“…Another two distributions that have astrophysical interest are the sech-square distribution, corresponding to an isothermal self-gravitating disk, see equation (41) in [1], equation at page 441 in [2], equations (9.8) and (14.6) in [3], equation (2.31) in [4], and the normal or Gaussian distribution, see equation (5) in [5]. In the field of probability, the truncation of a distribution is a common topic of research and we report some of the approaches on the double applications to a numerical relation between the root-mean-square speed and temperature and to a modification of the formula for the Jeans escape flux of molecules from an atmosphere [14], the relativistic Maxwell-Boltzmann distribution, with applications to the synchrotron emission in the presence of a magnetic field and to relativistic electrons [15], the truncated Weibull distribution, with applications to the masses of the stars and to the luminosity functions for galaxies and quasars [16], the truncated two-parameter Sujatha distribution [17], the gamma-Pareto distribution, with application to cosmic rays [18], and the truncated Weibull-Pareto distribution, with applications to the initial mass function for stars, the luminosity function for galaxies of the Sloan Digital Sky Survey, the luminosity function for QSO, and the photometric maximum of galaxies of the 2MASS Redshift Survey. This paper analyses in Section 2 the exponential, the half-normal and the sech-square distributions defined in the interval [ ] 0, ∞ .…”