How to determine bounds on one variable in a system of inequalities? I am interested in the point o

Llubanipo

Llubanipo

Answered question

2022-06-22

How to determine bounds on one variable in a system of inequalities?
I am interested in the point of 'cross-over' between a generalised harmonic number where the denominator of the summand is raised to a power, and a non-exponential harmonic sum operating on some subset of the natural numbers.
For example, take the generalised harmonic number H x ( k ) = n = 1 x 1 n k , and a harmonic number operating only on odd denominators G x = n = 1 x 1 2 n 1 .
Clearly, there exist values of x,k such that G x < H x ( k ) and values such that H x ( k ) < G x . Thus there exists a value c = G x 0 such that
G x 0 = c < H x 0 ( k ) = n = 1 x 1 n k
and
H x 0 + 2 ( k ) < G x 0 + 2 = c + 1 2 x 0 + 1 + 1 2 x 0 + 3
or
H x 0 + 2 ( k ) c < 1 2 x 0 + 1 + 1 2 x 0 + 3
The values of c , x 0 , k are obviously co-dependent. I am searching for a way to solve for x 0 or at least put bounds on it.
I am interested in how to approach this algebraically rather than numerically. This is a single simple example of G and I want to be able to explore how to solve such problems generally, for whatever pattern of G I choose (provided it's formulable!).
Algebraically, how do I put bounds on x 0 in terms of c , k?

Answer & Explanation

jarakapak7

jarakapak7

Beginner2022-06-23Added 14 answers

We can approximate the sums by the integrals and then to deal with the resulting functions. For instance, for k < 1,
H ( k ) ( x ) 1 x 1 t k d t = t 1 k 1 k | 1 x = 1 1 k ( x 1 k 1 ) .
For k = 1 and natural x,
H ( 1 ) ( x ) ln x + γ + 1 2 x 1 12 x 2 + 1 120 x 4 ,
where γ 0.5772156649 is the Euler–Mascheroni constant. For k > 1 when x tends to infinity, the sequence H x ( k ) converges to Riemann zeta function ζ ( k ).
Similarly we have
G ( x ) 1 x 1 2 t 1 d t = 1 2 ln ( 2 x 1 ) .

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