5 CONSERVATION OF ENERGY 5.4 Conservative and non-conservative force-fields
XXWi =
Afi(r)·dr (5.22)W =
Af(r)·dr. (5.25)net increase in that body’s kinetic energy between these two points. This result
is completely general (at least, for conservative force-fields—see later), and does
not just apply to 1 - dimensional motion.
Suppose, finally, that an object is subject to more than one force. How do wecalculate the net work W performed by all these forces as the object moves from
point A to point B? One approach would be to calculate the work done by each
force, taken in isolation, and then to sum the results. In other words, defining
∫Bas the work done by the ith force, the net work is given by
W = Wi. (5.23)
iAn alternative approach would be to take the vector sum of all the forces to find
the resultant force,
f = fi, (5.24)
iand then to calculate the work done by the resultant force:
∫BIt should, hopefully, be clear that these two approaches are entirely equivalent.
5.4 Conservative and non-conservative force-fields
Suppose that a non-uniform force-field f(r) acts upon an object which moves
along a curved trajectory, labeled path 1, from point A to point B. See Fig. 40.
As we have seen, the work W 1 performed by the force-field on the object can be
written as a line-integral along this trajectory:
W 1 = (^) A
(^) B:path 1 f·dr. (5.26)
→
∫