JP2001243597A - Vehicle detector and vehicle detection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicle detector having improved detection accuracy with which many parking spaces are managed by simple constitution. SOLUTION: This vehicle detector S is provided with loop coils L installed at the parking spaces (1) and (2) and a detection part 2. The detection part 2 is provided with coil oscillation means 11 provided corresponding to the loop coils L for constituting oscillation circuits 1a and 1b with the loop coils L and one discrimination means 3 for discriminating the presence/absence of a vehicle by pulse waves oscillated from the oscillation circuits 1a and 1b. The discrimination means 3 is provided with an AND circuit 30, a counter 31 and a microcomputer 32, The vehicle detector S compares the number of the pulse waves when the vehicles are not parked in the parking spaces (1) and (2) within fixed measurement time and the number of the pulse waves in the state where the vehicles are parked and the inductance of the loop coils L is changed and detects the presence/absence of the vehicle by the change amount.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for detecting the presence or absence of a vehicle using a loop coil, and more particularly, to a method for detecting the presence or absence of a vehicle based on a change amount of a pulse wave number of an oscillation circuit. The present invention relates to an apparatus for improving detection accuracy and managing a large number of parking spaces with a simple configuration.

[0002]

2. Description of the Related Art Conventionally, a vehicle detection device provided with a loop coil has been used for detecting the presence or absence of a vehicle in a parking lot. This vehicle detection device detects the presence or absence of a vehicle using a change in the characteristics of a loop coil when the vehicle is parked.

As the above-described vehicle detection device, for example,
2. Description of the Related Art There is known a transmission loop coil that generates a predetermined magnetic flux and a reception loop coil that is disposed at a predetermined distance from the loop coil.

According to this vehicle detection device, the reception loop coil receives the magnetic flux of the transmission loop coil and is guided to the reception loop coil by parking between the transmission loop coil and the reception loop coil. The presence or absence of the vehicle is detected by the sensing unit sensing that the electromotive force has been induced.

[0005]

However, in the above-described vehicle detection device, the transmission loop coil and the reception loop coil are arranged at a required distance, so that the magnetic flux of the transmission loop coil does not To some extent before being received by the loop coil. Therefore, the conventional one usually has an amplifier. However, the provision of the amplifier amplifies noise and the like not due to the magnetic flux of the transmission loop coil, which causes the sensing unit to malfunction, and the vehicle detection accuracy is not sufficient.

[0006] Further, in this vehicle detecting device, in order to accurately detect in which parking space the vehicle is parked, a sensing unit for sensing that an induced electromotive force is induced in the receiving loop coil. Are provided for each receiving loop coil. This sensor is made up of expensive components such as a sensor and a microcomputer, which complicates the configuration, and requires a great deal of cost to install the vehicle detection device.

[0007] Generally, an oscillation circuit of a type provided with a capacitor called Hartley or Colpitts is generally used. However, the capacitor has a dielectric between the electrodes, and has characteristics such that the distance between the electrodes changes and the characteristics of the dielectric change due to changes in climate or the like. For this reason, when an oscillation circuit having a capacitor is employed, the pulse wave is not stabilized, which causes a malfunction.

The inventor of the present invention has conducted experiments to determine whether oscillation can be performed without using a capacitor. The adoption of a so-called LR oscillation circuit using a loop coil and a resistor as an oscillation circuit allows the use of a capacitor which is an unstable element. It has been found that a stable pulse wave can be obtained without the need. The present invention has been completed based on this finding.

It is an object of the present invention to provide a vehicle detection device and a vehicle detection method which are less likely to malfunction due to noise or the like and have high vehicle detection accuracy. Another object of the present invention is to provide a vehicle detection device and a vehicle detection method capable of managing a large number of parking spaces with a simple configuration and reducing the installation cost. It is a further object of the present invention to provide a vehicle detection device and a vehicle detection method in which a stable pulse wave is obtained so that a malfunction does not easily occur and the detection accuracy of the vehicle is stabilized. Other objects of the present invention will become clear from the following description.

[0010]

Means of the present invention taken to achieve the above object are as follows. According to the first invention, a detection unit and a coil installed in a parking space are provided, and the detection unit is provided corresponding to the coil, and forms an oscillation circuit in combination with the coil. Coil oscillating means, and one determining means for determining the presence or absence of a vehicle with a pulse wave oscillated from the oscillating circuit,
The vehicle detection device, wherein the determination means includes an exclusive determination circuit, a measurement means, and a microcomputer having one or more functions selected from determination, calculation, storage, or processing functions. It is.

According to a second aspect of the present invention, there is provided a detecting unit and coils installed in a plurality of parking spaces, and the detecting units are provided corresponding to the coils, respectively. A plurality of coil oscillating means forming an oscillating circuit in combination with each corresponding coil, and at least one determining means for determining the presence or absence of a vehicle with a pulse wave oscillated from each of the oscillating circuits; The vehicle detection device is characterized in that the vehicle detection device includes an exclusive determination circuit, a measurement device, and a microcomputer having one or more functions selected from determination, calculation, storage, or processing functions. .

A third aspect of the present invention is the vehicle detection device according to the first or second aspect, wherein the oscillation circuit is a time constant circuit including a coil and a resistor.

According to a fourth aspect of the present invention, the LR circuit portion including a coil and a resistor is constituted by an analog circuit, and the other circuit is a digital circuit. 1 is a vehicle detection device according to the invention.

According to a fifth aspect of the present invention, there is provided a method for detecting the presence or absence of a vehicle in a parking space, wherein the pulse wave number when the vehicle is not parked within a predetermined measurement time, A vehicle detection method characterized by comparing the pulse wave number in a state where the inductance of the coil changes when the vehicle is parked, and detecting the presence or absence of a vehicle based on the amount of change.

According to a sixth aspect of the present invention, an oscillating circuit is constituted by a coil installed in a parking space and coil oscillating means provided corresponding to the coil, and the oscillating circuit constantly generates a pulse wave. The microcomputer is oscillating, and the microcomputer oscillates a measurement time pulse wave having a longer time from rise to fall than the pulse wave of the oscillation circuit,
A vehicle detection method characterized by detecting the presence or absence of a vehicle based on a change amount of a pulse wave number of the oscillation circuit included in a measurement time of the measurement time pulse wave.

According to a seventh aspect of the present invention, there is provided a method for managing a plurality of parking spaces, wherein each coil is provided in a plurality of parking spaces and provided corresponding to each of the coils. A plurality of oscillating circuits are constituted by the coil oscillating means, and each of the oscillating circuits constantly oscillates a pulse wave, and the microcomputer measures a longer time from rising to falling than the pulse wave of each of the oscillating circuits. A pulse wave is oscillated, and a predetermined pulse wave is assigned to each of the oscillation circuits by the assigning means, and each of the oscillation circuits is included in the assigned measurement time of the predetermined pulse wave. Detecting the presence or absence of a vehicle by the amount of change in the pulse wave number of
This is a vehicle detection method.

An eighth invention is the vehicle detection method according to the sixth or seventh invention, wherein the coil oscillating means includes a switching circuit, a hysteresis circuit, and a resistor.

(Operation) The vehicle detection device according to the present invention comprises:
Since no amplifier is provided, a malfunction due to amplification of noise or the like does not occur or is less likely to occur, and the vehicle detection accuracy is high.

The vehicle detection device according to the present invention employs a time constant circuit composed of a coil and a resistor as an oscillation circuit, and does not use a capacitor which is an unstable element. A stable pulse wave can be obtained. As a result, a malfunction is less likely to occur, and the detection accuracy of the vehicle can be stabilized.

According to the vehicle detection method of the present invention, the pulse wave number when the vehicle is not parked within a certain measurement time and the inductance of the coil when the vehicle is parked within the measurement time are changed. , The presence or absence of the vehicle can be detected based on the amount of change.

According to the vehicle detection method of the present invention, the presence or absence of a vehicle can be detected based on the amount of change in the pulse wave number of the oscillation circuit included in the measurement time of the measurement time pulse wave oscillated by the microcomputer.

If the measuring time of the measuring time pulse wave oscillated by the microcomputer is extended so that the number of pulse waves of the oscillation circuit included in the measuring time can be counted more, the numerical value of the differential pulse wave number becomes large. That is, the accuracy of vehicle detection can be improved.

The measurement time pulse wave oscillated from the microcomputer is assigned a predetermined pulse wave to each oscillation circuit by the assigning means, and the oscillation time of each oscillation circuit included in the measurement time of the assigned measurement time pulse wave. Since the presence / absence of the vehicle is detected based on the amount of change in the pulse wave, a plurality of oscillation circuits can be managed by one determination unit or the like. As a result, in the vehicle detection device and the vehicle detection method according to the present invention, the number of parts can be reduced and the structure can be simplified, and further, an amplifier is not required and the number of discrimination means and the like can be reduced, so that the installation cost can be reduced. can do.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in more detail with reference to the embodiments shown in the drawings. FIG. 1 is a block diagram for explaining the vehicle detection device. The vehicle detection device S has loop coils L, L and a detection unit 2. In this embodiment, the vehicle detection device is for two parking spaces, but the number of parking spaces is not limited.
Further, reference numerals indicating portions surrounded by a chain line in FIG.
Indicates a parking space, and one vehicle can be parked in each parking space.

The detecting section 2 includes coil oscillating means 11, 11
And determination means 3. Coil oscillating means 11,
Numeral 11 is connected to loop coils L, L buried in respective parking spaces where the vehicle is parked, and constitutes oscillation circuits 1a, 1b. Reference numeral 4 denotes an operating device that operates upon receiving a command based on the result determined by the determining means 3.

The discriminating means 3 comprises an AND circuit 30 which is an exclusive discriminating circuit for calculating the logical product of the pulse waves of the oscillation circuits 1a and 1b and the measurement time pulse wave generated by the microcomputer, and counts the calculated pulse wave number. And a microcomputer 32 that determines the presence or absence of a vehicle based on the counted pulse wave number.

FIG. 2 is a diagram for explaining the oscillation circuit shown in FIG. The coil oscillating means 11 includes a resistor R, a hysteresis circuit 111, and a switching circuit 112. For this reason, the oscillation circuits 1a and 1b
And a time constant circuit including the resistor R and an LR oscillation circuit.
The resistance R derives a time constant τ in cooperation with the transient of the loop coil L. The hysteresis circuit 111 operates the switching circuit 112 with a hysteresis time.

The switching circuit 112 allows a current having a high-level voltage value to flow or a current having a low-level voltage value to flow according to the current passed through the hysteresis circuit 111. Note that the “high level” voltage value indicates a predetermined voltage value (0.368E) or more, and the “low level” voltage value indicates a predetermined voltage value (0.368E).
Less than (including zero).

FIG. 3 is a diagram showing a state in which the voltage value changes with time in B of FIG. FIG. 4 is a waveform diagram obtained by shaping a pulse wave generated in the oscillation circuit. The principle of oscillation will be described with reference to FIGS. Note that, for convenience of description, A is described between the switching circuit 112 and the loop coil L in FIG. 2, B is shown between the loop coil L and the hysteresis circuit 111, and C is shown between the hysteresis circuit 111 and the switching circuit 112.

When a current having a high-level voltage value is supplied to A from the switching circuit 112, a waveform of the transient phenomenon shown in FIG. A current flows with such a voltage value. The waveform due to this transient phenomenon is obtained by the following formula. E (t) = L (d / dt) I · sin ωt E Voltage value [V] I Current value [A] t Time [s] ω Each frequency [rad / s]

When the voltage value of the current flowing through the loop coil L falls from a high level state to a predetermined voltage value (0.368E) over a required time due to a transient phenomenon, the hysteresis circuit 111 switches the switching circuit with a hysteresis time. Operate 112. As described above, the hysteresis circuit 111 has a hysteresis time and performs a logic operation, so that the pulse wave can be shaped and the switching circuit 112 can operate stably.

The configuration of the hysteresis circuit 111 includes, for example, a configuration in which two inverters having hysteresis are connected in series. However, the configuration of the hysteresis circuit 111 is not limited to this.

When a current flows through the loop coil L, the high-level voltage value is changed to the predetermined voltage value (0.368).
The time of falling to E) is represented by a time constant τ (see FIG. 3). The time constant τ is obtained by the following formula. τ = L / R τ Time constant L Inductance [H] R Impedance [Ω] The pulse width from the rise of the pulse wave to the fall of the pulse wave is formed by the time represented by the time constant τ (see FIG. 4). ).

The switching circuit 112 causes a current having a high-level voltage value to flow through A or a current having a low-level voltage value to flow through A according to the current of C passing through the hysteresis circuit 111.

FIG. 5 is a waveform diagram for explaining the principle of detecting a vehicle by a pulse wave. (a) is a pulse wave of the oscillation circuit when the vehicle is not parked, (b) is a pulse wave of the oscillation circuit when the vehicle is parked, (c)
Is a pulse wave having a constant width from rising to falling, and this pulse wave forms a measurement time. (d) is a pulse wave of the oscillation circuit when the vehicle is not parked,
The pulse wave in the state where the logical product of the pulse wave of the measurement time was calculated, and (e) the pulse in the state where the logical product of the pulse wave of the oscillation circuit in the parked state of the vehicle and the pulse wave of the measurement time was calculated. Shows waves.

The principle of detection by the vehicle detection device will be described with reference to FIGS. First, briefly, the vehicle detection device S includes a pulse wave number when the vehicle is not parked in each parking space and a loop coil L when the vehicle is parked within a measurement time set in advance by the microcomputer 32. Is compared with the pulse wave number in a state where the inductance changes, and the presence or absence of the vehicle is detected based on the amount of change.

This will be described in more detail. [State where the vehicle is not parked] The pulse wave when the vehicle is not parked in the parking space is referred to as “measured pulse wave A” (see FIG. 5A). In addition, when it is necessary to particularly explain, the measurement pulse wave A in the oscillation circuit 1a is referred to as “measurement pulse wave Aa”, and the measurement pulse wave A in the oscillation circuit 1b is referred to as “measurement pulse wave Ab”.

The oscillating circuits 1a and 1b are each composed of an oscillating circuit 1a,
The measurement pulse waves Aa and Ab unique to 1b are oscillated, and the measurement pulse waves Aa and Ab are sent to the AND circuit. The measurement pulse wave A is not affected by the vehicle and forms a substantially uniform pulse wave shape. Note that the oscillation circuits 1a, 1
b oscillates constantly so that a continuous pulse wave is output during the operation of the vehicle detection device S.

The microcomputer 32 generates a measurement time pulse wave (see FIG. 5C), and the measurement time pulse wave is sent to the AND circuit. The measurement time pulse wave has a longer time from rising to falling than the measurement pulse wave A output from the oscillation circuits 1a and 1b.

The logical product of the measured pulse wave A and the pulse wave measured by the microcomputer 32 is calculated by the AND circuit 3.
Calculate with 0. In the measurement time pulse, the "A" portion in the measurement time pulse is assigned to the measurement pulse wave Aa by the assigning means, and the "A" portion in the measurement time pulse wave and the measurement pulse wave Aa are assigned by the AND circuit. And is taken. Also, “A” during the measurement time pulse
Is assigned to the measurement pulse wave Ab, and the AND circuit calculates the logical product of the "a" part in the measurement time pulse wave and the measurement pulse wave Ab by the AND circuit.

The pulse wave for which the AND operation of the measurement pulse wave A and the measurement time pulse wave is calculated by the AND circuit is referred to as "logical product pulse wave A" (see FIG. 5D). When it is necessary to particularly explain, the AND pulse wave A in the oscillation circuit 1a is referred to as “AND pulse wave Aa”, and the AND pulse wave A in the oscillation circuit 1b is referred to as “AND pulse wave Ab”. Called. In other words, for the measurement time pulse wave, an AND pulse wave Aa with the measurement pulse wave Aa of the oscillation circuit 1a is calculated in the portion "a" in FIG. In the part "a", a logical product pulse wave Ab with the measured pulse wave Ab of the oscillation circuit 1b is calculated.

The counter 31 counts the pulse wave number of each of the AND pulse waves Aa and Ab by the oscillation circuits 1a and 1b. The information on the pulse wave number is sent to the microcomputer 32.

The microcomputer 32 compares the difference between the stored reference value and the sent pulse wave number, and if the difference pulse wave number does not exceed a predetermined value. A determination value is set to determine that there is no vehicle, and to determine that there is a vehicle if it exceeds. As the reference value, a detection value of a logical product pulse wave in a state where there is no vehicle at the time of initial installation is set.

When the information on the pulse wave number is sent, the microcomputer 32 compares the difference between the pulse wave number and the reference value, and determines whether or not the difference pulse wave number exceeds the above-described determination value.

In the case where there are a plurality of oscillation circuits and a plurality of measurement pulse waves as described above, it is determined which of the oscillation circuits each logical product pulse wave is the logical product of the measurement pulse wave output from. If recognized, the combination order of the measurement time pulse wave and the measurement pulse wave is not particularly limited.
The measurement time by the measurement time pulse wave can be set arbitrarily.

[State in which the vehicle is parked] When the vehicle is parked in a parking space or the like, the inductance of the loop coil L changes due to the influence of the vehicle. Oscillation circuit 1 provided in the parked parking space
From a and 1b, pulse waves different in shape from the measured pulse wave before parking are output. The pulse wave when the vehicle is parked in this parking space is referred to as “measurement pulse wave B” (see FIG. 5B). In addition, when it is necessary to particularly explain, the measurement pulse wave B in the oscillation circuit 1a is referred to as “measurement pulse wave Ba”, and the measurement pulse wave B in the oscillation circuit 1b is referred to as “measurement pulse wave Bb”.

Hereinafter, a case where a vehicle is parked in a parking space will be described as an example. The logical product of the measurement pulse wave Ba of the oscillation circuit 1a is calculated by the AND circuit 30 using the measurement time pulse wave. The pulse wave obtained by calculating the logical product of the measured pulse wave Ba and the above-described measured time pulse wave by the AND circuit 30 is referred to as “logical product pulse wave B” (FIG. 5E).
reference). When it is necessary to particularly explain, the AND pulse wave B in the oscillation circuit 1a is referred to as “AND pulse wave Ba”, and the AND pulse wave B in the oscillation circuit 1b is referred to as “AND pulse wave Bb”. Called.

AND pulse wave Ba from the oscillation circuit 1a
Is counted by the counter 31 in the same manner as the AND pulse wave Aa, and information on the pulse wave number is sent to the microcomputer 32. Since the time constant τ of the logical product pulse wave Ba sent to the microcomputer 32 decreases due to the decrease in the inductance, the pulse wave number of the logical product pulse wave Ba is smaller than that of the logical product pulse wave Aa. Many are detected.

The microcomputer 32 compares the difference between the pulse number of the AND pulse Ba and the reference value, and determines whether the difference pulse number does not exceed the determination value. As described above, the pulse number of the AND pulse Ba is detected to be larger than the pulse number of the AND pulse Aa, so that the difference pulse number exceeds the determination value, and as a result, the microcomputer 32
Determines that there is a vehicle.

The microcomputer 32 that has determined that the vehicle is present sends a command to the operating device to operate the operating device 4. In the present embodiment, the operating device is not specifically described with a specific example, but as the operating device, for example,
A device that transmits that the vehicle has been parked to the outside (lighting device, sound generation device, etc.), a device that prevents the vehicle from leaving or entering the vehicle (a lift plate that contacts the chassis of the vehicle, a bar that blocks the exit of the parking lot, Pole, shutter, etc.).

When the vehicle leaves the parked state, the state returns to the original state even if the inductance of the loop coil L changes.
a is output. As a result, the pulse wave number of the AND pulse wave Aa is compared with the pulse wave number of the reference value, and the difference pulse wave number does not exceed the determination value. Therefore, the microcomputer 32 determines again that there is no vehicle. I do.

In this embodiment, the vehicle detection device S
Although the example in which two parking spaces can be managed has been exemplified, the vehicle detection device S is not limited to this, and if at least one oscillation circuit is provided in one parking space, one vehicle detection device S is provided. It is also possible to manage only or more than two parking spaces.

Since the vehicle detection device S according to the present embodiment does not include an amplifier, it does not cause or is unlikely to malfunction due to amplification of noise and the like, and has high reliability in vehicle detection accuracy. .

The vehicle detection device S employs a so-called LR oscillation circuit in which the oscillation circuits 1a and 1b each include a loop coil L and a resistor R, and does not use a capacitor which is an unstable element. A more stable pulse wave can be obtained. As a result, a malfunction is less likely to occur, and the detection accuracy of the vehicle can be stabilized.

Further, the vehicle detection device S increases the measurement time of the measurement time pulse wave by the microcomputer 32,
If the number of pulse waves of the AND pulse wave A and the AND pulse wave B included in the measurement time can be counted more, the numerical value of the difference pulse wave number increases, and the accuracy of vehicle detection can be improved.

As the measurement time pulse wave, a predetermined measurement time pulse wave is allocated to each of the oscillation circuits 1a and 1b by the allocating means, and each of the oscillation circuits 1a and 1a included in the measurement time of the allocated measurement time pulse wave. 1b, the presence or absence of the vehicle is detected based on the amount of change in the pulse wave of 1b.
b can be managed. Thereby, the vehicle detection device S
Since the number of components can be reduced and the structure can be simplified, the amplifier is not required, and the number of determination means and the like can be reduced, so that the installation cost can be reduced.

Note that a small change in the outside air such as temperature or humidity may cause a slight change in the inductance of the loop coil L. Since such a fluctuation of the pulse wave can be kept within the range of the judgment value by the microcomputer 32, the fluctuation hardly causes the malfunction. However, a large change in the outside air, such as a season, affects the inductance of the loop coil L and adversely affects the detection accuracy.

Therefore, the following means are taken as compensation means. For example, when it is determined that the vehicle is in the normal state without a car, the information of the pulse wave number is sampled a predetermined number of times set in the microcomputer 32 in advance. The average value of the sampled pulse wave information is calculated. Then, the reference value stored in the microcomputer 32 is rewritten with the average value. Thus, the reference value stored in the microcomputer 32 is updated. When a vehicle is detected, the sampling for obtaining the average value of the pulse wave numbers is stopped.

Therefore, even if the inductance of the loop coil L changes due to a large change in the outside air such as temperature and humidity, the vehicle detection device S can store the information stored in the reference value at this time. Since it is rewritten to change due to factors such as humidity and corrected each time, even when a large change occurs in the outside air,
Detection can be performed in a highly accurate state, and the reliability of vehicle detection is higher.

The terms and expressions used in the present specification are merely illustrative, not restrictive, and terms and equivalents of the features described in this specification and some of them are used. There is no intention to exclude expression. It goes without saying that various modifications are possible within the scope of the technical idea of the present invention.

[0060]

The present invention has the above configuration and has the following effects. (A) Since the vehicle detection device according to the present invention does not include an amplifier, it does not cause or is unlikely to malfunction due to amplification of noise or the like, and has high reliability in vehicle detection accuracy.

(B) In the vehicle detection device according to the present invention, the oscillation circuit employs a time constant circuit including a coil and a resistor, and does not use a capacitor which is an unstable element.
A more stable pulse wave can be obtained than that of the type having a capacitor. As a result, a malfunction is less likely to occur, and the detection accuracy of the vehicle can be stabilized.

(C) According to the vehicle detection method according to the present invention, the pulse wave number when the vehicle is not parked within a certain measurement time and the inductance of the coil when the vehicle is parked within the measurement time vary. The presence or absence of the vehicle can be detected based on the amount of change by comparing the pulse wave number in the state where the pulse wave has occurred.

(D) According to the vehicle detection method of the present invention, the presence or absence of a vehicle can be detected by the amount of change in the pulse wave number of the oscillation circuit included in the measurement time of the measurement time pulse wave oscillated by the microcomputer. Also, if the measurement time of the measurement time pulse wave oscillated by the microcomputer is lengthened so that the number of pulse waves of the oscillation circuit included in this measurement time can be counted more, the numerical value of the difference pulse wave number also increases and the vehicle The accuracy of detection can be improved.

(E) A predetermined pulse wave is assigned to each oscillation circuit by the assigning means as the measurement time pulse wave oscillated from the microcomputer, and each of the measurement time pulse waves included in the measurement time of the assigned measurement time pulse wave is assigned. Since the presence / absence of the vehicle is detected based on the amount of change in the pulse wave of the oscillation circuit, a plurality of oscillation circuits can be managed by one determination unit or the like. As a result, in the vehicle detection device and the vehicle detection method according to the present invention, the number of parts can be reduced and the structure can be simplified, and further, an amplifier is not required and the number of discrimination means and the like can be reduced, so that the installation cost can be reduced. can do.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a vehicle detection device.

FIG. 2 is a diagram illustrating the oscillation circuit illustrated in FIG. 1;

FIG. 3 is a diagram showing a state in which a voltage value changes with time in B of FIG. 2;

FIG. 4 is a waveform diagram in which a pulse wave generated by an oscillation circuit is shaped.

FIG. 5 is a waveform diagram for explaining the principle of detecting a vehicle by a pulse wave.

[Explanation of symbols]

 S Vehicle detecting device L Loop coil R Resistance 1a, 1b Oscillation circuit 11 Coil oscillating means 111 Hysteresis circuit 112 Switching circuit 2 Detecting unit 3 Discriminating means 30 AND circuit 31 Counter 32 Microcomputer 4 Operating device

Claims (8)

[Claims] 1. A coil oscillating means, comprising: a detecting unit; and a coil installed in a parking space, wherein the detecting unit is provided corresponding to the coil, and a coil oscillating means which constitutes an oscillating circuit in combination with the coil. And one discriminating means for discriminating the presence or absence of the vehicle with a pulse wave oscillated from the oscillation circuit. The discriminating means includes an exclusive discriminating circuit, a measuring means, and a judging, calculating, storing or processing function. A vehicle detection device comprising a microcomputer having one or more functions selected from the group consisting of: 2. A vehicle, comprising: a detection unit; and coils installed in a plurality of parking spaces. The detection unit is provided corresponding to each of the coils, and is combined with each of the corresponding coils. A plurality of coil oscillating means constituting an oscillating circuit, and at least one discriminating means for discriminating the presence or absence of a vehicle with a pulse wave oscillated from each of the oscillating circuits. And a measuring means, and a microcomputer having one or more functions selected from the judging, calculating, storing or processing functions. 3. The vehicle detection device according to claim 1, wherein the oscillation circuit is a time constant circuit including a coil and a resistor. 4. The vehicle detection device according to claim 1, wherein an LR circuit portion including a coil and a resistor is configured by an analog circuit, and another circuit is a digital circuit. 5. A method for detecting the presence or absence of a vehicle in a parking space, comprising: a pulse wave number when the vehicle is not parked within a predetermined measurement time; and a coil when the vehicle is parked within the measurement time. A method for detecting a vehicle, comprising: comparing a pulse wave number in a state in which the inductance of the vehicle changes with the number of pulses; 6. An oscillation circuit comprising a coil installed in a parking space and coil oscillation means provided corresponding to the coil, wherein the oscillation circuit constantly oscillates a pulse wave. Oscillates a measurement time pulse wave having a longer time from rise to fall than the pulse wave of the oscillation circuit, and the vehicle is determined by a change amount of the pulse wave number of the oscillation circuit included in the measurement time of the measurement time pulse wave. A method for detecting a vehicle, comprising detecting the presence or absence of a vehicle. 7. A method for managing a plurality of parking spaces, comprising: a plurality of coils installed in a plurality of parking spaces; and a plurality of coil oscillating means provided in correspondence with the respective coils. Oscillator circuits are configured, each of the above oscillator circuits constantly oscillates a pulse wave, and the microcomputer oscillates a measurement time pulse wave having a longer time from rise to fall than the pulse wave of each of the above oscillator circuits. A predetermined pulse wave is assigned to each of the oscillation circuits by the assigning means, and the measurement time pulse wave is determined by an amount of change in the pulse wave number of each of the oscillation circuits included in the assigned measurement time of the predetermined pulse wave. A vehicle detection method for detecting the presence or absence of a vehicle. 8. The vehicle detection method according to claim 6, wherein the coil oscillation means includes a switching circuit, a hysteresis circuit, and a resistor.