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# Using Z3Py online to prove that n^5 <= 5 ^n for n >= 5

Using the following code:

``````n = Int('n')
s = Solver()
print s
print s.check()
``````

we obtain the following output:

``````[n ≥ 5, ¬(n^5 ≤ 5^n)]
unknown
``````

It is to say that Z3Py is not able to produce a direct proof.

Now using the code

``````n = Int('n')
prove(Implies(n >= 5, n**5 <= 5**n))
``````

Z3Py also fails.

A posible indirect proof is as follows:

``````n = Int('n')
e, f = Ints('e f')
t = simplify(-(5 + f + 1)**5 + ((5 + f)**5 + e)*5, som=True)
prove(Implies(And(e >=0, f >= 0), t >= 0))
``````

and the output is:

``````proved
``````

A proof using Isabelle + Maple is given at :Theorems and Algorithms: An Interface between Isabelle and Maple. Clemens Ballarin. Karsten Homann. Jacques Calmet.

Other possible indirect proof using Z3Py is as follows:

``````n = Int('n')
e, f = Ints('e f')
t = simplify(-(5 + f + 1)**5 + ((5 + f)**5 + e)*5, som=True)
s = Solver()
s.add(e >= 0, f >= 0)
print s
print s.check()
``````

and the output is:

``````[e ≥ 0,
f ≥ 0,
¬(7849 +
9145·f +
4090·f·f +
890·f·f·f +
95·f·f·f·f +
4·f·f·f·f·f +
5·e ≥
0)]
unsat
``````

Please let me know if it is possible to have a more direct proof using Z3Py. Many thanks.

-
Z3 does not have decision procedures for integer arithmetic, or powers for that matter. Your use of simplification looks pretty neat to me to combine the features available. – Nikolaj Bjorner Apr 29 '13 at 3:07

Z3 has very limited support for nonlinear integer arithmetic. See the following related post for more information:

Z3 has a complete solver (nlsat) for nonlinear real (polynomial) arithmetic. You can simplify your script by writing

``````n = Real('n')
e, f = Reals('e f')
prove(Implies(And(e >=0, f >= 0), -(5 + f + 1)**5 + ((5 + f)**5 + e)*5 >= 0))
``````

Z3 uses nlsat in the problem above because it contains only real variables. We can also force Z3 to use nlsat even if the problem contains integer variables.

``````n = Int('n')
e, f = Ints('e f')
s = Tactic('qfnra-nlsat').solver()
s.add(e >= 0, f >= 0)
s.add(Not(-(5 + f + 1)**5 + ((5 + f)**5 + e)*5 >= 0))
print s
print s.check()
``````
-
Wonderful, many thanks. – Juan Ospina May 1 '13 at 2:14