JPH0581878A - Method and device for reading recorded optical information - Google Patents

Abstract

PURPOSE:To read optical information recorded by an optical intercalation (deintercalation) phenomenon as digital signal. CONSTITUTION:An optical information recording medium 1 is provided with an optical semiconductor 3 indicating an optical intercalation effect. A pair of electrodes 9, 9 are provided on the optical semiconductor 3. When the optical information recording medium 1 is irradiated with a light beam 4 recording the information, the characteristic of the optical semiconductor 3 is changed by the optical intercalation phenomenon and the information is recorded. At this time, the electric resistance, as well of the optical semiconductor 3 is changed. Thus, when the electrodes 9, 9 are connected to a C-MOS oscillation circuit 16, a signal with a frequency in accordance with the resistance change of the optical semiconductor 3 is outputted. The signal is made to pulse by a multi-vibrator 17 and counted by a frequency counter 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical information reading method and apparatus for reading information recorded on an optical information recording medium by irradiating light, and more particularly to an optical intercalation effect or an optical deintercalation. The present invention relates to a method and an apparatus for reading out optical information recorded by utilizing the polarization effect.

[0002]

2. Description of the Related Art With the increasing need for high-speed processing of image information, the development of new optical information devices incorporating the concept of parallel processing has become an extremely important issue as the resolution of image devices increases. .. In order to meet such demands, a Si image sensor having a three-dimensional structure, a spatial light modulator, an optical associative memory using a hologram, an optical neuro device, etc. have been proposed so far.
The principle of the first stage optical information recording in these devices is
All of them are based on the existing photoelectric effect and electro-optical effect that have been adopted in the conventional series method, and thus inherently involve technical difficulties. Therefore, in order to realize a parallel processing device, it is considered necessary to adopt an optical information recording method based on a principle different from the conventional one.

As an optical information recording medium based on such a new principle, one utilizing a phenomenon called optical intercalation or optical deintercalation is known (H. Tributsch, Solid State Ionics 9 & 10 ( 1
983), p.41-57). Optical intercalation is a phenomenon in which a guest such as an ion is taken in between the lattice voids or layers of a crystal by light irradiation, and optical deintercalation is a phenomenon in which the taken guest is released by light irradiation. For the optical information recording medium, a substance whose optical or electrical characteristics are changed by such optical intercalation or optical deintercalation is used. Such substances have already been applied to electrochromic display devices and the like.

In the optical information recording medium shown in the above-mentioned paper, an optical semiconductor which becomes transparent by incorporating copper ions is used as a material exhibiting such an optical intercalation or optical deintercalation effect. .. The optical semiconductor is disposed adjacent to the other side surface of the transparent electrolyte having a counter electrode made of metallic copper disposed on one side surface, and the photo semiconductor and the counter electrode are electrically connected to each other. ing. According to such an optical information recording medium, when light having a predetermined energy is irradiated from the electrolyte side, the interface excites the electrolyte of the optical semiconductor in contact with the light, and copper ions in the electrolyte are taken into the optical semiconductor. , The optical semiconductor gradually becomes transparent. Then, when the irradiation of light is stopped, the state at that time is maintained. That is, optical information is recorded.

As described above, in the optical information recording medium utilizing the optical intercalation effect or the optical deintercalation effect, the recorded information shows an analog response. That is, the recorded information is not only proportional to the intensity of the light input during recording, but also depends on the irradiation time of the input light. Therefore, such an optical information recording medium is characterized by having both a memory function and a learning function. Moreover, the information recording can be performed in parallel. Therefore, it is conceivable that parallel processing of image information becomes possible by using the optical information recording medium having such a principle.

By the way, in order to construct an optical information device using such an optical information recording medium, the optical information thus recorded is taken out as an electrical signal in the subsequent stage and electrically processed. It is necessary to do so. As described above, when electrically reading recorded optical information, conventionally, the optical information recording medium is irradiated with light having lower energy than the light for recording information, and the transmitted light or reflected light is detected by an optical sensor. Was trying to detect by.

[0007]

However, in the optical information reading method in which the transmitted light or the reflected light is detected by the optical sensor, the output signal obtained is generally an analog signal. On the other hand, in order to process the recorded optical information, it is desirable that the read signal be digital. Therefore, the conventional optical information reading method is not preferable from the viewpoint of electrically processing the information. Further, as described above, in the case of the optical information recording medium utilizing the optical intercalation effect or the optical deintercalation effect, the characteristic change is essentially analog. And such an analog response is an extremely excellent feature from the viewpoint of learning function. Therefore, when reading the recorded optical information, it is desired to maintain the analog characteristic change.

As described above, in the case of the optical information recording medium utilizing the optical intercalation effect or the optical deintercalation effect, the recorded optical information is a signal having both analog characteristics and digital characteristics. It is desired that the signal be read as a form, but such a signal cannot be obtained by a conventional optical information reading method.

The present invention has been made in view of the above problems, and an object thereof is to facilitate electrical processing of optical information recorded by an optical intercalation effect or an optical deintercalation effect. Another object of the present invention is to provide a method and apparatus for reading optical information that can be read as a signal form that can utilize the learning function that is a feature of the optical information recording medium.

[0010]

In order to achieve this object, in the present invention, attention is paid to the fact that the electrical resistance of an optical semiconductor changes due to the optical intercalation effect or the optical deintercalation effect. , The recorded optical information is taken out as a digital signal. That is, the method for reading optical information according to the present invention is
It is characterized in that a change in electric resistance due to an optical intercalation effect or an optical deintercalation effect of an optical semiconductor is detected, and the resistance change is converted into a digital signal and output. Further, the optical information reading device according to the present invention includes an optical information recording medium provided with an optical semiconductor exhibiting an optical intercalation effect or an optical deintercalation effect, and an electrode for detecting a change in electric resistance generated in the optical semiconductor. A multi-vibrator which is provided with a C-MOS oscillating circuit for converting a resistance change detected by the electrode into a frequency change, and a pulse output signal of the oscillating circuit, and a frequency counter for counting and outputting the number of pulses. It is characterized by having and.

[0011]

As described above, when the information recording light is irradiated onto the optical information recording medium provided with the optical semiconductor exhibiting the optical intercalation effect or the optical deintercalation effect, the optical intercalation or deintercalation phenomenon may occur. The characteristics of the optical semiconductor change in an analog manner.
That is, optical information is recorded. In that case, the optical semiconductor changes not only its optical characteristics but also its electrical characteristics, for example, its electrical resistance. Therefore, as in the above-described optical information reading method according to the present invention, if a change in electrical resistance occurring in the optical semiconductor is detected and the resistance change is converted into a digital signal and output, the recorded optical information is recorded. You can get a digital value. In that case, the resulting output signal itself is a digital quantity, but essentially represents an analog quantity. That is, it becomes a so-called quantized analog amount. Therefore, the learning function can be utilized.

Further, by configuring the optical information reading device as described above, the analog sheet resistance change of the optical semiconductor caused by the optical intercalation or deintercalation phenomenon is caused by the electrode provided in the optical semiconductor. Is detected and converted into a frequency change of the C-MOS oscillation circuit. Then, after being pulsed through the multivibrator, it is counted by the frequency counter. Therefore, it is read as a digital pulse density change with respect to the incident light energy for information recording.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. 1 is a schematic configuration diagram showing an embodiment of an optical information reading device according to the present invention together with an input system for recording optical information on an optical information recording medium, and FIG. 2 is a sectional view of the optical information recording medium. Is.

As shown in FIG. 2, an optical information recording medium 1 comprises a transparent electrolyte 2 having high ion conductivity and an optical semiconductor 3 exhibiting an optical intercalation effect or an optical deintercalation effect. It is configured by arranging in order from the side irradiated with the information recording light 4 in a state of being in contact with each other. In the case of this embodiment, an amorphous WO ₃ thin film which is an n-type optical semiconductor exhibiting an optical intercalation effect is used as the optical semiconductor ₃ . The amorphous WO ₃ is deposited on the glass substrate 5. The electrolyte 2 is amorphous WO ₃
Ethanol (C ₂ H ₅ OH), which has no photoelution, is used. Since the electrolyte 2 is a liquid, it is enclosed in a thin hollow cell 8 formed by facing a glass substrate 5 and a quartz substrate 6 on which amorphous WO ₃ is vapor-deposited and sealing the periphery with an acrylic resin 7. It is supposed to do. In the optical semiconductor 3, a pair of Al (aluminum) electrodes 9, 9 are provided at regular intervals. The electrodes 9 and 9 are for detecting a change in sheet resistance occurring in the optical semiconductor 3, and the lead wire 1 extending to the outside of the cell 8
0 and 10 are respectively connected.

When recording optical information on the optical information recording medium 1 thus constructed, the light 4 is irradiated from the electrolyte 2 side, that is, the quartz substrate 6 side. As the light source,
For example, a 500 W xenon lamp 11 is used as shown in FIG. In that case, after the heat ray component of the continuous light 4 from the xenon lamp 11 is removed by passing through the infrared filter 12, the heat ray component is condensed by using the lens 13, and the cell 8 is irradiated through the mask 14. .. When the cell 8 is irradiated with the information recording light 4 in this manner, the light 4 reaches the interface with the optical semiconductor 3 through the transparent electrolyte 2. Then, the light 4 excites the optical semiconductor 3, and the optical and electrical characteristics of the optical semiconductor 3 change due to the optical intercalation phenomenon. Further, when the irradiation of the light 4 is stopped, the characteristics of the optical semiconductor 3 are maintained in the state at that time. That is, optical information is recorded. The recorded information changes according to the energy of the incident light 4 and its irradiation time.

In the case of this optical information recording medium 1, it is considered that the ions are drawn into the optical semiconductor 3 due to the simultaneous progress of the oxidation and reduction reactions on the interface of the optical semiconductor 3. Therefore, unlike the optical information recording medium shown in the above-mentioned paper, the optical semiconductor and the counter electrode do not need to be electrically connected, and even if the circuit between the two poles is opened, the optical intercalation is performed. The phenomenon progresses. That is, in the case of this optical information recording medium 1, optical information can be recorded without providing a counter electrode or the like. Moreover, in the optical information recording medium 1, since it is not necessary to elute the metal ions in the electrolyte 2, it is not necessary to use an opaque metal electrode. Further, since the optical semiconductor 3 is arranged on the side opposite to the irradiation side of the light 4, the input light 4 is not blocked by the change in the optical characteristics of the optical semiconductor 3. Therefore, the optical information recording medium can accurately record the input optical information.

A reading device 15 for reading the optical information from the optical information recording medium 1 on which the optical information is recorded in this manner.
As shown in FIG. 1, is a C-MOS oscillation circuit 16 for converting a resistance change into a frequency change, and its oscillation circuit 1
Multivibrator 17 for pulsing the output signal of 6
And a frequency counter 18 for counting and outputting the number of pulses output from the vibrator 17. When reading the recorded optical information, the pair of lead wires 10 and 10 extending from the cell 8 are connected to the C-MO.
It is connected to the S oscillation circuit 16. The optical semiconductor 3 in the cell 8 is
Since the electrical resistance is changed by the optical intercalation effect according to the intensity and irradiation time of the light 4 input for recording information, the lead wires 10, 10 are connected between the electrodes 9, 9. The resistance of is also changing. Therefore, when the cell 8 is connected to the oscillation circuit 16, the oscillation circuit 16 outputs a signal having a frequency corresponding to the resistance change.
Then, a pulse signal corresponding to the frequency is output from the multivibrator 17, and the number of pulses is counted by the frequency counter 18.

In this way, the optical information reading device 15 outputs the read signal as a digital pulse density change with respect to the energy of the incident light 4 at the time of recording information on the optical information recording medium 1. The signal, by itself, is a digital quantity, but is essentially an analog quantity. That is, it is a quantized analog amount. Therefore,
Since the recorded information is read out in an analog manner, it is possible to utilize the learning function that is a feature of the optical information recording medium 1 that utilizes the optical intercalation effect. Moreover, since the read signal is a digital signal, electrical processing in the subsequent stage of the signal becomes easy.

The optical information recording medium 1 and the optical information reading device 15 as described above were actually prototyped, and the optical information recording medium 1 was manufactured.
Was irradiated with light 4 while changing the illuminance and the irradiation time. And
The optical information read-out device 1 measures the frequency change of the cell 8 at that time.
5 was measured. The experimental results are shown in FIG. As is clear from this figure, there is a correlation between the irradiation time and the frequency change of the output signal when the illuminance of the incident light is used as a parameter. That is, it can be seen that the learning function has been achieved.

Thus, the optical information reading device 15
According to this, it becomes possible to electrically read the optical information recorded by the optical intercalation effect as a digital signal having analog characteristics. And CM
Since the OS oscillation circuit 16 can have a laminated structure with the IC, the oscillation circuit 16, the multivibrator 17, the frequency counter 18, and the like can be integrated together.
Therefore, external wiring and the like are not required, and it is easy to reduce the size of the entire device.

In the above embodiment, the n-type optical semiconductor 3 having the optical intercalation effect is used. However, the optical information using the p-type optical semiconductor having the optical deintercalation effect is used. Also in the case of a recording medium, the optical information can be similarly read out by the same configuration. Further, the optical information recording medium 1 in which the electrolyte 2 is arranged on the incident light 4 side of the optical semiconductor 3 has been described, but the same applies to an optical information recording medium in which they are arranged in the opposite direction. it can.

[0022]

As is apparent from the above description, according to the present invention, a change in electric resistance of an optical semiconductor exhibiting an optical intercalation effect or an optical deintercalation effect is detected, and the resistance change is detected by a digital signal. The analog optical information recorded by utilizing the optical intercalation effect or the optical deintercalation effect, which is a photoelectric phenomenon in which ions intervene, is electrically converted into a digital signal. Can be read. Therefore, it becomes easy to electrically process the optical information, and the optical information recording medium can be widely applied to parallel processing image sensing, spatial light modulation, image calculation and the like. Further, since the C-MOS oscillation circuit that can be formed into a laminated structure with an IC is used for the reading, the entire element can be easily miniaturized.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing an embodiment of an optical information reading device according to the present invention together with an input system for recording optical information on an optical information recording medium.

FIG. 2 is a sectional view of the optical information recording medium.

FIG. 3 is a graph showing a digital electric signal reading characteristic by the optical information reading device.

[Explanation of Codes] 1 Optical Information Recording Medium 2 Electrolyte 3 Optical Semiconductor 4 Input Light 8 Cell 9 Electrode 15 Optical Information Readout Device 16 C-MOS Oscillation Circuit 17 Multivibrator 18 Frequency Counter

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location G11B 11/00 9075-5D

Claims (2)

[Claims] 1. An optical information recording medium comprising a transparent electrolyte having a high ionic conductivity and an optical semiconductor having an optical intercalation effect or an optical deintercalation effect, which are arranged in contact with each other. A method of reading out optical information recorded by irradiating recording light from the optical information recording medium; detecting a change in electrical resistance due to an optical intercalation effect or an optical deintercalation effect of the optical semiconductor Then, the optical information is read out as a digital amount by converting the resistance change into a digital signal, and the recorded optical information is read out. 2. An optical information recording medium in which a transparent electrolyte having a high ionic conductivity and an optical semiconductor exhibiting an optical intercalation effect or an optical deintercalation effect are arranged in contact with each other. An electrode for detecting a change in electric resistance caused by an optical intercalation effect or an optical deintercalation effect in the optical semiconductor; a C-MOS oscillation circuit for converting the resistance change detected by the electrode into a frequency change; An apparatus for reading recorded optical information, comprising: a multivibrator for converting an output signal of an oscillation circuit into pulses, and a frequency counter for counting and outputting the number of pulses output from the vibrator.