JP2008159106A - Light receiver for optical pickup and optical pickup device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To optimize the gain of a transimpedance type amplifier for a corresponding laser wavelength and the power of respective laser beams during recording and during reproduction while sharing a poststage amplifier. <P>SOLUTION: The light receiver for an optical pickup comprises: two light receiving parts (photodetectors A and (a)) provided corresponding to two kinds of wavelengths; preamplifiers 22 and 32 for which the corresponding one of the light receiving parts is connected to a feedback input part; an output buffer 23 for amplifying voltage signals V1 outputted from the preamplifiers 22 and 32; resistors 24a-35b for feedback connectable between the feedback input part of the preamplifiers 22 and 32 and the output part of the output buffer; and switching parts 26 and 36 for switching and connecting one of the resistors 24a-35b for the feedback between the preamplifier 22 in an ON state between the preamplifiers 22 and 32 and the output buffer. The output current of the light receiving part connected to the preamplifier 22 in the ON state is converted to a voltage and amplified, and outputted as voltage signals V3. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a light receiving device for an optical pickup provided with n light receiving portions corresponding to n (n is an integer of 2 or more) types of different wavelengths, and an optical pickup device provided with the light receiving device for the optical pickup. is there.

  As this type of light receiving device for an optical pickup, a light receiving device (light receiving amplifier element) disclosed in Japanese Patent Application Laid-Open No. 2004-22051 is known. This light receiving device is used in a reproducing apparatus for DVD and CD, and includes two light receiving portions for DVD and CD, and two transimpedance amplifiers for DVD and CD connected to each light receiving portion. And a voltage amplifier that amplifies the output of each transimpedance amplifier. In this case, each of the transimpedance amplifiers on the DVD side and CD side includes a differential, a current mirror circuit, an output buffer circuit, and a feedback circuit. In this case, the current mirror circuit is a common active load for the DVD-side and CD-side differentials, and the collector of one transistor, which is a common output for the two differentials, is one output buffer circuit. The signal is output via

The light receiving device includes two light receiving units for DVD and CD, and two transimpedance amplifiers for DVD and CD connected to the light receiving units, and feedback of each transimpedance amplifier. The constant (gain) is set to an optimum value for each laser wavelength for DVD and CD to obtain an output corresponding to the two-wavelength laser light, and at the same time, output stages of the two transimpedance amplifiers (the above output buffers) By making the circuit common, the expansion of the chip size is suppressed.
Japanese Unexamined Patent Application Publication No. 2004-22051 (page 4-7, FIG. 3-4)

  However, the conventional light receiving device has the following problems. In other words, this light receiving device is assumed to be used in a reproducing device. For this reason, when employed in a device that changes the power of laser light during recording and during reproduction, such as a recording / reproducing device for an information medium in which both recording and reproduction such as DVD-R and CD-R are performed, In this light receiving device, the gain of each transimpedance amplifier cannot be changed in accordance with the power of the laser beam. Therefore, this light receiving device has a problem that the circuit characteristics (particularly gain) of each transimpedance amplifier cannot be optimally adjusted according to the difference in power of each laser beam during recording and during reproduction. is doing.

  The present invention has been made to solve such a problem, and while sharing the latter-stage amplifier, the laser wavelength corresponding to the circuit characteristics (gain) of each transimpedance amplifier, as well as at the time of recording and reproduction The main object is to provide a light receiving device for an optical pickup and an optical pickup device that can be optimized for the power of each laser beam.

  In order to achieve the above object, a light receiving device for an optical pickup according to the present invention includes n light receiving portions provided corresponding to n (n is an integer of 2 or more) types of different wavelengths, and the feedback input portion. N front-stage amplifiers to which corresponding ones of the light-receiving units are respectively connected and capable of on / off control, one rear-stage amplifier that amplifies a voltage signal output from each front-stage amplifier, and each front-stage amplifier M (m is an integer of 2 or more) feedback resistors connectable between the feedback input section of each amplifier and the output section of the rear-stage amplifier, and one of the front-stage amplifiers in an on state. A switching unit that switches and connects one of the m feedback resistors between the feedback input unit of the two pre-stage amplifiers and the output unit of the post-stage amplifier, and the one in the on state The light reception connected to the preamplifier And outputs as a voltage signal and amplifies and converts the output current into a voltage.

  An optical pickup device according to the present invention includes the above-described optical pickup light receiving device, a light emitting unit that emits laser beams of n different wavelengths, and irradiates the optical disc with the laser light and reflects light from the optical disc. And an optical system for guiding the light to the light receiving device for optical pickup.

  According to the light receiving device for an optical pickup and the optical pickup device according to the present invention, for example, in each process of recording on a recordable DVD, reproducing a DVD, recording on a recordable CD, and reproducing a CD, The output current of the unit can be converted into a voltage, and can be amplified with an optimum gain determined in advance for each process and output as a voltage signal. Further, according to the light receiving device for optical pickup, since the n number of pre-stage amplifiers can be turned on / off, all of the remaining amplifiers are always turned off when one is turned on (operating state). As a result, one post-stage amplifier can be shared by n pre-stage amplifiers. Therefore, the increase in chip size can be suppressed.

  Hereinafter, the best mode of a light receiving device for an optical pickup and an optical pickup device according to the present invention will be described with reference to the accompanying drawings.

  First, the configuration of the optical pickup device 1 will be described with reference to the drawings.

  The optical pickup device 1 shown in FIG. 1 is capable of recording and recording such as a recordable DVD such as DVD-R, DVD + R, DVD-RW, DVD + RW, and DVD-RAM, and a recordable CD such as CD-R and CD-RW. An optical pickup device used in a recording / reproducing apparatus that performs a recording / reproducing operation on an information medium 10 in which both reproduction is performed and a reproducing operation on an information medium 10 in which only reproduction is performed on a DVD-ROM, CD-ROM, or the like As shown in the figure, the laser diode 2, the optical system 3, and a light receiving device for optical pickup (hereinafter also referred to as “light receiving device”) 4 are provided. In the following description, DVD-R, DVD + R, DVD-RW, DVD + RW, DVD-RAM, and DVD-ROM are also collectively referred to as “DVD” unless otherwise specified. Similarly, CD-R, CD-RW, and CD-ROM are collectively referred to as “CD”.

  The laser diode 2 (light emitting portion in the present invention) is an n (n is an integer of 2 or more. In this example, n = 2 as an example), and is a 780 nm band laser beam required for CD recording / reproduction. And 650 nm band laser light necessary for DVD recording / reproduction can be output (emitted) from one package. As an example, the optical system 3 includes a prism 3a and a condenser lens 3b. Further, the optical system 3 condenses the laser light output from the laser diode 2 by the condenser lens 3b and irradiates the information medium 10, and the laser light reflected by the information medium 10 is received by the light receiving device 4 by the prism 3a. The laser light is guided to the light receiving device 4 by being refracted to the side.

  As shown in FIGS. 2 and 3, the light receiving device 4 includes n (two in this example) light receiving units 11 and 12 provided corresponding to n different wavelengths, and a plurality (one example in this example). 8) conversion units 13a to 13h, which are configured as one semiconductor device (PDIC). In this case, the light receiving section 11 is a DVD light receiving section, and as shown in FIG. 3, a plurality of (in this example, 12 as an example) light receiving elements A, B, C, D, E1 to E4, F1. To F4. On the other hand, the light receiving part 12 is a light receiving part for CD, and as shown in the figure, a plurality (eight as an example) of light receiving elements a, b, c, d, e1, e2, f1, f2 is provided.

  The light receiving elements A to F4 constituting the light receiving unit 11 are arranged in three groups as shown in FIG. 3, and one group composed of the light receiving elements A, B, C, and D is A main light receiving group 11a in the light receiving unit 11 is configured. On the other hand, one group composed of the light receiving elements E1 to E4 arranged so as to sandwich the main light receiving group 11a and one group composed of the light receiving elements F1 to F4 are sub-light receiving groups 11b and 11c in the light receiving unit 11. Configure each. Similarly, the light receiving elements a to f2 constituting the light receiving unit 12 are also divided into three groups as shown in the figure, and one group constituted by the light receiving elements a, b, c, and d. Constitutes a main light receiving group 12 a in the light receiving unit 12. On the other hand, one group composed of the light receiving elements e1 and e2 arranged so as to sandwich the main light receiving group 12a and one group composed of the light receiving elements f1 and f2 are sub-light receiving groups 12b and 12c in the light receiving unit 12. Configure each.

  As shown in FIG. 4, the conversion unit 13 a among the conversion units 13 a to 13 h includes n (two in this example) transimpedance amplifier circuits (hereinafter also referred to as “first amplifier circuits”) 21, 31 and one second amplifying circuit 41 are provided. Specifically, the first amplifier circuit 21 includes a front-stage amplifier 22, an output buffer (rear-stage amplifier in the present invention) 23, two feedback circuits 24 and 25, and a changeover switch (switching section in the present invention) 26. Yes. The first amplifier circuit 31 includes a preamplifier 32, an output buffer 23, two feedback circuits 34 and 35, and a changeover switch (switching unit in the present invention) 36. In this example, an output buffer having a gain of 1 is used as the subsequent amplifier, but an amplifier having a gain exceeding 1 can also be used.

  In this case, the preamplifier 22 has the light receiving element A of the light receiving unit 11 connected to the inverting input unit (the feedback input unit in the present invention), the reference voltage Vref is input to the non-inverting input unit, and the output unit outputs It is configured to be connected to the input unit of the buffer 23. Further, the preamplifier 22 is configured to be able to be turned on / off by the control signal S1, and as an example in this example, is turned on when the control signal S1 is not input, and is turned off when the control signal S1 is input. On the other hand, the preamplifier 32 is connected to the light receiving element a of the light receiving unit 11 at the inverting input unit (feedback input unit in the present invention), the reference voltage Vref is input to the non-inverting input unit, and the output unit is the preamplifier. 22 is connected to the input section of the output buffer 23 in the same manner. Further, the preamplifier 32 is configured to be able to be turned on / off by the control signal S1. In this example, as an example, the front-stage amplifier 32 is turned on when the control signal S1 is input, and is turned off when the control signal S1 is not input. As described above, each of the preamplifiers 22 and 32 is configured such that one output buffer 23 can be shared because one of the upstream amplifiers 22 and 32 is always in an off state (non-operating state) when the other is on. ing. The reference voltage Vref is generated by a reference voltage generation unit (not shown) disposed inside the light receiving device 4. The output buffer 23 buffer-amplifies (amplifies with a gain of 1) the voltage signals V1 and V2 output from the pre-stage amplifiers 22 and 32, and outputs them to the second amplifier circuit 41.

  The feedback circuit 24 includes a resistor (a feedback resistor in the present invention) 24a and a capacitor 24b connected in parallel, and is configured to be connectable between the inverting input portion of the preamplifier 22 and the output portion of the output buffer 23. Thus, it functions as a feedback circuit when recording on a recordable DVD. The feedback circuit 25 includes a resistor (feedback resistor in the present invention) 25a and a capacitor 25b connected in parallel, and is configured to be connectable between the inverting input portion of the preamplifier 22 and the output portion of the output buffer 23. Thus, it functions as a feedback circuit when reproducing a DVD. The changeover switch 26 is composed of a semiconductor switch such as a transistor, and switches and connects the feedback circuit 24 between the inverting input portion of the pre-stage amplifier 22 and the output portion of the output buffer 23 when the control signal S2 is not input. When the control signal S2 is input, the feedback circuit 25 is switched and connected between the inverting input section of the preamplifier 22 and the output section of the output buffer 23.

  The feedback circuit 34 includes a resistor (feedback resistor in the present invention) 34a and a capacitor 34b connected in parallel, and is configured to be connectable between the inverting input portion of the preamplifier 32 and the output portion of the output buffer 23. Thus, it functions as a feedback circuit when recording on a recordable CD. The feedback circuit 35 includes a resistor 35 (a feedback resistor in the present invention) and a capacitor 35 b connected in parallel, and is configured to be connectable between the inverting input portion of the preamplifier 32 and the output portion of the output buffer 23. Thus, it functions as a feedback circuit when reproducing a CD. The changeover switch 36 is composed of a semiconductor switch such as a transistor, and switches and connects the feedback circuit 34 between the inverting input part of the pre-stage amplifier 32 and the output part of the output buffer 23 when the control signal S3 is not input. When the control signal S3 is input, the feedback circuit 35 is switched and connected between the inverting input section of the pre-stage amplifier 32 and the output section of the output buffer 23. In this case, the resistance values of the four resistors 24a, 25a, 34a, and 35a as feedback resistors (the numerical value m in the present invention is 4) are recorded at the time of recording on DVD, at the time of reproducing DVD, and at the time of recording on CD. When reproducing CD and CD, the gain (gain) of the converter 13a, specifically, the gain of the first amplifier circuit 21 composed of the pre-stage amplifier 22 and the output buffer 23, and the structure of the pre-stage amplifier 32 and the output buffer 23 The gain of the other first amplification circuit 31 is determined in advance by experiment, simulation, or the like so as to be optimized for the corresponding laser wavelength and the power of each laser beam at the time of recording and reproduction. Yes. The second amplifier circuit 41 amplifies the voltage signal V3 output from the output buffer 23 and outputs it as a voltage signal Va.

  The conversion unit 13a configured as described above converts the output current of the light receiving element A or the light receiving element a connected to one of the front-stage amplifier 22 and the front-stage amplifier 32 which are turned on by the control signal S1 into a voltage. And a gain obtained by multiplying the gain determined by any one of the feedback circuits 24, 25, 34, and 35 selected by the control signals S2 and S3 by the gain of the second amplification circuit 41, The converted voltage is amplified and output as a voltage signal Va.

  Next, the other conversion units 13b to 13h will be described. In addition, since the basic composition of each conversion part 13b-13h is the same as the conversion part 13a, only a different structure is demonstrated.

  First, as shown in FIG. 2, light receiving elements B and b are connected to the converting unit 13b instead of the light receiving elements A and a in the converting unit 13a. Specifically, the light receiving element B is connected to the inverting input unit of the front-stage amplifier 22 of the conversion unit 13b, and the light-receiving element b is connected to the inverting input unit of the front-stage amplifier 32. With this configuration, the conversion unit 13b converts the output current of the light receiving element B or the light receiving element b into a voltage, amplifies it, and outputs it as a voltage signal Vb.

  Similarly, the light receiving elements C and c are connected to the conversion unit 13c, and the light receiving element C is connected to the inverting input unit of the front-stage amplifier 22 of the conversion unit 13c. Connected to the inverting input. With this configuration, the converter 13c converts the light receiving element C or the output current of the light receiving element c into a voltage, amplifies it, and outputs it as a voltage signal Vc. The conversion unit 13d is connected to the light receiving elements D and d. The light receiving element D is connected to the inverting input unit of the front-stage amplifier 22 of the conversion unit 13d, and the light-receiving element d is the inverting input of the front-stage amplifier 32. Connected to the department. With this configuration, the converter 13d converts the light receiving element D or the output current of the light receiving element d into a voltage, amplifies it, and outputs it as a voltage signal Vd.

  On the other hand, as shown in FIG. 2, three light receiving elements E1, F1, and e1 are connected to the conversion unit 13e instead of the light receiving elements A and a in the conversion unit 13a. Specifically, the light receiving elements E1 and F1 are both connected to the inverting input unit of the front-stage amplifier 22 of the conversion unit 13e, and the light-receiving element e1 is connected to the inverting input unit of the front-stage amplifier 32. With this configuration, the converter 13e converts the total output current of the light receiving elements E1 and F1 or the output current of the light receiving element e1 into a voltage, amplifies it, and outputs it as a voltage signal Ve. Similarly, light receiving elements E3, F3, and e2 are connected to the conversion unit 13f, and the light receiving elements E3 and F3 are both connected to the inverting input unit of the pre-stage amplifier 22 of the conversion unit 13f. e <b> 2 is connected to the inverting input section of the pre-stage amplifier 32. With this configuration, the converter 13f converts the output current of the light receiving elements E3 and F3 or the output current of the light receiving element e2 into a voltage, amplifies it, and outputs it as a voltage signal Vf.

  Further, the light receiving elements E2, F2, and f1 are connected to the conversion unit 13g, and both of the light receiving elements E2 and F2 are connected to the inverting input unit of the pre-stage amplifier 22 of the conversion unit 13g, and the light receiving element f1 is , And connected to the inverting input section of the pre-stage amplifier 32. With this configuration, the converter 13g converts the output current of the light receiving elements E2 and F2 or the output current of the light receiving element f1 into a voltage and amplifies it to output it as a voltage signal Vg. In addition, the light receiving elements E4, F4, and f2 are connected to the conversion unit 13h, and the light receiving elements E4 and F4 are both connected to the inverting input unit of the pre-stage amplifier 22 of the conversion unit 13h, and the light receiving element f2 is , And connected to the inverting input section of the pre-stage amplifier 32. With this configuration, the converter 13h converts the output current of the light receiving elements E4 and F4 or the output current of the light receiving element f2 into a voltage, amplifies it, and outputs it as a voltage signal Vh.

  Next, the operation of the optical pickup device 1 will be described for recording on a recordable DVD, reproducing a DVD, recording on a recordable CD, and reproducing a CD.

  First, when recording on a recordable DVD such as a DVD-R, the wavelength of the laser light output from the laser diode 2 is set to the wavelength for DVD, and the power of the laser light is set to the power for DVD recording. The input states of the control signals S1 and S2 are “non-input” and “non-input”. The control signal S3 may be “input” or “non-input”. Hereinafter, the input states of the control signals S1, S2, S3 not specifically mentioned are not limited. As a result, the pre-stage amplifier 22 of each of the converters 13a to 13h is turned on, and the pre-stage amplifier 32 is turned off. Further, the changeover switch 26 shifts to a state indicated by a solid line in FIG. 4 and connects the feedback circuit 24 between the pre-stage amplifier 22 and the output buffer 23. Therefore, in the conversion unit 13a, the preamplifier 22 and the output buffer 23 convert the output current of the light receiving element A into a voltage, and amplify it with a gain determined by the feedback circuit 24 to obtain the voltage signal V3 as the second amplification circuit 41. Output to. Next, the second amplifier circuit 41 amplifies the input voltage signal V3 and outputs it as a voltage signal Va. Similarly, in the converters 13b, 13c, and 13d, the output currents of the light receiving elements B, C, and D are converted into voltages and amplified with a gain determined by the feedback circuit 24 to be voltage signals Vb, Output as Vc and Vd.

  On the other hand, in the conversion unit 13e, the pre-stage amplifier 22 and the output buffer 23 convert the total output current of the light receiving elements E1 and F1 into a voltage, and amplify it with a gain determined by the feedback circuit 24 to the second amplifier circuit 41. Output. Next, the second amplifier circuit 41 amplifies the input voltage signal V3 and outputs it as a voltage signal Ve. Similarly, in the conversion units 13f, 13g, and 13h, the total output current of the light receiving elements E3 and F3, the total output current of the light receiving elements E2 and F2, and the total output current of the light receiving elements E4 and F4 are converted into voltages. At the same time, it is amplified by a gain determined by the feedback circuit 24 and output as voltage signals Vf, Vg, Vh. In this case, the voltage signals Va to Vh output from the conversion units 13a to 13h are used as a data signal (RF signal) and a servo signal (focus signal, tracking signal). The same applies to DVD playback, CD recording, and CD playback described below.

  When reproducing a DVD, the power of the laser beam output from the laser diode 2 is set to the power for reproducing the DVD, and the input states of the control signals S1 and S2 are set to “non-input”, “input”. " As a result, the pre-stage amplifier 22 of each of the converters 13a to 13h is turned on, and the pre-stage amplifier 32 is turned off. Further, the changeover switch 26 shifts to a state indicated by a broken line in FIG. 4 and connects the feedback circuit 25 between the pre-stage amplifier 22 and the output buffer 23. Therefore, in the conversion unit 13a, the pre-stage amplifier 22 and the output buffer 23 convert the output current of the light receiving element A into a voltage, amplify it with a gain determined by the feedback circuit 25, and output it to the second amplification circuit 41. The second amplifier circuit 41 amplifies the input voltage signal V3 and outputs it as a voltage signal Va. Similarly, in the conversion units 13b, 13c, and 13d, the output currents of the light receiving elements B, C, and D are converted into voltages and amplified with a gain determined by the feedback circuit 25 to be voltage signals Vb, Output as Vc and Vd.

  On the other hand, in the conversion unit 13e, the pre-stage amplifier 22 and the output buffer 23 convert the total output current flowing through the light receiving elements E1 and F1 into a voltage and amplify it with a gain determined by the feedback circuit 25 to obtain a voltage signal V3. Output to the second amplifier circuit 41. Next, the second amplifier circuit 41 amplifies the input voltage signal V3 and outputs it as a voltage signal Ve. Similarly, in the conversion units 13f, 13g, and 13h, the total output current of the light receiving elements E3 and F3, the total output current of the light receiving elements E2 and F2, and the total output current of the light receiving elements E4 and F4 are converted into voltages. And amplified by a gain determined by the feedback circuit 25 and output as voltage signals Vf, Vg, Vh.

  When recording on a CD-R or other recordable CD, the wavelength of the laser light output from the laser diode 2 is set to the wavelength for CD, and the power of the laser light is set to the power for CD recording. The input states of the control signals S1 and S3 are “input” and “non-input”. As a result, the pre-stage amplifier 32 of each of the conversion units 13a to 13h is turned on, and the pre-stage amplifier 22 is turned off. Further, the changeover switch 36 shifts to a state indicated by a solid line in FIG. 4 and connects the feedback circuit 34 between the pre-stage amplifier 32 and the output buffer 23. Therefore, in the conversion unit 13a, the preamplifier 32 and the output buffer 23 convert the output current of the light receiving element a into a voltage and amplify it with a gain determined by the feedback circuit 34 to obtain the second amplification circuit as a voltage signal V3. The second amplifier circuit 41 amplifies the voltage signal V3 and outputs it as a voltage signal Va. Similarly, in the conversion units 13b, 13c, and 13d, the output currents of the light receiving elements b, c, and d are converted into voltages and amplified with a gain determined by the feedback circuit 34 to be voltage signals Vb and Vc. , Vd.

  On the other hand, in the conversion unit 13e, the pre-stage amplifier 32 and the output buffer 23 convert the output current of the light receiving element e1 into a voltage and amplify it with a gain determined by the feedback circuit 34 to obtain the second amplification circuit as a voltage signal V3. 41 is output. Next, the second amplifier circuit 41 amplifies the input voltage signal V3 and outputs it as a voltage signal Ve. Similarly, in the conversion units 13f, 13g, and 13h, the output currents of the light receiving elements e2, f1, and f2 are converted into voltages and amplified with a gain determined by the feedback circuit 34 to be voltage signals Vf and Vg. , Vh.

  Further, when reproducing a CD (for example, CD-R), the power of the laser beam output from the laser diode 2 is set to the power for reproducing the CD, and the input states of the control signals S1 and S3 are set to “ Input and input. As a result, the pre-stage amplifier 32 of each of the conversion units 13a to 13h is turned on, and the pre-stage amplifier 22 is turned off. Further, the changeover switch 36 shifts to a state indicated by a broken line in FIG. 4 and connects the feedback circuit 35 between the pre-stage amplifier 32 and the output buffer 23. Therefore, in the conversion unit 13a, the pre-stage amplifier 32 and the output buffer 23 convert the output current of the light receiving element a into a voltage and amplify it with a gain determined by the feedback circuit 35 to obtain the second amplification circuit as the voltage signal V3. The second amplifier circuit 41 amplifies the voltage signal V3 and outputs it as a voltage signal Va. Similarly, in the conversion units 13b, 13c, and 13d, the output currents of the light receiving elements b, c, and d are converted into voltages and amplified with a gain determined by the feedback circuit 35 to be voltage signals Vb and Vc. , Vd.

  On the other hand, in the conversion unit 13e, the pre-stage amplifier 32 and the output buffer 23 convert the output current of the light receiving element e1 into a voltage and amplify it with a gain determined by the feedback circuit 35 to obtain the second amplification circuit as a voltage signal V3. 41 is output. Next, the second amplifier circuit 41 amplifies the input voltage signal V3 and outputs it as a voltage signal Ve. Similarly, in the conversion units 13f, 13g, and 13h, the output currents of the light receiving elements e2, f1, and f2 are converted into voltages and amplified with a gain determined by the feedback circuit 35 to be voltage signals Vf and Vg. , Vh.

  As described above, according to the light receiving device 4 and the optical pickup device 1, each of the light receiving elements of the recording type DVD, the reproduction of the DVD, the recording onto the recording type CD, and the reproduction of the CD is performed. The output current is converted to voltage and amplified with the optimum gain determined in advance for each process (corresponding laser wavelength and gain optimized for the power of each laser beam during recording and playback). The voltage signals Va to Vh can be output. Further, according to the light receiving device 4, since the front-stage amplifiers 22 and 32 as the front-stage amplifiers of the two first amplifier circuits 21 and 31 can be controlled to be turned on / off, one of them is turned on ( As a result that the other can always be in an off state (non-operating state) in the operating state), one output buffer 23 can be shared by the two first amplifier circuits 21 and 31. Therefore, the increase in chip size can be suppressed.

  In addition, this invention is not limited to said structure. For example, the example in which the number m of feedback circuits in the first amplifier circuits 21 and 31 is set to 4 has been described above, but each process of recording on a recordable DVD, reproducing a DVD, recording on a recordable CD, and reproducing a CD When two of the optimum gains at the same time are the same, the number m of the feedback circuits in the first amplifier circuits 21 and 31 may be set to 3 by adopting a configuration in which the two share one feedback circuit. it can. Further, the number m of feedback circuits is set to 5 so that the gains of the first amplifier circuits 21 and 31 can be changed in more stages in response to a change in output current and a decrease in output current due to aged deterioration of the light receiving units 11 and 12. The above configuration can also be adopted.

  In addition, two (n = 2) two-wavelength laser diodes that output 780 nm band laser light necessary for CD recording / reproduction and 650 nm band laser light necessary for DVD recording / reproduction from one package. The light receiving device 4 including the light receiving portions 11 and 12 has been described as an example. However, the number of light receiving portions of the light receiving device can be three or more according to the type of wavelength of the received laser light. Of course, the present invention can also be applied to such cases. For example, in addition to the above-mentioned 780 nm band laser light and 650 nm band laser light, a three-wavelength laser diode that can also output 405 nm band laser light necessary for recording / reproduction of BD (Blu-ray Disc (registered trademark)) When used, a light receiving part for BD is added to the light receiving parts 11 and 12 to make the total number of light receiving parts three (n = 3), and a transimpedance type preamplifier for BD, for BD Each of the recording / reproducing feedback resistors and a switching unit for switching them are added to constitute a light receiving device.

1 is a configuration diagram of an optical pickup device 1. FIG. 2 is a configuration diagram of a light receiving device 4. FIG. 3 is a plan view of light receiving units 11 and 12. FIG. It is a block diagram of the conversion parts 13a-13h.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Optical pick-up apparatus 2 Laser diode 3 Optical system 4 Light-receiving device 21, 31 1st amplifier circuit (front stage amplifier)
22, 32 Front-stage amplifier 23 Output buffer (back-stage amplifier)
24a, 25a, 34a, 35a Resistance (Resistance for feedback)
26, 36 change-over switches A to F3, a to f2 light receiving elements V1 to V3 Voltage signal

Claims (2)

n light receiving sections provided corresponding to different wavelengths of n (n is an integer of 2 or more),
N pre-stage amplifiers, each of which is connected to a feedback input unit and corresponding to one of the light receiving units, and capable of on / off control;
One post-stage amplifier that amplifies the voltage signal output from each of the pre-stage amplifiers;
M (m is an integer of 2 or more) feedback resistors connectable between the feedback input section of each of the front-stage amplifiers and the output section of the rear-stage amplifier;
A switching unit that switches and connects one of the m feedback resistors between the feedback input unit of one front-stage amplifier in the on-state of each of the front-stage amplifiers and the output unit of the rear-stage amplifier. And
A light-receiving device for an optical pickup that converts an output current of the light-receiving unit connected to the one pre-stage amplifier in the on state into a voltage and amplifies and outputs the voltage signal. A light receiving device for an optical pickup according to claim 1;
a light emitting unit that emits laser light of n different wavelengths;
An optical pickup device comprising: an optical system that irradiates the optical disc with the laser light and guides reflected light from the optical disc to the light receiving device for optical pickup.

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