JPH0227634Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a light receiving circuit for receiving trigger light, and particularly aims to provide a light receiving circuit that can accurately receive only the trigger light without malfunctioning.

In devices that use consumable batteries as a power source, power consumption must be kept low so that they can be used for long periods of time. For example, in a vehicle body identification device used in the production process of an automobile factory, as shown in FIG. After the light receiving section 5 of the station 3 recognizes that it has received the trigger light, the light receiving section 5 of the station 3 generates light modulated with an identification code signal from the light emitting section 6 of the object to be identified 2. The device receives the light and demodulates it to identify the vehicle body, but the object to be identified 2 is powered by a battery and can withstand long periods of use from the start of production to factory shipment or shipping. Because it has to be
The light modulated with the identification code signal is emitted only when necessary, that is, when the trigger light from the station 3 is received.

The present invention is intended to provide a light receiving circuit suitable for use in equipment such as the above-mentioned vehicle body identification device, and will be described below based on embodiments with reference to the drawings.
In FIG. 2, 8 is a photoelectric conversion element such as a silicon solar cell that generates a current according to the amount of light when it receives light, 9 is a chiyoke coil connected in parallel to the photoelectric conversion element 8, and 10 is the photoelectric conversion element. An output transistor 11 generates an output according to the current generated from the conversion element 8, and a first control transistor 13 forms a current mirror circuit together with a diode 12 in order to generate a current equal to the collector current of the output transistor 10. 14 is a second control transistor for adjusting the base bias of the output transistor 10 according to the collector current of the first control transistor 11; 14 is the output transistor 10;
A flip-flop circuit 15 whose state changes according to the output of the flip-flop circuit 15 is a switching transistor controlled by the flip-flop circuit 14 in order to connect and disconnect the battery power source 16 and a load 17 such as an identification code signal generating circuit.

The first control transistor 11 and the second control transistor 13 are provided to bias the output transistor 10 to near the rising point. That is, the collector current of the output transistor 10 is Ic ₁
Then, the collector current of the first control transistor 11 constituting the current mirror circuit also becomes Ic ₁ , and the second
The control transistor 13 has the collector current Ic ₁
A negative feedback circuit is formed in which the collector current of the output transistor 10 is always Ic ₁ as a whole. For example, if the collector current Ic ₁ of the output transistor 10 is 0.5 μA, the collector current of the first control transistor 11 is also 0.5 μA, and the current flowing through the bias resistor 18 is 4 μA, so that the bias is stably maintained up to the vicinity of the rising point. As a whole, a light receiving circuit with a low current consumption of 5 μA is formed.

When the photoelectric conversion element 8 is irradiated with light in this state,
A current is generated according to the amount of light irradiated from the photoelectric conversion element 8. At that time, since the chiyoke coil 9 is connected in parallel to the photoelectric conversion element 8, the current in response to unchanging light, such as direct sunlight, is
The current is bypassed by the choke coil 9 and does not affect the output transistor 10. On the other hand, when instantaneous light that changes rapidly, such as strobe light, is irradiated, a pulse-like current is generated in accordance with the change in the amount of light, which is not bypassed by the chiyoke coil 9 but is supplied to the base of the output transistor 10. Therefore, the output transistor 10 turns on, the collector voltage drops in a pulse-like manner, and this is applied as a trigger to the flip-flop circuit 14, the state of the flip-flop circuit 14 is reversed, and the switching transistor 15 is turned on. A load 17 and a battery power source 16 are connected.

As mentioned above, the light receiving circuit according to the present invention is extremely stable against temperature changes and has high sensitivity because the output transistor 10 is stably biased near the rising point due to the negative feedback effect. It has the advantage of In addition, the light receiving circuit according to the present invention can distinguish between light that does not change and light that changes sharply, so it can be sensitive to only the trigger light even under direct sunlight or under illumination conditions, so it can prevent malfunctions. It is possible to provide a light-receiving circuit without any.

As described above, the light receiving circuit according to the present invention is stable, highly sensitive, and does not malfunction, and is therefore extremely useful for use in a code identification device in the automobile production process, where usage conditions vary widely.

[Brief explanation of the drawing]

FIG. 1 is a model diagram showing a code identification device to which the present invention is applied, and FIG. 2 is a circuit diagram showing an embodiment of the present invention. Explanation of main figure numbers, 8...Photoelectric conversion element, 9...Chiyoke coil, 10...Output transistor.

Claims (1)

[Scope of utility model registration request] a photoelectric conversion element that generates a current according to the amount of light received; a chiyoke coil connected in parallel to the photoelectric conversion element for bypassing the DC component of the current generated from the photoelectric conversion element; An output transistor connected to the conversion element, a current mirror circuit for obtaining a current equal to the collector current of the output transistor, and a conduction state controlled according to the current obtained by the current mirror circuit, and a base of the output transistor. and a control transistor for adjusting bias, and the current mirror circuit and the control transistor constitute a negative feedback circuit for the output transistor,
A light receiving circuit characterized in that the output transistor is biased near a rising point by the negative feedback circuit.