JP2004215167A - Narrow-band communication instrument - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a narrow-band communication instrument which realizes lower power consumption. <P>SOLUTION: The narrow-band communication instrument is provided with a receiving circuit 102 for detecting preamble provided at the head of a communication frame and a startup trigger control circuit 103 for counting detection frequencies of the preamble detected by the receiving circuit 102 and for outputting a startup trigger signal when the detection frequencies reach preset frequencies, and starts a microprocessor 104 in a normal mode by which narrow-band communication becomes possible from a lower power consumption state on the basis of the startup trigger signal to be outputted by the startup trigger control circuit 103. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a short-range communication device that performs short-range communication with a wireless base station forming a communication area.
[0002]
[Prior art]
In recent years, non-stop automatic tolls that allow vehicles to pass through toll booths such as highways without stopping, while communicating with the communication system mounted on the vehicle at that time, An ETC system has been put to practical use. The ETC system uses a Dedicated Short Range Communication (DSRC) system (hereinafter, referred to as a DSRC system). The DSRC method is a communication method performed in a small communication area, and is a method for performing communication for payment of a fee during a very short time when a vehicle or the like passes through the communication area.
[0003]
With a DSRC device that performs communication using the conventional DSRC method, even if the vehicle is not near a tollgate or an interchange, communication can be performed immediately in response to a data reception request from a wireless base station installed at the tollgate or the interchange The DSRC device is always operated so that For this reason, in the conventional DSRC device, an increase in power consumption other than during DSRC communication has been a serious problem in practical use.
[0004]
As a technique for reducing the power consumption, a device combining a position detection device and a DSRC device has been proposed. In this device, when a vehicle equipped with the device is traveling on a highway, the position detection device is operated and the operation of the DSRC device is stopped. Then, when the position detecting device detects that a toll booth or the like is present in the vicinity, the operation of the DSRC device is started. As described above, since the DSRC device is operated only when the vehicle comes near the tollgate, it is possible to reduce the power consumption of the DSRC device except during DSRC communication (for example, see Patent Document 1).
[0005]
[Patent Document 1]
JP 2001-99659 A
[Problems to be solved by the invention]
However, the above-mentioned conventional device relates to a device in which a position detecting device and a DSRC device are combined, and no means has been proposed for solving the problem of power consumption as a single DSRC device.
[0007]
An object of the present invention is to solve the above-mentioned conventional problems, and an object of the present invention is to provide a short-range communication device capable of realizing low power consumption.
[0008]
[Means for Solving the Problems]
A short-range communication device according to the present invention is a short-range communication device having control means for controlling short-range communication performed with a wireless base station forming a communication area, wherein the short-range communication data is transmitted from the wireless base station. And detecting means for detecting a preamble from the data frame of the received short-range communication data, and for activating the control means when the number of times the preamble is detected by the detecting means reaches a predetermined number. Signal output means for outputting a signal.
[0009]
With this configuration, when the number of times that the preamble is detected from the data frame of the narrow-area communication data reaches a predetermined number, the control unit that controls the narrow-area communication performed with the wireless base station is activated. At times other than the time of communication, it is possible to keep the control means in a low power consumption state or a non-operation state. Therefore, it is possible to reduce power consumption other than during the short-range communication with the wireless base station.
[0010]
A short-range communication device according to the present invention is a short-range communication device having control means for controlling short-range communication performed with a wireless base station forming a communication area, wherein the short-range communication data is transmitted from the wireless base station. And detecting means for detecting a unique word from the data frame of the received short-range communication data, and activating the control means when the number of times the unique word is detected by the detecting means reaches a predetermined number. Signal output means for outputting a signal for the
[0011]
With this configuration, when the number of times a unique word is detected from the data frame of the narrow-area communication data reaches a predetermined number, the control unit that controls the narrow-area communication performed with the wireless base station is activated. At times other than the area communication, the control means can be set to the low power consumption state or the inoperative state. Therefore, it is possible to reduce power consumption other than during the short-range communication with the wireless base station.
[0012]
A short-range communication device according to the present invention is a short-range communication device having control means for controlling short-range communication performed with a wireless base station forming a communication area, wherein the short-range communication data is transmitted from the wireless base station. Storage means for storing a data signal included in the data frame of the received short-range communication data, and when the number of storages of the data signal by the storage means reaches a predetermined number, the control means Signal output means for outputting a signal for activation.
[0013]
With this configuration, when the number of times the data signal is stored reaches the predetermined number, the control unit that controls the short-range communication with the radio base station is activated. The means can be in a low power consumption state or a non-operation state. Therefore, it is possible to reduce power consumption other than during the short-range communication with the wireless base station.
[0014]
A short-range communication device according to the present invention is a short-range communication device having control means for controlling short-range communication performed with a wireless base station forming a communication area, wherein the short-range communication data is transmitted from the wireless base station. Receiving means, a first detecting means for detecting a preamble from a data frame of the narrow area communication data received by the receiving means, and a unique word from a data frame of the narrow area communication data received by the receiving means. A second detection unit for detecting the preamble, a storage unit for storing a data signal included in a data frame of the short-range communication data received by the reception unit, a number of times the preamble is detected by the first detection unit, Each of at least one of the number of times the unique word is detected by the second detection means and the number of times the data signal is stored by the storage means is When it reaches the number, and a signal output means for outputting a signal for activating the control means.
[0015]
With this configuration, it is possible to set the control unit to a low power consumption state or a non-operation state other than during the short-range communication.
Further, the control unit is controlled based on at least one of the number of preamble detections by the first detection unit, the number of unique word detections by the second detection unit, and the number of data signal storages by the storage unit. Since the signal for starting is output, the reliability of the device can be improved.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a block diagram illustrating a configuration of a short range communication (DSRC) device according to the first embodiment of the present invention. The DSRC device 100 is mounted on a vehicle such as a passenger car and performs short-range communication with a roadside device (wireless base station) installed at a tollgate on an expressway or the like. 102, a start trigger control circuit 103, and a microprocessor 104.
[0017]
The receiving circuit 102 receives, via the antenna 101, data for short-range communication (data having a frame configuration used in DSRC) transmitted from the roadside device. In addition, it analyzes the frame configuration of the received narrow-area communication data and, when detecting a preamble included in the data frame of the narrow-area communication data, activates a preamble detection signal indicating that the preamble has been detected. Output to the circuit 103.
[0018]
The start trigger control circuit 103 outputs a start trigger signal to the microprocessor 104 when the number of receptions of the preamble detection signal output from the reception circuit 102 reaches a predetermined number (at least once).
[0019]
The microprocessor 104 is in the low power consumption mode or the non-operation mode except when performing short-range communication with the roadside device. Also, the microprocessor 104 shifts from the low power consumption mode to the normal mode (a mode in which sufficient power is supplied for performing short-range communication) only when receiving a startup trigger signal from the startup trigger control circuit 103. And performs data processing of narrow-area communication data and performs narrow-area communication control with the roadside device.
[0020]
Next, the operation of the DSRC device 100 configured as described above will be described.
When the vehicle approaches the tollgate and narrow-area communication data is sent from the roadside device, the narrow-area communication data is input to the receiving circuit 102. The receiving circuit 102 analyzes the frame configuration of the short-range communication data received from the roadside device. Note that the data frame structure used in the DSRC is composed of one trigger slot including a preamble and a plurality of data slots following the trigger slot. The receiving circuit 102 detects the preamble at the top of the data frame, and outputs a preamble detection signal to the activation trigger control circuit 103.
[0021]
The activation trigger control circuit 103 counts the number of receptions of the preamble detection signal output from the reception circuit 102, and outputs an activation trigger signal to the microprocessor 104 when the counted number of receptions reaches a predetermined number. The microprocessor 104 that has received the activation trigger signal is activated by shifting from the low power consumption mode to the normal mode, receives necessary and sufficient power from a power supply (not shown), and controls the short-range communication with the roadside device. Do.
[0022]
As described above, the DSRC apparatus of the present embodiment recognizes that the narrow-area communication data having the frame structure used in the DSRC has been received based on the number of times the preamble included in the narrow-area communication data has been detected, and at the same time, Can be started in the normal mode. For this reason, when it is not necessary to perform the short-range communication (i.e., when the short-range communication data is not received), the microprocessor can be kept in low power consumption or in an inactive state. Therefore, it is possible to reduce the power consumption other than during the short-range communication.
[0023]
(Second embodiment)
FIG. 2 is a block diagram illustrating a configuration of a short range communication (DSRC) device according to the second embodiment of the present invention. The DSRC device 200 is mounted on a vehicle such as a passenger car and performs short-range communication with a roadside device or the like installed at a tollgate or the like on an expressway. The DSRC device 200 includes an antenna 201, a receiving circuit 202, and a start trigger control. The circuit includes a circuit 203 and a microprocessor 204.
[0024]
The receiving circuit 202 receives the short-range communication data transmitted from the roadside device via the antenna 201. In addition, while analyzing the frame configuration of the data used in the DSRC, a unique word included in the data frame of the narrow-area communication data is detected, and when a unique word is detected, it indicates that the unique word has been detected. The unique word detection signal is output to the start trigger control circuit 203.
[0025]
The activation trigger control circuit 203 outputs an activation trigger signal to the microprocessor 204 when the number of receptions of the unique word detection signal output from the reception circuit 202 reaches a predetermined number (at least once). The microprocessor 204 is in the low power consumption mode or the non-operation mode except when performing the short-range communication with the roadside device.
[0026]
Further, the microprocessor 204 shifts from the low power consumption mode to the normal mode (a mode in which sufficient power is supplied for performing short-range communication) only when receiving a start trigger signal from the start trigger control circuit 203. And performs data processing of narrow-area communication data and performs narrow-area communication control with the roadside device.
[0027]
Next, the operation of the DSRC device 200 configured as described above will be described.
When the vehicle approaches the tollgate and narrow-area communication data is sent from the roadside device, the narrow-area communication data is input to the receiving circuit 202. The receiving circuit 202 analyzes the frame configuration of the short-range communication data received from the roadside device. In the data frame used in the DSRC, a unique word of a bit pattern is arranged in a specific position in advance, and the receiving circuit 202 detects the unique word in the data frame and generates a unique word detection signal to activate the trigger control circuit. Output to 203.
[0028]
The activation trigger control circuit 203 counts the number of receptions of the unique word detection signal output from the reception circuit 202, and outputs an activation trigger signal to the microprocessor 204 when the counted number of receptions reaches a predetermined number. The microprocessor 204 that has received the activation trigger signal is activated by shifting from the low power consumption mode to the normal mode, receives necessary and sufficient power from a power supply (not shown), and controls the short-range communication with the roadside device. Do.
[0029]
As described above, the DSRC apparatus according to the present embodiment recognizes that the narrow-area communication data having the frame structure used in the DSRC has been received based on the number of times of detection of the unique word included in the narrow-area communication data. The processor can be started in the normal mode. For this reason, when it is not necessary to perform the short-range communication (i.e., when the short-range communication data is not received), the microprocessor can be kept in low power consumption or in an inactive state. Therefore, it is possible to reduce the power consumption other than during the short-range communication.
[0030]
(Third embodiment)
FIG. 3 is a block diagram showing a configuration of a short range communication (DSRC) device according to a third embodiment of the present invention. The DSRC device 300 is mounted on a vehicle such as a passenger car and performs short-range communication with a roadside device or the like installed at a tollgate or the like on an expressway, and includes an antenna 301, a receiving circuit 302, and a start trigger control. The circuit includes a circuit 303, a microprocessor 304, and a memory 305.
[0031]
The receiving circuit 302 receives the short-range communication data transmitted from the roadside device via the antenna 301, analyzes the frame configuration of the received short-range communication data, and performs the analysis in the data frame of the short-range communication data. The data signal which is the data slot of is extracted. Further, the extracted data signal is stored in the memory 305, the data signal is stored in the memory 305, and a reception completion signal indicating that the reception of the data signal is completed is output to the activation trigger control circuit 303.
[0032]
The activation trigger control circuit 303 receives the reception completion signal from the reception circuit 302, counts the number of times the reception completion signal is received, and, when the number of times the reception completion signal is received reaches a predetermined number (at least once), An activation trigger signal is output to the microprocessor 304.
[0033]
The microprocessor 304 is in the low power consumption mode or the non-operation mode except when performing short-range communication with the roadside device. Also, the microprocessor 304 shifts from the low power consumption mode to the normal mode (mode in which sufficient power for performing short-range communication) and starts only when receiving the start trigger signal from the start trigger control circuit 303. Then, data processing of narrow-area communication data and the like are performed, and narrow-area communication control with the roadside device is performed.
[0034]
Next, the operation of the DSRC device 300 configured as described above will be described.
When the vehicle approaches the tollgate and narrow-area communication data is sent from the roadside device, the narrow-area communication data is input to the receiving circuit 302. The receiving circuit 302 analyzes the frame configuration of the short-range communication data received from the roadside device. The receiving circuit 302 extracts a data signal, which is a data slot separated from the trigger slot, from the frame configuration of the data for the short range communication, stores the data signal in the memory 305, and outputs a reception completion signal to the activation trigger control circuit 303 I do.
[0035]
The activation trigger control circuit 303 counts the number of receptions of the reception completion signal output from the reception circuit 302, and outputs an activation trigger signal to the microprocessor 304 when the counted number of receptions reaches a predetermined number. The microprocessor 304 that has received the activation trigger signal is activated by shifting from the low power consumption mode to the normal mode, receives necessary and sufficient power from a power supply (not shown), and controls the short-range communication with the roadside device. Do.
[0036]
As described above, the DSRC apparatus according to the present embodiment indicates that the reception of the narrow-area communication data used in the DSRC has been completed by the reception completion indicating that the data signal in the data frame of the narrow-area communication data has been stored in the memory 305. Recognition can be performed based on the number of signal receptions, and at the same time, the microprocessor can be started in the normal mode. For this reason, when it is not necessary to perform the short-range communication (i.e., when the short-range communication data is not received), the microprocessor can be kept in low power consumption or in an inactive state.
[0037]
In addition, since the microprocessor can be activated after the data signal is stored in the memory 305, the time during which the microprocessor is in the low power consumption mode can be extended, and the first or second embodiment can be used. A DSRC device with lower power consumption than the described device can be provided.
[0038]
(Fourth embodiment)
FIG. 4 is a block diagram illustrating a configuration of a DSRC device according to a fourth embodiment of the present invention. The DSRC device 400 is mounted on a vehicle such as a passenger car and performs short-range communication with a roadside device or the like installed at a tollgate or the like on an expressway. The DSRC device 400 includes an antenna 401, a receiving circuit 402, and a start trigger control. The circuit includes a circuit 403, a microprocessor 404, and a memory 405.
[0039]
The receiving circuit 402 has all the functions of the receiving circuits 101, 201, and 301 described in the first to third embodiments, and receives the short-range communication data transmitted from the roadside device via the antenna 401. Then, while analyzing the frame configuration of the received short-range communication data, the data signal which is a data slot in the data frame of the short-range communication data is extracted, and the extracted data signal is stored in the memory 405. After the data signal is stored in the memory 405, a reception completion signal is output to the activation trigger control circuit 403.
[0040]
Further, the receiving circuit 402 detects a preamble and a unique word included in the data frame of the narrow-area communication data, and outputs a preamble detection signal and a unique word detection signal to the activation trigger control circuit 403.
[0041]
The activation trigger control circuit 403 outputs an activation trigger signal to the microprocessor 404 when each of at least one of the three signals output from the reception circuit 402 reaches a predetermined number.
[0042]
The microprocessor 404 is in the low power consumption mode or the non-operation mode except when performing short-range communication with the roadside device. Also, the microprocessor 404 shifts from the low power consumption mode to the normal mode (a mode in which sufficient power for performing short-range communication is received) and starts only when receiving the start trigger signal from the start trigger control circuit 403. Then, data processing of narrow-area communication data and the like are performed, and narrow-area communication control with the roadside device is performed.
[0043]
Next, the operation of the DSRC device 400 configured as described above will be described. The operation until the receiving circuit 402 outputs the preamble detection signal, the unique word detection signal, and the reception completion signal to the activation trigger control circuit 403 is the same as that described in the first to third embodiments. Is omitted.
[0044]
In the DSRC device 400, the activation trigger control circuit 403 counts the number of receptions of each of the three signals output from the reception circuit 402, and when each of at least one of the three signals reaches the predetermined number of times. Then, a start trigger signal is output to the microprocessor 404.
[0045]
The microprocessor 404 that has received the activation trigger signal is activated by shifting from the low power consumption mode to the normal mode, receives necessary and sufficient power from a power supply (not shown), and controls the short-range communication with the roadside device. Do.
[0046]
As described above, according to the present embodiment, the microprocessor 404 is set to the normal mode only when each of at least one of the preamble detection signal, the unique word detection signal, and the reception completion signal reaches a predetermined number. Since it is activated, it is possible to reduce power consumption at times other than during short-range communication.
[0047]
Further, for example, even if two signals are not output for some reason despite receiving the short-range communication data, the microprocessor 404 is activated by outputting the remaining one signal. Therefore, the reliability of the device can be improved.
[0048]
Also, when each of the three signals reaches a predetermined number of times so that the start trigger control circuit does not erroneously output the start trigger signal when any of the three signals is erroneously output due to noise or the like. It is also possible to output a start trigger signal only in the case of the first embodiment, so that the reliability of the device can be improved.
[0049]
【The invention's effect】
According to the present invention, it is possible to provide a short-range communication device capable of realizing low power consumption.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of a short-range communication device according to a first embodiment of the present invention.
FIG. 2 is a block diagram illustrating a configuration of a short-range communication device according to a second embodiment of the present invention.
FIG. 3 is a block diagram illustrating a configuration of a short-range communication device according to a third embodiment of the present invention.
FIG. 4 is a block diagram illustrating a configuration of a short-range communication device according to a fourth embodiment of the present invention.
[Explanation of symbols]
101, 201, 301, 401 DSRC device 102, 202, 302, 402 Receiving circuit 103, 203, 303, 403 Start trigger control circuit 104, 204, 304, 404 Microprocessor 305, 405 Memory

Claims (4)

A narrow-area communication device having control means for controlling short-range communication performed with a wireless base station constituting a communication area,
Detecting means for receiving narrow-area communication data from the wireless base station, and detecting a preamble from a data frame of the received narrow-area communication data,
A signal output unit that outputs a signal for activating the control unit when the number of times the preamble is detected by the detection unit reaches a predetermined number. A narrow-area communication device having control means for controlling short-range communication performed with a wireless base station constituting a communication area,
Detecting means for receiving narrow-area communication data from the wireless base station, and detecting a unique word from a data frame of the received narrow-area communication data,
A signal output unit that outputs a signal for activating the control unit when the number of times of detection of the unique word by the detection unit reaches a predetermined number. A narrow-area communication device having control means for controlling short-range communication performed with a wireless base station constituting a communication area,
Storage means for receiving data for a short-range communication from the wireless base station, and storing a data signal included in a data frame of the received data for a short-range communication,
A signal output unit that outputs a signal for activating the control unit when the number of storages of the data signal by the storage unit reaches a predetermined number. A narrow-area communication device having control means for controlling short-range communication performed with a wireless base station constituting a communication area,
Receiving means for receiving data for short-range communication from the wireless base station,
First detecting means for detecting a preamble from a data frame of the data for short-range communication received by the receiving means;
Second detection means for detecting a unique word from a data frame of the data for short-range communication received by the reception means,
Storage means for storing a data signal included in the data frame of the data for short-range communication received by the receiving means,
At least one of the number of times the preamble has been detected by the first detection means, the number of times the unique word has been detected by the second detection means, and the number of times the data signal has been stored by the storage means has reached a predetermined number. A signal output unit that outputs a signal for activating the control unit in such a case.

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