JP2009296221A - Optical signal receiver and electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress the occurrence of an undesired pulse by discriminating a transmission signal and a noise signal. <P>SOLUTION: The optical signal receiver 10 for outputting a pulse signal in accordance with an optical signal of a received rectangular wave includes: a PD (photodiode) 11 for outputting a current signal on the basis of the optical signal; a current-voltage conversion circuit 12 for converting an output current from the PD 11 into a voltage signal; an amplifier circuit 13 for amplifying the voltage signal converted by the current-voltage conversion circuit 12; a level shifting circuit 14 for generating a voltage signal 1b obtained by lowering a prescribed voltage level with respect to the voltage signal 1a amplified by the amplifier circuit 13; a delay circuit 15 for generating a voltage signal 1c obtained by delaying a prescribed time with respect to the voltage signal 1b generated by the level shifting circuit 14; and a signal comparator circuit 16 for comparing the voltage signal 1a with the voltage signal 1c, and outputting a pulse signal 1d when signal waveforms of both the voltage signal 1a and the voltage signal 1c intersect. Diffused external light noise in which a voltage signal waveform appears in a triangular wave or in a sinusoidal wave when half-wave rectified is further input to the PD 11. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an optical signal receiving device having a noise removal function and an electronic device including the same, and particularly, in an optical signal receiving device that performs infrared communication, unnecessary pulses generated due to disturbance light noise such as a fluorescent lamp. The present invention relates to a technique for suppressing signals.

  As the sensitivity of infrared light increases, ambient light noise such as a fluorescent lamp becomes a source of unnecessary pulse signals (unnecessary pulses) in a receiver that performs infrared communication, which is a problem. The generation of unnecessary pulses will be described with reference to FIGS.

  FIG. 14 is a schematic diagram showing a state in which an optical signal (transmission signal) transmitted from the transmitter 101 and disturbance light noise are input to the infrared receiving circuit 110 in infrared communication. FIG. 15 is a diagram illustrating the waveform of the transmission signal s1 transmitted from the transmitter 101 and the waveform of the noise signal s2 that appears when disturbance light noise is input to the infrared receiving circuit 110. FIG. 16 is a block diagram showing a configuration of a conventional infrared receiving circuit 110. FIG. 17 is a diagram showing signal waveforms of the infrared receiving circuit 110 shown in FIG.

  As shown in FIGS. 14 to 17, when the transmitter 101 transmits a transmission signal s <b> 1 by infrared light from the light emitting diode (LED) 102, the infrared receiving circuit 110 receives this infrared light by the photodiode (PD) 111. . At this time, the transmission signal s1 transmitted from the transmitter 101 is normally a rectangular wave as shown in FIG.

  The PD 111 creates a current signal according to the input infrared light, and the current-voltage conversion circuit 112 converts the current signal into a voltage signal and outputs the voltage signal to the amplifier circuit 113. The amplifier circuit 113 amplifies the input voltage signal and outputs it to the signal comparison circuit 114. As shown in FIG. 17, the voltage signal 8a output from the amplifier circuit 113 has the same waveform as the transmission signal s1, that is, a rectangular wave.

  The signal comparison circuit 114 compares the voltage signal 8a output from the amplification circuit 113 with a comparison signal 8b supplied from the outside, and outputs a binarized pulse signal 8c. Thereby, as shown in FIG. 17, the pulse signal 8c is output from the output terminal 115 according to the voltage signal 8a created based on the transmission signal s1.

  Here, when the sensitivity of the infrared receiving circuit 110 is increased to improve the reception distance characteristic, light (disturbance light noise) emitted from the inverter fluorescent lamp 103 is input to the PD 111 and converted into a voltage signal by the current-voltage conversion circuit 112. As a result, a noise signal s2 as shown in FIG.

  The noise signal s2 is input to the amplifier circuit 113, amplified, and then supplied to the signal comparison circuit 114 as the voltage signal 8a. At this time, the waveform of the noise signal s2 is approximated to a triangular wave, and a triangular wave voltage signal 8a as shown in FIG. The signal comparison circuit 114 compares the voltage signal 8a with the comparison signal 8b and outputs a binarized pulse signal 8c. As a result, an unnecessary pulse signal 8c is output from the output terminal 115 in accordance with the voltage signal 8a created based on the noise signal s2, although disturbance light noise is input.

  Thus, in the conventional infrared receiving circuit 110, the waveform of the noise signal s2 cannot be distinguished from the waveform of the transmission signal s1 transmitted from the transmitter 101, and the signal comparison circuit 114 has a case where the transmission signal s1 is input. Similarly, a pulse signal 8c is output. As a result, there is a problem that an unnecessary pulse is generated, thereby causing a malfunction.

  Thus, in infrared communication, a receiving circuit that prevents the occurrence of malfunction due to ambient light noise has been developed (see, for example, Patent Documents 1 to 3). FIG. 18 shows a configuration of a conventional infrared receiving circuit 120 to which a function for preventing malfunction due to ambient light noise is added.

  As shown in FIG. 18, the conventional infrared receiving circuit 120 includes a duty detection circuit 121, a threshold adjustment circuit 122, and a signal selection circuit 123 in addition to the configuration of the infrared receiving circuit 110. In the infrared receiving circuit 120, the voltage signal 9 a output from the amplifier circuit 113 is supplied to the signal comparison circuit 114 and also to the duty detection circuit 121. As shown in FIG. 19, the voltage signal 9a includes a transmission signal and a noise signal.

  The duty detection circuit 121 detects the duty of the voltage signal 9a output from the amplifier circuit 113. That is, by specifying the duty, it is identified whether the input voltage signal 9a is due to a transmission signal or a noise signal.

  Since the noise signal s2 is often a repetitive signal, the duty detection circuit 121 integrates the voltage signal 9a including the noise signal to create a voltage signal 9b as shown in FIG. On the other hand, for example, when the voltage signal 9c when a 1-pulse rectangular wave transmission signal is input is integrated, the duty detection circuit 121 generates the voltage signal 9d.

  The threshold adjustment circuit 122 refers to the voltage signal 9b and the voltage signal 9d, specifies the voltage signal 9f, and creates the threshold signal 9e shown in FIG. The threshold signal 9e is output to the signal comparison circuit 114.

  The signal comparison circuit 114 compares the voltage signal 9 a output from the amplification circuit 113 with the threshold signal 9 e output from the threshold adjustment circuit 122. When the voltage signal 9a is larger than the threshold signal 9e, the voltage signal 9a is regarded as a transmission signal and a pulse signal is output. As a result, a pulse signal is output from the output terminal 115 via the signal selection circuit 123.

As described above, the infrared receiving circuit 120 identifies the transmission signal and the noise signal by detecting the duty, and suppresses the output of unnecessary pulses.
JP-A-8-279784 (published on October 22, 1996) Japanese Patent Laid-Open No. 10-271064 (released on October 9, 1998) JP-A-9-102987 (published on April 15, 1997)

  However, the conventional infrared receiving circuit 120 has a problem that it can deal only with different duty and noise that is repeatedly input. For example, when the voltage signal 9g shown in FIG. 19 is output from the amplifier circuit 113, a low duty transmission signal cannot be identified. Therefore, there is a demand for a technique for discriminating a transmission signal and a noise signal regardless of the duty and suppressing the generation of unnecessary pulses.

  The present invention has been made in view of the above-described conventional problems, and an object of the present invention is to provide an optical signal receiving apparatus and an electronic apparatus that can identify a transmission signal and a noise signal and suppress generation of unnecessary pulses. It is to provide.

  In order to solve the above problems, an optical signal receiving apparatus according to the present invention inputs the optical signal in an optical signal receiving apparatus that outputs a pulse signal in accordance with the received rectangular wave optical signal, and based on the optical signal. A light-receiving element that outputs a current signal, a current-voltage conversion circuit that converts the current signal output from the light-receiving element into a voltage signal, an amplifier circuit that amplifies the voltage signal converted by the current-voltage conversion circuit, and A level shift circuit for generating a second voltage signal obtained by lowering a predetermined voltage level with respect to the first voltage signal amplified by the amplifier circuit, and a predetermined time for the second voltage signal generated by the level shift circuit. A delay circuit that creates a third voltage signal delayed by the delay circuit, the first voltage signal amplified by the amplification circuit, and the third voltage signal created by the delay circuit are compared, and the signal waveforms of the two intersect. When to A signal comparison circuit that outputs a pulse signal, and the light receiving element is further input with disturbance light noise that appears as a triangular wave or a sine wave when half-wave rectified in the voltage signal waveform. .

  According to the above configuration, when an optical signal is input to the light receiving element, the first voltage signal and the third voltage signal are rectangular waves, and when disturbance light noise is input, the first voltage signal and the first voltage signal are The three-voltage signal becomes a triangular wave or a sine wave when half-wave rectified.

  Therefore, when the signal comparison circuit compares the first voltage signal and the third voltage signal, the optical signal is input by adjusting the voltage level shift amount in the level shift circuit and the delay amount in the delay circuit. In this case, both signal waveforms intersect (that is, the falling portion of the waveform of the first voltage signal and the peak value portion of the waveform of the third voltage signal intersect), and disturbance light noise is input. The signal waveforms of both do not intersect.

  Therefore, a pulse signal is output when an optical signal is input, and no pulse signal is output when disturbance light noise is input. Therefore, the optical signal receiving apparatus of the present invention can discriminate between the optical signal and the disturbance light noise and suppress the generation of an unnecessary pulse signal created by the input of the disturbance light noise.

  The optical signal receiving apparatus of the present invention shapes the first voltage signal amplified by the amplifier circuit into a waveform having a peak value and a gradual falling, and supplies the waveform to the signal comparison circuit. It is preferable to further include a peak hold circuit and a low-pass filter circuit that removes a predetermined frequency component from the second voltage signal created by the level shift circuit and supplies the second voltage signal to the delay circuit.

  According to the above configuration, when the rectangular wave and the triangular wave or the sine wave obtained by half-wave rectification are filtered by the low-pass filter circuit, the peak of the rectangular wave amplitude and the triangular wave or half-wave are compared with the original waveform. The rectangular wave is larger than the peak of the amplitude of the sine wave when the wave is rectified. Therefore, by appropriately adjusting the gradual fall of the first voltage signal supplied to the signal comparison circuit in the peak hold circuit, the signal comparison circuit can reliably cross the rectangular wave to obtain a triangular wave or a half wave. It is possible not to cross the sine waves when the waves are rectified. In addition, the delay amount can be increased.

  The optical signal receiving apparatus of the present invention includes a differentiating circuit for creating a fourth voltage signal differentiated with respect to the first voltage signal amplified by the amplifying circuit, a fourth voltage signal created by the differentiating circuit, A first comparison circuit that compares a first threshold signal set in advance and outputs a pulse signal when the fourth voltage signal exceeds the first threshold signal; and a pulse signal output from the signal comparison circuit It is preferable to further include an open / close circuit that connects or disconnects the output path according to the presence or absence of the pulse signal output from the first comparison circuit.

  According to the above configuration, more accurate noise removal can be performed by double identification. For example, when an optical signal is input, a necessary pulse signal can be transmitted by connecting the output path of the pulse signal output from the signal comparison circuit by the switching circuit. In addition, when disturbance light noise is input, it is possible to reliably prevent unnecessary pulse signals from being generated by inputting the disturbance light noise by cutting the output path of the pulse signal. . Furthermore, even if there is an erroneous output from the signal comparison circuit, since the pulse signal output path is cut off, it is possible to prevent unnecessary pulse signals from being transmitted.

  The optical signal receiving apparatus according to the present invention also includes a first counter circuit that receives the pulse signal output from the signal comparison circuit and counts the number of the pulse signal, and a first voltage signal amplified by the amplifier circuit. And a second threshold signal set in advance, and when the first voltage signal exceeds the second threshold signal, the second comparison circuit that outputs a pulse signal and the second comparison circuit output Input a pulse signal and calculate the difference by subtracting the second counter circuit that counts the number of pulse signals, the count value counted by the first counter circuit, and the count value counted by the second counter circuit And a count subtracting circuit.

  According to the above configuration, the first counter circuit counts the optical signal. The second counter circuit counts an optical signal input to the light receiving element and a noise signal due to ambient light noise. Therefore, the number of generated noise signals can be obtained from the difference value calculated by the count subtracting circuit.

  Thus, for example, when a processing mode when there are many noise signals is provided, the output signal of the count subtraction circuit can be applied as a mode switching signal for switching the processing mode for a certain period of time.

  Further, the optical signal receiving device of the present invention detects the duty of the first voltage signal amplified by the amplifier circuit, so that the first voltage signal is based on either the optical signal or the disturbance light noise. A signal detection output circuit that outputs a pulse signal according to a first voltage signal based on the identified optical signal, a pulse signal output from the signal detection output circuit, and an output from the signal comparison circuit It is preferable to further include a signal selection circuit that selects one of the pulse signals.

  According to the above configuration, the signal selection circuit appropriately selects and outputs the pulse signal output from the signal detection output circuit and the pulse signal output from the signal comparison circuit. It is possible to effectively output a pulse signal according to the optical signal while suppressing the generation. For example, when a low-duty optical signal is input, a pulse signal is output from the signal comparison circuit according to the identified result even if the optical signal and the noise signal are not identified by the signal detection output circuit. Even for a duty input signal, a noise signal can be detected and generation of an unnecessary pulse signal can be suppressed.

  Further, since the optical signal and the ambient light noise are identified twice by the identification by the duty and the identification by the signal waveform, it is possible to make the noise removal with higher accuracy function.

  Further, the optical signal receiving apparatus of the present invention includes a plurality of circuits each including the level shift circuit and the delay circuit provided in parallel, and among the plurality of circuits according to a switching signal supplied from the outside. A switching circuit that selects one circuit, causes the level shift circuit of the selected circuit to supply the first voltage signal amplified by the amplifier circuit, and supplies the third voltage signal from the delay circuit to the signal comparison circuit. Is preferably further provided.

  According to the above configuration, the delay amount can be selected by setting the voltage level shift amount in the level shift circuit and the delay amount in the delay circuit for each circuit configured by the level shift circuit and the delay circuit. It becomes possible. Therefore, it is possible to easily switch the noise band to be removed.

  An electronic apparatus according to the present invention has an infrared communication function and includes the optical signal receiving device.

  According to said structure, since the optical signal receiver which suppresses generation | occurrence | production of an unnecessary pulse signal is provided, it becomes possible to provide the electronic device which prevents generation | occurrence | production of a malfunction.

  As described above, the optical signal receiving device of the present invention receives a rectangular wave optical signal and outputs a current signal based on the optical signal, and the current signal output from the light receiving element is a voltage signal. A current-voltage conversion circuit that converts the voltage signal converted by the current-voltage conversion circuit, an amplification circuit that amplifies the voltage signal converted by the current-voltage conversion circuit, and a second voltage level that is lower than the first voltage signal amplified by the amplification circuit. A level shift circuit for generating a voltage signal, a delay circuit for generating a third voltage signal delayed by a predetermined time with respect to the second voltage signal generated by the level shift circuit, and a first amplifier amplified by the amplifier circuit A signal comparison circuit that compares one voltage signal with the third voltage signal created by the delay circuit and outputs a pulse signal when the two signal waveforms cross each other. Signal waveform is triangular Or, a configuration in which ambient light noise that appears in a sine wave when the half-wave rectification is further input.

  Thus, when the signal comparison circuit compares the first voltage signal and the third voltage signal, the optical signal is input by adjusting the voltage level shift amount in the level shift circuit and the delay amount in the delay circuit. In this case, both signal waveforms intersect (that is, the falling portion of the waveform of the first voltage signal and the peak value portion of the waveform of the third voltage signal intersect), and disturbance light noise is input. The signal waveforms of both do not intersect.

  Therefore, a pulse signal is output when an optical signal is input, and no pulse signal is output when disturbance light noise is input. Therefore, there is an effect of providing an optical signal receiving apparatus capable of discriminating an optical signal from disturbance light noise and suppressing generation of an unnecessary pulse signal generated by inputting the disturbance light noise.

  In addition, an electronic device according to the present invention has an infrared communication function and includes the optical signal receiving device. Therefore, since the optical signal receiving device that suppresses the generation of unnecessary pulse signals is provided, it is possible to provide an electronic device that prevents the occurrence of malfunction.

  An embodiment of the present invention will be described below with reference to the drawings.

  The optical signal receiving apparatus according to the present invention identifies a transmission signal (optical signal) transmitted from a transmitter and disturbance light noise (that is, a noise signal generated when disturbance light noise is input), It suppresses the output of unnecessary pulses due to ambient light noise.

  For example, in a liquid crystal television (liquid crystal television with an infrared communication function) equipped with an infrared light receiving device and a fluorescent tube, the infrared light receiving device inputs a transmission signal transmitted from a remote control and backlight noise of the fluorescent tube. In the case where it is desired to discriminate the noise signal generated by the error and remove the output due to the backlight noise and generate the output only when the transmission signal is input, the infrared light receiving device is applied to the present invention. Such an optical signal receiving apparatus can be applied.

Below, it demonstrates as following (1) * (2).
(1) The transmission signal is assumed to be the rectangular wave transmission signal s1 shown in FIG. In other words, a rectangular wave signal is identified as a transmission signal.
(2) The noise signal is a signal having a specific waveform having a specific magnitude generated from a disturbance factor (such as an inverter fluorescent lamp). Here, the noise signal is assumed to be a noise signal s2 having a peak-shaped voltage waveform with a sharp peak value shown in FIG. In order to explain as a specific waveform, as shown in FIG. 15, the noise signal s2 is approximated to a triangular wave signal s3 or a half-wave rectified sine wave signal s4. That is, a triangular wave and a half-wave rectified sine wave signal are regarded as noise signals and are identified and removed.

[Embodiment 1]
(Configuration of optical signal receiver)
FIG. 1 is a block diagram illustrating a configuration example of the optical signal receiving apparatus 10 according to the present embodiment.

  As shown in FIG. 1, the optical signal receiving apparatus 10 includes a PD 11 (light receiving element), a current-voltage conversion circuit 12, an amplification circuit 13, a level shift circuit 14, a delay circuit 15, and a signal comparison circuit 16. The level shift circuit 14, the delay circuit 15, and the signal comparison circuit 16 constitute a noise removal circuit 17 as a configuration having a noise removal function.

  The PD 11 creates a current signal according to the amount of received light and outputs it to the current-voltage conversion circuit 12. The PD 11 inputs a transmission signal transmitted from the LED 102 of the transmitter 101 as shown in FIG. 14 or light (disturbance light noise) emitted from the inverter fluorescent lamp 103.

  The current-voltage conversion circuit 12 converts the current signal output from the PD 11 into a voltage signal and outputs the voltage signal to the amplifier circuit 13. The amplifier circuit 13 amplifies the voltage signal output from the current-voltage conversion circuit 12 and outputs the amplified voltage signal to the level shift circuit 14 and also to the signal comparison circuit 16.

  The level shift circuit 14 creates a voltage signal obtained by lowering a predetermined voltage level with respect to the voltage signal output from the amplifier circuit 13. The level shift circuit 14 outputs the level-shifted voltage signal to the delay circuit 15.

  The delay circuit 15 creates a voltage signal obtained by delaying the voltage signal output from the level shift circuit 14 by a predetermined time. The delay circuit 15 outputs the delayed voltage signal to the signal comparison circuit 16.

  The signal comparison circuit 16 compares the voltage signal output from the amplifier circuit 13 with the voltage signal output from the delay circuit 15, and determines whether or not the signal waveforms of the two intersect. If the two signal waveforms intersect as a result of the determination, the signal comparison circuit 16 outputs a binary pulse signal using the voltage signal output from the amplifier circuit 13 as a threshold value, and the two signal waveforms intersect. If not, no output is generated.

(Signal processing operation of optical signal receiver)
Next, the signal processing operation of the optical signal receiving apparatus 10 of the present embodiment will be described. First, a case where a noise signal is input will be described, and then a case where a transmission signal is input will be described.

  FIG. 2 is a diagram illustrating signal waveforms of the optical signal receiving device 10 when a noise signal is input. Although FIG. 2 shows the case where the noise signal is a triangular wave, the same processing is performed even in the case of a sine wave when half-wave rectified.

  When the light emitted from the inverter fluorescent lamp 103 is input to the PD 11, the voltage signal 1 a (first voltage signal) is output from the amplifier circuit 13 through the processing of the current-voltage conversion circuit 12 and the amplifier circuit 13. At this time, the voltage signal 1a is a triangular wave as shown in FIG. The alternate long and short dash line m is an auxiliary line passing through the apex of the triangular wave.

  The level shift circuit 14 creates a voltage signal 1b (second voltage signal) shifted by V1 [V] with respect to the voltage signal 1a. The voltage signal 1b is supplied to the delay circuit 15, and is output to the signal comparison circuit 16 as a voltage signal 1c (third voltage signal) shifted by time t1.

  The signal comparison circuit 16 compares the voltage signal 1a output from the amplifier circuit 13 with the voltage signal 1c output from the delay circuit 15, and determines whether or not the signal waveforms of the two intersect. At this time, since the signal waveforms of both do not intersect, the signal comparison circuit 16 does not generate an output. As a result, the pulse signal 1d is not output from the output terminal 18.

  Next, a case where a transmission signal is input will be described.

  FIG. 3 is a diagram illustrating signal waveforms of the optical signal receiving device 10 when a transmission signal is input.

  When a transmission signal transmitted from the transmitter 101 is input to the PD 11, the voltage signal 1 a is output from the amplification circuit 13 through the processing of the current-voltage conversion circuit 12 and the amplification circuit 13. At this time, the voltage signal 1a is a rectangular wave as shown in FIG.

  The level shift circuit 14 creates a voltage signal 1b shifted by V1 [V] with respect to the voltage signal 1a. The voltage signal 1b is supplied to the delay circuit 15, and is output to the signal comparison circuit 16 as the voltage signal 1c shifted by time t1. Thus, regardless of the input signal, the level shift circuit 14 shifts the same amount of voltage level, and the delay circuit 15 delays the same amount of time.

  The signal comparison circuit 16 compares the voltage signal 1a output from the amplifier circuit 13 with the voltage signal 1c output from the delay circuit 15, and determines whether or not the signal waveforms of the two intersect. At this time, since both signal waveforms intersect, the signal comparison circuit 16 outputs a pulse signal 1d binarized using the voltage signal 1a as a threshold value. As a result, the pulse signal 1 d is output from the output terminal 18. The pulse signal 1d may be input to a one-shot circuit (not shown) or the like and shaped into a signal according to the application.

  As described above, in the optical signal receiving device 10 of the present embodiment, when a transmission signal is input to the PD 11, the voltage signal 1a and the voltage signal 1c are rectangular waves, and a noise signal is input. The voltage signal 1a and the voltage signal 1c are triangular waves.

  Therefore, when the signal comparison circuit 16 compares the voltage signal 1a and the voltage signal 1c, if a transmission signal is input, the signal waveforms of the two intersect (that is, the falling portion of the waveform of the voltage signal 1a). And the peak value portion of the waveform of the voltage signal 1c), when a noise signal is input, the signal waveforms of both do not intersect.

  Therefore, when a noise signal is input, the pulse signal 1d is not output from the output terminal 18, and the pulse signal 1d is output from the output terminal 18 only when a transmission signal is input. Therefore, it is possible to identify the noise signal and the transmission signal and suppress the generation of unnecessary pulses.

  In the signal comparison circuit 16, the voltage level shift amount (V 1) in the level shift circuit 14 and the delay circuit 15 are set so that the signal waveforms intersect when a transmission signal is input and do not intersect when a noise signal is input. It is desirable to set the delay amount (t1) in advance.

[Embodiment 2]
The following will describe another embodiment of the present invention with reference to the drawings. Configurations other than those described in the present embodiment are the same as those in the first embodiment. For convenience of explanation, members having the same functions as those shown in the drawings of the first embodiment are given the same reference numerals, and explanation thereof is omitted.

(Configuration of optical signal receiver)
FIG. 4 is a block diagram illustrating a configuration example of the optical signal receiving apparatus 20 according to the present embodiment.

  As shown in FIG. 4, the optical signal receiving device 20 includes a low-pass filter circuit 21 and a peak hold circuit 22 in addition to the configuration of the optical signal receiving device 10 of the first embodiment. In this embodiment, the level shift circuit 14, the delay circuit 15, the signal comparison circuit 16, the low-pass filter circuit 21, and the peak hold circuit 22 constitute a noise removal circuit 23 having a noise removal function.

  The low-pass filter circuit 21 is inserted between the level shift circuit 14 and the delay circuit 15, receives the voltage signal output from the level shift circuit 14, removes a high frequency component, and outputs it to the delay circuit 15. .

  The peak hold circuit 22 is inserted between the amplifier circuit 13 and the signal comparison circuit 16, and holds a peak value with respect to the voltage signal output from the amplifier circuit 13 and has a slow fall. A signal is created and output to the signal comparison circuit 16.

  FIG. 7 shows a specific configuration example of the peak hold circuit 22. As shown in FIG. 7, the peak hold circuit 22 includes an operational amplifier 32, a diode 33, a capacitor 34, a constant current circuit 35, and an operational amplifier 36.

  The voltage signal output from the amplifier circuit 13 is input to the non-inverting input terminal of the operational amplifier 32 via the input terminal 31. The output signal of the operational amplifier 32 is input to the non-inverting input terminal of the operational amplifier 36 via the diode 33. Also, a capacitor 34 and a constant current circuit 35 are provided in parallel in this order from the diode 33 side between the path connecting the non-inverting input terminal of the operational amplifier 36 from the diode 33 and the ground. Further, the signal input to the non-inverting input terminal of the operational amplifier 36 is fed back to the inverting input terminal of the operational amplifier 32. The output signal of the operational amplifier 36 is negatively fed back and is output to the signal comparison circuit 16 via the output terminal 37.

  At this time, the falling slope of the output signal of the operational amplifier 36 depends on the constant current circuit 35. That is, since the electric charge accumulated in the capacitor 34 is discharged from the constant current circuit 35, the current flowing through the constant current circuit 35 decreases sharply as it increases, and decreases gradually as it decreases. Further, since the current flowing through the constant current circuit 35 is constant, the voltage can be lowered with linearity.

(Signal processing operation of optical signal receiver)
Next, the signal processing operation of the optical signal receiving device 20 of the present embodiment will be described. First, a case where a noise signal is input will be described, and then a case where a transmission signal is input will be described.

  FIG. 5 is a diagram illustrating signal waveforms of the optical signal receiving device 20 when noise is input. Although FIG. 5 shows a case where the noise signal is a triangular wave, the same processing is performed even in the case of a half-wave rectified sine wave.

  When light emitted from the inverter fluorescent lamp 103 is input to the PD 11, the voltage signal 2 a (first voltage signal) is output from the amplifier circuit 13 through the processing of the current-voltage conversion circuit 12 and the amplifier circuit 13. At this time, the voltage signal 2a is a triangular wave as shown in FIG.

  The level shift circuit 14 creates a voltage signal 2b (second voltage signal) shifted by V1 [V] with respect to the voltage signal 2a. The voltage signal 2 b is supplied to the delay circuit 15 after the high frequency component is removed through the low-pass filter circuit 21. The delay circuit 15 creates a voltage signal 2c (third voltage signal) shifted by time t1 with respect to the voltage signal output from the low-pass filter circuit 21, and outputs the voltage signal 2c to the signal comparison circuit 16.

  On the other hand, the peak hold circuit 22 creates a voltage signal 2d (first voltage signal) that holds a peak value with respect to the voltage signal 2a and has a falling slope of the triangular wave that is gentler than that of the voltage signal 2a. The signal is output to the signal comparison circuit 16. The signal comparison circuit 16 compares the voltage signal 2d output from the peak hold circuit 22 with the voltage signal 2c output from the delay circuit 15, and determines whether or not the signal waveforms of the two cross. At this time, since the signal waveforms of both do not intersect, the signal comparison circuit 16 does not generate an output. Thereby, the pulse signal 2e is not output from the output terminal 18.

  Next, a case where a transmission signal is input will be described.

  FIG. 6 is a diagram illustrating each signal waveform of the optical signal receiving device 20 when a transmission signal is input.

  When the transmission signal generated from the transmitter 101 is input to the PD 11, the voltage signal 2 a is output from the amplifier circuit 13 through the processing of the current-voltage conversion circuit 12 and the amplifier circuit 13. At this time, the voltage signal 2a is a rectangular wave as shown in FIG.

  The level shift circuit 14 creates a voltage signal 2b shifted by V1 [V] with respect to the voltage signal 2a. The voltage signal 2 b is supplied to the delay circuit 15 after the high frequency component is removed through the low-pass filter circuit 21. The delay circuit 15 creates a voltage signal 2c shifted by time t2 with respect to the voltage signal output from the low-pass filter circuit 21, and outputs the voltage signal 2c to the signal comparison circuit 16.

  On the other hand, the peak hold circuit 22 generates a voltage signal 2d that holds a peak value with respect to the voltage signal 2a and has a falling slope of the rectangular wave that is gentler than that of the voltage signal 2a. Output. The signal comparison circuit 16 compares the voltage signal 2d output from the peak hold circuit 22 with the voltage signal 2c output from the delay circuit 15, and determines whether or not the signal waveforms of the two cross. At this time, since both signal waveforms intersect, the signal comparison circuit 16 outputs a pulse signal 2e binarized using the voltage signal 2d as a threshold value. As a result, the pulse signal 2 e is output from the output terminal 18. This pulse signal 2e may be input to a one-shot circuit (not shown) or the like and shaped into a signal according to the application.

  As described above, in the optical signal receiving device 20 according to the present embodiment, when the noise signal is input, the pulse signal 2e is not output from the output terminal 18, and only when the transmission signal is input, the output terminal 18 To output a pulse signal 2e. Therefore, it is possible to identify the noise signal and the transmission signal and suppress the generation of unnecessary pulses.

  In general, when a rectangular wave and a triangular wave are filtered by the low-pass filter circuit 21, the rectangular wave has a larger amplitude peak than the original waveform and the triangular wave has an amplitude peak. Therefore, by appropriately adjusting the falling edge of the voltage signal 2d serving as the threshold in the peak hold circuit 22, the signal comparison circuit 16 can always cross the rectangular wave and not cross the triangular wave.

  Furthermore, the optical signal receiving device 20 can increase the delay amount (t1 <t2) as compared with the optical signal receiving device 10 of the above embodiment. Normally, when a delay circuit is inserted, the waveform may be distorted like the waveform of the voltage signal 2c in FIG. 6, and there is a circuit in which the distortion increases when the delay amount increases. In this embodiment, however, the delay amount is increased. Even if the signal waveform is distorted, the signal waveform can be identified.

[Embodiment 3]
The following will describe another embodiment of the present invention with reference to the drawings. Configurations other than those described in the present embodiment are the same as those in the first and second embodiments. For convenience of explanation, members having the same functions as those shown in the drawings of the first and second embodiments are given the same reference numerals, and explanation thereof is omitted.

(Configuration of optical signal receiver)
FIG. 8 is a block diagram illustrating a configuration example of the optical signal receiving device 40 according to the present embodiment.

  As shown in FIG. 8, the optical signal receiving device 40 of this embodiment includes an optical signal receiving circuit 41, a differentiating circuit 42, a comparing circuit 43 (first comparing circuit), and a changeover switch 44 (opening / closing circuit). Yes.

  The optical signal receiving circuit 41 is a circuit including the configuration of the optical signal receiving device 10 shown in FIG. 1 or the configuration of the optical signal receiving device 20 shown in FIG. That is, the optical signal receiving circuit 41 performs the signal processing operation of the optical signal receiving device 10 of the first embodiment or the optical signal receiving device 20 of the second embodiment described above.

  The differentiating circuit 42 is provided to input the voltage signal output from the amplifier circuit 13 of the optical signal receiving circuit 41. The differentiation circuit 42 creates a differentiated voltage signal with respect to the input voltage signal and outputs the differentiated voltage signal to the comparison circuit 43.

  The comparison circuit 43 compares the voltage signal output from the differentiation circuit 42 with a comparison signal supplied from the outside, and outputs a switching signal to the changeover switch 44 according to the comparison result. That is, when the voltage signal output from the differentiating circuit 42 exceeds the comparison signal, the comparison circuit 43 outputs a switching signal so that the changeover switch 44 is turned on for a certain period of time. On the other hand, when the voltage signal output from the differentiation circuit 42 does not exceed the comparison signal, the comparison circuit 43 does not output the switching signal because the changeover switch 44 is turned off.

  The changeover switch 44 is connected to the output terminal 18 of the optical signal reception circuit 41 and switches on / off according to the changeover signal output from the comparison circuit 43. Thereby, the output signal of the optical signal receiving circuit 41 is output from the output terminal 45 only when the changeover switch 44 is ON.

(Signal processing operation of optical signal receiver)
Next, the signal processing operation of the optical signal receiving device 40 of the present embodiment will be described.

  FIG. 9 is a diagram illustrating each signal waveform of the optical signal receiving device 40 when a transmission signal is input and when a noise signal is input.

  When a noise signal is input or when a transmission signal is input, the voltage signal 3a (first voltage signal) is output from the amplifier circuit 13 through the processing of the current-voltage conversion circuit 12 and the amplifier circuit 13. At this time, the voltage signal 3a is a rectangular wave or a triangular wave as shown in FIG.

  The voltage signal 3a is output to the noise removal circuit 17 or the noise removal circuit 23, and the signal processing operation as described above is performed in the optical signal reception circuit 41.

  On the other hand, the voltage signal 3 a is output to the differentiation circuit 42. The differentiating circuit 42 creates a differentiated voltage signal 3b (fourth voltage signal) with respect to the voltage signal 3a. At this time, as shown in FIG. 9, the voltage signal 3b has a waveform corresponding to the case where the voltage signal 3a is a noise signal or a transmission signal. The voltage signal 3b is output to the comparison circuit 43.

  The comparison circuit 43 is supplied with a comparison signal 3c (first threshold signal) as shown in FIG. The comparison circuit 43 compares the voltage signal 3b output from the differentiation circuit 42 with the comparison signal 3c to determine whether the voltage signal 3b exceeds the comparison signal 3c.

  In the case of “voltage signal 3b> comparison signal 3c”, the comparison circuit 43 outputs a changeover signal (pulse signal) to the changeover switch 44 for a predetermined time. As a result, the output path of the pulse signal output from the optical signal receiving circuit 41 is connected, and the pulse signal is output from the output terminal 45. That is, in this case, a pulse signal based on the transmission signal is output from the output terminal 45 by the optical signal receiving circuit 41.

  In the case of “voltage signal 3b <comparison signal 3c”, the comparison circuit 43 does not output a switching signal. As a result, the output path of the pulse signal output from the optical signal receiving circuit 41 is disconnected, and no signal is output from the output terminal 45. Thus, in order to prevent output from the output terminal 45 when a noise signal is input, the comparison signal 3c may be set in advance to a value that does not exceed the voltage signal 3b when the noise signal is differentiated. desirable. Even if there is an erroneous output from the optical signal receiving circuit 41, no output is generated from the output terminal 45 because the changeover switch 44 is turned off.

  As described above, in the optical signal receiving device 40 of the present embodiment, when a noise signal is input, a pulse signal is not output from the output terminal 45, and only when a transmission signal is input, from the output terminal 45. A pulse signal is output. Therefore, it is possible to identify the noise signal and the transmission signal and suppress the generation of unnecessary pulses. Furthermore, since the transmission signal and the noise signal are identified twice, it is possible to make noise removal function with higher accuracy.

[Embodiment 4]
The following will describe another embodiment of the present invention with reference to the drawings. Configurations other than those described in the present embodiment are the same as those in the first to third embodiments. For convenience of explanation, members having the same functions as those shown in the drawings of Embodiments 1 to 3 are given the same reference numerals, and descriptions thereof are omitted.

(Configuration of optical signal receiver)
FIG. 10 is a block diagram illustrating a configuration example of the optical signal receiving device 50 according to the present embodiment.

  As shown in FIG. 10, the optical signal receiving apparatus 50 of the present embodiment includes an optical signal receiving circuit 51, a counter 52 (first counter circuit), a comparison circuit 53 (second comparison circuit), and a counter 54 (second counter). Circuit) and a count subtraction function circuit 55 (count subtraction circuit).

  The optical signal receiving circuit 51 is a circuit including the configuration of the optical signal receiving device 10 shown in FIG. 1 or the configuration of the optical signal receiving device 20 shown in FIG. That is, the optical signal receiving circuit 41 performs the signal processing operation of the optical signal receiving device 10 of the first embodiment or the optical signal receiving device 20 of the second embodiment described above.

  The counter 52 is connected to the output terminal 18 of the optical signal receiving circuit 51, receives the pulse signal output from the optical signal receiving circuit 51, and counts the number of the pulse signals. The counter 52 outputs a signal indicating the count value to the count subtraction function circuit 55.

  The comparison circuit 53 is provided so as to input the voltage signal output from the amplification circuit 13 of the optical signal reception circuit 51. The comparison circuit 53 compares the voltage signal output from the amplifier circuit 13 with a comparison signal supplied from the outside, and outputs a pulse signal to the counter 54 according to the comparison result. That is, the comparison circuit 53 outputs a pulse signal when the voltage signal output from the amplifier circuit 13 exceeds the comparison signal. On the other hand, when the voltage signal output from the amplifier circuit 13 does not exceed the comparison signal, the comparison circuit 53 does not generate an output.

  The counter 54 receives the pulse signal output from the comparison circuit 53 and counts the number of the pulse signals. The counter 54 outputs a signal indicating the count value to the count subtraction function circuit 55.

  The count subtraction function circuit 55 inputs the signal output from the counter 52 and the signal output from the counter 54 and subtracts them to calculate a difference. Thereby, the number of generated noise signals can be counted.

(Signal processing operation of optical signal receiver)
Next, the signal processing operation of the optical signal receiving device 50 of the present embodiment will be described.

  FIG. 11 is a diagram illustrating signal waveforms of the optical signal receiving device 50 when a transmission signal is input and a noise signal is input.

  When a noise signal is input or when a transmission signal is input, the voltage signal 4a (first voltage signal) is output from the amplifier circuit 13 through the processing of the current-voltage conversion circuit 12 and the amplifier circuit 13. At this time, the voltage signal 4a is a rectangular wave or a triangular wave as shown in FIG.

  The voltage signal 4a is output to the noise removal circuit 17 or the noise removal circuit 23, and the signal processing operation as described above is performed in the optical signal reception circuit 51. Thereby, a pulse signal is output from the output terminal 57 only when a transmission signal is input. This pulse signal is also output to the counter 52. The counter 52 counts the pulse signal output from the optical signal receiving circuit 51 and outputs a signal indicating the count value to the count subtraction function circuit 55.

  On the other hand, the voltage signal 4 a is output to the comparison circuit 53. The comparison circuit 53 is supplied with a comparison signal 4b (second threshold signal) as shown in FIG. The comparison circuit 53 compares the voltage signal 4a output from the amplifier circuit 13 with the comparison signal 4b to determine whether the voltage signal 4a exceeds the comparison signal 4b.

  When “voltage signal 4 a> comparison signal 4 b”, comparison circuit 53 outputs a pulse signal to counter 54. In the case of “voltage signal 4a <comparison signal 4b”, the comparison circuit 53 does not output a pulse signal. The counter 54 counts the pulse signal output from the comparison circuit 53 and outputs a signal indicating the count value to the count subtraction function circuit 55. The count subtraction function circuit 55 subtracts the signal output from the counter 52 and the signal output from the counter 54 to calculate a difference.

  Here, since the optical signal receiving circuit 51 outputs a pulse signal based on a signal other than a noise signal, the counter 52 counts a signal other than noise. The counter 54 counts all the signals input to the PD 11 of the optical signal receiving circuit 51. Therefore, the difference value indicates the number of noise signals. As a result, the number of noise signals generated in the optical signal receiving device 50 can be acquired from the output terminal 56.

  As described above, in the optical signal receiving apparatus 50 of the present embodiment, when a noise signal is input, a pulse signal is not output from the output terminal 57, and only when a transmission signal is input, the output terminal 57 A pulse signal is output. Therefore, it is possible to identify the noise signal and the transmission signal and suppress the generation of unnecessary pulses.

  Furthermore, the noise amount can be recognized by the noise count function provided by the counter 52, the comparison circuit 53, the counter 54, and the count subtraction function circuit 55. Thus, when a processing mode when there is a lot of noise is provided, the output signal of the count subtraction function circuit 55 can be applied as a mode switching signal for switching the processing mode for a certain period of time.

[Embodiment 5]
The following will describe another embodiment of the present invention with reference to the drawings. Configurations other than those described in the present embodiment are the same as those in the first to fourth embodiments. For convenience of explanation, members having the same functions as those shown in the drawings of Embodiments 1 to 4 are given the same reference numerals, and descriptions thereof are omitted.

  FIG. 12 is a block diagram illustrating a configuration example of the optical signal receiving device 60 according to the present embodiment.

  As shown in FIG. 12, the optical signal receiving device 60 of this embodiment includes a noise removing circuit 61 in addition to the configuration of the infrared receiving circuit 120 shown in FIG.

  The noise removal circuit 61 is the noise removal circuit 17 shown in FIG. 1 or the noise removal circuit 23 shown in FIG. The noise removal circuit 61 is provided between the amplifier circuit 113 and the signal selection circuit 123 in parallel with a circuit (signal detection output circuit) configured by the duty detection circuit 121, the threshold adjustment circuit 122, and the signal comparison circuit 114. ing.

  As a result, in the optical signal receiving device 60, the PD 111, the current-voltage conversion circuit 112, the amplifier circuit 113, and the noise removal circuit 61 described above are the optical signal receiving device 10 of the first embodiment or the second embodiment described above. The signal processing operation of the optical signal receiving device 20 is performed.

  In the optical signal receiving device 60, the voltage signal output from the amplifier circuit 113 undergoes signal processing of the duty detection circuit 121, the threshold adjustment circuit 122, and the signal comparison circuit 114, and is regarded as a transmission signal based on the detection result of the duty ratio. The pulse signal is supplied to the signal selection circuit 123.

  However, in the above signal processing, there is a problem that only the noise with different duty and the noise that is repeatedly input can be dealt with, so that the transmission signal cannot be accurately identified.

  On the other hand, in the optical signal receiving device 60, while the pulse signal based on the duty detection result is output from the signal comparison circuit 114, the transmission signal and the noise signal are compared by comparing the signal waveforms by providing the noise removal circuit 61. And have been identified. Thus, when a transmission signal is input, a pulse signal is supplied from the noise removal circuit 61 to the signal selection circuit 123, and when a noise signal is input, the pulse signal is not supplied to the signal selection circuit 123.

  Therefore, the signal selection circuit 123 appropriately selects and outputs the pulse signal output from the signal comparison circuit 114 and the pulse signal output from the noise removal circuit 61, thereby suppressing the generation of unnecessary pulses. However, the pulse signal can be effectively output according to the transmission signal.

  For example, when a low-duty transmission signal 9a ′ as shown in FIG. 19 is input, even if the transmission signal and the noise signal are not distinguished and no output is generated from the signal comparison circuit 114, the noise removal circuit 61 Since the pulse signal is output according to the identified result, it is possible to detect the noise signal even for the low-duty input signal 9a ′ and suppress the generation of an unnecessary pulse signal.

  Therefore, the optical signal receiving device 60 can detect and remove a noise signal even for a low duty input signal. Furthermore, since the transmission signal and the noise signal are identified twice, it is possible to make noise removal function with higher accuracy.

[Embodiment 6]
The following will describe another embodiment of the present invention with reference to the drawings. Configurations other than those described in the present embodiment are the same as those in the first to fifth embodiments. For convenience of explanation, members having the same functions as those shown in the drawings of the first to fifth embodiments are given the same reference numerals, and descriptions thereof are omitted.

  FIG. 13 is a block diagram illustrating a configuration example of the optical signal receiving apparatus 70 according to the present embodiment.

  As shown in FIG. 13, the optical signal receiver 70 of this embodiment includes a PD 11, a current-voltage conversion circuit 12, an amplifier circuit 13, level shift circuits 14a and 14b, delay circuits 15a and 15b, a signal comparison circuit 16, and A switching circuit 71 is provided.

  In other words, the optical signal receiving device 70 of the present embodiment is provided with a plurality of circuits composed of level shift circuits and delay circuits in parallel as compared with the configuration of the optical signal receiving device 10 of the first embodiment. In addition, a switching circuit 71 is provided between the amplifier circuit 13 and the level shift circuits 14a and 14b, and between the signal comparison circuit 16 and the delay circuits 15a and 15b.

  The switching circuit 71 selects one of the circuit of the level shift circuit 14a and the delay circuit 15a and the circuit of the level shift circuit 14b and the delay circuit 15b in accordance with a switching signal supplied from the outside. Thus, the supply destination of the voltage signal output from the amplifier circuit 13 is switched, and the supply source of the voltage signal output to the signal comparison circuit 16 is switched.

  The circuit configured by the level shift circuit 14a and the delay circuit 15a and the circuit configured by the level shift circuit 14b and the delay circuit 15b each have a noise band to be removed. That is, a level shift amount and a delay amount are set.

  Thereby, in the optical signal receiving device 70, it is possible to easily select the delay amount only by giving the switching signal to the switching circuit 71. Therefore, it is possible to easily switch the noise band to be removed.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  INDUSTRIAL APPLICABILITY The present invention is suitably used in the field related to an optical signal receiving device that is required to identify a transmitted rectangular wave optical signal and remove a noise signal generated by the input of ambient light noise in infrared communication. In addition to the optical signal receiving device manufacturing method, the optical signal receiving device can be suitably used. Further, the electronic device is equipped with the optical signal receiving device, for example, a mobile phone for performing data optical communication, or optical communication with a remote controller. It can also be widely used in fields such as liquid crystal televisions.

It is a block diagram which shows one Embodiment of the optical signal receiver in this invention. It is a figure which shows each signal waveform of the said optical signal receiver at the time of noise signal input. It is a figure which shows each signal waveform of the said optical signal receiver at the time of transmission signal input. It is a block diagram which shows other embodiment of the optical signal receiver in this invention. It is a figure which shows each signal waveform of the said optical signal receiver at the time of noise signal input. It is a figure which shows each signal waveform of the said optical signal receiver at the time of transmission signal input. FIG. 3 is an equivalent circuit diagram illustrating a configuration example of a peak hold circuit in the optical signal receiving device. It is a block diagram which shows other embodiment of the optical signal receiver in this invention. It is a figure which shows each signal waveform of the said optical signal receiver at the time of transmission signal input and noise signal input. It is a block diagram which shows other embodiment of the optical signal receiver in this invention. It is a figure which shows each signal waveform of the said optical signal receiver at the time of transmission signal input and noise signal input. It is a block diagram which shows other embodiment of the optical signal receiver in this invention. It is a block diagram which shows other embodiment of the optical signal receiver in this invention. In infrared communication, it is a schematic diagram which shows a mode that the transmission signal transmitted from a transmitter and disturbance light noise are input into an infrared receiving circuit. It is a figure which shows the waveform of the transmission signal transmitted from a transmitter, and the waveform of the noise signal which appears when disturbance light noise is input in an infrared receiving circuit. It is a block diagram which shows the structure of the conventional infrared receiving circuit. It is a figure which shows each signal waveform of the said conventional infrared receiving circuit. It is a block diagram which shows the structure of the other conventional infrared receiving circuit. It is a figure which shows each signal waveform of the said conventional infrared receiving circuit. It is a figure which shows a signal when each signal shown in FIG. 19 is integrated.

Explanation of symbols

10, 20, 40, 50, 60, 70 Optical signal receiver 11, 111 Photodiode (light receiving element)
12, 112 Current / voltage conversion circuit 13, 113 Amplifier circuit 14 Level shift circuit 15 Delay circuit 16 Signal comparison circuit 17 Noise removal circuit 21 Low pass filter circuit 22 Peak hold circuit 23 Noise removal circuit 41, 51, 61 Optical signal reception circuit 42 Differentiation Circuit 43 comparison circuit (first comparison circuit)
44 changeover switch (open / close circuit)
52 Counter (first counter circuit)
53 Comparison circuit (second comparison circuit)
54 Counter (second counter circuit)
55 Count subtraction function circuit (count subtraction circuit)
71 switching circuit 101 transmitter 102 light emitting diode 103 inverter fluorescent lamp 114 signal comparison circuit (signal detection output circuit)
121 Duty detection circuit (signal detection output circuit)
122 Threshold adjustment circuit (signal detection output circuit)
123 Signal selection circuit

Claims (7)

In the optical signal receiving device that outputs a pulse signal according to the received rectangular wave optical signal,
A light receiving element that inputs the optical signal and outputs a current signal based on the optical signal;
A current-voltage conversion circuit that converts the current signal output from the light receiving element into a voltage signal;
An amplifier circuit for amplifying the voltage signal converted by the current-voltage converter circuit;
A level shift circuit for creating a second voltage signal obtained by lowering a predetermined voltage level with respect to the first voltage signal amplified by the amplifier circuit;
A delay circuit that creates a third voltage signal delayed by a predetermined time with respect to the second voltage signal created by the level shift circuit;
A signal comparison circuit that compares the first voltage signal amplified by the amplification circuit and the third voltage signal created by the delay circuit and outputs a pulse signal when the signal waveforms of the two intersect; ,
An optical signal receiving apparatus, wherein the light receiving element further receives disturbance light noise that appears as a triangular wave or a sine wave when half-wave rectified in the voltage signal waveform. A peak hold circuit that shapes the first voltage signal amplified by the amplifier circuit into a waveform that holds a peak value and has a gradual fall, and supplies the waveform to the signal comparison circuit;
2. The light according to claim 1, further comprising a low-pass filter circuit that removes a predetermined frequency component from the second voltage signal created by the level shift circuit and supplies the second voltage signal to the delay circuit. Signal receiving device. A differentiating circuit for creating a fourth voltage signal differentiated with respect to the first voltage signal amplified by the amplifying circuit;
A first comparison circuit that compares the fourth voltage signal created by the differentiation circuit with a preset first threshold signal and outputs a pulse signal when the fourth voltage signal exceeds the first threshold signal. When,
And a switching circuit for connecting or disconnecting an output path of the pulse signal output from the signal comparison circuit according to the presence or absence of the pulse signal output from the first comparison circuit. 2. The optical signal receiving device according to 1. A first counter circuit for inputting a pulse signal output from the signal comparison circuit and counting the number of the pulse signals;
A second comparison circuit that compares the first voltage signal amplified by the amplifier circuit with a preset second threshold signal and outputs a pulse signal when the first voltage signal exceeds the second threshold signal When,
A second counter circuit for inputting the pulse signal output from the second comparison circuit and counting the number of the pulse signals;
2. The count subtraction circuit according to claim 1, further comprising a count subtraction circuit that calculates a difference by subtracting the count value counted by the first counter circuit and the count value counted by the second counter circuit. Optical signal receiver. By detecting the duty of the first voltage signal amplified by the amplifier circuit, it is identified whether the first voltage signal is based on the optical signal or the disturbance light noise, and based on the identified optical signal A signal detection output circuit for outputting a pulse signal in response to the first voltage signal;
2. The signal selection circuit according to claim 1, further comprising a signal selection circuit that selects one of the pulse signal output from the signal detection output circuit and the pulse signal output from the signal comparison circuit. The optical signal receiving apparatus described. A plurality of circuits composed of the level shift circuit and the delay circuit are provided in parallel,
In response to a switching signal supplied from the outside, one of the plurality of circuits is selected, and the level shift circuit of the selected circuit is supplied with the first voltage signal amplified by the amplifier circuit, and the delay The optical signal receiving apparatus according to claim 1, further comprising a switching circuit that supplies the third voltage signal from the circuit to the signal comparison circuit. Infrared communication function
An electronic apparatus comprising the optical signal receiving device according to claim 1.

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