JP2005117414A - Dsrc mobile station - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a DSRC mobile station having a power saving function without causing the reliability of a system and without causing a cost increase in the system. <P>SOLUTION: A control microcomputer 7 for transmitting and receiving data to/from the DSRC base station 1 via an RF part 5 in a normal operation mode is shifted from a power saving mode to the normal operation mode by a data interrupt signal by reception of a receiving part 3 and is shifted to the power saving mode when communication with the DSRC base station 1 in response to the data interrupt signal is finished. A power saving mode and a normal operation mode of the RF part and a protocol processing part 6 are controlled in accordance with switching of the power saving mode and the normal operation mode, power feeding from a power source 8 is stopped in the power saving mode in a transmitting part 4 and the protocol processing part 6, and the receiving part 3 is set in prescribed receiving sensitivity in the normal operation mode and set in receiving sensitivity higher than the prescribed receiving sensitivity in the power saving mode. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an in-vehicle DSRC mobile station that uses DSRC (Dedicated Short Range Communication) communication.

As a system using DSRC communication, a system for collecting tolls at a toll road toll booth (generally referred to as ETC) is well known. In this type of DSRC communication system, radio communication is performed between the ETC roadside equipment (DSRC base station) on the toll gate side and the ETC on-board unit (DSRC mobile station) on the vehicle side to automatically charge the toll road usage fee. To receive.
The power consumption of these ETC on-board units (DSRC mobile stations) is preferably suppressed as much as possible due to problems such as heat generation and battery consumption due to power consumption. Therefore, an ETC on-board unit (DSRC mobile station) with a function of waiting in a power saving mode until it reaches or approaches a communication area, or an ETC on-board unit (DSRC mobile station) with a function of turning on the power only when communication is possible Many mobile stations have been proposed.

For example, in “ETC on-vehicle device” of Patent Document 1, an on-vehicle device that saves power consumption of the on-vehicle device by activating the protocol processing unit only when data is received from a roadside device is exemplified.
In addition, “on-vehicle device used in an automatic fee collection system” in Patent Document 2 exemplifies an on-vehicle device that reduces power consumption by turning on the power only when an IC card is inserted.
Further, in “Paper communication device and communication method thereof” in Patent Document 3 and “Position detection device with DSRC function and control method thereof” in Patent Document 4, a roadside device is obtained based on position information of a car navigation system or GPS (Global Positioning System). An on-vehicle device that saves power consumption by switching between a standby mode and a normal mode by obtaining information such as the presence or absence and the type is exemplified.
On the other hand, as shown in Patent Document 5, “Wireless Automatic Recognition Terminal and Communication Method with the Device”, a means for informing a communication area in advance such as a beacon is provided to switch from the super power saving mode to the communication mode. In-vehicle devices are also proposed.

JP 2000-90312 A (pages 5-6, FIG. 1) JP 2000-353260 A (pages 2 and 3, FIG. 1) JP 2002-260034 A (pages 3 to 4, FIG. 1) JP 2001-99659 A (pages 4 to 6, FIG. 3) Japanese Patent Laid-Open No. 11-134527 (pages 4-5, FIG. 2)

  In a system such as ETC, the ETC on-board unit (DSRC mobile station) enters the communication area of the ETC roadside unit (DSRC base station), and the ETC on-board unit (DSRC mobile station) becomes communicable. Communication must be completed in the period before leaving the communication area. Since the time required for data communication for executing automatic fee collection includes a retry time when a communication data error occurs, it changes depending on the radio wave environment, and the required communication time changes. This indicates that if the period during which the ETC on-board device is in a communicable state is shortened, the possibility of completing data communication for executing automatic toll collection is reduced, and the reliability of the system is lowered.

In the vehicle-mounted device that saves power consumption of the vehicle-mounted device by activating the protocol processing unit at the time of data reception from the roadside device exemplified in Patent Document 1, the activation of the protocol processing unit is completed after receiving the data Thus, since a predetermined time is required until the communication becomes possible, the period in which the communication is possible becomes shorter compared with the vehicle-mounted device that is always operating in the normal mode. That is, there is a problem that the reliability of the system is lowered as compared with the vehicle-mounted device that is always operating in the normal mode.
On the other hand, Patent Document 2 proposes an in-vehicle device having a function of turning on a power supply only when an IC card is inserted. According to this method, the above-mentioned problem does not occur. However, in recent years, DSRC communication systems are also used in applications that do not use IC cards. For example, an entrance / exit management system for a parking lot using DSRC communication has been put into practical use. In this system, entrance / exit management is performed using ID information stored in a vehicle-mounted device (mobile station) body. In such a system, the function of turning on the power only when the IC card is inserted as described above cannot be used.

In Patent Document 3 and Patent Document 4, information such as the presence / absence or type of a roadside device is obtained from the position information of the car navigation system or GPS, and the power saving mode and the normal mode are switched. Since a position detection device such as GPS is required, it cannot be used by a vehicle-mounted device alone, so that the cost of the system increases.
As shown in Patent Document 5, there is a method of providing a means such as a beacon in advance to notify the entry into the communication area. However, it is necessary to provide such a means for all road devices (DSRC base stations), and the entire system It is not realistic considering the cost of.

  The present invention has been made to solve the above-described problems, and does not incur system reliability, is not limited to application using an IC card, and increases the cost of the system. It is an object of the present invention to obtain a DSRC mobile station having a power saving function without incurring power consumption.

  The DSRC mobile station according to the present invention includes a receiving unit that receives a reception signal from a DSRC base station and a transmission unit that transmits a transmission signal to the DSRC base station, and performs RF communication with the DSRC base station. Part, a power saving mode and a normal operation mode. In the normal operation mode, the microcomputer is arranged between the RF microcomputer and the control microcomputer for transmitting / receiving data to / from the DSRC base station via the RF unit, and the RF A protocol processing unit that extracts the received data from the reception signal of the unit and forms a transmission signal from the transmission data from the control microcomputer, and a power source that supplies power to the RF unit, the protocol processing unit, and the control microcomputer. At the time when the communication with the DSRC base station is completed by switching from the power saving mode to the normal operation mode by the data interrupt signal received by the unit The mode is shifted to the power mode, and the power saving mode and the normal operation mode of the RF unit and the protocol processing unit are controlled according to the switching between the power saving mode and the normal operation mode. The power supply from is stopped, and the receiving unit is set to a predetermined receiving sensitivity in the normal operation mode and set to a receiving sensitivity higher than the predetermined receiving sensitivity in the power saving mode.

  As described above, the present invention includes a receiving unit that receives a reception signal from a DSRC base station and a transmission unit that transmits a transmission signal to the DSRC base station, and performs radio wave communication with the DSRC base station. Part, a power saving mode and a normal operation mode. In the normal operation mode, the microcomputer is arranged between the RF microcomputer and the control microcomputer for transmitting / receiving data to / from the DSRC base station via the RF unit, and the RF A protocol processing unit that extracts the received data from the reception signal of the unit and forms a transmission signal from the transmission data from the control microcomputer, and a power source that supplies power to the RF unit, the protocol processing unit, and the control microcomputer. When the communication with the DSRC base station is completed when the mode is changed from the power saving mode to the normal operation mode by the data interrupt signal received by the unit. And the power saving mode and the normal operation mode of the RF unit and the protocol processing unit are controlled in accordance with the switching between the power saving mode and the normal operation mode. Since the power supply is stopped and the receiving unit is set to a predetermined receiving sensitivity in the normal operation mode and set to a receiving sensitivity higher than the predetermined receiving sensitivity in the power saving mode, the receiving sensitivity of the receiving unit in the power saving mode is set. Is set higher than the predetermined sensitivity, and the normal operation mode is entered before entering the communication area, so that the same communication time as that of the DSRC mobile station that is always in the normal operation mode can be secured, thereby avoiding a decrease in communication reliability. be able to.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a DSRC mobile station according to Embodiment 1 of the present invention.
In FIG. 1, a DSRC base station 1 communicates with a DSRC mobile station 2 by radio waves. The DSRC mobile station 2 includes the following 3 to 8.
The receiving unit 3 receives radio waves from the DSRC base station 1. The receiving unit 3 is always supplied with power, is set to a predetermined reception sensitivity defined in the DSRC communication standard in the normal operation mode, and is higher than a predetermined reception sensitivity defined in the DSRC communication standard in the power saving mode. Set to The transmission unit 4 transmits radio waves to the DSRC base station 1. The receiving unit 3 and the transmitting unit 4 constitute an RF unit 5.
The protocol processing unit 6 takes out the data content included in the reception signal from the reception unit 3 as accurate reception data RD, inputs it to the control microcomputer 7, and processes the transmission data TD from the control microcomputer 7 into a transmission signal. Output to the transmitter 4. The control microcomputer 7 controls the reception unit 3, the transmission unit 4, and the protocol processing unit 6. The power supply 8 supplies power to the RF unit, the protocol processing unit 6 and the control microcomputer 7.
FIG. 2 is a flowchart showing the operation of the control microcomputer of the DSRC mobile station according to Embodiment 1 of the present invention.

Next, the operation will be described.
The DSRC base station 1 outputs a radio wave inquiring about the presence / absence of the DSRC mobile station 2 to the DSRC mobile station 2 in order to confirm the presence / absence of the DSRC mobile station 2 in the DSRC base station communication area. When the DSRC mobile station 2 receives this radio wave, the DSRC mobile station 2 returns a response notifying the presence and starts communication.
The receiving unit 3 receives a radio wave from the DSRC base station 1, converts it into a digital signal and outputs it to the protocol processing unit 6. When receiving the radio wave from the DSRC base station 1, the receiving unit 3 sends a data interrupt signal to the control microcomputer. 7 is output. In addition, a reception sensitivity setting signal Sr set to a high sensitivity instruction is input from the control microcomputer 7 in the power saving mode, and the reception sensitivity is set based on this signal.
The transmission unit 4 processes the digital signal input from the protocol processing unit 6 and transmits it to the DSRC base station 1. A signal St indicating the power saving mode is input from the control microcomputer 7. In this power saving mode, the power supply to the transmission unit 4 is stopped to suppress power consumption.

The protocol processing unit 6 outputs the data content included in the reception signal from the DSRC base station 1 to the control microcomputer 7 as accurate reception data RD, and processes the transmission data TD from the control microcomputer 7 to the transmission unit 4. Output. A signal Sp indicating the power saving mode is input from the control microcomputer 7. In this power saving mode, the power supply to the protocol processing unit 6 is stopped to suppress power consumption.
When the control microcomputer 7 is turned on, the signal St to the transmission unit 4 and the signal Sp to the protocol processing unit 6 indicate a power saving mode, and the reception sensitivity setting signal Sr to the reception unit 3 indicates a high sensitivity level. In addition, after performing initialization processing such as setting each, the device itself enters the power saving mode.

Next, the operation of the control microcomputer will be described with reference to FIG.
In step S1, when the receiving unit 3 receives a radio wave from the DSRC base station 1 and a data interrupt signal is input to the control microcomputer 7 (when the determination in step S1 is Yes), the control microcomputer 7 is activated ( Step S2). Next, 1 is added to the activation number counter (step S3). The activation counter is set to 0 when the power is turned on. In step S4, when the value of the activation number counter is larger than the predetermined number, the normal operation mode is entered, the activation number counter is cleared, that is, set to 0 (step S5), and the transmission unit 4 and the protocol processing unit 6 are activated. (Process of step S6). On the other hand, if the activation number counter is equal to or smaller than the predetermined number, the power saving mode is restored (step S12).
When the transmission unit 4 and the protocol processing unit 6 are activated in step S6, the count value of the communication end timer is initialized (step S7), and the communication processing step S8 is started. The communication end timer is used to return to the power saving mode when communication is not performed for a predetermined time.

In step S9, when it is determined that the communication is finished, the process proceeds to step S12 and returns to the power saving mode. On the other hand, if it is not the end of communication, it is determined in step S10 whether or not any data is received by the receiving unit 3 in the communication process of step S8, and if any data is received, the communication end timer of step S7 is set. A series of processing is executed again from the count value initialization processing.
If no data has been received, it is determined in step S11 whether or not the value of the communication end timer has exceeded a predetermined time, and if it has exceeded the predetermined time, the process proceeds to step S12 to enter the power saving mode. Return. If it is within the predetermined time, a series of processing is executed again from the communication processing in step S8.

According to the first embodiment, the reception sensitivity is set higher than a predetermined sensitivity in the power saving mode, and is shifted to the normal operation mode before entering the communication area, thereby being the same as the DSRC mobile station that is always in the normal operation mode. A communication time can be secured and a decrease in communication reliability can be avoided.
In addition, the control microcomputer determines that communication has been completed when communication has not been performed for a predetermined time in the normal operation mode, and shifts to the power saving mode, so it exits the communication area before communication is completed. It is possible to prevent wasteful power consumption without being switched to the power saving mode.
In addition, when the control microcomputer receives a data interrupt signal from the receiving unit a predetermined number of times, the control microcomputer shifts from the power saving mode to the normal operation mode. To prevent the receiving unit from being easily affected by external noise, causing an erroneous data interrupt signal to be output, and unnecessarily shifting to the normal operation mode, causing unnecessary power consumption. Can do.

It is a block diagram which shows the DSRC mobile station by Embodiment 1 of this invention. It is a flowchart which shows operation | movement of the control microcomputer of the DSRC mobile station by Embodiment 1 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 DSRC base station 2 DSRC mobile station 3 Reception part 4 Transmission part 5 RF part 6 Protocol processing part 7 Control microcomputer 8 Power supply.

Claims (4)

  An RF unit that has a reception unit that receives a reception signal from a DSRC base station and a transmission unit that transmits a transmission signal to the DSRC base station, and performs radio wave communication with the DSRC base station, a power saving mode, and a normal operation A control microcomputer that transmits and receives data to and from the DSRC base station via the RF unit in the normal operation mode, and is disposed between the RF unit and the control microcomputer and receives the RF unit. A protocol processing unit that extracts received data from the signal and forms a transmission signal from transmission data from the control microcomputer; and a power source that supplies power to the RF unit, the protocol processing unit, and the control microcomputer. In response to the data interrupt signal received by the receiver, the power saving mode is shifted to the normal operation mode, and communication with the DSRC base station is performed. When the power saving mode and the normal operation mode are switched, the power saving mode and the normal operation mode of the RF unit and the protocol processing unit are controlled according to the switching between the power saving mode and the normal operation mode. The processing unit stops power supply from the power source in the power saving mode, and the receiving unit is set to a predetermined reception sensitivity in the normal operation mode, and receives higher than the predetermined reception sensitivity in the power saving mode. A DSRC mobile station characterized by being set to sensitivity.   The DSRC mobile station according to claim 1, wherein the control microcomputer shifts to a power saving mode when communication is not performed for a predetermined time in the normal operation mode.   3. The DSRC movement according to claim 1, wherein the control microcomputer shifts from the power saving mode to the normal operation mode when the data interrupt signal from the receiving unit is received a predetermined number of times. Bureau. 4. The DSRC mobile station according to claim 1, wherein the control microcomputer initializes the RF unit and the protocol processing unit to enter a power saving mode when the power is turned on.

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