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Description  |
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FIELD OF THE INVENTION
The present invention relates generally to holographic storage devices and
more particularly to a method for addressing holograms stored in a
plurality of separate storage media by directing a reference beam to a
selected one of the storage media, focusing the reference beam so as to
obtain a substantially flat wavefront within a reference beam plane of the
selected storage medium, and varying the angle of the reference beam so as
to address a selected hologram stored therein, the selected hologram being
readout as a result of such addressing.
BACKGROUND OF THE INVENTION
Holographic techniques for storing images are well known. Such techniques
are commonly used to store images of three dimensional objects in a wide
variety of different applications. Additionally, various methodologies for
utilizing such holographic techniques to store digital data for use in
computer systems are currently being explored.
The technique for forming holograms comprises splitting the highly coherent
output beam of a laser into separate reference and object beams. The
reference beam is directed onto the holographic storage medium, e.g., a
photorefractive material, while the object beam is directed onto the
object whose image is to be stored. Light reflected from the object is
directed to the photorefractive material wherein an interference pattern
is formed via interference of the reference beam with the reflected light
of the object beam. In the case of digital data storage, the object beam
may pass through an optical modulator rather than being reflected off the
object whose image is to be stored.
Subsequently, directing a reference beam onto the holographic storage
medium results in the reconstruction of an image representative of the
originally illuminated object or digital data.
Also known are techniques for storing a plurality of such images within a
single photorefractive medium via angle-multiplexing of the images. Such
angle-multiplexing is discussed in "THEORY OF OPTICAL INFORMATION STORAGE
IN SOLIDS," Applied Optics, Vol. 2, No. 4, p. 393 (1963). The method of
angle-multiplexing generally involves maintaining a constant angle for the
object beam, while varying the angle of the reference beam for each
exposure. Anglemultiplexing thus allows a large number of holographic
images to be stored within a common volume of photorefractive medium,
thereby greatly enhancing the storage density thereof.
In order to provide increased total storage capacity, it is, in general,
desirable to utilize multiple holographic storage modules, wherein each
storage module comprises a separate storage medium. The use of such
multiple storage modules, however, presents technical problems which must
be overcome in order to make such construction feasible. One problem
commonly associated with the use of multiple storage modules is the
ability to quickly and accurately address the desired hologram stored
within the storage medium of a selected storage module. Not only must the
reference beam be directed to the selected storage medium, but the
reference beam must be directed thereto in a manner which provides a
sufficiently flat wavefront within the reference beam plane of the
selected storage medium to avoid inadvertent, partial recall of other
holograms stored within said storage medium.
The degree of flatness required is determined by the angular separation
between adjacent multiplexed holograms as discussed in detail below.
As such, it is desirable to provide a means for addressing a plurality of
different storage modules and means for adjusting the wavefront flatness
of the addressing reference beam, preferably automatically, each time a
different storage module is addressed.
SUMMARY OF THE INVENTION
The present invention specifically addresses and alleviates the
above-mentioned deficiencies with the prior art. More particularly, the
present invention comprises a method for addressing holograms stored in a
plurality of distinct storage media. The method comprises the steps of
directing a reference beam to a selected one of a plurality of storage
media, focusing the reference beam so as to obtain a sufficiently flat
wavefront within a reference beam plane of the selected storage medium,
and varying the angle of the reference beam so as to address a selected
hologram stored therein. The selected hologram is read-out as a result of
such addressing.
Preferably, the reference beam is focused via a lens disposed upon a
translation stage. Preferably, the hologram being read-out or
reconstructed object beam, is monitored and servo control is utilized so
as to effect such focusing of the reference beam via the translation
stage.
Optionally, data specifying the position of the translation stage for each
different storage medium is stored in a memory. Reading the stored data
and moving the translation stage to the indicated position results in at
least coarse focusing of the reference beam for that particular storage
medium.
The reference beam is preferably directed to a selected one of the
plurality of different storage media by aligning the polarization of the
reference beam such that the reference beam is reflected by a polarizing
beam splitter toward the selected storage medium. The reference beam is
otherwise transmitted by the beam splitter, such as when a different
storage medium is selected.
These, as well as other advantages of the present invention will be more
apparent from the following description and drawings. It is understood
that changes in the specific structure shown and described may within the
scope of the claims without departing from the spirit of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic representation of a modularized volume-holographic
memory comprising a plurality of different storage media as well as the
optical system for effecting auto-focus and addressing of selected
holograms stored within selected storage media; and
FIG. 2 is a schematic representation of a single storage medium showing the
formation of beam waists associated with each of the reference beams
reflected into the storage media via a cube beam splitter array.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The detailed description set forth below in connection with the appended
drawings is intended as a description of the presently preferred
embodiment of the invention, and is not intended to represent the only
form in which the present invention may be constructed or utilized. The
description sets forth the functions and sequence of steps for
constructing and operating the invention in connection with the
illustrated embodiment. It is to be understood, however, that the same or
equivalent functions and sequences may be accomplished by different
embodiments that are also intended to be encompassed within the spirit and
scope of the invention.
The present invention provides a means for generating a well-collimated
laser reference beam within any one of N (an integer) holographic storage
modules. Together, the N modules comprise a larger holographic memory.
Precise and real-time adjustment of reference beam collimation is provided
so as to achieve physical interchangability of the N modules.
The reference beam auto-focus apparatus for a modularized
volume-holographic memory of the present invention is illustrated in FIGS.
1 and 2, which depict a presently preferred embodiment of the invention.
Referring now to FIG. 1, the present invention is comprised generally of a
plurality of different storage media or modules such as 10, 12, and 14. As
shown, the separate storage media 10, 12, 14 are spaced apart from one
another. Reference beam optics direct a reference beam to a selected one
of the storage media, focus the reference beam so as to obtain a maximally
flat wave front within a reference beam plane of the selected storage
medium, and vary the angle of the reference beam so as to address a
desired hologram stored therein. Thus, the selected hologram is read-out
as a result of such addressing.
More particularly, the focusing lens FL.sub.1 is disposed upon translation
stage 50 such that movement of translation stage 50 back and forth in the
indicated direction, i.e., along the optical axis of focusing lens
FL.sub.1, effects focusing of the reference beam so as to obtain a
substantially flat wave front within a reference beam plane of the
selected storage medium.
Means for effecting angular positioning of the reference beam relative to
the optical axis of FL.sub.1 are preferably disposed prior to FL.sub.1
within the optical path of the reference beam. Those skilled in the art
will recognize that various such means are suitable for effecting angular
positioning of the reference beam. An acousto-optic Bragg cell 49 as shown
is one example of such an angular positioning means.
Focusing lens FL.sub.1 focuses the collimated laser reference beam,
nominally to a point, at P.sub.1, from which the reference beam is
directed through first polarization rotator PR.sub.1. The polarization
rotator PR.sub.1 may, for example, comprise a liquid crystal material
capable of rotating the polarization plane of the reference signal in
response to an electrical input.
After passing through the polarization rotator PR.sub.1 the reference beam
is incident upon polarizing beam splitter PBS.sub.1.
The combination of the polarization rotator PR.sub.1 and the polarizing
beam splitter PBS.sub.1 define a switch for directing the reference beam
either toward the first storage module 10 or alternatively on to other
such polarization rotator/polarizing beam splitter pairs which can
similarly be switched so as to direct the reference beam to a desired
storage module.
Any hologram within any one of the N holographic storage modules of the
memory of FIG. 1 can be precisely addressed by translating focusing lens
FL.sub.1 in the .+-.Y direction. Holographic storage module "n" (n=1, 2, .
. . , N) is precisely addressed when the reference beam wavefront is flat,
to within a certain tolerance to be specified, within reference beam plane
RP.sub.n of the selected module. The degree of flatness (in optical
wavelengths) is determined by the angular separation between multiplexed
holograms. For example, if the length of a module is L, as shown in FIG.
1, the optical wave length is .lambda., and the angular separation between
muliplexed holograms is defined as .DELTA..phi., then the flatness
tolerance is:
.DELTA.f=(L/.lambda.) tan (.DELTA..phi.).
For L=3 cm, .DELTA..phi.=0.01.degree., and .phi.=488 nm, .DELTA.f=10.7
optical wavelengths. Given typical optical tolerances, .DELTA.f is
difficult to maintain for reasonably sized memories (N greater than
approximately 3), unless provision is made to adjust or minimize .DELTA.f
each time a different storage module is addressed. Focusing lens FL.sub.1
performs this adjusting function.
As shown in FIG. 1, the second (n=2) holographic storage module 12
contained within an N-module memory (n=1, 2, . . . , N) has been selected
and may be precisely addressed by adjusting the position of focusing lens
FL.sub.1. As discussed above, the second holographic storage module 12 is
selected by adjusting polarization rotator PR.sub.2 so as to cause the
reference beam to reflect from polarizing beam splitter PBS2 toward the
second storage module 12.
Referring now to FIG. 2, the combination of spherical lens CL.sub.2 and
Cube Beam Splitter Array CBSA.sub.2 generates "M" reference beam waists
within Storage Module 2, where M is the number of elements of CBSA.sub.2
(M=4 in FIG. 1). For a given L (length of one of the holographic storage
modules) and M, the focal length of CL.sub.n (which is nominally set equal
to d.sub.1 +d.sub.2 for all n) is selected such that the greatest
distance, 1.sub.MAX, between Reference Plane RP.sub.2 and Beam Waist "1"
or "M" is less than or equal to .DELTA.f.multidot..lambda..
For typical, i.e., economical, optical elements, .DELTA.f cannot be
maintained within tolerance for all storage modules simultaneously, if all
elements of the module addressing optics are fixed in position. By
attaching Focusing Lens FL.sub.1 to a translation stage, however, .DELTA.f
may be minimized in real time in order to address precisely any one of the
N modules shown in FIG. 1.
Different holograms within a given storage module are individually
addressed by adjusting the angle at which the collimated laser beam is
incident on FL.sub.1. Real-time, closed-loop adjustment of the position of
FL.sub.1 in the .+-.Y direction, is achieved by monitoring a portion of an
object beam (Object Beam (2) in the example shown in FIG. 1) addressed by
the incident reference beam (Reference Beam Array (2) in the example shown
in FIG. 1). The object beam is preferably monitored via hologram monitor
43. Thus, by maximizing the intensity of a portion of said object beam,
.DELTA.f is minimized by servoing the translation stage upon which
FL.sub.1 is attached. Such servoing is preferably effected via servo
control 45. By this means all holograms within all storage modules may be
optimized in real-time.
Coarse minimization of .DELTA.f for each module may be achieved by
pre-storing translation stage positions within a digital memory 47.
It is understood that the exemplary reference beam auto-focus apparatus for
modularized volume-holographic memory shown herein and shown in the
drawings represents only a presently preferred embodiment of the present
invention. Indeed, various modifications and additions may be made to such
embodiment without departing from the spirit and scope of the invention.
For example, as those skilled in the art will appreciate, various
different optical components may be substituted for those illustrated and
described. Thus, various lenses, mirrors, etc., may be incorporated,
depending upon the particular geometry of the system.
Thus, these and other modifications and additions may be obvious to those
skilled in the art and may be adapted for use in a variety of different
applications.
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