 |
Claims  |
|
|
It is claimed:
1. A diffraction device comprising a relief pattern in a surface of a
substrate, said pattern including at least one region having grooves of a
particular depth such that the intensity of light diffracted therefrom in
a narrow visible wavelength range is substantially zero at all viewing
angles throughout one diffractive order while the intensity of light
diffracted therefrom in other wavelengths is significantly greater than
zero at at least one viewing angle in the same diffractive order.
2. The diffraction device according to claim 1 wherein said surface relief
diffraction pattern includes a hologram.
3. The diffraction pattern according to claim 1 wherein said surface relief
diffraction pattern includes at least one other region adjacent to at
least said one region that includes grooves of a particular depth such
that the intensity of light diffracted in a wavelength other than said one
wavelength is substantially zero, while the intensity of light diffracted
therefrom in said one wavelength is significantly greater than zero.
4. A diffraction device according to claim 1 which additionally comprises a
carrier to which the diffraction device is attached, said carrier
including a device or information which is desired to be authenticated or
secured.
5. The diffraction device according to claim 4 wherein said carrier is
selected from the group of credit card, passport, identification card,
driver's license, and certificate.
6. A diffraction device as in claim 1, wherein said surface relief pattern
exists only on a single surface.
7. A diffraction device as in claim 6, wherein said diffraction device is
reproducable by embossing from a master created therefrom.
8. In a hologram having a diffraction pattern resulting from interference
between an object carrying wavefront and a coherent reference wavefront,
said object wavefront having a particular intensity distribution
thereacross according to the object characteristics, and said reference
wavefront having substantially no intensity variations thereacross, the
improvement wherein said diffraction pattern diffracts polychromatic light
incident thereon into at least one diffracted wavefront that reconstructs
therein an image of the object with at least a portion of said image
having a property of both substantially zero diffractive efficiency for
all viewing angles throughout one diffractive order in one narrow
wavelength range and significant diffractive efficiency for at least one
viewing angle in other wavelengths in the same diffractive order.
9. The hologram according to claim 8 wherein said diffraction pattern is
additionally characterized in that a copy made therefrom in monochromatic
light constructs said at least a portion of said image of said object
without said property.
10. A hologram as in claim 8, wherein said diffraction pattern is a surface
relief pattern that exists only on a single surface.
11. A hologram as in claim 10, wherein said diffraction pattern is
reproducable by embossing from a master created therefrom.
12. In a method of making a hologram that includes the steps of forming a
coherent object carrying wavefront, positioning a holographic recording
photosensitive medium in the path of said wavefront, directing a reference
wavefront coherent with said object wavefront onto said detector for
interference with said object wavefront, and processing the detector to
make a surface, the improvement comprising the steps of adjusting the
intensity of the object and reference wavefronts, and controlling the
processing of the holographic recording photosensitive medium, such that
the resulting hologram has a surface relief pattern or grooves in first
and second areas thereof that are each characterized by diffracting
substantially no light at all viewing angles throughout one diffractive
order in one wavelength and significant light into at least one viewing
angle in the same diffractive order in other wavelengths.
13. A method of making a hologram as in claim 12, wherein said surface
relief pattern exists only on a single surface.
14. A method of making a hologram as in claim 13, wherein the steps further
comprise:
creating a master with said surface relief pattern; and
embossing the master on a thermoplastic material to create the hologram
therefrom.
15. A carrier comprising an article or information which is desired to be
authenticated or secured, and a diffraction pattern or hologram device
attached thereto, said diffraction pattern or hologram device having been
constructed from the interference of two coherent light beams and
characterized by at least a portion thereof having a diffraction
efficiency for one narrow range of visible light wavelengths that is
substantially zero while having an efficiency that is significantly
non-zero for other visible light wavelengths, whereby a copy of said
diffraction pattern or hologram made with monochromatic light diffracted
by said device will not reproduce the same diffraction efficiency
variation at various wavelengths and thereby will be visually identifiable
as a copy.
16. The combination of claim 15 wherein the light intensity differences of
said diffraction pattern or hologram are contained in a single first order
diffracted beam.
17. The combination of claim 15 wherein the light diffraction intensity
differences of said diffraction pattern or hologram occur between
different diffracted orders.
18. The combination of claim 15 wherein said carrier is selected from the
group of credit card, passport, identification card, driver's license, and
certificate.
19. A diffraction pattern or hologram device of a type constructed from the
interference of two coherent light beams and especially adapted for
attachment to genuine documents and things to authenticate them,
comprising:
a first portion thereof having a diffraction efficiency that is
substantially zero at a first visible light wavelength range and having an
efficiency that is significantly non-zero for other visible light
wavelengths,
a second portion thereof adjacent said first portion and having a
diffraction efficiency that is substantially zero at a second visible
light wavelength range that is different from said first visible light
wavelength range and having an efficiency that is significantly non-zero
for visible light wavelengths other than said second wavelength range,
said device being characterized by reconstructing in polychromatic light an
image in a diffracted order that includes at least a spot that appears to
move between said first and second portions as the device is rotated to
view different colors of the diffraction, and
said device further being characterized in that a copy made of said
diffraction pattern or hologram with monochromatic light diffracted by
said device does not reproduce the same diffraction efficiency variation
at various wavelengths and thus does not reconstruct the moving spot when
viewed in polychromatic light, thereby enabling a non-genuine device to be
visually detected.
20. A method of authenticating an article, comprising the steps of:
attaching to said article a diffraction pattern or hologram device that has
been constructed in at least a portion thereof to have a substantially
zero diffraction efficiency in a given range of visible wavelengths while
having a significant non-zero diffraction efficiency in other visible
wavelengths, and which is characterized by diffracting incident white
light thereupon into at least one diffracted order, wherein said other
visible wavelengths are spatially separated across said order and said
given range of visible wavelengths is absent,
illuminating said diffraction pattern or hologram device with polychromatic
light, thereby to diffract such incident light into said at least one
diffracted order,
detecting the diffracted light by positioning a light detector in one of
said diffracted orders, and
providing relative motion between said detector and said diffraction
pattern or hologram device in a manner to detect the absence of said given
range of visible wavelengths and the presence of said other visible
wavelengths.
21. The method according to claim 20 wherein the detecting step comprises
positioning a human eye in said at least one diffracted order as the
detector.
22. The method according to claim 20 wherein said device has been so
constructed only in a portion thereof.
23. A method of authenticating an article, comprising the steps of:
attaching to said article a diffraction pattern or hologram device that has
been constructed in a first portion thereof to have a substantially zero
diffraction efficiency in a first given range of visible wavelengths while
having a significant non-zero diffraction efficiency in visible
wavelengths other than said first range, and in a second portion thereof
to have a substantially zero diffraction efficiency in a second given
range of visible wavelengths while having a significant non-zero
diffraction efficiency in visible wavelengths other than said second
range, said first and second ranges being distinct,
each of the first and second portions of said device further being
characterized by diffracting incident white light thereupon into at least
one diffracted order, the diffracted order from said first portion being
absent of said first range of wavelengths and the diffracted order from
said second portion being absent of said second range of wavelengths,
illuminating said device with polychromatic light, thereby to diffract such
incident light by both first and second portions of said device,
detecting the diffracted light by positioning a light detector in one of
said diffracted orders, and
providing relative motion between said detector and said device in a manner
to detect the absence of said first and second given ranges of visible
wavelengths of light diffracted from each of said first and second regions
of said device, respectively.
24. The method according to claim 23 wherein the detecting step comprises
positioning a human eye in said at least one diffracted order.
25. A copy protected device comprising:
a diffraction pattern which diffracts an incident polychromatic light into
bundles of light beams of different, angularly separated diffractive
orders, each said bundle of beams composed of angular separated beams,
each said beam corresponding to a color component of the incident
polychromatic light; and
means provided as at least a portion of said diffraction pattern for
substantially nulling the intensity of at least one of said diffracted
beams corresponding to one color component of a first or higher order
bundle of beams,
whereby a substantial null is observable along the angle corresponding to
said one color component, and not so for other angles corresponding to
other color components, whereas a copy of said diffraction pattern made in
monochromatic light will not have the same observable diffractive
attributes.
26. The diffraction device according to claim 25 wherein the recorded
diffraction pattern is additionally characterized by an intensity
distribution with at least one moving dark spot as said device is tilted
and wherein said diffraction pattern is further characterized by said copy
diffraction device having at least one dark spot which remains fixed as
the copy is tilted in white light.
27. The diffraction device according to claim 25 and additionally including
a carrier to which it is attached, said carrier containing information to
be authenticated.
28. The diffraction device according to claim 25 wherein said recorded
diffraction pattern includes a hologram.
29. A copy protected device as in claim 25, wherein said diffraction
pattern comprises a relief pattern or grooves in a surface of a substrate,
and said nulling means for said first or higher order beam of said color
component is effected by adjusting the groove depth.
30. A copy protected device as in claim 29, wherein said surface relief
pattern exists only on a single surface.
31. A copy protected device as in claim 30, wherein said surface relief
pattern is reproducable by embossing from a master created therefrom. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
BACKGROUND OF THE INVENTION
This invention relates generally to diffraction gratings and holograms,
especially those designed for use as security devices to authenticate
documents or objects to which they are attached.
Holograms are becoming widely used on credit cards as security devices to
authenticate genuine cards. Similar use of holograms is being made, or
proposed to be made, in authenticating certificates of various kinds, as
seals for containers to restrict unauthorized entry, and similar
applications. Currently, such holograms are embossed onto thin plastic
with a reflective layer added, the embossing hologram originally being
made in an optical laboratory with laser equipment. The plastic replicated
holograms are made of very thin material and attached to the credit card,
or other device being authenticated, in a manner that an attempted removal
of the hologram destroys it. This reduces the likelihood that holograms
for counterfeit documents can be removed from other expired or unused
cards or documents.
Holograms which reconstruct images of objects are a preferred form of
diffraction grating for security applications because they are harder to
make. The specialized skills and extensive equipment that is required to
make a hologram create a significant barrier for counterfeiters who
attempt to make original holograms from an object scene that resembles
that of the security hologram to be simulated.
Effort has been directed to making security holograms in which the object
scene is chosen such that any copies that might be made by counterfeiters
will not look exactly like the original. However, it is difficult to make
such a security hologram from which a copy of it can readily be
distinguished by the usual observer from the original. Therefore, it is a
primary object of the present invention to provide a diffraction grating
and hologram, and methods of making them, from which unauthorized copies
thereof are more readily apparent.
SUMMARY OF THE INVENTION
This and additional objects are accomplished by the various aspects of the
present invention, wherein, briefly, a diffraction grating, or hologram,
is made in a way that an image reconstructed from a copy is significantly
different from that reconstructed from the original, so copies can esily
be detected. One technique in making the original security grating, or
hologram, according to the present invention is to do so in a manner that
the image changes when the hologram, which is illuminated in polychromatic
light, is tilted with respect to the viewer and thus viewed in the
different colors of diffracted light. This security hologram is also made
so that copies from it do not show this changing image. For example, the
original grating or hologram can be made so that at least one dark region
moves across the diffracted light pattern or image as the grating or
hologram is tilted. A copy made in monochromatic light will, when
reconstructed in white light, show a fixed dark spot as the grating or
hologram is tilted, rather than a moving one, thereby being easily
detectable as a counterfeit.
A way of constructing such a security hlogram, according to the present
invention, is to take advantage of the fact that the diffraction intensity
characteristics of a grating or hologram are not a linear function of the
light intensity pattern recorded on it. The prevalent current approach is
to operate on a linear enough portion of such a characteristic curve that
reconstructed image degradations are kept within desired limits. But the
technique of the present invention intentionally operates on non-linear
portions of a grating or hologram characteristic curve so that an image
wavefront reconstructed from the copy is much different than that
reconstructed from the grating or hologram being copied for all but a
narrow range of reconstruction wavelengths.
Additional objects, advantages and features of the various aspects of the
present invention will become apparent from the following description of
its preferred embodiments, which description should be taken in
conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIGS. 1 and 2 show, as background, general existing techniques for making a
master optical hologram;
FIG. 3 illustrates the viewing characteristics of a typical existing type
of hologram that is replicated from that made according to the method
shown in FIGS. 1 and 2;
FIG. 4 illustrates characteristic curves of a diffraction grating or
hologram;
FIGS. 5 and 6 show an example of making a diffraction pattern using
characteristics illustrated in the curves of FIG. 4;
FIG. 7 shows an example of a diffraction pattern that was made according to
the method of FIGS. 5 and 6;
FIG. 8 illustrates one use of such a diffraction pattern;
FIGS. 9 and 10 show two typical methods that counterfeiters might use for
copying a hologram from a credit card and the like;
FIG. 11 shows the diffraction pattern of FIG. 7 that is obtained on such a
copy;
FIG. 12 illustrates schematically the effect of the diffraction
characteristics of an original and copy hologram;
FIG. 13 shows additional characteristic curves of a diffraction grating or
hologram; and
FIG. 14 illustrates the reconstruction of an image from a hologram made
according to yet another aspect of the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
The embodiment described herein is a surface relief hologram. In this
description, a diffraction grating is considered to be a special case of a
hologram. Both are formed by interfering two coherent light beams at a
photosensitive surface. The result in both is a surface that diffracts
light into one or more diffracted orders of varying colors when viewed in
white light. The difference for a hologram is that, during its
construction, one of the coherent beams used to make it can either pass
through, or be reflected from, an object scene before striking the
photosensitive surface. Such a hologram thus forms in its diffracted beams
an image of that object scene. A diffraction grating is made from a
controlled wavefront, such as a plane wave, so does not reconstruct an
image of a complex object. What is viewed in a diffracted beam from a
diffraction grating is either a uniform wavefront or a simply varying one.
Although specific diffraction grating security techniques are described
herein with respect to the figures, it will be understood that the more
complex holographic techniques are also within the scope of this
application.
Referring initially to FIGS. 1-3, well-known holographic techniques, and
the resulting holograms, will be generally described as background. If a
hologram is desired to be made of a three-dimensional diffusely reflecting
object 11, for example, that object is illuminated by coherent radiation
13, usually obtained from a laser. Light reflected from the object 11 in
an object beam 15 may be passed directly onto a photosensitive hologram
detector 17, or, more generally, is passed through an optical system 19
beforehand, and then onto the detector 17 as object beam 16. In either
case, a reference beam 21, coherent with the object illuminating beam 13,
is directed against the hologram detector 17 at a finite angle with the
object information carrying beam 16. The reference beam 21 is usually
unmodulated.
For a simple holographic grating, neither the object wave 11 nor the
optical system 19 need be used. Instead, an unmodulated plane wave is used
in place of object wave 16.
The hologram detector 17 is then processed to record a diffraction pattern
formed thereat by interference of the beams 16 and 21. This forms hologram
17' that is, in a second step illustrated in FIG. 2, illuminated by
reconstructing coherent radiation 22 in order to produce a replica 16' of
the recorded object image carrying beam 16. This replicated wavefront 16'
may, optionally, pass through an appropriate optical system to create the
information carrying beam 15' on a second hologram detector 25 that is
positioned therein at the location of a reconstructed real image 11' of
the original object 11. The wavefront 15' is captured on the detector 25
by directing a reference beam 27, that is coherent with the hologram
illuminating beam 22, against the holographic detector 25 at a finite
angle with the beam 15'.
FIGS. 1 and 2 show a rather generic, two-step hologram making process. The
hologram resulting from appropriate processing of detector 25 is capable
of reconstructing an image adjacent the surface of the hologram itself.
This is termed a "focused image" hologram and is the type that is most
commonly made for replicated holograms, including those used on credit
cards and the like. Alternatively, an image may be focused into the
hologram detector 17 by appropriate optics within the optical system 19,
in order to make a hologram according to the single step of FIG. 1 without
having to make the second hologram of FIG. 2. But the two-step process
shown in FIGS. 1 and 2 is preferred for quality and a large field of view.
The hologram detector 25 is most commonly made of a photoresist material
such that the interference pattern formed thereacross by interference
between the beams 15' and 27 is converted into a surface relief pattern
that refracts incident light into its various orders, although it is
optically clear thereacross. However, this is referred to herein as
"diffraction," as is commonly used in the holographic arts. The first
hologram 17 is often made from high resolution silver halide photographic
film, in a linear region, in order to form a high quality intensity
hologram.
The surface relief hologram has many advantages for inexpensive replication
since a metal master (not shown) can be made from it, and that metal
master is then used to emboss thin plastic foil with the surface relief
pattern. These embossed replicas are usually coated with a thin film of
reflective material so that a replica of the recorded wavefront is
reconstructed therefrom in reflected lght.
Referring to FIG. 3, such a hologram replica 29 is illustrated, from which
an image 11" is reconstructed therefrom when illuminated by white
(multicolored, non-coherent) light 31. An observer 33 sees the best image
when looking in a first order diffracted beam. A single such first order
diffracted beam is shown in FIG. 3, with a separation of colors that
exists. The observer 33 is shown to be positioned to view the image 11" in
a green portion 35 of the first order diffracted beam. By tilting the
hologram about an axis perpendicular to the paper, the observer 33 can
view the image in other colors, such as in a red portion 37 of the
diffracted beam, or, if tilted in an opposite direction, in a blue portion
39. The color spectrum is generally continuous, but only three color
components are being described for simplicity.
The hologram 29 is viewable in non-coherent, white light because its image
is reconstructed near the surface of the hologram and because of optical
elements used in the known optical system 19 and/or 23 of the master
making process shown in FIGS. 1 and 2. The most commonly used systems 19
and 23 also are designed to limit the bandwidth of the object wavefront
recorded on the master hologram 25 by discarding vertical parallax and
retaining horizontal parallax.
The curves of FIG. 4 illustrate the known diffraction efficiency
characteristics of a simple sinusoidal grating which results with the
construction of a hologram whose object is a plane wave. The making of a
simple security grating that takes advantage of these characteristics is
illustrated in FIGS. 5 and 6. An opaque mask 46 contains three adjacent
transparent regions 47, 49 and 51. The region 47 is optically clear, the
region 49 somewhat gray and the region 51 more gray. These regions are
illuminated by a plane wave coherent beam 50, in FIG. 6(A), and imaged by
a lens system 48 onto the hologram detector 25. The use of a planar
off-axis reference beam 52, coherent with the beam 50, forms the desired
diffraction pattern.
As a variation of the technique of FIG. 6(A), the mask 46 may be positioned
immediately adjacent the detector 25 and both the interfering coherent
wavefronts 50 and 52 passed through its regions 47, 49 and 51, as shown in
FIG. 6(B). In either case, the diffraction pattern so formed may be
replicated as a surface relief pattern to form a replica 29, as described
above.
On a horizontal axis of FIG. 4, which is specifically related to surface
relief hologram gratings, is the depth of the groove of the grating,
beginning at the left with zero depth (smooth surface). The vertical axis
indicates the percentage of light striking the grating that is diffracted
into a single first order diffracted beam. As is well known, some of the
incident light is diffracted into other orders or is reflected as a
zero-order beam. Also, as is well known, the curves of FIG. 4 are Bessel
functions, given the usual mathematical notation J.sub.1.sup.2. When white
(multicolored) light strikes such a simple grating, it is diffracted into
rays which are oriented according to the colors just as is illustrated in
FIG. 3 for the generalized hologram.
FIG. 4 illustrates exemplary characteristics of a portion of the replica 29
containing a grating made according to either FIGS. 6 (A) or (B), in the
separate colors chosen for illustration in FIG. 3. A curve 41 shows the
intensity characteristics of the blue portion 39 of the diffracted beam.
Similarly, a curve 43 shows that characteristic for the green portion 35
of the diffracted order, and curve 45 for the red portion 37.
The groove depth of the resulting diffraction pattern is controlled
primarily by two factors. One factor is the intensity of the light that is
recorded on the master hologram 25, and the other factor is the
post-exposure processing. For a general hologram, the first hologram 17
made in the existing process illustrated in FIGS. 1 and 2, is held on a
very linear portion its characteristic curve. When the second hologram 25
is made, the groove depth is usually increased in order to improve the
amount of light that is diffracted into an image carrying first order
beam. It is not unusual for groove depths to be selected for the
diffraction efficiency to extend to near the peak of the curves, such as
indicated at D2 for the blue curve 41. Some distortion is encountered when
operating in the region that includes slightly non-linear portions, but
this does not significantly degrade the quality of most focused image
holograms. Gratings are generally made with groove depths at the peak of
such curves in order to maximize the amount of incident light that is
diffracted into a first order beam. With diffraction gratings, of course,
there is not the concern for image distortion.
A principal aspect of the present invention is the intentional making of
holograms that operate well beyond the first path of its characteristic
Bessel function curve for a first order diffracted beam. The extremely
non-linear, low, and even zero, diffraction intensity efficiency
characteristics to the right of these peaks in the curves of FIG. 4,
avoided by traditional techniques, are intentionally utilized in order to
make a hologram that cannot be exactly replicated.
As a specific example of the inventive technique, consider a part of a
hologram 29 of FIG. 7 having three adjacent grating regions 47', 49' and
51' that have been made by one of the techniques of FIG. 6. In this
illustrative example, the area 47' is constructed to have a groove depth
substantially that indicated at D3 in FIG. 4. As can be seen, the amount
of light diffracted from that area into a blue component 39 of the first
order diffracted beam is zero, while there is some intensity in other
colors. Similarly, the adjacent area 49' is made to have a groove depth
substantially equal to D4 indicated on FIG. 4, thus having no light
diffracted in the green portion 35. Lastly, for this illustration, the
region 51' is made to have a depth substantially equal to D5 of FIG. 4,
thereby having substantially no intensity diffracted into the red
component 37 of the image carrying beam of FIG. 3, while having some
intensity that is viewable in the other color components 35 and 39. The
effect is thus that as a hologram 29 is rotated with respect to the
observer 23 about a horizontal axis (perpendicular to the surface of FIG.
3), a black spot appears to move across the portion of the image
containing areas 47', 49' and 51' as the diffraction beam sweeps through
the colors.
FIG. 8 illustrates generally the use of such a hologram 29, attached to a
carrier 53. The carrier 53 can be a credit card, for example, or a
passport, identification card, driver's license, stock certificate, and
the like. The purpose of the hologram 29 is to authenticate the carrier 53
and any information carried on it. By rotation of the carrier 53 above the
horizontal axis, a black spot appears to move across the hologram portions
47', 49' and 51', a part of a larger image 11".
The reason that the non-conventional hologram 29 is useful is that a copy
made in monochromatic light from it will not reproduce the moving spot.
Therefore, copies can be readily identified. This is explained with
respect to FIGS. 9-11. FIG. 9 shows a one typical way of copying a
replicated hologram. The hologram 29 is illuminated by a coherent light
beam 55 to form a diffracted beam 57 that is captured on an intermediate
holographic detector 59 by use of an off-axis reference beam 61. Processed
hologram 59' is then played back by a coherent reconstruction beam 63 to
record on another hologram detector 65 a first order diffracted beam 67.
The detector 65 is positioned to coincide with the image 69 reconstructed
in the first order beam 67 so that it will be a replica of the focused
image hologram 29. That image is recorded by a coherent, off-axis
reference beam 71.
The known copying technique of FIG. 9 is generally preferred since only a
single diffracted order of light is captured on the hologram detector 59
of FIG. 9(A) and 65 of FIG. 9(B). A different technique, termed contact
copying, is illustrated in FIG. 10 and is somewhat simpler. The hologram
29 is placed immediately adjacent to a holographic copy detector 73. A
coherent light beam 75 is then passed through the hologram 29. All of the
orders diffracted by the hologram 29 are thus captured on the detector 73,
along with the zero diffracted order (that is, the undiffracted portion of
the light beam 75 passes directly through the hologram 29). All of these
diffracted orders interfere among themselves to create extra and unwanted
image terms. Also, the zero order beam, which serves as the reference, is
not of uniform intensity across it by the time it strikes the detector 73.
Therefore, images reconstructed from a contact copy are generally of
poorer quality than those made of the technique of FIG. 9.
It will be recognized that both FIGS. 9 and 10 assume that the hologram 29
allows reconstructing light to pass through it. With a metallized, plastic
embossed hologram of the type now used for security applications, this
first requires neutralization or removal of the reflective coating.
However, the techniques of FIGS. 9 and 10 can be used to make a copy from
reflective holograms as well.
This discussion of copying is included herein for the purpose of
illustrating the additional security features of the hologram 29. This is
best illustrated by reference to FIG. 11 wherein a cross-section of a copy
hologram at the portions of the image corresponding to areas 47', 49' and
51' of the original hologram are illustrated as 47", 49" and 51". FIG.
11(A) shows such a replica made in blue coherent light. Only monochromatic
light can be used in making copies of the hologram if undesirable
distortion or blurring is to be prevented. The result of using this
standard copy technique on the hologram 29 in blue light means that the
region 47' of the hologram 29 that had zero diffraction intensity
efficiency in blue light is not recorded at all. The copy hologram
detector simply receives no light in the object beam from the region 47',
and so the replica illustrated in FIG. 11(A) is smooth in the
corresponding area. Similarly, FIG. 11(B) shows a replica made with green
monochromatic light, and FIG. 11(C) a replica in red. In any of these
cases, a portion of the information on the original hologram is not
copied, so the reconstructed image will not be the same. In this specific
example, the spot will not move as a hologram is tilted about a horizontal
axis.
FIG. 12 shows in a different, more general way, why the image reconstructed
from the copy hologram will be different from that originally recorded on
the original hologram. Each of the original and copied holograms are
indicated by a box in FIG. 12 with a given input/output transfer function.
The original optical signal "s" is recorded on the original hologram. The
first order diffracted signal reconstructed from it is,
J[(C/.lambda..sub.2)s],
which is then recorded on the copy hologram, where "C" is a constant, and
.lambda..sub.2 is the copy wavelength. The first order signal
reconstructed at wavelength .lambda..sub.3 from the copy, is,
J.sub.1 [(k/.lambda..sub.3)J.sub.1 [(C/.lambda..sub.2)s]],
where "k" is a constant. As the reconstruction wavelength .lambda..sub.3 of
the copy hologram is varied, the amplitude of the first order diffracted
light varies in a manner different than that of the original hologram.
That is, in general,
J.sub.1 [(C/.lambda..sub.3)s].noteq.J.sub.1 [(k/.lambda..sub.3)J.sub.1
[(C/.lambda..sub.2)s]]as the wavelength .lambda..sub.3 is varied. The
wavelength .lambda..sub.2 is fixed in the recording step of the copy. This
effect is particularly noticeable when extremely non-linear portions of
J.sub.1 in the original hologram are used.
As discussed above, it is a usual goal in making a surface phase hologram
to operate on a linear portion of the Bessel function curve. But in the
present invention, the original hologram is intentionally made in an
extremely non-linear portion of its characteristic curve so the signal
recorded on the copy hologram is the original signal with a non-linear
transfer function superimposed on it. Therefore, the optical signal
reconstructed from the copy will not be a faithful reproduction of the
original optical signal recorded.
Referring to FIG. 13, another first order Bessel function 81 is shown,
along with a second order function 83. That is, the curve 81 shows the
relative intensity of light diffracted into a first order beam, and the
curve 83 that diffracted into a second order beam. The second order
diffraction was not considered above, since it was assumed that the image
was being viewed in only a first order diffracted beam. But the existence
of a second order diffracted beam, in which a useful reconstruction of an
image may also be present, can also be used to implement the present
invention. A master hologram can be made with a particular geometry so
second, and even higher, diffracted orders are easily viewable, as well as
the first order. It will be noticed from FIG. 13 that the first order
curve 81 has a zero diffraction efficiency at a groove depth d1, and the
second order beam a zero diffraction efficiency at a different and deeper
groove depth d2. For the same reasons stated above, therefore, this allows
operation in those zero regions of the curves to produce the same result
when rotating a surface relief hologram 85 (FIG. 14) about a horizontal
axis. An observer alternately views an image 89 in a first order
diffracted beam 91 and then in a second order diffracted beam 93.
Alternative to operating in a region including zero diffraction
efficiency, operation in extreme non-linear regions of the curves of FIG.
13 also brings about the desired results.
While a hologram made in accordance with the techniques discussed above
with respect to FIGS. 13 and 14 cannot be copied by one of the methods of
FIGS. 9 or 10 in a manner to faithfully mimic the patterns in the original
hologram as the reconstructing wavelength is changed, it is possible to
make a copy in a different way that closely mimics the patterns of the
original at a single wavelength. This, however, is extremely difficult to
accomplish, thus still providing a hologram with good security. For
example, if all the orders are collected and used simultaneously as the
object beam of the copy hologram, additional cross-product terms will
result. This causes the relative intensities of the observed orders in the
copy to be different than that of the original. A second way to make a
copy includes individually recording, one at a time, all measurable orders
diffracted from the hologram 85 onto a linear photosensitive copy
detector. The laborious multiple holograms are recorded with low intensity
in order to operate on a linear portion of the copy detector's
characteristic curve and also to assure that extra terms of higher order
are to be avoided. The resulting images reconstructed from the copy are
thus very dim. Even so, specific changes in the original that occur with a
single wavelength will not be faithfully copied, for the reasons discussed
above with respect to FIGS. 4-11.
Although the various aspects of the present invention have been described
with respect to its preferred embodiments, it will be understood that the
invention is entitled to protection within the full scope of the appended
claims. Specifically, it should be understood that the method is not
limited to holographic diffraction gratings but can be used with much more
complex holographic imagery.
* * * * *
|
|
|
|
|
|
|
Description |
|
