of a person's death (now “ obituary ”). An “ obit ” was also a service performed at a funeral or in commemoration of a dead person, particularly the founder or benefactor of a church, college or other institution, hence “ obit-days,” “obit Sunday,” &c. A “ post-obit ” is a bond given as a security for the repayment of money lent upon the death of a person from whom the borrower has expectations (see Bond).
OBITER DICTUM, that which is said by the way or in passing (Lat. ob, by, and iter, road); specifically, in law, an opinion expressed by a judge incidentally in the course of a case, on a point of law not necessarily connected with the issue or not forming part of the grounds of the decision; such obiter dicta
have no binding authority.
OBJECT and SUBJECT, in philosophy, the terms used to denote respectively the external world and consciousness. The term “ object ” (from Lat. ob, over against, and jacere, to throw) is used generally in philosophy for that in which an activity of the mind ends, or towards which it is directed. With these may be compared the ordinary uses of the term for “ thing ”
simply, or for that after which one strives, or at which one aims. “ Subject,” literally that which is “ thrown under ” (sub), is originally the material or content of a discussion or thought,
but in philosophy is used for the thought or the thinking person.
The relation between the thinking subject and the object thought
is analogous to the grammatical antithesis of the same terms:
the “ subject ” of a verb is the person or thing from which the
action proceeds, while the “ object,” direct or indirect, is the
person or thing affected. The true relation between mind or
thought (subject) and matter or extension (object) is the chief
problem of philosophy, and may be investigated from various
standpoints (see Psychology and Metaphysics). It should
be observed that the philosophical use of “ subject ” is precisely
the opposite of the common use. In ordinary language the
“ subject ” of discussion, of a poem, of a work of art, is that
which the speaker, author or artist treats.
OBJECTIVE, or OBJECT GLASS, the lens of any optical system which first receives the light from the object viewed; in a
compound system the rays subsequently traverse the eye-piece.
The theoretical investigations upon which the construction of
an optical system having specified properties is based, are treated
in the article ABERRATION, and, from another standpoint, in
the article DIFFRACTION. Here we deal with the methods by
which the theoretical deductions are employed by the practical
optician. It should be noted that the mathematical calculations
provide data which are really only approximations, and
consequently it is often found that a system constructed on such
data requires modification before it fulfils the practical requirements.
For example, take the case of a photographic objective.
Calculations of the paths of two extreme rays in the meridional
section of an oblique pencil of large aperture may prove that the
rays intersect on a. plane containing the axial focus, but similar
calculations of many other rays would be necessary before the
mean point of intersection could be settled with sufficient
exactness. Suppose, however, that the optician has accurately
realized the results of the mathematician, he can then determine
the divergence of the practical from the theoretical properties
by measuring the positions and conformation of the most distinct
or mean foci, and, if sufficiently acquainted with the theory of
the construction, he can modify one or more curvatures or thicknesses
and so attain to a closer agreement with the ideal. Theory
and practice co-operate in the realization of an original system.
The order is not always the same, but generally the mathematician,
by notoriously laborious calculations, supplies data
which are at first closely followed by the constructor and afterwards
modified in accordance with experimental observations.
In addition to the problem of constructing an original system,
the optician has to deal with the reproduction of a realized system
in different sizes. Two questions then arise: (1) To what
degree of accuracy the radii of curvature can, or should, be repeated,
and (2) to what degree of uniformity the surfaces can,
or should be figured. With regard to the first point there is
no great difficulty in working the requisite iron or brass tools
of any curvature to within an error of -11;;th% of the radius;
male and female templets being used for very deep curves, and
the spherometer for tools of longer radii (by appropriate grinding
together, the radii are alterable at will within narrow, but
sufficient, limits). The accuracy attained in the grinding,
however, is open to very perceptible modincation by the subsequent
polishing and figuring processes. This is particularly
undesirable in the case of deep curves and large apertures. A
variation in a radius of curvature may occasion a little spherical
aberration at the axial focus, but if the amount be small it
may be neutralized by imparting to the lens a parabolic form
or its opposite. Such an artifice is frequently adopted in
correcting large telescope objectives.
With optical systems which transmit large pencils with considerable obliquity (such as wide angle photographic objectives) the curves are very deep, and a departure from the true radius which would be tolerated in a telescope cannot be permitted here. Such lenses are usually tested by means of a master curve worked in glass. The master curve is fitted to the experimental lens, and an inspection of the interference fringes shows the quality of the fit-whether it be perfect, or too shallow or too deep. The Workman then modifies his polisher or stroke in order to correct the divergence. Flat surfaces are tested similarly. This test by contact has been strongly advocated and has been regarded as sufficient to detect all irregularities of any moment. This claim, however, is not justified, for the test is not sensitive to errors sufficient in amount to render a telescope objective almost valueless; but such errors are easily discernible by other optical devices. In general, accuracy in the radii of curvature is of primary importance and trueness of figuring is of secondary importance in photographic objectives, while the reverse holds with telescopic objectives; in wide angle microscopic objectives these two conditions are of equal moment. Eye pieces do not require the same degree of accuracy either in the curvature or the figuring.
A rough idea of the exactitude to which the figuring of the finest telescope objectives must be carried out is readily deduced. If two slips of paper, bearing printed letters £5 of an in. high be placed in almost exact alignment, one 31-2 in. from the eye and the other 39 in., and viewedvin moderate daylight with the eye having a papillary aperture of 8 of an in., one set of the letters will be legible while the other is not. In this case the difference of convergence or refracting power exercised by the eye in transferring its focus from one slip to the other is ig; or one quarter diopter. If an image on the retina is } diopter out of focus, then each point of the object is represented by a circle of confusion 0-0004 in. or 2' 45" in an ular measure in diameter, the focal length of the eye being assumecf to be 0-5 in. and the papillary aperture § of an in. If the effective aperture of the pupil or the aperture of a pencil traversing the pu il be I/nth of this standard, the size of the disk of confusion will ge the same (viz. 0-0004 in.) if the retinal image be n quarter diopters out of focus. In general, for a constant 'size of the circle of confusion or, in other words, the same amount of visual blurring, the apertures of the pencils traversing the pupil and the focus sing errors (expressed in quarter diopters) vary inversely.
If a portion of a figured surface of a telescope objective differs in curvature from the major portion of the lens so as to form a circle of confusion on the retina of a diameter not less than 2' 45", it is dear that the lens is faulty, the image formed by the perfect portion being sharp and well defined, and that formed by the imperfect portion blurred to the extent above determined, and to a greater extent if we allow for the effect of diffraction in the formation of the image. For example, a protuberance I in. in diameter at the centre of an object glass of 12 in. aperture refracting to a separate focus would theoretically form a spurious disk of about 5 seconds diameter, which would subtend a diameter of 50 minutes at the retina under a power of 600. .
Regarding 2' 45” as the maximum diameter of 'a geometric circle of confusion permissible in a telescopic object glass, we proceed to determine the heights of the protuberance or depression which causes it. If f be the equivalent focal length of the eye-piece and- F that of the objective (the back focal length in the case of the microscope), then the linear error at the focus of the eye-pieceis 3 ld", or, expressed as a variation of 1/F, Th(f/F)2, (=A%). If a lens has one side plane and is worked to a mathematically sharp edge, its thickness t at the centre is (approximately) A2/8r, where A is the whole aperture and r the radius; and if g be the equivalent focal length and pm the refractive index, we may write r =§ (l#- I) and obtain
- =A=/8z(u-1) . (1).5
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