The present invention relates to an optical reader for a two dimensional storage disc, comprising means for generating a plurality of laser beams and projecting said beams onto a rotating disc, means for detecting the beams after being diffracted by the disc, and means for determining a focus error signal based on one of the plurality of beams.
Conventionally, optical storage is performed in one dimension, i.e. a track of consecutive bits is written onto the disc (e.g. CD, DVD). Recently, the concept of two dimensional optical storage has been introduced. The format of a 2D disc is based on a broad spiral, consisting of a number of parallel bit rows. Parallel read out is realized using a single laser beam which passes through a diffraction grating producing an array of spots scanning the fall width of the broad spiral. Such a system is disclosed in “Two-Dimensional Optical Storage”, by Wim M. J. Coene, OSA Topical Meetings on Optical Data Storage, May 11-14, 2003, Technical Digest, pp 90-92.
For focus tracking of the laser, a focus error signal is generated using conventional methods (e.g. Foucault, astigmatic, spot size) based on the central spot of the array. However, the small separation between spots (in the order of micrometers) causes the spots to overlap very quickly when out of focus. In the overlap region the intensity profile is highly distorted because of interference from adjacent spots, which disturbs the focus signal. As a result, the capture range, or focus S-curve length, is significantly reduced. While a conventional one dimensional optical reader (e.g. a CD ROM drive) has a capture range of around 2-5 micrometers, a two dimensional reader may have a capture range less than one micrometer. The problem is also present during writing of a disc.
With regards to one dimensional optical storage, CD and DVD systems are typically operated with different types of tracking methods, i.e. single spot, multiple spot. In order to provide both types of reading in the same optical reader, such readers are sometimes provided with two different lasers, having different wavelengths, and a wavelength dependent optical element in the laser path. Such a reader is disclosed in EP 1069555. The optical element is a grating made of a birefringent material, adapted to act as a grating and thus diffracting light from one of the lasers (having one of the wavelengths), while leaving light from the second laser (having another wavelength) unaffected.
It is an object of the present invention to overcome this problem, and to provide a two dimensional optical reader/writer with improved focus tracking.
It is a further object to provide a two dimensional optical reader/writer with improved capture range.
These and other objects are achieved by an optical reader/writer of the kind mentioned in the introduction, wherein said plurality of beams comprises an array of beams having a first wavelength, and a dedicated focus tracking beam having a second wavelength, and wherein said focus error signal is based on said focus tracking beam. According to the invention, beams having one wavelength is used for the actual accessing of the data on the disc, while a beam having a second wavelength is used for focus tracking. The focus tracking can then be based on one single beam, without interference from adjacent beams.
The focus tracking beam may coincide with one of the beams, preferably the central beam, of the beam array. This ensures that the reflected beam used for focus tracking is reflected in a spot that is actually used during read-out/writing. The likelihood of achieving acceptable focus in most of the array beams (i.e. even if they are mutually unaligned) is increased by using the central beam.
The means for detecting the beams preferably comprises a beam separator for separating the dedicated focus tracking beam from the array of beams. This provides for separation of the dedicated focus tracking beam from the read-out/writing beams, and thus facilitates application of tracking methods, such as the Foucault method. In the case of reading, the read-out beams must also be separated in order to enable processing of the high frequency data, while in the case of writing, it may be enough to distinguish the focus beam. The beam separator can comprise a dichroic mirror, arranged to reflect the array of read-out beams in one direction, and the dedicated focus tracking beam in a different direction. Such wavelength dependent beam splitters are known in the art.
Alternatively, the beam separator can comprise a diffraction element being adapted to transmit light having said first wavelength while blocking light having said second wavelength. Such a wavelength dependent diffraction element can be realized by means of a binary grating.
According to one embodiment of the invention, the laser generating means can comprise two lasers for generating two laser beams having said first and second wavelengths respectively, and a diffraction element arranged in the optical path of both beams, said diffraction element being adapted to diffract light having said first wavelength while transmitting light having said second wavelength.
Such a wavelength dependent diffraction element is known per se, and is described e.g. in EP 1069555, mentioned above. However, in the reader according to EP 1069555, light of only one wavelength at a time is used selectively to read different types of optical discs (CD and DVD respectively), and the purpose of the diffraction element is to provide different diffraction depending on the currently selected wavelength. The purpose of the present invention is instead, as mentioned above, to provide a dedicated focus tracking beam by using laser light of two different wavelengths simultaneously. Letting the two laser beams pass through a diffraction element as described in EP 1069555 is only one possible embodiment of the invention.
The diffraction element can be a binary grating having a grating depth essentially satisfying:
h(n−1)=1λ1+φstep/2π and h(n−1)=mλ2,
where h is the grating depth, n is the index of refraction of the grating, λ1 and λ1 are the two wavelengths, φstep is the desired phase step, and 1 and m are integers. Such a grating is reasonably easy to realize.
According to a different embodiment, the laser generating means comprises a first laser for generating a first laser beam having said first wavelength, a diffraction element for diffracting said first laser beam into an array of laser beams, a second laser for generating a second laser beam having said second wavelength, and means for merging said array of beams with said second beam.
This embodiment does not require a wavelength dependent grating as mentioned above, but instead merges laser beams having different wavelengths together after one of them has been diffracted into an array of beams.
These and other aspects of the invention will be apparent from and will be elucidated with reference to the embodiments described hereinafter.
The present invention will now be described in more detail, by way of example, with reference to the accompanying drawings, wherein:
The principles of two dimensional storage on an optical disc 1 is illustrated in
A first embodiment of the invention is shown in
This can be accomplished with a binary grating where the grating depth of the grating is such that for one wavelength the required phase depth is achieved and for the other wavelength the phase depth is a multiple of 2π. In equation form, this corresponds to:
h(n−1)=1λ1+φstep/2π and h(n−1)=mλ2,
where h is the grating depth, n is the index of refraction of the grating, λ1 and λ1 are the two wavelengths, φstep is the desired phase step, and 1 and m are integers.
The two initial laser beams can be arranged to coincide, such that, after the diffraction, the undiffracted focus beam will coincide with the central beam of the beam array.
The beam array and the dedicated focus tracking beam are then focused onto the disc and reflected in a similar way as was described above with reference to
The high frequent read-out data is directed to an optical multi-partitioned photo-detector 25 which generates a number of high frequency waveforms used as input for 2D signal processing in a processor 26, essentially in the same way as described above with reference to
A second embodiment of the invention is shown in
Further, in the embodiment in
The person skilled in the art realizes that the present invention by no means is limited to the preferred embodiments described above. On the contrary, many modifications and variations are possible within the scope of the appended claims. For example, although the invention has been described with reference to an optical reader, the invention is equally applicable to an optical writer, where the same focus tracking is required.
Any reference sign in a claim should not be construed as limiting the claim. Use of the verb “to comprise” and its conjugations does not exclude the presence of elements or steps other than those stated in a claim. Use of the article “a” or “an” preceding an element or step does not exclude the presence of a plurality of such elements or steps.
Number | Date | Country | Kind |
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04101910.0 | May 2004 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB05/51374 | 4/27/2005 | WO | 00 | 10/30/2006 |