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Claims  |
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What is claimed is:
1. A holographic data storage medium, comprising:
a support structure comprising an optically transmissive planar substrate;
a plurality of holographic storage regions formed on said support
structure, said storage regions formed from a photosensitive photopolymer
material, each of said storage regions having an incident face for
receiving reference and data laser beams for the Read/Write operation
within said storage region and a diametrically opposed face disposed
proximate to said planar substrate and for allowing said reference and
data laser beams to exit said storage region, each of said storage regions
fabricated from a material that is operable to store pages of data in the
form of interference gratings; and
a matrix wells formed in a planar isolating layer, which said isolating
layer is disposed on the surface of said substrate, each of said wells
extending through said isolating layer and for containing said holographic
storage regions and for isolating select ones of said storage regions from
each other.
2. The data storage media of claim 1, wherein the portion of said isolating
layer between each of said wells is operable to optically isolate said
select ones of said storage regions from each other.
3. The data storage media of claim 1, and further comprising an optically
transmissive capping layer for being disposed on the surface of said
isolating layer diametrically opposite said planar substrate, said capping
layer for containing said photopolymer material.
4. The data storage media of claim 1, wherein the portion of said planar
isolating layer between said wells comprises non polymerizable regions of
said photopolymer material, wherein said non-polymerizable regions are at
a substantially complete polymerized state, with said storage regions
being polymerized to a level consistent with the data stored therein.
5. The data storage media of claim 4, and further comprising an optically
transmissive capping layer for being disposed on the surface of said non
polymerizable regions and said storage regions proximate to said incident
face of said storage regions for containing said photopolymer material of
said storage regions.
6. The data storage media of claim 4, wherein said storage regions and said
non polymerizable regions are formed from a common layer of photopolymer
material.
7. The data storage means of claim 1, wherein said material from which said
holographic storage regions are formed comprises a viscous gel material.
8. The data storage media of claim 1, wherein the portion of said planar
isolating layer between said wells has an index of refraction relative to
said storage regions that will cause internal reflections to occur in said
storage regions.
9. The data storage media of claim 1, wherein the portion of said isolation
layer between said wells is operable to chemically isolate said select
ones of said storage regions from each other.
10. A holographic data storage system, comprising:
a coherent light source;
a beam splitter for splitting the light beam output by said light source
into a data beam and a reference beam;
a write device for encoding data onto said data beam;
a steering device for directing said reference beam to intersect said data
beam and cause an interference grating at said intersection;
a holographic storage medium having a recording surface disposed at the
plane of said intersection of said reference and data beams; lo said
steering device operable to steer said intersection to a select location
on the surface of said storage medium; and
said holographic storage medium comprising:
a support structure comprising an optically transmissive planar substrate,
a plurality of holographic storage regions formed on said support
structure, said storage regions formed from a photosensitive photopolymer
material, each of said storage regions having an incident face for
receiving reference and data laser beams for the Read/Write operation
within said storage region and a diametrically opposed face disposed
proximate to said planar substrate and for allowing said reference and
data laser beams to exit said storage region, each of said storage regions
fabricated from the material that is operable to store pages of data in
the form of interference gratings, and
a matrix of wells formed in a planar isolating layer, which said isolating
layer is disposed on the surface of said substrate, each of said wells
extending through said isolating layer and for containing said holographic
storage regions and for isolating select ones of said storage regions from
each other.
11. The data storage system of claim 10, wherein the portion of said planar
isolating layer between said wells comprises a plurality of
non-polymerizable regions of said photopolymer material, wherein said
non-polymerizable regions are at a substantially complete polymerized
state, with said storage regions being polymerized to a level consistent
with the data stored therein.
12. The data storage media of claim 11, and further comprising an optically
transmissive capping layer for being disposed on the surface of said
non-polymerizable regions and said storage regions proximate to said
incident face of said storage regions for containing said photopolymer
material of said storage regions.
13. A method for fabricating a holographic data storage medium, comprising
the steps of:
providing a support structure comprised of an optically transmissive planar
substrate;
forming a plurality of storage regions on the planar substrate, the storage
regions fabricated from a photosensitive photopolymer material, each of
the storage regions having an incident face for receiving reference and
data laser beams for the read/write operation within the storage region
and a diametrically opposite face disposed proximate to the surface of the
planar substrate and allowing the reference and data streams to exit the
storage region, each of the storage regions fabricated from a material
that is operable to store pages of data in the form of interference
grating; and
isolating select ones of the storage regions from each other by forming a
matrix of wells in a planar isolating layer and disposing the planar
isolating layer on the surface of the planar substrate, each of the wells
extending through the planar isolating layer and operable to contain the
holographic storage regions, each of the wells surrounding the associated
one of the holographic storage regions.
14. The method of claim 13, wherein the step of isolating comprises
chemically isolating select ones of the storage regions from each other
with the matrix of wells.
15. The method of claim 14, wherein the step of isolating comprises
optically isolating select ones of the storage regions from each other
with the matrix of wells.
16. The method of claim 13, and further comprising disposing an optically
transmissive capping layer on the upper surface of the isolating layer
diametrically opposite the planar substrate, the capping layer for
containing the photopolymer material.
17. The method of claim 13, wherein the the portion of the isolating layer
between the wells comprises non-polymerizable regions of the photopolymer
material formed on the surface of the support structure, wherein the
non-polymerizable regions are at a substantially complete polymerized
state, with the storage regions being polymerized to a level consistent
with the data stored therein. |
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Claims |
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Description |
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TECHNICAL FIELD OF THE INVENTION
The present invention pertains in general to holographic memories and, more
particularly, to the storage media and the technique for increasing the
density of storage regions on the storage media.
CROSS REFERENCE TO RELATED APPLICATIONS
This application is related to U.S. patent application Ser. No. 091,311 now
U.S. Pat. No. 5,377,176 issued Dec. 27, 1994, filed concurrent herewith,
and entitled "Method and Apparatus for Phase Encoding Data Storage Regions
in a Thick Holographic Storage Media" (Atty. Dkt. No. TAMA-21,889).
BACKGROUND OF THE INVENTION
As the need for increased data storage changes, the search for higher
density, faster access memory technologies also increases. One of these,
holographic data storage, provides the promise for increased access to
higher density data. The techniques for realizing such storage typically
utilize some type of storage media, such as photorefractive crystals or
photopolymer layers, to store 3-D "stacks" of data in the form of pages of
data. Typically, coherent light beams from lasers are utilized to perform
the addressing, writing and reading of the data from the storage media by
directing these beams at a specific region on the surface of the media.
Writing is achieved by remembering the interference pattern formed by
these beams at this region. Reading is achieved by detecting a
reconstructed light beam as it exits the storage medium, the data then
being extracted therefrom. Addressing is achieved by the positioning of
the laser beams, and this is typically done through the mechanical
movement of mirrors or lenses; however, the storage media itself can be
moved relative to fixed laser beams.
One of the limiting aspects to the density of storage in the storage media
is the physical separation between storage areas. A storage area or region
is typically defined by the intersecting diameters of two beams. When
these beams impinge upon a given area, the data is stored within the
intersecting or overlapping area of the two beams and contained within the
underlying structure of the media. The useful recording portion of the
media is therefore confined to the overlap area. However, in actuality,
parts of each beam will spread out beyond the overlap area. This will
expose the media with useless information. Further, the overlap area may
contain too much information and could be made smaller, such that it may
be desirable to clip or aperture the overlap area. Therefore, some type of
guard ring or region is desirable between storage regions.
Another aspect to be considered when dealing with adjacent regions in media
such as photopolymer materials, is the diffusion of monomers within the
media. Whenever one region is subjected to a Write operation, there will
be some migration of monomers in the material, this being necessary to
obtain contrast in the recording. Ideally, it would be desirable to
locally confine this migration to the area of the recording. However,
since the material is relatively homogenous and all regions are
contiguous, migration of monomers can occur between recording regions.
SUMMARY OF THE INVENTION
The present invention disclosed and claimed herein discloses a holographic
data storage media. The data storage media comprises a support structure
on which a plurality of holographic storage regions are formed. Each of
the storage regions has an incident face for receiving reference and data
laser beams for Read/Write operations in the storage regions. Further,
each of the storage regions is fabricated from a photo or light sensitive
material that is operable to store pages of data in the form of
interference gratings. An isolation structure is provided for optically
isolating select ones of the storage regions from each other.
In another aspect of the present invention, the storage regions are
fabricated from a photosensitive photopolymer material. The support
structure comprises a planar substrate or a parallel pair of planar
substrates that are optically transmissive. The isolation structure
comprises a matrix of optically isolating structures disposed on the
surface of the support structure. In one embodiment, the isolation
structure comprises a layer of material in which wells are formed that
extend through the layer. The wells define the bounds of the storage
regions and contain the photopolymer material of the storage regions. In
the case of a single planar substrate support structure, a capping layer
is disposed over the surface proximate to the incident face of the storage
regions, wherein the support structure substrate is disposed proximate to
the diametrically opposite face thereof.
In a further aspect of the present invention, the support structure is
comprised of a plurality of pre-polymerized regions of the photopolymer
material. The pre-polymerized regions are in a substantially complete
polymerized state compared with the storage regions, which are at a
polymerized state consistent with the data stored therein. The
pre-polymerized regions form boundaries for each of the storage regions
and prevent migration between the storage regions and also provide optical
isolation therebetween. Further, the pre-polymerized regions and the
storage regions are fabricated from a common layer of photopolymer
material.
BRIEF DESCRIPTION OF THE DRAWINGS
For a more complete understanding of the present invention and the
advantages thereof, reference is now made to the following description
taken in conjunction with the accompanying Drawings in which:
FIG. 1 illustrates an overall block diagram of a holographic storage
assembly;
FIG. 1a illustrates a detail of the recording media;
FIG. 2 illustrates an exploded view of one embodiment of the present
invention illustrating the perforated structure that forms the isolation
structure in which photopolymer material is disposed, the perforations
defining the recording regions;
FIG. 3 illustrates a cross-sectional view of the structure of FIG. 2 after
assembly thereof and with a data beam and a reference beam impinging on
the surface thereof;
FIG. 3a illustrates a top view of one of the regions showing the spread of
the beams beyond the overlapping record region;
FIGS. 4a and 4b illustrate the intensity of the beams as a function of the
distance across the regions;
FIGS. 5a and 5b illustrate one method for forming the assembled structure
illustrated in FIG. 2;
FIG. 6 illustrates an alternate embodiment of a method for isolating
regions in a photopolymer storage media; and
FIG. 7 illustrates a method for manufacturing the media structure of FIG.
6.
DETAILED DESCRIPTION OF THE INVENTION
Referring now to FIG. 1, there is illustrated a holographic storage
assembly which is operable to store data in a transparent holographic
storage recording media 10 and extract that data therefrom. The data is
organized in the recording media as an array of stacks of pages 11
(images). This is illustrated in FIG. 1a, wherein each of the stacks of
pages 11 occupies a small region 54 of the recording media 10, with each
of the pages in each of the regions 54 comprising an interference grating,
all of the interference gratings in a given region 54 superimposed over
each other. A laser 12 is provided, which can be comprised of, for
example, a diode-pumped YAG (yttrium aluminum garnet) laser with a power
output of around 80 milliwatts, with a wavelength in the range of 532
nanometers. The output beam of the laser is processed by a stack-selector
assembly 14 which steers the beam to the location of an individual stack
of pages 11 in the recording media 10. The output of the stack selector
assembly 14 is then passed to a beam splitter 18 which separates the beam
into two beams, a data beam 20 and a reference beam 22.
The data beam 20 is expanded by a beam expander 24 which is then input to a
Spatial Light Modulator (SLM) 26 to output an expanded data beam 28. The
SLM 26 receives data from a computer system (not shown) and then this data
is superimposed on the expanded data beam 28 by the SLM 26, creating a bit
pattern of light and dark spots in the conventional manner. This pattern
of spots represents the bits on the page to be stored. After the SLM 26,
the data beam is then passed through a focusing system 30 which then
focuses the beam onto a select portion of the surface of the holographic
storage media 10. This focused data beam 39 is the Fourier transform of
the pattern of spots, or page.
The reference beam 22 is reflected from a mirror 32 and then passed through
a polarization rotator 34, the polarization orientation dictated by an
external control signal. This rotator is utilized to adjust the
polarization of the reference beam 22 during a read operation. The output
of the polarization rotator 34 is then input to a page addressing
deflector system 36 system which defines the angle at which the reference
beam will impinge the surface of the recording media 10 and also the
location thereof on the surface of the recording media 10. This is
represented by a deflected reference beam 38.
As the two beams, the data beam and the reference beam, enter the recording
media 10, the reference beam interferes with the data beam, writing an
interference grating in the storage media 10. In the case of a
photorefractive material, the grating pattern results from a stored
electronic-charge pattern that modifies the optical properties of the
crystallite. In the case of photopolymer material, certain areas of the
photopolymer material are polymerized to form the interference grating.
The result is a 3-D holographic image of the Fourier transform of the bit
pattern carried in the data beam. This stored interference grating allows
the original data beam to be recreated when the system reads the data.
This process on which the interference grating is formed on the recording
media 10 is basically the Write process for a holographic storage
material.
The Write process is repeated a number of times, with the angle of the
reference beam operable to be changed each time, to record a plurality of
interference gratings. Each of the interference gratings is associated
with a different input bit pattern, which interference gratings are
superimposed over each other. This collection of superimposed recordings
is called a stack. The recordings that comprise each of the stacks are
angularly multiplexed within each of the stacks.
During a Read cycle, the data beam is shut off so that only the deflected
reference beam 38 is input to the storage media 10 at the appropriate
angle and location. The angle is determined by the desired page in that
particular stack. The deflected reference beam 38 will be constructively
diffracted by the interference grating that was recorded with a particular
underlying spatial frequency that corresponds to the deflected reference
beams particular angle. This results in a reconstructed image of the
original bit pattern that stored there with a reference beam with that
particular angle. The diffracted reference beam 39 or reconstructed data
beam then passes through the storage media 10 into a focusing system 40
which focuses the reconstructed image onto the surface of a detector array
42 of, for example, a charge-coupled device that captures the
reconstructed light and dark bit patterns of the image and then convert
them back to digital electronic signals for transfer to a computer. This
is represented by a data output line 44.
Referring now to FIG. 2, there is illustrated an exploded view of one
embodiment of the storage media 10. The storage media of FIG. 2 utilizes a
photopolymer, which photopolymer is a material that undergoes
photo-induced polymerization. These compositions have been used to form
conventional holograms. These are typically fabricated from a viscous or
gelatin-like composition which is photo-reactive. When two laser beams
intersect in this composition to set up an interference pattern, this
causes selective polymerization within the material. These compositions
typically contain a polymeric binder, a liquid ethylinically unsaturated
monomer and a photoinitiator system. Typically, the layer of viscous or
gelatin-like recording material is spun or web coated onto a substrate
such as glass to provide a thin coating of approximately 20 microns. A
capping layer of material such as Mylar.RTM. is then disposed over the
gelatin layer. This provides a relatively good optical surface on the
upper surface of the gelatin layer, and the glass substrate provides a
high quality optical surface on the bottom surface of the gelatin-like
recording layer.
Returning to FIG. 2, an optically transmissive substrate 48 is provided
over which an optically isolating perforated structural member 50 is
disposed. The structural member 50 has a plurality of defined openings or
wells 52 disposed therein, which wells 52 contain data storage regions 54.
Each of the data storage regions 54 is separated from the other data
storage region 54 by a predetermined distance. The structural member 50 is
fabricated from a non-polymerizable material which is approximately 20
microns thick. In the preferred embodiment, the wells 52 are circular
regions which are approximately equal to the diameter of the laser beam
that impinges on the surface when reading or writing data to the storage
media. The wells 52 are each operable to receive a storage area 54 of
photopolymer material. An upper capping layer of Mylar.RTM. 56 is
provided.
Referring now to FIG. 3, there is illustrated a cross-sectional diagram of
the assembled structure of FIG. 2. It can be seen that each of the wells
52 is arranged to hold photopolymer material that forms the data storage
regions 54. The photopolymer material is therefore confined within the
wells 52 and separated from adjacent storage regions 54 by the portion of
the structure 50 that separates the wells 52. This is represented by the
space 58 between each of the photopolymer material storage regions 54.
When the data beam 39 and reference beam 38 are properly adjusted, they
will impinge upon the surface and be aligned with respect to the surface
of a select one of the photopolymer storage regions 54. This results in a
number of benefits. First, the light is confined within the regions, since
the index of refraction of the structure 50 and the photopolymer material
in the isolated storage regions 54 is different. Second, since the
isolated regions 54 are not in contact, monomer diffusion between regions
is reduced. Thirdly, an increased structural rigidity is provided for a
given region 54 such that a thicker layer of photopolymer can be
accommodated. In general, with a large monolithic surface area layer, the
thickness of the photopolymer must be limited due to the instability of
the material, since it is in a gelatin state. However, the spacers 58
provide isolation and reduce the fluid motion of the polymer to
accommodate a thicker layer, it being noted that the photopolymer material
is a viscous material.
Referring now to FIG. 3a, there is illustrated a top view of one of the
isolated storage regions 54. Although illustrated as a perfect cylindrical
beam in FIG. 3, the data beam 39 and reference beam 38 are not perfect
cylinders. Rather, the light energy is distributed in an uneven pattern
across each of the data and reference beams. The reference beam is
typically round and the other, the data beam, representing a transform,
which for the typical data patterns stored in the recording media being
somewhat star shaped. This results in "bleed areas" 60 and 61 that exist
outside of the isolated storage region 54 and the perimeter of the well
52. For relatively thick media, this can result in light scattering in
other regions 54 and corrupting the data therein and wasting the recording
dynamic range of the adjacent regions 54. This is especially so as the
angle of incidence of the laser beam varies for addressing different pages
of information. By providing the isolated storage regions 54, the
scattering of light between adjacent data storage regions 54 is also
minimized.
Referring now to FIG. 4a, there is illustrated a curve representing the
distribution of light energy across the beam. FIG. 4a illustrates the
distribution across the reference beam 38, which distribution is generally
a Gaussian distribution. It can be seen that a large part of the energy is
disposed within the region having a diameter represented by "d". The
portion outside of the diameter is relatively low energy and does not
intersect with the data beam. However, this low energy light, although not
utilized to form the interference grating in the storage region 54 or read
the interference grating therefrom, can corrupt data in the other regions
54 during the Write operation, or provide extraneous noise during the Read
operation.
Referring now to FIG. 4b, there is illustrated a curve representing the
distribution of light energy in the data beam 39. It can be seen that the
distribution is more complex due to the pattern that is encoded and the
transform nature of the data beam 39. However, the major portion of the
light energy is disposed within the main diameter "d" of the beam and,
thus, within the isolated storage region 54. Any light energy that occurs
outside of the intersection of the data beam 39 and the reference beam 38
comprises the light energy in the bleed regions 60 and 61. The structure
of the embodiment of FIGS. 2-3 contains the light energy and reduces the
effect of this bleed region 60 on adjacent regions 54 such that the
distance between regions 54 can be reduced.
Referring now to FIGS. 5a and 5b, there is illustrated one method for
forming the structures of FIG. 2 and FIG. 3. Initially, the substrate 48,
which in the preferred embodiment comprises a glass substrate, has the
structural member 50 with the wells 52 disposed therein attached to its
upper surface. The structural member 50 is fabricated in one of multiple
ways. One method for fabricating this material would be to provide an
optically opaque layer of material, such as a tinted Mylar.RTM. layer or
some similar plastic material, and then form the openings 52 with a laser,
which would form the wells 52 therein. Further, the wells 52 could be
mechanically perforated. The wells 52 have a dimension of approximately
one millimeter, whereas the thickness of the structural member 50 is
approximately 20 microns.
After the structural member 50 is disposed on the surface of the substrate
48, a layer of the photopolymer material in its gelatin state is disposed
on the surface applied to the substrate by a "screed" operation.
Alternatively, the photopolymer material could be spun onto the surface
forming a conformal coat. The conformal coat would then have the upper
surface thereof scraped away to have only portions of the photopolymer
material spun into the wells 52. Thereafter, the capping layer 56 of
Mylar.RTM. is disposed over the surface. However, any optical material
that provides high quality optical properties could be utilized as the
capping layer 56. The only purpose of the substrate 48 and the capping
layer 56 is to provide containment by a transparent optical surface.
Referring now to FIG. 6, there is illustrated a second embodiment for
forming isolated regions. The substrate 48 first has layer of photopolymer
material disposed thereon which has isolated regions 64 defined therein by
forming walls of polymerized photopolymer material 62 therebetween. The
walls 62 define square isolated storage regions 64 therebetween. The walls
62 can be fabricated of a separate structural material, but in the
embodiment of FIG. 6 in the preferred mode, they are formed by optically
polymerizing the material, such that a slight structural advantage is
provided but chemical isolation is also provided in the form of a
non-polymerizable region. This impedes monomer migration between adjacent
recording regions in the recording media. Since the region containing the
walls 62 are polymerized, the migration of monomers between region 64
cannot occur. The capping layer 56 is then disposed on the upper surface.
Referring now to FIG. 7, there is illustrated a cross-sectional diagram of
a process utilized for forming the polymerized wall 62. A template 66,
having selectively disposed holes 68 defining a pattern, is disposed on
the upper surface of the capping layer 56. The upper surface of the
template 66 is then exposed to saturate the storage media between the
layers 48 and 56 with sufficient light to saturate that exposed portion.
This will then completely polymerize the exposed portion, forming the
layer 62. Although a rectangular structure is illustrated, any pattern
could be formed, depending upon the pattern of the openings 68 in the
template 66. The template 66 could be a mechanical template, as
illustrated in FIG. 7 or it could be a photoresist layer.
In summary, there have been provided methods and apparatus for forming a
holographic storage media with selected storage regions disposed thereon
in an isolated manner. Regions within the storage media are physically
isolated by placing barriers between the regions. In one embodiment, an
opaque structure is disposed on a transparent substrate to define wells. A
photopolymer material is disposed within the wells and then a capping
layer disposed over the structure. The wells define the storage regions.
In another technique, walls are formed within the photopolymer material by
complete polymerization of select regions. This defines selected regions.
Although preferred embodiments have been described in detail, it should be
understood that various changes, substitutions and alterations can be made
therein without departing from the spirit and scope of the invention as
defined by the appended claims.
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