JPH05335923A - Photodetector - Google Patents

Abstract

PURPOSE:To reduce the total current consumption by connecting a display circuit for displaying a passing state of an object between a 1st power supply and a 2nd power supply. CONSTITUTION:A display circuit 117 used to light or extinguish a light emitting diode 115 is connected between a power supply line 118 to which a power supply voltage Vcc (30V) is applied and a power supply line 103 to which a power supply voltage Vcc (5V) is applied. Similarly, a display circuit 125 used to light or extinguish a light emitting diode 116 is connected between the power supply line 118 and the power supply line 103. Let a current consumed in the inside of a regulator 101 be I0, a current consumption of a 5V system circuit 102 be I1 and a current consumption of an output circuit 114 be I2, then, since the current consumption of the 5V system circuit 102 is fixed to be I1=10mA because of its characteristic, the current I1 is constant independently of lighting/ extinguishment of the light emitting diodes 115, 116. Thus, the total current consumption ITTL of the circuit is constant as ITTL I0+I1+I2 independently of lighting / extinguishment of the light emitting diodes 115, 116, thereby reducing the current consumption.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photodetecting device capable of displaying whether or not an object blocks the optical path of an optical signal.

[0002]

2. Description of the Related Art FIG. 2 is a diagram showing a conventional photodetector. In FIG. 2, (1) is a regulator, for example, 3
The constant voltage of 5V is generated from the power source voltage Vcc of 0V. (2) is a power supply line to which the constant voltage of 5 V is applied
It is a 5V system circuit that operates by being connected to (3). 5V system circuit
(2) Inside, (4) is an oscillating circuit OSC that generates an oscillating clock of a predetermined cycle, and causes the light emitting diode (5) to blink in a few μsec width in synchronization with the oscillating clock. (6)
Is a light receiving diode which receives an optical signal when the light emitting diode (5) is turned on through a reflector or the like and supplies a current corresponding to the optical signal level. Reference numeral (7) is a resistor for converting the current flowing through the light receiving diode (6) into a voltage. The voltage component thus photoelectrically converted has the DC component removed via the capacitor (8). (9) is an amplifier that amplifies the voltage signal from which the DC component is removed. Here, a variable resistor (10) for adjusting the amplification factor is connected to the amplifier (9). This is because when the distance between the light emitting diode (5) and the reflecting plate becomes long in accordance with the passage condition of the object, the light receiving sensitivity of the light receiving diode (6) deteriorates, and the amplifier (9) is connected to the rear stage. It is provided in order to prevent that the amplification level required for signal processing cannot be obtained. That is, regardless of the distance between the light emitting diode (5) and the reflector, the variable resistance
By adjusting (10), it is possible to obtain an amplification level higher than a predetermined level. (11) is reference voltage V ₁ and amplifier
(9) A comparator for comparing the output with the amplifier (9) "H" having a width of several μsec when the output level exceeds the reference voltage V _1.
Is output. Reference numeral (12) is a comparator for comparing the reference voltage V ₂ higher than the reference voltage V _{1 with the} output of the amplifier (9). When the output level of the amplifier (9) exceeds the reference voltage V ₂ , “H” having a width of several μsec. Is output. Reference numeral (13) is a logic circuit, which carries out predetermined arithmetic processing on the comparison outputs of the comparators (11) and (12). (14) is connected to the power supply Vcc which receives and operates the logic circuit (13) and controls the opening and closing of loads such as relays.
This is a 30V system output circuit, and when the object blocks the optical path of the optical signal, that is, the comparison outputs of the comparators (11) and (12) are both "L".
At the time of, the relay is closed, and when the optical path of the optical signal is not interrupted, the relay is opened.

Further, (15) and (16) are light emitting diodes for displaying whether or not an object blocks the optical path of an optical signal,
It is assumed that they emit light of yellow and green, respectively. (17) (18)
Is a transistor for making each light emitting diode (15) (16) emit light, and its collector is each light emitting diode (15) (1)
It is connected to a 5V power source line (3) via 6) and the emitter is grounded. The transistors (17) and (18) are driven based on the comparison outputs of the comparators (11) and (12). For example, when the output level of the amplifier (9) exists between V ₁ and V ₂ , the comparator (11) repeatedly outputs “H” with a width of several μsec, and accordingly, the logic circuit (13) causes human "H" extended to a width of several msec is repeatedly output so that the transistor (17) is driven and the light emitting diode (15) is lit visually. Also the amplifier
When the output level Va of (9) is larger than V ₂ , the comparator (11)
"H" with a width of several μsec is repeatedly output from (12), and along with this, "H" extended to a few msec width is repeatedly output from the logic circuit (13) so that it can be seen by humans. (17) (18) is driven and light emitting diode
(15) (16) lights up visually. Furthermore, when the optical path of the optical signal is cut off and the output level Va of the amplifier (9) becomes zero, the comparison output of the comparators (11) and (12) always becomes zero, and the light emitting diodes (15) and (16) are turned off. To do.

By the way, the light emitting diodes (15) and (16) are not only for display as described above, but when the amplification factor of the amplifier (9) is adjusted according to the distance between the light emitting diode (5) and the reflector,
It is also used for confirmation. For example, a light emitting diode
When the distance between (5) and the reflector is short, the light receiving sensitivity of the light receiving diode (6) is good, so that the amplification factor of the amplifier (9) may be relatively small. That is, the light emitting diode (15) (1
The gain of the amplifier (9) can be set to an appropriate value by adjusting the variable resistor (10) while watching the yellow or green display of (6). On the other hand, when the distance between the light emitting diode (5) and the reflecting plate is long, the light receiving sensitivity of the light receiving diode (6) is deteriorated, so that the amplification factor of the amplifier (9) is required to be relatively large. That is, by adjusting the variable resistor (10) while observing the yellow or green display of the light emitting diodes (15) (16), the amplification factor of the amplifier (9) can be set to an appropriate value in the same manner. It is possible to suppress unnecessary current consumption. In order to set the amplification factor of the amplifier (9) more appropriately, different reference voltages are applied to the- (inverting input) terminal, and the output of the amplifier (9) is applied to the + (non-inverting input) terminal. It is only necessary to provide three or more comparators, and correspondingly three or more light emitting diodes and transistors controlled by the logic circuit (13).

In the circuit shown in FIG. 2, a light emitting diode is used.
(5) (15) (16), light receiving diode (6), resistor (7), capacitor (8), variable resistor (10), transistors (17) (18) except that the configuration is integrated To do.

[0006]

In FIG. 2, the current consumption of the regulator (1) is I ₀ , the current consumption of the 5V system circuit (2) is I ₁ , the current consumption of the output circuit (14) is I ₃ , and the light emission is performed. Diode (1
5) (16) and transistor (17) (18) current consumption is I _LED , the current I _TTL supplied to the regulator (1) is I
Only _TTL = I ₀ + I ₁ + I ₂ + I _{LED is} required.

The current consumption of the above IC is usually 10
The current consumption of the light emitting diodes (15) and (16) is required to be about 2 mA due to the relationship between the light emitting power and the amount of current at that time. Therefore, the current consumption of the light emitting diodes (15) and (16) occupies a large weight in the current consumption of the IC, and there is a problem that other configurations are sacrificed. Further, when the number of light emitting diodes is increased, the amplification factor of the amplifier (9) can be set more appropriately, but there is a problem that the current consumption increases. Further, since the current consumption of the IC is designed to be about 10 mA, there is a problem that the number of light emitting diodes is limited, that is, the proper setting of the amplification factor of the amplifier (9) is also limited.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a photodetector capable of appropriately detecting an object without increasing current consumption.

[0009]

The present invention has been made to solve the above problems, and is characterized by a photoelectric conversion circuit for photoelectrically converting an optical signal obtained in a predetermined cycle. A first amplifier that amplifies the voltage signal obtained from the photoelectric conversion circuit, a comparator that compares the amplified signal obtained from the amplifier with a reference signal, and a logic circuit that processes the comparison signal obtained from the comparator An output circuit that is connected to a power source and that processes a logic signal obtained from the logic circuit to drive a load is connected to a second power source that is larger than the first power source, and an object passes the optical path of the optical signal. A photodetector that detects the interruption and puts the load in a predetermined state, and displays whether the object interrupts the optical path of the optical signal between the first power supply and the second power supply. Display circuit The point was painting.

[0010]

According to the present invention, since the display circuit for displaying whether or not the object has interrupted the optical path of the optical signal is provided between the first power supply and the second power supply, the object can be consumed without increasing the current consumption. Can be reliably detected.

[0011]

The details of the present invention will be described in detail with reference to the drawings. FIG. 1 is a view showing an apparatus of the present invention, which is integrated into an IC except for a part as in FIG. In FIG. 1, (10
Reference numeral 1) is a regulator that generates a constant voltage of 5 V from a power supply voltage Vcc of 30 V, for example. (102) is the above 5
This is a 5V system circuit that operates by being connected to a power supply line (103) to which a constant voltage of V is applied. Inside the 5V system circuit (102), reference numeral (104) is an oscillation circuit OSC which generates an oscillation clock of a predetermined cycle, and causes the light emitting diode (105) to blink in several μsec width in synchronization with the oscillation clock. Reference numeral (106) is a light receiving diode which receives an optical signal when the light emitting diode (105) is turned on via a reflection plate or the like (not shown) and supplies a current corresponding to the optical signal level. (107) is a photodiode (10
This is a resistor that converts the current flowing in 6) into a voltage. A photoelectric conversion circuit is composed of the light receiving diode (106) and the resistor (107). The voltage signal photoelectrically converted in this way is a capacitor
The DC component is removed via (108). (109) is an amplifier for amplifying the voltage signal from which the DC component is removed. Here, the amplifier (109) has a variable resistor (11
0) is connected. This is because when the distance between the light emitting diode (105) and the reflector becomes long in accordance with the passage condition of the object, the light receiving sensitivity of the light receiving diode (106) is deteriorated, and the light receiving diode (106) is connected to the rear stage. It is provided in order to prevent that the amplification level required for signal processing cannot be obtained. That is, the light emitting diode (10
Regardless of the distance between 5) and the reflector, it is possible to obtain an amplification level above a predetermined level by adjusting the variable resistor (110). (111) is a reference voltage V ₁ and an amplifier (109)
This is a comparator for comparing with the output, and when the output level of the amplifier (109) exceeds the reference voltage V ₁ , "H" of several μsec width
Is output. (112) is a reference voltage V ₂ higher than the reference voltage V _1.
It is a comparator that compares the output with the amplifier (109) output,
A few μ when the output level of the amplifier (109) exceeds the reference voltage V _2.
Output "H" of sec width. (113) is a logic circuit composed of MOS transistors, and comparators (111) (11
The comparison output of 2) is subjected to predetermined arithmetic processing. still,
It is assumed that the total amount of current consumed inside the 5V system circuit (102) is set to 10 mA. (114) is an output circuit of 30V system connected to the power source Vcc, which controls the opening and closing of the load such as a relay in response to the calculation result of "H" or "L" of the logic circuit (113), and the object is an optical signal. The relay is closed when the optical path of the optical signal is blocked, that is, when the comparison outputs of the comparators (111) and (112) are both "L", and the relay is opened when the optical path of the optical signal is not blocked.

Further, (115) and (116) are light emitting diodes for displaying whether or not an object blocks the optical path of an optical signal and for confirming the adjustment state of the amplification factor of the amplifier (109), It shall emit yellow and green light, respectively. Reference numeral (117) is a display circuit for turning on or off the light emitting diode (115), and a power supply line (118) to which a power supply voltage Vcc of 30V is applied.
And a power supply line (103) to which 5V is applied. Inside this display circuit (117), the transistor
(119) operates by applying to the base a logic signal of "H" or "L" according to the comparison output of the comparator (111),
The emitter is grounded. Also, the transistor (120)
(121) is a current mirror connection, and outputs a current having a predetermined ratio of the collector current of the transistor (119) from the collector of the transistor (121). The transistor (122) operates by supplying the collector current of the transistor (121) to the base, and the emitter is connected to the power supply line (102) via the resistor (123). The transistor (124) operates by supplying the emitter current of the transistor (122) to the base, the collector is connected to the base of the transistor (122), and the emitter is connected to the power supply line (102). That is, the transistors (122) and (124) form a constant current circuit capable of keeping the light emission amount of the light emitting diode (115) constant even if the power supply Vcc changes. Similarly, (125) is a display circuit for turning on or off the light emitting diode (116), and the power line (1
It is connected between 18) and the power supply line (103). Inside the display circuit (125), the transistor (126) has "H" or "L" depending on the comparison output of the comparator (112) as a base.
Is applied to operate, and the emitter is grounded. Further, the transistors 127, 128 are current-mirror connected, and a current having a predetermined ratio of the collector current of the transistor 126 is output from the collector of the transistor 128. Transistor (129) is the base transistor
The collector current of (128) is supplied to operate, and the emitter is connected to the power supply line (102) through the resistor (130).
Also, the transistor (131) is a transistor (129) on the base.
The emitter current is supplied to operate, the collector is connected to the base of the transistor (129), and the emitter is connected to the power supply line (102). That is, the transistor (129) (1
Reference numeral 31) constitutes a constant current circuit capable of keeping the light emission amount of the light emitting diode (116) constant even if the power supply Vcc fluctuates. The current consumption when the light emitting diodes (115) and (116) emit light is about 2 mA.

For example, the object does not block the optical path of the optical signal,
The output level of the amplifier (109) is the reference voltage V ₁ and the reference voltage V ₂
, And the output of the comparator (111) becomes "H", the display circuit (117) operates and the light emitting diode (115) is turned on. When the output level of the amplifier (109) is the reference voltage V ₂ or higher,
As the outputs of the comparators (111) and (112) both become “H”, the display circuits (117) and (125) operate together, and the light emitting diodes (115) and (116) both light up. .. Further, when an object passes between the light emitting diode (105) and the reflector and the optical path of the optical signal of the light emitting diode (105) is blocked, the output level of the amplifier (109) becomes zero. As the outputs of (111) and (112) both become "L", the display circuits (117) and (125) both stop operating, so that the light emitting diodes (115) and (116) are both turned off. Become. From the above, the passing state of the object between the light emitting diode (105) and the reflector can be confirmed by turning on and off the light emitting diodes (115) and (116). Furthermore, depending on the environment in which an object passes, for example, when the distance between the light emitting diode (105) and the reflector is short, the light receiving sensitivity of the light receiving diode (106) is improved, so the amplification factors of the amplifier (109) are compared. It is fine to be small. That is, the light emitting diode (115)
By adjusting the variable resistor (110) while observing the yellow or green display of (116), the amplification factor of the amplifier (109) can be set to an appropriate value. On the other hand, when the distance between the light emitting diode (105) and the reflecting plate is long, the light receiving sensitivity of the light receiving diode (106) is deteriorated, so that the amplification factor of the amplifier (109) is required to be relatively large. That is, the light emitting diodes (115) (116)
By adjusting the variable resistor (110) while observing the yellow or green display of, the amplification factor of the amplifier (109) can be set to an appropriate value, and wasteful current consumption of the amplifier (9) can be suppressed. ..

Here, it is consumed inside the regulator (101).
Current I₀, 5V system circuit (102) consumption current I₁,output
The current consumption of the circuit (114) is I₂, Consumption of display circuit (117) (125)
Current I_ledThen, the current consumption of the 5V system circuit (102)
Due to the characteristics of₁= 10mA, so the light emitting diode
Regardless of whether the mode (115) (116) is on or off₁Is constant
It That is, the light emitting diodes (115) (116) are off.
At this time, the total current amount I consumed in the circuit of FIG._TTLIs I_TTL= I₀
＋ I₁＋ I₂Becomes Also, the light emitting diode (115) and / or
Alternatively, when (116) is lit, the regulator (101) does not
The current supplied to the source line (102) is the same as that of the 5V system circuit (102).
I because the current consumption is constant₁-I_ledCan only be
Than I_TTLIs I_TTL= I₀＋ (I₁-I_led) + I₂＋ I_led=
I₀＋ I₁＋ I₂Becomes Therefore, from both formulas,
Figure 1 circuit is erased regardless of whether the (115) (116) is on or off
Cost current I_TTLBecomes constant and I is smaller than that of the conventional circuit of FIG._led
Therefore, the current consumption can be reduced. still,
Current consumption I of display circuits (117) (125) _ledIs a 5V system circuit (102)
Current consumption I₁It is a smaller range. Furthermore, 5V system
Within the range of the current consumption of the circuit (102),
The number of light emitting diodes driven by the display circuit
Even the current consumption I_TTLIs constant, the amplification factor of the amplifier (109)
Can be set appropriately.

[0015]

According to the present invention, since the display circuit for displaying the passing state of the object is connected between the first power supply and the second power supply which is larger than the first power supply, the total current consumption is displayed by the display circuit. Since it can be kept constant regardless of the operating state, the total current consumption can be reduced compared to the conventional one.

[Brief description of drawings]

FIG. 1 is a diagram showing a photodetector of the present invention.

FIG. 2 is a diagram showing a conventional photodetector.

[Explanation of symbols]

 (103) (118) Power line (106) Light receiving diode (107) Resistor (109) Amplifier (111) (112) Comparator (113) Logic circuit (114) Output circuit (115) (116) Light emitting diode (117) ( 125) Display circuit

Claims (3)

[Claims] 1. A photoelectric conversion circuit for photoelectrically converting an optical signal obtained in a predetermined cycle, an amplifier for amplifying a voltage signal obtained from the photoelectric conversion circuit, and comparing an amplified signal obtained from the amplifier with a reference signal. A comparator, a logic circuit for processing the comparison signal obtained from the comparator is connected to a first power supply, and an output circuit for signal processing the logic signal obtained from the logic circuit to drive a load. A photodetection device which is connected to a second power supply larger than one power supply and detects that an object has interrupted the optical path of the optical signal to bring the load into a predetermined state, wherein the first power supply and the second power supply are A photodetection device, characterized by including a display circuit for displaying whether or not the object blocks the optical path of the optical signal. 2. The photodetector according to claim 1, wherein the display circuit drives a light emitting diode. 3. The photodetector according to claim 1, wherein the current consumption of the display circuit is smaller than the current consumption of all the elements connected to the first power supply.