Classifications

• • G—PHYSICS
  • G11—INFORMATION STORAGE
  • G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
  • G11B7/00—Recording or reproducing by optical means, e.g. recording using a thermal beam of optical radiation by modifying optical properties or the physical structure, reproducing using an optical beam at lower power by sensing optical properties; Record carriers therefor
  • G11B7/004—Recording, reproducing or erasing methods; Read, write or erase circuits therefor
  • G11B7/0065—Recording, reproducing or erasing by using optical interference patterns, e.g. holograms
• • G—PHYSICS
  • G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
  • G03H—HOLOGRAPHIC PROCESSES OR APPARATUS
  • G03H1/00—Holographic processes or apparatus using light, infrared or ultraviolet waves for obtaining holograms or for obtaining an image from them; Details peculiar thereto
  • G03H1/22—Processes or apparatus for obtaining an optical image from holograms
• • G—PHYSICS
  • G11—INFORMATION STORAGE
  • G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
  • G11B7/00—Recording or reproducing by optical means, e.g. recording using a thermal beam of optical radiation by modifying optical properties or the physical structure, reproducing using an optical beam at lower power by sensing optical properties; Record carriers therefor
  • G11B7/08—Disposition or mounting of heads or light sources relatively to record carriers
  • G11B7/083—Disposition or mounting of heads or light sources relatively to record carriers relative to record carriers storing information in the form of optical interference patterns, e.g. holograms
• • G—PHYSICS
  • G11—INFORMATION STORAGE
  • G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
  • G11B7/00—Recording or reproducing by optical means, e.g. recording using a thermal beam of optical radiation by modifying optical properties or the physical structure, reproducing using an optical beam at lower power by sensing optical properties; Record carriers therefor
  • G11B7/12—Heads, e.g. forming of the optical beam spot or modulation of the optical beam
  • G11B7/135—Means for guiding the beam from the source to the record carrier or from the record carrier to the detector
  • G11B7/1365—Separate or integrated refractive elements, e.g. wave plates
  • G11B7/1369—Active plates, e.g. liquid crystal panels or electrostrictive elements

Definitions

• Holographic storage system for reading a hologram stored on a holographic storage medium and a method carried out therewith
• the present invention relates to the reconstruction of holograms, in particular to a holographic storage system for reading a hologram stored on a holographic storage medium and a method carried out therewith.
• Holographic data storage is based on the concept of recording the interference pattern of a data- encoded signal beam (also referred to as an object beam) carrying the data and of a reference beam at a holographic storage medium.
• a spatial light modulator SLM
• the holographic storage medium can be for example a photopolymer or photorefractive crystal or any other material which is suitable for registering the relative amplitudes of, and phase differences between the object beam and the reference beam.
• a hologram is created in the storage medium, projecting the reference beam into the storage medium interacts and reconstructs the original data-encoded object beam, which can be detected by a detector such as a CCD-array camera or the like.
• the reconstructed data-encoded object beam is generally referred to in the art as the reconstructed hologram itself.
• reconstruction of a hologram means the reconstruction of the original data-encoded object beam; and reading of the hologram means detecting the reconstructed hologram, in particular an image of the reconstructed hologram. This terminology is adapted in the present specification.
• the writing of holograms is greatly influenced by the spatial overlap of the object beam and the reference beam, while hologram reading is strongly affected by the relative position of the reconstructing reference beam and the hologram stored in the storage medium.
• Reading of a holographic storage medium can be relatively easily achieved if both the reference beam and the object beam cover a relatively large spot on the surface of the storage medium.
• the tolerance of displacement between the centre of the hologram and the centre of the reference beam is approximately 10% of the size of the beam diameter, which is usually within the mechanical limits of conventional systems.
• decreasing the hologram size leads to a higher demand on alignment of the reference beam and the hologram when reading the medium.
• High-precision alignment can also be necessary for example, in case of multiplexing and/or security encrypting the stored holographic data.
• phase coded multiplexing and encrypting holograms there are many known methods of multiplexing and/or encrypting holograms. Such methods may involve phase coding the object beam and/or the reference beam both in the real and/or in the Fourier-plane.
• a method of, and device for, phase coded multiplexing and encrypting by phase coding the reference beam is disclosed in WO 02/05270 Al.
• phase coded multiplexing or encrypting When applying phase coded multiplexing or encrypting the tolerance of displacement between the centre of the reference beam and the hologram during reconstruction of the hologram can drop to 1% of the beam diameter.
• Misalignment of the beam and the hologram is generally associated with the misalignment of the optical components of the system, which can be due to mechanical shocks, temperature changes, etc. It is however a particular problem of systems designed to receive removable storage medium, for example holographic identification cards.
• US 7,116,626 Bl teaches a micro-positioning method to overcome the above identified problem of misalignment.
• the object of the described method is to increase the performance of a holographic storage system, i.e., the quality of the modulated image, by ensuring the correct alignment of various components of the system such as an SLM with various devices, such as light sources, lenses, detectors, and the storage medium.
• the alignment technique focuses on "pixel matching" that is aligning the pixels of a unique SLM used for data-encoding the object beam, the stored holographic image and the detector so that each pixel of the SLM is projected onto a single pixel of the detector resulting in better data recovering efficiency.
• the method involves physically moving all or some of the said components of the system with respect to each other.
• the means for displacing the said components can include micro-actuators. Such physical displacing means are expansive and complicated to apply in small devices.
• the object of the invention is to overcome the above problems by providing a system and method for enabling precise non-mechanical alignment of a reference beam with respect to a holographic storage medium.
• the above object is achieved by providing a holographic storage system according to claim 1 and a method of reading a hologram according to claim 15.
• Fig. Ia is a schematic view of an exemplary embodiment of a reflection type holographic storage system according to the invention.
• Fig. Ib is a schematic view of another exemplary embodiment of a transmission type holographic storage system according to the invention.
• Fig. Ic is a schematic view of an exemplary embodiment of a transmission type holographic storage medium reading and writing system according to the invention.
• Fig. 2 shows an exemplary reference beam code pattern generated by a spatial light modulator.
• Fig. 3 illustrates the shifting of the reference beam code pattern by one SLM pixel.
• Fig. 4 shows another exemplary reference beam code pattern generated by a spatial light modulator.
• Fig. Ia is a schematic view showing a first exemplary embodiment of a holographic storage system 1 according to the invention.
• the system 1 comprises a light source 2 providing a reference beam 3.
• the light source 2 generally consists of a laser and a beam expander.
• the light source 2 is followed by a spatial light modulator (SLM) 4 encoding the reference beam 3.
• SLM spatial light modulator
• the system 1 further comprises a detector 5 and means (not shown) arranged along an optical path of the reference beam for holding a holographic storage medium 6 carrying a hologram 7 to be read.
• the storage medium holding means can be any conventional medium-receiving component, such as a CD or DVD tray, a holographic identification card slot, or any other means suitable for keeping the storage medium 6 at a well-defined location within the holographic storage system 1.
• the detector 5 can be a CCD camera, a CMOS, a photodiode matrix or any other known detector type comprising sensor elements arranged in a pixel array.
• the hologram 7 is preferably a Fourier-hologram, due to its smaller sensitivity to surface defects of the storage medium than that of image plane holograms.
• the phase code pattern displayed by the SLM 4, used for phase-coding the reference beam 3 is imaged onto the Fourier-transform of an object beam when creating the hologram 7. Because of its good diffraction efficiency and low wavelength selectivity, e.g. a thin polarisation hologram can be used.
• Suitable holographic storage media are e.g. azo-benzene type photoanizotropic polymers.
• a beam splitter 10 which can be a neutral beam splitter or a polarisation beam splitter in case of polarisation holograms, or any other beam separation element such as a beam splitter cube with a central layer discontinuity, as disclosed in EP 1 492 095 A2.
• the SLM 4 is imaged into the plane of the hologram 7 by an imaging system.
• This imaging system comprises preferably a first and second Fourier lenses 11 and 12, arranged before and after the beam splitter 10 as known in the art.
• an aperture 13 can be interposed between the first Fourier lens 11 and the beam splitter 10 improving the imaging quality by limiting the diameter of the beam and providing the further advantage of restricting the definition of the SLM 4 as will be explained later on.
• the reference beam encoding is preferably phase coding to avoid information loss present at amplitude encoding, although amplitude encoding can be applied too, or any other known light modulation encoding (e.g. polarisation encoding, wavelength encoding).
• the phase code can be for example a security key for reading an encrypted hologram 7 or a key for reading a multiplexed hologram 7.
• the invention also relates to applications other than encryption or multiplexing.
• the SLM 4 can also be used as an aperture creating an easy to position circular reference beam 3. This is useful to reduce inter-hologram cross-talk at hologram reconstruction when multiple holograms 7 are written close to each other into the storage medium 6.
• the reference beam 3 When reading the hologram 7 of the storage medium 6, the reference beam 3 needs to be positioned with respect to the storage medium 6.
• the positioning of the reference beam 3 is carried out by displaying a reference beam code pattern encoding the reference beam 3 at different positions on the SLM 4.
• a servo control unit 14 which is connected to the detector 5 for analysing the image detected by the detector 5 and computing a servo signal as will be explained later on.
• the servo signal is used for controlling the position of the code pattern displayed by the SLM 4.
• the servo control unit 14 can be for example a computer, microcontroller or any application-specific electric circuit with the necessary software to operate the SLM 4.
• Fig. Ib illustrates another preferred embodiment of the holographic storage system 1, where the holographic storage medium 6 is read in transmission mode, i.e. the reconstructed object beam 9 is transmitted through the storage medium 6. Accordingly, the detector 5 is arranged on the opposite side of the storage medium 6 and a third Fourier lens 111 can be interposed between the detector 5 and the storage medium 6 for imaging the reconstructed object beam 9 onto the imaging plane of the detector 5.
• Fig. Ic illustrates another preferred embodiment of the holographic storage system 1, which is adapted both for reading and writing holographic storage media 6. Similarly to the embodiment of Fig. Ib the storage medium 6 is read in transmission mode.
• the beam splitter 10 is used to unite the reference beam 3 and an object beam 3 1 coming from an object beam SLM 4' when the system 1 is used for recording a hologram 7 on a storage medium 6.
• the object beam 3' can be provided with a separate light source (not shown), or the light source 2 of the reference beam 3 can be used to provide both beams 3 and 3 1 as known in the art.
• Fig. 2 illustrates a reference beam phase code pattern 15 displayed on the SLM 4.
• each reference beam code pixel 16 consists of 5 x 5 SLM pixels 17.
• the number of SLM pixels 17 used for displaying a single code pixel 16 can vary depending on the application.
• code pixels 16 consisting of more than one SLM pixel 17 allows for a simple way of shifting the code pattern 15. For example to shift the code pattern 15 by one SLM pixel 17 to the right each code pixel 16a is shifted by one row of SLM pixels 17 as demonstrated in Fig. 3.
• the new code pixel 16b is displayed by a new block of 5 x 5 SLM pixels 17 consisting of 5 x 4 SLM pixels 17 overlapping with the original code pixel 16a and 1 x 4 SLM pixels 17 to the right from the original code pixel 16a.
• the code pattern 15 can be shifted in any direction following the above concept, including directions not parallel with the rows or columns of the SLM pixels 17.
• a hologram 7 recorded with a particular reference beam phase code pattern 15 can only be reconstructed with a reference beam encoded with a phase code pattern 15 identical or highly similar to the one used for recording the hologram 7, thus encoding the reference beam 3 allows for security encryption or multiplexing.
• the reference beam code pattern 15 can for example have a size of 10 x 10 code pixels 16 leading to 2100 possible code combinations.
• the hologram 7 should not be readable with reference beam code patterns 15 other than the one used for recording the hologram 7. Therefore only a set of sufficiently distinct code patterns 15 can be used out of the total possible code patterns 15, which in practice is still a very high number, e.g. about 225 code combinations could be used.
• a method of generating distinct code patterns 15 is disclosed in WO 02/05270.
• the aperture 13 has the additional benefit of restricting the definition of the SLM 4, so that the individual SLM pixels 17 are not distinguishable on the image detected by the detector 5 while the encoding effect of the code pixels 16 is still perceptible.
• the aperture 13 is arranged in the Fourier plane of the SLM 4 (or its close vicinity) in order to filter the high frequency components in the Fourier space thereby blurring the resulting image.
• Beside phase modulation the code pattern 15 can be created by modulating any other light property or a combination thereof (including phase, amplitude, wavelength and polarisation) as known in the art.
• the reference beam code pattern 15 can be a simple light transmitting inner circle 18 with a non-transparent outer border zone 19 as illustrated in Fig. 4. This can be achieved for example by using the SLM 4 in amplitude modulation mode and decreasing the amplitude of the border zone
• the circular reference beam 3 can be easily positioned by changing the amplitude modulation of the individual SLM pixels 17 so as to create the light transmitting inner circle 18 at another location of the SLM 4.
• a known method to realise amplitude modulation mode is to provide a polariser before and an analyser after the SLM 4.
• the polarisation of the reference beam 3 falling within the inner circle 18 can be left unchanged by the SLM 4, while it can be rotated by 90 degrees within the outer border zone 19. Only the unchanged polarisation will pass through the analyser thus creating the easy to position circular reference beam 3.
• the easy to position circular reference beam 3 can be provided together with phase coding as well, either using the same or a further reference beam encoding SLM 4 disposed along the optical path of the reference beam 3.
• the same SLM can be used for simultaneous phase and amplitude modulation e.g. in ternary modulation mode of special SLMs. Using two SLMs for separate phase and amplitude modulation requires additional optical elements to image the two SLMs onto each other.
• SLM pixel 17 as one code pixel 16 is also at hand for a phase-coded reference beam 3, however it is advantageous to be able to shift the phase pattern in finer steps than the size of a code pixel 16 for the purpose of calculating a misalignment between the reference beam 3 and the storage medium 6.
• the code pattern 15 can be created in any other known way as well as long as it is possible to shift the code pattern 5 on the SLM 4.
• a figure of merit associated with the detected image can be determined.
• the figure of merit is generally a scalar quantity indicative of the pixel misalignment, e.g. average pixel intensity or signal to noise ratio.
• An example for using figures of merit can be found in US 7,116,626 Bl (referred to as a channel metric).
• the reference beam 3 can be repositioned by shifting the code pattern 15 on the SLM.
• the figure of merit is only suitable for indicating the magnitude or degree of misalignment but not the direction of the misalignment. Consequently, if a figure of merit is used for describing the misalignment the figure of merit may need to be recalculated at a number of different reference beam positions.

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• Physics & Mathematics (AREA)
• Chemical & Material Sciences (AREA)
• Crystallography & Structural Chemistry (AREA)
• Optics & Photonics (AREA)
• General Physics & Mathematics (AREA)
• Holo Graphy (AREA)
• Optical Recording Or Reproduction (AREA)

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• 2007
  • 2007-02-06 HU HU0700133A patent/HU0700133D0/hu unknown
• 2008
  • 2008-01-24 AU AU2008213456A patent/AU2008213456A1/en not_active Abandoned
  • 2008-01-24 KR KR1020097016397A patent/KR20090109099A/ko not_active Withdrawn
  • 2008-01-24 JP JP2009547581A patent/JP2010518420A/ja active Pending
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  • 2008-01-24 EP EP08707228A patent/EP2126907B1/en not_active Not-in-force
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