:: SPRECT_5 semantic presentation  Show TPTP formulae Show IDV graph for whole article:: Showing IDV graph ... (Click the Palm Trees again to close it)

theorem Th1: :: SPRECT_5:1  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for D being non empty set
for f being FinSequence of D
for q, p being Element of D st q in rng (f | (p .. f)) holds
q .. f <= p .. f
proof end;

theorem Th2: :: SPRECT_5:2  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for D being non empty set
for f being FinSequence of D
for p, q being Element of D st p in rng f & q in rng f & p .. f <= q .. f holds
q .. (f :- p) = ((q .. f) - (p .. f)) + 1
proof end;

theorem Th3: :: SPRECT_5:3  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for D being non empty set
for f being FinSequence of D
for p, q being Element of D st p in rng f & q in rng f & p .. f <= q .. f holds
p .. (f -: q) = p .. f
proof end;

theorem Th4: :: SPRECT_5:4  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for D being non empty set
for f being FinSequence of D
for p, q being Element of D st p in rng f & q in rng f & p .. f <= q .. f holds
q .. (Rotate f,p) = ((q .. f) - (p .. f)) + 1
proof end;

theorem Th5: :: SPRECT_5:5  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for D being non empty set
for f being FinSequence of D
for p1, p2, p3 being Element of D st p1 in rng f & p2 in rng f & p3 in rng f & p1 .. f <= p2 .. f & p2 .. f < p3 .. f holds
p2 .. (Rotate f,p1) < p3 .. (Rotate f,p1)
proof end;

theorem :: SPRECT_5:6  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for D being non empty set
for f being FinSequence of D
for p1, p2, p3 being Element of D st p1 in rng f & p2 in rng f & p3 in rng f & p1 .. f < p2 .. f & p2 .. f <= p3 .. f holds
p2 .. (Rotate f,p1) <= p3 .. (Rotate f,p1)
proof end;

theorem Th7: :: SPRECT_5:7  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for D being non empty set
for g being circular FinSequence of D
for p being Element of D st p in rng g & len g > 1 holds
p .. g < len g
proof end;

theorem Th8: :: SPRECT_5:8  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence holds f /^ 1 is one-to-one
proof end;

theorem Th9: :: SPRECT_5:9  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence
for q being Point of (TOP-REAL 2) st 1 < q .. f & q in rng f holds
(f /. 1) .. (Rotate f,q) = ((len f) + 1) - (q .. f)
proof end;

theorem Th10: :: SPRECT_5:10  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence
for p, q being Point of (TOP-REAL 2) st p in rng f & q in rng f & p .. f < q .. f holds
p .. (Rotate f,q) = ((len f) + (p .. f)) - (q .. f)
proof end;

theorem Th11: :: SPRECT_5:11  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence
for p1, p2, p3 being Point of (TOP-REAL 2) st p1 in rng f & p2 in rng f & p3 in rng f & p1 .. f < p2 .. f & p2 .. f < p3 .. f holds
p3 .. (Rotate f,p2) < p1 .. (Rotate f,p2)
proof end;

theorem Th12: :: SPRECT_5:12  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence
for p1, p2, p3 being Point of (TOP-REAL 2) st p1 in rng f & p2 in rng f & p3 in rng f & p1 .. f < p2 .. f & p2 .. f < p3 .. f holds
p1 .. (Rotate f,p3) < p2 .. (Rotate f,p3)
proof end;

theorem :: SPRECT_5:13  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence
for p1, p2, p3 being Point of (TOP-REAL 2) st p1 in rng f & p2 in rng f & p3 in rng f & p1 .. f <= p2 .. f & p2 .. f < p3 .. f holds
p1 .. (Rotate f,p3) <= p2 .. (Rotate f,p3)
proof end;

theorem :: SPRECT_5:14  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence holds (S-min (L~ f)) .. f < len f
proof end;

theorem :: SPRECT_5:15  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence holds (S-max (L~ f)) .. f < len f
proof end;

theorem :: SPRECT_5:16  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence holds (E-min (L~ f)) .. f < len f
proof end;

theorem :: SPRECT_5:17  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence holds (E-max (L~ f)) .. f < len f
proof end;

theorem :: SPRECT_5:18  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence holds (N-min (L~ f)) .. f < len f
proof end;

theorem :: SPRECT_5:19  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence holds (N-max (L~ f)) .. f < len f
proof end;

theorem :: SPRECT_5:20  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence holds (W-max (L~ f)) .. f < len f
proof end;

theorem :: SPRECT_5:21  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence holds (W-min (L~ f)) .. f < len f
proof end;

Lm1: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(E-max (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

Lm2: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(E-max (L~ z)) .. z < (S-min (L~ z)) .. z
proof end;

Lm3: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(E-max (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

Lm4: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(E-min (L~ z)) .. z < (S-min (L~ z)) .. z
proof end;

Lm5: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(E-min (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

Lm6: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(S-max (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

Lm7: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(N-max (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

Lm8: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(N-min (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

Lm9: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(N-max (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

Lm10: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-min (L~ z) holds
(N-max (L~ z)) .. z < (S-min (L~ z)) .. z
proof end;

theorem Th22: :: SPRECT_5:22  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = W-min (L~ f) holds
(W-min (L~ f)) .. f < (W-max (L~ f)) .. f
proof end;

theorem :: SPRECT_5:23  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = W-min (L~ f) holds
(W-max (L~ f)) .. f > 1
proof end;

theorem Th24: :: SPRECT_5:24  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) & W-max (L~ z) <> N-min (L~ z) holds
(W-max (L~ z)) .. z < (N-min (L~ z)) .. z
proof end;

theorem Th25: :: SPRECT_5:25  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(N-min (L~ z)) .. z < (N-max (L~ z)) .. z
proof end;

theorem Th26: :: SPRECT_5:26  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) & N-max (L~ z) <> E-max (L~ z) holds
(N-max (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

theorem Th27: :: SPRECT_5:27  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(E-max (L~ z)) .. z < (E-min (L~ z)) .. z
proof end;

theorem Th28: :: SPRECT_5:28  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) & E-min (L~ z) <> S-max (L~ z) holds
(E-min (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:29  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) & S-min (L~ z) <> W-min (L~ z) holds
(S-max (L~ z)) .. z < (S-min (L~ z)) .. z
proof end;

theorem Th30: :: SPRECT_5:30  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = S-max (L~ f) holds
(S-max (L~ f)) .. f < (S-min (L~ f)) .. f
proof end;

theorem :: SPRECT_5:31  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = S-max (L~ f) holds
(S-min (L~ f)) .. f > 1
proof end;

Lm11: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(E-max (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

Lm12: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(N-min (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

Lm13: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(N-min (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

Lm14: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(N-max (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

Lm15: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(W-max (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

Lm16: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(N-max (L~ z)) .. z < (E-min (L~ z)) .. z
proof end;

Lm17: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(N-min (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

Lm18: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(W-max (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

Lm19: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-min (L~ z) holds
(W-max (L~ z)) .. z < (E-min (L~ z)) .. z
proof end;

theorem Th32: :: SPRECT_5:32  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) & S-min (L~ z) <> W-min (L~ z) holds
(S-min (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

theorem Th33: :: SPRECT_5:33  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) holds
(W-min (L~ z)) .. z < (W-max (L~ z)) .. z
proof end;

theorem Th34: :: SPRECT_5:34  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) & W-max (L~ z) <> N-min (L~ z) holds
(W-max (L~ z)) .. z < (N-min (L~ z)) .. z
proof end;

theorem Th35: :: SPRECT_5:35  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) holds
(N-min (L~ z)) .. z < (N-max (L~ z)) .. z
proof end;

theorem Th36: :: SPRECT_5:36  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) & N-max (L~ z) <> E-max (L~ z) holds
(N-max (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:37  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) & E-min (L~ z) <> S-max (L~ z) holds
(E-max (L~ z)) .. z < (E-min (L~ z)) .. z
proof end;

theorem Th38: :: SPRECT_5:38  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = E-max (L~ f) holds
(E-max (L~ f)) .. f < (E-min (L~ f)) .. f
proof end;

theorem :: SPRECT_5:39  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = E-max (L~ f) holds
(E-min (L~ f)) .. f > 1
proof end;

theorem Th40: :: SPRECT_5:40  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) & S-max (L~ z) <> E-min (L~ z) holds
(E-min (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

theorem Th41: :: SPRECT_5:41  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) holds
(S-max (L~ z)) .. z < (S-min (L~ z)) .. z
proof end;

Lm20: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) holds
(N-min (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

Lm21: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) holds
(W-max (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

Lm22: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) holds
(W-min (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

Lm23: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) holds
(W-max (L~ z)) .. z < (N-max (L~ z)) .. z
proof end;

Lm24: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) holds
(W-min (L~ z)) .. z < (N-min (L~ z)) .. z
proof end;

Lm25: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) holds
(S-min (L~ z)) .. z < (N-min (L~ z)) .. z
proof end;

Lm26: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-max (L~ z) holds
(S-min (L~ z)) .. z < (N-max (L~ z)) .. z
proof end;

theorem Th42: :: SPRECT_5:42  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) & S-min (L~ z) <> W-min (L~ z) holds
(S-min (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

theorem Th43: :: SPRECT_5:43  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) holds
(W-min (L~ z)) .. z < (W-max (L~ z)) .. z
proof end;

theorem Th44: :: SPRECT_5:44  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) & W-max (L~ z) <> N-min (L~ z) holds
(W-max (L~ z)) .. z < (N-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:45  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) & N-max (L~ z) <> E-max (L~ z) holds
(N-min (L~ z)) .. z < (N-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:46  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = N-max (L~ f) & N-max (L~ f) <> E-max (L~ f) holds
(N-max (L~ f)) .. f < (E-max (L~ f)) .. f
proof end;

theorem :: SPRECT_5:47  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-max (L~ z) holds
(E-max (L~ z)) .. z < (E-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:48  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-max (L~ z) & E-min (L~ z) <> S-max (L~ z) holds
(E-min (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:49  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-max (L~ z) holds
(S-max (L~ z)) .. z < (S-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:50  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-max (L~ z) & S-min (L~ z) <> W-min (L~ z) holds
(S-min (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:51  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-max (L~ z) holds
(W-min (L~ z)) .. z < (W-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:52  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = N-max (L~ z) & N-min (L~ z) <> W-max (L~ z) holds
(W-max (L~ z)) .. z < (N-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:53  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = E-min (L~ f) & E-min (L~ f) <> S-max (L~ f) holds
(E-min (L~ f)) .. f < (S-max (L~ f)) .. f
proof end;

theorem :: SPRECT_5:54  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-min (L~ z) holds
(S-max (L~ z)) .. z < (S-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:55  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-min (L~ z) & S-min (L~ z) <> W-min (L~ z) holds
(S-min (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

Lm27: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) holds
(S-max (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

Lm28: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) holds
(E-min (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;

Lm29: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) holds
(E-min (L~ z)) .. z < (W-max (L~ z)) .. z
proof end;

Lm30: for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-max (L~ z) holds
(S-min (L~ z)) .. z < (W-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:56  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-min (L~ z) holds
(W-min (L~ z)) .. z < (W-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:57  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-min (L~ z) & W-max (L~ z) <> N-min (L~ z) holds
(W-max (L~ z)) .. z < (N-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:58  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-min (L~ z) holds
(N-min (L~ z)) .. z < (N-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:59  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = E-min (L~ z) & E-max (L~ z) <> N-max (L~ z) holds
(N-max (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:60  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = S-min (L~ f) & S-min (L~ f) <> W-min (L~ f) holds
(S-min (L~ f)) .. f < (W-min (L~ f)) .. f
proof end;

theorem :: SPRECT_5:61  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-min (L~ z) holds
(W-min (L~ z)) .. z < (W-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:62  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-min (L~ z) & W-max (L~ z) <> N-min (L~ z) holds
(W-max (L~ z)) .. z < (N-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:63  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-min (L~ z) holds
(N-min (L~ z)) .. z < (N-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:64  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-min (L~ z) & N-max (L~ z) <> E-max (L~ z) holds
(N-max (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:65  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-min (L~ z) holds
(E-max (L~ z)) .. z < (E-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:66  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = S-min (L~ z) & S-max (L~ z) <> E-min (L~ z) holds
(E-min (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:67  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for f being standard non constant special_circular_sequence st f /. 1 = W-max (L~ f) & W-max (L~ f) <> N-min (L~ f) holds
(W-max (L~ f)) .. f < (N-min (L~ f)) .. f
proof end;

theorem :: SPRECT_5:68  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-max (L~ z) holds
(N-min (L~ z)) .. z < (N-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:69  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-max (L~ z) & N-max (L~ z) <> E-max (L~ z) holds
(N-max (L~ z)) .. z < (E-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:70  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-max (L~ z) holds
(E-max (L~ z)) .. z < (E-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:71  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-max (L~ z) & E-min (L~ z) <> S-max (L~ z) holds
(E-min (L~ z)) .. z < (S-max (L~ z)) .. z
proof end;

theorem :: SPRECT_5:72  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-max (L~ z) holds
(S-max (L~ z)) .. z < (S-min (L~ z)) .. z
proof end;

theorem :: SPRECT_5:73  Show TPTP formulae Show IDV graph:: Showing IDV graph ... (Click the Palm Tree again to close it) Show TPTP problem
for z being standard non constant clockwise_oriented special_circular_sequence st z /. 1 = W-max (L~ z) & W-min (L~ z) <> S-min (L~ z) holds
(S-min (L~ z)) .. z < (W-min (L~ z)) .. z
proof end;