be Element of X;
Imf(X,X).(x,x) <= R.(x,x) by A1;
then R.(x,x) <= 1 & R.(x,x) >= 1 by FUZZY_4:4,25;
hence thesis by XXREAL_0:1;
end;
end;
assume
A2: for x being Element of X holds R.(x,x) = 1;
let x,y be Element of X;
per cases;
suppose
A3: x = y;
then Imf(X,X).(x,y) = 1 by FUZZY_4:25;
hence thesis by A2,A3;
end;
suppose
x <> y;
then Imf(X,X).(x,y) = 0 by FUZZY_4:25;
hence thesis by FUZZY_4:4;
end;
end;
end;
definition
let X be non empty set;
let R be RMembership_Func of X,X;
attr R is symmetric means
converse R = R;
end;
definition
let X be non empty set;
let R be RMembership_Func of X,X;
redefine attr R is symmetric means
for x,y being Element of X holds R .(x,y) = R.(y,x);
compatibility
proof
thus R is symmetric iff for x,y being Element of X holds R.(x,y) = R.(y,x)
proof
thus R is symmetric implies
for x,y being Element of X holds R.(x,y) = R.(y,x) by FUZZY_4:26;
assume
A1: for x,y being Element of X holds R.(x,y) = R.(y,x);
A2: for x,y being object st [x,y] in dom R
holds (converse R).(x,y) = R.(x, y)
proof
let x,y be object;
assume [x,y] in dom R;
then reconsider x,y as Element of X by ZFMISC_1:87;
R.(x,y) = R.(y,x) by A1;
hence thesis by FUZZY_4:26;
end;
dom converse R = [:X,X:] & dom R = [:X,X:] by FUNCT_2:def 1;
then converse R = R by A2,BINOP_1:20;
hence thesis;
end;
end;
end;
definition
let X be non empty set;
let R be RMembership_Func of X,X;
attr R is transitive means
R (#) R c= R;
end;
Lm1: for X,Y,Z being non empty set for R being RMembership_Func of X,Y for S
being RMembership_Func of Y,Z for x being Element of X, z being Element of Z
holds rng min(R,S,x,z) = the set of all
R. [x,y] "/\" S. [y,z] where y is Element of Y & rng min(R,S,x,z) <> {}
proof
let X,Y,Z be non empty set;
let R be RMembership_Func of X,Y;
let S be RMembership_Func of Y,Z;
let x be Element of X, z being Element of Z;
set L = the set of all R. [x,y] "/\" S. [y,z] where y is Element of Y;
A1: Y = dom min(R,S,x,z) & min(R,S,x,z) is PartFunc of dom min(R,S,x,z), rng
min (R,S,x,z) by FUNCT_2:def 1,RELSET_1:4;
for c be object holds c in L iff c in rng min(R,S,x,z)
proof
let c be object;
hereby
assume c in L;
then consider y being Element of Y such that
A2: c = R. [x,y] "/\" S. [y,z];
c = min(R,S,x,z).y by A2,FUZZY_4:def 2;
hence c in rng min(R,S,x,z) by A1,PARTFUN1:4;
end;
assume c in rng min(R,S,x,z);
then consider y being Element of Y such that
y in dom min(R,S,x,z) and
A3: c = min(R,S,x,z).y by PARTFUN1:3;
c = R. [x,y] "/\" S. [y,z] by A3,FUZZY_4:def 2;
hence thesis;
end;
hence rng min(R,S,x,z) = L by TARSKI:2;
thus rng min(R,S,x,z) <> {};
end;
definition
let X be non empty set;
let R be RMembership_Func of X,X;
redefine attr R is transitive means
for x,y,z being Element of X holds R. [x ,y] "/\" R. [y,z] <<= R. [x,z];
compatibility
proof
thus R is transitive iff for x,y,z being Element of X holds R. [x,y] "/\"
R. [y,z] <<= R. [x,z]
proof
hereby
assume R is transitive;
then
A1: R (#) R c= R;
thus for x,y,z being Element of X holds R. [x,y] "/\" R. [y,z] <<= R.
[x,z]
proof
let x,y,z be Element of X;
R.(x,y) "/\" R.(y,z) in the set of all
R.(x,y9) "/\" R.(y9,z) where y9 is
Element of X;
then R.(x,y) "/\" R.(y,z) <<= "\/"((the set of all
R.(x,y9) "/\" R.(y9,z) where y9
is Element of X), RealPoset [. 0,1 .]) by YELLOW_2:22;
then R.(x,y) "/\" R.(y,z) <<= (R (#) R).(x,z) by LFUZZY_0:22;
then
A2: R.(x,y) "/\" R.(y,z) <= (R (#) R).(x,z) by LFUZZY_0:3;
(R (#) R).(x,z) <= R.(x,z) by A1;
then R. [x,y] "/\" R. [y,z] <= R. [x,z] by A2,XXREAL_0:2;
hence thesis by LFUZZY_0:3;
end;
end;
assume
A3: for x,y,z being Element of X holds R. [x,y] "/\" R. [y,z] <<= R. [x,z];
thus R (#) R c= R
proof
let x,z be Element of X;
set W = rng min(R,R,x,z);
for r being Real st r in W holds r <= R. [x,z]
proof
let r be Real;
assume r in W;
then r in the set of all
R. [x,y9] "/\" R. [y9,z] where y9 is Element of X by Lm1;
then consider y being Element of X such that
A4: r = R. [x,y] "/\" R. [y,z];
R. [x,y] "/\" R. [y,z] <<= R. [x,z] by A3;
hence thesis by A4,LFUZZY_0:3;
end;
then upper_bound W <= R. [x,z] by SEQ_4:144;
hence thesis by FUZZY_4:def 3;
end;
end;
end;
end;
definition
let X be non empty set;
let R be RMembership_Func of X,X;
attr R is antisymmetric means
for x,y being Element of X holds R.(x,y ) <> 0 & R.(y,x) <> 0 implies x = y;
end;
registration
let X;
cluster Imf(X,X) -> symmetric transitive reflexive antisymmetric;
coherence
proof
thus Imf(X,X) is symmetric
proof
let x,y be Element of X;
per cases;
suppose
x=y;
hence thesis;
end;
suppose
A1: not x=y;
hence Imf(X,X).(x,y) = 0 by FUZZY_4:25
.= Imf(X,X).(y,x) by A1,FUZZY_4:25;
end;
end;
thus Imf(X,X) is transitive
proof
let x,y,z be Element of X;
per cases;
suppose
A2: x = z;
thus thesis
proof
per cases;
suppose
A3: x = y;
Imf(X,X). [x,y] "/\" Imf(X,X). [y,z] = min(Imf(X,X).(x,y), Imf
(X,X).(y,z))
.= 1 by A2,A3,FUZZY_4:25;
then Imf(X,X).(x,y) "/\" Imf(X,X).(y,z) <= Imf(X,X).(x,z) by A2,
FUZZY_4:25;
hence thesis by LFUZZY_0:3;
end;
suppose
A4: not x=y;
Imf(X,X). [x,y] "/\" Imf(X,X). [y,z] = min(Imf(X,X).(x,y),Imf(
X,X).(y,z))
.= min(Imf(X,X).(x,y),0) by A2,A4,FUZZY_4:25
.= min(0,0) by A4,FUZZY_4:25
.= 0;
then Imf(X,X).(x,y) "/\" Imf(X,X).(y,z) <= Imf(X,X).(x,z) by A2,
FUZZY_4:25;
hence thesis by LFUZZY_0:3;
end;
end;
end;
suppose
A5: not x=z;
thus thesis
proof
per cases;
suppose
A6: x=y;
Imf(X,X). [x,y] "/\" Imf(X,X). [y,z] = min(Imf(X,X).(x,y),Imf
(X,X).(y,z))
.= min(Imf(X,X).(x,y),0) by A5,A6,FUZZY_4:25
.= min(1,0) by A6,FUZZY_4:25
.= 0 by XXREAL_0:def 9;
then Imf(X,X).(x,y) "/\" Imf(X,X).(y,z) <= Imf(X,X).(x,z) by A5,
FUZZY_4:25;
hence thesis by LFUZZY_0:3;
end;
suppose
A7: x <> y;
thus thesis
proof
per cases;
suppose
A8: y=z;
Imf(X,X). [x,y] "/\" Imf(X,X). [y,z] = min(Imf(X,X).(x,y)
,Imf(X,X).(y,z))
.= min(Imf(X,X).(x,y),1) by A8,FUZZY_4:25
.= min(0,1) by A7,FUZZY_4:25
.= 0 by XXREAL_0:def 9;
then Imf(X,X).(x,y) "/\" Imf(X,X).(y,z) <= Imf(X,X).(x,z) by A5
,FUZZY_4:25;
hence thesis by LFUZZY_0:3;
end;
suppose
A9: y <> z;
Imf(X,X). [x,y] "/\" Imf(X,X). [y,z] = min(Imf(X,X).(x,y)
,Imf(X,X).(y,z))
.= min(Imf(X,X).(x,y),0) by A9,FUZZY_4:25
.= min(0,0) by A7,FUZZY_4:25
.= 0;
then Imf(X,X).(x,y) "/\" Imf(X,X).(y,z) <= Imf(X,X).(x,z) by A5
,FUZZY_4:25;
hence thesis by LFUZZY_0:3;
end;
end;
end;
end;
end;
end;
thus Imf(X,X) is reflexive;
thus for x,y being Element of X holds Imf(X,X).(x,y) <> 0 & Imf(X,X).(y,x)
<> 0 implies x = y by FUZZY_4:25;
end;
end;
registration
let X;
cluster reflexive transitive symmetric antisymmetric for
RMembership_Func of X,X;
existence
proof
take Imf(X,X);
thus thesis;
end;
end;
theorem Th9:
for R,S being RMembership_Func of X,X holds R is symmetric & S is
symmetric implies converse min(R,S) = min(R,S)
by FUZZY_4:8;
theorem Th10:
for R,S being RMembership_Func of X,X holds R is symmetric & S
is symmetric implies converse max(R,S) = max(R,S)
by FUZZY_4:7;
registration
let X;
let R,S be symmetric RMembership_Func of X,X;
cluster min(R,S) -> symmetric;
coherence
by Th9;
cluster max(R,S) -> symmetric;
coherence
by Th10;
end;
theorem Th11:
for R,S being RMembership_Func of X,X holds R is transitive & S
is transitive implies min(R,S) (#) min(R,S) c= min(R,S)
proof
let R,S be RMembership_Func of X,X;
assume that
A1: R is transitive and
A2: S is transitive;
let x be Element of X, y be Element of X;
min(R(#)S, S(#)S). [x,y] = min((S(#)S). [x,y], (R(#)S). [x,y]) by
FUZZY_1:def 3;
then
A3: min(R(#)S, S(#)S). [x,y] <= (S(#)S). [x,y] by XXREAL_0:17;
S(#)S c= S by A2;
then (S(#)S).(x,y) <= S.(x,y);
then
A4: min(R(#)S, S(#)S). [x,y] <= S. [x,y] by A3,XXREAL_0:2;
min(R(#)R, S(#)R). [x,y] = min((R(#)R). [x,y], (S(#)R). [x,y]) by
FUZZY_1:def 3;
then
A5: min(R(#)R, S(#)R). [x,y] <= (R(#)R). [x,y] by XXREAL_0:17;
R(#)R c= R by A1;
then (R(#)R).(x,y) <= R.(x,y);
then min(R(#)R, S(#)R). [x,y] <= R. [x,y] by A5,XXREAL_0:2;
then
A6: min(min(R(#)R, S(#)R). [x,y],min(R(#)S, S(#)S). [x,y]) <= min(R. [x,y],
S. [x,y]) by A4,XXREAL_0:18;
(min(R,S) (#) min(R,S)) c= min(min(R,S) (#) R, min(R,S) (#) S) by FUZZY_4:15;
then
A7: (min(R,S) (#) min(R,S)). [x,y] <= min(min(R,S) (#) R, min(R,S) (#) S). [
x,y];
min(R,S) (#) S c= min(R(#)S, S(#)S) by FUZZY_4:16;
then
A8: (min(R,S) (#) S). [x,y] <= min(R(#)S, S(#)S). [x,y];
min(R,S) (#) R c= min(R(#)R, S(#)R) by FUZZY_4:16;
then
min(min(R,S) (#) R, min(R,S) (#) S). [x,y] = min((min(R,S) (#) R). [x,y]
, ( min(R,S) (#) S). [x,y]) & (min(R,S) (#) R). [x,y] <= min(R(#)R, S(#)R). [x,
y] by FUZZY_1:def 3;
then
min(min(R,S) (#) R, min(R,S) (#) S). [x,y] <= min(min(R(#)R, S(#)R). [x
,y],min(R(#)S, S(#)S). [x,y]) by A8,XXREAL_0:18;
then
(min(R,S) (#) min(R,S)). [x,y] <= min(min(R(#)R, S(#)R). [x,y],min(R(#)
S, S(#)S). [x,y]) by A7,XXREAL_0:2;
then (min(R,S) (#) min(R,S)). [x,y] <= min(R. [x,y], S. [x,y]) by A6,
XXREAL_0:2;
hence thesis by FUZZY_1:def 3;
end;
registration
let X;
let R,S be transitive RMembership_Func of X,X;
cluster min(R,S) -> transitive;
coherence
by Th11;
end;
definition
let A be set, X be non empty set;
redefine func chi(A,X) -> Membership_Func of X;
coherence
proof
dom chi(A,X) = X by FUNCT_3:def 3;
hence chi(A,X) is Membership_Func of X by FUNCT_2:def 1;
end;
end;
theorem
for r being Relation of X st r is_reflexive_in X holds chi(r,[:X,X:])
is reflexive
proof
let r be Relation of X;
assume
A1: r is_reflexive_in X;
for x being Element of X holds chi(r,[:X,X:]).(x,x) = 1
proof
let x be Element of X;
[x,x] in r by A1,RELAT_2:def 1;
hence thesis by FUNCT_3:def 3;
end;
hence thesis;
end;
theorem
for r being Relation of X st r is antisymmetric holds chi(r,[:X,X:])
is antisymmetric
proof
let r be Relation of X;
assume r is antisymmetric;
then
A1: r is_antisymmetric_in field r by RELAT_2:def 12;
for x,y being Element of X holds chi(r,[:X,X:]).(x,y) <> 0 & chi(r,[:X,X
:]).(y,x) <> 0 implies x = y
proof
let x,y be Element of X;
assume that
A2: chi(r,[:X,X:]).(x,y) <> 0 and
A3: chi(r,[:X,X:]).(y,x) <> 0;
A4: x in field r & y in field r & [x,y] in r & [y,x] in r implies x = y by A1,
RELAT_2:def 4;
[x,y] in r by A2,FUNCT_3:def 3;
hence thesis by A3,A4,FUNCT_3:def 3,RELAT_1:15;
end;
hence thesis;
end;
theorem
for r being Relation of X st r is symmetric holds chi(r,[:X,X:]) is symmetric
proof
let r be Relation of X;
assume r is symmetric;
then
A1: r is_symmetric_in field r by RELAT_2:def 11;
let x,y be Element of X;
A2: x in field r & y in field r & [x,y] in r implies [y,x] in r by A1,
RELAT_2:def 3;
A3: x in field r & y in field r & [y,x] in r implies [x,y] in r by A1,
RELAT_2:def 3;
per cases;
suppose
A4: [x,y] in r;
then chi(r,[:X,X:]). [x,y] = 1 by FUNCT_3:def 3;
hence thesis by A2,A4,FUNCT_3:def 3,RELAT_1:15;
end;
suppose
not [x,y] in r;
then ( not [y,x] in r)& chi(r,[:X,X:]). [x,y] = 0 by A3,FUNCT_3:def 3
,RELAT_1:15;
hence thesis by FUNCT_3:def 3;
end;
end;
theorem
for r being Relation of X st r is transitive holds chi(r,[:X,X:]) is
transitive
proof
let r be Relation of X;
assume
A1: r is transitive;
let x,y,z be Element of X;
r is_transitive_in field r by A1,RELAT_2:def 16;
then
A2: x in field r & y in field r & z in field r & [x,y] in r & [y,z] in r
implies [x,z] in r by RELAT_2:def 8;
per cases;
suppose
A3: [x,y] in r;
thus thesis
proof
per cases;
suppose
A4: [y,z] in r;
chi(r,[:X,X:]). [x,y] "/\" chi(r,[:X,X:]). [y,z] = min(1,chi(r,[:X
,X:]). [y,z]) by A3,FUNCT_3:def 3
.= min(1,1) by A4,FUNCT_3:def 3
.= chi(r,[:X,X:]). [x,z] by A2,A3,A4,FUNCT_3:def 3,RELAT_1:15;
hence thesis by LFUZZY_0:3;
end;
suppose
A5: not [y,z] in r;
chi(r,[:X,X:]). [x,y] "/\" chi(r,[:X,X:]). [y,z] = min(1,chi(r,[:X
,X:]). [y,z]) by A3,FUNCT_3:def 3
.= min(1,0) by A5,FUNCT_3:def 3
.= 0 by XXREAL_0:def 9;
then
chi(r,[:X,X:]). [x,y] "/\" chi(r,[:X,X:]). [y,z] <= chi(r,[:X,X:])
. [x,z] by FUZZY_2:1;
hence thesis by LFUZZY_0:3;
end;
end;
end;
suppose
A6: not [x,y] in r;
thus thesis
proof
per cases;
suppose
A7: [y,z] in r;
chi(r,[:X,X:]). [x,y] "/\" chi(r,[:X,X:]). [y,z] = min(0,chi(r,[:
X,X:]). [y,z]) by A6,FUNCT_3:def 3
.= min(0,1) by A7,FUNCT_3:def 3
.= 0 by XXREAL_0:def 9;
then
chi(r,[:X,X:]). [x,y] "/\" chi(r,[:X,X:]). [y,z] <= chi(r,[:X,X:]
). [x,z] by FUZZY_2:1;
hence thesis by LFUZZY_0:3;
end;
suppose
A8: not [y,z] in r;
chi(r,[:X,X:]). [x,y] "/\" chi(r,[:X,X:]). [y,z] = min(0,chi(r,[:
X,X:]). [y,z]) by A6,FUNCT_3:def 3
.= min(0,0) by A8,FUNCT_3:def 3
.= 0;
then
chi(r,[:X,X:]). [x,y] "/\" chi(r,[:X,X:]). [y,z] <= chi(r,[:X,X:]
). [x,z] by FUZZY_2:1;
hence thesis by LFUZZY_0:3;
end;
end;
end;
end;
theorem
Zmf(X,X) is symmetric antisymmetric transitive
proof
thus Zmf(X,X) is symmetric
proof
let x,y be Element of X;
Zmf(X,X). [x,y] = 0 & Zmf(X,X). [y,x] = 0 by FUZZY_4:21;
hence thesis;
end;
thus Zmf(X,X) is antisymmetric
proof
let x,y be Element of X;
Zmf(X,X). [x,y] = 0 by FUZZY_4:21;
hence thesis;
end;
thus Zmf(X,X) is transitive
proof
let x,y,z be Element of X;
A1: Zmf(X,X). [x,z] = 0 by FUZZY_4:20;
Zmf(X,X). [x,y] "/\" Zmf(X,X). [y,z] = min(0, Zmf(X,X). [y,z]) by
FUZZY_4:20
.= min(0,0) by FUZZY_4:20
.= 0;
hence thesis by A1,LFUZZY_0:3;
end;
end;
theorem
Umf(X,X) is symmetric transitive reflexive
proof
thus Umf(X,X) is symmetric
proof
let x,y be Element of X;
thus Umf(X,X).(x,y) = Umf(X,X). [x,y] .= 1 by FUZZY_4:21
.= Umf(X,X). [y,x] by FUZZY_4:21
.= Umf(X,X).(y,x);
end;
thus Umf(X,X) is transitive
proof
let x,y,z be Element of X;
Umf(X,X). [x,y] "/\" Umf(X,X). [y,z] = min(1,Umf(X,X). [y,z]) by FUZZY_4:20
.= min(1,1) by FUZZY_4:20
.= 1;
then Umf(X,X). [x,y] "/\" Umf(X,X). [y,z] <= Umf(X,X). [x,z] by FUZZY_4:20;
hence thesis by LFUZZY_0:3;
end;
thus Umf(X,X) is reflexive
proof
let x be Element of X;
Umf(X,X). [x,x] = 1 by FUZZY_4:21;
hence thesis;
end;
end;
theorem
for R being RMembership_Func of X,X holds max(R,converse R) is symmetric
proof
let R be RMembership_Func of X,X;
set S = max(R,converse R);
let x,y be Element of X;
thus S.(x,y) = S. [x,y] .= max(R.(x,y), (converse R).(x,y)) by FUZZY_1:def 4
.= max(R.(x,y), R.(y,x)) by FUZZY_4:26
.= max((converse R).(y,x), R.(y,x)) by FUZZY_4:26
.= S. [y,x] by FUZZY_1:def 4
.= S.(y,x);
end;
theorem
for R being RMembership_Func of X,X holds min(R,converse R) is symmetric
proof
let R be RMembership_Func of X,X;
set S = min(R,converse R);
let x,y be Element of X;
thus S.(x,y) = S. [x,y] .= min(R.(x,y), (converse R).(x,y)) by FUZZY_1:def 3
.= min(R.(x,y), R.(y,x)) by FUZZY_4:26
.= min((converse R).(y,x), R.(y,x)) by FUZZY_4:26
.= S. [y,x] by FUZZY_1:def 3
.= S.(y,x);
end;
theorem
for R being RMembership_Func of X,X for R9 being RMembership_Func of X
,X st R9 is symmetric & R c= R9 holds max(R, converse R) c= R9
proof
let R be RMembership_Func of X,X;
let T be RMembership_Func of X,X;
assume that
A1: T is symmetric and
A2: R c= T;
let x,y be Element of X;
R. [y,x] <= T. [y,x] by A2;
then R.(y,x) <= T.(y,x);
then
A3: R.(y,x) <= T.(x,y) by A1;
R. [x,y] <= T. [x,y] by A2;
then max(R.(x,y), R.(y,x)) <= T.(x,y) by A3,XXREAL_0:28;
then max(R.(x,y), (converse R).(x,y)) <= T.(x,y) by FUZZY_4:26;
then max(R. [x,y], (converse R). [x,y]) <= T. [x,y];
hence thesis by FUZZY_1:def 4;
end;
theorem
for R being RMembership_Func of X,X for R9 being RMembership_Func of X
,X st R9 is symmetric & R9 c= R holds R9 c= min(R, converse R)
proof
let R be RMembership_Func of X,X;
let T be RMembership_Func of X,X;
assume that
A1: T is symmetric and
A2: T c= R;
let x,y be Element of X;
T. [y,x] <= R. [y,x] by A2;
then T.(y,x) <= R.(y,x);
then
A3: T.(x,y) <= R.(y,x) by A1;
T. [x,y] <= R. [x,y] by A2;
then T.(x,y) <= min(R.(x,y), R.(y,x)) by A3,XXREAL_0:20;
then T.(x,y) <= min(R.(x,y), (converse R).(x,y)) by FUZZY_4:26;
then T. [x,y] <= min(R. [x,y], (converse R). [x,y]);
hence thesis by FUZZY_1:def 3;
end;
begin :: Transitive closure of a fuzzy relation
definition
let X be non empty set;
let R be RMembership_Func of X,X;
let n be Nat;
func n iter R -> RMembership_Func of X,X means
:Def9:
ex F being sequence of Funcs([:X,X:],[. 0,1 .]) st it = F.n & F.0 = Imf(X,X)
& for k being Nat
ex Q being RMembership_Func of X,X st F.k = Q & F.(k + 1) = Q (#) R;
existence
proof
reconsider n9 = n as Element of NAT by ORDINAL1:def 12;
set D = the carrier of FuzzyLattice [:X,X:];
defpred P[set,set,set] means ex Q being Element of D st $2 = Q & $3 = @Q
(#) R;
A1: for k being Nat for x being Element of D ex y being Element
of D st P[k,x,y]
proof
let k be Nat;
let Q be Element of D;
set y = @Q (#) R;
reconsider y9 = ([:X,X:],y)@ as Element of D;
take y9;
thus thesis by LFUZZY_0:def 6;
end;
consider F being sequence of D such that
A2: F.0 = ([:X,X:],Imf(X,X))@ & for k being Nat holds P[k,F
.k,F.(k+1)] from RECDEF_1:sch 2 (A1);
reconsider F as sequence of Funcs([:X,X:],[. 0,1 .]) by LFUZZY_0:14;
reconsider IT = F.n9 as Element of FuzzyLattice [:X,X:] by LFUZZY_0:14;
reconsider IT9 = @(IT) as RMembership_Func of X,X;
take IT9;
thus ex F being sequence of Funcs([:X,X:],[. 0,1 .]) st IT9 = F.n & F.
0 = Imf(X,X) & for k being Nat ex Q being RMembership_Func of X,X st
F.k = Q & F.(k + 1) = Q (#) R
proof
take F;
thus IT9 = F.n by LFUZZY_0:def 5;
thus F.0 = Imf(X,X) by A2,LFUZZY_0:def 6;
thus for k being Nat ex Q being RMembership_Func of X,X st F.
k = Q & F.(k + 1) = Q (#) R
proof
let k be Nat;
reconsider n=k as Element of NAT by ORDINAL1:def 12;
reconsider Q9 = F.n as Element of D by LFUZZY_0:14;
reconsider Q = @Q9 as RMembership_Func of X,X;
take Q;
thus F.k = Q by LFUZZY_0:def 5;
P[n,F.n,F.(n+1)] by A2;
hence thesis;
end;
end;
end;
uniqueness
proof
let S,T be RMembership_Func of X,X;
given F being sequence of Funcs([:X,X:],[. 0,1 .]) such that
A3: S = F.n and
A4: F.0 = Imf(X,X) and
A5: for k being Nat ex Q being RMembership_Func of X,X st F
. k = Q & F.(k + 1) = Q (#) R;
given G being sequence of Funcs([:X,X:],[. 0,1 .]) such that
A6: T = G.n and
A7: G.0 = Imf(X,X) and
A8: for k being Nat ex Q being RMembership_Func of X,X st G
. k = Q & G.(k + 1) = Q (#) R;
defpred P[Nat] means F.$1 = G.$1;
A9: for k being Nat st P[k] holds P[k+1]
proof
let k be Nat;
assume
A10: F.k = G.k;
(ex Q being RMembership_Func of X,X st G.k = Q & G.(k + 1) = Q (#)
R )& ex Q9 being RMembership_Func of X,X st F.k = Q9 & F.(k + 1) = Q9 (#) R by
A5,A8;
hence thesis by A10;
end;
A11: P[0] by A4,A7;
for k being Nat holds P[k] from NAT_1:sch 2(A11,A9);
hence S=T by A3,A6;
end;
end;
reserve X for non empty set;
reserve R for RMembership_Func of X,X;
theorem Th22:
Imf(X,X) (#) R = R
proof
A1: for x,y being object st [x,y] in dom (Imf(X,X) (#) R)
holds (Imf(X,X) (#) R).(x,y) = R.(x,y)
proof
let x,y be object;
assume [x,y] in dom (Imf(X,X) (#) R);
then reconsider x,y as Element of X by ZFMISC_1:87;
set S = the set of all Imf(X,X).(x,z) "/\" R.(z,y) where z is Element of X;
for c being Element of RealPoset [. 0,1 .] st c in S holds c <<= R. [x ,y]
proof
let c be Element of RealPoset [. 0,1 .];
assume c in S;
then consider z being Element of X such that
A2: c = Imf(X,X).(x,z) "/\" R.(z,y);
per cases;
suppose
A3: x = z;
A4: R.(z,y) <= 1 by FUZZY_4:4;
c = min(R. [z,y],1) by A2,A3,FUZZY_4:25
.= R. [x,y] by A3,A4,XXREAL_0:def 9;
hence thesis by LFUZZY_0:3;
end;
suppose
A5: x <> z;
A6: 0 <= R.(z,y) by FUZZY_4:4;
c = min(R. [z,y],0) by A2,A5,FUZZY_4:25
.= 0 by A6,XXREAL_0:def 9;
then c <= R.(x,y) by FUZZY_4:4;
hence thesis by LFUZZY_0:3;
end;
end;
then
A7: (Imf(X,X) (#) R).(x,y) = "\/"((the set of all
Imf(X,X).(x,z) "/\" R.(z,y) where z is
Element of X), RealPoset [. 0,1 .]) & R.(x,y) is_>=_than S
by LATTICE3:def 9,LFUZZY_0:22;
for b being Element of RealPoset [. 0,1 .] st b is_>=_than S holds R.
(x,y) <<= b
proof
let b be Element of RealPoset [. 0,1 .];
A8: R.(x,y) <= 1 by FUZZY_4:4;
Imf(X,X).(x,x) "/\" R. [x,y] = min(1, R.(x,y)) by FUZZY_4:25
.= R. [x,y] by A8,XXREAL_0:def 9;
then
A9: R.(x,y) in S;
assume b is_>=_than S;
hence thesis by A9,LATTICE3:def 9;
end;
hence thesis by A7,YELLOW_0:32;
end;
dom (Imf(X,X) (#) R) = [:X,X:] by FUNCT_2:def 1
.= dom R by FUNCT_2:def 1;
hence thesis by A1,BINOP_1:20;
end;
theorem Th23:
R (#) Imf(X,X) = R
proof
A1: for x,y being object st [x,y] in dom (R (#) Imf(X,X))
holds (R (#) Imf(X,X)).(x,y) = R.(x,y)
proof
let x,y be object;
assume [x,y] in dom (R (#) Imf(X,X));
then reconsider x,y as Element of X by ZFMISC_1:87;
set S = the set of all R.(x,z) "/\" Imf(X,X).(z,y) where z is Element of X;
for c being Element of RealPoset [. 0,1 .] st c in S holds c <<= R. [x ,y]
proof
let c be Element of RealPoset [. 0,1 .];
assume c in S;
then consider z being Element of X such that
A2: c = R.(x,z) "/\" Imf(X,X).(z,y);
per cases;
suppose
A3: y = z;
A4: R.(x,z) <= 1 by FUZZY_4:4;
c = min(R. [x,z],1) by A2,A3,FUZZY_4:25
.= R. [x,y] by A3,A4,XXREAL_0:def 9;
hence thesis by LFUZZY_0:3;
end;
suppose
A5: not y = z;
A6: 0 <= R.(x,z) by FUZZY_4:4;
c = min(R. [x,z],0) by A2,A5,FUZZY_4:25
.= 0 by A6,XXREAL_0:def 9;
then c <= R.(x,y) by FUZZY_4:4;
hence thesis by LFUZZY_0:3;
end;
end;
then
A7: (R (#) Imf(X,X)).(x,y) = "\/"((the set of all
R.(x,z) "/\" Imf(X,X).(z,y) where z is
Element of X), RealPoset [. 0,1 .]) & R.(x,y) is_>=_than S
by LATTICE3:def 9,LFUZZY_0:22;
for b being Element of RealPoset [. 0,1 .] st b is_>=_than S holds R.
(x,y) <<= b
proof
let b be Element of RealPoset [. 0,1 .];
A8: R.(x,y) <= 1 by FUZZY_4:4;
R. [x,y] "/\" Imf(X,X).(y,y) = min( R. [x,y],1) by FUZZY_4:25
.= R. [x,y] by A8,XXREAL_0:def 9;
then
A9: R.(x,y) in S;
assume b is_>=_than S;
hence thesis by A9,LATTICE3:def 9;
end;
hence thesis by A7,YELLOW_0:32;
end;
dom (R (#) Imf(X,X)) = [:X,X:] by FUNCT_2:def 1
.= dom R by FUNCT_2:def 1;
hence thesis by A1,BINOP_1:20;
end;
theorem Th24:
0 iter R = Imf(X,X)
proof
ex F being sequence of Funcs([:X,X:],[. 0,1 .]) st 0 iter R = F.0 & F
.0 = Imf(X,X) & for k being Nat ex Q being RMembership_Func of X,X
st F.k = Q & F.(k + 1) = Q (#) R by Def9;
hence thesis;
end;
theorem Th25:
1 iter R = R
proof
consider F being sequence of Funcs([:X,X:],[. 0,1 .]) such that
A1: 1 iter R = F.1 & F.0 = Imf(X,X) and
A2: for k being Nat ex Q being RMembership_Func of X,X st F.k
= Q & F.(k + 1) = Q (#) R by Def9;
ex Q being RMembership_Func of X,X st F.0 = Q & F.(0 + 1 ) = Q (#) R by A2;
hence thesis by A1,Th22;
end;
theorem Th26:
for n being Nat holds (n+1) iter R = (n iter R) (#) R
proof
let n be Nat;
consider f being sequence of Funcs([:X,X:],[. 0,1 .]) such that
A1: (n+1) iter R = f.(n+1) & f.0 = Imf(X,X) and
A2: for k being Nat ex Q being RMembership_Func of X,X st f.k
= Q & f.(k + 1) = Q (#) R by Def9;
ex Q being RMembership_Func of X,X st f.n = Q & f.(n + 1) = Q(#)R by A2;
hence thesis by A1,A2,Def9;
end;
theorem Th27:
for m,n being Nat holds (m+n) iter R = (m iter R) (#) (n iter R)
proof
let m,n be Nat;
defpred P[Nat] means (m+ $1) iter R = (m iter R) (#) ($1 iter R);
A1: for n being Nat st P[n] holds P[n+1]
proof
let n be Nat;
assume
A2: (m+n) iter R = (m iter R) (#) (n iter R);
thus ((m) iter R) (#) ((n+1) iter R) = (m iter R) (#) ((n iter R) (#)R )
by Th26
.= ((m+n) iter R) (#) R by A2,LFUZZY_0:23
.= ((m+n)+1) iter R by Th26
.= (m+(n+1)) iter R;
end;
(m iter R) (#) (0 iter R) = (m iter R) (#) Imf(X,X) by Th24
.= m iter R by Th23;
then
A3: P[0];
for m being Nat holds P[m] from NAT_1:sch 2(A3,A1);
hence thesis;
end;
theorem
for m,n being Nat holds (m*n) iter R = m iter (n iter R)
proof
let m,n be Nat;
defpred P[Nat] means ($1 * n) iter R = $1 iter (n iter R);
A1: for m being Nat st P[m] holds P[m+1]
proof
let m be Nat;
assume
A2: (m*n) iter R = m iter (n iter R);
A3: (m+1) iter (n iter R) = (m iter (n iter R)) (#) (1 iter (n iter R)) by Th27
.= (m iter (n iter R)) (#) (n iter R) by Th25;
((m+1)*n) iter R = (m*n + 1*n) iter R
.= (m iter (n iter R)) (#) (n iter R) by A2,Th27;
hence thesis by A3;
end;
(0*n) iter R = Imf(X,X) by Th24
.= 0 iter (n iter R) by Th24;
then
A4: P[0];
for m being Nat holds P[m] from NAT_1:sch 2(A4,A1);
hence thesis;
end;
definition
let X be non empty set;
let R be RMembership_Func of X,X;
func TrCl R -> RMembership_Func of X,X equals
"\/"({n iter R where n is
Element of NAT : n > 0},FuzzyLattice [:X,X:]);
coherence
proof
set S = "\/"({n iter R where n is Element of NAT : n > 0}, FuzzyLattice [:
X,X:]);
S = @S by LFUZZY_0:def 5;
hence thesis;
end;
end;
theorem Th29:
for x,y being Element of X holds (TrCl R). [x,y] = "\/"(pi({n
iter R where n is Element of NAT : n > 0}, [x,y]), RealPoset [. 0,1 .])
proof
set Q = {n iter R where n is Element of NAT : n > 0};
Q c= the carrier of FuzzyLattice [:X,X:]
proof
let t be object;
assume t in Q;
then ex n being Element of NAT st t = n iter R & n > 0;
then reconsider t as Membership_Func of [:X,X:];
([:X,X:],t)@ is Element of FuzzyLattice [:X,X:];
then reconsider t as Element of FuzzyLattice [:X,X:] by LFUZZY_0:def 6;
t in the carrier of FuzzyLattice [:X,X:];
hence thesis;
end;
then reconsider Q as Subset of FuzzyLattice [:X,X:];
let x,z be Element of X;
reconsider i = [x,z] as Element of [:X,X:];
A1: for a being Element of [:X,X:] holds ([:X,X:] --> RealPoset [. 0,1 .]).a
is complete LATTICE by FUNCOP_1:7;
FuzzyLattice [:X,X:] = (RealPoset [. 0,1 .]) |^ [:X,X:] by LFUZZY_0:def 4
.= product ([:X,X:] --> RealPoset [. 0,1 .]) by YELLOW_1:def 5;
then (sup Q).i = "\/"(pi(Q,i), ([:X,X:] --> RealPoset [. 0,1 .]).i) by A1,
WAYBEL_3:32;
hence thesis by FUNCOP_1:7;
end;
theorem Th30:
R c= TrCl R
proof
for c being Element of [: X,X :] holds R.c <= (TrCl R).c
proof
set Q = {n iter R where n is Element of NAT : n > 0};
let c be Element of [: X,X :];
consider x,y being object such that
A1: [x,y] = c by RELAT_1:def 1;
reconsider x,y as Element of X by A1,ZFMISC_1:87;
R = 1 iter R by Th25;
then R in Q;
then
A2: R. [x,y] in pi(Q, [x,y]) by CARD_3:def 6;
(TrCl R). [x,y] = "\/"(pi(Q, [x,y]), RealPoset [. 0,1 .]) by Th29;
then R. [x,y] <<= (TrCl R). [x,y] by A2,YELLOW_2:22;
hence thesis by A1,LFUZZY_0:3;
end;
hence thesis;
end;
theorem Th31:
for n being Nat st n > 0 holds n iter R c= TrCl R
proof
let n9 be Nat;
assume
A1: n9 > 0;
for c being Element of [: X,X :] holds (n9 iter R).c <= (TrCl R).c
proof
reconsider n9 as Element of NAT by ORDINAL1:def 12;
set Q = {n iter R where n is Element of NAT : n > 0};
let c be Element of [: X,X :];
consider x,y being object such that
A2: [x,y] = c by RELAT_1:def 1;
reconsider x,y as Element of X by A2,ZFMISC_1:87;
n9 iter R in Q by A1;
then
A3: (n9 iter R). [x,y] in pi(Q, [x,y]) by CARD_3:def 6;
(TrCl R). [x,y] = "\/"(pi(Q, [x,y]), RealPoset [. 0,1 .]) by Th29;
then (n9 iter R). [x,y] <<= (TrCl R). [x,y] by A3,YELLOW_2:22;
hence thesis by A2,LFUZZY_0:3;
end;
hence thesis;
end;
theorem Th32:
for Q being Subset of FuzzyLattice X, x being Element of X holds
("\/"(Q,FuzzyLattice X)). x = "\/"(pi(Q, x), RealPoset [. 0,1 .])
proof
let Q be Subset of FuzzyLattice X;
let x be Element of X;
A1: for a being Element of X holds (X --> RealPoset [. 0,1 .]).a is complete
LATTICE by FUNCOP_1:7;
FuzzyLattice X = (RealPoset [. 0,1 .]) |^ X by LFUZZY_0:def 4
.= product (X --> RealPoset [. 0,1 .]) by YELLOW_1:def 5;
then (sup Q).x = "\/"(pi(Q,x), (X --> RealPoset [. 0,1 .]).x) by A1,
WAYBEL_3:32;
hence thesis by FUNCOP_1:7;
end;
Lm2: for R being RMembership_Func of X,X, Q being Subset of FuzzyLattice [:X,X
:], x,z being Element of X holds the set of all
R.(x,y) "/\" (@("\/"(Q,FuzzyLattice [:X,X:]))
).(y,z) where y is Element of X = the set of all R. [x,y] "/\" "\/"(pi(Q,
[y,z]), RealPoset [. 0,1 .]) where y is Element of X
proof
let R be RMembership_Func of X,X;
let Q be Subset of FuzzyLattice [:X,X:];
let x,z be Element of X;
defpred P[Element of X] means not contradiction;
deffunc F(Element of X) = R.(x,$1) "/\" (@("\/"(Q,FuzzyLattice [:X,X:]))).(
$1,z);
deffunc G(Element of X) = R. [x,$1] "/\" "\/"(pi(Q, [$1,z]), RealPoset [. 0,
1 .]);
for y being Element of X holds R. [x,y] "/\" (@("\/"(Q,FuzzyLattice [:X,
X:]))). [y,z] = R. [x,y] "/\" "\/"(pi(Q, [y,z]), RealPoset [. 0,1 .])
proof
let y be Element of X;
(@("\/"(Q,FuzzyLattice [:X,X:]))). [y,z] = (("\/"(Q,FuzzyLattice [:X,X
:]))). [y,z] by LFUZZY_0:def 5
.= "\/"(pi(Q, [y,z]), RealPoset [. 0,1 .]) by Th32;
hence thesis;
end;
then
A1: for y being Element of X holds F(y) = G(y);
thus {F(y) where y is Element of X: P[y]} = {G(y9) where y9 is Element of X:
P[y9]} from FRAENKEL:sch 5(A1);
end;
theorem Th33:
for R being complete Heyting LATTICE, X being Subset of R, y be
Element of R holds y "/\" "\/"(X,R) = "\/"({y "/\" x where x is Element of R: x
in X},R)
proof
let R be complete Heyting LATTICE, X be Subset of R, y be Element of R;
for z being Element of R holds z "/\" is lower_adjoint by WAYBEL_1:def 19;
hence thesis by WAYBEL_1:64;
end;
Lm3: for R being RMembership_Func of X,X, Q being Subset of FuzzyLattice [:X,X
:], x,z being Element of X holds the set of all
R. [x,y] "/\" "\/"(pi(Q, [y,z]), RealPoset [.
0,1 .]) where y is Element of X = the set of all "\/"({R. [x,y9] "/\" b
where b is Element of RealPoset [. 0,1 .]: b in pi(Q,[y9,z])} ,RealPoset [. 0,1
.]) where y9 is Element of X
proof
let R be RMembership_Func of X,X;
let Q be Subset of FuzzyLattice [:X,X:];
let x,z be Element of X;
defpred P[Element of X] means not contradiction;
deffunc F(Element of X) = R. [x,$1] "/\" "\/"(pi(Q, [$1,z]), RealPoset [. 0,
1 .]);
deffunc G(Element of X) = "\/"({R. [x,$1] "/\" b where b is Element of
RealPoset [. 0,1 .]: b in pi(Q,[$1,z])} ,RealPoset [. 0,1 .]);
for y being Element of X holds R. [x,y] "/\" "\/"(pi(Q, [y,z]),
RealPoset [. 0,1 .]) = "\/"({R. [x,y] "/\" b where b is Element of RealPoset [.
0,1 .]: b in pi(Q,[y,z])} ,RealPoset [. 0,1 .])
proof
let y be Element of X;
FuzzyLattice [:X,X:] = (RealPoset [. 0,1 .]) |^ [:X,X:] by LFUZZY_0:def 4
.= product ([:X,X:] --> RealPoset [. 0,1 .]) by YELLOW_1:def 5;
then reconsider Q as Subset of product ([:X,X:] --> RealPoset [. 0,1 .]);
pi(Q, [y,z]) is Subset of RealPoset [. 0,1 .] by FUNCOP_1:7;
hence thesis by Th33;
end;
then
A1: for y being Element of X holds F(y) = G (y);
{F(y) where y is Element of X:P[y]} = {G(y) where y is Element of X:P[y]
} from FRAENKEL:sch 5(A1);
hence thesis;
end;
Lm4: for R being RMembership_Func of X,X, Q being Subset of FuzzyLattice [:X,X
:], x,z being Element of X holds the set of all
"\/"({R. [x,y] "/\" b where b is Element of
RealPoset [. 0,1 .]: b in pi(Q,[y,z])} ,RealPoset [. 0,1 .]) where y is Element
of X = the set of all "\/"({R. [x,y9] "/\" r. [y9,z] where r is Element of
FuzzyLattice [:X,X:]: r in Q} ,RealPoset [. 0,1 .]) where y9 is Element of X
proof
let R be RMembership_Func of X,X;
let Q be Subset of FuzzyLattice [:X,X:];
let x,z be Element of X;
set RP = RealPoset [. 0,1 .], FL = FuzzyLattice [:X,X:];
defpred P[Element of X] means not contradiction;
deffunc F(Element of X) = "\/"({R. [x,$1] "/\" b where b is Element of RP: b
in pi(Q,[$1,z])} ,RP);
deffunc G(Element of X) = "\/"({R. [x,$1] "/\" r. [$1,z] where r is Element
of FL: r in Q} ,RP);
for y being Element of X holds "\/"({R. [x,y] "/\" b where b is Element
of RP: b in pi(Q,[y,z])} ,RP) = "\/"({R. [x,y] "/\" r. [y,z] where r is Element
of FL: r in Q} ,RP)
proof
let y be Element of X;
set A = {R. [x,y] "/\" b where b is Element of RP: b in pi(Q,[y,z])}, B =
{R. [x,y] "/\" r. [y,z] where r is Element of FL: r in Q};
A1: B c= A
proof
let a be object;
assume a in B;
then consider r being Element of FL such that
A2: a = R. [x,y] "/\" r. [y,z] and
A3: r in Q;
r. [y,z] in pi(Q,[y,z]) by A3,CARD_3:def 6;
hence thesis by A2;
end;
A c= B
proof
let a be object;
assume a in A;
then consider b be Element of RP such that
A4: a = R. [x,y] "/\" b and
A5: b in pi(Q,[y,z]);
ex f be Function st f in Q & b = f. [y,z] by A5,CARD_3:def 6;
hence thesis by A4;
end;
hence thesis by A1,XBOOLE_0:def 10;
end;
then
A6: for y being Element of X holds F(y) = G (y);
thus {F(y) where y is Element of X:P[y]} = {G(y) where y is Element of X:P[y
]} from FRAENKEL:sch 5(A6);
end;
Lm5: for X,Y,Z being non empty set for R being RMembership_Func of X,Y for S
being RMembership_Func of Y,Z for x being Element of X, z being Element of Z
holds rng min(R,S,x,z) = the set of all
R. [x,y] "/\" S. [y,z] where y is Element of Y & rng min(R,S,x,z) <> {}
proof
let X,Y,Z being non empty set;
let R being RMembership_Func of X,Y;
let S being RMembership_Func of Y,Z;
let x being Element of X, z being Element of Z;
set L = the set of all R. [x,y] "/\" S. [y,z] where y is Element of Y;
A1: Y = dom min(R,S,x,z) & min(R,S,x,z) is PartFunc of dom min(R,S,x,z), rng
min (R,S,x,z) by FUNCT_2:def 1,RELSET_1:4;
for c be object holds c in L iff c in rng min(R,S,x,z)
proof
let c be object;
hereby
assume c in L;
then consider y being Element of Y such that
A2: c = R. [x,y] "/\" S. [y,z];
c = min(R,S,x,z).y by A2,FUZZY_4:def 2;
hence c in rng min(R,S,x,z) by A1,PARTFUN1:4;
end;
assume c in rng min(R,S,x,z);
then consider y being Element of Y such that
y in dom min(R,S,x,z) and
A3: c = min(R,S,x,z).y by PARTFUN1:3;
c = R. [x,y] "/\" S. [y,z] by A3,FUZZY_4:def 2;
hence thesis;
end;
hence rng min(R,S,x,z) = L by TARSKI:2;
thus rng min(R,S,x,z) <> {};
end;
Lm6: for X,Y,Z being non empty set for R being RMembership_Func of X,Y for S
being RMembership_Func of Y,Z for x being Element of X, z being Element of Z
holds (R (#) S). [x,z] = "\/"((the set of all
R. [x,y] "/\" S. [y,z] where y is Element of Y), RealPoset [. 0,1 .])
proof
let X,Y,Z being non empty set;
let R being RMembership_Func of X,Y;
let S being RMembership_Func of Y,Z;
let x being Element of X, z being Element of Z;
set L = the set of all R. [x,y] "/\" S. [y,z] where y is Element of Y;
[x,z] in [:X,Z:];
then
A1: (R (#) S).(x,z) = upper_bound(rng(min(R,S,x,z))) by FUZZY_4:def 3;
A2: for b being Element of RealPoset [. 0,1 .] st b is_>=_than L holds (R
(#) S). [x,z] <<= b
proof
let b be Element of RealPoset [. 0,1 .];
assume
A3: b is_>=_than the set of all R. [x,y] "/\" S. [y,z] where y is Element of Y;
A4: rng min(R,S,x,z) c= [. 0,1 .] by RELAT_1:def 19;
A5: L = rng min(R,S,x,z) by Lm5;
for r being Real st r in rng min(R,S,x,z) holds r <= b
proof
let r be Real;
assume
A6: r in rng min(R,S,x,z);
then reconsider r as Element of RealPoset [. 0,1 .] by A4,LFUZZY_0:def 3;
r <<= b by A3,A5,A6,LATTICE3:def 9;
hence thesis by LFUZZY_0:3;
end;
then upper_bound rng min(R,S,x,z) <= b by SEQ_4:144;
hence thesis by A1,LFUZZY_0:3;
end;
for b being Element of RealPoset [. 0,1 .] st b in L holds (R (#) S). [x
,z] >>= b
proof
let b be Element of RealPoset [. 0,1 .];
assume b in L;
then consider y being Element of Y such that
A7: b = R. [x,y] "/\" S. [y,z];
dom min(R,S,x,z) = Y & b = min(R,S,x,z).y
by A7,FUNCT_2:def 1,FUZZY_4:def 2;
then b <= upper_bound rng min(R,S,x,z) by FUZZY_4:1;
hence thesis by A1,LFUZZY_0:3;
end;
then (R (#) S). [x,z] is_>=_than L by LATTICE3:def 9;
hence thesis by A2,YELLOW_0:32;
end;
Lm7: for R being RMembership_Func of X,X, Q being Subset of FuzzyLattice [:X,X
:], x,z being Element of X holds {"\/"((the set of all
R. [x,y] "/\" r. [y,z] where y is
Element of X) ,RealPoset [. 0,1 .]) where r is Element of
FuzzyLattice [:X,X:]: r in Q} = {"\/"((the set of all
R. [x,y] "/\" @(r9). [y,z] where y is
Element of X) ,RealPoset [. 0,1 .]) where r9 is Element of
FuzzyLattice [:X,X:]: r9 in Q}
proof
let R be RMembership_Func of X,X;
let Q be Subset of FuzzyLattice [:X,X:];
let x,z be Element of X;
set FL = FuzzyLattice [:X,X:];
defpred P[Element of FL] means $1 in Q;
deffunc F(Element of FL) = "\/"((the set of all
R. [x,y] "/\" $1. [y,z] where y is Element
of X),RealPoset [. 0,1 .]);
deffunc G(Element of FL) = "\/"((the set of all
R. [x,y] "/\" @($1). [y,z] where y is
Element of X) ,RealPoset [. 0,1 .]);
for r being Element of FL st r in Q holds "\/"((the set of all
R. [x,y] "/\" r. [y,z]
where y is Element of X),RealPoset [. 0,1 .]) = "\/"((the set of all R. [x,
y] "/\" @(r). [y,z] where y is Element of X),RealPoset [. 0,
1 .])
proof
let r be Element of FL;
assume r in Q;
the set of all R. [x,y] "/\" r. [y,z] where y is Element of X =the set of
all
R. [x,y] "/\" @r. [y,z] where y is Element of X
proof
deffunc g(Element of X) = R. [x,$1] "/\" @r. [$1,z];
deffunc f(Element of X) = R. [x,$1] "/\" r. [$1,z];
defpred P[Element of X] means not contradiction;
A1: for y being Element of X holds f(y) = g(y) by LFUZZY_0:def 5;
thus {f(y) where y is Element of X:P[y]} ={g(y) where y is Element of X:
P[y]} from FRAENKEL:sch 5(A1);
end;
hence thesis;
end;
then
A2: for r being Element of FL st P[r] holds F(r) = G(r);
thus {F(r) where r is Element of FuzzyLattice [:X,X:]: P[r] } = {G(r) where
r is Element of FuzzyLattice [:X,X:]: P[r]} from FRAENKEL:sch 6(A2);
end;
Lm8: for R being RMembership_Func of X,X, Q being Subset of FuzzyLattice [:X,X
:], x,z being Element of X holds {"\/"((the set of all
R. [x,y] "/\" @(r). [y,z] where y is
Element of X) ,RealPoset [. 0,1 .]) where r is Element of
FuzzyLattice [:X,X:]: r in Q} = {(R(#)@r). [x,z] where r is Element of
FuzzyLattice [:X,X:]: r in Q}
proof
let R be RMembership_Func of X,X;
let Q be Subset of FuzzyLattice [:X,X:];
let x,z be Element of X;
set FL = FuzzyLattice [:X,X:];
defpred P[Element of FL] means $1 in Q;
deffunc F(Element of FL) = "\/"((the set of all
R. [x,y] "/\" @($1). [y,z] where y is
Element of X),RealPoset [. 0,1 .]);
deffunc G(Element of FL) = (R (#) @($1)). [x,z];
A1: for r being Element of FL st P[r] holds F(r) = G(r) by Lm6;
thus {F(r) where r is Element of FuzzyLattice [:X,X:]:P[r]} = {G(r) where r
is Element of FuzzyLattice [:X,X:]: P[r]} from FRAENKEL:sch 6(A1);
end;
Lm9: for R being RMembership_Func of X,X, Q being Subset of FuzzyLattice [:X,X
:], x,z being Element of X holds {(R(#)@r). [x,z] where r is Element of
FuzzyLattice [:X,X:]: r in Q} = pi({(R(#)@r) where r is Element of FuzzyLattice
[:X,X:]: r in Q}, [x,z])
proof
let R be RMembership_Func of X,X;
let Q be Subset of FuzzyLattice [:X,X:];
let x,z be Element of X;
set FL = FuzzyLattice [:X,X:], A= {(R(#)@r). [x,z] where r is Element of
FuzzyLattice [:X,X:]: r in Q}, B= pi({(R(#)@r) where r is Element of FL: r in Q
}, [x,z]);
thus A c= B
proof
let a be object;
assume a in A;
then consider r being Element of FL such that
A1: a = (R(#)@r). [x,z] and
A2: r in Q;
(R(#)@r) in {(R(#)@r9) where r9 is Element of FL: r9 in Q} by A2;
hence thesis by A1,CARD_3:def 6;
end;
thus B c= A
proof
let b be object;
assume b in B;
then consider f be Function such that
A3: f in {(R(#)@r9) where r9 is Element of FL: r9 in Q} and
A4: b = f. [x,z] by CARD_3:def 6;
ex r being Element of FL st f = R (#) @r & r in Q by A3;
hence thesis by A4;
end;
end;
Lm10: for R being RMembership_Func of X,X, Q being Subset of FuzzyLattice [:X,
X:], x,z being Element of X holds "\/"((the set of all
"\/"({R. [x,y] "/\" r. [y,z] where r is
Element of FuzzyLattice [:X,X:]: r in Q} ,RealPoset [. 0,1 .]) where y is
Element of X),RealPoset [. 0,1 .]) = "\/"({"\/"((the set of all R. [x,y]
"/\" r9. [y,z] where y is Element of X),RealPoset [. 0,1 .])
where r9 is Element of FuzzyLattice [:X,X:]: r9 in Q},RealPoset [. 0,1 .])
proof
let R be RMembership_Func of X,X;
let Q be Subset of FuzzyLattice [:X,X:];
let x,z be Element of X;
set FL = FuzzyLattice [:X,X:], RP = RealPoset [. 0,1 .];
defpred P[Element of X] means not contradiction;
defpred Q[Element of FuzzyLattice [:X,X:]] means $1 in Q;
deffunc F(Element of X,Element of FuzzyLattice [:X,X:]) = R. [x,$1] "/\" $2
. [$1,z];
A1: for y being Element of X, r being Element of FL st P[y] & Q[r] holds F(
y,r) = F(y,r);
thus "\/"({ "\/"({F(y,r) where r is Element of FL: Q[r]}, RP) where y is
Element of X: P[y] }, RP) = "\/"({ "\/"({F(y9,r9) where y9 is Element of X: P[
y9]}, RP) where r9 is Element of FL: Q[r9] }, RP) from LFUZZY_0:sch 5(A1);
end;
theorem Th34:
for R being RMembership_Func of X,X, Q being Subset of
FuzzyLattice [:X,X:] holds R (#) @("\/"(Q,FuzzyLattice [:X,X:])) = "\/"({R (#)
@r where r is Element of FuzzyLattice [:X,X:]:r in Q}, FuzzyLattice [:X,X:])
proof
let R be RMembership_Func of X,X;
let Q be Subset of FuzzyLattice [:X,X:];
set FL = FuzzyLattice [:X,X:], RP = RealPoset [. 0,1 .];
("\/"({R (#) @r where r is Element of FL:r in Q},FL)) = @("\/"({R (#) @r
where r is Element of FL:r in Q},FL)) by LFUZZY_0:def 5;
then reconsider F = ("\/"({R (#) @r where r is Element of FL:r in Q},FL)) as
RMembership_Func of X,X;
for x,z being Element of X holds (R (#) @("\/"(Q,FL))).(x,z) = F.(x,z)
proof
let x,z be Element of X;
A1: {(R(#)@r) where r is Element of FL: r in Q} c= the carrier of
FuzzyLattice [:X,X:]
proof
let t be object;
assume t in {(R(#)@r) where r is Element of FL: r in Q};
then consider r being Element of FuzzyLattice [:X,X:] such that
A2: t = (R(#)@r) and
r in Q;
([:X,X:],(R(#)@r))@ = (R(#)@r) by LFUZZY_0:def 6;
hence thesis by A2;
end;
thus (R (#) @("\/"(Q,FL))).(x,z) = "\/"((the set of all
R.(x,y) "/\" (@("\/"(Q,FL))) . (y
,z) where y is Element of X),RP) by LFUZZY_0:22
.= "\/"((the set of all
R. [x,y] "/\" "\/"(pi(Q, [y,z]), RP) where y is Element of X),RP) by Lm2
.= "\/"((the set of all
"\/"({R. [x,y] "/\" b where b is Element of RP:b in pi(Q,[y,
z])} ,RP) where y is Element of X),RP) by Lm3
.= "\/"((the set of all
"\/"({R. [x,y] "/\" r. [y,z] where r is Element of FL: r in
Q} ,RP) where y is Element of X),RP) by Lm4
.= "\/"( {"\/"((the set of all R. [x,y] "/\" r. [y,z]
where y is Element of X)
,RP) where r is Element of FL: r in Q},RP) by Lm10
.= "\/"( {"\/"((the set of all R. [x,y] "/\" @r. [y,z]
where y is Element of X)
,RP) where r is Element of FL: r in Q},RP) by Lm7
.= "\/"({(R(#)@r). [x,z] where r is Element of FL: r in Q},RP) by Lm8
.= "\/"(pi({(R(#)@r) where r is Element of FL: r in Q}, [x,z]),RP) by Lm9
.= F.(x,z) by A1,Th32;
end;
hence thesis by Th2;
end;
theorem Th35:
for R being RMembership_Func of X,X, Q being Subset of
FuzzyLattice [:X,X:] holds @("\/"(Q,FuzzyLattice [:X,X:])) (#) R = "\/"({@r (#)
R where r is Element of FuzzyLattice [:X,X:]:r in Q}, FuzzyLattice [:X,X:])
proof
let R be RMembership_Func of X,X;
let Q be Subset of FuzzyLattice [:X,X:];
set FL = FuzzyLattice [:X,X:], RP = RealPoset [. 0,1 .];
("\/"({@r (#) R where r is Element of FL:r in Q},FL)) = @("\/"({@r (#) R
where r is Element of FL:r in Q},FL)) by LFUZZY_0:def 5;
then reconsider F = ("\/"({@r (#) R where r is Element of FL:r in Q},FL)) as
RMembership_Func of X,X;
for x,z being Element of X holds (@("\/"(Q,FL)) (#) R).(x,z) = F.(x,z)
proof
let x,z be Element of X;
A1: {(@r(#)R) where r is Element of FL: r in Q} c= the carrier of
FuzzyLattice [:X,X:]
proof
let t be object;
assume t in {(@r(#)R) where r is Element of FL: r in Q};
then consider r being Element of FuzzyLattice [:X,X:] such that
A2: t = (@r(#)R) and
r in Q;
([:X,X:],(@r(#)R))@ = (@r(#)R) by LFUZZY_0:def 6;
hence thesis by A2;
end;
A3: the set of all "\/"(pi(Q, [x,y]), RP) "/\" R. [y,z] where y is Element of X
= the set of all "\/"({b "/\" R. [y9,z] where b is Element of RP:b in pi(Q,[x,
y9])} ,RP) where y9 is Element of X
proof
deffunc G(Element of X) = "\/"({b "/\" R. [$1,z] where b is Element of
RP: b in pi(Q,[x,$1])} ,RP);
deffunc F(Element of X) = "\/"(pi(Q, [x,$1]),RP) "/\" R. [$1,z];
defpred P[Element of X] means not contradiction;
for y being Element of X holds "\/"(pi(Q, [x,y]), RealPoset [. 0,1
.]) "/\" R. [y,z] = "\/"({b "/\" R. [y,z] where b is Element of RP:b in pi(Q,[x
,y])} ,RP)
proof
FuzzyLattice [:X,X:] = (RealPoset [. 0,1 .]) |^ [:X,X:] by
LFUZZY_0:def 4
.= product ([:X,X:] --> RealPoset [. 0,1 .]) by YELLOW_1:def 5;
then reconsider
Q as Subset of product ([:X,X:] --> RealPoset [. 0,1 .]);
let y be Element of X;
pi(Q, [x,y]) is Subset of RealPoset [. 0,1 .] by FUNCOP_1:7;
hence thesis by LFUZZY_0:15;
end;
then
A4: for y being Element of X holds F(y) = G (y);
{F(y) where y is Element of X:P[y]} = {G(y9) where y9 is Element of
X: P[y9]} from FRAENKEL:sch 5(A4);
hence thesis;
end;
A5: the set of all
"\/"({b "/\" R. [y,z] where b is Element of RP:b in pi(Q,[x,y])} ,RP
) where y is Element of X = the set of all "\/"({r. [x,y9] "/\" R. [y9,z]
where r is Element of FL: r in Q} ,RP) where y9 is Element of X
proof
deffunc G(Element of X) = "\/"({r. [x,$1] "/\" R. [$1,z] where r is
Element of FL: r in Q} ,RP);
deffunc F(Element of X) = "\/"({b "/\" R. [$1,z] where b is Element of
RP: b in pi(Q,[x,$1])} ,RP);
defpred P[Element of X] means not contradiction;
for y being Element of X holds "\/"({b "/\" R. [y,z] where b is
Element of RP: b in pi(Q,[x,y])} ,RP) = "\/"({r. [x,y] "/\" R. [y,z] where r is
Element of FL: r in Q} ,RP)
proof
let y be Element of X;
set A = {b "/\" R. [y,z] where b is Element of RP: b in pi(Q,[x,y])},
B = {r. [x,y] "/\" R. [y,z] where r is Element of FL: r in Q};
A6: B c= A
proof
let a be object;
assume a in B;
then consider r being Element of FL such that
A7: a = r. [x,y] "/\" R. [y,z] and
A8: r in Q;
r. [x,y] in pi(Q,[x,y]) by A8,CARD_3:def 6;
hence thesis by A7;
end;
A c= B
proof
let a be object;
assume a in A;
then consider b be Element of RP such that
A9: a = b "/\" R. [y,z] and
A10: b in pi(Q,[x,y]);
ex f be Function st f in Q & b = f. [x,y] by A10,CARD_3:def 6;
hence thesis by A9;
end;
hence thesis by A6,XBOOLE_0:def 10;
end;
then
A11: for y being Element of X holds F(y) = G (y);
thus {F(y) where y is Element of X:P[y]} = {G(y) where y is Element of X
:P[y]} from FRAENKEL:sch 5(A11);
end;
A12: "\/"((the set of all "\/"({r. [x,y] "/\" R. [y,z]
where r is Element of FL: r in Q}
,RP) where y is Element of X),RP) = "\/"({"\/"((the set of all r9. [x,y]
"/\" R. [y,z] where y is Element of X),RP) where r9 is
Element of FL: r9 in Q},RP)
proof
deffunc F(Element of X,Element of FuzzyLattice [:X,X:]) = $2. [x,$1]
"/\" R. [$1,z];
defpred Q[Element of FuzzyLattice [:X,X:]] means $1 in Q;
defpred P[Element of X] means not contradiction;
A13: for y being Element of X, r being Element of FL st P[y] & Q[r]
holds F(y,r) = F(y,r);
thus "\/"({ "\/"({F(y,r) where r is Element of FL: Q[r]}, RP) where y
is Element of X: P[y] }, RP) = "\/"({ "\/"({F(y9,r9) where y9 is Element of X:
P[y9]}, RP) where r9 is Element of FL: Q[r9] }, RP) from LFUZZY_0:sch 5(A13);
end;
A14: {"\/"((the set of all r. [x,y] "/\" R. [y,z] where y is Element of X),RP)
where r is Element of FL: r in Q} = {"\/"((the set of all @r9. [x,y] "/\"
R. [y,z] where y is Element of X) ,RP) where r9 is Element of
FL: r9 in Q}
proof
deffunc G(Element of FL) = "\/"((the set of all
@($1). [x,y] "/\" R. [y,z] where y is
Element of X),RealPoset [. 0,1 .]);
deffunc F(Element of FL) = "\/"((the set of all
$1. [x,y] "/\" R. [y,z] where y is
Element of X),RealPoset [. 0,1 .]);
defpred P[Element of FL] means $1 in Q;
for r being Element of FL st r in Q holds "\/"((the set of all
r. [x,y] "/\" R. [y
,z] where y is Element of X) ,RealPoset [. 0,1 .]) = "\/"((the set of all @r
. [x,y] "/\" R. [y,z] where y is Element of X) ,RealPoset [.
0,1 .])
proof
let r be Element of FL;
assume r in Q;
the set of all r. [x,y] "/\" R. [y,z] where y is Element of X =the set
of all @r. [x,y] "/\" R. [y,z] where y is Element of X
proof
deffunc g(Element of X) = @r. [x,$1] "/\" R. [$1,z];
deffunc f(Element of X) = r. [x,$1] "/\" R. [$1,z];
defpred P[Element of X] means not contradiction;
A15: for y being Element of X holds f(y) = g(y) by LFUZZY_0:def 5;
thus {f(y) where y is Element of X:P[y]} ={g(y) where y is Element
of X:P[y]} from FRAENKEL:sch 5(A15);
end;
hence thesis;
end;
then
A16: for r being Element of FL st P[r] holds F(r) = G(r);
thus {F(r) where r is Element of FuzzyLattice [:X,X:]: P[r] } = {G(r)
where r is Element of FuzzyLattice [:X,X:]: P[r]} from FRAENKEL:sch 6(A16);
end;
A17: {(@r(#)R). [x,z] where r is Element of FL: r in Q} = pi({(@r(#)R)
where r is Element of FL: r in Q}, [x,z])
proof
set A= {(@r(#)R). [x,z] where r is Element of FL: r in Q}, B= pi({(@r(#)
R) where r is Element of FL: r in Q}, [x,z]);
thus A c= B
proof
let a be object;
assume a in A;
then consider r being Element of FL such that
A18: a = (@r(#)R). [x,z] and
A19: r in Q;
(@r(#)R) in {(@r9(#)R) where r9 is Element of FL: r9 in Q} by A19;
hence thesis by A18,CARD_3:def 6;
end;
thus B c= A
proof
let b be object;
assume b in B;
then consider f be Function such that
A20: f in {(@r9(#)R) where r9 is Element of FL: r9 in Q} and
A21: b = f. [x,z] by CARD_3:def 6;
ex r being Element of FL st f = (@r(#)R) & r in Q by A20;
hence thesis by A21;
end;
end;
A22: the set of all
(@("\/"(Q,FL))). [x,y] "/\" R. [y,z] where y is Element of X = the set of all
"\/"(pi(Q, [x,y]), RP) "/\" R. [y,z] where y is Element of X
proof
deffunc G(Element of X) = "\/"(pi(Q, [x,$1]), RP) "/\" R. [$1,z];
deffunc F(Element of X) = (@("\/"(Q,FL))). [x,$1] "/\" R. [$1,z];
defpred P[Element of X] means not contradiction;
for y being Element of X holds (@("\/"(Q,FuzzyLattice [:X,X:]))). [x
,y] "/\" R. [y,z] = "\/"(pi(Q, [x,y]), RealPoset [. 0,1 .]) "/\" R. [y,z]
proof
let y be Element of X;
(@("\/"(Q,FuzzyLattice [:X,X:]))). [x,y] = (("\/"(Q,FuzzyLattice
[:X,X:]))). [x,y] by LFUZZY_0:def 5
.= "\/"(pi(Q, [x,y]), RealPoset [. 0,1 .]) by Th32;
hence thesis;
end;
then
A23: for y being Element of X holds F(y) = G(y);
thus {F(y) where y is Element of X: P[y]} = {G(y9) where y9 is Element
of X: P[y9]} from FRAENKEL:sch 5 (A23);
end;
A24: {"\/"((the set of all @r. [x,y] "/\" R. [y,z] where y is Element of X),RP)
where r is Element of FL: r in Q} = {(@r9(#)R). [x,z] where
r9 is Element of FL: r9 in Q}
proof
deffunc G(Element of FL) = (@($1)(#)R). [x,z];
deffunc F(Element of FL) = "\/"((the set of all @($1). [x,y] "/\"
R. [y,z] where y is Element of X),RealPoset [. 0,1 .]);
defpred P[Element of FL] means $1 in Q;
A25: for r being Element of FL st P[r] holds F(r) = G(r) by Lm6;
thus {F(r) where r is Element of FuzzyLattice [:X,X:]:P[r]} = {G(r)
where r is Element of FuzzyLattice [:X,X:]: P[r]} from FRAENKEL:sch 6(A25);
end;
thus (@("\/"(Q,FL)) (#) R).(x,z) = "\/"((the set of all
(@("\/"(Q,FL))). [x,y] "/\" R. [y
,z] where y is Element of X),RP) by Lm6
.= F.(x,z) by A1,A22,A3,A5,A12,A14,A24,A17,Th32;
end;
hence thesis by Th2;
end;
theorem Th36:
for R being RMembership_Func of X,X holds (TrCl R)(#)(TrCl R) =
"\/"({(i iter R) (#) (j iter R) where i is Element of NAT, j is Element of NAT:
i > 0 & j > 0},FuzzyLattice [:X,X:])
proof
let R be RMembership_Func of X,X;
set Q = {n iter R where n is Element of NAT : n > 0}, FL = FuzzyLattice [:X,
X:];
A1: Q c= the carrier of FL
proof
let q be object;
assume q in Q;
then consider i being Element of NAT such that
A2: q = (i iter R) and
i > 0;
([:X,X:],(i iter R) )@ = i iter R by LFUZZY_0:def 6;
hence thesis by A2;
end;
A3: {"\/"({@r (#) @s where s is Element of FL : s in Q},FL) where r is
Element of FL : r in Q} = {"\/"({([:X,X:],@r9 (#) @s9)@ where s9 is Element of
FL: s9 in Q},FL) where r9 is Element of FL : r9 in Q}
proof
deffunc G(Element of FL) = "\/"({([:X,X:],@$1 (#) @s)@ where s is Element
of FL : s in Q},FL);
deffunc F(Element of FL) = "\/"({@$1 (#) @s where s is Element of FL : s
in Q},FL);
defpred P[Element of FL] means $1 in Q;
for r being Element of FL holds "\/"({@r (#) @s where s is Element of
FL: s in Q},FL) = "\/"({([:X,X:],@r (#) @s)@ where s is Element of FL : s in Q
},FL)
proof
let r be Element of FL;
{@r (#) @s where s is Element of FL : s in Q} = {([:X,X:],@r (#) @s
)@ where s is Element of FL : s in Q}
proof
deffunc g(Element of FL) = ([:X,X:],@r (#) @$1)@;
deffunc f(Element of FL) = @r (#) @$1;
defpred P[Element of FL] means $1 in Q;
A4: for s being Element of FL holds f(s) = g(s) by LFUZZY_0:def 6;
{f(s) where s is Element of FL : P[s]} = {g(s) where s is Element
of FL : P[s]} from FRAENKEL:sch 5 (A4);
hence thesis;
end;
hence thesis;
end;
then
A5: for r being Element of FL holds F(r) = G(r);
{F(r) where r is Element of FL : P[r]} = {G(r) where r is Element of
FL: P[r]} from FRAENKEL:sch 5 (A5);
hence thesis;
end;
defpred R[Element of FL] means $1 in Q;
defpred P[Element of FL] means $1 in Q;
deffunc f(Element of FL,Element of FL) = ([:X,X:],@$1 (#) @$2)@;
A6: {@r (#) @s where r is Element of FL,s is Element of FL:r in Q & s in Q}
= {(i iter R) (#) (j iter R) where i is Element of NAT, j is Element of NAT:i >
0 & j > 0}
proof
set A = {@r (#) @s where r is Element of FL,s is Element of FL:r in Q & s
in Q}, B = {(i iter R) (#) (j iter R) where i is Element of NAT, j is Element
of NAT:i > 0 & j > 0};
thus A c= B
proof
let a be object;
assume a in A;
then consider r,s being Element of FL such that
A7: a = @r (#) @s and
A8: r in Q & s in Q;
A9: r = @r & s = @s by LFUZZY_0:def 5;
(ex i being Element of NAT st r = i iter R & i > 0 )& ex j being
Element of NAT st s = j iter R & j > 0 by A8;
hence thesis by A7,A9;
end;
thus B c= A
proof
let b be object;
assume b in B;
then consider i,j being Element of NAT such that
A10: b = (i iter R) (#) (j iter R) and
A11: i > 0 & j > 0;
(j iter R) = ([:X,X:],(j iter R))@ by LFUZZY_0:def 6;
then reconsider s = j iter R as Element of FL;
(i iter R) = ([:X,X:],(i iter R))@ by LFUZZY_0:def 6;
then reconsider r = i iter R as Element of FL;
A12: @r = r & @s = s by LFUZZY_0:def 5;
(i iter R) in Q & (j iter R) in Q by A11;
hence thesis by A10,A12;
end;
end;
A13: {([:X,X:],@r (#) @s)@ where r is Element of FL, s is Element of FL:r in
Q & s in Q} = {@r (#) @s where r is Element of FL, s is Element of FL:r in Q &
s in Q}
proof
deffunc G(Element of FL,Element of FL) = @$1 (#) @$2;
deffunc F(Element of FL,Element of FL) = ([:X,X:],@$1 (#) @$2)@;
defpred P[Element of FL,Element of FL] means $1 in Q & $2 in Q;
A14: for r being Element of FL, s being Element of FL holds F(r,s) = G(r,s
) by LFUZZY_0:def 6;
{F(r,s) where r is Element of FL,s is Element of FL:P[r,s]} ={G(r,s)
where r is Element of FL,s is Element of FL:P[r,s]} from FRAENKEL:sch 7(A14);
hence thesis;
end;
A15: "\/"(Q,FL) = @"\/"(Q,FL) by LFUZZY_0:def 5;
{@r (#) (TrCl R) where r is Element of FL:r in Q} = {"\/"({@r9 (#) @s
where s is Element of FL:s in Q},FL) where r9 is Element of FL : r9 in Q}
proof
set A = {@r (#) (TrCl R) where r is Element of FL:r in Q}, B = {"\/"({@r9
(#) @s where s is Element of FL:s in Q},FL) where r9 is Element of FL : r9 in Q
};
thus A c= B
proof
let a be object;
assume a in A;
then consider r being Element of FL such that
A16: a = @r (#) (TrCl R) and
A17: r in Q;
a = "\/"({@r (#) @s where s is Element of FL:s in Q},FL) by A15,A1,A16
,Th34;
hence thesis by A17;
end;
thus B c= A
proof
let a be object;
assume a in B;
then consider r being Element of FL such that
A18: a = "\/"({@r (#) @s where s is Element of FL:s in Q},FL) and
A19: r in Q;
a = @r (#) (TrCl R) by A15,A1,A18,Th34;
hence thesis by A19;
end;
end;
hence
(TrCl R)(#)(TrCl R) = "\/"({"\/"({f(r,s) where s is Element of FL:R[s]}
,FL) where r is Element of FL :P[r]},FL) by A15,A1,A3,Th35
.= "\/"({f(r,s) where r is Element of FL, s is Element of FL: P[r] & R[s
]},FL) from LFUZZY_0:sch 1
.= "\/"({(i iter R) (#) (j iter R) where i is Element of NAT, j is
Element of NAT: i > 0 & j > 0},FL) by A6,A13;
end;
registration
let X be non empty set;
let R be RMembership_Func of X,X;
cluster TrCl R -> transitive;
coherence
proof
set FL = FuzzyLattice [:X,X:], RP = RealPoset [. 0,1 .], A = {(i iter R)
(#) (j iter R) where i is Element of NAT, j is Element of NAT: i > 0 & j > 0};
for c being Element of [:X,X:] holds ((TrCl R)(#)(TrCl R)).c <= (TrCl R).c
proof
let c be Element of [:X,X:];
A1: A c= the carrier of FuzzyLattice [:X,X:]
proof
let t be object;
assume t in A;
then consider i,j being Element of NAT such that
A2: t = (i iter R) (#) (j iter R) and
i > 0 and
j >0;
([:X,X:],((i iter R) (#) (j iter R)))@ = (i iter R) (#) (j iter R)
by LFUZZY_0:def 6;
hence thesis by A2;
end;
for b being Element of RP st b in pi(A,c) holds b <<= (TrCl R) . c
proof
let b be Element of RP;
assume b in pi(A,c);
then consider f be Function such that
A3: f in A and
A4: b = f.c by CARD_3:def 6;
consider i,j being Element of NAT such that
A5: f = (i iter R) (#) (j iter R) and
A6: i > 0 and
j > 0 by A3;
A7: f = (i+j) iter R by A5,Th27;
reconsider f as RMembership_Func of X,X by A5;
f c= TrCl R by A6,A7,Th31;
then f.c <= (TrCl R).c;
hence thesis by A4,LFUZZY_0:3;
end;
then (TrCl R).c is_>=_than pi(A,c) by LATTICE3:def 9;
then
A8: "\/"(pi(A,c),RP) <<= (TrCl R).c by YELLOW_0:32;
((TrCl R)(#)(TrCl R)).c = "\/"(A,FL).c by Th36
.= "\/"(pi(A,c),RP) by A1,Th32;
hence thesis by A8,LFUZZY_0:3;
end;
then (TrCl R)(#)(TrCl R) c= (TrCl R);
hence thesis;
end;
end;
theorem Th37:
for R being RMembership_Func of X,X, n being Nat st R
is transitive & n > 0 holds n iter R c= R
proof
let R be RMembership_Func of X,X;
let n be Nat;
assume that
A1: R is transitive and
A2: n > 0;
reconsider n as non zero Element of NAT by A2,ORDINAL1:def 12;
defpred P[Nat] means $1 iter R c= R;
A3: R (#) R c= R by A1;
A4: for k being non zero Nat st P[k] holds P[k+1]
proof
let k be non zero Nat;
assume P[k];
then k iter R (#) R c= R(#)R by Th6;
then (k+1) iter R c= R(#)R by Th26;
hence thesis by A3,Th5;
end;
A5: P[1] by Th25;
for k being non zero Nat holds P[k] from NAT_1:sch 10(A5,A4);
then P[n];
hence thesis;
end;
theorem Th38:
for R being RMembership_Func of X,X st R is transitive holds R = TrCl R
proof
let R be RMembership_Func of X,X;
assume
A1: R is transitive;
for c being Element of [:X,X:] holds (TrCl R).c <= R.c
proof
set Q = {n iter R where n is Element of NAT : n > 0}, RP = RealPoset [. 0,
1 .];
let c be Element of [:X,X:];
for b being Element of RP st b in pi(Q,c) holds b <<= R.c
proof
let b be Element of RP;
assume b in pi(Q,c);
then consider f being Function such that
A2: f in Q and
A3: b = f.c by CARD_3:def 6;
consider n be Element of NAT such that
A4: f = n iter R and
A5: n>0 by A2;
n iter R c= R by A1,A5,Th37;
then (n iter R).c <= R.c;
hence thesis by A3,A4,LFUZZY_0:3;
end;
then
A6: R.c is_>=_than pi(Q,c) by LATTICE3:def 9;
Q c= the carrier of FuzzyLattice [:X,X:]
proof
let t be object;
assume t in Q;
then consider i being Element of NAT such that
A7: t = (i iter R) and
i > 0;
([:X,X:],(i iter R))@ = (i iter R) by LFUZZY_0:def 6;
hence thesis by A7;
end;
then (TrCl R).c = "\/"(pi(Q,c),RP) by Th32;
then (TrCl R).c <<= R.c by A6,YELLOW_0:32;
hence thesis by LFUZZY_0:3;
end;
then
A8: TrCl R c= R;
R c= TrCl R by Th30;
hence thesis by A8,Th3;
end;
theorem Th39:
for R,S being RMembership_Func of X,X, n being Nat st
R c= S holds n iter R c= n iter S
proof
let R,S be RMembership_Func of X,X;
let n be Nat;
defpred P[Nat] means $1 iter R c= $1 iter S;
assume
A1: R c= S;
A2: for k being Nat st P[k] holds P[k+1]
proof
let k be Nat;
assume
A3: P[k];
(k iter R) (#) R = (k+1) iter R & (k iter S) (#) S = (k+1) iter S by Th26;
hence thesis by A1,A3,Th6;
end;
0 iter R = Imf(X,X) by Th24
.= 0 iter S by Th24;
then
A4: P[0];
for k being Nat holds P[k] from NAT_1:sch 2(A4,A2);
hence thesis;
end;
theorem
for R,S being RMembership_Func of X,X st S is transitive & R c= S
holds TrCl R c= S
proof
let R,S be RMembership_Func of X,X;
assume that
A1: S is transitive and
A2: R c= S;
for c being Element of [:X,X:] holds (TrCl R).c <= (TrCl S).c
proof
set Q = {n iter R where n is Element of NAT : n > 0}, RP = RealPoset [. 0,
1 .];
let c be Element of [:X,X:];
for b being Element of RP st b in pi(Q,c) holds b <<= (TrCl S).c
proof
let b be Element of RP;
assume b in pi(Q,c);
then consider f being Function such that
A3: f in Q and
A4: b = f.c by CARD_3:def 6;
consider n be Element of NAT such that
A5: f = n iter R and
A6: n>0 by A3;
A7: n iter S c= TrCl S by A6,Th31;
n iter R c= n iter S by A2,Th39;
then n iter R c= TrCl S by A7,Th5;
then (n iter R).c <= (TrCl S).c;
hence thesis by A4,A5,LFUZZY_0:3;
end;
then (TrCl S).c is_>=_than pi(Q,c) by LATTICE3:def 9;
then
A8: "\/"(pi(Q,c),RP) <<= (TrCl S).c by YELLOW_0:32;
Q c= the carrier of FuzzyLattice [:X,X:]
proof
let t be object;
assume t in Q;
then consider i being Element of NAT such that
A9: t = (i iter R) and
i > 0;
([:X,X:],(i iter R))@ = (i iter R) by LFUZZY_0:def 6;
hence thesis by A9;
end;
then (TrCl R).c = "\/"(pi(Q,c),RP) by Th32;
hence thesis by A8,LFUZZY_0:3;
end;
then TrCl R c= TrCl S;
hence thesis by A1,Th38;
end;