JPH0470675B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to improvements in sensor input circuits. For example, a notification device is known that detects the opening and closing of a door, etc., transmits the information via a telephone line to a receiving device installed in a remote location, and displays the information audibly or visually there.

In such a device, in order to detect the opening/closing of a door, etc., there is a sensor having an electrical opening/closing means, and a predetermined current is applied to the sensor to reliably detect the operating state of the electrical opening/closing means of the sensor. A sensor input circuit is provided to receive the opening/closing output.

(Prior Art) In a conventional sensor input circuit, the above-mentioned energizing current is a constant value during the operation of the sensor, so in a device in which a large number of sensors are provided, the current increases in accordance with the number of sensors.

(Problems to be Solved by the Invention) Therefore, when the power source of the above-mentioned reporting device is configured with only a battery, the power consumption due to the above-mentioned energizing current becomes an important problem, and there has been a demand for power saving.

Therefore, the present invention provides a predetermined energizing current to ensure reliable detection of the sensor's operation when the sensor is in operation, and configures the sensor input circuit so that the current value becomes the minimum necessary value after the sensor is in operation. This is intended to save power.

(Means for Solving the Problems) Therefore, in the present invention, either a sensor having an electrical switching means, and first and second resistors each connected in series to the sensor to form a closed circuit are provided. Consisting of a transistor inserted into one closed circuit to open and close the closed circuit, and a flip-flop circuit to control the transistor,
When the above sensor is normally (open), the above transistor is activated by the output of the above flip-flop circuit.
NO, and by resetting the flip-flop circuit and turning off the transistor due to the output signal of the sensor during operation (closed), the current flowing through the sensor after operation is reduced, and the sensor is restored. The present invention is characterized in that the flip-flop circuit is inverted due to this, and the transistor is turned on again.

(Example) Next, the present invention will be explained in detail with reference to an example shown in the drawings. FIG. 1 is a block diagram for explaining a sensor input circuit according to the present invention, where 1 is a sensor, S ₁
is an electrical opening/closing means (switch) possessed by sensor 1, 2 is a sensor input circuit, and 3 is a control circuit.
Based on the status information of the sensor 1, data signals for visual display etc. are sent to the above-mentioned receiving device (notification operation), and it is configured to include, for example, a microprocessor. The details are omitted because they are not directly related to the invention and are the same as conventional ones.

R ₁ and R ₂ are resistors, TR is a transistor, 4 is a flip-flop circuit, 5 to 7 are inverters, and 8 is a differential circuit. Next, the operation will be explained along with a second operation waveform diagram.

First, when the power is turned on, the output terminal of the control circuit 3
A set signal A is sent from SET, and the flip-flop circuit 4 enters the set state. That is, the voltage level of the output terminal becomes a low level (“0”), and the transistor TR becomes an ON state.

Therefore, when the sensor 1 responds and the switch _S1 closes, a predetermined current I flows through the resistors _R1 and _R2 .
is obtained. This makes it possible to reliably detect the closing of switch _S1 . By closing the switch _S1 , the input of the inverter 5 becomes "0" and its output becomes high level ("1"), which is input to the inverter 7 via the differentiating circuit 8, so the control circuit A starting pulse B is applied to the input terminal INT of No. 3.

Further, the information at this time is also given to another input terminal P, and the state of the sensor 1 can be monitored by this input terminal P. When a plurality of sensors 1 are provided, the input terminal is shared, and an input terminal P is provided corresponding to each sensor. The control circuit 3 is activated by the activation pulse B, performs a predetermined notification operation according to the information at the input terminal P, and sends out a reset pulse C to the output terminal. As a result, the flip-flop circuit 4 is brought into a reset state, and its output terminal becomes "1", so that the transistor TR is turned off. Therefore, the current flowing I is only the current flowing through the resistor _R1 . Since the minimum necessary current value at this time can be made much smaller than the above-mentioned predetermined current value, the power consumption can be greatly reduced.

After that, when the switch _S1 is opened, the output of the inverter 5 becomes "0", so an inverted signal is applied to the input terminal CK of the flip-flop circuit 4 via the inverter 6, the flip-flop circuit 4 is inverted, and the output becomes "0". 0”, so the transistor
TR becomes ON state again, the state is restored to the state at the time of power-on described above, and the subsequent operation of sensor 1 is monitored.

(Effects of the Invention) As explained above, according to the present invention, since the current flowing to the sensor 1 is reduced after the sensor 1 operates, it is possible to save power without affecting the operation detection. Furthermore, in recent years, a microprocessor equipped with a standby function is sometimes used as the control circuit 3 in order to save power, but according to the sensor input circuit according to the present invention, the activation pulse B is input to the input terminal. Even if the microprocessor wakes up to the operating state and performs a predetermined reporting operation only when input to the microprocessor, and then remains in the standby state, there is an advantage that the above-mentioned control of the energizing current can be carried out. Note that the set signal A and the reset pulse C described above do not necessarily need to be given from the control circuit 3; for example, the set signal A may be provided with a circuit that sends out a pulse when the power is turned on, and the output thereof may be given. good. Furthermore, as for the reset pulse C, a signal from the output side of the inverter 5 can also be formed.

[Brief explanation of the drawing]

FIG. 1 is a block diagram for explaining a sensor input circuit according to the present invention, and FIG. 2 is an operational waveform diagram thereof. 1...Sensor, 2...Sensor input circuit, 3
...Control circuit, 4...Flip-flop circuit.

Claims (1)

[Claims] 1 A sensor having electrical switching means, first and second resistors each connected in series to the sensor to form a closed circuit, and inserted into either one of the closed circuits to open and close the closed circuit. When the sensor is normally (open), the transistor is turned on by the output of the flip-flop circuit, and the transistor is activated (closed).
By resetting the flip-flop circuit and turning off the transistor due to the output signal of the sensor, the current flowing through the sensor after operation is reduced, and the flip-flop circuit is reset due to the sensor's recovery. and reconnect the above transistor
A sensor input circuit characterized in that it is turned on.