set n = 1;
let f be non constant standard special_circular_sequence; :: thesis: for p being Point of (TOP-REAL 2) st p in rng f holds
right_cell f,(p .. f) = right_cell (Rotate f,p),1
let p be Point of (TOP-REAL 2); :: thesis: ( p in rng f implies right_cell f,(p .. f) = right_cell (Rotate f,p),1 )
assume A1: p in rng f ; :: thesis: right_cell f,(p .. f) = right_cell (Rotate f,p),1
set k = p .. f;
len f > 1 by GOBOARD7:36, XXREAL_0:2;
then p .. f < len f by A1, SPRECT_5:7;
then A2: (p .. f) + 1 <= len f by NAT_1:13;
A3: 1 <= p .. f by A1, FINSEQ_4:31;
A4: for i1, j1, i2, j2 being Element of NAT st [i1,j1] in Indices (GoB (Rotate f,p)) & [i2,j2] in Indices (GoB (Rotate f,p)) & (Rotate f,p) /. 1 = (GoB (Rotate f,p)) * i1,j1 & (Rotate f,p) /. (1 + 1) = (GoB (Rotate f,p)) * i2,j2 & not ( i1 = i2 & j1 + 1 = j2 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,j1 ) & not ( i1 + 1 = i2 & j1 = j2 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,(j1 -' 1) ) & not ( i1 = i2 + 1 & j1 = j2 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i2,j2 ) holds
( i1 = i2 & j1 = j2 + 1 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),(i1 -' 1),j2 )
proof
(Rotate f,p) /. (((1 + 1) + (p .. f)) -' (p .. f)) = (Rotate f,p) /. (1 + 1) by NAT_D:34;
then A5: (Rotate f,p) /. ((((p .. f) + 1) + 1) -' (p .. f)) = (Rotate f,p) /. (1 + 1) ;
A6: right_cell f,(p .. f) = right_cell f,(p .. f) ;
let i1, j1, i2, j2 be Element of NAT ; :: thesis: ( [i1,j1] in Indices (GoB (Rotate f,p)) & [i2,j2] in Indices (GoB (Rotate f,p)) & (Rotate f,p) /. 1 = (GoB (Rotate f,p)) * i1,j1 & (Rotate f,p) /. (1 + 1) = (GoB (Rotate f,p)) * i2,j2 & not ( i1 = i2 & j1 + 1 = j2 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,j1 ) & not ( i1 + 1 = i2 & j1 = j2 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,(j1 -' 1) ) & not ( i1 = i2 + 1 & j1 = j2 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i2,j2 ) implies ( i1 = i2 & j1 = j2 + 1 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),(i1 -' 1),j2 ) )
assume that
A7: ( [i1,j1] in Indices (GoB (Rotate f,p)) & [i2,j2] in Indices (GoB (Rotate f,p)) ) and
A8: (Rotate f,p) /. 1 = (GoB (Rotate f,p)) * i1,j1 and
A9: (Rotate f,p) /. (1 + 1) = (GoB (Rotate f,p)) * i2,j2 ; :: thesis: ( ( i1 = i2 & j1 + 1 = j2 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,j1 ) or ( i1 + 1 = i2 & j1 = j2 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,(j1 -' 1) ) or ( i1 = i2 + 1 & j1 = j2 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i2,j2 ) or ( i1 = i2 & j1 = j2 + 1 & right_cell f,(p .. f) = cell (GoB (Rotate f,p)),(i1 -' 1),j2 ) )
A10: GoB (Rotate f,p) = GoB f by REVROT_1:28;
len (Rotate f,p) = len f by REVROT_1:14;
then (Rotate f,p) /. (len f) = (Rotate f,p) /. 1 by FINSEQ_6:def 1;
then (Rotate f,p) /. (((p .. f) + (len f)) -' (p .. f)) = (Rotate f,p) /. 1 by NAT_D:34;
then A11: f /. (p .. f) = (GoB f) * i1,j1 by A1, A3, A8, A10, REVROT_1:18;
p .. f < (p .. f) + 1 by NAT_1:13;
then A12: f /. ((p .. f) + 1) = (GoB f) * i2,j2 by A1, A2, A9, A10, A5, REVROT_1:10;
then A13: ( ( i1 = i2 & j1 + 1 = j2 & right_cell f,(p .. f) = cell (GoB f),i1,j1 ) or ( i1 + 1 = i2 & j1 = j2 & right_cell f,(p .. f) = cell (GoB f),i1,(j1 -' 1) ) or ( i1 = i2 + 1 & j1 = j2 & right_cell f,(p .. f) = cell (GoB f),i2,j2 ) or ( i1 = i2 & j1 = j2 + 1 & right_cell f,(p .. f) = cell (GoB f),(i1 -' 1),j2 ) ) by A3, A2, A7, A10, A11, A6, GOBOARD5:def 6;
per cases ( ( i1 = i2 & j1 + 1 = j2 ) or ( i1 + 1 = i2 & j1 = j2 ) or ( i1 = i2 + 1 & j1 = j2 ) or ( i1 = i2 & j1 = j2 + 1 ) ) by A3, A2, A7, A10, A11, A12, A6, GOBOARD5:def 6;
case ( i1 = i2 & j1 + 1 = j2 ) ; :: thesis: right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,j1
hence right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,j1 by A13, REVROT_1:28; :: thesis: verum
end;
case ( i1 + 1 = i2 & j1 = j2 ) ; :: thesis: right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,(j1 -' 1)
hence right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i1,(j1 -' 1) by A13, REVROT_1:28; :: thesis: verum
end;
case ( i1 = i2 + 1 & j1 = j2 ) ; :: thesis: right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i2,j2
hence right_cell f,(p .. f) = cell (GoB (Rotate f,p)),i2,j2 by A13, REVROT_1:28; :: thesis: verum
end;
case ( i1 = i2 & j1 = j2 + 1 ) ; :: thesis: right_cell f,(p .. f) = cell (GoB (Rotate f,p)),(i1 -' 1),j2
hence right_cell f,(p .. f) = cell (GoB (Rotate f,p)),(i1 -' 1),j2 by A13, REVROT_1:28; :: thesis: verum
end;
end;
end;
1 + 1 <= len (Rotate f,p) by GOBOARD7:36, XXREAL_0:2;
hence right_cell f,(p .. f) = right_cell (Rotate f,p),1 by A4, GOBOARD5:def 6; :: thesis: verum