Page:A Treatise on Electricity and Magnetism - Volume 2.djvu/188

integrate this expression with respect to ${\displaystyle s^{\prime }}$. Integrating the first term by parts, we find

${\displaystyle {\frac {dX}{ds}}=(P\xi ^{2}-Q)_{(s^{\prime },0)}-\int _{0}^{s^{\prime }}(2Pr-B-C){\frac {l^{\prime }\xi }{r}}\,ds^{\prime }}$.

(19)

When ${\displaystyle s^{\prime }}$ is a closed circuit this expression must be zero. The first term will disappear of itself. The second term, however, will not in general disappear in the case of a closed circuit unless the quantity under the sign of integration is always zero. Hence, to satisfy Ampère's condition,

${\displaystyle P={\frac {1}{2r}}(B+C)}$.

(20)

517.] We can now eliminate ${\displaystyle P}$, and find the general value of ${\displaystyle {\frac {dX}{ds}}}$,

${\displaystyle {\frac {dX}{ds}}=\left\{{\frac {B+C}{2}}{\frac {\xi }{r}}(l\xi +m\eta n\zeta )+Q\right\}_{(s^{\prime },0)}}$ ${\displaystyle {}+m\int _{0}^{s^{\prime }}{\frac {B-C}{2}}{\frac {m^{\prime }\xi -l^{\prime }\eta }{r}}\,ds^{\prime }-n\int _{0}^{s^{\prime }}{\frac {B-C}{2}}{\frac {l^{\prime }\zeta -n^{\prime }\xi }{r}}\,ds^{\prime }}$.

(21)

When ${\displaystyle s^{\prime }}$ is a closed circuit the first term of this expression vanishes, and if we make

${\displaystyle \alpha ^{\prime }=\int _{0}^{s^{\prime }}{\frac {B-C}{2}}{\frac {n^{\prime }\eta -m^{\prime }\zeta }{r}}\;ds^{\prime }}$, ${\displaystyle \beta ^{\prime }=\int _{0}^{s^{\prime }}{\frac {B-C}{2}}{\frac {l^{\prime }\zeta -n^{\prime }\xi }{r}}\,ds^{\prime }}$, ${\displaystyle \gamma ^{\prime }=\int _{0}^{s^{\prime }}{\frac {B-C}{2}}{\frac {m^{\prime }\xi -l^{\prime }\eta }{r}}\,ds^{\prime }}$,

(22)

where the integration is extended round the closed circuit ${\displaystyle s^{\prime }}$, we may write

Similarly

${\displaystyle {\frac {dX}{ds}}=m\gamma ^{\prime }-n\beta ^{\prime }}$. ${\displaystyle {\frac {dY}{ds}}=n\alpha ^{\prime }-l\gamma ^{\prime }}$, ${\displaystyle {\frac {dZ}{ds}}=l\beta ^{\prime }-m\alpha ^{\prime }}$.

(23)

The quantities ${\displaystyle \alpha ^{\prime }}$, ${\displaystyle \beta ^{\prime }}$, ${\displaystyle \gamma ^{\prime }}$ are sometimes called the determinants of the circuit ${\displaystyle s^{\prime }}$ referred to the point ${\displaystyle P}$. Their resultant is called by Ampère the directrix of the electrodynamic action.

It is evident from the equation, that the force whose components are ${\displaystyle {\frac {dX}{ds}}}$, ${\displaystyle {\frac {dY}{ds}}}$, and ${\displaystyle {\frac {dZ}{ds}}}$ is perpendicular both to ${\displaystyle ds}$ and to this directrix, and is represented numerically by the area of the parallelogram whose sides are ${\displaystyle ds}$ and the directrix.