19
and if we multiply the first by v, and the second by u, and subtract, we shall have
0=2uv−(u+v)rcosφ;
and ∴ v=urcosφ2u−rcosφ, or 1u+1v=2rcosφ,
and if we put 2f for r the expressions will be rather simpler,
v=ufcosφu−fcosφ, or 1u+1v=1fcosφ.
23. Here we may observe, that if u be infinite, that is, the incident rays parallel, we have simply v=fcosφ, which referred to the geometrical figure, shows that Aq is in that case one-fourth of the chord of the osculating circle so that if Ry be a tangent, and Qy perpendicular to it, calling Qy, p, we have in general
| 1u+1v=2dppdu, and v=pudu2udp−pdu | =du2dpp−duu |
| =dudlp2u. |
24. Prop. Given the radiant point, and the reflecting surface, to describe the caustic.
In order to determine the nature of the caustic curve, that is, the section of the superficial caustic, we may consider it as a spiral having Q for its pole.
Let Qx (Fig. 18.) be drawn perpendicular on Rq which is of course a tangent to the caustic at q. Call Qq, u′; and Qx, p′
| u′2 | =u2+v2−2uvcos2φ, |
| p′ | =usin2φ, |
| cosφ | =pu; ∴ cos2φ=2p2u2−1; sin2φ=2pu√1−p2u2; |
| ∴ u′2 | =u2+v2−2uv(2p2u2−1)=(u+v)2−4p2vu, |
