JP6897217B2 - Vehicle management device, vehicle management terminal and its control method and control program - Google Patents

Description

The present invention relates to a vehicle management device and the like, and more particularly to a vehicle management device that generates position data.

The fire-fighting vehicle or ambulance vehicle is equipped with an AVM (Automatic Vehicle Monitor) device for navigating the vehicle to the site by receiving a dispatch command from the command center or transmitting the vehicle position data or the activity status of the site to the command center. It is installed.

FIG. 11 is a configuration diagram showing a configuration of an AVM device, which is the first related technology. The AVM device shown in FIG. 11 is fixedly installed in the vehicle, and from the vehicle side, a vehicle battery, an ignition signal (indicated as IGN in the figure), an accessory power supply signal (indicated as ACC in the figure), and a forward / backward identification signal. (Indicated as FBIS in the figure) and an interface signal with another device (indicated as IFS in the figure) are input.

In the AVM device shown in FIG. 11, the vehicle speed signal (vehicle speed pulse) and the angular velocity signal of the gyro sensor are used to realize highly accurate positioning (autonomous navigation) for the vehicle in which the AVM device is installed.

On the other hand, in order to acquire an accurate angular velocity signal from the gyro sensor, the installation position of the AVM device inside the gyro sensor is fixed, and the AVM device cannot be carried out of the vehicle.

FIG. 12 is a configuration diagram showing a configuration of an AVM device, which is a second related technique. The AVM device of the second related technology shown in FIG. 12 is composed of two units, a vehicle unit and a unloading unit. The AVM device shown in FIG. 12 has a configuration in which a vehicle unit including a gyro sensor or the like is fixedly installed on the vehicle, and a carry-out unit provided with a screen display unit for displaying position data or a road map is carried out of the vehicle for use. Is adopted.

Patent Document 1 includes an in-vehicle device equipped with a vehicle speed sensor, a gyro sensor, and GPS, and a mobile terminal capable of GPS positioning. The in-vehicle device generates correction position data and transmits the correction position data to the mobile terminal, and the mobile terminal performs the correction position. It is described that the vehicle position data is generated based on the data and GPS positioning.

Further, Patent Document 2 describes an in-vehicle cradle in which a portable device capable of GPS positioning is installed in a vehicle and the portable device can be attached and detached. It is stated that an anti-theft sensor is provided on the in-vehicle cradle to prevent the portable device from being stolen from inside the vehicle.

JP-A-2014-109719A Japanese Unexamined Patent Publication No. 2010-086215

The AVM device of the first related technology cannot take the AVM device out of the vehicle. Further, in the AVM device of the second related technology, similar parts such as a CPU and a memory are duplicated between the vehicle unit and the unloading unit, or between the in-vehicle device and the mobile terminal in Patent Document 1. Was. Therefore, simplification of the device configuration has been required. The portable device described in Patent Document 2 generates position data only from the GPS positioning signal even when the portable device is connected to the in-vehicle cradle, and generates highly accurate position data for the vehicle with respect to the terminal mounted on the vehicle. You can't.

An object of the present invention is to provide a vehicle management device or the like that reduces duplication of device configurations, enables unloading from a vehicle, and generates highly accurate position data with respect to the vehicle.

One aspect of the vehicle management device of the present invention is
With the cradle fixed in the vehicle,
It is equipped with a vehicle management terminal that is removable and electrically connectable to the cradle.
The cradle
It includes a vehicle speed acquisition unit that acquires a vehicle speed signal from a vehicle and a gyro sensor that detects a direction change of the vehicle and outputs a direction change signal.
The vehicle management terminal is
It is provided with a receiving circuit that receives radio waves of an artificial satellite and outputs a positioning signal, a position generating unit that generates position data of the own terminal based on at least the positioning signal, and a determination unit that determines mounting on the cradle.
When the vehicle management terminal is mounted on the cradle, the position generator generates the position data based on the positioning signal, the vehicle speed signal, and the direction change signal.
When the vehicle management terminal is not mounted on the cradle, the position generation unit generates the position data based on the positioning signal.

One aspect of the control method of the present invention is
It is a control method of a vehicle management end device including a cradle fixed in a vehicle and a vehicle management terminal that can be attached to and detached from the cradle and can be electrically connected.
The cradle,
The vehicle speed signal is acquired from the vehicle, the direction change of the vehicle is detected, and the direction change signal is output.
The vehicle management terminal
Receives artificial satellite radio waves and outputs positioning signals,
Generate the position data of the own terminal based on at least the positioning signal,
Judging that it is attached to the cradle,
When the vehicle management terminal is mounted on the cradle, the position data is generated based on the positioning signal, the vehicle speed signal, and the direction change signal.
When the vehicle management terminal is not mounted on the cradle, the position data is generated based on the positioning signal.

One aspect of the control program of the present invention is
A control program for a vehicle management end device including a cradle fixed in a vehicle and a vehicle management terminal that is detachable and electrically connectable to the cradle.
The cradle,
The vehicle speed signal is acquired from the vehicle, the direction change of the vehicle is detected, and the direction change signal is output.
The vehicle management terminal
Receives artificial satellite radio waves and outputs positioning signals,
Generate the position data of the own terminal based on at least the positioning signal,
Judging that it is attached to the cradle,
When the vehicle management terminal is mounted on the cradle, the position data is generated based on the positioning signal, the vehicle speed signal, and the direction change signal.
When the vehicle management terminal is not mounted on the cradle, the vehicle management device is made to generate the position data based on the positioning signal.

One aspect of the vehicle management terminal of the present invention is a vehicle management terminal mounted on a cradle fixed in a vehicle and electrically connected to the cradle, which receives radio waves from an artificial satellite and outputs a positioning signal. The vehicle management terminal is mounted on the cradle, and includes a receiving unit, a position generating unit that generates position data of the own terminal based on at least the positioning signal, and a determination unit that determines mounting of the cradle. If so, the position generation unit generates the position data based on the positioning signal, the vehicle speed signal indicating the speed of the vehicle, and the direction change signal indicating the direction change of the vehicle, which are output from the cradle. When the vehicle management terminal is not mounted on the cradle, the position generation unit generates the position data based on the positioning signal.

One aspect of the vehicle management terminal control method of the present invention is a control method of a vehicle management terminal mounted on a cradle fixed in a vehicle and electrically connected to the cradle, and receives radio waves of an artificial satellite. To output a positioning signal, generate position data of the own terminal based on at least the positioning signal, determine mounting with the cradle, and when the vehicle management terminal is mounted on the cradle, the positioning signal. The position data is generated based on the vehicle speed signal indicating the speed of the vehicle and the direction change signal indicating the direction change of the vehicle output from the cradle, and the vehicle management terminal is not mounted on the cradle. In the case, the position data is generated based on the positioning signal.

One aspect of the vehicle management terminal control program of the present invention is a vehicle management terminal control program mounted on a cradle fixed in the vehicle and electrically connected to the cradle, and receives radio waves from an artificial satellite. To output a positioning signal, generate position data of the own terminal based on at least the positioning signal, determine mounting with the cradle, and when the vehicle management terminal is mounted on the cradle, the positioning signal. The position data is generated based on the vehicle speed signal indicating the speed of the vehicle and the direction change signal indicating the direction change of the vehicle output from the cradle, and the vehicle management terminal is not mounted on the cradle. In the case, a control program for causing the vehicle management terminal to generate the position data based on the positioning signal.

INDUSTRIAL APPLICABILITY The present invention can reduce duplication of device configurations, enable unloading from a vehicle, and generate highly accurate position data with respect to the vehicle.

can do.

It is a block diagram which shows the structure of the vehicle management apparatus of 1st Embodiment. It is a flowchart which shows the operation of the vehicle management terminal which uses the position data at the time of mounting a cradle. It is a graph which shows charge control to a built-in battery in a power saving state. It is a block diagram which shows the structure of the vehicle management apparatus of 2nd Embodiment. It is a block diagram which shows the structure of the vehicle management apparatus of 3rd Embodiment. It is a block diagram which shows the structure of the fixture which fixes a vehicle management terminal to a cradle. It is a block diagram which shows the structure of the cradle of 4th Embodiment. It is a block diagram which shows the structure of the vehicle management terminal of 4th Embodiment. It is a flowchart which shows the operation of the vehicle management terminal of 4th Embodiment. It is a block diagram which shows the hardware configuration which realizes the vehicle management apparatus in each embodiment by a computer. It is a block diagram which shows the structure of the vehicle management apparatus in the 1st related technique. It is a block diagram which shows the structure of the vehicle management apparatus in the 2nd related technique.

The vehicle management device according to the first embodiment will be described with reference to FIG. FIG. 1 is a configuration diagram showing a configuration of a vehicle management device according to the first embodiment. As shown in FIG. 1, the vehicle management device 100 includes a vehicle management terminal 110 and a cradle 210. The vehicle management device 100 may be referred to as an AVM device, and the vehicle management terminal may be referred to as an AVM terminal.

First, the configuration of the vehicle management terminal 110 will be described. The vehicle management terminal 110 includes a power supply circuit 113, a built-in battery 114, a GPS receiving circuit 115, a determination circuit 116, a position generation circuit 117, a CPU 118, a screen display unit 119, a memory 120, a wireless circuit 121, and an external interface 122.

The power supply circuit 113 has a function of supplying electric power to each circuit such as the CPU 118 in the vehicle management terminal 110. The power supply circuit 113 starts power supply by user operation, wireless incoming call, or the like.

Further, the power supply circuit 113 receives an accessory power supply signal (indicated as ACC in the figure) or an ignition signal (indicated as IGN in the figure) from the vehicle via the cradle 210. The power supply circuit 113 can identify the power supply state from the vehicle, for example, the engine stop, etc., based on the accessory power supply signal or the ignition signal.

The ignition signal is output from the vehicle battery when the engine is started and when the electrical components related to the running of the vehicle such as when the engine is rotating are moved. The accessory power signal is output from the vehicle battery when the electrical components are operated even when the engine is stopped.

The built-in battery 114 is one of the power supply sources for the vehicle management terminal 110. The built-in battery 114 supplies electric power to the entire vehicle management terminal 110 in the carry-out mode (described later), or supplies electric power to the wireless circuit 121 while the engine is stopped. The built-in battery 114 is a rechargeable / dischargeable secondary battery (for example, a lithium ion battery). The built-in battery 114 is charged and controlled by the power supply circuit 113. For example, when the vehicle management terminal 110 is attached to the cradle 210 and the remaining battery level of the built-in battery 114 is equal to or less than a certain value while the vehicle is running, power is supplied from the vehicle battery to charge the built-in battery 114. On the other hand, when the engine of the vehicle is stopped and the remaining amount of the built-in battery 114 is equal to or higher than a certain value, the charging of the built-in battery 114 is stopped.

The GPS receiving circuit 115 receives radio waves from an artificial satellite and outputs a positioning signal. The output positioning signal is used in the position generation circuit 117 to generate the position data of the vehicle management terminal 110.

The determination circuit 116 determines whether the vehicle management terminal 110 is equipped with the cradle 210. The determination by the determination circuit 116 is derived based on the presence or absence of electrical connection between the vehicle management terminal 110 and the cradle 210. As shown in FIG. 1, a wiring connected from the power supply circuit 113 to the determination circuit 116 via the cradle 210 is provided. The cradle 210 outputs the voltage from the power supply circuit 113 to the determination circuit 116 of the vehicle management terminal 110 through. The determination circuit 116 determines whether or not the vehicle management terminal 110 is mounted on the cradle 210 by detecting the voltage of the wiring via the cradle 210. For example, if the determination circuit 116 can detect a predetermined voltage, it determines that the vehicle management terminal 110 is mounted on the cradle 210 (mounting mode), and if the determination circuit 116 cannot detect the predetermined voltage, the vehicle management terminal 110 determines that the cradle 210 is mounted. It is determined that the device has been removed from the device (delivery mode).

When the vehicle management terminal 110 is in the mounting mode, the position generation circuit 117 is input to the vehicle management terminal 110 via the positioning signal of the GPS receiving circuit 115, the direction change signal of the gyro sensor, the vehicle speed signal of the vehicle speed acquisition unit, and the cradle 210. Further, the position data of the vehicle management terminal 110 is generated based on the forward / backward identification signal of the vehicle (indicated as FBIS in the figure). It should be noted that the position data may be generated without using the forward / backward identification signal of the vehicle.

Further, when the vehicle management terminal 110 is in the carry-out mode, the position generation circuit 117 generates the position data of the vehicle management terminal 110 based on the positioning signal output by the GPS receiving circuit 115.

The CPU 118 executes a control program such as a start program stored in a memory or the like, and controls the vehicle management terminal 110 or the cradle 210 constituting the vehicle management device 100.

The screen display unit 119 has a function of displaying, for example, a road map and the position data of the vehicle management terminal 110 generated by the position generation circuit 117. The screen display unit 119 may include an input function in addition to the display function. For example, the screen display unit 119 includes a liquid crystal display and a touch panel. The CPU 118 controls the screen display unit 119 to display the user interface screen, and can receive an operation input from the user according to the screen display.

The memory 120 stores the control program executed by the CPU 118 or the position data generated by the position generation circuit 117.

The wireless circuit 121 is a wireless communication circuit such as GSM (registered trademark), 3GPP, Bluetooth (registered trademark), or wireless LAN. The wireless circuit 121 receives, for example, a dispatch command from the command center, or transmits the position data of the vehicle management terminal 110 to the command center.

The external interface 122 includes a control circuit for an SD card, USB, a wired LAN, and the like, and a connection terminal.

Next, the configuration of the cradle 210 of the vehicle management device 100 will be described. The cradle 210 is an expansion device that is fixedly arranged in the vehicle and holds the vehicle management terminal 110. The cradle 210 shown in FIG. 1 includes a vehicle speed acquisition circuit 211 and a gyro sensor 212.
The cradle 210 is electrically connected to the vehicle management terminal 110, for example, via a connector (not shown).

A plurality of signals (accessory power signal, ignition signal, etc.) from the vehicle and signals generated by the cradle 210 are sent to the vehicle management terminal 110 via the cradle 210. The power of the vehicle battery is also sent to the vehicle management terminal 110 via the cradle 210.

The vehicle speed acquisition circuit 211 acquires and outputs a vehicle speed signal indicating the speed of the vehicle. The vehicle speed acquisition circuit 211 acquires a vehicle speed signal from a vehicle speed sensor installed in the vehicle, for example. The vehicle speed signal may be output as the vehicle speed signal acquired from the vehicle sensor, or may be output after the vehicle speed signal is converted or processed for use in the subsequent stage.

The gyro sensor 212 detects the direction change of the vehicle and outputs a direction change signal. An example of a direction change signal is an angular velocity signal.

A connector (not shown) is arranged on the cradle 210 and the vehicle management terminal 110, respectively, and the connector portion is a power line of the vehicle battery between the cradle 210 and the vehicle management terminal 110, and a signal line such as an accessory power supply signal and a vehicle speed signal. It becomes an electrical contact point of. The power line and signal line are electrically connected / disconnected depending on whether or not the vehicle management terminal 110 is attached to the cradle 210.

(Operation of the first embodiment)
Next, the operation of the vehicle management device according to the first embodiment will be described with reference to the drawings. The vehicle management terminal 110 receives an operation input for system activation by the user, the power supply circuit 113 supplies electric power to the circuit of the vehicle management terminal 110, and the CPU 118 executes a program to activate the vehicle management terminal 110.

The cradle 210 outputs the voltage from the power supply circuit 113 through to the vehicle management terminal 110, and detects this by the determination circuit 116. The determination circuit 116 determines whether the vehicle management terminal 110 is mounted on the cradle 210 based on the presence or absence of voltage detection.

When the vehicle management terminal 110 is mounted on the cradle 210, the vehicle management terminal 110 operates in the mounting mode. The operation in the mounting mode will be described below.

The power supply circuit 113 monitors an ignition signal (indicated as IGN in FIG. 1) and an accessory power supply signal (indicated as ACC in FIG. 1), which are input signals from the vehicle, and transmits the engine ON / OFF state to the CPU 118.

The position generation circuit 117 performs autonomous navigation using the direction change signal of the gyro sensor 212, the vehicle speed signal of the vehicle speed acquisition circuit 211, the forward / backward identification signal (referred to as FBIS in FIG. 1), and the positioning signal of the GPS receiving circuit 115. The position generation circuit 117 generates position data of the vehicle management terminal 110 by autonomous navigation. The CPU 118 transmits the position data generated by using the wireless circuit.

Further, the power supply circuit 113 determines whether the engine is ON / OFF based on the ignition signal and the accessory power supply signal, and charges the built-in battery 114 while the engine is ON. The vehicle management terminal 110 goes into a power saving mode (sleep or suspend) or shuts down by user operation or engine OFF.

When the power wireless incoming call (dispatch command) or the engine ON is detected while the engine is OFF, the CPU 118 activates the vehicle management terminal 110, and it becomes possible to use the external interface 122 and control the interface signal with other devices. If the wireless incoming call or the engine ON is not detected within a certain period of time, the CPU 118 automatically puts the vehicle management terminal 110 into a power saving state (sleep or suspend).

When the voltage value of the built-in battery 114 is higher than the charging stop voltage value, the power supply circuit 113 stops charging, supplies power from the built-in battery 114 to the wireless circuit 121, and performs a standby operation in a power-saving state. When the voltage value of the built-in battery 114 is lower than the charging start voltage, the load on the vehicle battery is reduced by supplying electric power from the vehicle battery.

When the vehicle management terminal 110 is not attached to the cradle 210, the vehicle management terminal 110 operates in the carry-out mode. The operation in the carry-out mode will be described below.

The position generation circuit 117 generates the position data of the vehicle management terminal 110 based on the positioning signal of the GPS receiving circuit 115. The CPU 118 transmits the position data generated by using the wireless circuit.

The power supply circuit 113 does not determine engine ON / OFF when the vehicle management terminal 110 is not mounted on the cradle 210. Therefore, in the case of the carry-out mode, the transition to the power saving mode (sleep or suspend) is executed by a preset timer time or an operation input by the user.

In the carry-out mode, the electric power to the vehicle management terminal 110 is supplied from the built-in battery 114. When there is a wireless incoming call (dispatch command) during the power saving mode (sleep or suspend), the CPU 118 starts the system. In the carry-out mode, when there is no operation input from the user to the vehicle management terminal 110 for a certain period of time, the CPU 118 shifts the vehicle management terminal 110 to the power saving mode (sleep or suspend).

Further, when the vehicle management terminal 110 in the power saving state is mounted on the cradle 210 and the power supply circuit 113 detects that the engine of the vehicle is turned on, the CPU 118 activates the system of the vehicle management terminal 110 and shifts to the mounting mode.

In the carry-out mode, the position data of the vehicle management terminal 110 is generated only by the positioning signal from the GPS receiving circuit 115. Therefore, depending on the reception environment of the radio waves from the artificial satellite, the accuracy of the position data of the vehicle management terminal 110 generated by the position generation circuit 117 deteriorates.

For example, when the vehicle is stopped in a place surrounded by a group of buildings, the vehicle management terminal 110 is removed from the cradle 210, the vehicle management terminal 110 is moved to a site away from the vehicle, and the vehicle is returned to the vehicle again, the cradle 210 There is a possibility that the accuracy of the position data generated by the vehicle management terminal 110 without being attached to the vehicle management terminal 110 has deteriorated.

FIG. 2 is a flowchart showing the operation of the vehicle management terminal using the position data when the cradle is attached. As shown in FIG. 2, when the vehicle management terminal 110 is removed from the cradle 210 (step C1), the CPU 118 stores the latest position data generated by the position generation circuit 117 at the time of mounting on the cradle 210 in the memory 120. (Step C2).

Then, when the vehicle management terminal 110 is mounted on the cradle 210 again (step C3), the CPU 118 confirms whether the latest position data generated by the position generation circuit 117 at the time of mounting on the cradle 210 is stored in the memory 120. To do.

When the position data at the time of the most recent mounting is stored in the memory 120 (Yes in step C4), the CPU 118 uses the stored position data (step C5).

When the position data at the time of the latest mounting is not stored in the memory 120 (No in step C4), the position generation circuit 117 acquires the positioning signal, the vehicle speed signal, and the position change signal, and newly generates the position data. (Step C6). The CPU uses the newly generated position data (data C7).

If the position of the vehicle has not changed from when the vehicle management terminal 110 was removed from the cradle 210, the vehicle management terminal 110 is generated when it is attached to the cradle 210 stored in the memory 120 and has a highly accurate position. Data can be used. As a result, it is possible to start the navigation of the vehicle without creating new position data at the time of mounting.

When the vehicle management terminal 110 is removed from the cradle 210 and used, the vehicle on which the cradle 210 is installed may not stay in place. If the position of the vehicle changes when the vehicle management terminal 11 is removed from the cradle 210 and when the vehicle management terminal 110 is attached to the cradle 210, the position generation circuit 117 is generated after the vehicle management terminal 110 is removed from the cradle 210. The latest position data obtained may be used as the starting point of the position of the vehicle. In this case, it is preferable that the reception environment of radio waves from the artificial satellite is good.

Whether or not to use the position data stored in the memory 120 in the mounting mode or the carrying-out mode, and whether or not to use the position data stored in the memory 120, depends on the screen display unit by the user of the vehicle management terminal 110. It can be selected or set by inputting the operation to.

(Power supply in power saving state)
In the explanation using FIG. 1, it has been explained that the vehicle management terminal 110 is put into a power saving state by turning off the engine or operating the user, and the wireless circuit 121 waits for a wireless incoming call. Hereinafter, the power supply in the power saving state will be described with reference to FIG. FIG. 3 is a graph showing charge control of the built-in battery in the power saving state.

In the power saving state of the vehicle management terminal 110, the power supply circuit 113 stays in the vehicle management terminal 110 in the power saving state until the voltage value of the built-in battery 114 reaches the preset threshold voltage for charging stop (V2 in FIG. 3). On the other hand, power is supplied from the built-in battery 114. As a result, the load on the vehicle battery connected to the vehicle management device 100 is reduced.

When the voltage value of the built-in battery 114 falls below the preset threshold voltage for charging stop (V2 in FIG. 3), the power supply circuit 113 supplies power from the vehicle battery to the vehicle management terminal 110 in the power-saving state.

While the power is being supplied from the vehicle battery, the built-in battery 114 continues to be discharged minutely, and when it becomes smaller than the threshold voltage for starting charging (V1 in FIG. 3), the power supply circuit 113 starts charging the built-in battery 114. This makes it possible to prevent the built-in battery 114 from being completely discharged.

By supplying electric power from the built-in battery 114 to the circuit of the vehicle management terminal or the like, each circuit of the vehicle management terminal 110 can operate stably even when the voltage of the vehicle battery drops.

The contact between the connector of the vehicle management terminal 110 and the cradle 210 may become unstable due to vibration while the vehicle is running, or chattering may occur due to noise at engine start and affect the voltage detected by the determination circuit. There is. Therefore, chattering countermeasures may be applied to the determination circuit 116, the ignition signal, and the accessory power supply signal by adding a capacitance element or by polling processing by software.

(Effect of the first embodiment)
According to the first embodiment, it is possible to reduce duplication of device configurations, enable unloading from the vehicle, and generate highly accurate position data with respect to the vehicle.

According to the first embodiment, the vehicle management terminal 110 can be carried out, and the vehicle management terminal 110 can be operated without returning to the vehicle during the activity outside the vehicle.

According to the first embodiment, it is not necessary to install the external operation device used in the AVM device of the second related technology and to lay the cable wiring connecting the vehicle unit and the carry-out unit.

(Second embodiment)
Next, the vehicle management device of the second embodiment will be described with reference to the drawings. The vehicle management device 100 of the second embodiment is different from the first embodiment in that short-range wireless circuits are provided in each of the vehicle management terminal 110 and the cradle 210. FIG. 4 is a configuration diagram showing the configuration of the vehicle management device of the second embodiment. In the figure, the short-range wireless circuit 123 of the vehicle management terminal 110 is connected to the CPU 118 and the like, and the short-range wireless circuit 213 of the cradle 210 is connected to the vehicle speed acquisition circuit 211 and the gyro sensor 212.

The short-range wireless circuit 213 of the cradle 210 wirelessly transmits the vehicle speed signal output from the vehicle speed acquisition circuit 211 and the direction change signal output from the gyro sensor 212 to the short-range wireless circuit 123 of the vehicle management terminal 110. Further, the short-range radio circuit 213 indicates an accessory power supply signal (indicated as ACC in the figure), an ignition signal (indicated as IGN in the figure), and a forward / backward identification signal (indicated as FBIS in the figure) input from the vehicle to the cradle. ), The interface signal (indicated as IFS in the figure) is wirelessly transmitted to the short-range wireless circuit 123 of the vehicle management terminal 110.

The short-range wireless circuit 123 of the vehicle management terminal 110 receives various signals from the vehicle transmitted from the short-range wireless circuit 213 of the cradle 210, signals generated by the gyro sensor 212, and the like. As a result, various signals from the vehicle and signals generated by the gyro sensor 212 of the cradle 210 can be used by the CPU 118 of the vehicle management terminal 110 or the position generation circuit 117.

As the short-range wireless circuit, for example, wireless communication of a Bulletoth, a wireless LAN, or a non-contact type IC can be used.

(Effect of the second embodiment)
According to the second embodiment, the number of signal lines for sending various signals from the cradle to the vehicle management terminal can be reduced as compared with the vehicle management device of the first embodiment. Alternatively, the number of terminals of the connector for electrically connecting the cradle and the vehicle management terminal can be reduced.

The reason is that the signal transmission from the cradle to the vehicle management terminal is wirelessly communicated instead of wired.

(Third Embodiment)
Next, the configuration of the vehicle management device of the third embodiment will be described with reference to the drawings. The vehicle management device 100 of the third embodiment is an example in which a rotating structure (hereinafter referred to as a rotating hinge) is adopted in the cradle 210 on which the vehicle management terminal 110 is mounted. FIG. 5 is a configuration diagram showing a configuration of a vehicle management device in which a vehicle management terminal is mounted on a cradle having a rotary hinge.

As shown in FIG. 5, the vehicle management device 100 includes a vehicle management terminal 110 and a cradle 210 having a rotary hinge 215. The rotary hinge 215 has a fixed portion fixed to the cradle 210 and a rotatable portion on the vehicle management terminal 110 side. Wiring 216 from the circuit board 214 of the cradle 210 is arranged inside the rotary hinge 215. The wiring 216 is connected to the circuit board 214 of the cradle 210. On the circuit board 214, the electric power of the vehicle battery from the vehicle, the accessory power supply signal (indicated as ACC in the figure), the ignition signal (indicated as IGN in the figure), the forward / backward identification signal (indicated as FBIS in the figure), An interface signal (indicated as IFS in the figure) is input. Each signal line is arranged. For the wiring 216, a flexible substrate or a cable wire is used so as to withstand kinking when the rotary hinge 215 rotates.

Further, a pressure contact type connector 217 is provided on the upper surface of the rotary hinge 215. The connector 217 is connected to the connector 125 provided on the lower surface of the vehicle management terminal 110. Various signals and electric power from the cradle 210 are sent to the vehicle management terminal 110 via the connectors 125 and 217.

This makes it possible to change the orientation of the vehicle management terminal 110 without affecting the operation of the gyro sensor 212.

(Fixture)
FIG. 6 is a configuration diagram showing a configuration of a fixture for fixing the vehicle management terminal to the cradle. As shown in FIG. 6, the rotary hinge 215 is provided on the cradle 210, and the vehicle management terminal 110 is installed on the rotary hinge 215. When the screen display unit 119 of the vehicle management terminal 110 is on the front side, the fixture 220 is arranged on the back side of the vehicle management terminal 110 extending from the upper surface to the bottom surface of the vehicle management terminal 110. The lower portion of the fixture 220 is fixed to the rotatable portion of the rotary hinge 215, and the fixture 220 also rotates in conjunction with the rotation of the rotatable portion of the rotary hinge 215.

The fixture 220 and the vehicle management terminal 110 are fixed, for example, by a screw hole (not shown) at the top of the vehicle management terminal 110 and a screw (not shown) provided at the top of the fixture.

The connector 125 provided on the vehicle management terminal 110 and the connector 217 provided on the rotary hinge 215 are connected to the connector 125 of the vehicle management terminal 110 and the connector 217 of the rotary hinge 215 by fixing the fixture 220 and the vehicle management terminal 110. It is configured to be. The fixture 220 and the vehicle management terminal 110 may be other than screws. For example, the fixture 220 and the vehicle management terminal 110 may be fixed by a hook mechanism.

(Effect of the third embodiment)
It is possible to reduce duplication of device configurations, enable unloading from the vehicle, and generate highly accurate position data with respect to the vehicle.

According to the third embodiment, when the vehicle management terminal 110 is attached to the cradle 210, the orientation of the vehicle management terminal 110 can be changed without affecting the operation of the gyro sensor 212. The reason is that the gyro sensor 212 is provided on the cradle 210 fixed to the vehicle, and the vehicle management terminal 110 is electrically connected to the cradle 210 via a rotary hinge 215 provided on the upper surface of the cradle 210. Because it is.

(Fourth Embodiment)
Next, the vehicle management device according to the fourth embodiment will be described with reference to the drawings. The vehicle management device of the fourth embodiment is an embodiment showing an outline of the vehicle management device of the first embodiment. The vehicle management device of the fourth embodiment includes a vehicle management terminal 11 and a cradle 21. FIG. 7 is a configuration diagram showing a configuration of a cradle of the vehicle management device. FIG. 8 is a configuration diagram showing a configuration of a vehicle management terminal of the vehicle management device.

First, the configuration of the cradle 21 will be described with reference to the drawings. The cradle 21 is an expansion device that is fixedly arranged in the vehicle and has the vehicle management terminal 11 stationary. The cradle 21 shown in FIG. 7 includes a vehicle speed acquisition unit 22 that acquires a vehicle speed signal from the vehicle, and a gyro sensor 23 that detects a direction change of the vehicle and outputs a direction change signal. The vehicle management terminal 11 is electrically connected to the cradle 21 by being attached to the cradle 21.

Next, the configuration of the vehicle management terminal 11 will be described with reference to the drawings. The vehicle management terminal 11 shown in FIG. 8 includes a receiving unit 12 that receives radio waves of an artificial satellite and outputs a positioning signal, and a position generating unit 14 that generates position data of the vehicle management terminal 11 based on at least the positioning signal. A determination unit 13 for determining whether the vehicle management terminal 11 is mounted on the cradle 21 is provided.

The determination by the determination unit 13 is derived based on the presence or absence of electrical connection between the vehicle management terminal 11 and the cradle 21. For example, the determination unit 13 determines whether or not the vehicle management terminal 11 is mounted on the cradle 21 by detecting the signal from the cradle 21.
For example, if the determination unit 13 can detect a predetermined signal used for generating position data, it determines that the vehicle management terminal 11 is mounted on the cradle 21, and if it cannot detect the predetermined signal, the vehicle management terminal 11 Is determined to have been removed from the cradle 21. The predetermined signal is a vehicle speed signal and a direction change signal output from the cradle 21.

When the vehicle management terminal 11 is mounted on the cradle 21, the position generation unit 14 determines the vehicle management terminal 11 based on the positioning signal of the receiving unit 12, the direction change signal of the gyro sensor 23, and the vehicle speed signal of the vehicle speed acquisition unit 22. Generate position data for. Further, when the vehicle management terminal 11 is not mounted on the cradle 21, the position generation unit 14 generates the position data of the vehicle management terminal 11 based on the positioning signal output by the reception unit 12.

Next, the operation of the vehicle management terminal in the fourth embodiment will be described with reference to the drawings. FIG. 9 is a flowchart showing the operation of the vehicle management terminal according to the fourth embodiment. As shown in FIG. 9, the determination unit 13 of the vehicle management terminal 11 determines whether the vehicle management terminal 11 is mounted on the cradle 21 (step D1).

When the vehicle management terminal 11 is not mounted on the cradle 21, the position generation unit 14 acquires the positioning signal of the receiving unit 12 (step D3) and generates the position data of the vehicle management terminal 11 based on the positioning signal. (Step D4).

When the vehicle management terminal 11 is mounted on the cradle 21 (Yes in step D2), the position generation unit 14 acquires the positioning signal of the receiving unit 12, the direction change signal of the gyro sensor 23, and the vehicle speed signal of the vehicle speed acquisition unit 22. (Step D5).

The position generation unit 14 generates the position data of the vehicle management terminal 11 based on the positioning signal, the direction conversion signal, and the vehicle speed signal (step D6).

(Effect of Fourth Embodiment)
According to the fourth embodiment, it is possible to reduce duplication of device configurations, enable unloading from the vehicle, and generate highly accurate position data with respect to the vehicle.

(Other)
In the above embodiment, the example in which GPS is used as the global positioning system has been described, but the present invention is not limited to GPS. For example, other global positioning systems such as GLONASS and Galileo may be used.
(Hardware configuration)
FIG. 10 is a diagram showing a hardware configuration in which the vehicle management terminal 11 according to the fourth embodiment is realized by a computer. In the fourth embodiment, each component of the vehicle management terminal 11 represents a block of functional units. Part or all of each component is realized, for example, by any combination of the computer 600 and the program as shown in FIG. As an example, the computer 600 includes the following configuration.
CPU (Central Processing Unit) 601
ROM (Read Only Memory) 602,
RAM (Random Access Memory) 603,
Program 604 loaded into RAM 603,
Storage device 605 for storing program 604,
Drive device 607 that reads and writes the storage medium 606,
Communication interface 608 that connects to the communication network 609,
Input / output interface 610 for inputting / outputting data,
System bus 611 connecting each component
Each component of the vehicle management terminal 11 is realized by the CPU 601 acquiring and executing the program 604 that realizes these functions. The program 604 that realizes the functions of each component is stored in, for example, in the storage device 605, ROM 602, or RAM 603 in advance, and is read by the CPU 601 as needed. The program 604 may be supplied to the CPU 601 via the communication network 609, or may be stored in the storage medium 606 in advance, and the drive device 607 may read the program and supply the program to the CPU 601.

There are various modifications in the method of realizing the vehicle management terminal 11. For example, the vehicle management terminal 11 may be realized by any combination of a computer 600 and a program, which are separate for each component. Further, a plurality of components included in the vehicle management terminal 11 may be realized by any combination of one computer 600 and a program.

Further, a part or all of each component of the vehicle management terminal 11 is realized by other general-purpose or dedicated circuits, processors, or a combination thereof. These may be composed of a single chip or may be composed of a plurality of chips connected via a system bus. Further, a programmable logic device such as FPGA (Field-Programmable Gate Array) may be used instead of the computer 600.

Further, a part or all of each component of the vehicle management terminal 11 may be realized by a combination of the above-mentioned circuit or the like and a program.

Further, when a part or all of each component of the vehicle management terminal 11 is realized by a plurality of computers, circuits, etc., the plurality of computers, circuits, etc. may be centrally arranged or distributed. May be good. For example, a computer or a circuit may be realized as a form in which each is connected via a communication network, such as a client-and-server system or a cloud computing system.

Although the invention of the present application has been described above with reference to the embodiment, the invention of the present application is not limited to the above embodiment. Various changes that can be understood by those skilled in the art can be made within the scope of the present invention in terms of the structure and details of the present invention.

Further, the direction of the arrow in the drawing shows an example, and does not limit the direction of the signal between the blocks.

10 Vehicle management device 11 Vehicle management terminal 12 Receiver 13 Judgment unit 14 Position generation unit 21 Cradle 22 Vehicle speed acquisition unit 23 Gyro sensor 100 Vehicle management device 110 Vehicle management terminal 113 Power supply circuit 114 Built-in battery 115 GPS reception circuit 116 Judgment circuit 117 position Generation circuit 118 CPU
119 Screen display 120 Memory 121 Wireless circuit 122 External interface 123 Short-range wireless circuit 125 Connector 210 Cradle 211 Vehicle speed acquisition circuit 212 Gyro sensor 213 Short-range wireless circuit 214 Circuit board 215 Rotating hinge 216 Wiring 217 Connector 220 Fixture 600 Computer 601 CPU
602 ROM
603 RAM
604 Program 605 Storage device 606 Storage medium 607 Drive device 608 Communication interface 609 Network 610 I / O interface 611 System bus

Claims (7)

With the cradle fixed in the vehicle,
It is detachable from the cradle, and the vehicle management terminal electrically connectable,
A power supply circuit that supplies the power of the built-in battery or the vehicle battery built in the vehicle management terminal to the vehicle management terminal, and
With
The cradle
It includes a vehicle speed acquisition unit that acquires a vehicle speed signal from the vehicle and a gyro sensor that detects a direction change of the vehicle and outputs a direction change signal.
The power supply circuit receives an ignition signal of the vehicle and an accessory power supply signal via the cradle, and the vehicle is based on the presence / absence of the ignition signal, the presence / absence of the accessory power supply signal, or a combination of the presence / absence of these signals. The power supply source to the vehicle management terminal is switched to the built-in battery or the vehicle battery based on the engine ON / OFF of the vehicle.
The vehicle management terminal is
A receiving circuit that receives radio waves from an artificial satellite and outputs a positioning signal, a position generator that generates position data of its own terminal based on at least the positioning signal, and electric power supplied from the vehicle battery via the cradle. Equipped with a determination unit that determines mounting on the cradle based on the voltage of
When the vehicle management terminal is mounted on the cradle, the position generator generates the position data based on the positioning signal, the vehicle speed signal, and the direction change signal.
When the vehicle management terminal is not mounted on the cradle, the position generator generates the position data based on the positioning signal.
Vehicle management device. The determination unit determines whether the cradle is mounted on the cradle based on the presence or absence of the direction change signal from the gyro sensor.
The vehicle management device according to claim 1. For the vehicle management terminal mounted on the cradle and in a power saving state
The power supply circuit
The built-in battery is used as a power supply source until the voltage value of the built-in battery reaches the charging stop voltage value at which charging of the built-in battery is stopped.
The vehicle battery is used as a power supply source until the voltage value of the built-in battery falls below the charging stop voltage value at which charging of the built-in battery is stopped and reaches the charging start voltage value at which charging of the built-in battery is started.
When the voltage value of the built-in battery falls below the charging start voltage value at which charging of the built-in battery is started, the power supply source of the vehicle battery is used, and the built-in battery is used until the charging stop voltage at which charging of the built-in battery is stopped is reached. To charge,
The vehicle management device according to claim 1 or 2. The vehicle management terminal and the cradle are each further provided with a short-range radio circuit, and the short-range radio circuit of the cradle provides the vehicle speed signal and the direction change signal to the short-range of the vehicle management terminal. Send to wireless circuit,
The vehicle management device according to any one of claims 1 to 3. The cradle includes a rotation mechanism that enables the vehicle management terminal to rotate with respect to the cradle at a connection point with the vehicle management terminal.
The vehicle management device according to any one of claims 1 to 4. The vehicle management terminal uses the power of the cradle fixed in the vehicle, the vehicle management terminal that is detachable and electrically connectable to the cradle, and the built-in battery or the vehicle battery built in the vehicle management terminal. a vehicle tube MakotoSo location control method comprising: a power supply circuit for supplying, to,
The cradle
A vehicle speed signal is acquired from the vehicle, a direction change of the vehicle is detected, and a direction change signal is output.
The power supply circuit receives an ignition signal and an accessory power supply signal of the vehicle via the cradle, and the vehicle is based on the presence / absence of the ignition signal, the presence / absence of the accessory power supply signal, or a combination of the presence / absence of these signals. The power supply source to the vehicle management terminal is switched to the built-in battery or the vehicle battery based on the engine ON / OFF of the vehicle.
The vehicle management terminal
Receives artificial satellite radio waves and outputs positioning signals,
Generate the position data of the own terminal based on at least the positioning signal,
The mounting on the cradle is determined based on the voltage of the electric power supplied from the vehicle battery via the cradle.
When the vehicle management terminal is mounted on the cradle, the position data is generated based on the positioning signal, the vehicle speed signal, and the direction change signal.
When the vehicle management terminal is not mounted on the cradle, the position data is generated based on the positioning signal.
How to control the vehicle management device. The vehicle management terminal uses the power of the cradle fixed in the vehicle, the vehicle management terminal that is detachable and electrically connectable to the cradle, and the built-in battery or the vehicle battery built in the vehicle management terminal. a vehicle tube MakotoSo location control program comprising: a power supply circuit for supplying, to,
The cradle
A vehicle speed signal is acquired from the vehicle, a direction change of the vehicle is detected, and a direction change signal is output.
The power supply circuit receives an ignition signal and an accessory power supply signal of the vehicle via the cradle, and the vehicle is based on the presence / absence of the ignition signal, the presence / absence of the accessory power supply signal, or a combination of the presence / absence of these signals. The power supply source to the vehicle management terminal is switched to the built-in battery or the vehicle battery based on the engine ON / OFF of the vehicle.
The vehicle management terminal
Receives artificial satellite radio waves and outputs positioning signals,
Generate the position data of the own terminal based on at least the positioning signal,
The mounting on the cradle is determined based on the voltage of the electric power supplied from the vehicle battery via the cradle.
When the vehicle management terminal is mounted on the cradle, the position data is generated based on the positioning signal, the vehicle speed signal, and the direction change signal.
A control program for a vehicle management device that causes a vehicle management device to generate the position data based on the positioning signal when the vehicle management terminal is not mounted on the cradle.

Images