Certification Problem

Input (TPDB SRS_Standard/Waldmann_19/random-470)

The rewrite relation of the following TRS is considered.

a(b(a(a(x1))))	→	a(b(b(a(x1))))	(1)
a(b(a(b(x1))))	→	a(b(b(a(x1))))	(2)
b(b(a(a(x1))))	→	a(b(a(a(x1))))	(3)
b(b(b(b(x1))))	→	a(a(a(a(x1))))	(4)

Property / Task

Prove or disprove termination.

Answer / Result

Yes.

Proof (by AProVE @ termCOMP 2023)

1 Closure Under Flat Contexts

Using the flat contexts

{a(☐), b(☐)}

We obtain the transformed TRS

a(b(a(a(x1))))	→	a(b(b(a(x1))))	(1)
a(b(a(b(x1))))	→	a(b(b(a(x1))))	(2)
a(b(b(a(a(x1)))))	→	a(a(b(a(a(x1)))))	(5)
b(b(b(a(a(x1)))))	→	b(a(b(a(a(x1)))))	(6)
a(b(b(b(b(x1)))))	→	a(a(a(a(a(x1)))))	(7)
b(b(b(b(b(x1)))))	→	b(a(a(a(a(x1)))))	(8)

1.1 Semantic Labeling

Root-labeling is applied.

We obtain the labeled TRS

a_b(b_a(a_a(a_a(x1))))	→	a_b(b_b(b_a(a_a(x1))))	(9)
a_b(b_a(a_a(a_b(x1))))	→	a_b(b_b(b_a(a_b(x1))))	(10)
a_b(b_a(a_b(b_a(x1))))	→	a_b(b_b(b_a(a_a(x1))))	(11)
a_b(b_a(a_b(b_b(x1))))	→	a_b(b_b(b_a(a_b(x1))))	(12)
a_b(b_b(b_a(a_a(a_a(x1)))))	→	a_a(a_b(b_a(a_a(a_a(x1)))))	(13)
a_b(b_b(b_a(a_a(a_b(x1)))))	→	a_a(a_b(b_a(a_a(a_b(x1)))))	(14)
b_b(b_b(b_a(a_a(a_a(x1)))))	→	b_a(a_b(b_a(a_a(a_a(x1)))))	(15)
b_b(b_b(b_a(a_a(a_b(x1)))))	→	b_a(a_b(b_a(a_a(a_b(x1)))))	(16)
a_b(b_b(b_b(b_b(b_a(x1)))))	→	a_a(a_a(a_a(a_a(a_a(x1)))))	(17)
a_b(b_b(b_b(b_b(b_b(x1)))))	→	a_a(a_a(a_a(a_a(a_b(x1)))))	(18)
b_b(b_b(b_b(b_b(b_a(x1)))))	→	b_a(a_a(a_a(a_a(a_a(x1)))))	(19)
b_b(b_b(b_b(b_b(b_b(x1)))))	→	b_a(a_a(a_a(a_a(a_b(x1)))))	(20)

1.1.1 Dependency Pair Transformation

The following set of initial dependency pairs has been identified.

a_b^#(b_a(a_a(a_a(x1))))	→	a_b^#(b_b(b_a(a_a(x1))))	(21)
a_b^#(b_a(a_a(a_a(x1))))	→	b_b^#(b_a(a_a(x1)))	(22)
a_b^#(b_a(a_a(a_b(x1))))	→	a_b^#(b_b(b_a(a_b(x1))))	(23)
a_b^#(b_a(a_a(a_b(x1))))	→	b_b^#(b_a(a_b(x1)))	(24)
a_b^#(b_a(a_b(b_a(x1))))	→	a_b^#(b_b(b_a(a_a(x1))))	(25)
a_b^#(b_a(a_b(b_a(x1))))	→	b_b^#(b_a(a_a(x1)))	(26)
a_b^#(b_a(a_b(b_b(x1))))	→	a_b^#(b_b(b_a(a_b(x1))))	(27)
a_b^#(b_a(a_b(b_b(x1))))	→	b_b^#(b_a(a_b(x1)))	(28)
a_b^#(b_a(a_b(b_b(x1))))	→	a_b^#(x1)	(29)
a_b^#(b_b(b_a(a_a(a_a(x1)))))	→	a_b^#(b_a(a_a(a_a(x1))))	(30)
a_b^#(b_b(b_a(a_a(a_b(x1)))))	→	a_b^#(b_a(a_a(a_b(x1))))	(31)
b_b^#(b_b(b_a(a_a(a_a(x1)))))	→	a_b^#(b_a(a_a(a_a(x1))))	(32)
b_b^#(b_b(b_a(a_a(a_b(x1)))))	→	a_b^#(b_a(a_a(a_b(x1))))	(33)
a_b^#(b_b(b_b(b_b(b_b(x1)))))	→	a_b^#(x1)	(34)
b_b^#(b_b(b_b(b_b(b_b(x1)))))	→	a_b^#(x1)	(35)

1.1.1.1 Dependency Graph Processor

The dependency pairs are split into 2 components.

The 1^st component contains the pair

a_b^#(b_b(b_b(b_b(b_b(x1))))) → a_b^#(x1) (34)

a_b^#(b_a(a_b(b_b(x1)))) → a_b^#(x1) (29)

1.1.1.1.1 Monotonic Reduction Pair Processor with Usable Rules
Using the linear polynomial interpretation over the naturals

[b_b(x₁)] = 1 · x₁

[b_a(x₁)] = 1 · x₁

[a_b(x₁)] = 1 · x₁

[a_b^#(x₁)] = 1 · x₁

having no usable rules (w.r.t. the implicit argument filter of the reduction pair), the rule could be deleted.
1.1.1.1.1.1 Size-Change Termination

Using size-change termination in combination with the subterm criterion one obtains the following initial size-change graphs.

a_b^#(b_b(b_b(b_b(b_b(x1))))) → a_b^#(x1) (34)

1 > 1

a_b^#(b_a(a_b(b_b(x1)))) → a_b^#(x1) (29)

1 > 1

As there is no critical graph in the transitive closure, there are no infinite chains.

The 2^nd component contains the pair

a_b^#(b_b(b_a(a_a(a_a(x1)))))	→	a_b^#(b_a(a_a(a_a(x1))))	(30)
a_b^#(b_a(a_a(a_a(x1))))	→	a_b^#(b_b(b_a(a_a(x1))))	(21)
a_b^#(b_b(b_a(a_a(a_b(x1)))))	→	a_b^#(b_a(a_a(a_b(x1))))	(31)
a_b^#(b_a(a_a(a_b(x1))))	→	a_b^#(b_b(b_a(a_b(x1))))	(23)

1.1.1.1.2 Monotonic Reduction Pair Processor with Usable Rules

Using the linear polynomial interpretation over the naturals

[a_b(x₁)]	=	1 · x₁
[b_a(x₁)]	=	1 · x₁
[a_a(x₁)]	=	1 · x₁
[b_b(x₁)]	=	1 · x₁
[a_b^#(x₁)]	=	1 · x₁

together with the usable rules

a_b(b_a(a_a(a_a(x1))))	→	a_b(b_b(b_a(a_a(x1))))	(9)
a_b(b_a(a_a(a_b(x1))))	→	a_b(b_b(b_a(a_b(x1))))	(10)
a_b(b_a(a_b(b_a(x1))))	→	a_b(b_b(b_a(a_a(x1))))	(11)
a_b(b_a(a_b(b_b(x1))))	→	a_b(b_b(b_a(a_b(x1))))	(12)
a_b(b_b(b_a(a_a(a_a(x1)))))	→	a_a(a_b(b_a(a_a(a_a(x1)))))	(13)
a_b(b_b(b_a(a_a(a_b(x1)))))	→	a_a(a_b(b_a(a_a(a_b(x1)))))	(14)
a_b(b_b(b_b(b_b(b_a(x1)))))	→	a_a(a_a(a_a(a_a(a_a(x1)))))	(17)
a_b(b_b(b_b(b_b(b_b(x1)))))	→	a_a(a_a(a_a(a_a(a_b(x1)))))	(18)

(w.r.t. the implicit argument filter of the reduction pair), the rule could be deleted.

1.1.1.1.2.1 Reduction Pair Processor

Using the linear polynomial interpretation over the naturals

[a_b^#(x₁)]	=	1 · x₁
[b_b(x₁)]	=	1 + 1 · x₁
[b_a(x₁)]	=	1 + 1 · x₁
[a_a(x₁)]	=	1 + 1 · x₁
[a_b(x₁)]	=	1 + 1 · x₁

the pairs

a_b^#(b_b(b_a(a_a(a_a(x1)))))	→	a_b^#(b_a(a_a(a_a(x1))))	(30)
a_b^#(b_b(b_a(a_a(a_b(x1)))))	→	a_b^#(b_a(a_a(a_b(x1))))	(31)

could be deleted.

1.1.1.1.2.1.1 Dependency Graph Processor

The dependency pairs are split into 0 components.