JPH08129020A - Running sensor - Google Patents

Abstract

PURPOSE: To obtain a running sensor not outputting an erroneous running pulse even if the voltage of a power supply fluctuates by providing a reference voltage variable means making the value of the reference voltage inputted to a comparator variable. CONSTITUTION: A magnet 11 is rotated by rotating a transmission shaft to apply a magnetic field to a Hall element 12. When positive voltage is induced by the Hall element 12, a transistor 13 becomes a continuity state to set the voltage of the negative terminal of a comparator 1 to 0V. The comparator 1 outputs a running pulse corresponding to the rotation of the magnet 11. When the voltage V of a power supply drops and the comparison voltage of the comparator 37 of a reference voltage variable means 6 drops, the output of the comparator 37 becomes 'H' and transistors 38, 43 become a continuity state and a resistor 21 is short-circuited. By this constitution, the reference voltage of the comparator is boosted and the output of the comparator 1 does not change. Therefore, the sending-out of the erroneous running pulse from the comparator 1 caused by the drop of the voltage V of the power supply is prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a travel sensor which outputs a pulse each time a vehicle travels a unit distance.

[0002]

2. Description of the Related Art A conventional travel sensor will be described with reference to FIG. In FIG. 5, 11 is a magnet attached to the transmission shaft of the vehicle, 12 is a Hall element, 1
3 is a transistor, 14 is a diode, 15 is a capacitance, 1
6 to 19, 21 and 22 are resistors, and 1 is a comparator.

A current is supplied to the Hall element 12 from a power source V via a resistor 16. In this state, Hall element 1
When a magnetic field is applied perpendicularly to 2, a voltage is induced in a direction perpendicular to the direction of current flow and is output to the transistor 13. The magnet 11 is rotated by the rotation of the transmission shaft, and the Hall element 12 receives N, S, N,
S, ... and a magnetic field are applied.

When a positive voltage is induced in the Hall element 12, the transistor 13 becomes conductive and the voltage at the negative terminal of the comparator 1 becomes 0V (ground voltage). Further, the reference voltage divided by the resistors 21 and 22 is supplied from the power supply V to the + terminal of the comparator 1.

The comparator 1 outputs "H" when the voltage (comparison voltage) input to the-terminal is lower than the reference voltage input to the + terminal, and outputs "L" when it is higher. Therefore, the output of the comparator 1 is the magnet 11
The traveling pulse which becomes "H" and "L" in response to the rotation of is output.

[0006]

As described above, in the conventional travel sensor, the bias current supplied to the Hall element is supplied from the power supply via the resistor. This power supply voltage is obtained from the battery of the vehicle, and when starting the engine of the vehicle, a large current is discharged from the battery to lower the power supply voltage. As a result, the bias current supplied to the Hall element changes, the voltage induced by the Hall element decreases, and the conductive state of the transistor 13 is brought into a state close to the non-conductive state, and the output of the comparator 1 is changed from "H" to "H". Change to "L".

That is, as shown in FIG. 6, time t = t
When the power supply voltage ₁ ~t ₄ is lowered, in response to a decrease in power supply voltage of the comparator 1 - comparison voltage input to the terminal is higher than 0V. This is because the power supply voltage appears at the negative terminal of the comparator 1 due to the non-conducting state of the transistor 13.

Further, the reference voltage input to the + terminal of the comparator 1 is proportional to the power supply voltage, and the comparison voltage is higher than the reference voltage during the period of time t = t _{2 to} t ₃ , and the output of the comparator 1 is It changes from "H" to "L". It is an object of the present invention to provide a travel sensor that does not output an erroneous travel pulse even when the power supply voltage changes.

[0009]

Means adopted by the present invention for solving the above-mentioned problems will be described with reference to FIGS. 1 and 3. FIG. FIG. 1 is a circuit configuration diagram showing a basic configuration and a first embodiment of a traveling sensor according to the present invention, and FIG. 3 is a circuit configuration diagram showing a basic configuration of the traveling sensor and a second embodiment. That is, the travel sensor of the present invention is a travel sensor that outputs a travel pulse based on the voltage induced from the Hall element 12 by the magnet 11 that rotates according to the vehicle speed, and a reference voltage generating means 2 that generates a reference voltage, The comparison voltage generating means 7 for generating a comparison voltage based on the voltage induced from the Hall element 12, the comparator 1 for outputting a pulse signal from the reference voltage and the comparison voltage, and the power supply voltage for driving the traveling sensor are lowered. In this case, the reference voltage changing means 6 is provided for changing the voltage value of the reference voltage so that the output of the comparator 1 maintains the output before the power supply voltage is reduced.

Further, the reference voltage varying means 6 has a relationship that the voltage value of the comparison voltage is equal to or lower than the voltage value of the reference voltage when the power supply voltage is a normal voltage value, and When the voltage value of the comparison voltage is higher than the voltage value of the reference voltage, the voltage detection unit 3 detects that the power supply voltage becomes a certain value or less, and the power supply voltage is constant by the voltage detection unit 3. And a boosting means 4 for boosting the reference voltage generated by the reference voltage generating means 2 to be higher than the voltage value of the comparison voltage when the value is detected to be less than or equal to the value.

Further, the reference voltage generating means 2 is configured to divide a power supply voltage by a resistor connected in series to generate a reference voltage, and the boosting means 4 is short-circuited with the resistor connected in series. It is configured to boost the voltage.

The boosting means 4 is configured to boost the reference voltage to the power supply voltage.

Further, the reference voltage changing means 6 has a relationship that the voltage value of the comparison voltage is equal to or higher than the voltage value of the reference voltage when the power supply voltage is a normal voltage value, and When the voltage value of the comparison voltage is lower than the voltage value of the reference voltage, the voltage detection unit 3 detects that the power supply voltage becomes a certain value or less, and the power supply voltage is fixed by the voltage detection unit 3. And a step-down means 5 for stepping down the reference voltage generated by the reference voltage generation means 2 so as to become lower than the voltage value of the comparison voltage when the value is detected to be less than or equal to the value.

Further, the reference voltage generating means 2 is configured to divide the power supply voltage by a resistor connected in series to generate a reference voltage, and the step-down means 5 is connected to the resistor connected in series to short-circuit the reference voltage. It is configured to step down the voltage.

Further, the step-down means 5 is configured to step down the reference voltage to the ground voltage.

[0016]

The reference voltage changing means 6 detects a change in the power supply voltage and changes the voltage value of the reference voltage supplied to the comparator 1 according to the change in the power supply voltage. That is, as the voltage value of the comparison voltage changes according to the change of the power supply voltage, the magnitude relationship between the voltage value of the comparison voltage and the voltage value of the reference voltage changes, and when the output of the comparator 1 changes, the reference voltage The variable means 6 raises or lowers the reference voltage so as to maintain the magnitude relation between the voltage value of the comparison voltage and the voltage value of the reference voltage before the power supply voltage decreases. As a result, even if the comparison voltage changes due to a change in the power supply voltage, the voltage value of the reference voltage can be changed in accordance with the change in the comparison voltage. The state is maintained and the wrong running pulse is not output even if the power supply voltage fluctuates.

Further, the voltage detecting means 3 detects that the power supply voltage has fallen below a certain value, and the boosting means 4
Boosts the reference voltage to a voltage value equal to or higher than the comparison voltage when the power supply voltage falls below a certain value. Therefore, when the power supply voltage is at a normal voltage value, the voltage value of the comparison voltage is equal to or lower than the voltage value of the reference voltage, and the voltage value of the comparison voltage becomes lower than the reference voltage due to the decrease of the power supply voltage. When it becomes higher than the voltage value,
Even if the power supply voltage drops, the voltage value of the comparison voltage can be maintained below the voltage value of the reference voltage, and an erroneous travel pulse is not output.

Further, the reference voltage generating means 2 divides the power supply voltage by the resistors connected in series to generate the reference voltage, and the boosting means 4 short-circuits the resistors connected in series to boost the reference voltage. In this way, the resistance is short-circuited to boost the reference voltage when the power supply voltage becomes equal to or lower than a certain value, so that the reference voltage can be boosted with a simple configuration.

Further, the boosting means 4 boosts the reference voltage to the power supply voltage. Therefore, when the voltage value of the comparison voltage becomes higher than the voltage value of the reference voltage due to the decrease of the power supply voltage, the voltage value of the comparison voltage becomes higher. Even if such a change occurs, the output of the comparator 1 does not change, and an erroneous traveling pulse is not output.

Further, the voltage detecting means 3 detects that the power supply voltage has become a certain value or less, and the step-down means 5
Lowers the reference voltage to a voltage value equal to or lower than the comparison voltage when the power supply voltage falls below a certain value. Therefore, when the power supply voltage is at a normal voltage value, the voltage value of the comparison voltage is greater than or equal to the voltage value of the reference voltage, and the voltage value of the comparison voltage is lower than the reference voltage due to the decrease in the power supply voltage. When it becomes lower than the voltage value,
The voltage value of the comparison voltage can be maintained above the voltage value of the reference voltage, and an erroneous travel pulse is not output.

The reference voltage generating means 2 divides the power supply voltage by a resistor connected in series to generate a reference voltage, and the step-down means 5 short-circuits the resistors connected in series to step down the reference voltage. In this way, the resistance is short-circuited to lower the reference voltage when the power supply voltage becomes equal to or lower than a certain value, so that the reference voltage can be stepped down with a simple configuration.

Further, the step-down means 5 steps down the reference voltage to the ground voltage. Therefore, when the voltage value of the comparison voltage becomes lower than the voltage value of the reference voltage due to the decrease of the power supply voltage, the voltage value of the comparison voltage becomes lower. Even if such a change occurs, the output of the comparator 1 does not change, and an erroneous traveling pulse is not output.

[0023]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit configuration diagram showing a first embodiment of a travel sensor according to the present invention. In the figure, a magnet 11, a Hall element 12, a transistor 13, a diode 14, a capacitor 1
The travel sensor composed of 5, the resistors 16 to 19 and the comparator 1 is as described in the conventional example of FIG.

The reference voltage generating means 2 is composed of voltage dividing resistors 21 and 22 connected in series. Then, the power supply voltage V is divided by these resistors 21 and 22 to generate a reference voltage, and this reference voltage is applied to the + of the comparator 1.
Applied to the terminal.

The voltage detecting means 3 comprises resistors 31 to 36, a comparator 37, a transistor 38 and a Zener diode 39. The boosting means 4 is composed of resistors 41 and 42 and a transistor 43. The voltage detecting means 3 and the boosting means 4 constitute a reference voltage varying means 6.

The comparison voltage generating means 7 is the transistor 1
3, the diode 14, the capacitor 15, and the resistors 17 and 18. The comparison voltage generating means 7 is provided for the transistor 13 when the voltage value of the induced voltage from the hall element 12 is equal to or higher than the switching voltage value of the transistor 13.
Becomes conductive and short-circuits the voltage at the contact points of the resistors 17 and 18 to the ground, while the induced voltage from the Hall element 12 is lower than the switching voltage, the transistor 13
Becomes non-conductive. That is, the comparison voltage input to the-terminal of the comparator 1 becomes the ground voltage (approximately 0V) when the transistor 13 is in the conductive state, and becomes the power supply voltage V when the transistor 13 is in the non-conductive state.

In such a comparison voltage generating means 7,
When the power supply voltage is a normal voltage value and the voltage value of the comparison voltage of the comparator 1 is equal to or lower than the voltage value of the reference voltage, the power supply voltage decreases and the transistor 13 becomes non-conductive. In this case, the reference voltage is a voltage obtained by dividing the power supply voltage, while the comparison voltage is almost the power supply voltage V. That is, as the power supply voltage V decreases, the magnitude relationship between the voltage value of the reference voltage and the voltage value of the comparison voltage is reversed.

Regarding the voltage detecting means 3, a constant voltage is input from the Zener diode 39 as the reference voltage supplied to the + terminal of the comparator 37. In addition, the comparator 37
The reference voltage supplied to the negative terminal of the resistors 31 and 3 is set to be higher than the reference voltage when the power supply voltage V is normal.
2 is set. Therefore, when the power supply voltage is normal, the output of the comparator 37 becomes "L" and the transistor 38
Is non-conductive, and the transistor 43 of the boosting means 4 is also non-conductive.

The power supply voltage V drops and the comparator 37
When the comparison voltage of the comparator is lower than the reference voltage, the output of the comparator 37 becomes "H" and the transistors 38 and 4
3 becomes conductive and short-circuits the resistor 21. When the resistor 21 is short-circuited, the reference voltage of the comparator 1 is boosted to the power supply voltage V. At this time, the comparison voltage of the comparator 1 also becomes substantially the power supply voltage V, but since this comparison voltage does not become higher than the power supply voltage V, that is, the reference voltage, the output of the comparator 1 does not change. Therefore, it is possible to prevent erroneous transmission of the traveling pulse from the comparator 1 due to the decrease in the power supply voltage.

The above operation will be described with reference to the time chart of FIG. 2. At time t = t _{2 to} t ₃ , the comparator 37 of the voltage detecting means 3 determines that the power supply voltage V is below a certain value.
Output "H".

When the output of the comparator 37 becomes "H", the transistor 43 of the boosting means 4 becomes conductive,
The resistor 21 is short-circuited and the reference voltage of the comparator 1 is boosted. That is, the power supply voltage V is supplied to the comparator 1 as a reference voltage. As mentioned above, the comparator 1
Of the comparison element, that is, the voltage generated by the reduction of the induced voltage of the Hall element 12 does not become higher than the power supply voltage V, so that the output of the comparator 1 maintains the “H” state.

As described above, in the device of the first embodiment, the reference voltage of the comparator 1 is boosted during the period t = t _{2 to} t ₃ , so that the power supply voltage has a normal voltage value. When the voltage value of the comparison voltage is below the voltage value of the reference voltage and the voltage value of the comparison voltage becomes higher than the voltage value of the reference voltage due to the decrease of the power supply voltage, the power supply voltage decreases. Even then, the voltage value of the comparison voltage can be maintained below the voltage value of the reference voltage, and an erroneous travel pulse is not output.

Although the reference voltage is boosted to the power supply voltage V in the first embodiment, the power supply line and the resistor 21 are used.
A resistor may be inserted between and to boost the voltage to a value slightly lower than the power supply voltage.

By the way, in the comparison voltage generating means 7 in the first embodiment, as described above, the power supply voltage has a normal voltage value, and the comparison voltage value of the comparator 1 is the reference voltage value. In the following cases, there is a characteristic that the voltage value of the comparison voltage becomes higher than the voltage value of the reference voltage when the power supply voltage decreases. Some of them have a characteristic that the voltage value of the comparison voltage becomes lower than the voltage value of the reference voltage. An embodiment in which the present invention is applied to the comparison voltage generating means having such characteristics will be described below.

FIG. 4 is a circuit configuration diagram showing a second embodiment of the traveling sensor according to the present invention. In the figure, the same parts as those described above are designated by the same reference numerals and the description thereof will be omitted. In this second embodiment, the comparison voltage generating means 7
The configuration is substantially different from that of the first embodiment described above, and other configurations are changed accordingly. Here, the comparison voltage generating means 7 will be described first, and then the other configurations will be described.

The comparison voltage generating means 7 has a first transistor 13a whose base terminal is connected to the output terminal of the Hall element 12, a base terminal connected to the collector terminal of this first transistor 13a, and The second transistor 13b whose collector terminal is connected to the power supply V
And the collector terminal of the first transistor 13a and the power supply V
A resistor 17a connected between the resistor 17a and a resistor 1a connected between the emitter terminal of the second transistor 13b and the ground.
7b, one end of which is the second transistor 13b and the resistor 1
A resistor 18a whose other end is connected to the negative terminal of the comparator 1 at the contact of 7b, a capacitor 15 connected between the other end of the resistor 18a and the ground, and a resistor 18b connected in parallel with this capacitor 15 And has a so-called current supply / output type circuit configuration.

In the comparison voltage generating means 7, when the Hall element 12 induces a predetermined switching voltage, the first transistor 13a becomes conductive and the second transistor 13b becomes non-conductive. In this state, the comparison voltage of the comparator 1 becomes almost the ground voltage and becomes equal to or lower than the reference voltage from the reference voltage generating means 2 described later, and the output of the comparator 1, that is, the sensor output becomes "H".

On the other hand, when the voltage induced by the Hall element 12 is less than the switching voltage of the first transistor 13a, the first transistor 13a becomes non-conductive. As a result, the second transistor 13b becomes conductive, and the comparison voltage supplied to the comparator 1 is divided by the resistors 18a and 18b and becomes a predetermined ON voltage. The resistance values of the resistors 18a and 18b are
The resistor 18a has a relatively small value so that the ON voltage has a voltage value equal to or higher than the reference voltage of the comparator 1.
b is set to a relatively large value. Therefore, the sensor output becomes "L" when the second transistor 13b is in the conductive state. Regarding the resistor 17b,
The resistance value is also large. The reason for this will be described later.

In summary, the comparison voltage generating means 7 in the device of the second embodiment makes the voltage value of the comparison voltage of the comparator 1 equal to or higher than the voltage value of the reference voltage of the comparator 1 when the power supply voltage has a normal voltage value. Therefore, the voltage value of the comparison voltage becomes lower than the voltage value of the reference voltage due to the decrease in the power supply voltage.

The reference voltage generating means 2 is composed of voltage dividing resistors 21 and 22 for dividing the internal power supply voltage Vcc.
The voltage divided by 1 and 22 is supplied as a reference voltage to be supplied to the + terminal of the comparator 1. This internal power supply voltage Vcc is a voltage supplied via the stabilized power supply circuit. Therefore, the reference voltage generated by the reference voltage generating means 2 is constant regardless of the fluctuation of the power supply voltage V. The reference voltage generated by the reference voltage generating means 2 is the second voltage of the comparison voltage generating means 7 as described above.
Is set lower than the comparison voltage when the transistor 13b of the second transistor 13b is in the conductive state.
Is set to be higher than the comparison voltage when is off.

The voltage detecting means 3 includes a comparator 37,
It is composed of voltage dividing resistors 31 to 33 and 39a and a resistor 34a. Then, a constant voltage obtained by dividing the internal power supply voltage Vcc by the voltage dividing resistors 33 and 39a is used as a reference voltage of the comparator 37, and a voltage obtained by dividing the power supply voltage V by the voltage dividing resistors 31 and 32 is used as a comparison voltage. 37.

In the voltage detecting means 3, the voltage dividing resistors 31 and 32 for dividing the power source voltage V to generate a comparison voltage and the voltage dividing resistors 33 and 39a for dividing the internal power source voltage Vcc to generate a reference voltage. The resistance value of is set such that the comparison voltage becomes equal to or higher than the reference voltage when the power supply voltage V is a normal voltage value, and when the power supply voltage V decreases, the second value of the comparison voltage generation means 7 The comparison voltage of the comparator 37 is set to be lower than the reference voltage of the comparator 37 in a time earlier than when the transistor 13b is turned off.

Therefore, when the power supply voltage V is in the normal state, the output of the comparator 37 becomes "L". As a result, the transistor 38 becomes non-conductive,
The reference voltage input to the + terminal of the comparator 1 is a constant value voltage obtained by dividing the internal power supply voltage Vcc by the resistors 21 and 22. Further, when the power supply voltage drops, the second transistor 1 of the comparison voltage generating means 7
The comparator 37 is turned on (output “H”) at a time earlier than the time when 3b is turned off.

In the step-down means 5, the output terminal of the comparator 37 is connected to its base terminal through the resistor 35,
And the collector terminal is the + terminal of the comparator 1,
A transistor 38 whose emitter terminal is connected to ground,
It is composed of a resistor 36 connected between the base terminal of the transistor 38 and the ground. The step-down means 5 and the voltage detecting means 3 described above are combined with the reference voltage varying means 6
Is composed.

In such a reference voltage changing means 6,
When the power supply voltage V drops, the comparator 3
The voltage value of the comparison voltage applied to the-terminal of 7 also decreases.
Then, the voltage value of this comparison voltage is + of the comparator 37.
When the voltage value of the reference voltage supplied to the terminal becomes equal to or lower than the voltage value, the output of the comparator 37 becomes "H" and the transistor 38 is turned on. When the transistor 38 becomes conductive, the + terminal of the comparator 1 and the ground are short-circuited, and the reference voltage of the comparator 1 becomes approximately 0 V (ground voltage).

Next, the operation of the second embodiment will be described with reference to the time chart of FIG. First, at time t ₁ , the engine is started and the power supply voltage V starts to drop. Then, at time t ₁₁ , the output of the comparator 37 becomes “H”. As a result, the reference voltage of the comparator 1 becomes almost 0V (ground voltage).

At the subsequent time t ₂ , the second transistor 13b of the comparison voltage generating means 7 is turned off. As a result, the negative terminal of the comparator 1 is grounded via the resistors 17b and 18b, but these resistors 17b and 18b are set to have a relatively high resistance value as described above. Therefore, the comparison voltage supplied to the-terminal of the comparator 1 gradually decreases due to the discharge from the capacitor 15.

Then, at time t ₃ , the second transistor 13b becomes conductive again. This makes the capacity 1
As the storage of electricity to 5 is started, the comparison voltage of the comparator 1 is sharply boosted. At the subsequent time t ₃₁ , the output of the comparator 37 changes from “H” to “L”, and accordingly, the reference voltage of the comparator 1 returns to a predetermined voltage value. At this time, the comparison voltage of the comparator 1 has already been boosted to a voltage value higher than the predetermined voltage value.

As described above, in the second embodiment,
Since the reference voltage of the comparator 1 is set to the ground voltage between the times t _{11 and} t ₃₁ , the comparison voltage generating means 7 in which the voltage value of the comparison voltage becomes lower than the voltage value of the reference voltage when the power supply voltage decreases, That is, when the power supply voltage has a normal voltage value, the voltage value of the comparison voltage is greater than or equal to the voltage value of the reference voltage, and the voltage value of the comparison voltage becomes lower than the voltage value of the reference voltage due to the decrease in the power supply voltage. In the above, even if the power supply voltage drops, the voltage value of the comparison voltage can be maintained at the voltage value of the reference voltage or more, and an erroneous traveling pulse is not output.

When the voltage induced from the Hall element 12 in the first embodiment is negative, that is, when the comparison voltage of the comparator 1 is higher than the reference voltage of the comparator 1, the Hall element 12 of the second embodiment is used. When the voltage induced by the voltage is positive, that is, when the comparison voltage of the comparator 1 is lower than the reference voltage of the comparator 1, even if the power supply voltage V decreases and the comparison voltage of the comparator 1 changes, Since the output does not change, the above-mentioned problem does not occur.

[0051]

As described above, according to the traveling sensor of the present invention, the following effects can be obtained. That is, as the voltage value of the comparison voltage changes due to the decrease in the power supply voltage, the magnitude relationship between the voltage value of the comparison voltage and the voltage value of the reference voltage changes, and when the output of the comparator 1 changes, the reference voltage The variable means steps up or down the reference voltage so as to maintain the magnitude relationship between the voltage value of the comparison voltage and the voltage value of the reference voltage before the power supply voltage drops, so that even if the comparison voltage changes due to a change in the power supply voltage. The voltage value of the reference voltage can be changed in accordance with the change of the comparison voltage, the output of the comparator 1 is maintained in the state before the power supply voltage is lowered, and erroneous running is performed even if the power supply voltage changes. Stops outputting pulses.

Further, the voltage detecting means detects that the power supply voltage is below a certain fixed value, and the boosting means uses the reference voltage as the comparison voltage when the power supply voltage is below a certain fixed value. Since the voltage is boosted to have the above voltage value, when the power supply voltage is a normal voltage value, the voltage value of the comparison voltage is less than or equal to the voltage value of the reference voltage. When the voltage value of the comparison voltage is higher than the voltage value of the reference voltage, the voltage value of the comparison voltage can be maintained below the voltage value of the reference voltage even if the power supply voltage is reduced, and an erroneous travel pulse Will not be output.

Further, the reference voltage generating means divides the power supply voltage by the resistors connected in series to generate the reference voltage, and the boosting means short-circuits the resistors connected in series to boost the reference voltage. Since the resistance is short-circuited and the reference voltage is boosted when the voltage becomes a certain value or less, the reference voltage can be boosted with a simple configuration.

Further, the boosting means boosts the reference voltage to the power supply voltage. Therefore, in the case where the voltage value of the comparison voltage becomes higher than the voltage value of the reference voltage due to the decrease of the power supply voltage, what is the voltage value of the comparison voltage? The output of the comparator does not change even when the value changes to, and an erroneous travel pulse is not output.

Further, the voltage detecting means detects that the power supply voltage is below a certain fixed value, and the step-down means uses the reference voltage as the comparison voltage when the power supply voltage is below a certain fixed value. Since the voltage is stepped down to have the following voltage value, when the power supply voltage is a normal voltage value, the voltage value of the comparison voltage has a relationship of the voltage value of the reference voltage or more, When the voltage value of the comparison voltage becomes lower than the voltage value of the reference voltage, the voltage value of the comparison voltage can be maintained at the voltage value of the reference voltage or more, and an erroneous traveling pulse is not output.

Further, the reference voltage generating means divides the power supply voltage by the resistors connected in series to generate the reference voltage,
The step-down means short-circuits the resistors connected in series to step down the reference voltage, so that when the power supply voltage drops below a certain value, the resistors are short-circuited to step down the reference voltage. The reference voltage can be stepped down with.

Further, since the step-down means steps down the reference voltage to the ground voltage, what is the voltage value of the comparison voltage when the voltage value of the comparison voltage becomes lower than the voltage value of the reference voltage due to the decrease of the power supply voltage? The output of the comparator does not change even when the value changes to, and an erroneous travel pulse is not output.

[Brief description of drawings]

FIG. 1 is a circuit configuration diagram of a first embodiment of the present invention.

FIG. 2 is a time chart showing the operation of the embodiment.

FIG. 3 is a circuit configuration diagram of a second embodiment of the present invention.

FIG. 4 is a time chart showing the operation of the embodiment.

FIG. 5 is a configuration diagram of a conventional device.

FIG. 6 is a time chart showing the operation of the conventional device.

[Explanation of symbols]

1,37 Comparator 2 Reference voltage generating means 3 Voltage detecting means 4 Boosting means 5 Step-down means 6 Reference voltage varying means 7 Reference voltage generating means 11 Magnet 12 Hall element 13,38,43 Transistor 14 Diode 15 Diode 16 Capacitance 16-19,21, 22,31-36,41,42 resistance 39 Zener diode 39a resistance

[Procedure amendment]

[Submission date] August 22, 1995

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0050

[Correction method] Change

[Correction content]

In the first embodiment described above, when the voltage induced from the Hall element 12 is negative, that is, when the comparison voltage of the comparator 1 is higher than the reference voltage of the comparator 1, and in the second embodiment, the Hall element is used. When the voltage induced by 12 is positive, that is, the comparator 1
When the comparison voltage is lower than the reference voltage of the comparator 1, the output from the comparator 1 does not change even if the power supply voltage V decreases and the comparison voltage of the comparator 1 changes, so the above-mentioned problem does not occur.

Claims (7)

[Claims] 1. A travel sensor which outputs a travel pulse based on a voltage induced from a hall element by a magnet rotating according to a vehicle speed, a reference voltage generating means for generating a reference voltage, and the hall element. A comparison voltage generating unit that generates a comparison voltage based on a voltage, a comparator that outputs a pulse signal from the reference voltage and the comparison voltage, and an output of the comparator when the power supply voltage for driving the traveling sensor is lowered. A traveling sensor, comprising: a reference voltage varying means for varying the voltage value of the reference voltage so as to maintain the output before the power supply voltage drops. 2. The reference voltage varying means has a relationship that the voltage value of the comparison voltage is equal to or less than the voltage value of the reference voltage when the power supply voltage is a normal voltage value, and the reference voltage varying means reduces the power supply voltage. When the voltage value of the comparison voltage is higher than the voltage value of the reference voltage, voltage detection means for detecting that the power supply voltage has become a certain fixed value or less, and the power supply voltage in the voltage detection means is a certain value or less The travel sensor according to claim 1, further comprising: a booster that boosts a reference voltage generated by the reference voltage generator so as to be higher than a voltage value of the comparison voltage when detected. 3. The reference voltage generating means is configured to divide a power supply voltage by a resistor connected in series to generate a reference voltage, and the boosting means short-circuits the resistance connected in series to reduce the reference voltage. The travel sensor according to claim 2, wherein the travel sensor is configured to increase the pressure. 4. The travel sensor according to claim 2, wherein the boosting means boosts the reference voltage to the power supply voltage. 5. The reference voltage varying means has a relationship in which the voltage value of the comparison voltage is equal to or higher than the voltage value of the reference voltage when the power supply voltage is a normal voltage value, and the reference voltage varying means reduces the power supply voltage. When the voltage value of the comparison voltage is lower than the voltage value of the reference voltage, voltage detection means for detecting that the power supply voltage has become a certain value or less, and the power supply voltage in the voltage detection means is a certain value or less 2. The travel sensor according to claim 1, further comprising: a step-down means for stepping down the reference voltage generated by the reference voltage generating means so as to become lower than the voltage value of the comparison voltage when detected. 6. The reference voltage generating means is configured to divide a power supply voltage by a resistor connected in series to generate a reference voltage, and the step-down means short-circuits the resistor connected in series to reduce the reference voltage. The travel sensor according to claim 5, wherein the travel sensor is configured to reduce the voltage. 7. The travel sensor according to claim 5, wherein the step-down means steps down the reference voltage to the ground voltage.