2.1.

Monocular Architecture

A new concept of optical architecture for HDSS dubbed “monocular architecture” was created in order to realize backward compatibility with BD system. The signal and the reference beams travel through a single objective lens in the new architecture as shown in Fig. 2.¹² The objective lens in the architecture can be placed parallel to the holographic medium. The geometry is the same as that in conventional BD system. The reference beam is focused on the back focal plane of the objective lens by the reference beam lens in the figure. Thus, the reference beam is collimated to a plane wave overlapping with the signal beam in the holographic medium. These two beams interfere with each other and generate interference fringes to be recorded in the medium as a hologram. Since the objective lens works as a Fourier transform lens, the incident angle $\theta$ of the reference beam onto the holographic medium is described as Eq. (1),

Fig. 2

Overview of monocular architecture.

Fig. 3

Monocular architecture, angular multiplexing by (a) mirror tilt, (b) reference beam lens shift, and (c) objective lens sift.

2.2.

Compatible Optical System between HDSS and BD using the Monocular Architecture

Light propagation in a compatible optical system between HDSS and BD using the monocular architecture is described schematically in Fig. 4.¹³ Figure 4(a) shows light propagation in holographic recording state for both signal and reference beams. A light beam outputted from external cavity laser diode (ECLD)¹⁴ is divided into signal and reference beams by beam splitter (BS). Signal beam is transmitted through the BS proceeds to be incident on a spatial light modulator (SLM). After the amplitude of signal beam is spatially modulated by SLM, the signal beam is focused on a holographic medium by an objective lens of NA 0.85. Reference beam reflected by Mirror1 is focused onto the back focal plane of the objective lens by reference beam lens equipped on an actuator. The focused reference beam is then collimated by the objective, overlapping with the signal beam in the holographic medium. Angular multiplexing is accomplished by changing incident angle of the collimated reference beam with the rotation of Mirror1 or displacement of the objective lens as previously explained in Sec. 2.1 with Fig. 3. On the other hand, Fig. 4(b) shows light propagation during the BD recording/readout state in the common optical system to Fig. 4(a). A light beam emitted from a blue-laser diode is collimated by a collimating lens. The reference beam lens working in Fig. 4(a) is removed and quarter wave plate is inserted in exchange by the actuator from and into the optical path of the collimated beam, respectively. After beam focusing on BD by the objective, the reflected beam travels through the opposite direction along the incident path and is detected by a photo detector. Holographic optical element placed in front of the photo detector that divides the reflected beam into a plurality of beams in order to generate a focusing error signal and a tracking error signal.¹⁵ The monocular architecture will potentially allow making the drive size much smaller and making the affinity for BD compatibility higher than conventional angularly multiplexing architecture because of its unique geometry and its angular multiplexing technique using conventional lens motion in the BD system.

Fig. 4

Optical architecture for backward compatibility with Blu-ray Disc™ (BD) system (a) during holographic recording state and (b) during the BD recording/readout state.

3.1.

Verification of the Validity of the Monocular Architecture

The experimental system for verification of the monocular architecture is shown in Fig. 5. A coherent laser with a power of 100 mW at 532 nm is used as a light source. A phase mask is imaged onto a $1280\times 1000$ data page SLM with a 12-μm pixel pitch using a pair of relay lenses. The mask is moved during angularly multiplexed recording to introduce random phase distribution to the modulated signal beam to mitigate any high frequency enhancement in the recorded holograms.⁴ A pair of relay lenses images the SLM to the back focal plane of an objective lens. In between the relay lens pair, a polytopic filter of 5.38-mm square is placed. The size is the square root of 1.2 times larger than Nyquist size on a side. Reference beam is introduced into the objective lens through a reference beam lens to be a plane wave at a medium. The beam size of the plane wave of the reference beam at the medium is $\sim 9.5\text{-}\mathrm{mm}$ square that is enough to overlap with signal beam in a holographic medium. The holographic medium is a 1.5-mm thickness InPhase HDS-3000 transparent disk, which is sensitive in the green wavelength range. The objective and reference beam lenses used are the same lenses, which are Hasselblad lenses (f#2.0, $\text{focal length}=110.8\mathrm{mm}$) allowing $\sim 2\mathrm{deg}$ of sweep range of the reference beam at the angle of 15 deg from the axis of the signal beam. Angularly multiplexed recording is accomplished by shifting either the reference beam lens position (A. in Fig. 5) or the objective lens (B. in Fig. 5). The reproduced signal beams are imaged on a $2200\times 1726\text{pixels}$ camera with a 7-μm pixel pitch and detected with an over-sampling detection process.¹⁶ In this experimental system, the holographic medium was forced to be tilted 20 deg to eliminate the directional reflection from the medium and to keep the reflected beam out from the camera because the performance of anti-reflective (AR) coating coated on the surface of HDS-3000 was not sufficient. Therefore, the objective lens was not placed parallel to the holographic medium yet in this experiment. However, the tentative configuration is not essential but can be solved by refinement of the coating or still effective to confirm the validity of angular multiplexing in the monocular architecture.

Fig. 5

Monocular experimental setup using green laser system and low numerical aperture (NA) objective lens.

First, an output angle of reference beam with respect to the optical axis of the objective lens was measured in comparison with theory. The solid line and some points in Fig. 6 show theoretical curve expressed as Eq. (1) and measured angles of reference beam within 1 deg resolution of measurement, respectively. Measured angles were in good agreement with theory as expected. Next, Fig. 7 shows the result of a scan of the Bragg angular selectivity curve of the recorded hologram compared to theoretical curve calculated by coupled wave theory.¹⁷ The relationship is theoretically given by Eq. (2),

Fig. 6

The result of output angle of reference beam with respect to the optical axis of the objective lens.

Fig. 7

Bragg angular selectivity curve for single hologram.

Table 1

Optical parameters of the experimental system.

Figure 8 shows a graph of SNR of three holograms angularly multiplexed by shifting either the reference beam lens (case A) or the objective lens (case B). The SNR is estimated by Eq. (3),

Fig. 8

Measured SNR and reproduced raw data image on camera.

Fig. 9

Relationship between SNR and bit error rate.

It was proved that the monocular architecture is capable of angularly multiplexed recording. Though the objective lens could not be placed parallel to the holographic medium yet due to insufficient AR coating of the medium in the experiment, it could be solved and parallel placement must be available with the refinement. We confirm the angular multiplexing both by reference beam lens motion and by objective lens motion. The latter is the identical movement required for an objective lens in the BD system. This can make the affinity for the BD compatibility higher and take advantage of conventional lens motion technique in the BD system. Through these examinations, the validity of the monocular architecture was verified.

3.2.

Monocular Architecture Composed of a Blue Laser and an Objective Lens of NA 0.85

To further investigate the performance of the monocular architecture and to demonstrate that the objective lens can be placed parallel to a holographic medium, a test-bed composed of a blue laser system and objective lens of NA 0.85, which are the same as the optical parameters in BD system was designed and fabricated as shown in Fig. 10.¹⁹ The blue laser diode (LD) unit is a modular laser that consists of an ECLD, isolator, and beam expander. The resulting beam is split into a signal and reference beam. The amplitude of the signal beam is spatially modulated using a $1200\times 820$ encoding data page giving a raw data page capacity of 100,676 bytes on an SLM with a 10.7-μm pixel pitch. The objective lens is a custom, high NA lens ($\mathrm{NA}=0.85$, $\text{focal length}=7.8\mathrm{mm}$) consisting of six spherical lenses. The objective lens was designed to allow the reference beam to sweep through 30 deg. Both the signal and reference beams pass through the objective lens such that the focal point of the reference beam is at the back focal plane of the lens resulting in a collimated reference beam at the medium. The medium is a custom transparent disk with a 1.5-mm recording layer (photopolymer) sandwiched between a 0.1-mm first substrate and a 1.0-mm second substrate with the AR coating. In the system, phase conjugate readout geometry is used for data recovery. Therefore, two stationary mirrors and two galvano mirrors (Galvo2, Galvo3) are placed on the back side of the medium to retro-reflect the reference beam for data recovery. Recovered holograms are imaged using a $1696\times 1710\text{pixel}$ camera with an 8.0-μm pixel pitch and the hologram image is reproduced by over-sampling detection with a ratio of $4:3$.

Fig. 10

Monocular test-bed composed of a blue laser system and objective lens of NA 0.85.

Using this designed test-bed, angularly multiplexed recording was successfully achieved. Figure 11 shows the relative intensity and the SNR of 130 multiplexed holograms recorded by scanning the mirror (Galvo1) angle. Each hologram was offset from the next by an angle of from 0.14 to 0.39 deg over the range. The graph indicates that the quality of 130 multiplexed holograms is sufficient for recovery because the average SNR for all holograms was about 3.2 dB and the BER was under $1.0\times {10}^{-10}$. The validity of angular multiplexing using geometry that an objective lens of NA 0.85 is placed parallel to a holographic medium was verified.

Fig. 11

Results of (a) relative intensity and (b) the SNR of 130 multiplexed holograms.

3.3.

Feasibility Study of Compatibility with Blu-ray Disc™ System

From the viewpoint of wave aberration, preliminary feasibility study of compatibility with the BD system was also examined because wave aberration is a crucial evaluation indicator for both HDSS and BD system. First of all, wave aberration of the optical path for HDSS, whose objective lens is identical with the lens of NA 0.85 shown in Fig. 10, was analyzed. For HDSS using angularly multiplexed recording, the wave aberration of reference beam is critical compared to that of signal beam, and $0.1\lambda$ root mean square (RMS) is proposed provisionally as a criterion at previous work.²⁰ Based on the criterion, wave aberration of reference beam was evaluated. Figure 12 shows wave aberration of reference beam in a holographic medium calculated by ray tracing. In this analysis, the size of the squared aperture for reference beam in Fig. 10 was set so that the reference beam in the medium became 1.5-mm square, which was sufficient to overlap with the signal beam in the holographic medium. Under the condition, it was confirmed that wave aberration could be lower than $0.1\lambda$ RMS in overall range of scanning field of 30 deg.

Fig. 12

Wave aberration of various incident angles of reference beam at 26, 36, 48, and 56 deg calculated by ray tracing.

Second, the wave aberration of the optical path for BD system was numerically analyzed. For this analysis, the optical model described in Fig. 4 was utilized where the objective lens is assumed to be identical with the lens of NA 0.85 shown in Fig. 10. With a combination of the objective lens and a collimating lens composed of two aspheric lenses shown in Fig. 13, the on-axis wave aberration of focused beam through a cover glass of 0.1-mm thickness could be reduced to $0.06\lambda$ RMS at NA of 0.85. Meanwhile, the working distance between the front edge of the objective lens and the surface of the cover glass could be designed to be 1.1 mm, which is comparable to that of current BD system.²¹ Still further improvement of the wave aberration will be required for practical use, but we consider the above result showed highly probable feasibility of the compatibility as a first phase because the wave aberration was at least lower than Marechal criterion of $0.07\lambda$ RMS. Only one beam is incident on BD in this system, which means required level of the off-axis wave aberration for the objective lens can be mitigated compared to system employing conventional method such as differential push–pull method, which needs three optical beams with different angles each other incident on the disc for generating a tracking error signal. In this study, from the viewpoint of preliminary analysis, the objective lens was designed to consist of six spherical lenses. If an aspheric lens design technique is employed, the wave aberration in addition to the size of the objective lens could be improved considerably. Through these numerical analyses, the monocular architecture showed a strong possibility to realize compatibility with BD system.

Fig. 13

(a) Optical model for wave aberration analysis and (b) calculated wavefront.