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Claims  |
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What is claimed is:
1. In a test system comprising a Fizeau spherical or plano wavefront
interferometer, said interferometer comprising a source of light for
providing a wavefront, a plano or spherical test surface, an optical
element located in said wavefront and having a reference surface normal to
said wavefront, said reference surface comprising a last surface with
respect to the direction of said wavefront, said reference surface
producing a reflected reference wavefront and a transmitted test wavefront
which is directed at a common center of curvature of said reference
surface and said plano or spherical test surface, said test wavefront
interacting with said test surface and being returned from said test
surface by reflection back through said reference surface, and means for
interfering said reflected wavefront and reflected test wavefront for
producing two beam interference fringes; the improvement comprising a
partially reflective, partially absorbtive, partially transmissive beam
splitting coating on said reference surface, said coating having a fixed
reflectivity and transmittance such that there will be only two beam
interference and the contrast of said two beam interference fringes is
substantially equalized with respect to said test surface reflectivity.
2. An improved system in accordance with claim 1 wherein said coating is
such that said contrast is substantially equalized at the two extremes of
said test surface reflectivity.
3. An improved system in accordance with claim 2 wherein said source of
light is a laser.
4. An improved system in accordance with claim 3 wherein said system
comprises means for testing a full reflectivity range of said plano or
spherical test surface.
5. An improved system in accordance with claim 4 wherein said full
reflectivity range comprises from 4% to 100%.
6. An improved system in accordance with claim 3 wherein said means for
passing said light through said optical element comprises means for
passing said light through said optical element as an expanded beam.
7. An improved system in accordance with claim 6 wherein said transmitted
test wavefront comprises a transmitted converging, diverging or plano test
wavefront.
8. An improved system in accordance with claim 7 wherein said reference
surface is everywhere normal to said wavefront.
9. An improved system in accordance with claim 8 wherein said coating has a
transmittance T determined by
T={R.sub.r /[R.sub.t(max) R.sub.t(min) ].sup.1/2 }.sup.1/2
where R.sub.r is said reference surface reflectivity and R.sub.t(max) and
R.sub.t(min) are respectively, the maximum and minimum expected test
surface reflectivity.
10. An improved system in accordance with claim 3 wherein said coating has
a transmittance T determined by
T={R.sub.r /[R.sub.t(max) R.sub.t(min) ].sup.1/2 }.sup.1/2
where R.sub.r is said reference surface reflectivity and R.sub.t(max) and
R.sub.t(min) are respectively, the maximum and minimum expected test
surface reflectivity.
11. An improved system in accordance with claim 1 wherein said source of
light is a laser.
12. An improved system in accordance with claim 11 wherein said coating has
a transmittance T determined by
T={R.sub.r /[R.sub.t(max) R.sub.t(min) ].sup.1/2 }.sup.1/2
where R.sub.r is said reference surface reflectivity and R.sub.t(max) and
R.sub.t(min) are respectively, the maximum and minimum expected test
surface reflectivity.
13. An improved system in accordance with claim 1 wherein said coating has
a transmittance T determined by
T={R.sub.r /[R.sub.t(max) R.sub.t(min) ].sup.1/2 }.sup.1/2
where R.sub.r is said reference surface reflectivity and R.sub.t(max) and
R.sub.t(min) are respectively, the maximum and minimum expected test
surface reflectivity.
14. An improved system in accordance with claim 10 wherein said means for
passing said light through said optical element comprises means for
passing said light through said optical element as an expanded beam.
15. An improved system in accordance with claim 13 wherein said reference
surface is everywhere normal to said wavefront.
16. An improved system in accordance with claim 1 wherein said reference
surface is everywhere normal to said wavefront.
17. An improved system in accordance with claim 16 wherein said source of
light is a laser.
18. An improved system in accordance with claim 1 wherein said coating is a
metallic or semi-metallic optical coating.
19. An improved system in accordance with claim 18 wherein said source of
light is a laser.
20. An improved system in accordance with claim 13 wherein said contrast is
represented by C and is defined in terms of said test surface and said
reference surface reflectivity by the expression
C=2T(R.sub.r R.sub.t).sup.1/2 /(R.sub.r +T.sup.2 R.sub.t)
where R.sub.t is said test surface reflectivity. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a coating and method useful for the
interferometric measurement of plano and spherical wavefront producing
optical surfaces and systems. More particularly, the invention relates to
the application of a partially absorbtive metallic or semi-metallic
optical coating which is applied to the reference surface of a spherical
or plano wavefront Fizeau interferometer to produce high contrast two-beam
interference fringes for any test surface or system reflectivity.
2. The Prior Art
The development of the laser and advances in vacuum coating technology have
greatly expanded the utility of classical interferometers. The Fizeau
interferometer, in particular, has become an extremely convenient and
flexible instrument for a wide variety of optical metrology applications.
Nevertheless, a conspicuous shortcoming of the laser Fizeau interferometer
has been in testing high reflectivity optical surfaces and systems which
produce plano and spherical wavefronts. With the recent developments in
phase measurement interferometry where high contrast, two-beam
interference fringes are required to simplify the data analysis, this is
especially germane, see M. Schaham, Proceedings SPIE, Vol. 306, pp.
183-191 (1981). A multiple-beam spherical wavefront Fizeau interferometer
is discussed in detail by Heintze et al. in Applied Optics, Vol. 6, p.
1924 (November, 1967). The major difficulties with the interferometer
discussed by Heintze et al. are: (1) the partially transmissive coating on
the spherical reference surface must be selected to match closely the
reflectivity of the test surface or system to achieve useful contrast.
Therefore, a number of these expensive surfaces is required to handle a
range of test surface or system reflectivity, and (2) a field lens which
matches each test surface or system is required, and (3) multiple-beam
interference fringes are produced, thereby excluding fringe analysis using
phase measurement interferometry. A multiple-beam plano wavefront Fizeau
interferometer has similar difficulties as mentioned for the multiple-beam
spherical wavefront Fizeau interferometer with the exception that a field
lens is not required. Another method is to use the Fizeau interferometer
together with a thin coated pellicle placed into the interferometer
cavity, i.e., the space between the reference surface and the test surface
or system, having a transmission determined by the test surface or system
reflectivity, see Hunter and Forman, U.S. Pat. No. 3,998,553 issued Dec.
21, 1976. The difficulties with this method are: (1) locating the pellicle
in the interferometer cavity limits the proximity to which a test surface
or system can be positioned relative to the reference surface. This
severely limits the range of test surface or system surface curvatures
that can be tested, and (2) the pellicle itself is expensive, delicate,
and easily damaged, and (3) the introduction of the pellicle into the
interferometer cavity in the presence of a strongly convergent or
divergent measurement beam has the effect of introducing significant
wavefront errors which seriously degrade the measurement accuracy of the
interferometer, and (4) usually more than one pellicle is required for the
full range of test surface or system reflectivity, and (5) the back
reflections from the pellicle surface can produce spurious fringes or
cause severe reductions in fringe contrast requiring the pellicle to be
tilted with respect to the interferometer optical axis limiting still
further the volume between the reference surface and the test surface or
system.
Other types of interferometry are used to test high reflectivity optical
surfaces and systems. For example, scatter plate interferometers and
shearing-type interferometers are two prominent prior-art techniques.
However, these interferometers are not only difficult to use and align,
but they are also considerably less versatile than the Fizeau
interferometer. The Twyman-Green two-beam interferometer, while being able
to measure the full range of optical surface and system reflectivity
without any additional surfaces in the interferometer cavity or any
specialized coating on the reference surface, other than one to match the
test surface or system reflectivity, has the disadvantage of being more
complex and expensive. That is, following the beamsplitting surface, any
optical surface or element in either arm of the interferometer up to and
including the reference surface must be of high optical quality, whereas
in the Fizeau interferometer, only the reference surface must be of high
optical quality. Also, the interferometer cavity in a Twyman-Green
interferometer is inherently longer than a Fizeau interferometer cavity
and thus more susceptible to environmental noise.
While these prior-art techniques are useful for some applications, they
cannot be used in those optical metrology applications requiring both
phase measurement interferometry and a small separation between the
reference surface and test surface or system. To this end, a coating and
method are required for testing the full reflectivity range of expected
optical surfaces and systems without the limitations of the
above-mentioned prior-art.
SUMMARY OF THE INVENTION
In accordance with the instant invention, I test a full reflectivity range,
i.e., from 4% to 100%, of optical surfaces and systems by modifying a
standard Fizeau spherical or plano wavefront interferometer consisting of
(1) a source of light, most preferably a laser (2) means for passing said
light, as an expanded beam, through (3) an optical element located in the
wavefront whose last surface, the reference surface, is everywhere normal
to the wavefront which has (4) a partially reflective, partially
absorbtive, and partially transmissive beamsplitting coating applied to
the plano or spherical reference surface to produce a reflected reference
wavefront and a transmitted converging, diverging or plano test wavefront,
which is directed at (4) a common center of curvature of the reference
surface and the plano or spherical test surface or system (5) said test
wavefront then interacts with the test surface or system and is returned
from the test surface or system by reflection back through the reference
surface and (6) means for interfering the reflected reference wavefront
and reflected test wavefront; the invention consists of the application of
a partially reflective and partially absorbtive optical coating onto the
reference surface which has a transmittance T determined by
T={R.sub.r /[R.sub.t(max) R.sub.t(min) ].sup.1/2 }.sup.1/2
where R.sub.r is the reference surface reflectivity and R.sub.t(max) and
R.sub.t(min) are respectively, the maximum and minimum expected test
surface or system reflectivity. If the reference surface coating is chosen
such that the above relationship is adhered to, then there will be only
two beam interference and the contrast of the two-beam fringes will be
equalized at the two extremes of the test surface or system reflectivity
R.sub.t(max) and R.sub.t(min).
THE DRAWINGS
In the drawings,
FIG. 1 is a schematic of a spherical wavefront Fizeau interferometer with
the addition of a pellicle into the interferometer cavity--i.e., the prior
art.
FIG. 2 is a schematic of a spherical wavefront Fizeau interferometer with
the absorbtive beamsplitting coating of the instant invention on the
reference surface.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows the layout of a typical Fizeau two-beam spherical wavefront
interferometer. A light source, most preferably a laset (2) provides
radiation. The output laser beam (4) is focused by lens (6) to produce the
converging spherical wavefront (8) which after passing through focus
emerges as diverging spherical wavefront (8) and is then reflected by
beamsplitter (10). The beam reflected from the beamsplitter (10), the
diverging spherical wavefront (12), is converted to a converging spherical
wavefront (16) by lens (14). Lenses (6) and (14) serve to expand the
diameter of the output laser beam (4). Element (18) is an aplanatic
element located in wavefront (16). Element (18) has a non-refracting,
spherical reference surface (20). Reference surface (20) has a fixed
reflectivity of about 4% and a transmission of about 96% assuming an
element (18) substrate of glass or fused silica. The wavefront produced by
the reflection of wavefront (16) from reference surface (20) is the
reference wavefront (25R), the wavefront transmitted by surface (20), is
the converging spherical test wavefront (22). The test wavefront (22) is
transmitted through a thin, partially transmissive plastic pellicle (34)
coated with a partially transmissive coating where it reflects from the
high reflectivity test surface (28) to become diverging wavefront (23).
Diverging wavefront (23) is transmitted through the thin, partially
transmissive plastic pellicle (34) and the reference surface (20) to
become the test wavefront (25T). The diverging test wavefront (25T) and
reference wavefront (25R) are transformed into converging spherical
wavefronts (27R) and (27T) by lens (14) where the interference of the
wavefronts (27R) and (27T) is viewed at interference plane (30).
FIG. 2 is a schematic of a spherical wavefront Fizeau interferometer useful
for testing the full reflectivity range of optical surfaces and systems
which is the preferred embodiment of the invention.
Referring to FIG. 2, the significant differences from the interferometer of
FIG. 1 are (a) the application of a partially reflective, partially
absorbtive, and partially transmissive reference surface beamsplitting
coating (19) in lieu of the thin, partially transmissive plastic pellicle
(34), and (b) the reference surface beamsplitting coating (19) has a fixed
reflectivity R.sub.r and transmittance T determined by the relation
T={R.sub.r /[R.sub.t(max) R.sub.t(min) ].sup.1/2 }.sup.1/2
where R.sub.t(max) and R.sub.t(min) are respectively, the maximum and
minimum expected test surface or system reflectivity, and (c) the
reference surface beamsplitting coating (19) suppresses any reflection off
the reference surface (20) from the incident diverging wavefront (23)
causing essentially two-beam interference to occur. If the reference
surface beamsplitting coating (19) is chosen such that the above
relationship is adhered to, then the contrast of the two-beam fringes will
be equalized at the two extremes of test surface or system reflectivity
R.sub.t(max) and R.sub.t(min). The fringe contrast C can be defined in
terms of test surface or system and reference surface reflectivity as
follows:
C=2T(R.sub.r R.sub.t).sup.1/2 /(R.sub.r +T.sup.2 R.sub.t)
where R.sub.t is the test surface or system reflectivity. In fact, the
fringe contrast C will typically be about 75% at the two extremes of test
surface or system reflectivity for two-beam interference fringes when the
reference surface reflectivity R.sub.r is about 10% and the test surface
or system reflectivity R.sub.t is either 4% or 100% for a transmittance T
of about 70%. The fringe contrast C increases for any test surface or
system reflectivity between the two extremes of 4% and 100% and reaches
100% for test surface or system reflectivity approaching 20%. Because
maximum fringe contrast is not critical during an interferometric
measurement and a fringe contrast of 70% is more than adequate for most
measurement accuracy needs, a reference surface coating with a given
transmittance T can suffice for a very broad range of test surface or
system reflectivity. Better fringe contrast at the test surface or system
reflectivity extremes is obtained by sub-dividing the test surface or
system reflectivity range so that more than one coated reference surface,
each with a different transmittance T, is optimized for this smaller test
surface or system reflectivity range. Any number of test surface or system
reflectivity increments can be chosen and coatings designed which would
maximize fringe contrast across any test surface or system reflectivity
range.
The advantages of the instant invention arise from the application of a
test and reference wavefront splitting absorbtive coating to the reference
surface to maximize fringe contrast over any test surface or system
reflectivity range. This coating suppresses multiple-beam interference by
eliminating the reflection off the reference surface of the beam returning
from the test surface or system to produce essentially two-beam
interference fringes necessary for accurate automatic phase measurement
interferometry. The instant invention does this without an additional
absorbtive or reflective element in the interferometer cavity. The
increased reflectivity of the reference surface, typically 10%, results in
(1) a more light efficient interferometer when compared to one having a
reference surface whose substrate is uncoated glass and (2) the
intercavity medium need not be air, but can be oil, water, etc., which
provides the ability to make very high resolution, high accuracy
interferometric measurements.
The specific embodiments of the invention disclosed herein can, of course,
be changed without departing from the invention, which is defined in the
claims.
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Description |
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