JP3622723B2 - Vehicle theft prevention method, vehicle theft prevention device, and vehicle theft prevention system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicle theft prevention method, a vehicle theft prevention device, and a vehicle theft prevention system suitable for a vehicle such as an automobile.
[0002]
[Prior art]
Conventionally, various vehicle antitheft devices have been developed to prevent theft of automobiles. There are various types of these theft devices depending on the price. An inexpensive type detects a vehicle abnormality caused by theft with a simple sensor, and performs a siren ringing or flashing flasher for intimidation. The expensive type is equipped with various sensors (infrared, ultrasonic, radio wave, vibration, shock, inclination, etc.) corresponding to the phenomenon that can be detected when the vehicle is stolen. The system is equipped with a function to notify the remote user of the determination result.
[0003]
In the inexpensive type, since only simple detection for theft prevention is performed by a simple sensor, there are many cases where the antitheft function is easily canceled by a familiar criminal.
[0004]
On the other hand, since the expensive type includes various sensors and performs various types of detection using them, the anti-theft function is enhanced as compared with the inexpensive type.
[0005]
[Problems to be solved by the invention]
However, although the above-mentioned conventional expensive type vehicle antitheft device has a relatively high antitheft function as described above, each phenomenon that is expected to appear during vehicle theft is detected by each individual sensor. Therefore, a large number of sensors are necessary. For example, the intrusion into the vehicle by the criminal is detected by a vibration sensor, and the inclination of the vehicle due to the wrecker movement or the like is individually detected by an inclination sensor or the like.
[0006]
That is, in the expensive type, in order to increase the anti-theft function, the more the abnormality detection items are increased, the more the components of the device are increased, resulting in an increase in cost and the space capacity occupied by the entire device is increased. It will be. Therefore, as the number of components and abnormality detection functions increase, it becomes an expensive system and the burden on the user at the time of introduction increases, which is a factor that hinders the spread of vehicle antitheft devices.
[0007]
Moreover, in the vehicle antitheft device, the size and shape of the entire device are important factors from the standpoints of installation property and concealment on the vehicle due to the nature of the product. In this regard, when the spatial capacity occupied by the entire device increases as described above, the mounting position of the vehicle antitheft device can be easily identified, or it can be easily removed. In addition, the commercial value will be significantly reduced.
[0008]
Therefore, the present invention provides a vehicle theft prevention method, a vehicle theft prevention device, and a vehicle theft prevention system capable of preventing a vehicle theft with a small and low cost configuration with a small number of sensors while maintaining a high vehicle theft prevention function. The purpose is to provide.
[0009]
[Means for Solving the Problems]
In order to solve the above-described problem, a vehicle theft prevention method according to the present invention includes an acceleration detection step for detecting the acceleration of the vehicle, and whether or not there is an abnormality associated with theft of the vehicle based on the acceleration detected by the acceleration detection step. And a determination step for determining whether or not.
[0010]
Further, the vehicle antitheft device of the present invention includes an acceleration detecting unit that detects the acceleration of the vehicle, and a determining unit that determines whether there is an abnormality associated with the theft of the vehicle based on the acceleration detected by the acceleration detecting unit. It is characterized by having.
[0011]
According to said structure, the presence or absence of abnormality accompanying theft of a vehicle is determined based on the acceleration of a vehicle. The abnormality associated with theft of the vehicle is, for example, a change in the state of the vehicle that occurs with respect to the normal parking state because the vehicle is being stolen from the normal parking state or has been stolen. .
[0012]
In this case, a plurality of states in the vehicle can be detected from the output of the acceleration sensor that detects the acceleration of the vehicle. For example, from the output of the acceleration sensor that detects the longitudinal acceleration of the vehicle, the vehicle is moving, that is, the vehicle is being stolen and moved, and the vehicle is tilted, that is, the vehicle is The state where the wrecker is moved can be detected. The state in which the vehicle is inclined appears as a vehicle longitudinal component of gravitational acceleration.
[0013]
Therefore, the number of sensors necessary for the vehicle antitheft operation can be reduced while maintaining a high antitheft function. As a result, the vehicle anti-theft device having a high anti-theft function can be made compact and low-cost.
[0014]
In the vehicle theft prevention method, at least the longitudinal acceleration of the vehicle is detected in the acceleration detection step, and the vehicle is moving in the determination step, which is abnormal based on the longitudinal acceleration of the vehicle. It is good also as a structure which determines the presence or absence of this, and the presence or absence of the state which the vehicle inclines.
[0015]
Further, in the above vehicle antitheft device, the acceleration detecting means detects at least the longitudinal acceleration of the vehicle, and the determining means is abnormal based on the longitudinal acceleration of the vehicle. It is good also as a structure which determines the presence or absence of the state which is moving, and the presence or absence of the state which the vehicle inclines.
[0016]
According to the above configuration, at least the longitudinal acceleration of the vehicle is detected, and based on this acceleration, whether the vehicle is moving and whether the vehicle is tilted, that is, the vehicle is stolen. It is determined whether or not the vehicle is moving and whether or not the vehicle is moving towed.
[0017]
Therefore, by using one acceleration sensor, it is possible to detect at least two types of abnormality associated with theft of the vehicle. As a result, the number of sensors required for the vehicle anti-theft operation can be surely reduced, and the vehicle anti-theft device having a high anti-theft function can be reliably made small and low-cost.
[0018]
In the vehicle anti-theft method, the acceleration detecting step detects accelerations in a plurality of axial directions, and the determining step is based on the accelerations in the plurality of axial directions. It is good also as a structure which determines the presence or absence of abnormality.
[0019]
Further, in the above vehicle antitheft device, the acceleration detecting means detects accelerations in a plurality of axial directions, and the determining means generates accelerations in the respective axial directions based on the accelerations in the plurality of axial directions. The presence or absence of each abnormality
It is good also as a structure.
[0020]
According to the above configuration, accelerations in a plurality of axial directions are detected, and the presence / absence of each abnormality that causes the acceleration in each of the axial directions is determined. In this case, one or more types of states can be detected for each vehicle from the accelerations in a plurality of axial directions. For example, from the output of the acceleration sensor that detects the longitudinal acceleration of the vehicle, the vehicle is moving, that is, the vehicle is being stolen and moved, and the vehicle is tilted, that is, the vehicle is The state where the wrecker is moved can be detected. For example, an acceleration sensor that detects acceleration in the width direction of the vehicle can detect a state in which the vehicle is swaying in the vehicle width direction (side-rolling state), that is, a state in which an intruder has entered the vehicle, for example.
[0021]
Accordingly, the number of sensors required for the vehicle anti-theft operation can be reduced while maintaining a high anti-theft function, and the vehicle anti-theft device having a high anti-theft function is made small and low-cost configuration. Can do.
[0022]
In the vehicle theft prevention method, at least acceleration in the longitudinal direction of the vehicle and acceleration in the width direction of the vehicle are detected in the acceleration detection step, and in the determination step, an abnormality occurs based on the acceleration in the longitudinal direction of the vehicle. Determines whether the vehicle is moving and whether the vehicle is tilted, and determines whether there is an abnormal vehicle swinging in the width direction based on the acceleration in the width direction of the vehicle It is good also as composition to do.
[0023]
In the above vehicle antitheft device, the acceleration detecting means detects at least the longitudinal acceleration of the vehicle and the acceleration in the width direction of the vehicle, and the determining means is based on the longitudinal acceleration of the vehicle. It is determined whether the vehicle is moving and whether the vehicle is moving and whether the vehicle is tilted. Based on the acceleration in the width direction of the vehicle, the vehicle is shaking in the width direction. It is good also as a structure which determines the presence or absence of a state.
[0024]
According to the above configuration, at least acceleration in the front-rear direction of the vehicle and acceleration in the width direction of the vehicle are detected, and based on the acceleration, the presence or absence of a state in which the vehicle is moving and the presence or absence of a state in which the vehicle is tilted, And whether or not the vehicle is swinging in the vehicle width direction, that is, whether or not the vehicle is stolen and moved, whether or not the vehicle is towed, and for example, an intruder has entered the vehicle The presence or absence of is determined.
[0025]
Therefore, by using a small number of acceleration sensors, for example, one biaxial acceleration sensor, at least three types of abnormalities associated with theft of the vehicle can be detected. As a result, the number of sensors required for the vehicle anti-theft operation can be reduced, and the vehicle anti-theft device having a high anti-theft function can be reliably made small and low-cost.
[0026]
The vehicle theft prevention method may further include an output control step of operating an alarm device attached to the vehicle when the determination step determines that there is an abnormality.
[0027]
The vehicle antitheft device may further include output control means for operating an alarm device attached to the vehicle when the determination means determines that there is an abnormality.
[0028]
According to the above configuration, the alarm device is activated when an abnormality of the vehicle, that is, a theft state is detected, so that it is possible to appropriately prevent theft.
[0029]
The vehicle anti-theft system according to the present embodiment includes the above-described vehicle anti-theft device and a management device, and when the vehicle anti-theft device determines that there is an abnormality, the abnormality occurrence information indicating that fact. Is transmitted to the management device, and the management device transmits information indicating the occurrence of abnormality in the vehicle to the user terminal device after receiving the abnormality occurrence information.
[0030]
According to the above configuration, when a vehicle abnormality, that is, a theft state is detected in the vehicle antitheft device, the information is transmitted to the user terminal device via the management device. Therefore, the user can quickly respond to the vehicle theft.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described below with reference to FIGS.
The vehicle antitheft system including the vehicle antitheft device of the present embodiment has the configuration shown in FIG. As shown in the figure, the vehicle antitheft system includes a vehicle antitheft device 1, a management device 2, a mobile terminal device 3, and a remote control transmission unit (hereinafter abbreviated as a remote control transmission unit) 4.
[0032]
The vehicle antitheft device 1 is mounted on a vehicle 11 and can be operated in a normal mode and a warning mode. The normal mode is a mode that is set when the user uses the vehicle 11. In this normal mode, even if the vehicle 11 moves from a stationary state, for example, it is not detected as abnormal. On the other hand, the warning mode is a mode for detecting an abnormality of the vehicle 11, and the vehicle anti-theft function works when this mode is set. In this alert mode, when the vehicle 11 moves from a stationary state, it is detected as an abnormality.
[0033]
The management device 2 centrally manages information received from each vehicle antitheft device 1 mounted on the plurality of vehicles 11. That is, the management device 2 centrally manages the operation mode of the vehicle anti-theft device 1, the abnormal state determined by the vehicle anti-theft device 1, instructions from the user, etc., and automatically performs the operation according to those situations. To do.
[0034]
The mobile terminal device 3 includes, for example, a mobile phone or other information terminal device possessed by the user 12 and having an e-mail transmission / reception function. The mobile terminal device 3 has functions as a monitor device and an operation device.
[0035]
When functioning as a monitor device, the mobile terminal device 3 confirms the operation mode of the vehicle antitheft device 1 and the content of the abnormality notification determined by the vehicle antitheft device 1 with respect to the management device 2. Can do. In this case, when the management device 2 receives the confirmation request from the mobile terminal device 3, it responds to the confirmation request, and the response result is displayed on a display unit (not shown) of the mobile terminal device 3.
[0036]
When functioning as an operation device, the mobile terminal device 3 instructs the management device 2 to change the operation mode of the vehicle antitheft device 1 and an external output device connected to the vehicle antitheft device 1 by wire or wirelessly. The operation instruction can be performed. In this case, when the management device 2 receives the above instruction from the mobile terminal device 3, the management device 2 issues an operation mode change instruction to the vehicle antitheft device 1 and an operation instruction to the external output device. Based on this instruction, the operation mode is changed in the vehicle antitheft device 1 and the operation is started in the external output device.
[0037]
The remote control transmission unit 4 is provided corresponding to each vehicle antitheft device 1, and remotely controls the operation of the vehicle antitheft device 1. This remote control transmission unit 4 is owned by the user 12 of the vehicle 11 and instructs the vehicle antitheft device 1 to change the unique ID set in each remote control transmission unit 4 and the operation mode of the vehicle antitheft device 1. Command signal can be transmitted. When receiving this command signal, the vehicle antitheft device 1 changes the operation mode in accordance with the instruction.
[0038]
As shown in FIG. 1, the vehicle antitheft device 1 includes a remote control reception unit (hereinafter abbreviated as a remote control reception unit) 21, an acceleration sensor 22 (acceleration detection means), a control device 23, a transmission / reception unit (communication means). ) 24 and an input / output device 25. For example, an electronic buzzer 26 as an external device is connected to the input / output device 25.
[0039]
The remote control receiving unit 21 receives the command signal transmitted from the remote control transmission unit 4 and identifies the ID number included in the command signal. As a result, if it is a command signal addressed to the own device, the control device 23 is notified of a mode change command indicated by the command signal.
[0040]
In the present embodiment, the acceleration sensor 22 is installed, for example, horizontally with the ground, and detects accelerations in two axial directions, ie, the X-axis direction and the Y-axis direction, which are horizontal directions. The Y-axis direction is set in the front-rear direction of the vehicle 11, and the X-axis direction is set in the width direction of the vehicle 11.
[0041]
Further, the acceleration sensor 22 is constituted by, for example, an ultra-small package in which the function of an accelerometer is integrated on an IC, and in addition to an analog voltage output, a digital output having a duty cycle proportional to the acceleration is possible. The output can be directly measured by a microcomputer counter. Therefore, the acceleration sensor 22 contributes to downsizing of the vehicle antitheft device 1. As such an acceleration sensor 22, for example, a biaxial acceleration sensor (product number: ADXL202E) manufactured by Analog Devices, Inc. can be used.
[0042]
The control device 23 is configured by a computer and includes a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory). A program for controlling the CPU is written in the ROM. The control device 23 includes a mode switching unit 31, a calculation unit 32, a determination unit (determination unit) 33, and an output control unit (output control unit) 34 as functional units.
[0043]
The mode switching unit 31 alternately switches the operation mode between the normal mode and the warning mode every time the mode change notification is received from the remote control receiving unit 21. Further, in order to notify the user 12 of the mode set by this switching, for example, an electronic buzzer 26 as an external output device is sounded via the input / output unit 11, and the mode change is made to the management device 2 via the transmission / reception unit 24. Notify 吏.
[0044]
The calculation unit 32 periodically reads the output from the acceleration sensor 22 to obtain the horizontal acceleration (biaxial direction) of the vehicle 2 and various data based on the acceleration by calculation.
[0045]
The determination unit 33 determines whether there is an abnormality in the state of the vehicle 11 based on the calculation result in the calculation unit 32.
[0046]
When the determination unit 33 determines that there is an abnormality, the output control unit 34 notifies the management device 2 to that effect via the transmission / reception unit 24, and also via the control unit 23 to an external output device such as an electronic buzzer 26. Is activated.
[0047]
As shown in FIG. 3, the management device 2 shown in FIG. 2 includes a transmission / reception unit 41 that transmits / receives information to / from the mobile terminal device 3 and the vehicle antitheft device 1, a management unit 42 that manages the entire system, and stores various information. A database 43 is provided.
[0048]
When the management unit 42 includes a computer and receives an operation mode change notification or abnormality notification from the vehicle antitheft device 1 via the transmission / reception unit 41, the management unit 42 stores information indicating the situation in the database 43. Further, an e-mail corresponding to the above situation is created or selected from those prepared in advance, and notified to a mail address designated in advance by the user 12.
[0049]
When the management unit 42 receives an operation mode change instruction or an operation instruction for an external output device from the mobile terminal device 3 of the user 12, the management unit 42 stores the instruction content in the database 43, and the vehicle theft prevention device 1. Send their instructions.
[0050]
In the above configuration, when receiving an instruction to change the operation mode (normal mode, warning mode) from the user 12, the vehicle antitheft device 1 changes the operation mode according to the instruction of the user 12, while operating the external output device. When the instruction is received, a device (external output device) connected to the outside via the input / output unit 11 is operated. Each of the above instructions is received directly from the remote control transmission unit 4 or from the mobile terminal device 3 via the management device 2. In addition, as an apparatus attached to the exterior of the vehicle 11 among external output apparatuses, a flasher, a siren, etc. other than the said electronic buzzer 26 can be used as a threatening means to a vehicle theft person.
[0051]
In addition, the vehicle antitheft device 1 performs an abnormality detection operation for the vehicle 11. This abnormality detection operation detects the presence or absence of a state in which the vehicle 11 is stolen, and further detects the presence or absence of an impact from an object such as another vehicle on the vehicle 11. Specifically, the presence / absence of the vehicle 11 being tilted, the presence / absence of movement from a stationary state, the presence / absence of an impact applied to the vehicle 11 and the like are detected, and the presence / absence of an abnormality in the vehicle 11 is determined based on the detection.
[0052]
Here, the principle of abnormality detection of the vehicle 11 based on the output of the acceleration sensor 22 in the vehicle antitheft device 1 will be described based on FIG. The figure shows various movements (behavior) of the vehicle 11 and acceleration caused by them. First, the cause of the acceleration will be described.
[0053]
(1) Acceleration generated when the vehicle moves
As shown in FIG. 4A, when the vehicle 11 moves in the traveling direction, acceleration and deceleration always occur in the traveling direction (Y-axis direction), and the acceleration accompanying the acceleration and deceleration is measured by the acceleration sensor 22. . Although not shown in the figure, in normal traveling, it is impossible to travel only in a straight line, and since steering is always performed left and right, acceleration in the lateral direction (X-axis direction) is also measured. In the case of general traveling, the acceleration obtained here varies in a short time.
[0054]
(2) Horizontal component of gravitational acceleration that occurs when the vehicle is tilted
As shown in FIG. 4B, when the vehicle 11 is inclined at some angle with respect to the ground surface (horizontal direction), the horizontal component of the gravitational acceleration is detected. Therefore, in this case, a constant acceleration is detected even when the vehicle 11 is stationary. This state corresponds to the case where the vehicle 11 is parked on an inclined land or the vehicle 11 is lifted by a tow truck or the like. The acceleration in this case fluctuates when the vehicle 11 is leaning and becomes constant and does not fluctuate when the vehicle 11 stops.
[0055]
(3) Vehicle shake
As shown in FIG. 4C, the parked vehicle 11 is subjected to rough vibrations due to factors of the external environment of the vehicle 11, such as wind, the influence of a large vehicle traveling in the vicinity, or artificial tampering.
[0056]
(4) Impact of objects on the vehicle
As shown in FIG. 4D, when another object such as a vehicle collides with the parked vehicle 11, excessive acceleration is momentarily applied to the vehicle 11. At that time, the acceleration is measured by the vehicle antitheft device 1 fixed to the vehicle 11, that is, the acceleration sensor 22.
[0057]
In the vehicle antitheft device 1, the acceleration sensor 22 is used for the vehicle antitheft device based on the relationship between the generation of acceleration in the vehicle 11 and the factors.
[0058]
When the acceleration sensor 22 is attached to the vehicle 11 as a component of the vehicle antitheft device 1, the acceleration sensor 22 outputs a composite component of acceleration caused by the above factors. In this case, it is difficult to strictly distinguish the acceleration for each factor from the synthesized component of acceleration. However, the classification of the factors necessary for detecting the abnormality of the vehicle 11 can be broadly divided into those that occur when the vehicle 11 is stolen, that is, the impact caused by the inclination and movement of the vehicle 11 and contact with other vehicles. There are two types of things.
[0059]
Here, in a normal parking state, a slight acceleration is measured depending on a certain degree of inclination of the parking place and the mounting angle of the vehicle antitheft device 1, that is, the acceleration sensor 22. However, in this case, since the vehicle 11 is stationary, the acceleration does not vary. By paying attention to this point, it is possible to detect an abnormality by determining whether the fluctuation of acceleration is in a normal state or whether it is out of the normal state and in an abnormal state.
[0060]
In a more effective abnormality detection operation using the acceleration sensor 22, in order to accurately capture acceleration fluctuations, first, each of the accelerations in the X-axis direction and the Y-axis direction during a certain period of time in a normal state in the parking state is used. An average value, that is, an acceleration offset value is recorded. Then, the difference between the acceleration offset value and the acceleration measured at any time is regarded as effective dynamic acceleration, that is, effective acceleration, and the presence / absence of abnormality of the vehicle 11 is determined based on the effective acceleration.
[0061]
Among the abnormalities of the vehicle 11, the impact applied to the vehicle 11 can be detected as follows. When the vehicle 11 receives an impact due to another vehicle colliding or the like, an excessive acceleration is detected in a short time. In this case, since the effective acceleration exceeds the shock acceleration reference, that is, the shock reference value, it is possible to detect the shocked state.
[0062]
Further, the inclination and movement of the vehicle 11 can be detected as follows. It is assumed that an abnormality is detected when an allowable error, that is, an effective acceleration exceeding the detection margin is detected and integrated, and the integrated value exceeds a reference value (abnormality detection reference value). Thereby, in the vehicle antitheft device 1, the movement and inclination of the vehicle 11 are comprehensively detected.
[0063]
Next, the procedure of the abnormality detection operation of the vehicle 11 by the vehicle antitheft device 1 will be described based on the flowcharts of FIGS. In the vehicle antitheft device 1, in the abnormality detection operation, (1) calculation of instantaneous acceleration, (2) calculation of 100 ms average acceleration, (3) calculation of acceleration offset value, (4) calculation of acceleration fluctuation value, and (5) Each process of abnormality determination is performed. Each of these processes is performed as follows.
[0064]
(1) Calculation of instantaneous acceleration
The calculation unit 32 of the vehicle antitheft device 1 activates acceleration pulse processing by interrupt processing every time an acceleration pulse is generated in the output from the acceleration sensor 22 in order to obtain instantaneous acceleration. In this processing, as shown in FIG. 5, the width of the pulse generated from the acceleration sensor 22 (X-axis direction, Y-axis direction) is measured, and the instantaneous time is determined from the ratio between the ON time of these pulses and the time of one cycle. Acceleration is calculated and stored (S1).
[0065]
(2) Calculation of 100ms average acceleration
As shown in FIG. 6, the calculation unit 32 calculates an average acceleration every 100 ms from the instantaneous acceleration calculated during 100 ms (S11). Next, a dynamic effective acceleration every 100 ms is calculated by subtracting an acceleration offset value described later from the average acceleration every 100 ms (S12).
[0066]
Thereafter, when the operation mode is the alert mode and the acceleration offset value is obtained (S13), the determination unit 33 of the vehicle antitheft device 1 uses the effective acceleration and acceleration offset value obtained every 100 ms obtained in S12. Then, abnormality determination processing is performed (S14).
[0067]
(3) Calculation of acceleration offset value
In order to obtain an accurate acceleration applied to the vehicle 11, the arithmetic unit 32 averages the output values of the acceleration sensor 22 in the parking state to obtain acceleration offset values in the X-axis direction and the Y-axis direction. This acceleration offset value is obtained from an average value for 10 seconds in the parking state. The acceleration offset value calculation process is started when the vehicle antitheft device 1 is turned on or when the operation mode is changed, and the acceleration offset value is updated every 10 minutes in consideration of the temperature characteristics of the acceleration sensor 22. To start.
[0068]
In this process, as shown in FIG. 7, first, the average absolute deviation of acceleration for 10 seconds is obtained, that is, the acceleration fluctuation value is calculated (S21), and compared with a predetermined value set in advance. Then, it is determined whether or not the vehicle 11 is stationary (S22). If the result of this determination is that the vehicle is at rest, the average acceleration for the past 10 seconds is adopted as the acceleration offset value (S23), and the integral value of effective acceleration described later is reset (S24).
[0069]
(4) Calculation of acceleration fluctuation value
In order to determine whether or not the vehicle 11 is stationary, the fluctuation amount of acceleration for 10 seconds is calculated. At this time, as shown in FIG. 8, the calculation unit 32 obtains an average acceleration for 1 second from an average acceleration of 100 ms (S31), further obtains an average acceleration for 10 seconds (S32), and 1 second with respect to the average acceleration of 10 seconds. The average absolute deviation of the average acceleration is obtained and set as an acceleration fluctuation value for 10 seconds (S33).
[0070]
(5) Abnormality determination processing
In order to detect an abnormal acceleration applied to the stationary vehicle 2, the determination unit 33 performs an abnormality determination process shown in S14 of FIG. In this process, as shown in FIG. 9, the determination unit 33 first sets in advance the absolute value of the effective acceleration every 100 ms obtained in the process (2) in each of the X-axis direction and the Y-axis direction. It is compared with the shock detection reference value that has been made (S41). As a result of this comparison, if the absolute value of the execution acceleration is equal to or greater than the impact detection reference value, it is considered that the impact applied to the vehicle 11 has been detected, the operation mode is shifted to the tracking mode, and via the transmission / reception unit 24, The management device 2 is notified of the change of the operation mode (S42).
[0071]
Further, the determination unit 33 compares the absolute value of the effective acceleration every 100 ms obtained in the process (2) in each of the X-axis direction and the Y-axis direction with a preset detection margin (S43). . If the absolute value of the execution acceleration is equal to or greater than the detection margin as a result of the comparison, the calculation unit 32 calculates an integral value of the execution acceleration (S44). The detection margin is set to a value that allows a detection error in the acceleration sensor 22 and a slight fluctuation due to the influence of the surrounding environment.
[0072]
Next, the determination unit 33 compares the integrated value with the abnormality detection reference value (S45). As a result of this comparison, if the integral value is equal to or greater than the abnormality detection reference value, it is considered that the vehicle 11 is moving or tilting. Upon receiving this result, the output control unit 34 shifts the operation mode to the tracking mode, and notifies the management device 2 of the change of the operation mode via the transmission / reception unit 24 (S46).
[0073]
Here, the result of verifying the abnormality detection operation of the vehicle 11 using the acceleration sensor 22 will be described based on the graphs of FIGS. 10 to 12.
[0074]
FIG. 10 is a graph of the integrated value of acceleration data in the Y-axis direction and a value exceeding the detection margin in the acceleration data when the vehicle 11 moves. From this graph, the change in the integrated value due to the acceleration generated when the vehicle 11 is moved can be seen. This integrated value is used for determination of movement and inclination of the vehicle 11 (S45) in the abnormality determination processing shown in FIG.
[0075]
FIG. 11 exceeds the detection margin in the acceleration data in the X-axis direction and the Y-axis direction, the difference data between the acceleration and the acceleration offset value (effective acceleration), and the acceleration data when the vehicle 11 is tilted. It is a graph of the integral value of a value. From this graph, the change in the integrated value in the horizontal component of the gravitational acceleration generated when the vehicle 11 is tilted can be seen. Similarly, the integrated value is used for determination of movement and inclination of the vehicle 11 (S45) in the abnormality determination process shown in FIG.
[0076]
FIG. 12 shows the acceleration values in the X-axis direction and the Y-axis direction and the fluctuation values of the acceleration in both directions when determining the stationary state of the vehicle 11. In determining whether the vehicle 11 is stationary, in order to see the stability of the acceleration in each of the X-axis direction and the Y-axis direction, the average value of the absolute deviations of the respective measured values is regarded as the fluctuation amount of the acceleration in that direction. When the acceleration fluctuation amount is less than a certain value, it is determined that the vehicle is stationary.
[0077]
As described above, in the vehicle antitheft device 1 according to the present embodiment, for example, only one acceleration sensor 22 that detects acceleration in a plurality of axial directions, for example, two axial directions, for example, acceleration in the moving direction of the vehicle 11, By detecting the acceleration caused by the inclination of the vehicle 11 and the acceleration caused by applying an impact to the vehicle 11, and based on these accelerations, specifically, analyzing these accelerations from multiple aspects, That is, the presence or absence of the theft state is determined. Therefore, the vehicle antitheft device 1 does not need to be provided with a large number of sensors, and the vehicle antitheft device 1 has a small size and low cost.
[0078]
Further, when an abnormality of the vehicle 11 is detected, the abnormality is notified to the user 12 via the management device 2, so that the user 12 can quickly cope with the theft of the vehicle 11.
[0079]
In this case, since the configuration of the vehicle antitheft device 1 is simplified, it becomes easy to add a communication module even in a limited space, and the vehicle antitheft device 1 is connected to the management device 2 and the mobile terminal device 3 of the user 12. Vehicle anti-theft system combined with can be easily constructed. As a result, the detection result of the vehicle antitheft device 1 can be notified to the remote user 12.
[0080]
In the vehicle antitheft device 1, a siren or a hazard as an external output device provided in the vehicle 11 can be operated to serve as a mark when searching for the vehicle 11 threatened by the criminal or being stolen.
[0081]
In the present embodiment, the acceleration directions detected by the acceleration sensor 22 are the Y-axis direction and the X-axis direction. However, the present invention is not limited to this, and Z is a vertical direction in the two-axis direction. It may be a triaxial direction including the axial direction. Further, it may be any two-axis direction among the X-axis direction, the Y-axis direction, and the Z-axis direction. Furthermore, for example, even when only the acceleration in the Y-axis direction is detected, as described above, a plurality of states in the vehicle 11, that is, the presence or absence of the moving state of the vehicle 11 and the presence or absence of the inclined state are detected. Can do.
[0082]
【The invention's effect】
As described above, the vehicle theft prevention method of the present invention includes an acceleration detection step for detecting the acceleration of the vehicle, and a determination for determining whether there is an abnormality associated with theft of the vehicle based on the acceleration detected by the acceleration detection step. And a step.
[0083]
Further, the vehicle antitheft device of the present invention includes an acceleration detecting unit that detects the acceleration of the vehicle, and a determining unit that determines whether there is an abnormality associated with the theft of the vehicle based on the acceleration detected by the acceleration detecting unit. It is the composition which is provided.
[0084]
According to the above configuration, since a plurality of states in the vehicle can be detected from the output of the acceleration sensor that detects the acceleration of the vehicle, the anti-theft function has a high number of sensors necessary for the anti-theft operation of the vehicle. Can be reduced while maintaining. As a result, the vehicle anti-theft device having a high anti-theft function can be made compact and low-cost.
[0085]
In the vehicle theft prevention method, at least the longitudinal acceleration of the vehicle is detected in the acceleration detection step, and the vehicle is moving in the determination step, which is abnormal based on the longitudinal acceleration of the vehicle. It is good also as a structure which determines the presence or absence of this, and the presence or absence of the state which the vehicle inclines.
[0086]
Further, in the above vehicle antitheft device, the acceleration detecting means detects at least the longitudinal acceleration of the vehicle, and the determining means is abnormal based on the longitudinal acceleration of the vehicle. It is good also as a structure which determines the presence or absence of the state which is moving, and the presence or absence of the state which the vehicle inclines.
[0087]
According to the above configuration, based on the longitudinal acceleration of the vehicle, whether the vehicle is moving and whether the vehicle is tilted, that is, whether the vehicle has been stolen and moved In addition, it is possible to determine whether or not the vehicle is in a state of being towed.
[0088]
Therefore, by using one acceleration sensor, it is possible to detect at least two types of abnormality associated with theft of the vehicle. As a result, the number of sensors required for the vehicle anti-theft operation can be surely reduced, and the vehicle anti-theft device having a high anti-theft function can be reliably made small and low-cost.
[0089]
In the vehicle anti-theft method, the acceleration detecting step detects accelerations in a plurality of axial directions, and the determining step is based on the accelerations in the plurality of axial directions. It is good also as a structure which determines the presence or absence of abnormality.
[0090]
Further, in the above vehicle antitheft device, the acceleration detecting means detects accelerations in a plurality of axial directions, and the determining means generates accelerations in the respective axial directions based on the accelerations in the plurality of axial directions. The presence or absence of each abnormality
It is good also as a structure.
[0091]
According to the above configuration, since one or more types of states can be detected from each of the accelerations in the plurality of axial directions, the anti-theft function has a high number of sensors necessary for the anti-theft operation of the vehicle. It can be reduced while maintaining. As a result, the vehicle anti-theft device having a high anti-theft function can be made compact and low-cost.
[0092]
In the vehicle theft prevention method, at least acceleration in the longitudinal direction of the vehicle and acceleration in the width direction of the vehicle are detected in the acceleration detection step, and in the determination step, an abnormality occurs based on the acceleration in the longitudinal direction of the vehicle. Determines whether the vehicle is moving and whether the vehicle is tilted, and determines whether there is an abnormal vehicle swinging in the width direction based on the acceleration in the width direction of the vehicle It is good also as composition to do.
[0093]
In the above vehicle antitheft device, the acceleration detecting means detects at least the longitudinal acceleration of the vehicle and the acceleration in the width direction of the vehicle, and the determining means is based on the longitudinal acceleration of the vehicle. It is determined whether the vehicle is moving and whether the vehicle is moving and whether the vehicle is tilted. Based on the acceleration in the width direction of the vehicle, the vehicle is shaking in the width direction. It is good also as a structure which determines the presence or absence of a state.
[0094]
According to the above configuration, based on the longitudinal acceleration of the vehicle and the width direction of the vehicle, whether or not the vehicle is stolen and moved, whether or not the vehicle is towed, and for example, the vehicle It is possible to detect the presence or absence of an intruder in the vehicle.
[0095]
Therefore, by using a small number of acceleration sensors, for example, one biaxial acceleration sensor, at least three types of abnormalities associated with theft of the vehicle can be detected. As a result, the number of sensors required for the vehicle anti-theft operation can be reduced, and the vehicle anti-theft device having a high anti-theft function can be reliably made small and low-cost.
[0096]
The vehicle theft prevention method may further include an output control step of operating an alarm device attached to the vehicle when the determination step determines that there is an abnormality.
[0097]
The vehicle antitheft device may further include output control means for operating an alarm device attached to the vehicle when the determination means determines that there is an abnormality.
[0098]
According to the above configuration, the alarm device is activated when an abnormality of the vehicle, that is, a theft state is detected, so that it is possible to appropriately prevent theft.
[0099]
The vehicle anti-theft system according to the present embodiment includes the above-described vehicle anti-theft device and a management device, and when the vehicle anti-theft device determines that there is an abnormality, the abnormality occurrence information indicating that fact. Is further configured to transmit information indicating an occurrence of an abnormality in the vehicle to the user terminal device after receiving the abnormality occurrence information.
[0100]
According to the above configuration, when a vehicle abnormality, that is, a theft state is detected in the vehicle antitheft device, the information is transmitted to the user terminal device via the management device. It is possible to respond quickly.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a vehicle antitheft device according to an embodiment of the present invention.
2 is a block diagram showing a configuration of a vehicle antitheft system including the vehicle antitheft device shown in FIG. 1. FIG.
FIG. 3 is a block diagram illustrating a configuration of the management apparatus illustrated in FIG. 2;
4 (a) is a perspective view showing the principle of detection of acceleration caused by movement of the vehicle in the traveling direction by the acceleration sensor shown in FIG. 1, and FIG. 4 (b) is based on the inclination of the vehicle. FIG. 4C is a perspective view showing the principle of detection of acceleration caused by the shake of the vehicle, and FIG. 4D is the principle of detection of acceleration caused by impact applied to the vehicle. FIG.
FIG. 5 is a flowchart showing acceleration pulse processing in the vehicle antitheft device shown in FIG. 1;
6 is a flowchart showing a 100 ms average acceleration calculation process in the vehicle antitheft device shown in FIG. 1; FIG.
7 is a flowchart showing acceleration offset value calculation processing in the vehicle antitheft device shown in FIG. 1. FIG.
FIG. 8 is a flowchart showing acceleration fluctuation value calculation processing in the vehicle antitheft device shown in FIG. 1;
FIG. 9 is a flowchart showing a vehicle abnormality determination operation in the vehicle antitheft device shown in FIG. 1;
10 is a graph showing acceleration data in the Y-axis direction when the vehicle moves, obtained from the acceleration sensor shown in FIG. 1, and an integrated value of a value exceeding the detection margin in this acceleration data.
11 is obtained from the acceleration sensor shown in FIG. 1, acceleration data in the X-axis direction and the Y-axis direction when the vehicle is tilted, difference data (effective acceleration) between these accelerations and acceleration offset values, and It is a graph which shows the integrated value of the value which exceeded the detection margin in those acceleration data.
12 is a graph showing the acceleration values in the X-axis direction and the Y-axis direction and the fluctuation values of the accelerations in both directions when determining the stationary state of the vehicle, obtained from the acceleration sensor shown in FIG. 1;
[Explanation of symbols]
1 Vehicle anti-theft device
2 management devices
3 Mobile terminal devices
4 Remote control transmission unit
11 Vehicle
22 Acceleration sensor (acceleration detection means)
23 Control device
24 Transmission / reception unit (communication means)
31 Mode switching part
32 Calculation unit
33 determination unit (determination means)
34 Output control unit (output control means, communication means)

Claims (7)

An acceleration detection step for detecting acceleration in a plurality of axial directions of the vehicle;
A vehicle anti-theft method comprising: a determination step for determining presence / absence of each abnormality that causes acceleration in each of the axial directions based on the acceleration in the plurality of axial directions detected by the acceleration detection step. There,
In the determination step,
For each of the longitudinal and lateral directions of the vehicle, the difference between the acceleration offset value obtained by averaging the acceleration during a certain period of the vehicle in a stationary state and the acceleration measured at any time in the acceleration detecting step is As acceleration,
A vehicle theft prevention method comprising detecting whether or not the vehicle has received an impact based on whether or not the effective acceleration exceeds a reference value of the impact acceleration. An acceleration detection step for detecting acceleration in a plurality of axial directions of the vehicle;
A vehicle anti-theft method comprising: a determination step for determining presence / absence of each abnormality that causes acceleration in each of the axial directions based on the acceleration in the plurality of axial directions detected by the acceleration detection step. There,
In the determination step,
For each of the longitudinal and lateral directions of the vehicle, the difference between the acceleration offset value obtained by averaging the acceleration during a certain period of the vehicle in a stationary state and the acceleration measured at any time in the acceleration detecting step is As acceleration,
When the effective acceleration exceeds an allowable error, the effective acceleration is integrated, and whether or not the vehicle has moved or tilted is detected based on whether or not the integrated value exceeds the abnormality detection reference value. Prevention method. The vehicle theft prevention method according to claim 1, further comprising an output control step of operating an alarm device attached to the vehicle when it is determined that there is an abnormality in the determination step. Acceleration detecting means for detecting acceleration in a plurality of axial directions of the vehicle;
A vehicle antitheft device comprising: a determination unit that determines the presence or absence of each abnormality that causes acceleration in each of the axial directions based on the acceleration in the plurality of axial directions detected by the acceleration detection unit. There,
The determination means includes
For each of the longitudinal and lateral directions of the vehicle, the difference between the acceleration offset value obtained by averaging the acceleration during a certain period of the vehicle in a stationary state and the acceleration measured at any time in the acceleration detecting step is As acceleration,
A vehicle antitheft device that detects whether or not the vehicle has received an impact based on whether or not the effective acceleration exceeds a reference value of impact acceleration. Acceleration detecting means for detecting acceleration in a plurality of axial directions of the vehicle;
A vehicle antitheft device comprising: a determination unit that determines the presence or absence of each abnormality that causes acceleration in each of the axial directions based on the acceleration in the plurality of axial directions detected by the acceleration detection unit. There,
The determination means includes
For each of the longitudinal and lateral directions of the vehicle, the difference between the acceleration offset value obtained by averaging the acceleration during a certain period of the vehicle in a stationary state and the acceleration measured at any time in the acceleration detecting step is As acceleration,
When the effective acceleration exceeds an allowable error, the effective acceleration is integrated, and whether the vehicle has moved or tilted is detected based on whether the integrated value exceeds the abnormality detection reference value. A vehicle antitheft device. 6. The vehicle antitheft device according to claim 4, further comprising output control means for activating an alarm device attached to the vehicle when it is determined that there is an abnormality by the determination means. The vehicle antitheft device according to any one of claims 4 to 6 and a management device, wherein the vehicle antitheft device indicates an abnormality when the determination means determines that there is an abnormality. Further comprising communication means for transmitting the occurrence information to the management device;
The said management apparatus transmits the information which shows the abnormality generation in a vehicle to a user's terminal device after reception of the said abnormality occurrence information, The vehicle antitheft system characterized by the above-mentioned.

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