The points for which is constant lie in the hyperbola whose axes are and .
On the axis of , between and ,
(4) |
On the axis of , beyond these limits on either side, we have
(5) |
Hence, if is the potential function, and the function of flow, we have the case of electricity flowing from the negative to the positive side of the axis of through the space between the points -1 and +1 , the parts of the axis beyond these limits being impervious to electricity.
Since, in this case, the axis of is a line of flow, we may suppose it also impervious to electricity.
We may also consider the ellipses to be sections of the equipotential surfaces due to an indefinitely long flat conductor of breadth 2, charged with half a unit of electricity per unit of length.
If we make the potential function, and the function of flow, the case becomes that of an infinite plane from which a strip of breadth 2 has been cut away and the plane on one side charged to potential while the other remains at zero.
These cases may be considered as particular cases of the quadric surfaces treated of in Chapter X. The forms of the curves are given in Fig. X.
EXAMPLE VI. Fig. XI.
193.] Let us next consider and as functions of and , where
(6) |
and will be also conjugate functions of and .
The curves resulting from the transformation of Fig. X with respect to these new coordinates are given in Fig. XI.
If and are rectangular coordinates, then the properties of the axis of in the first figure will belong to a series of lines parallel to in the second figure for which , where is any integer.
The positive values of on these lines will correspond to values of greater than unity, for which, as we have already seen,
(7) |