The technical field relates generally to optical systems and, more particularly, to a hologram recording apparatus.
An optical system such as a hologram recording apparatus can include a laser source for emitting an object beam and reference beam, which are radiated onto a hologram-recording media at the same position. The object beam and the reference beam interfere with each other inside the media to form a diffraction pattern or so called microhologram at the irradiation point for recording data on the media.
When the media on which the data is already recorded is irradiated with the reference light, diffracted light (reproducing light) is generated by the microhologram formed in the recording process. The reproducing light includes data superimposed on the object beam in the recording process. Therefore, the recorded signal can be reproduced by receiving the reproducing light with a photo-sensitive element such as a photodiode.
High interference between the signal light and the reference beam, or generally two or more light beams, is important for generating holography. The level of interference between the two or more light beams will depend upon the coherence of the two or more light beams.
In one exemplary configuration, the laser source can be a semiconductor laser diode for emitting the laser beam and reference beam. However, the semiconductor laser diode has the drawback of low coherence due to the multimode associated with the laser beam, and thereby lower interference.
In another exemplary configuration, the laser source of the optical system can be an external cavity laser including a laser diode emitting a laser beam which is collimated by a collimating lens, and radiated onto a reflective diffraction grating so that the laser beam is a single mode beam, thereby having higher coherence. However, a change in the current supplied to the laser diode or generally a change in the diode temperature can result in mode hop, which is a transition between single modes of the laser beam. A conventional external cavity can include an interferometer and detectors for periodically monitoring for the occurrence of mode hop. However, such objects can increase the manufacturing costs of the external cavity laser as well as enlarging the structure.
Hologram recording apparatus can write data on the entire volume of a media such as a disc of 1 mm in thickness. Taking advantage of the bit-by-bit holography method where each single microhologram represents a single data bit and can be made as small in size as the data bits in a Blu-ray disc technology, data can possibly be stored in, for example, 100 layers of a disc. In comparison, data is only stored in two layers of a Blu-ray disc. Despite this potential improvement in storage capacity, hologram recording apparatus have been limited to niche markets such as data storage because of, for example, the high costs associated with the external cavity laser and the complexity of the optical system as discussed above. That is, an optical system including a compact, low cost laser source that could feasibly be made for the general consumer market has not yet been realized.
Accordingly, an optical system according to various novel embodiments includes a laser source for generating a laser beam; an optical subsystem for splitting the laser beam into a reference beam and an object beam; and first and second objective lens for receiving the reference beam and object beam, respectively, and focusing the reference and object beams at a focal point on media at which the reference beam and object beam interfere with each other. The reference beam and the object beam have first and second optical path lengths defined from the laser source to the focal point of the media. The optical subsystem is positioned so that an optical path length difference between the first and second optical path lengths is substantially equal to an integer multiple of an interference revival period associated with the reference beam and the object beam. The interference revival period is associated with peak values of visibility of the interference versus the optical path difference.
The laser source can be merely a semiconductor laser diode generating a multimode laser beam. Alternatively, the laser source can be an external cavity laser including a multimode laser diode source for generating a multimode laser beam and a grating for outputting a single mode of the light associated with the laser beam.
An optical system according to the various novel embodiments can implement a hologram recording apparatus which can write data on the entire volume of a media at a lower cost due to, for example, use of a semiconductor laser diode as the laser source, or a lower cost external cavity laser.
Various embodiments of an optical system utilizing holography to read and/or record data on a media will be discussed. The optical system reads and/or records data by generating two or more laser beams which generate interference at the media. The optical system can utilize an interference revival effect so that data is successively read from the media and/or recorded on the media even if a path difference between the two or more laser beams is greater than a coherence length of the two or more laser beams. The terms coherence and interference revival will be introduced below.
The concept of coherence is linked to a phase relationship between two points of an optical field separated either in time or space. The optical field is generated by an optical source of some finite dimension. That is, the optical field generally includes a large amount of atoms, each of which can be considered as a photon source. Inside a laser source there is always a high degree of phase correlation between the photons emitted by two atoms of the active region because the emission is mainly stimulated by other photons. Nonetheless, the correlation decreases with distance and time. The coherence length is the extent in space over which the electric field remains correlated or over which the field phase can be predicted. The coherence time is the time needed by a wavetrain to travel a distance equal to the coherence length.
The coherence length is proportional to the coherence time by the speed of light in a vacuum. On the other hand the coherence of a source is tightly linked to the source frequency bandwidth. For example, when the electric field emitted from the source is envisioned as the superposition of wavetrains with a certain duration, the very finite nature in time of these wavetrains is responsible for their infinite spectrum. The bandwidth of this spectrum is inversely proportional to the coherence time, which is the duration of the wavetrain. The proportionality constant depends on the shape of the wavetrain and on the criterion chosen to define the bandwidth, but the above is a general principle that applies to any source. Accordingly, the coherence of a laser source is an indication of the laser bandwidth.
The coherence of a laser source can be measured by a Michelson interferometer such as the exemplary Michelson interferometer 100 shown in
A quantitative measure of the quality of the fringes in an interference pattern can be expressed by visibility, which is a measure of the degree of coherence of the two beams in the Michelson interferometer 100. The visibility function can be measured by moving one arm (or one mirror) of the interferometer 100. The resulting visibility function is the bell shaped curve shown in
Thus, to ensure the interference of the two or more beams inside the media, the coherence length should be larger than an optical path difference in all operating conditions. However, for an optical system using the semiconductor laser diode, the coherence length will be very short. For example, the laser diode currently used in Blu-ray or DVD recording has a short coherence length that is usually less than 600 micrometers, which is not sufficiently long enough to provide a feasible optical system.
An effect referred to here as interference revival observed when the path difference is much higher than the coherence length and the laser is a multimode source will be introduced. In a Michelson interferometer setup, increasing the path difference steadily decreases the visibility of the fringes until no fringes are visible. However, after a travel of a few mm there will be again fringes forming on the sensor plane. This effect is the interference revival. As shown in
The coherence region is the width of the peak at the minimum allowed visibility. The size of the coherence region in any revival peak will be referred to here as the Peak Coherence Length (PCL). For example, the PCL of the laser diode shown in
An optical system, according to various embodiments, utilizes the periodic revival to permit the optical path difference to be greater than the short coherence length of, for example, Blu-ray or DVD laser light. Generally, the optical path difference between the two beams when focused in the mid layer can be set at substantially the interference revival period (or at an integer multiplier).
The holographic media should allow permanent refraction index changes depending on the intensity of the electric field of the light so that the holograms can be recorded. Data reading can be performed using the same light at lower intensity to avoid overwriting and observing the reflected light.
Referring to
Referring to
Referring to
The reference beam 606 and the object beam 608 have first and second optical path lengths defined from the laser source to the focal point of the media. For example, excluding the path between the laser source and the beam splitter 604, the path of the object beam 608 is A+D0 and the path of the reference beam 606 is B+C+D1. Generally, the optical subsystem 600 is positioned so that an optical path length difference between the first and second optical path lengths is substantially equal to an integer multiple of an interference revival period associated with the reference beam 606 and the object beam 608. As discussed above, the interference revival period is associated with the constant steps of peak values of visibility of the interference versus the optical path difference.
Assuming that the laser source is merely the laser diode 502 and collimator lens 506 for generating the multi-mode light, the interference revival period will be equal to 2nL, wherein n is the refraction index of the diode material and L is the length of the diode. For a Blu-ray laser diode, the interference revival period is approximately 4260 micrometers as shown in
Assuming that the laser source is the external cavity laser 500 such as the external cavity laser 500 shown in
Referring to
Similarly to the optical system 600, the reference beam 706 and the object beam 710 have first and second optical path lengths defined from the laser source to the focal point of the media. The path lengths of the reference and object beams 706, 710 are common up to the focal point inside the media 716. However, a path difference between the two beams is present from the focal point of the media 716 to the second mirror 708 and back to the focal point of the media 716. Thus, the optical path length difference is equal to 2D, wherein D is the distance between the second mirror 708 and the focal point of the media 716. The second mirror 708 is preferably disposed a predetermined distance D from the focal point so that the optical path length difference between the first and second optical path lengths is substantially equal to the integer multiple of the interference revival period. For example, if the distance D from the focal point to the surface of the second mirror 708 is an integer multiplier of the interference revival half-period, preferably one half of the revival period, the optical path difference will be an integer multiple of the interference revival period. This will allow even in this architecture with an intrinsic unavoidable path difference the use of a system with short coherence.
Referring to
Similarly to the second mirror 708 of the above embodiment, the retroreflector 808 is disposed a predetermined distance from the focal point so that the optical path length difference is substantially equal to the integer multiple of the interference revival period. For example, the distance D from the focal point to the retroreflector 808 can exactly match an integer multiplier of the interference revival half-period, preferably one half of the revival period.
Generally, as discussed above, the optical subsystem according to the above embodiments is positioned so that an optical path length difference between the first and second optical path lengths is substantially equal to an integer multiple of an interference revival period associated with the reference and object beams. However, a certain coherence length may still be needed to compensate for a variable optical path difference (Pvar) relevant to the many writing layers of the media. The variable optical path difference which occurs along with movement of the lens and optical element of the optical system is illustrated in
The optical system can sufficiently read or write to all layers of the media as long as the PCL of the revival peak is greater than Pvar for the most extreme case. Such an optical system is illustrated in
First and second actuators (not shown) can be configured to control the motion of the first and second objective lens 902, 912. The Pvar for the most extreme case will be equal to 2nT. In this case, the revival peak of the beams 904, 910 can be greater than Pvar for the most extreme case.
According to another embodiment of an optical system illustrated in
However, moving together the optical element 908 and the second objective lens may not be sufficient for reducing Pvar to be less than the PCL when, for example, the laser source is the bare laser diode due to its small PCL. However, according to another embodiment illustrated in
Generally, an optical system including the external cavity laser as the laser source may provide laser light with a PCL sufficient so that the configuration of optical system 900 or 900′ can be used. If a bare laser diode is the laser source, then the configuration of optical system 900″ may be needed.
Referring to
Returning to
A half transparent mirror 1023 reflects a first portion 1026 of the laser beam 1016, which is the reference beam, towards a first objective lens 1028 and a second portion 1024 towards an optical element 1029, which focuses the second portion 1024 of the laser beam into a power monitor 1032 for measuring the beam power level.
The reference beam 1026 passes through the first objective lens 1028, which focuses it at a focal point on the media 1001. The reference beam 1026 passes through the media 1001, a second objective lens 1034 and a shutter 1036, and is reflected back by a mirror 1038 to form an object beam 1040. The first and second lens 1028, 1034 respectively focus the reference and object beams 1026, 1040 at the focal point on the media 1001 at which the beams interfere with each other to create microholograms. The microholograms previously written can be read by, for example, directing only the reference beam 1026 at the focal point while activating the shutter 1036 to block the object beam 1040. The first and second lens 1028, 1034 can be coupled to actuators 1042, 1043, which can be configured to independently move the lens to focus on a correct layer inside the media 1001. Alternatively a single actuator can move both objective lenses together. A controlling device such as a processor (not shown) can control the actuators 1042, 1043. Further, similarly to the various embodiments illustrated in
The reference beam 1026 and the object beam 1040 have first and second optical path lengths defined from the external cavity laser 1002 to the focal point of the media 1001. The optical subsystem is positioned so that an optical path length difference between the first and second optical path lengths is substantially equal to an integer multiple of an interference revival period associated with the reference beam 1026 and the object beam 1040, the interference revival period associated with peak values of visibility of the interference versus the optical path difference. Generally, the path difference will be substantially equal to twice the path from the focal point of the media 1001 to the mirror 1038.
As shown in
Therefore, the present disclosure concerns an optical system for reading and recording data on a media. According to an embodiment, the system can include: a laser source for generating a laser beam; an optical subsystem for splitting the laser beam into a reference beam and an object beam; and first and second lens for receiving the reference and object beams, respectively, and focusing the reference and object beams at a focal point on the media at which the reference beam and object beam interfere with each other. The reference beam and object beam have first and second optical path lengths defined from the laser source to the focal point of the media. The optical subsystem is positioned so that an optical path length difference between the first and second optical path lengths is substantially equal to an integer multiple of an interference revival period associated with the reference beam and the object beam.
Other embodiments of the optical system will be apparent to those skilled in the art from consideration of the specification and practice of the optical system as disclosed herein. For example, the subsystem can include a tracking system to ensure the proper positioning of the objective lenses and the optical elements. Further, the system can include computer code for configuring the processor to adjust the lens and optical elements based upon data related to the interference revival period. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.