DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0018] An embodiment of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is a schematic diagram showing a holographic disc recording system according to the embodiment of the present embodiment. This system includes a coherent light source 10 which emits a plane-wave beam of collimated coherent light. The coherent light source 10 may be constructed of, for example, a laser device.

[0019] A beam emitted by the coherent light source 10 is split into a signal beam 23 and a reference beam 26 by a beam splitter 20 . The signal beam 23 is expanded by a signal-beam expander 30 such that the diameter of the signal beam 23 is increased to a size suitable for exposure. More specifically, the diameter of the signal beam 23 is increased to a size such that the signal beam 23 covers substantially the entire effective recording area of a transmissive source disc 50 , which will be described below, when it passes through the transmissive source disc 50 , and is incident on substantially the entire effective recording area of a target disc 60 composed of a holographic recording material, which will be described below.

[0020] The signal beam 23 with the increased beam diameter passes through a signal-beam adjustment optical element 40 . The signal-beam adjustment optical element 40 is provided when it is necessary to fine-tune the optical characteristics of the signal beam 23 . A polarizer, a filter, an attenuator, etc., may be used as the signal-beam adjustment optical element 40 . For example, if the signal beam 23 is to be polarized in the radial direction of the target disc 60 when it is incident on the target disc 60 , a circularly symmetric polarizer may be used as the signal-beam adjustment optical element 40 . In addition, if the signal beam 23 is to have a substantially uniform light intensity over substantially the entire effective recording area of the target disc 60 when it is incident on the target disc 60 , a neutral density filter which is specially designed to correct the intensity distribution of a beam which passes therethrough may be used as the signal-beam adjustment optical element 40 so that the signal beam 23 is attenuated to make the light intensity distribution uniform.

[0021] After fine-tuning the optical characteristics, the signal beam 23 passes through the transmissive source disc 50 . When the signal beam 23 passes through the transmissive source disc 50 , the amplitude and/or the phase of the signal beam 23 is/are modulated such that information to be recorded on the target disc 60 is imprinted on the signal beam 23 . Then, the modulated signal beam 23 is incident on one side of the target disc 60 composed of a holographic recording material, so that the entire effective recording area of the target disc 60 is irradiated with the signal beam 23 .

[0022] The reference beam 26 is guided by an optical unit included in the holographic disc recording system and is incident on the target disc 60 at the opposite side thereof without passing through the source disc 50 such that substantially the entire effective recording area of the target disc 60 is irradiated. More specifically, the reference beam 26 is guided to the opposite side of the target disc 60 by a mirror unit 100 and is expanded by a reference-beam expander 90 such that the diameter of the reference beam 26 is increased to a size suitable for exposure. More specifically, the diameter of the reference beam 26 is increased to a size such that substantially the entire effective recording area of the target disc 60 is irradiated when the reference beam 26 is incident on the target disc 60 at the opposite side thereof.

[0023] The reference beam 26 with the increased beam diameter passes through a reference-beam adjustment optical element 80 . Similarly to the case of the signal beam 23 , the reference-beam adjustment optical element 80 is provided when it is necessary to fine-tune the optical characteristics of the reference beam 26 , and the elements mentioned above in the description of the signal-beam adjustment optical element 40 may also be used as the reference-beam adjustment optical element 80 .

[0024] After fine-tuning the optical characteristics, the reference beam 26 is incident on a conical beam shaper 70 . The conical beam shaper 70 transforms the collimated reference beam 26 into a conical beam having a substantially cylindrically symmetrical shape and including light rays which travel along lines which intersect a beam axis of the conical beam at substantially the same angle with respect to the beam axis.

[0025] There are various types of optical elements that can be used as the conical beam shaper 70 . FIGS. 2 to 4 show examples of such optical elements. FIG. 2 shows a conical mirror 120 as a first example of a conical beam shaper. Although the three-dimensional shape of the conical mirror 120 is actually conical, it appears triangular since FIG. 2 is a side view of the conical mirror 120 . When a collimated beam 110 is incident on the conical mirror 120 in a direction parallel to the central axis of the conical mirror 120 , it is reflected by the surface of the conical mirror 120 such that the collimated beam 110 is transformed into an output beam 150 A including light rays which travel in all radial directions of the conical mirror 120 along lines inclined at the same angle with respect to the central axis of the conical mirror 120 . FIG. 3 shows a conical prism 130 as a second example, and FIG. 4 shows an inverted conical prism 140 as a third example. Similarly to the case of the conical output beam 150 A emitted from the conical mirror 120 , by suitably designing the prisms 130 and 140 , output beams 150 B and 150 C having a substantially cylindrically symmetrical shape and including light rays which travel along lines which intersect the beam axes at substantially the same angle with respect to the beam axes can be emitted from the prisms 130 and 140 , respectively.

[0026] The reference beam 26 , which is transformed into a conical beam as described above, is incident on the target disc 60 in such a manner that the beam axis of the conical beam substantially coincides with the central axis of the target disc 60 . Accordingly, substantially all of the light rays of the conical beam are incident on the target disc 60 at substantially the same angle.

[0027] Thus, according to the present invention, the reference beam used for recording the holograms is transformed into a conical beam having a substantially cylindrically symmetrical shape and including light rays which travel along lines which intersect the beam axis of the conical beam at substantially the same angle with respect to the beam axis. Then, the conical beam is incident on the target disc in such a manner that the beam axis of the conical beam substantially coincides with a central axis of the target disc, so that substantially all of the light rays of the conical beam are incident on the target disc at substantially the same angle.

[0028] According to the above-described construction, the entire effective recording area of the target disc 60 can be irradiated with the reference beam 26 . In addition, all optical characteristics of the reference beam 26 are highly uniform over the entire effective recording area of the target disc 60 . Furthermore, the uniformity of the optical characteristics can be improved by fine-tuning the optical characteristics of the reference beam 26 , such as the polarization state, the light intensity distribution, etc., with the reference-beam adjustment optical element 80 .

[0029] In addition, the holographic disc recording system having the above-described construction has high versatility and can perform the replication of both a source disc manufactured by an amplitude-modulation recording method and a source disc manufactured by a phase-modulation recording method.

[0030] Since FIG. 1 is a schematic diagram which shows the principle of the holographic disc recording system according to the present invention, the detailed structure of this system is not shown. The above-described system preferably includes a plurality of conical beam shapers 70 for emitting conical beams which are incident on the target disc 60 at different angles and a conical beam shaper selecting mechanism for selectively using one of the conical beam shapers. Accordingly, the holograms can be multiplexed by changing the incidence angle of the reference beam with a simple structure. In this case, the system may include a plurality of reference-beam adjustment optical elements 80 which are selectively used as necessary in accordance with the shape of the conical beam, which changes depending on which conical beam shaper is used.

[0031] Although FIG. 1 shows an example of the layout of elements included in the holographic disc recording system according to the present invention, the layout of the elements is not limited to this. For example, the beam expanders 30 and 90 may be disposed at any place on the optical path as long as they can change the diameters of the signal beam 23 and the reference beam 26 , respectively, to a size suitable for exposure. Similarly, the signal-beam adjustment optical element 30 and the reference-beam adjustment optical element 80 may also be disposed at any place as long as they can serve their respective functions.