A naive integral
Abstract
In arXiv:2406.0243 two real functions g(x,t) and f(x,t) are defined, so that the Riemann-Siegel Z function is given as \[Z(t)=Re\u(t)eπ i812+it∫0∞ g(x,t)ei f(x,t)\,dt\,\] where u(t) is a real function of order t-1/4 when t+∞. The function g(x,t) is indefinitely differentiable and tends to 0 as well as all its derivatives when x0+ or x+∞. Since, furthermore, for t+∞ the function f(x,t) tends to +∞ we may expect that the integral depends essentially on the behavior of g(x,t) at the extremes. As Polya in an analogous situation we consider the substitution of (x) by a simpler similar function. A simple function with this behavior is \[0(x):=2π(1+14x-5/2)e-π x-π4x.\] Therefore, we define J0(t) replacing in the definition of J(t) the function (x) by the simpler 0(x). equation J0(t)=2π∫0∞ (1+14x-52)e-π x-π4x(1-ix)12(12+it)\,dx. equation The resulting Z0(t) disappoints us \[Z0(t) Re\2π\i(t2t2π-t2-π8)\+2(2π t)1/4(π it2π\;)\, t+∞.\] However, the integral J0(t) is interesting as a technical challenge. And still we have the possibility to get a better result improving 0(x). This is a preliminary version, and we set it as a challenge: to compute and study this integral.
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