page 300 note ^* v. Review, p. 309.

page 300 note ^† When γ is zero, P ₄ is a constant and the system is telescopic, the formulae being of the type

The optical relation found as in § 2 is then

page 300 note ^‡ Thus we exclude immersion-objectives for microscopes, but we include any ordinary microscope, telescope or photographic lens.

page 301 note ^* For if we restrict our work to rays lying in a plane through the axis, that plane can be taken as the plane of zx; then the incident ray will be such that y =0, m=0, and thus the terms containing y and m will be missing from the formula found for x′.

page 301 note ^† The “first order aberrations” are derived from the six terms of the second order in Φ; and there are five independent aberrations (see Dr. Steward’s Tract, pp. 30-32).

page 302 note ^* In fact, if we eliminate the ratio x′: x we find that, for consistency, we must have

and if we multiply the first equation of (13) by (AC—B ²), it will be found to agree with the equation just found. When AC=B ², we obtain the telescopic case; this presents no fresh point of difficulty, but details are left to the reader.

page 302 note ^† In general, the reader will have no difficulty in seeing that c = a²μ′/μ, if the refractive indices are taken as μ, μ′: and that, in the usual phraseology of Optics, this is equivalent to the statement that the two focal lengths are in the same ratio as μ: μ′. In the present case −a is the focal length, as ordinarily defined; while, allowing for μ and μ′, −a is the first focal length and −aμ′ is the second, c being equal to their product.

page 302 note ^‡ Thus our problem corresponds to the image of a star in a telescope; or (for ordinary purposes) to the image formed on a plate by a photographic lens.

page 303 note ^* Review, p. 309.