LITMIR.BIZ

Figure 2.2 A system of particles in an inertial reference frame OXYZ.

      For the convenience of notation, consider the overdot to denote the time derivative relative to the inertial reference frame. Taking a scalar product of Eq. (2.33) with , and summing over all particles, we have

(2.37)

The term on the left‐hand side of Eq. (2.37) is identified to be the time derivative of the net kinetic energy of the system given by

(2.38)

Before proceeding further, it is necessary to consider that gravity is a conservative force, because, as will be seen later, it has no influence on the net energy, , of a system. A force which depends only upon the relative position of the masses (as gravity does) is a conservative force, and can be expressed as the gradient of a scalar function, called the gravitational potential. The gradient of a scalar, U, with respect to a position vector, , is defined to be the following derivative of the scalar with respect to the given vector,

      (2.39)

      Thus, the gradient of a scalar with respect to a column vector is a row vector.

      Consider, for example, an isolated pair of masses, . The gravitational attraction on due to is given by the force, . By Newton's law of gravitation, we have

(2.40)

      where the relative position of mass from the mass is given by the vector . Let be the gravitational potential at the location of the particle, , defined by

      (2.41)

      The gradient of with respect to is the following:

(2.42)

On comparing Eqs. (2.40) and (2.42), we have

      (2.43)

      The acceleration of the mass Скачать книгу