JPH04188923A - Light receiving element and information equipment using the same - Google Patents

Abstract

PURPOSE:To reduce a current consumption by turning off the power source of a photodetecting circuit which operates the signal processing of the output from a photodiode if unnecessary. CONSTITUTION:A discriminating means 17 of a photodetecting circuit 11 discriminates whether or not an identification code transmitted from an outside controller is coincident with the identification code of its own stored in a storage means 14. When the means 17 judges that the identification code transmitted from the outside controller is coincident with the identification code of its own, the power source of the photodetecting circuit 11 is turned on, and the output through a communication means 18 to the outside controller is operated. Therefore, the power source of the photodetecting circuit 11 can be turned off if unnecessary. Thus, the current consumption can be reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a light-receiving element and information equipment such as a printer, facsimile machine, and copying machine using the light-receiving element.

<Prior art> As shown in FIG.
It consists of an amplifier circuit 2 and a waveform shaping circuit 3, and outputs either High or Low depending on the presence or absence of incident light to the photodiode 1.

<Problems to be Solved by the Invention> In recent years, in information devices equipped with light receiving elements, the number of light receiving elements used has increased as the number of sensors has increased.

In order to cope with this, a large number of (N
When transmitting data between two (3) light-receiving elements and one control unit (CPU) 4, a transmission line must be provided for each output of each light-receiving element, as shown in FIG. Wiring inside the device has become complicated, which is an obstacle to miniaturizing the device.

Also, the number of data rhinos required to connect to the CPU is
This is necessary for the number of light-receiving elements, and the power supply of the photodetection circuit is always in an off state, resulting in a large amount of current consumption.

In view of the above, an object of the present invention is to provide a light-receiving element and information equipment using the light-receiving element, which facilitates wiring simplification, facilitates miniaturization of equipment, and reduces current consumption.

Means for solving the problem 〉 (+) The means for solving the problem according to claim I of the present invention is defined in Section 1.2.
4.5, in a light receiving element consisting of a light receiving element chip IO and a light detecting circuit II that processes the output from the light receiving element chip IO, the light detecting circuit ll
The storage means (4) for storing an identification code within the controller recognizes the identification code sent from the external control device (I6), and if this identification code matches its own identification code stored in the storage means (14). When the determining means 17 determines that the identification code matches the own identification code, the power of the photodetecting circuit 11 is turned on and the external control device 1
6 and a communication means 18 for outputting the output.

(2) The problem solving means according to claim 2 is as shown in FIG.
A large number of light receiving elements according to claim I are arranged, and these light receiving elements are connected to an external control device 16 through one transmission line.

(3) The problem solving means according to claim 3 is as shown in FIG.
In a light-receiving element consisting of a light-receiving element chip 10 and a light-detecting circuit 11 that processes the output from the light-receiving element chip 10, the light-receiving element receives a control signal from an external control device 16 or a previous-stage light-receiving element in the light-detecting circuit II. The start signal input circuit 30 accepts the input end signal as a start signal and turns on the power of the photodetector circuit 11, and the photodetector circuit 11 outputs the detected data of the optical signal incident on the photodetector chip IO to an external device. A data output circuit 31 that outputs to the control device 16, and an end signal that outputs an end signal to the next stage light receiving element and turns off the power of the photodetector circuit 11 after the data output circuit 31 sends the detection data. An output circuit 32 is provided.

(4) The problem solving means according to claim 4 is as shown in FIG.
A plurality of light receiving elements according to claim 3 are arranged, and an input terminal 30a of a start signal input circuit 30 of these light receiving elements;
External control device by connecting in series with the output terminal 32a of the end signal output circuit 32! ! 16, and the output terminal 31a of the data output circuit 31 is connected to the external control device 16 through one common transmission line.

<Operation> In the problem solving means according to claim I, the discrimination means 17 of the photodetection circuit 11 distinguishes between the identification code sent from the external # button device 16 and its own identification code stored in the storage means 14. When the determining means 17 determines that the identification code matches the own identification code, the light detection circuit l! The power is turned on and output is sent to the external control device 16.

Therefore, as in claim 2, data can be exchanged between the external control device 16 and a large number of light receiving elements using one transmission line.

Further, in claim 3, when the start signal input circuit 30 of the photodetection circuit 11 receives a control signal from the external control device 16 and a start signal from the light receiving element in the previous stage, the second signal is started. Photodetection circuit 1 that accepts it as a signal
After the data output circuit 31 outputs the detection data to the external control device 16, the end signal output circuit 32 outputs a signal to the light receiving element of the next stage.

Therefore, as in claim 4, data can be exchanged between the plurality of light receiving elements and the external control device 16 using two lines.

Further, according to claim 1.3, the power of the photodetection circuit 11 can be turned off except when necessary.

<Example> Embodiments of the present invention will be described below based on the drawings.

[First embodiment of claim 1] Fig. 1 is a block diagram of a light-receiving element according to the first embodiment of the present invention, Fig. 2 is a flowchart thereof, and Fig. 3 is a diagram of an information device using the light-receiving element. It is a figure which shows an example.

As shown in FIG. 1, the light receiving element of this embodiment includes a light receiving element chip (photodiode) 10 and a light detection circuit (signal processing 1c) I+ for signal processing the output from the photodiode 10.
It consists of

The photodetector circuit 11 includes an amplifier circuit 12 that amplifies the output of the photodiode IO, a waveform shaping circuit I3 that shapes the output waveform of the photodiode IO amplified by the amplifier circuit 12, and an identification code (ID nanobar). It is comprised of an external write-once memory 14 for storing ID numbers, which is a storage means for storing ID numbers, and an interface circuit I5 for communication with an external control unit (CPU).

The communication interface circuit 15 is connected to a control device (C
a discriminating means 17 for recognizing an ID number sent from the P U) and discriminating whether or not this ID number matches its own [D number stored in the write-once memory 14; When the determining means 17 determines that the ID nanobar matches its own ID nanobar, a communication means 18 is provided which turns off the power of the photodetecting circuit 11 and outputs the output to the external CPU.

Note that the photodiode IO1 amplifier circuit I2, the waveform shaping circuit 13, the write-once memory 14, and the communication interface circuit 15 are integrated into one chip.

Here, the operation of the light receiving element will be explained according to the flowchart 1 shown in FIG.

First, the interface circuit 15 reads the control signal sent from the external fiEcPU and checks whether the ID number sent from the external fiEcPU matches the own ID number stored in the write-once memory 14, which is a storage means. The determination means 17 makes the determination.

At this time, if they do not match, the period status is determined.

On the other hand, if they match, the power of the photodetection circuit 11, that is, the amplifier circuit 12 and the waveform shaping circuit 13 is turned off. Then, the photodetection circuit 11 detects the optical signal incident on the photodiode 10, and the amplification circuit I2 and waveform shaping circuit I3
The detection signal is output to the external CP via the communication means 18 of the interface circuit 15.

Thereafter, the power to the amplifier circuit 12 and waveform shaping circuit 13 is turned off to return to the initial state.

Note that the ID number is written in the write-once memory using a dedicated writer before the equipment is installed, and the write-once memory 14 may be a ROM, an electrification injection method, a junction breaking method, or a fuse blowing method.

In this way, within the photodetection circuit +1, there is a storage means 14 for storing an ID number, and an ID number sent from an external CPU.
Recognize the number and store this ID nanobar and storage means 14
When the determining means 17 determines whether or not the own ID nanobar stored in the ID nanobar matches the own ID nanobar, the power supply of the photodetecting circuit 11 is turned off. By incorporating a communication means 18 that is turned on and outputs to an external CPU, as shown in Fig. 3,
When a large number (N) of light receiving elements are arranged and data is exchanged with an external CPU 16, control signals and data signals can be transmitted using one transmission line 19.

Therefore, it is possible to significantly reduce the number of to-to wires, facilitate wiring within the device, and downsize the device.

Furthermore, since the power to the photodetection circuit II can be turned off except when necessary, current consumption can be reduced at the same time.

[Second Embodiment of Claim 1] FIG. 4 is a block diagram of a light receiving element according to a second embodiment of the present invention, and FIG. 5 is a flowchart thereof.

In this embodiment, the photodetection circuit +1 includes, as shown in FIG. ! 8 and an address writing interface 21, and the other configurations are the same as in the first embodiment.

Here, follow the Lf two operation flow shown in Figure 5 for 1,000 yards.
The operation of the above light receiving element will be explained.

First, using the dedicated memory writer 4 in the built-in iQ device, a) write the address number in the address memo'l-14 via the address input interface 21;

In this case, the address memory 14 may be a ROM of a charge injection type, a junction breaking type, a fuse blowing type, or the like. Alternatively, there is a method in which the address number is written in the address memory 14 from the control device of the device after installation to the device. In this case, the address memory 14 may be a RAM other than the above-mentioned ROM. Furthermore, the address write interface 21 can be included in the communication interface circuit 15 so that the terminals can be shared.

After writing an address into the address memory 14 using any of the methods described above, a control signal sent from an external control device inside the device is handled by a pass line, and an address nanobar is written into the address memory 14 as a storage means.
The determination means 17 of the interface circuit 15 determines whether it matches the own address number bar stored in memory, and if it does not match, it enters a standby state.

If they match, the amplifier circuit 12 of the photodetector circuit II, A/
Turn off the power of the D conversion circuit 20, and turn off the photodiode 1.l.
It detects the optical signal incident on O, outputs the detection signal to the pass line via the amplifier circuit 12 and A/D conversion circuit 20, and the communication means 18 of the interface circuit 20, and sends it to the external control device.

After outputting the detection signal, the amplifier circuit 12 and the A/
The power to the D conversion circuit 20 is turned off and the process returns to the standby state.

Since the light receiving element of this embodiment operates as described above, it is possible to obtain the same effects as in the first embodiment.

[Third Embodiment of Claim 3] FIG. 6 is a block diagram of a light receiving element according to a third embodiment of the present invention, and FIG. 7 is a diagram showing an example of an information equipment system using the light receiving element.

The photodetection circuit I+ of this embodiment is composed of an amplifier circuit 12, an A, /D conversion circuit 20, and a communication interface circuit 15, as shown in FIG.

And communication interface circuit 15! i. The control signal from the external control device is received as a start signal when the end signal from the πI stage ○ light receiving element is input.
A start signal input circuit 30 that turns off the power of the photodetection circuit II, a data output circuit 31 that outputs data detected from the optical signal incident on the photodetection circuit I+ or the photodiode IO to an external control device, and the data output circuit 31 The end signal output circuit 32 outputs an end signal to the next-stage light-receiving element and turns off the power of the photodetector circuit 11 after transmitting the detection data.

In addition, in FIG. 6, 30a is an input terminal of the start signal input circuit 30, 31a is an output terminal of the data output circuit 31, and 3
2a is an output terminal of the end signal output circuit 32.

In the above configuration, when a start signal is manually input from the external control device, the power circuit 30 turns off the power of the amplifier circuit 12 and A/D conversion circuit 20 of the photodetection circuit 11. Then, the photodetection circuit 11 detects the optical signal incident on the photodiode 10, and the amplification circuit 12, A
The detected data is outputted to the pass line through the /D conversion circuit 20 and the data output circuit 31, and sent to an external control device.

Thereafter, the start signal output circuit 32 outputs a note signal to the start signal input circuit 30 of the next stage light receiving element, and at the same time, the amplifier circuit 12 and the A/D conversion circuit 20 are turned off, and the state returns to the state of deafness.

The start signal input circuit 30 of the next-stage light-receiving element receives the end signal from the previous-stage light-receiving element as a start signal,
Repeat the same operation as the previous stage light receiving element.

In this way, the start signal input circuit 30 operates the photodetection circuit 11 by the manual input of the start signal, the data output circuit 3I outputs the detection data to the external control device, and then the etching signal output circuit 32 operates the photodetection circuit 11. END to Motoko
By configuring it to output a signal, as shown in FIG.
The start signal input terminal 30a of the 1st light receiving element is connected to the external control device 16, and the end signal output terminal 32a of the 1st light receiving element is connected to the start signal input terminal 30a of the 2nd 9th light receiving element. It is sufficient to connect the data output terminals 31a of each light-receiving element to one common signal line 19 from the external control device 16 while making the connections in sequence using a Norise connection.

In other words, by simply using two lines between the light receiving element and the external control device 16, by simply sending a start signal from the external control device 16 to the first light receiving element, the data from the light receiving elements in sequence can be sent to the external control device. 16.

Other configurations and effects are similar to those of the first embodiment.

It should be noted that the present invention is not limited to the above embodiments, and it goes without saying that many modifications and changes can be made to the above embodiments within the scope of the present invention.

For example, in the above embodiment, the photodetector and the signal processing section (photodetection circuit) may be composed of two or more chips.

However, a phototransistor may be used instead of a photodiode.

<Effects of the Invention> As is clear from the above explanation, according to the present invention, signal transmission between a large number of light receiving elements and an external control device can be performed using one or two lines, resulting in a significant lead. It is possible to reduce the number of wires, facilitate wiring within the device, and downsize the device.

Furthermore, since the power to the optical intelligence circuit can be turned off except when necessary, current consumption can be reduced at the same time.

[Brief explanation of drawings]

Fig. 1 is a block diagram of a light receiving element according to the first embodiment of the present invention, Fig. 2 is a flowchart thereof, Fig. 3 is a diagram showing an example of the system of information equipment using the light receiving element, and Fig. 4 is a diagram of the present invention. A block diagram of the light receiving element according to the second embodiment, FIG. 5 is a flowchart thereof, FIG. 6 is a block diagram of the light receiving element according to the third embodiment of the present invention, and FIG. 7 is information using the light receiving element. Figure 8 is a block diagram of a conventional light-receiving element, and Figure 9 is a block diagram of a conventional light-receiving element.
y is a diagram showing an example of the /stem of 7 pieces of information equipment. IO photodetector chip, lI, photodetector circuit, 141. S2
Storage means, 16 External control device, 17 Discrimination means, 18 Communication means, 30 Start signal input circuit, 30a Start signal input terminal, 3I Data output circuit, 31a Data output terminal, 32 End signal output circuit, 32a: End signal Output terminal. Applicant Noyab Co., Ltd.

Claims (1)

[Scope of Claims] 1. A light receiving element consisting of a light receiving element chip and a photodetection circuit for signal processing the output from the light receiving element chip,
Storage means for storing an identification code in the photodetection circuit;
a determining means for recognizing an identification code sent from an external control device and determining whether or not this identification code matches its own identification code stored in the storage means; When it is determined that it matches the identification code of
A light-receiving element characterized in that it is provided with communication means for turning on the power of the light-detecting circuit and outputting it to an external control device. 2. An information device characterized in that a large number of light receiving elements according to claim 1 are arranged, and these light receiving elements are connected to an external control device through a single transmission line. 3. In a light-receiving element consisting of a light-receiving element chip and a photodetection circuit that processes the output from the light-receiving element chip,
a start signal input circuit that receives a control signal from an external control device or an end signal from a previous stage light receiving element as a start signal and turns on the power of the photodetection circuit when a control signal from an external control device or an end signal from a previous stage light receiving element is input into the photodetection circuit; and a photodetection circuit. a data output circuit that outputs data obtained by detecting an optical signal incident on the light receiving element chip to an external control device; and after the data output circuit sends the detection data, outputs an end signal to the next stage light receiving element; 1. A light-receiving element comprising: an end signal output circuit for turning off the power of the photo-detection circuit. 4. A large number of light-receiving elements according to claim 3 are arranged, and the input terminals of the start signal input circuit and the output terminal of the end signal output circuit of these light-receiving elements are connected in series and connected to an external control device, and the data 1 with a common output terminal of the output circuit
An information device characterized in that it is connected to an external control device through a transmission line.