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:: Ternary Fields | |
:: by Micha{\l} Muzalewski and Wojciech Skaba | |
environ | |
vocabularies STRUCT_0, SUBSET_1, MULTOP_1, XBOOLE_0, VECTSP_1, FUNCT_1, | |
NUMBERS, REAL_1, RELAT_1, ARYTM_3, CARD_1, ARYTM_1, MESFUNC1, SUPINF_2, | |
ALGSTR_3, FUNCT_7; | |
notations XBOOLE_0, SUBSET_1, FUNCT_7, ORDINAL1, NUMBERS, XCMPLX_0, XREAL_0, | |
STRUCT_0, REAL_1, MULTOP_1; | |
constructors REAL_1, MEMBERED, MULTOP_1, RLVECT_1, FUNCT_7; | |
registrations NUMBERS, MEMBERED, STRUCT_0, XREAL_0, RELSET_1; | |
requirements NUMERALS, SUBSET, ARITHM; | |
definitions STRUCT_0; | |
equalities STRUCT_0; | |
theorems MULTOP_1, XCMPLX_1, XREAL_0; | |
schemes MULTOP_1; | |
begin | |
:: TERNARY FIELDS | |
:: This few lines define the basic algebraic structure (F, 0, 1, T) | |
:: used in the whole article. | |
definition | |
struct(ZeroOneStr) TernaryFieldStr (# carrier -> set, ZeroF, OneF -> Element | |
of the carrier, TernOp -> TriOp of the carrier #); | |
end; | |
registration | |
cluster non empty for TernaryFieldStr; | |
existence | |
proof | |
set A = the non empty set,Z = the Element of A,t = the TriOp of A; | |
take TernaryFieldStr(#A,Z,Z,t#); | |
thus the carrier of TernaryFieldStr(#A,Z,Z,t#) is non empty; | |
end; | |
end; | |
reserve F for non empty TernaryFieldStr; | |
:: The following definitions let us simplify the notation | |
definition | |
let F; | |
mode Scalar of F is Element of F; | |
end; | |
reserve a,b,c for Scalar of F; | |
definition | |
let F,a,b,c; | |
func Tern(a,b,c) -> Scalar of F equals | |
(the TernOp of F).(a,b,c); | |
correctness; | |
end; | |
:: The following definition specifies a ternary operation that | |
:: will be used in the forthcoming example: TernaryFieldEx | |
:: as its TriOp function. | |
definition | |
func ternaryreal -> TriOp of REAL means | |
:Def2: | |
for a,b,c being Real holds it.(a,b,c) = a*b + c; | |
existence | |
proof | |
deffunc F(Real,Real,Real) = In($1*$2 + $3,REAL); | |
consider X being TriOp of REAL such that | |
A1: for a,b,c being Element of REAL holds X.(a,b,c) = F(a,b,c) | |
from MULTOP_1:sch 4; | |
take X; | |
let a,b,c be Real; | |
reconsider a,b,c as Element of REAL by XREAL_0:def 1; | |
X.(a,b,c) = F(a,b,c) by A1; | |
hence thesis; | |
end; | |
uniqueness | |
proof | |
let o1,o2 be TriOp of REAL; | |
assume that | |
A2: for a,b,c being Real holds o1.(a,b,c) = a*b + c and | |
A3: for a,b,c being Real holds o2.(a,b,c) = a*b + c; | |
for a,b,c being Element of REAL holds o1.(a,b,c) = o2.(a,b,c) | |
proof | |
let a,b,c be Element of REAL; | |
thus o1.(a,b,c) = a*b + c by A2 | |
.= o2.(a,b,c) by A3; | |
end; | |
hence thesis by MULTOP_1:3; | |
end; | |
end; | |
:: Now comes the definition of example structure called: TernaryFieldEx. | |
:: This example will be used to prove the existence of the Ternary-Field mode. | |
definition | |
func TernaryFieldEx -> strict TernaryFieldStr equals | |
TernaryFieldStr (# REAL,In(0,REAL),In(1,REAL), ternaryreal #); | |
correctness; | |
end; | |
registration | |
cluster TernaryFieldEx -> non empty; | |
coherence; | |
end; | |
:: On the contrary to the Tern() (starting with uppercase), this definition | |
:: allows for the use of the currently specified example ternary field. | |
definition | |
let a,b,c be Scalar of TernaryFieldEx; | |
func tern(a,b,c) -> Scalar of TernaryFieldEx equals | |
(the TernOp of | |
TernaryFieldEx).(a,b,c); | |
correctness; | |
end; | |
theorem Th1: | |
for u,u9,v,v9 being Real holds u <> u9 implies ex x being Real st | |
u*x+v = u9*x+v9 | |
proof | |
let u,u9,v,v9 be Real; | |
set x = (v9 - v)/(u - u9); | |
assume u <> u9; | |
then u - u9 <> 0; | |
then | |
A1: (u - u9)*x = v9 - v by XCMPLX_1:87; | |
reconsider x as Real; | |
take x; | |
thus thesis by A1; | |
end; | |
theorem | |
for u,a,v being Scalar of TernaryFieldEx for z,x,y being Real holds u= | |
z & a=x & v=y implies Tern(u,a,v) = z*x + y by Def2; | |
:: The 1 defined in TeranaryFieldEx structure is equal to | |
:: the ordinary 1 of real numbers. | |
reconsider jj=1, zz=0 as Real; | |
theorem | |
1 = 1.TernaryFieldEx; | |
Lm1: for a being Scalar of TernaryFieldEx holds Tern(a, 1.TernaryFieldEx, 0. | |
TernaryFieldEx) = a | |
proof | |
let a be Scalar of TernaryFieldEx; | |
reconsider x=a as Real; | |
thus Tern(a, 1.TernaryFieldEx, 0.TernaryFieldEx) | |
= x*jj + zz by Def2 | |
.= a; | |
end; | |
Lm2: for a being Scalar of TernaryFieldEx holds Tern(1.TernaryFieldEx, a, 0. | |
TernaryFieldEx) = a | |
proof | |
let a be Scalar of TernaryFieldEx; | |
reconsider x=a as Real; | |
thus Tern(1.TernaryFieldEx, a, 0.TernaryFieldEx) | |
= ternaryreal.(jj, x, zz) | |
.= x*1 + 0 by Def2 | |
.= a; | |
end; | |
Lm3: for a,b being Scalar of TernaryFieldEx holds Tern(a, 0.TernaryFieldEx, b) | |
= b | |
proof | |
let a,b be Scalar of TernaryFieldEx; | |
reconsider x=a, y=b as Real; | |
thus Tern(a, 0.TernaryFieldEx, b) = x*0 + y by Def2 | |
.= b; | |
end; | |
Lm4: for a,b being Scalar of TernaryFieldEx holds Tern(0.TernaryFieldEx, a, b) | |
= b | |
proof | |
let a,b be Scalar of TernaryFieldEx; | |
reconsider x=a, y=b as Real; | |
thus Tern(0.TernaryFieldEx, a, b) = 0*x + y by Def2 | |
.= b; | |
end; | |
Lm5: for u,a,b being Scalar of TernaryFieldEx ex v being Scalar of | |
TernaryFieldEx st Tern(u,a,v) = b | |
proof | |
let u,a,b be Scalar of TernaryFieldEx; | |
reconsider z=u, x=a, y=b as Real; | |
reconsider t = y - z*x as Element of REAL by XREAL_0:def 1; | |
reconsider v=t as Scalar of TernaryFieldEx; | |
take v; | |
y = z*x + t; | |
hence thesis by Def2; | |
end; | |
Lm6: for u,a,v,v9 being Scalar of TernaryFieldEx holds Tern(u,a,v) = Tern(u,a, | |
v9) implies v = v9 | |
proof | |
let u,a,v,v9 be Scalar of TernaryFieldEx; | |
reconsider z=u, x=a, y=v, y9=v9 as Real; | |
Tern(u, a, v) = z*x + y & Tern(u, a, v9) = z*x + y9 by Def2; | |
hence thesis; | |
end; | |
Lm7: for a,a9 being Scalar of TernaryFieldEx holds a <> a9 implies for b,b9 | |
being Scalar of TernaryFieldEx ex u,v being Scalar of TernaryFieldEx st Tern(u, | |
a,v) = b & Tern(u,a9,v) = b9 | |
proof | |
let a, a9 be Scalar of TernaryFieldEx; | |
assume | |
A1: a<>a9; | |
let b, b9 be Scalar of TernaryFieldEx; | |
reconsider x=a, x9=a9, y=b, y9=b9 as Real; | |
A2: x9-x <> 0 by A1; | |
set s = (y9-y)/(x9-x); | |
set t = y - x*s; | |
reconsider u=s, v=t as Scalar of TernaryFieldEx by XREAL_0:def 1; | |
take u,v; | |
thus Tern(u,a,v) = s*x + ((-s*x) + y) by Def2 | |
.= b; | |
thus Tern(u,a9,v) = ((y9-y)/(x9-x))*x9 + ((- x*((y9-y)/(x9-x))) + y) by Def2 | |
.= (((y9-y)/(x9-x))*(x9-x)) + y | |
.= y9-y + y by A2,XCMPLX_1:87 | |
.= b9; | |
end; | |
Lm8: for u,u9 being Scalar of TernaryFieldEx holds u <> u9 implies for v,v9 | |
being Scalar of TernaryFieldEx ex a being Scalar of TernaryFieldEx st Tern(u,a, | |
v) = Tern(u9,a,v9) | |
proof | |
let u,u9 be Scalar of TernaryFieldEx; | |
assume | |
A1: u <> u9; | |
let v,v9 be Scalar of TernaryFieldEx; | |
reconsider uu = u, uu9 = u9, vv = v, vv9 = v9 as Real; | |
consider aa being Real such that | |
A2: uu*aa+vv = uu9*aa+vv9 by A1,Th1; | |
reconsider a = aa as Scalar of TernaryFieldEx by XREAL_0:def 1; | |
Tern(u,a,v) = uu*aa+vv & Tern(u9,a,v9) = uu9*aa+vv9 by Def2; | |
hence thesis by A2; | |
end; | |
Lm9: for a,a9,u,u9,v,v9 being Scalar of TernaryFieldEx holds Tern(u,a, v) = | |
Tern(u9,a, v9) & Tern(u,a9,v) = Tern(u9,a9,v9) implies a = a9 or u = u9 | |
proof | |
let a,a9,u,u9,v,v9 be Scalar of TernaryFieldEx; | |
assume | |
A1: Tern(u,a, v) = Tern(u9,a, v9) & Tern(u,a9,v) = Tern(u9,a9,v9); | |
reconsider aa=a,aa9=a9,uu=u,uu9=u9,vv=v,vv9=v9 as Real; | |
A2: Tern(u,a9,v) = uu*aa9 + vv & Tern(u9,a9,v9) = uu9*aa9 + vv9 by Def2; | |
Tern(u,a, v) = uu*aa + vv & Tern(u9,a, v9) = uu9*aa + vv9 by Def2; | |
then uu*(aa - aa9) = uu9*(aa - aa9) by A1,A2; | |
then uu = uu9 or aa - aa9 = 0 by XCMPLX_1:5; | |
hence thesis; | |
end; | |
definition | |
let IT be non empty TernaryFieldStr; | |
attr IT is Ternary-Field-like means | |
:Def5: | |
0.IT <> 1.IT & (for a being | |
Scalar of IT holds Tern(a, 1.IT, 0.IT) = a) & (for a being Scalar of IT holds | |
Tern(1.IT, a, 0.IT) = a) & (for a,b being Scalar of IT holds Tern(a, 0.IT, b ) | |
= b) & (for a,b being Scalar of IT holds Tern(0.IT, a, b ) = b) & (for u,a,b | |
being Scalar of IT ex v being Scalar of IT st Tern(u,a,v) = b) & (for u,a,v,v9 | |
being Scalar of IT holds Tern(u,a,v) = Tern(u,a,v9) implies v = v9) & (for a,a9 | |
being Scalar of IT holds a <> a9 implies for b,b9 being Scalar of IT ex u,v | |
being Scalar of IT st Tern(u,a,v) = b & Tern(u,a9,v) = b9) & (for u,u9 being | |
Scalar of IT holds u <> u9 implies for v,v9 being Scalar of IT ex a being | |
Scalar of IT st Tern(u,a,v) = Tern(u9,a,v9)) & for a,a9,u,u9,v,v9 being Scalar | |
of IT holds Tern(u,a,v) = Tern(u9,a,v9) & Tern(u,a9,v) = Tern(u9,a9,v9) implies | |
a = a9 or u = u9; | |
end; | |
registration | |
cluster strict Ternary-Field-like for non empty TernaryFieldStr; | |
existence by Def5,Lm1,Lm2,Lm3,Lm4,Lm5,Lm6,Lm7,Lm8,Lm9; | |
end; | |
definition | |
mode Ternary-Field is Ternary-Field-like non empty TernaryFieldStr; | |
end; | |
reserve F for Ternary-Field; | |
reserve a,a9,b,c,x,x9,u,u9,v,v9,z for Scalar of F; | |
theorem | |
a<>a9 & Tern(u,a,v) = Tern(u9,a,v9) & Tern(u,a9,v) = Tern(u9,a9,v9) | |
implies u=u9 & v=v9 | |
proof | |
assume that | |
A1: a<>a9 and | |
A2: Tern(u,a,v) = Tern(u9,a,v9) and | |
A3: Tern(u,a9,v) = Tern(u9,a9,v9); | |
u = u9 by A1,A2,A3,Def5; | |
hence thesis by A2,Def5; | |
end; | |
theorem | |
a<>0.F implies for b,c ex x st Tern(a,x,b) = c | |
proof | |
assume | |
A1: a <> 0.F; | |
let b,c; | |
consider x such that | |
A2: Tern(a,x,b) = Tern(0.F,x,c) by A1,Def5; | |
take x; | |
thus thesis by A2,Def5; | |
end; | |
theorem | |
a<>0.F & Tern(a,x,b) = Tern(a,x9,b) implies x=x9 | |
proof | |
assume that | |
A1: a<>0.F and | |
A2: Tern(a,x,b) = Tern(a,x9,b); | |
set c = Tern(a,x,b); | |
A3: Tern(a,x,b) = Tern(0.F,x,c) by Def5; | |
Tern(a,x9,b) = Tern(0.F,x9,c) by A2,Def5; | |
hence thesis by A1,A3,Def5; | |
end; | |
theorem | |
a<>0.F implies for b,c ex x st Tern(x,a,b) = c | |
proof | |
assume | |
A1: a <> 0.F; | |
let b,c; | |
consider x,z such that | |
A2: Tern(x,a,z) = c & Tern(x,0.F,z) = b by A1,Def5; | |
take x; | |
thus thesis by A2,Def5; | |
end; | |
theorem | |
a<>0.F & Tern(x,a,b) = Tern(x9,a,b) implies x=x9 | |
proof | |
assume | |
A1: a<>0.F & Tern(x,a,b) = Tern(x9,a,b); | |
Tern(x,0.F,b) = b & Tern(x9,0.F,b) = b by Def5; | |
hence thesis by A1,Def5; | |
end; | |