JP3765856B2 - Current-voltage conversion circuit and photoelectric conversion device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a current-voltage conversion circuit and a photoelectric conversion device, and more particularly to a circuit for converting an optical signal into a voltage and an information reading device to which the circuit is applied.
[0002]
[Prior art]
In recent years, information processing apparatuses have come to handle an enormous amount of information as the functions of image editing and information transmission increase. For this reason, magneto-optical storage devices capable of storing information amounts of several hundred mega or more have been developed. The magneto-optical storage device executes modes such as information write (write), read (read), erase (erase), and error verification (verify). In the magneto-optical storage device, information is read out by an information reading unit, and a photoelectric conversion device is used for the information reading unit.
[0003]
FIG. 8A shows a configuration diagram of an information reading unit of a magneto-optical storage device according to a conventional example. In FIG. 8A, reference numeral 100 denotes a magneto-optical storage medium of the magneto-optical storage device. Reference numeral 200 denotes an information reading unit that reads information from the magneto-optical storage medium 100. The information reading unit 200 includes a laser light source 201 that generates laser light, and guides the laser light to a magneto-optical storage medium, condenses the laser light, and guides laser reflected light from the magneto-optical storage medium to a light receiving system. Optical means 202 to 206, and a photoelectric conversion device 207 that receives the laser reflected light from the magneto-optical storage medium and converts it into a voltage. 202 and 206 are polarization beam splitters, 203 is a mirror, 204 is a lens, and 205 is a half-wave plate.
[0004]
The photoelectric conversion device 207 receives the reflected laser light from the magneto-optical storage medium 100 and generates a photocurrent, and receives the reflected light from the magneto-optical storage medium and generates a photocurrent having a phase opposite to that of the diode 1. It comprises a photodiode 3 that is generated, current-voltage conversion circuits 2 and 4 that convert the output currents of the photodiodes 1 and 3 into voltages, and a differential amplifier 5 that amplifies the output voltages of the current-voltage conversion circuits 2 and 4.
[0005]
The current / voltage conversion circuits 2 and 4 apply the current / voltage conversion circuit previously filed by the present inventors (Japanese Patent Laid-Open No. 7-212147). As shown in FIG. 8B, the current-voltage conversion circuits 2 and 4 include a current-voltage conversion amplifier 6 that amplifies the optical signal, a feedback resistor 7 that feeds back the output of the amplifier 6 to the input, and an amplifier 6. A clamping diode 8 for saturation, a current absorption circuit 9 that flows in a current when a large optical signal (current) is input, and a switch circuit 10 that selects whether or not to operate the current absorption circuit 9 Have.
[0006]
Next, the operation at the time of reading of the information reading unit of the magneto-optical storage device will be described. First, when laser light is generated from the laser light source 201, the laser light is guided to the magneto-optical storage medium 100 through the polarization beam splitter 202, the mirror 203, and the lens 204. Laser reflected light including read information from the magneto-optical storage medium 100 is guided to a light receiving system through a lens 204, a mirror 203, a polarizing beam splitter 202, a half-wave plate 205, and a polarizing beam splitter 206. The laser reflected light taken into the polarization beam splitter 206 enters the photodiodes 1 and 3. The photodiode 1 receives the laser reflected light and generates a photocurrent, and the photodiode 3 receives the laser reflected light and generates a photocurrent having a phase opposite to that of the diode 1. The current / voltage conversion circuits 2 and 4 convert the output currents of the photodiodes 1 and 3 into voltages, and the differential amplifier 5 amplifies the output voltages of the current / voltage conversion circuits 2 and 4. Thus, the information reading unit 200 can read information from the magneto-optical storage medium 100.
[0007]
Next, the operation of the information reading unit during writing and erasing will be described. In the magneto-optical storage device, when information is written in the magneto-optical storage body 100 or information in the magneto-optical storage medium 100 is erased, the information reading unit 200 reads information from the magneto-optical storage medium 100 immediately after that. Execute. Therefore, during writing and erasing, the information reading unit 200 does not read information and performs the following clamping operation so that the amplifier 6 of the current-voltage conversion circuits 2 and 4 is not saturated.
[0008]
For example, regarding the current-voltage conversion circuit 2, a large optical signal is output from the photodiode 1 to the current-voltage conversion circuit 2 during writing and erasing. The current absorption circuit 9 operates by turning on the switch circuit 10 during writing and erasing. Then, a large optical signal (current) is absorbed by the current absorption circuit 9. The diode 8 clamps the voltage across the feedback resistor 7 to make the amplifier 6 non-saturated. Thereby, saturation of the input transistor of the amplifier 6 can be prevented, and the output voltage of the amplifier 6 can be made constant. When the normal signal current (at the time of reading) is restored, the amplifier circuit 6 can be quickly returned to the amplification operation by turning off the switch circuit 10.
[0009]
Therefore, in the photoelectric conversion device using the conventional current-voltage conversion circuit, the switching time from the write or erase mode to the read mode can be shortened, so that the speed of the photoelectric conversion device can be increased.
[0010]
[Problems to be solved by the invention]
However, when the storage density of the magneto-optical storage medium (single dense, 120 Mbytes) increases to double density (240 Mbytes) and quadruple density (640 Mbytes) as the capacity of the magnetooptical storage apparatus increases, the photoelectric conversion apparatus further increases. Increased operating speed is required.
For example, in an information reading unit that reads information from a quadruple-density magneto-optical storage medium, the current-voltage conversion circuits 2 and 4 and the differential amplifier 5 are not coupled by a capacitor in order to increase the operation speed. A method of connecting the outputs of these circuits 2 and 4 directly to the input of the differential amplifier 5 is adopted. This is a so-called direct-coupled amplifier type.
[0011]
On the other hand, since the information reading unit of the magneto-optical storage device including the single-density magneto-optical storage medium can adopt a capacitor coupling method, the output offset generated between the outputs of the current-voltage conversion circuits 2 and 4 Can be cut by a capacitor. However, in the information reading unit that reads information from the quadruple-density magneto-optical storage medium, it is impossible to employ capacitor coupling that hinders the increase in operation speed. Therefore, a new method can be used between the outputs of the current-voltage conversion circuits 2 and 4. The output offset must be removed. However, there is a problem that if the current-voltage conversion circuits 2 and 4 are saturated, the recovery of the operation of the amplifier 6 is delayed and the high-speed read operation is hindered.
[0012]
The present invention was created in view of the problems of the conventional example. Even when the input current becomes large, the circuit unrelated to the input current is saturated without saturating the current-voltage conversion amplifier. It is an object of the present invention to provide a current-voltage conversion circuit and a photoelectric conversion device that can output a constant voltage.
[0013]
[Means for Solving the Problems]
As shown in FIG. 1, the current / voltage circuit of the present invention is connected between a first amplifier circuit for amplifying an input current and an input and an output of the first amplifier circuit. A feedback resistor, a rectifier connected in parallel to the feedback resistor, and an input of the first amplifier circuit; absorption Do Current absorption circuit And said Current absorption circuit A switch circuit for selecting whether or not to operate, One end connected to the first power supply line, one end connected to the other end of the first resistor and the output unit, a control end connected to the bias source, and the other end connected to the first power line An output transistor connected to the output of one amplifier circuit, and a second resistor having one end connected to the other end of the output transistor and the other end connected to a second power supply line. A second amplifier circuit When the input current is larger than a predetermined value, the switch circuit operates the current absorption circuit to absorb the input current and input the input of the first amplifier circuit to the rectifier element and the feedback resistor. And the first amplifier circuit is desaturated and the operation of the output transistor is stopped, whereby the output voltage of the second amplifier circuit is fixed to a predetermined voltage value, and the input current is Is smaller than a predetermined value, the switch circuit stops the operation of the current absorption circuit and operates the output transistor, whereby the output voltage of the second amplifier circuit is changed to that of the first amplifier circuit. Set the voltage according to the output voltage It is characterized by that.
[0015]
In the current-voltage conversion circuit according to the present invention, the rectifier element includes n diodes, and the number n is equal to that of the second amplifier circuit. output The saturation voltage of the transistor is Vsat, the potential of the first power supply line is Vcc, and the value of the first resistor is R1. age , The value of the second resistor is R2 age When the input voltage of the second amplifier circuit is VA and the voltage drop in the forward direction of the diode is VF,
Vsat ≧ [Vcc−R1 · (VA / R2)] − nVF
It is determined by the relational expression.
[0016]
The first photoelectric conversion device of the present invention includes a first light receiving element that receives light and generates a current, and a second light receiving element that receives a reflected light of the light and generates a current having a phase opposite to the current. A first current-voltage conversion circuit that converts an output current of the first light receiving element into a voltage, a second current-voltage conversion circuit that converts an output current of the second light receiving element into a voltage, and the first And the output of the second current-voltage conversion circuit Voltage And the first and second current-voltage conversion circuits are any of the current-voltage conversion circuits of the present invention.
[0017]
The second photoelectric conversion device of the present invention includes a first light receiving element that receives light and generates a current, and a second light receiving element that receives a reflected light of the light and generates a current having a phase opposite to the current. A first current-voltage conversion circuit that converts an output current of the first light receiving element into a voltage, a second current-voltage conversion circuit that converts an output current of the second light receiving element into a voltage, and the first And a reference power source for generating a reference voltage required for the addition operation of the outputs of the second current-voltage conversion circuit, and an adder for adding the output voltages of the first and second current-voltage conversion circuits based on the reference voltage And the first and second current / voltage conversion circuits and the reference power source are each formed of any one of the current / voltage conversion circuits according to the present invention.
[0018]
Next, the operation of the current-voltage conversion circuit will be described. For example, a case where the current-voltage conversion circuit of the present invention is applied to an information reading unit of a magneto-optical storage device will be described as an example. In the magneto-optical storage device, a large current that saturates the first amplifier circuit is input in a write mode for writing information to the magneto-optical storage medium or an erase mode for erasing this information. In addition, since reading is performed immediately after the write mode or erase mode of the magneto-optical storage device, recovery of the amplification operation of the first amplifier circuit must be accelerated.
[0019]
Therefore, it is necessary to continue the amplification operation of the first amplifier circuit even in the write mode and the erase mode. In other words, it is necessary to place the first amplifier circuit unsaturated. Therefore, such a large current flows into the constant current source so that the first amplifier circuit is not saturated. For this purpose, the switch circuit is turned on to operate the constant current source in the write mode or the erase mode. When the switch circuit is turned on, this large current flows into the constant current source. At the same time, a current flows through the rectifying element connected in parallel with the feedback resistor. When the current flows through the rectifying element, the input voltage of the second amplifier circuit increases.
[0020]
When the input voltage exceeds the operation reference voltage of the second amplifier circuit, the second amplifier circuit stops the amplification operation. As a result, even if a large current that saturates the first amplifier circuit is input to the first amplifier circuit, the output of the second amplifier circuit does not change. Therefore, the output of the second amplifier circuit can be fixed when a large current flows into the first amplifier circuit during the write mode or erase mode in the magneto-optical storage device.
[0021]
In the read mode for reading information from the magneto-optical storage medium and the verify mode for verifying information, the current input to the first amplifier circuit is several thousandths of the current in the previous write mode or erase mode. To a degree. The minute current i flows into the feedback resistor RF and is amplified by the first amplifier circuit. The output voltage VA of the first amplifier circuit is i × RF, and becomes the input voltage of the second amplifier circuit. Since a reverse bias is applied to the rectifying element, no current flows through the rectifying element. The input voltage of the second amplifier circuit is lower in the read mode and verify mode than in the write mode and erase mode.
[0022]
Therefore, when the input voltage becomes lower than the operation reference voltage of the second amplifier circuit, the second amplifier circuit performs an amplification operation. As a result, since the second amplifier circuit amplifies the output voltage VA of the first amplifier circuit, the voltage obtained by amplifying the output voltage VA of the first amplifier circuit is used in the read mode or verify mode of the magneto-optical storage device. It can be obtained from two amplifier circuits.
[0023]
As described above, in the current-voltage conversion circuit of the present invention, when the input current to the first amplifier circuit becomes large, the switch circuit is turned on to flow current into the constant current source, and the rectifying element is The input voltage of the second amplifier circuit is increased while the one amplifier circuit is not saturated. For this reason, since the amplification operation of the second amplifier circuit can be stopped by an input voltage exceeding the operation reference voltage, the output of the second amplifier circuit can be fixed.
[0024]
Further, when the input current to the first amplifier circuit is small, the non-saturated first amplifier circuit can be quickly restored to the amplification operation by turning off the switch circuit. As the first amplifier circuit recovers the amplification operation early, the second amplifier circuit amplifies the output of the first amplifier circuit.
In the current-voltage conversion circuit of the present invention, the second amplifier circuit has first and second resistors and a base-grounded transistor, and the rectifier element has n diodes. Since the number n of diodes is determined by the above relational expression, the operation of the transistors of the second amplifier circuit can be stopped by the n diodes. When the operation of the transistor of the second amplifier circuit is stopped, the output of the second amplifier circuit can be fixed.
[0025]
Next, the operation of the first photoelectric conversion device of the present invention will be described. First, the first light receiving element receives light and generates a current, and the second light receiving element receives the reflected light of the light and generates a current having a phase opposite to the output current of the first light receiving element. The first current-voltage conversion circuit comprising the current-voltage conversion circuit of the present invention converts the output current of the first light receiving element into a voltage. In this case, the first current-voltage conversion circuit operates the constant current source by turning on the switch circuit when the input current from the first light receiving element to the first amplifier circuit becomes large. While the current flows in, the rectifying element desaturates the first amplifier circuit, stops the operation of the second amplifier circuit, and fixes the output of the second amplifier circuit.
[0026]
Similarly, when the input current from the second light receiving element to the first amplifier circuit becomes large, the second current-voltage conversion circuit including the current-voltage conversion circuit of the present invention turns on the switch circuit. The constant current source is operated to flow current, and the rectifying element desaturates the first amplifier circuit, stops the operation of the second amplifier circuit, and fixes the output of the second amplifier circuit.
[0027]
In addition, when the input current from the first and second light receiving elements to the first amplifier circuit of each current-voltage conversion circuit becomes small, each switch circuit is turned off, so that each current-voltage conversion circuit is not saturated. Since the first amplifier circuit rapidly recovers the amplification operation, the second amplifier circuit of each current-voltage conversion circuit outputs a voltage according to the output of the first amplifier circuit. The differential amplifier amplifies the output voltage of the first current-voltage conversion circuit and the output voltage of the opposite phase of the second current-voltage conversion circuit, and outputs the output voltage of the same phase to the amplification circuit of the next stage.
[0028]
As described above, in the first photoelectric conversion device of the present invention, the first and second current-voltage conversion circuits are configured by the current-voltage conversion circuit of the present invention, so that the first amplifier circuit of each current-voltage conversion circuit is configured. Since the non-saturation, the number of connected diodes, the output condition of the second amplifier circuit, and the like are aligned, the output offset between the first and second current-voltage conversion circuits can be reduced.
[0029]
Next, the operation of the second photoelectric conversion device of the present invention will be described. First, the first light receiving element receives light and generates a current, and the second light receiving element receives the reflected light of the light and generates a current having a phase opposite to the output current of the first light receiving element. The first current-voltage conversion circuit comprising the current-voltage conversion circuit of the present invention converts the output current of the first light receiving element into a voltage, and the second current-voltage conversion circuit comprising the current-voltage conversion circuit of the present invention is The output current of the second light receiving element is converted into a voltage. The reference power supply comprising the current-voltage conversion circuit of the present invention outputs a reference voltage to the adder. Then, the adder adds the output voltages of the first and second current-voltage conversion circuits based on the reference voltage.
[0030]
As described above, in the second photoelectric conversion device of the present invention, the first and second current-voltage conversion circuits and the reference power supply are configured from the current-voltage conversion circuit of the present invention, so that the first The non-saturation of the amplifier circuit, the number of connected diodes and the output condition of the second amplifier circuit, and the non-saturation of the first amplifier circuit of the reference power supply, the number of connected diodes and the output condition of the second amplifier circuit, etc. Therefore, even when the usage environment changes, a reference voltage having the same output condition as that of the first and second current-voltage conversion circuits can be output from the reference power source to the adder.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings. 1 to 7 are explanatory diagrams of a current-voltage conversion circuit and a photoelectric conversion device according to an embodiment of the present invention.
(1) First embodiment
FIG. 1 shows a configuration diagram of a current-voltage conversion circuit according to each embodiment of the present invention. The current-voltage conversion circuit can be applied to an information reading unit of a magneto-optical storage device. When the current-voltage conversion circuit is applied to the information reading unit, a photodiode as shown in the broken-line circle diagram is connected to the input of the current-voltage conversion circuit.
[0032]
Further, when the current-voltage conversion circuit is applied to the reference power source of the information reading unit, the photodiode is used without being connected. A photoelectric conversion device using these current-voltage conversion circuits will be described with reference to FIGS.
In FIG. 1, 11 is a transimpedance amplifier that amplifies an input current, and is an example of a first amplifier circuit. A circuit example of the transimpedance amplifier 11 will be described in detail with reference to FIG.
[0033]
RF is a feedback resistor that feeds back the output voltage of the amplifier 11 to the input, and is also called transimpedance. The feedback resistor is connected between the input and output of the amplifier 11. A clamp circuit 12 clamps the voltage applied across the feedback resistor to make the amplifier non-saturated. The clamp circuit 12 has n diodes D1, D2,. How to determine the number of diode stages will be described later. The diodes D1, D2,... Are examples of rectifying elements, and are connected in parallel to the feedback resistor. The rectifying element may be a diode-connected field effect transistor.
[0034]
Reference numeral 13 denotes a current absorption circuit that flows in the input current when the input current increases. The current absorption circuit 13 is connected to the input of the amplifier 11. The current absorption circuit 13 includes a constant current source 20, a current mirror circuit composed of npn type bipolar transistors Q21 and Q22, an npn type bipolar transistor Q23 for operating the current mirror circuit, and a resistor R21 for supplying a base voltage to this Q23, R22.
[0035]
Reference numeral 14 denotes a switch circuit for selecting whether or not to operate the current absorption circuit 13. The switch circuit 14 is operated by an external control signal. The switch circuit 14 is turned on when the input current is large. Since the current absorption circuit 13 operates when the switch circuit 14 is turned on, the current flows into the constant current source 20. Turn off when input current is small. When the switch circuit 14 is turned off, the current absorption circuit 13 is deactivated, and the current is input to the amplifier 11.
[0036]
The switch circuit 14 saturates and outputs a constant voltage when the clamp circuit 12 and the current absorption circuit 13 are operated. When the clamp circuit 12 and the current absorption circuit 13 are not operated, the voltage 15 is output according to the output of the amplifier 11. Is an output enable circuit. The output enable circuit 15 is an example of a second amplifier circuit, and includes resistors R1 and R2, an npn-type bipolar transistor Q1, and a bias source (VREF).
[0037]
One end of the resistor R1 is connected to the power supply line (first power supply line) VCC, and the other end is connected to the output OUT and the collector of the transistor Q1. The base of the transistor Q1 is connected to the bias source, and the emitter is connected to the output of the amplifier 11 and one end of the resistor R2. The other end of the resistor R2 is connected to a ground line (second power supply line) GND.
[0038]
Next, how to determine the number n of clamping diodes will be described. First, the saturation voltage of the transistor Q1 is Vsat, the potential of the power supply line VCC is VCC, the value of the resistor R1 is R1, the value of the resistor R2 is R2, the input voltage of the amplifier 11 is VA, and the voltage drop in the forward direction of the diode Is VF, the number n of diodes for clamping is given by the following equation:
Vsat ≧ [VCC−R1 · (VA / R2)] − nVF (1)
Decide by. The number n of diodes is actually determined using this equation (1). The saturation voltage Vsat of the transistor Q1 is set to 0.3V, and the forward voltage drop VF of the diode is set to 0.7V. Further, the output of the amplifier 11 becomes almost VA due to the nature of the transimpedance amplifier. In addition, the current flowing through the resistor R2 is expressed by equation (2), that is,
VA / R2 (2)
Given by. Further, the collector voltage VC of the transistor Q1 is expressed by the following equation (3), that is,
VC = [VCC-R1 · (VA / R2)] (3)
It is. Here, when the switch circuit 14 is turned on to operate the diodes D1, D2,..., The emitter voltage VE of Q1 is expressed by the following equation (4):
VE = 0.7 × n (4)
It becomes. Therefore, the relational expression of the saturation voltage Vsat of Q1 from the expressions (3) and (4) is
0.3 ≧ [VCC-R1 · (VA / R2)] − n × 0.7 (5)
It becomes. What is necessary is just to determine the number of diodes which satisfy (5) Formula. When the potential VCC of the power supply line VCC is 5V, R1 = 66Ω, the resistance R2 is R2 = 28Ω, and VA is 1.4V, the number of diodes is two. In this embodiment, the case where there are two diodes will be described as an example.
[0039]
FIG. 2 shows an example of the internal configuration of the transimpedance amplifier. In FIG. 2, the transimpedance amplifier 11 includes load resistors R11 and R12, an input transistor Q11 whose emitter is grounded, and an output transistor Q12 that constitutes an emitter follower circuit. RF is a feedback resistor, and D1 and D2 are clamping diodes. The transistor Q11 performs an amplification operation with an input impedance of 10Ω and an input voltage VA of 0.7V, for example. The amplifier 11 prevents the transistor Q11 from being saturated by turning on the diodes D1 and D2 when a large input current is input.
[0040]
Next, the operation of the current-voltage conversion circuit will be described with reference to FIG. The operating condition is that the voltage VB of the bias source VREF is about 2V. The power supply line VCC is 5V. First, when the input current to the amplifier 11 is large enough to saturate the input transistor of the amplifier, the switch circuit 14 is turned on. Then, the constant current source 20 operates and a large input current is absorbed by the constant current source 20. The diodes D1 and D2 connected in parallel to the feedback resistor RF clamp the voltage VA = 1.4 V applied to both ends of the feedback resistor RF to make the amplifier 11 non-saturated. At this time, when the diodes D1 and D2 operate, the transistor Q1 of the output enable circuit 15 is saturated, and Q1 is cut off. In other words, D1 and D2 fix the emitter voltage of the transistor Q1 to 1.4 V, which is about twice as high as 0.7 V in normal operation, so that Q1 is cut off. As a result, the collector current does not flow through Q1, so that the output of the output enable circuit 15 outputs the potential of the power supply line VCC as it is as the output voltage VOUT.
[0041]
Next, when the input current to the amplifier 11 becomes small, the switch circuit 14 is turned off. Then, since the constant current source 20 does not operate, a small input current is input to the amplifier 11. Since the unsaturated amplifier 11 recovers the amplification operation at an early stage, the amplifier 11 amplifies the input current, and the transistor Q1 outputs a voltage according to the output VA (eg, 0.7 V) of the amplifier 11. Here, assuming that the emitter resistance of the transistor Q1 is re, Q1 outputs a voltage of [R1 / (re + R2)] × VA.
[0042]
As described above, in the current-voltage conversion circuit according to each embodiment of the present invention, when the input current to the amplifier 11 increases, the switch circuit 14 is turned on to operate the constant current source 20 to generate the current. In addition, the diodes D1 and D2 desaturate the amplifier 11, stop the operation of the transistor Q1 unrelated to the input current, and fix the output of the output enable circuit 15. Further, when the input current to the amplifier 11 becomes small, the non-saturated amplifier 11 can be suddenly restored to the amplification operation by turning off the switch circuit 14, so that the transistor Q1 has the output VA of the amplifier 11. Voltage [R1 / (re + R2)] × VA is output.
[0043]
In each embodiment of the present invention, the output enable circuit 15 includes resistors R1 and R2 and a base-grounded transistor Q1, and the clamp circuit includes two diodes D1 and D2 determined by the equation (1). have. Therefore, the operation of the transistor Q1 can be stopped by the voltage generated by the current flowing through the diodes D1 and D2. By stopping the operation of Q1, the output of the output enable circuit 15 can be fixed.
[0044]
Next, the information reading unit of the magneto-optical storage device to which the current-voltage conversion circuit of the present invention is applied will be described. FIG. 4A is a configuration diagram of the information reading unit of the magneto-optical storage device according to the first embodiment of the present invention. FIG. 5 is a diagram for explaining the operation of the information reading unit.
The information reading unit is an example of a first photoelectric conversion device. In FIG. 4A, reference numeral 21 denotes a photodiode that generates current upon receiving light from the magneto-optical storage medium of the magneto-optical storage device, and is an example of a first light receiving element. Similarly, reference numeral 22 denotes a photodiode that receives reflected light from the magneto-optical storage medium and generates a current having a phase opposite to that of the output current of the photodiode 21, and is an example of a second light receiving element. Reference numeral 23 denotes a first current-voltage conversion circuit that converts the output current of the photodiode 21 into a voltage, and is composed of the current-voltage conversion circuit of the present invention.
[0045]
Reference numeral 24 denotes a second current-voltage conversion circuit for converting the output current of the photodiode 22 into a voltage, which comprises the current-voltage conversion circuit of the present invention. The current-voltage conversion circuits 23 and 24 each include the amplifier 11, the feedback resistor RF, the clamp circuit 12, the current absorption circuit 13, the switch circuit 14, and the output enable circuit 15 described with reference to FIG. The clamp circuit 12 of the current-voltage conversion circuits 23 and 24 also has diodes D1 and D2, and the current absorption circuit 13 has a constant current source 20. Reference numeral 25 denotes a differential amplifier that amplifies the output currents of the current-voltage conversion circuits 23 and 24.
[0046]
Next, the magneto-optical storage medium of the magneto-optical storage device will be described. FIG. 5A is a format showing the data structure of the magneto-optical storage medium. In FIG. 5A, ID (N) is an area provided with an individual identification code of the magneto-optical storage medium. ID (N) is read at the time of reading. The VFO is an area where a voltage oscillation code for operating a PLL (phase loop fixed) circuit of the magneto-optical storage device is provided. The voltage oscillation code is read at the time of reading. MD is an area for storing information (DATA). In the MD area, information is written during writing, information is read during reading, information is erased during erasing, and information is verified during verification. A large current flows in the direction of the amplifier 11 during this write or erase. An empty space is provided between ID (N) and ID (N + 1). During this period, the current-voltage conversion circuit must return the clamped amplifier 11 to the amplification operation. A small current flows in the direction of the amplifier 11 even when there is no signal.
[0047]
Next, the operation of the information reading unit of the magneto-optical storage device according to the first embodiment of the present invention will be described with reference to FIG. First, the operation of the information reading unit during writing or erasing will be described. In FIG. 5B, during writing or erasing, the input current from the photodiode 21 to the amplifier 11 of the current-voltage conversion circuit 23 increases. Usually, during writing or erasing, the photodiode 21 generates a current of 10 μA to 100 μA. Therefore, by turning on the switch circuit 14 of the current-voltage conversion circuit 23, the constant current source 20 is operated and this current flows. At the same time, the diodes D1 and D2 of the current-voltage conversion circuit 23 desaturate the amplifier 11 and stop the operation of the output enable circuit 15. At this time, the emitter voltage of the transistor Q1 is fixed at 1.4 V by the diodes D1 and D2 of the clamp circuit 12, and Q1 is cut off. As a result, no collector current flows through Q1, and the output enable circuit 15 of the current-voltage conversion circuit 23 fixes the output at the power supply voltage VCC.
[0048]
Similarly, the input current from the photodiode 22 to the amplifier 11 of the current-voltage conversion circuit 24 is also increased. Therefore, by turning on the switch circuit 14 of the current-voltage conversion circuit 24, the constant current source 20 is operated and current flows. At the same time, the diodes D1 and D2 of the current-voltage conversion circuit 24 desaturate the amplifier 11 and stop the operation of the output enable circuit 15 unrelated to the input current. As a result, the output of the output enable circuit 15 of the current-voltage conversion circuit 24 is fixed.
[0049]
In the magneto-optical storage device, as described in the format of FIG. 5A, a large current flows in the direction of the amplifier 11 at the time of writing or erasing, and reading is performed immediately after that. Therefore, in FIG. 5B, it is necessary to recover the operation of each amplifier 11 of the current-voltage conversion circuits 23 and 24 using the period of the empty space. For this purpose, the switch circuits 14 of the current-voltage conversion circuits 23 and 24 are turned off. As a result, each of the non-saturated amplifiers 11 of the current-voltage conversion circuits 23 and 24 rapidly recovers the amplification operation.
[0050]
In FIG. 5B, Td is a delay time from when the switch circuit 14 is turned off until the amplifier 11 recovers to the amplification operation. The delay time Td must be within the empty space period, and the shorter the Td, the shorter the empty space period can be achieved, thereby enabling high-speed reading processing.
At the time of reading, the input current from the photodiode 21 to the amplifier 11 of the current-voltage conversion circuit 23 and the input current from the photodiode 22 to the amplifier 11 of the current-voltage conversion circuit 24 are reduced. The current at the time of reading is as small as several hundred nA to several μA compared with the current of 10 μA to 100 μA at the time of writing or erasing.
[0051]
For example, the photodiode 21 receives light from the ID region of the magneto-optical storage medium and generates a current. The photodiode 22 passes this light through a polarization beam splitter as described with reference to FIG. Light is received, and a current having a phase opposite to that of the output current of the photodiode 21 is generated. Then, the current-voltage conversion circuit 23 converts the output current of the photodiode 21 into a voltage, and the current-voltage conversion circuit 24 converts the output current of the photodiode 22 into a voltage.
[0052]
The output enable circuit 15 of each of the current-voltage conversion circuits 23 and 24 outputs a voltage according to the output of the amplifier 11. The differential amplifier 25 amplifies the output voltage of the current-voltage conversion circuit 23 and the output voltage of the opposite phase of the current-voltage conversion circuit 24, and outputs the output voltage of the same phase to the next-stage amplifier.
Thus, in the photoelectric conversion apparatus according to the first embodiment of the present invention, each of the current-voltage conversion circuits 23, 24 is configured by configuring the current-voltage conversion circuits 23, 24 from the current-voltage conversion circuit of the present invention. Since the amplifier 11 is not saturated, the number of diodes connected to the clamp circuit 12, the output condition of the output enable circuit 15, and the like are uniformed, the operation switching time of the amplifier 11 is shortened and the current-voltage conversion circuits 23 and 24 are connected. The output offset can be reduced.
[0053]
Next, the result of simulation of the relationship between the number of clamping diodes and the output offset will be described. 6 and 7 are diagrams showing output voltage levels of the current-voltage conversion circuit according to the present invention. 6 and 7, the vertical axis represents the output voltage of the current-voltage conversion circuit, and the horizontal axis represents the application time. VOUT1x is the output voltage level of the current-voltage conversion circuit 23, and VOUT2x is the output voltage level of the current-voltage conversion circuit 24. x takes 1 and 2. x = 1 is the case where there is one clamping diode, and the output voltage level of the current-voltage conversion circuit 23 is described as VOUT11, and similarly, the output voltage level of the current-voltage conversion circuit 24 is described as VOUT21. x = 2 is the case where there are two clamping diodes, the output voltage level of the current-voltage conversion circuit 23 is described as VOUT12, and the output voltage level of the current-voltage conversion circuit 24 is described as VOUT22.
[0054]
The simulation operating condition is that a common constant current source 26 is connected to the inputs of the current-voltage conversion circuits 23 and 24, and currents of 400, 200, 100, and 50 μA are input from the constant current source 26. Then, the output voltages VOUT12, VOUT22, VOUT11, and VOUT21 of the current-voltage conversion circuits 23 and 24 are obtained when the number of clamping diodes is two and one. Next, an output offset Voff2 was obtained from the output voltages VOUT12 and VOUT22, Voff1 was obtained from VOUT11 and VOUT21, and the effect of the number of diodes installed was evaluated by comparing Voff1 and Voff2.
[0055]
In FIG. 6, when there are two clamping diodes and the currents are 400, 200, 100, and 50 μA, VOUT12 becomes 2.895V on average. Moreover, VOUT22 became 2.825V. The output offset Voff2 was 70 mV.
In FIG. 7, when there is one clamping diode and the current is 400, 200, 100, 50 μA, VOUT12 is 2.932 V on average. Moreover, VOUT22 became 2.778V. The output offset Voff1 was 154 mV.
[0056]
From these two simulation results, it has become clear that the output offset can be reduced to ½ when the number of diodes is two compared to when the number of diodes is one. When the output offset is reduced in this way, the operation speed of the direct connection amplifier that operates at the rising edge of the signal can be increased.
(2) Second embodiment
FIG. 4B is a configuration diagram of the information reading unit of the magneto-optical storage device according to the second embodiment of the present invention. In the second embodiment, unlike the first embodiment, a reference power supply having the same configuration as that of the current-current conversion circuit is connected to the information reading unit.
[0057]
That is, the information reading unit according to the second embodiment is similar to the photodiode 31 that generates current upon receiving light from the magneto-optical storage medium of the magneto-optical storage device in FIG. A photodiode 32 that receives light reflected from the storage medium and generates a current having a phase opposite to that of the output current of the photodiode 31; a first current-voltage conversion circuit 33 that converts the output current of the photodiode 31 into a voltage; A second current-voltage conversion circuit 34 that converts the output current of the photodiode 32 into a voltage, a reference power source 35 that generates a reference voltage (VR) required for the addition operation of the outputs of the current-voltage conversion circuits 33 and 34, It comprises an addition amplifier 36 for adding the output voltages of the current-voltage conversion circuits 33 and 34 based on the reference voltage. The current / voltage conversion circuits 33 and 34 and the reference power source 35 are formed of the current / voltage conversion circuit of the present invention.
[0058]
That is, the current-voltage conversion circuits 33 and 34 and the reference power supply 35 have the amplifier 11, the feedback resistor RF, the clamp circuit 12, the current absorption circuit 13, the switch circuit 14, and the output enable circuit 15 as described in FIG. Yes. The current-voltage conversion circuits 33 and 34 and the clamp circuit 12 of the reference power supply 35 also have diodes D1 and D2, and the current absorption circuit 13 has a constant current source 20. Other configurations and components having the same names as those of the first embodiment have the same functions, and thus description thereof is omitted.
[0059]
Next, the operation of the information reading unit of the magneto-optical storage device according to the second embodiment of the present invention will be described. First, the photodiode 31 receives light and generates a current, and the photodiode 32 receives the reflected light of the light and generates a current having a phase opposite to the output current of the photodiode 31. The current-voltage conversion circuit 33 converts the output current of the photodiode 31 into a voltage, and the current-voltage conversion circuit 34 converts the output current of the photodiode 32 into a voltage. Then, the reference power source 35 outputs a reference voltage to the addition amplifier 36. Then, the addition amplifier 36 adds the output voltages of the current-voltage conversion circuits 33 and 34 based on the reference voltage.
[0060]
In this way, in the photoelectric conversion device according to the second embodiment of the present invention, the first and second current-voltage conversion circuits 33 and 34 and the reference power supply 35 are configured by the current-voltage conversion circuit of the present invention. The non-saturation of the amplifier 11 of each current-voltage conversion circuit 33, 34, the number of diodes connected to the clamp circuit 12, the output condition of the output enable circuit 15, etc., the non-saturation of the amplifier 11 of the reference power supply, Since the number of connections and the output conditions of the output enable circuit 15 can be made uniform, the reference voltage of the same output conditions as the current-voltage conversion circuits 33 and 34 can be set even when the usage environment such as temperature and input current strength changes. It can be output from the reference power source 35 to the adder 36.
[0061]
Thereby, the addition operation of the adder 36 due to the change in the use environment can be performed accurately. Therefore, it is possible to provide a high-accuracy and high-speed information reading unit using the current-voltage conversion circuits 33 and 34 and the reference power supply 35. As a result, the information reading unit of the magneto-optical storage device in which the storage density is double dense and quadruple dense can be sufficiently dealt with.
[0062]
【The invention's effect】
As described above, according to the current-voltage conversion circuit of the present invention, when the input current to the first amplifier circuit becomes large, the constant current source is operated by turning on the switch circuit to generate the current. At the same time, the rectifying element desaturates the first amplifier circuit and stops the operation of the second amplifier circuit regardless of the input current. In addition, when the input current to the first amplifier circuit is small, the non-saturated first amplifier circuit can be rapidly restored to the amplification operation by turning off the switch circuit.
[0063]
In the photoelectric conversion device of the present invention, the first and second current-voltage conversion circuits are constituted by the current-voltage conversion circuit of the present invention, so that the first amplifier circuit of each current-voltage conversion circuit is not saturated and the number of connected diodes. Since the output conditions of the second amplifier circuit and the like are made uniform, the output offset between the first and second current-voltage conversion circuits can be reduced.
[0064]
In another photoelectric conversion device of the present invention, the first and second current-voltage conversion circuits and the reference power supply are configured by configuring the first and second current-voltage conversion circuits and the reference power supply from the current-voltage conversion circuit of the present invention. Therefore, the first and second current-voltage conversion circuits can be matched even when the usage environment changes. The reference voltage generated under the same conditions can be output to the adder.
[0065]
An information reading unit of a magneto-optical storage device with a high density can be provided by a photoelectric conversion device capable of high-speed reading using such a current-voltage conversion circuit.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a current-voltage conversion circuit according to each embodiment of the present invention.
FIG. 2 is an internal configuration diagram of a transimpedance amplifier according to each embodiment of the present invention.
FIG. 3 is an operation explanatory diagram of a current-voltage conversion circuit according to each embodiment of the present invention.
FIG. 4 is a configuration diagram of a photoelectric conversion apparatus according to the first and second embodiments of the present invention.
FIG. 5 is an operation explanatory diagram of an information reading unit according to the first embodiment of the present invention.
FIG. 6 is a diagram for comparing output voltages (after improvement) of the photoelectric conversion devices according to the embodiments of the present invention.
FIG. 7 is a diagram for comparing output voltages (before improvement) of photoelectric conversion devices according to respective embodiments of the present invention.
FIG. 8 is a configuration diagram of a photoelectric conversion device and a current-voltage conversion circuit according to a conventional example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1, 6, 11 ... Amplifier (1st amplifier circuit), 12 ... Clamp circuit, 9, 13 ... Current absorption circuit, 10, 14 ... Switch circuit, 15 ... Output enable circuit (2nd amplifier circuit), 1, 3, 21, 22, 31, 32 ... photodiodes, 2, 4, 22, 23, 33, 34 ... current-voltage conversion circuit, 5, 25 ... differential amplifier, 35 ... reference power supply, 36 ... summing amplifier, 8, D1, D2 ... Diode, 7, RF ... Feedback resistor, 20 ... Constant current source, Q1, Q11, Q12, Q21, Q22, Q23 ... Transistor, R1, R2, R11, R12, R21, R22 ... Resistor, 100 ... Light Magnetic storage medium, 200 ... information reading unit, 201 ... laser light source, 202, 206 ... polarization beam splitter, 203 ... mirror, 204 ... lens, 205 ... half-wave plate, 207 ... photoelectric conversion device.

Claims (5)

A first amplifier circuit for amplifying an input current;
A feedback resistor connected between an input and an output of the first amplifier circuit;
A rectifying element connected in parallel to the feedback resistor;
A current absorption circuit connected to the input of the first amplifier circuit and absorbing the input current ;
A switch circuit for selecting whether or not to operate the current absorption circuit ;
One end connected to the first power supply line, one end connected to the other end of the first resistor and the output unit, a control end connected to the bias source, and the other end connected to the first power line A second amplifier circuit having an output transistor connected to the output of the first amplifier circuit, and a second resistor having one end connected to the other end of the output transistor and the other end connected to a second power supply line. equipped with a door,
When the input current is larger than a predetermined value, the switch circuit operates the current absorption circuit to absorb the input current and input the first amplifier circuit by the rectifier element and the feedback resistor. By clamping, the first amplifier circuit is desaturated and the operation of the output transistor is stopped, thereby fixing the output voltage of the second amplifier circuit to a predetermined voltage value,
When the input current is smaller than a predetermined value, the switch circuit stops the operation of the current absorption circuit and operates the output transistor, whereby the output voltage of the second amplifier circuit is set to the first voltage. A current-voltage conversion circuit characterized by having a voltage corresponding to the output voltage of the amplifier circuit . The rectifying element is composed of n diodes, and the number n is:
The saturation voltage of the output transistor of the second amplifier circuit is V sat , the potential of the first power supply line is V cc , the value of the first resistor is R1, and the value of the second resistor is R2 When the input voltage of the second amplifier circuit is VA and the voltage drop in the forward direction of the diode is VF,
V sat ≧ [V cc −R1 · ( VA / R2 ) ] − nVF
The current-voltage conversion circuit according to claim 1, wherein the current-voltage conversion circuit is determined by the relational expression: 2. The current-voltage conversion according to claim 1, wherein when the input current is larger than a predetermined value, a write mode or an erase mode is selected, and when the input current is smaller than a predetermined value, a read mode or a verify mode is selected. circuit. A first light receiving element that receives light and generates a current; a second light receiving element that receives a reflected light of the light and generates a current having a phase opposite to the current; and an output current of the first light receiving element. a first current-voltage conversion circuit for converting the voltage, the second and the second current-voltage conversion circuit for converting the output current of the light receiving element into a voltage, said first and second current-voltage converting circuit of the output voltage And a differential amplifier for amplifying
4. A photoelectric conversion device, wherein the first and second current-voltage conversion circuits are each formed of the current-voltage conversion circuit according to claim 1, 2, or 3. A first light receiving element that receives light and generates a current; a second light receiving element that receives a reflected light of the light and generates a current having a phase opposite to the current; and an output current of the first light receiving element. A first current-voltage conversion circuit for converting the voltage into a voltage; a second current-voltage conversion circuit for converting the output current of the second light receiving element into a voltage; and outputs of the first and second current-voltage conversion circuits. A reference power source that generates a reference voltage required for the addition operation, and an adder that adds the output voltages of the first and second current-voltage conversion circuits based on the reference power source,
4. The photoelectric conversion apparatus according to claim 1, wherein the first and second current / voltage conversion circuits and the reference power source are each composed of the current / voltage conversion circuit according to claim 1, 2 or 3.

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