JP2011168099A - Tire air pressure monitoring system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a tire air pressure monitoring system improving reliability of radio communication between a monitoring device installed in a vehicle and sensor units installed in individual wheels. <P>SOLUTION: The tire air pressure monitoring system includes: the sensor units U1-U4 for transmitting response signals containing air pressure information; and the monitoring device 10 by which, upon receipt of the response signals, the air pressure information contained in the response signals is displayed on an indicator 13. Here, upon receipt of an instruction signal transmitted from the monitoring device 10, the sensor units U1-U4 determine randomly a delay time, namely from an activation signal receiving point to the start of transmission of the response signals, and then transmits the response signals after standby for the determined delay time. If the monitoring device 10 detects interference of the response signals when the instruction signal is transmitted to the sensor units U1-U4, the monitoring device retransmits the instruction signal to the sensor units U1-U4. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a tire air pressure monitoring system that monitors the air pressure of a tire of each wheel provided in a vehicle.

  In recent years, a so-called direct tire pressure monitoring system that directly monitors tire air pressure through a sensor unit provided on each wheel of a vehicle and warns a driver when an abnormality is detected in the tire air pressure. (TPMS: Tire Pressure Monitoring System) is well known. If this tire pressure monitoring system is installed in a vehicle, the driver can detect an abnormality in tire air pressure at an early stage, so that for example, the ride comfort and fuel consumption of the vehicle can be kept good, and the tread can be maintained. It is possible to prevent the peeling of the tire and the burst of the tire.

  By the way, this tire air pressure monitoring system initially warns when an abnormality is detected in any of the air pressures detected through sensors provided on each wheel. That is, a warning is given when an abnormality occurs in the air pressure of any tire without specifying a tire in which an abnormality in air pressure has occurred. On the other hand, in recent years, there has been a demand for a system in which a driver can discriminate a tire in which an abnormality has occurred in order to quickly and accurately take measures against a tire in which an abnormality in air pressure has occurred. is there. Conventionally, as such a tire pressure monitoring system, for example, a system described in Patent Document 1 is known.

  In the tire pressure monitoring system described in Patent Document 1, an initiator is provided in front of the vehicle, and an activation signal is transmitted from the initiator to the right front wheel and the left front wheel of the vehicle. When the sensor unit of each wheel receives this activation signal, it detects the tire air pressure through a built-in air pressure sensor and also detects the direction of each wheel through a built-in electronic compass. The sensor unit of each wheel generates a response signal including information on the detected tire air pressure and the direction of each wheel, and waits for a random time from the time when the start signal is received, and then generates the response signal. Is transmitted to the monitoring device provided in the vehicle. When the monitoring device receives the response signal, the monitoring device detects the azimuth of the vehicle through a built-in electronic compass, and compares the detected azimuth of the vehicle with the azimuth of each wheel included in the response signal. The monitoring device determines whether the response signal is transmitted from the right front wheel or the left front wheel based on the comparison result, and further includes the tire included in the response signal based on the determination result. Is displayed on the indicator as information on the air pressure of the tires of the right front wheel and the left front wheel. In this tire pressure monitoring system, an initiator is also provided at the rear of the vehicle, and a similar communication process is performed by transmitting an activation signal from the initiator to the right rear wheel and the left rear wheel of the vehicle.

  According to such a configuration, it is possible to display the tire pressure information of each wheel on the indicator separately while adopting a simple configuration in which initiators are respectively provided in front and rear of the vehicle, so that the driver can It becomes possible to discriminate the tire in which the occurrence has occurred. Moreover, since transmission of the response signal by each sensor unit is performed when a random time has elapsed since each sensor unit received the activation signal, interference of the response signal can be suppressed. Accordingly, it is possible to accurately ensure the reliability of wireless communication between the monitoring device and the sensor unit.

JP 2008-273477 A

  By the way, as in the tire pressure monitoring system described in Patent Document 1, the response signal is transmitted by each sensor unit when each sensor unit receives a start signal and a random time has elapsed. If only the waiting time of each sensor unit happens to be the same, there is a possibility that interference of response signals may occur. In addition, even when the standby times of the sensor units are not completely the same, when the difference between the standby times is very small, the timings at which the response signals are transmitted by the two sensor units may overlap. In this case as well, there is a possibility that the interference of the response signal occurs similarly. If the interference of the response signal occurs in this way, the monitoring device cannot receive the response signal, so that wireless communication cannot be appropriately performed between the monitoring device and the sensor unit. Therefore, there is a possibility that the function required for the tire pressure monitoring system may be hindered, for example, the tire pressure cannot be displayed on the indicator.

  The present invention has been made in view of such circumstances, and an object of the present invention is to improve the reliability of wireless communication between a monitoring device provided in a vehicle and a sensor unit provided in each wheel. It is to provide a tire pressure monitoring system.

  In order to solve the above-described problem, the invention according to claim 1 is a sensor unit that detects the tire air pressure of each wheel of the vehicle and wirelessly transmits a response signal including information on the detected air pressure, and the sensor. A starting signal for causing the unit to transmit the response signal is transmitted to each wheel, and when the response signal is received, the tire air pressure of each wheel is determined based on the air pressure information included in the response signal. In the tire pressure monitoring system comprising a monitoring device for monitoring the response, when the sensor unit receives a command signal transmitted from the monitoring device, the sensor unit starts transmitting the response signal from the time when the activation signal is received. The delay time is determined at random, and the response signal is transmitted by waiting for the determined delay time. When the command signal is transmitted to the plurality of sensor units, the command signal is sent to the plurality of sensor units again on condition that a response signal transmitted from the plurality of sensor units is detected to interfere. The gist is to send.

  According to the system, when a command signal is transmitted from a monitoring device to a plurality of sensor units, if the plurality of sensor units select different delay times, interference of response signals transmitted from each sensor unit is avoided. can do. On the other hand, when a plurality of sensor units select the same delay time, or when the difference between the selected delay times is very small, response signals transmitted from these sensor units will interfere. At this time, since the command signal is transmitted again from the monitoring device to the sensor unit, the delay time is randomly determined again by the plurality of sensor units. If the command signal is transmitted again when the response signal interferes in this way, the delay time of each sensor unit can be set so that the response signal does not eventually interfere. Therefore, since interference of response signals transmitted from each sensor unit can be suppressed, the reliability of wireless communication between the monitoring device and the sensor unit can be improved.

  According to a second aspect of the present invention, in the tire pressure monitoring system according to the first aspect, when the monitoring device transmits the command signal, the response signal according to the plurality of delay times is present or absent. The delay time that needs to be reset among the delay times determined by the plurality of sensor units is determined based on the information about the delay time that needs to be reset when the command signal is transmitted again The sensor unit transmits the command signal based on the delay time information that needs to be reset when the command signal is received. The gist is to determine whether or not to reset the delay time.

  If the sensor unit determines whether or not to reset the delay time based on the delay time information that needs to be reset, which is included in the command signal, as in the same system, The delay time can be efficiently allocated. As a result, the number of times the command signal and the response signal are repeatedly exchanged between the monitoring device and the sensor unit can be reduced, so that the communication time when the command signal and the response signal are exchanged between them can be shortened. Will be able to.

  According to a third aspect of the present invention, in the tire pressure monitoring system according to the first or second aspect, the plurality of sensors are detected from the time when the interference of the response signal is detected when the command signal is transmitted to the plurality of sensor units. The gist is that it is performed based on detecting that any of the response signals transmitted from the plurality of sensor units has not been received in a period until all of the units complete the transmission of the response signal. .

  By detecting the interference of the response signal based on the fact that one of the response signals transmitted from the plurality of sensor units cannot be received as in the system, the interference of the response signal can be easily and accurately detected. Can be detected.

  According to a fourth aspect of the present invention, in the tire pressure monitoring system according to the third aspect of the present invention, the detection that all of the plurality of sensor units have completed the transmission of the response signal is performed by using the command signal as the plurality of sensors. The gist is that this is performed based on detecting that the transmission time of one frame of the response signal has elapsed after the longest delay time of the delay time has elapsed since the transmission to the unit.

  According to the system, it is possible to detect that all sensor units have completed transmission of response signals by simply measuring the elapsed time from the time when command signals are transmitted to a plurality of sensor units. It becomes possible to easily and accurately detect that the unit has completed the transmission of the response signal.

  According to a fifth aspect of the present invention, in the tire pressure monitoring system according to the third or fourth aspect, the plurality of sensor units transmit identification information set for each sensor unit separately in the response signal. And detecting that one of the response signals transmitted from the plurality of sensor units has not been received has received the response signals including the identification information different from each other by the number of the plurality of sensor units. The gist is that it is performed based on the detection of the absence.

  Detects that one of the response signals sent from multiple sensor units cannot be received based on the fact that the same number of response signals containing different identification information cannot be received as in the system. By doing so, it becomes possible to easily and accurately detect that any of the response signals transmitted from the plurality of sensor units has not been received.

  In this case, as in the invention according to claim 6, in the tire pressure monitoring system according to any one of claims 1 to 5, the determination of the delay time by the sensor unit is the transmission of the response signal. It is effective to employ a configuration in which one of the delay times is randomly selected from a plurality of delay times set in advance with a time interval longer than the time. According to such a configuration, the delay time of each sensor unit can be set so that the response signal does not interfere only by allocating a plurality of preset delay times to the plurality of sensor units. The delay time of the unit can be set easily. As a result, the number of times the command signal and the response signal are repeatedly exchanged between the monitoring device and the sensor unit can be reduced, so that the communication time when the command signal and the response signal are exchanged between them can be shortened. Will be able to.

  According to a seventh aspect of the present invention, in the tire pressure monitoring system according to the sixth aspect, the number of the plurality of predetermined delay times selected is set to be larger than the number of the plurality of sensor units. It is the gist.

  If the number of selected delay times is set to be larger than the number of sensor units as in the system, for example, the number of delay times is set to the same number as the number of sensor units. Compared with the set case, the possibility that a plurality of sensor units select the same delay time can be reduced. Therefore, since it becomes easy to assign a plurality of preset delay times to each sensor unit, the number of times of repeating the second command signal and the response signal between the monitoring device and the sensor unit is reduced. Will be able to. For this reason, it becomes possible to shorten the communication time when the command signal and the response signal are exchanged between them.

  According to an eighth aspect of the present invention, in the tire pressure monitoring system according to the seventh aspect, the delay times of the plurality of sensor units are once determined so as not to cause interference of the response signals, and then the plurality of delays. The gist is to allocate each of the plurality of sensor units in order from the shortest time.

  As described above, when the predetermined number of selected delay times is set to be larger than the number of sensor units, the larger the number of selected delay times, the more the same sensor unit becomes. Since the possibility of selecting the delay time can be reduced, it is easy to assign a plurality of delay times to each sensor unit. However, as the number of selected delay times increases, the delay time of each sensor unit may become longer. Therefore, the communication time increases when the start signal and the response signal are exchanged between the monitoring device and the sensor unit. There is a risk that. In this regard, as in the above system, after the delay times of the plurality of sensor units are once determined, if the plurality of delay times are assigned to the plurality of sensor units in order from the shortest, the number of delay times selected The communication time when exchanging the start signal and the response signal between the monitoring device and the sensor unit can be shortened.

  In a ninth aspect of the present invention, in the tire pressure monitoring system according to any one of the first to eighth aspects, the monitoring device receives the response signals transmitted from the plurality of sensor units, respectively. A plurality of receiving antennas capable of receiving the response signal, and selecting a receiving antenna that can easily receive the response signal according to a delay time set for each sensor unit, and the response signal is selected via the selected receiving antenna. The gist is to receive.

  In such a tire pressure monitoring system, for example, the sensor unit provided on the front wheel and the sensor unit provided on the rear wheel are spaced apart by substantially the entire length of the vehicle. If only one receiving antenna is provided, the monitoring device may not be able to properly receive the response signal transmitted from each sensor unit. In this regard, as in the above system, after providing a plurality of receiving antennas capable of receiving response signals respectively transmitted from a plurality of sensor units, the response signals are set according to the delay time set for each sensor unit. If a receiving antenna that is easy to receive is selected, response signals transmitted from all sensor units can be suitably received via a plurality of receiving antennas. It is possible to accurately ensure the reliability of wireless communication.

  A tenth aspect of the present invention is the tire air pressure monitoring system according to any one of the first to ninth aspects, wherein a predetermined time elapses after the sensor unit transmits the response signal. The gist of the period up to is to prohibit transmission of the response signal based on reception of the activation signal.

  According to the system, in an environment where there is noise that can be received by the sensor unit, it is possible to preferably avoid a situation where the sensor unit misunderstands the noise as a start signal and repeats transmission of a response signal. The battery consumption of the sensor unit can be suppressed.

  According to the tire pressure monitoring system of the present invention, it is possible to improve the reliability of wireless communication between the monitoring device provided in the vehicle and the sensor unit provided in each wheel.

The block diagram which shows the system configuration | structure about 1st Embodiment of the tire pressure monitoring system concerning this invention. The perspective view which shows the perspective structure of the sensor unit about the tire pressure monitoring system of the said 1st Embodiment. The block diagram which shows the system configuration | structure of the sensor unit. The figure which shows typically the content of the response signal transmitted from the sensor unit. The block diagram which shows the operation example of the tire pressure monitoring system of the 1st embodiment. The block diagram which shows the operation example of the tire pressure monitoring system of the 1st embodiment. (A), (b) is a timing chart which shows the timing which a response signal is transmitted from the sensor unit about the tire pressure monitoring system of the first embodiment. The figure which shows typically the content of the command signal transmitted from the sensor unit about the tire pressure monitoring system of the said 1st Embodiment. The chart which shows the relationship between the value of the command contained in the command signal, and the command content to the sensor unit. The flowchart which shows the process sequence of the delay time setting process by the tire pressure monitoring system of the said 1st Embodiment. (A)-(f) is a timing chart which shows the operation example of the tire pressure monitoring system of the 1st embodiment. (A), (b) is a timing chart which shows the timing which a response signal is transmitted from the sensor unit about 2nd Embodiment of the tire pressure monitoring system concerning this invention. (A), (b) is the command value contained in the 5th command signal transmitted from the sensor unit about the tire pressure monitoring system of the 2nd embodiment, and the command contents to a sensor unit. A chart showing the relationship. The flowchart which shows the process sequence of the delay time setting process by the tire pressure monitoring system of the said 2nd Embodiment. (A)-(f) is a timing chart which shows the operation example of the tire pressure monitoring system of the 2nd embodiment. The block diagram which shows the system configuration | structure about 3rd Embodiment of the tire pressure monitoring system concerning this invention. The figure which shows the information memorize | stored in the non-volatile memory of the vehicle control apparatus. The flowchart which shows the process sequence of the receiving antenna switching process by the tire pressure monitoring system of the said 3rd Embodiment. (A)-(h) is a timing chart which shows the operation example of the tire pressure monitoring system of the 3rd embodiment. (A), (b) is a timing chart which shows the timing of the response signal transmitted from the sensor unit about the other example of the tire pressure monitoring system concerning this invention.

(First embodiment)
Hereinafter, a first embodiment of a tire pressure monitoring system according to the present invention will be described with reference to FIGS. FIG. 1 is a block diagram showing the system configuration of a tire pressure monitoring system according to the present embodiment. First, the system configuration of the tire pressure monitoring system will be described with reference to FIG.

  As shown in FIG. 1, in this tire pressure monitoring system, various communication processes are executed between the monitoring device 10 provided on the vehicle and the sensor units U1 to U4 provided on the wheels W1 to W4. .

  Here, the monitoring device 10 is provided with a receiving antenna 12 for receiving response signals Sr transmitted from the sensor units U1 to U4, together with a transmitting antenna 11 for transmitting the activation signal Ss to each of the wheels W1 to W4. It has been. Incidentally, the transmission antenna 11 transmits radio waves in the LF (Low Frequency) band on which the activation signal Ss is carried. On the other hand, the receiving antenna 12 receives a radio wave in the UHF (Ultra High Frequency) band on which the response signal Sr is placed. Further, the transmission antenna 11 is disposed closer to the front than the center of the vehicle. Thereby, by controlling the intensity of the radio wave in the LF band transmitted from the transmission antenna 11, the activation signal Ss is transmitted only to the front wheels W1 and W2, or the activation signal Ss is transmitted to all the wheels W1 to W4. It can be sent. In addition, the monitoring device 10 is provided with an indicator 13 for displaying the state quantity of each tire for each wheel and for notifying the driver when abnormality occurs in the tire. Then, transmission control of the activation signal Ss through the transmission antenna 11, processing of the response signal Sr received through the reception antenna 12, and various display processing through the indicator 13 are configured with a microcomputer at the center. This is done through the vehicle control device 14. Incidentally, the vehicle control device 14 includes a geomagnetic sensor 14a for detecting the direction of geomagnetism applied to the vehicle and a vehicle speed sensor 14b for detecting the speed of the vehicle.

  Next, the structure of the sensor units U1 to U4 will be described in detail with reference to FIGS. FIG. 2 shows a perspective structure of the sensor unit U1, and FIG. 3 shows a system configuration of the sensor unit U1 in a block diagram. Since the sensor units U1 to U4 have the same structure, only the structure of the sensor unit U1 will be described below as a representative for convenience.

  As shown in FIG. 2, the sensor unit U1 includes a unit main body 21 incorporating various sensors such as an air pressure sensor and a temperature sensor (not shown), and is projected from the unit main body 21 so that air is inhaled. It is comprised from the valve | bulb 22 used as the part. Incidentally, the unit body 21 is formed with an air hole 21a for guiding the air sucked from the valve 22 to the inside of the tire, and a sensor hole 21b for guiding the air inside the tire to the built-in air pressure sensor or temperature sensor. Has been. Further, as shown in FIG. 1, each sensor unit U1 to U4 is mounted on each wheel W1 to W4 in such a manner that the valve 22 faces the outside of the vehicle. That is, in the sensor units U1, U3 of the right wheels W1, W3 and the sensor units U2, U4 of the left wheels W2, W4, the protruding directions of the valve 22 are opposite to each other.

  On the other hand, as shown in FIG. 3, the sensor unit U1 includes a receiving antenna 26 for receiving LF-band radio waves carrying the activation signal Ss transmitted from the monitoring device 10, and the response signal Sr. And a transmitting antenna 27 for transmitting a radio wave of UHF band on which is placed. The sensor unit U1 is provided with various sensors for detecting the state quantity of the tire. Specifically, in addition to the air pressure sensor 23 and the temperature sensor 24 described above, a geomagnetic sensor 25 for detecting the direction of geomagnetism applied to the sensor unit U1 is provided. Then, the output signals of these sensors 23 to 25 are taken into a control device 28 mainly composed of a microcomputer. The control device 28 generates the response signal Sr based on the output signals of the sensors 23 to 25, and transmits the generated response signal Sr from the transmission antenna 27 or is received via the reception antenna 26. This is a part for processing the activation signal Ss. Incidentally, as shown in FIG. 4, the response signal Sr includes a non-volatile memory 28 a built in the control device 28 together with tire pressure, tire temperature, and geomagnetism information detected through the sensors 23 to 25. Includes information of an identification code (ID code) ID1 unique to the sensor unit U1 stored in advance. Note that different identification codes ID2 to ID4 are stored in the memories built in the sensor units U2 to U4, respectively. The geomagnetism information is information indicating whether or not the geomagnetism direction detected through the geomagnetism sensor 25 has a component in the protruding direction of the valve 22 (the direction indicated by the arrow a in FIG. 2). .

Next, the operation of the tire pressure monitoring system having such a configuration will be described in detail with reference to FIGS. 5 and 6.
First, in the vehicle control device 14, the direction of geomagnetism detected through the geomagnetic sensor 14a is a direction orthogonal to the traveling direction of the vehicle, and the speed of the vehicle detected through the vehicle speed sensor 14b is equal to or less than a predetermined speed. When the condition is satisfied, an activation signal is transmitted to the communication area A1 indicated by a two-dot chain line in FIG. That is, as indicated by an arrow in FIG. 5, in the state where the geomagnetism in the direction orthogonal to the traveling direction of the vehicle and from the left side of the vehicle toward the right side of the vehicle is applied to the vehicle, the speed of the vehicle When the speed becomes equal to or lower than a predetermined speed, an activation signal Ss is transmitted from the transmission antenna 11 to the front wheels W1, W2. When the activation signal Ss thus transmitted is received by the sensor units U1 and U2, the sensor units U1 and U2 detect tire state quantities such as tire air pressure through the built-in sensors 23 to 25. At the same time, a response signal Sr is generated based on the detected tire state quantity and transmitted to the monitoring device 10. Here, as shown in FIG. 5, when the direction of geomagnetism applied to the vehicle is from the left side of the vehicle to the right side of the vehicle, the direction of geomagnetism applied to the sensor unit U1 is the valve 22. The direction of geomagnetism applied to the sensor unit U2 is opposite to the direction in which the valve 22 protrudes. That is, the response signal Sr transmitted from the sensor unit U1 includes information indicating that the detected geomagnetism is in the same direction as the protruding direction of the valve 22 as geomagnetic information, while being transmitted from the sensor unit U2. The response signal Sr includes information indicating that the detected geomagnetism is in the direction opposite to the protruding direction of the valve 22 as geomagnetic information.

  When the response signal Sr transmitted from the sensor units U1 and U2 is received via the receiving antenna 12, the vehicle control device 14 changes the direction of geomagnetism detected through the geomagnetic sensor 14a from the vehicle left side to the vehicle right side. Based on the direction of heading, the following determination process is performed. First, when the geomagnetic information included in the response signal Sr indicates the same direction as the protruding direction of the valve 22, it is determined that the received response signal Sr is transmitted from the right front wheel W1. . On the other hand, when the geomagnetic information contained in the response signal Sr indicates that the direction of the valve 22 is opposite to the protruding direction, it is determined that the received response signal Sr is transmitted from the left front wheel W2. . Further, based on the determination result, the vehicle control device 14 displays the air pressure and temperature information included in the response signal Sr on the indicator 13 as the tire information of the right front wheel W1 or the left front wheel W2, and the response. The identification codes ID1 and ID2 included in the signal Sr are stored in the built-in nonvolatile memory 14c as identification codes for the right front wheel W1 or the left front wheel W2.

  Then, after the vehicle control device 14 stores the identification codes ID1 and ID2 of the sensor units U1 and U2 in the memory 14c in this way, this time, the radio wave transmitted from the transmission antenna 11 is strengthened. Thus, the activation signal Ss is transmitted to the communication area A2 indicated by a two-dot chain line in FIG. As a result, the activation signal Ss is transmitted to the sensor units U1 to U4 of all the wheels W1 to W4. When the activation signal Ss thus transmitted is received by the sensor units U1 to U4, the sensor units U1 to U4 transmit a response signal Sr based on the reception of the activation signal Ss. At this time, the response signal Sr transmitted from the sensor unit U3 includes information indicating that the detected geomagnetism is in the same direction as the protruding direction of the valve 22 as geomagnetic information. The response signal Sr to be transmitted includes information indicating that the detected geomagnetism is in the direction opposite to the protruding direction of the valve 22 as geomagnetic information.

  When the response signal Sr transmitted in this way is received by the monitoring device 10, the vehicle control device 14 determines whether or not the identification code included in the response signal Sr is already stored in the memory 14c. Judging. Here, when the vehicle control device 14 determines that the identification code included in the response signal Sr is already stored in the memory 14c, the received response signal Sr is transmitted from the front wheels W1 and W2. Judge that it is a thing and discard it. On the other hand, when the vehicle control device 14 determines that the identification code included in the response signal Sr is not stored in the memory 14c, the received response signal Sr is transmitted from the rear wheels W3 and W4. It is judged that. In this case, the vehicle control device 14 performs a process in accordance with the determination process for the front wheels W1 and W2 described above, so that the response signal Sr is transmitted from either the right rear wheel W3 or the left rear wheel W4. Determine whether. Further, based on the determination result, the state quantity of the tire included in the response signal Sr is displayed on the indicator 13 as the tire information of the rear wheels W3 and W4, and the identification codes ID3 and ID4 of the sensor units U3 and U4. Is stored in the memory 14c.

  5 and 6 also when the direction of the geomagnetism applied to the vehicle is opposite to the direction illustrated in FIGS. 5 and 6, that is, the direction from the right side of the vehicle to the left side of the vehicle. By adopting a method according to the method described with reference to, information on the tires of the wheels W1 to W4 is displayed on the indicator 13 separately.

  After the vehicle control device 14 completes the location registration for storing the identification codes ID1 to ID4 of the sensor units U1 to U4 and the positions of the wheels W1 to W4 in a one-to-one correspondence with each other, the vehicle control device 14 completes the location registration. Determines as to which of the wheels W1 to W4 the tire information included in the response signal Sr indicates. That is, when the response signal Sr is received via the receiving antenna 12, the identification code included in the response signal Sr is collated with the identification code stored in the memory 14c, and based on the collation result. Thus, it is determined which tire information of the wheels W1 to W4 indicates the tire information included in the response signal Sr.

  According to such a configuration, only by providing one transmission antenna 11 in the vehicle, the location registration of the sensor units U1 to U4 with respect to the wheels W1 to W4 is performed, or the tire information of the wheels W1 to W4 is indicated as an indicator. 13 can be displayed separately.

  By the way, in the tire pressure monitoring system having such a configuration, when the response signals Sr are transmitted at the same timing from the sensor units U1 to U4 in response to the activation signal Ss, the respective response signals Sr are transmitted. There is a risk of interference. If such interference of the response signal Sr occurs, it becomes impossible to receive the response signal Sr via the receiving antenna 12. Therefore, wireless communication is appropriately performed between the monitoring device 10 and the sensor units U1 to U4. It becomes impossible to do. Therefore, for example, the tire pressure may not be displayed on the indicator 13 or the location registration of the sensor units U1 to U4 may not be performed properly.

Therefore, in the present embodiment, as shown in FIG. 7, there are four types of delay times from when the sensor units U1 to U4 receive the activation signal Ss via the reception antenna 26 until the transmission of the response signal Sr starts. Delay times Td1 to Td4 are prepared in advance. Incidentally, each time interval of the delay times Td1 to Td4 is set to a time longer than the transmission time Tsr of one frame of the response signal Sr. That is, the four types of delay times Td1 to Td4 are set so as to satisfy the relational expression “(Td _n −Td _n−1 )> Tdr” (where n = 2 to 4). Then, these four types of delay times Td1 to Td4 are assigned to the respective sensor units U1 to U4 to suppress interference of the response signal Sr. Information on these four types of delay times Td1 to Td4 is stored in advance in the memory 14c of the vehicle control device 14 and the memory 28a of the sensor units U1 to U4.

Next, a method for assigning the delay times Td1 to Td4 to the sensor units U1 to U4 will be described in detail with reference to FIGS.
FIG. 8 shows the contents of the command signal Sc transmitted from the vehicle control device 14 to the sensor units U1 to U4 when the delay times Td1 to Td4 are assigned to the sensor units U1 to U4.

  As shown in FIG. 8, the command signal Sc is used to further specify a preamble composed of a bit string of a predetermined length, a command for specifying the operation of the sensor units U1 to U4, and the operation content of the command. It consists of arguments. Here, the command consists of a three-digit value constructed by binary information of “0” and “1”. The argument consists of a 4-digit value that is also constructed from binary information. As shown in FIG. 9, the command signal Sc is roughly composed of four types of signals according to the value of the command.

  (B1) When the value of the command is “000”. In this case, the delay time is randomly selected from the above-described four types of delay times Td1 to Td4, and the first command signal Sc1 is transmitted to transmit the response signal Sr based on the selected delay time.

  (B2) When the value of the command is “001”. In this case, of the four types of delay times Td1 to Td4, a delay time is randomly selected from the delay times that need to be reset, provided that the delay time that needs to be reset is selected. Thus, the second command signal Sc2 for transmitting the response signal Sr is obtained. The second command signal Sc2 is a response signal using the delay time selected by itself as it is for the sensor unit that has selected another delay time excluding the delay time that needs to be reset. This is a command signal for transmitting Sr. Here, in the second command signal Sc2, which of the four types of delay times Td1 to Td4 is the delay time that needs to be reset is specified by the value of each digit of the argument. Specifically, when the value of a predetermined digit is “0”, the delay time corresponding to that digit is a delay time that needs to be reset, and the value of the predetermined digit is “1”. In some cases, the delay time corresponding to that digit does not need to be reset. Therefore, when the value of the argument is “0100”, it indicates that the delay time Td2 does not need to be reset, while the delay times Td1, Td3, and Td4 indicate that resetting is necessary. At this time, the second command signal Sc2 is a command signal that causes the sensor unit that has selected the delay time Td2 to transmit the response signal Sr using the delay time Td2 as it is, while the delay time Td1. , Td3, and Td4, the command signal is such that the response signal Sr is transmitted by randomly selecting the delay time from the delay times Td1, Td3, and Td4.

  (B3) When the value of the command is “010”. In this case, the third command signal Sc3 that transmits the response signal Sr using the delay time set for each sensor unit on the condition that a specific delay time determined based on the argument is selected. It becomes. Here, in the third command signal Sc3, the value of each digit of the argument needs to transmit the response signal Sr with the sensor unit that needs to transmit the response signal Sr among the four sensor units U1 to U4. This shows a sensor unit without a mark. Specifically, when the value of a predetermined digit is “0”, the sensor unit that selects the delay time corresponding to the digit does not need to transmit the response signal Sr. When the value of the digit of “1” is “1”, it indicates that the sensor unit that selects the delay time corresponding to the digit needs to transmit the response signal Sr. Therefore, when the value of the argument is “0100”, the third command signal Sc3 is a command signal that causes the response signal Sr to be transmitted only to the sensor unit that has selected the delay time Td2. When the value of the argument is “1111”, the third command signal Sc3 is a command signal that causes all the sensor units U1 to U4 to transmit the response signal Sr. In the present embodiment, the third command signal Sc3 is used as the activation signal Ss.

  (B4) The fourth command signal Sc4 is a signal indicating that the setting of the delay times Td1 to Td4 of the sensor units U1 to U4 has been completed. Incidentally, when each of the sensor units U1 to U4 receives the fourth command signal Sc4, it continues to use the set delay time until it receives the first command signal Sc1. ing.

And the said vehicle control apparatus 14 determines the delay time of each sensor unit U1-U4 by transmitting these command signals Sc to sensor unit U1-U4.
FIG. 10 is a flowchart showing a processing procedure for determining the delay time of each of the sensor units U1 to U4, which is executed through the vehicle control device 14. Hereinafter, with reference to FIG. A specific procedure will be described. This process is executed, for example, when the ignition switch of the vehicle is turned on.

  As shown in FIG. 10, in this process, first, the first command signal Sc1 is transmitted to each of the wheels W1 to W4 via the transmission antenna 11 (step S1), and four kinds of signals are sent from that time point. It is detected whether or not the response signal Sr has been received when the delay times Td1 to Td4 have elapsed (step S2). Further, following the process of step S2, it is determined whether or not the transmission of response signals Sr from all the sensor units U1 to U4 has been completed (step S3). In the process of step S3, specifically, the elapsed time from the time when transmission of the first command signal Sc1 is completed is measured through a timer built in the control device 14, and the elapsed time is a predetermined time. It is determined that transmission of response signals Sr from all sensor units U1 to U4 has been completed when T1 or more is reached. Incidentally, the predetermined time T1 is set to a time longer than the time obtained by adding the longest delay time Td4 and the transmission time Tsr of one frame of the response signal Sr among the four types of delay times Td1 to Td4. Thereby, it is possible to easily determine whether or not all the sensor units U1 to U4 have completed the transmission of the response signal Sr only by measuring the elapsed time from the time when the first command signal Sc1 is transmitted. It becomes like this. In addition, the process of the said step S2 is continued during the period when transmission of the response signal Sr from all the sensor units U1-U4 is not completed (step S3: NO).

  When it is determined that the transmission of the response signals Sr from all the sensor units U1 to U4 has been completed (step S3: YES), it is transmitted from the sensor units U1 to U4 as the processing of the subsequent step S4. It is determined whether or not the response signal Sr has interference. In the process of step S4, specifically, four responses with different identification codes are received from the time when the first command signal Sc1 is received until the transmission of the response signal Sr by all the sensor units U1 to U4 is completed. When the signal Sr is not received, it is determined that no interference occurs in the response signal Sr.

  Here, when there is interference in the response signal Sr transmitted from the sensor units U1 to U4 (step S4: YES), the second command signal Sc2 is transmitted to each wheel W1 to W4 via the transmission antenna 11. Are transmitted to the sensor units U1 to U4 (step S5). In the process of step S5, it is necessary to reset the delay time during which the response signal Sr could not be received among the four types of delay times Td1 to Td4 based on the detection result of step S2. The argument of the second command signal Sc2 is set as the delay time and the delay time in which the response signal Sr can be received is a delay time that does not need to be reset. Moreover, the process of step S2, step S3, and step S5 is repeatedly performed during the period (step S4: YES) during which it is determined that interference has occurred in the response signals Sr transmitted from the sensor units U1 to U4. .

  If it is determined that no interference has occurred in the response signals Sr transmitted from the sensor units U1 to U4 (step S4: NO), that is, all the sensors from the time when the first command signal Sc1 is received. When the four response signals Sr having different identification codes can be received during the period until the transmission of the response signal Sr by the units U1 to U4 is completed, the fourth command signal Sc4 is transmitted to the wheels W1 to W4. (Step S6). And the vehicle control apparatus 14 complete | finishes this series of processes, after performing the process of this step S6.

  FIG. 11 is a timing chart showing an operation example of the tire pressure monitoring system based on such a delay time setting process by the vehicle control device 14. Hereinafter, the operation of this system will be described in detail with reference to FIG. Describe.

  For example, if the ignition switch of the vehicle is turned on by the driver at time t1, the first command signal Sc1 is sent from the monitoring device 10 to each of the wheels W1 to W4 as shown in FIG. Sent. At this time, when the first command signal Sc1 is received by the sensor units U1 to U4 of the wheels W1 to W4, each of the sensor units U1 to U4 has one delay among the four types of delay times Td1 to Td4. A time is selected at random, and a response signal Sr is transmitted based on the selected delay time. Here, the sensor unit U1 of the right front wheel W1 has a delay time Td1, the sensor unit U2 of the left front wheel W2 has a delay time Td2, and the sensor units U3 and U4 of the right rear wheel W3 and the left rear wheel W4 have a delay. If the time Td4 is selected, the response signals Sr are transmitted from the sensor units U1 to U4 in the manner shown in FIGS. 11 (c) to 11 (f). That is, since the response signals Sr are transmitted at the same timing in the sensor units U3 and U4 of the right rear wheel W3 and the left rear wheel W4 (time t3), the response signals Sr interfere with each other. Therefore, as shown in FIG. 11B, the monitoring device 10 can receive the response signal Sr transmitted from the sensor units U1 and U2 of the front wheels W1 and W2, while the sensors of the rear wheels W3 and W4. The response signal Sr transmitted from the units U3 and U4 cannot be received. In other words, the identification codes ID1 and ID2 of the sensor units U1 and U2 can be acquired, but the identification codes ID3 and ID4 of the sensor units U3 and U4 cannot be acquired. For this reason, the monitoring device 10 can receive four response signals Sr having different identification codes during a period from time t2 when transmission of the first command signal Sc1 is completed to time t4 when the predetermined time T1 elapses. When it is detected that there is no interference, it is determined that there is interference in the response signal Sr, and the second command signal Sc2 is transmitted from the transmission antenna 11 to each of the wheels W1 to W4. Since the monitoring apparatus 10 can receive the response signal Sr during the delay times Td1 and Td2, the value of the argument is set to “1100” when transmitting the second command signal Sc2.

  Then, when the second command signal Sc2 is received, the sensor units U1 to U4 of the wheels W1 to W4 execute the following processing based on the argument included in the signal. First, in the sensor units U1 and U2, the value of the argument corresponding to the delay times Td1 and Td2 selected by the sensor unit U1 and U2 is “1”, that is, the delay time selected by the sensor unit U1 and U2 does not need to be reset. 11 (c) and 11 (d), the response signal Sr is transmitted using the previously selected delay times Td1 and Td2 as they are. On the other hand, in the sensor units U3 and U4, the value of the argument corresponding to the delay times Td3 and Td4 selected by itself is “0”, that is, the delay time selected by itself is a delay time that needs to be reset. Is recognized, one delay time is randomly selected from the delay times Td3 and Td4 that need to be reset, and the response signal Sr is transmitted. As described above, if it is possible to determine whether or not the delay time needs to be reset based on the value of the argument included in the second command signal Sc2, each sensor unit U1 to U4 can be determined. Four types of delay times Td1 to Td4 can be efficiently allocated. For this reason, the number of times the second command signal Sc2 and the response signal Sr are exchanged between the monitoring device 10 and the sensor units U1 to U4 can be reduced.

  If the sensor unit U3 selects the delay time Td3, and the sensor unit U4 selects the delay time Td4, each sensor unit U1 to U4 responds in the manner shown in FIGS. The signal Sr is transmitted. That is, since the response signal Sr is transmitted from each of the sensor units U1 to U4 at different timings, interference of the response signal Sr can be avoided. Then, as shown in FIG. 11B, the monitoring device 10 has an identification code in a period from time t5 when transmission of the second command signal Sc2 is completed to time t6 when the predetermined time T1 elapses. When it is detected that four response signals Sr having different values can be received, a fourth command signal Sc4 is transmitted to each of the wheels W1 to W4.

And after determining the delay time of each sensor unit U1-U4 in this way, the monitoring apparatus 10 operate | moves as follows.
First, when the monitoring apparatus 10 acquires tire information of all the wheels W1 to W4, the wheels W1 to W4 are set with the third command signal Sc3 having an argument value set to “1111” as the start signal Ss. Send to. At this time, since the sensor units U1 to U4 of the wheels W1 to W4 transmit the response signal Sr using the delay times Td1 to Td4 set to the wheels W1 to W4, in the monitoring device 10, the sensor units U1 to U4 are transmitted from the sensor units U1 to U4. All response signals Sr can be received. That is, since interference of response signals Sr transmitted from the sensor units U1 to U4 can be suppressed, the reliability of wireless communication between the monitoring device 10 and the sensor units U1 to U4 can be improved. become.

  In addition, when the monitoring apparatus 10 acquires tire information only through a specific sensor unit among the sensor units U1 to U4, the monitoring device 10 sets the argument value based on the delay time corresponding to the specific sensor unit. 3 command signal Sc3 is transmitted to each of the wheels W1 to W4 as the start signal Ss. Specifically, when it is desired to acquire tire information only through the sensor unit U2, a third command signal Sc3 having an argument value set to “0100” is transmitted to each of the wheels W1 to W4 as the start signal Ss. To do. Such a configuration is particularly effective in situations where it is necessary to frequently acquire information on tires of specific wheels, for example, when an abnormality occurs in the air pressure of tires of specific wheels.

As described above, according to the tire pressure monitoring system according to the present embodiment, the following effects can be obtained.
(1) When the sensor units U1 to U4 receive the first command signal Sc1 transmitted from the monitoring device 10, one type of delay time is randomly determined from the four types of delay times Td1 to Td4. At the same time, the response signal Sr is transmitted after waiting for the determined delay time. In addition, the monitoring device 10 transmits the second command signal Sc2 to the sensor units U1 to U4 when it is detected that interference has occurred in the response signals Sr transmitted from the sensor units U1 to U4. did. Thereby, since the delay time of each sensor unit U1-U4 can be set so that the interference of the response signal Sr does not finally occur, the interference of the response signal Sr can be suppressed. It becomes possible to improve the reliability of wireless communication with the sensor units U1 to U4.

  (2) When the monitoring device 10 transmits the first command signal Sc1, the monitoring device 10 determines a delay time that needs to be reset based on the presence or absence of interference of the response signal Sr according to the delay times Td1 to Td4. When transmitting the second command signal Sc2, information on the delay time that needs to be reset is included in the second command signal Sc2. As a result, four types of delay times Td1 to Td4 can be efficiently allocated to the sensor units U1 to U4, so that the second command signal Sc2 and the response signal Sr between the monitoring device 10 and the sensor units U1 to U4. Can be reduced. Accordingly, since the number of times of repeating the second command signal Sc2 and the response signal Sr between the monitoring device 10 and the sensor units U1 to U4 can be reduced, the monitoring device 10 and the sensor units U1 to U4 can be reduced. Thus, it is possible to shorten the communication time when the command signal Sc and the response signal Sr are exchanged.

  (3) The determination of the delay time by the sensor units U1 to U4 is any one of four types of delay times Td1 to Td4 determined in advance with a time interval longer than the transmission time of one frame of the response signal Sr. The delay time is selected at random. As a result, the delay times of the sensor units U1 to U4 can be set so that the response signal Sr does not interfere by simply allocating the four types of delay times Td1 to Td4 to the sensor units U1 to U4. The delay times of the units U1 to U4 can be set easily. Accordingly, since the number of times of repeating the second command signal Sc2 and the response signal Sr between the monitoring device 10 and the sensor units U1 to U4 can be reduced, the monitoring device 10 and the sensor units U1 to U4 can be reduced. Thus, it is possible to shorten the communication time when the command signal Sc and the response signal Sr are exchanged.

  (4) The sensor unit during a period from when the first and second command signals Sc1 and Sc2 are transmitted to the sensor units U1 to U4 until all the sensor units U1 to U4 complete the transmission of the response signal Sr. When any of the response signals Sr transmitted from U1 to U4 cannot be received, it is determined that interference of the response signal Sr has occurred. Thereby, the interference of the response signal Sr can be detected easily and accurately.

  (5) After the longest delay time Td4 has elapsed from the time when the first command signal Sc1 is transmitted to the sensor units U1 to U4, all the sensor units have a transmission time of one frame of the response signal Sr. It is determined that U1 to U4 have completed the transmission of the response signal Sr. Thereby, it becomes possible to easily and accurately detect that all the sensor units U1 to U4 have completed the transmission of the response signal Sr.

  (6) It is determined that all the response signals transmitted from the sensor units U1 to U4 have been received when the response signals Sr having different identification codes are received by the number of the sensor units U1 to U4. As a result, it is possible to easily and accurately detect whether or not all the response signals Sr transmitted from the sensor units U1 to U4 have been received.

(Second Embodiment)
Next, a second embodiment of the tire pressure monitoring system according to the present invention will be described with reference to FIGS. The basic configuration of the tire pressure monitoring system to which the second embodiment is applied is the same as that of the tire pressure monitoring system illustrated in FIGS.

  As shown in FIG. 12 corresponding to the previous FIG. 7, in this embodiment, the sensor units U1 to U4 start transmitting the response signal Sr from the time when the activation signal Ss is received via the reception antenna 26. As the delay time, 10 types of delay times Td1 to Td10 are prepared in advance. The time intervals of these delay times Td1 to Td10 are also set to a time longer than the transmission time of one frame of the response signal Sr.

  In this embodiment, these ten types of delay times Td1 to Td10 are allocated to the sensor units U1 to U4 separately. Thereby, as compared with the case where the number of delay times is set to the same number as the number of sensor units U1 to U4 as in the first embodiment, the sensor units U1 to U4 can select the same delay time. Therefore, it is easy to assign a plurality of delay times to each sensor unit U1 to U4.

  However, in this case, since the length of the delay time of each sensor unit U1 to U4 is Td10 at the longest, compared with the case where the length of the delay time is Td4 at the longest as in the first embodiment, There is a possibility that the communication time may be extended when the activation signal Ss and the response signal Sr are exchanged between the monitoring device 10 and the sensor units U1 to U4. Therefore, in the present embodiment, after the delay times of the sensor units U1 to U4 are once determined as any one of the ten delay times Td1 to Td10, the delay times Td1 to Td4 are set. It is made to allocate to each sensor unit U1-U4.

  Next, referring to FIG. 13, the command signal Sc transmitted from the monitoring device 10 to the sensor units U1 to U4 when performing such rearrangement of the delay times of the sensor units U1 to U4 will be described.

  As shown in FIG. 13A, the command signal Sc becomes the fifth command signal Sc5 when the value of the command is “100”. The fifth command signal Sc5 has one of the delay times Td1 to Td4 based on how short the delay time selected by itself is among the delay times selected by all the sensor units U1 to U4. This is a command signal for selecting a delay time. Here, in the fifth command signal Sc5, the argument consists of a 10-digit value, and the delay time selected by each of the sensor units U1 to U4 depends on the value of this argument. It is shown that it is. Specifically, when the value of a predetermined digit is “0”, the delay time corresponding to that digit is not selected by the sensor units U1 to U4, and the value of the predetermined digit is “1”. , It indicates that the delay time corresponding to the digit is selected by the sensor units U1 to U4. Therefore, as shown in FIG. 13B, when the value of the argument is “1010000101”, it indicates that the delay times Td1, Td3, Td8, and Td10 are selected by the sensor units U1 to U4. At this time, the fifth command signal is a command signal shown in the following (c1) to (c4) for each of the sensor units U1 to U4.

(C1) A command signal for selecting the delay time Td1 as it is for the sensor unit selecting the delay time Td1.
(C2) A command signal for selecting the delay time Td2 for the sensor unit selecting the delay time Td3.

(C3) A command signal for selecting the delay time Td3 for the sensor unit selecting the delay time Td8.
(C4) A command signal for selecting the delay time Td4 for the sensor unit selecting the delay time Td10.

  The vehicle control device 14 transmits the fifth command signal Sc5 and the first and second command signals Sc1 and Sc2 to the wheels W1 to W4, thereby delaying the sensor units U1 to U4. To decide. As shown in FIG. 14, the process for determining the delay times of the sensor units U1 to U4, which is executed through the vehicle control device 14, is basically the same as the process illustrated in FIG. is there. However, in this embodiment, instead of the process of the previous step S6, that is, the process of transmitting the fourth command signal Sc4 to each of the wheels W1 to W4, the process of step S7, that is, the fifth command signal Sc5 is applied to each wheel. Processing to transmit to W1 to W4 is executed. Further, in the process of step S3, the predetermined time T1 used for determining whether or not the transmission of the response signal Sr from all the sensor units U1 to U4 is completed is the longest delay time Td10 and the response signal Sr. The time is set longer than the time obtained by adding the transmission time Tsr of one frame.

Next, operation | movement of the tire pressure monitoring system of this embodiment is demonstrated.
FIG. 15 is a timing chart showing an operation example of the tire air pressure monitoring system of the present embodiment as a diagram corresponding to FIG.

  For example, assuming that the ignition switch of the vehicle is turned on by the driver at time t10, a first command signal Sc1 is sent from the monitoring device 10 to each of the wheels W1 to W4 as shown in FIG. Sent. At this time, when the first command signal Sc1 is received by the sensor units U1 to U4 of the wheels W1 to W4, each of the sensor units U1 to U4 has one delay among the ten delay times Td1 to Td4. A time is selected at random, and a response signal Sr is transmitted based on the selected delay time. Here, assuming that the delay times Td1, Td3, Td8, and Td10 are selected in the sensor units U1 to U4, the response signals Sr are sent from the sensor units U1 to U4 in the manner shown in FIGS. 15 (c) to (f). Will be sent. That is, since the response signal Sr is transmitted from each of the sensor units U1 to U4 at different timings, interference of the response signal Sr can be avoided. Then, as shown in FIG. 15B, the monitoring apparatus 10 receives the identification code during a period from time t11 when transmission of the first command signal Sc1 is completed to time t12 when the predetermined time T1 elapses. When it is detected that four different response signals Sr can be received, a fifth command signal Sc5 is transmitted to each of the wheels W1 to W4. The monitoring apparatus 10 sets the argument value of the fifth command signal Sc5 to “1010000101” based on the reception of the response signal Sr with the delay times Td1, Td3, Td8, and Td10.

  Then, in the sensor units U1 to U4 of the wheels W1 to W4, when the fifth command signal Sc5 is received, the process illustrated in FIG. 13B is executed. That is, the delay time is set to Td1 in the sensor unit U1, the delay time is set to Td2 in the sensor unit U2, the delay time is set to Td3 in the sensor unit U3, and the delay time is set to Td4 in the sensor unit U4. For this reason, when the third command signal Sc3 whose argument value is set to “1111” is transmitted from the monitoring device 10 to each of the wheels W1 to W4 as the activation signal Ss at the time t13 thereafter, At the time t15 when the delay time Td4 elapses from the time t14 when the transmission of the signal Ss is completed, the transmission of the response signals by all the sensor units U1 to U4 is completed. Therefore, for example, compared with the case where the delay time of the sensor unit U4 is set to Td10, the communication time when exchanging the activation signal Ss and the response signal Sr between the monitoring device 10 and the sensor units U1 to U4 is shortened. Will be able to.

  As described above, according to the tire pressure monitoring system according to the present embodiment, in addition to the effects (1) to (6) of the first embodiment, the following effects can be obtained. .

  (7) The number of preset delay times is set to be larger than the number of sensor units U1 to U4. This makes it easy to assign a plurality of delay times to each sensor unit, thereby reducing the communication time when the command signal Sc and the response signal Sr are exchanged between the monitoring device 10 and the sensor units U1 to U4. Will be able to.

  (8) The delay times Td1 to Td4 are assigned to the sensor units U1 to U4 after the delay times of the sensor units U1 to U4 are once determined so that the interference of the response signal Sr does not occur. Thereby, it becomes possible to shorten the communication time when the activation signal Ss and the response signal Sr are exchanged between the monitoring device 10 and the sensor units U1 to U4.

(Third embodiment)
Next, a third embodiment of the tire pressure monitoring system according to the present invention will be described with reference to FIGS.

  In the first and second embodiments, the sensor units U1, U2 provided on the front wheels W1, W2 and the sensor units U3, U4 provided on the rear wheels W3, W4 are separated by substantially the entire vehicle length. Therefore, if only one receiving antenna 12 is provided in the vehicle, the monitoring device 10 may not be able to appropriately receive the response signal Sr transmitted from each sensor.

  Therefore, in the present embodiment, the sensor units U1 to U1 are selected by providing a plurality of receiving antennas for receiving the response signal and selecting a receiving antenna that easily receives the response signal according to the delay times Td1 to Td4. The response signal transmitted from U4 is easily received.

  FIG. 16 is a block diagram showing a system configuration of the tire pressure monitoring system according to the present embodiment as a diagram corresponding to FIG. Note that the basic configuration of the tire pressure monitoring system according to the third embodiment is similar to the structure shown in FIG. In FIG. 16, the same elements as those shown in FIG. 1 are denoted by the same reference numerals, and redundant description is omitted. Hereinafter, differences between the two will be mainly described.

  As shown in FIG. 16, in this tire pressure monitoring system, two receiving antennas 12a and 12b are provided as receiving antennas for receiving response signals Sr transmitted from the sensor units U1 to U4. . Here, the 1st receiving antenna 12a is provided in the vehicle-mounted components arrange | positioned ahead of a vehicle, for example, an instrument panel etc., Comprising: The response transmitted mainly from sensor unit U1, U2 of front wheel W1, W2 The signal Sr is arranged so as to be easily received. On the other hand, the second receiving antenna 12b is provided on an in-vehicle component disposed on the rear side of the vehicle, for example, an upper back or a C pillar, and mainly from the sensor units U3 and U4 of the rear wheels W3 and W4. It arrange | positions so that it may be easy to receive the response signal transmitted. Further, the first and second receiving antennas 12 a and 12 b are connected to the vehicle control device 14 through the switch 15. Thereby, by operating the switch 15, the response signal received via the first receiving antenna 12a is taken into the vehicle control device 14, or the response signal received via the second receiving antenna 12b is received. It is possible to select whether to take in the vehicle control device 14. In other words, the reception antenna for receiving the response signal can be switched to one of the first and second reception antennas 12a and 12b through the operation of the switch 15. Incidentally, the switching operation of the switch 15 is performed through the vehicle control device 14.

  On the other hand, when the vehicle control device 14 completes the process illustrated in FIG. 10 or the process illustrated in FIG. 14, the vehicle control device 14 delays the identification codes ID1 to ID4 of the sensor units U1 to U4 as the processing results. Information associated with the times Td1 to Td4 is stored in the memory 14c. Further, as described above, the vehicle control device 14 also performs a location registration process for storing the identification codes ID1 to ID4 of the sensor units U1 to U4 and the positions of the wheels W1 to W4 in a one-to-one correspondence in the memory 14c. Do. Therefore, when these processes are completed, as shown in FIG. 17, information relating the positions of the wheels W1 to W4, the identification codes ID1 to ID4 of the sensor units U1 to U4, and the delay times Td1 to Td4 are stored in the memory 14c. Will be stored.

  And in this embodiment, while determining the optimal receiving antenna for reception of a response signal for every delay time Td1-Td4 based on the information illustrated in FIG. 17, by switching the receiving antenna based on the determination result, The response signal is easily received. The receiving antenna switching process determines the delay time of the sensor units U1 to U4 by completing the process illustrated in FIG. 10 or the process illustrated in FIG. 14, and the location registration process is completed. It is executed on condition that it is doing. Further, in the vehicle control device 14, when the delay time of the sensor units U1 to U4 has not been determined, or when the location registration process has not been completed, the first and second receiving antennas 12a and 12b The response signal Sr is received via one predetermined receiving antenna.

  FIG. 18 is a flowchart showing a processing procedure for switching the receiving antenna, which is executed through the vehicle control device 14, and a specific procedure for this processing will be described below with reference to FIG. . This process is executed, for example, when the activation signal Ss is transmitted from the transmission antenna 11.

  As shown in FIG. 18, in this process, it is first determined whether or not the delay time Td2 has elapsed since the transmission of the activation signal Ss was completed (step S10). In the process of step S10, specifically, the elapsed time from the completion of transmission of the activation signal Ss is measured through a timer built in the control device 14, and this elapsed time becomes the delay time Td2. Accordingly, it is determined that the delay time Td2 has elapsed since the transmission of the activation signal Ss was completed. If it is determined that the delay time Td2 has not elapsed since the transmission of the activation signal Ss is completed (step S10: NO), the switch 15 is operated to cope with the delay time Td1. A receiving antenna optimum for receiving the response signal transmitted from the sensor unit is selected (step S11). In the process of step S11, specifically, the sensor units that wait for the delay time Td1 and transmit a response signal based on the information stored in the memory 14c illustrated in FIG. 17 are the front wheels W1, W2. When it is determined that the sensor unit is provided in the first reception antenna 12a, the first reception antenna 12a is selected. On the other hand, when it is determined that the sensor unit that waits for the delay time Td1 and transmits the response signal is the sensor unit provided in the rear wheels W3 and W4, the second receiving antenna 12b is selected. The

  On the other hand, in the determination process of step S10, when it is determined that the delay time Td2 has elapsed from the time when transmission of the activation signal Ss is completed (step S10: YES), from the time when transmission of the activation signal Ss is completed. It is determined whether or not the delay time Td3 has elapsed (step S12). Here, when it is determined that the delay time Td3 has not elapsed since the completion of transmission of the activation signal Ss (step S12: NO), the switch 15 is operated to cope with the delay time Td2. A receiving antenna optimum for receiving the response signal transmitted from the sensor unit is selected (step S13). In addition, the process of this step S13 is a process according to the process of previous step S11.

  On the other hand, in the determination process of step S12, when it is determined that the delay time Td3 has elapsed since the transmission of the activation signal Ss is completed (step S12: YES), the transmission of the activation signal Ss is completed. It is determined whether or not the delay time Td4 has elapsed (step S14). Here, when it is determined that the delay time Td4 has not elapsed since the transmission of the activation signal Ss is completed (step S14: NO), the switch 15 is operated to cope with the delay time Td3. A receiving antenna optimum for receiving the response signal transmitted from the sensor unit is selected (step S15). Note that the process of step S15 is also a process according to the process of the previous step S11.

  When it is determined in the determination process of step S14 that the delay time Td4 has elapsed since the transmission of the activation signal Ss was completed (step S14: YES), the switch 15 is operated to delay the operation. An optimal receiving antenna is selected to receive a response signal transmitted from the sensor unit corresponding to time Td3 (step S16). Note that the process of step S16 is also a process according to the process of the previous step S11. And the vehicle control apparatus 14 complete | finishes this series of processes, after performing the process of step S16.

  FIG. 19 is a timing chart showing an operation example of the tire pressure monitoring system based on such a receiving antenna switching process by the vehicle control device 14. Hereinafter, the operation of this system will be described in detail with reference to FIG. Describe. Here, the delay time of the sensor unit U1 of the right front wheel W1 is Td1, the delay time of the sensor unit U2 of the left front wheel W2 is Td2, the delay time of the sensor unit U3 of the right rear wheel W3 is Td3, and the left rear wheel The case where the delay time of the sensor unit U4 of W4 is set to Td4 is illustrated.

  For example, assume that the activation signal Ss is transmitted from the monitoring device 10 at time t20 as shown in FIG. At this time, as shown in FIG. 19B, the monitoring apparatus 10 performs the first reception during the period from the time t21 when the transmission of the activation signal Ss is completed to the time t24 when the delay time Td3 elapses. The antenna 12a is selected. For this reason, as shown in FIG. 19E, if a response signal is transmitted from the sensor unit U1 of the right front wheel W1 at the time t22 when the delay time Td1 has elapsed from the time t21, the response signal is As shown in FIG. 19C, the signal is received via the first receiving antenna 12a. Further, as shown in FIG. 19 (f), if a response signal is transmitted from the sensor unit U2 of the left front wheel W2 at the time t22 when the time t23 when the delay time Td2 has elapsed from the time t21, this response The signal is also received via the first receiving antenna 12a as shown in FIG. For this reason, the monitoring device 10 can suitably receive the response signals transmitted from the sensor units U1 and U2 of the front wheels W1 and W2.

  Then, after time t24, as shown in FIG. 19B, the monitoring device 10 selects the second receiving antenna 12b. For this reason, as shown in FIG. 19 (g), if a response signal is transmitted from the sensor unit U3 of the right rear wheel W3 at time t24, the response signal is as shown in FIG. 19 (d). In addition, the signal is received via the second receiving antenna 12b. Further, as shown in FIG. 19 (h), if a response signal is transmitted from the sensor unit U4 of the left rear wheel W4 at the time t25 when the delay time Td4 has elapsed from the time t21, this response signal is also shown in FIG. As shown in FIG. 19D, the signal is received via the second receiving antenna 12b. For this reason, the monitoring device 10 can suitably receive the response signals transmitted from the sensor units U3 and U4 of the rear wheels W3 and W4.

  According to such a configuration as the tire pressure monitoring system, the response signals transmitted from all the sensor units U1 to U4 can be suitably received via the first and second receiving antennas 12a and 12b. The reliability of wireless communication between the device 10 and the sensor units U1 to U4 can be ensured accurately.

  As described above, according to the tire pressure monitoring system according to the present embodiment, in addition to the effects (1) to (8) according to the first embodiment, the following effects can be obtained. .

  (9) The first and second receiving antennas 12a and 12b are provided in the vehicle, and a receiving antenna that easily receives a response signal is selected according to the delay times Td1 to Td4. Thereby, since the response signal transmitted from sensor unit U1-U4 can be received suitably via the 1st and 2nd receiving antenna 12a, 12b, between monitoring device 10 and sensor units U1-U4. It is possible to accurately ensure the reliability of wireless communication.

(Other embodiments)
In addition, each said embodiment can also be implemented with the following forms which changed this suitably.
The sensor units U1 to U4 receive the start signal Ss or the first to third command signals Sc1 to Sc3 after the response signal Sr is once transmitted until a predetermined time elapses. The transmission of the response signal Sr based on the above may be prohibited. Specifically, as shown in FIGS. 20A and 20B, the activation signal Ss is transmitted from the monitoring apparatus 10 at time t30, and at the time t31 in response to the activation signal Ss. Assume that the response signal Sr is transmitted from the sensor unit U1 of the right wheel W1. At this time, in the sensor unit U1, during the period from the time t31 when the response signal Sr is transmitted until the timeout time Tout elapses, the activation signal Ss is temporarily transmitted from the monitoring device 10 as indicated by a broken line in the drawing. Even so, the response signal Sr is not transmitted. Further, after the timeout time Tout has elapsed, the response signal Sr is transmitted when the activation signal Ss is transmitted from the monitoring device 10 as indicated by a two-dot chain line in the drawing. Thereby, for example, in an environment where there is noise received via the receiving antenna 26, the situation where the sensor units U1 to U4 misunderstand the noise as the activation signal Ss and repeat the transmission of the response signal Sr is avoided. Therefore, consumption of the batteries of the sensor units U1 to U4 can be suppressed. When the timeout time is provided for the transmission of the response signal Sr as described above, the time interval for continuously transmitting the first to fourth command signals and the activation signal Ss is set longer than the timeout time Tout. It goes without saying that you need to do it. In addition to such a configuration, by sending an appropriate command signal from the monitoring device 10 to the sensor units U1 to U4, the timeout setting of the sensor units U1 to U4 is canceled or the timeout setting is restored. You may make it make it. According to such a configuration, in a situation where the influence of noise is weak, for example, when the vehicle is running, information on the tire air pressure of each of the wheels W1 to W4 can be frequently obtained by canceling the timeout setting. It becomes like this. Further, in a situation that is easily affected by noise, such as when the vehicle is stopped, it is possible to suppress battery consumption of the sensor units U1 to U4 by returning the timeout setting.

  In the first embodiment, when the second command signal is transmitted, the delay time that needs to be reset by appropriately changing the value of the argument included in the signal from the monitoring device 10 to the sensor unit Although the notification is made to U1 to U4, the notification of the delay time that needs to be reset may be omitted. That is, in this case, instead of the process of transmitting the second command signal Sc2, the process of transmitting the first command signal Sc1 may be executed as the process of step S5 of FIG. In short, when it is detected that the response signals transmitted from the sensor units U1 to U4 are interfering with each other, a command signal for transmitting the response signal by randomly determining the delay time is transmitted to the sensor units U1 to U4. Anything to do.

  In the second embodiment, after the delay times of the sensor units U1 to U4 are once determined so that the interference of the response signal Sr does not occur, “delay time Td1 → delay time” in order from the sensor unit having the shortest delay time. The delay times are assigned in the order of “Td2 → delay time Td3 → delay time Td4”. Instead of this, for example, delay times may be allocated in the order of “delay time Td4 → delay time Td3 → delay time Td2 → delay time Td1” in order from the sensor unit with the shortest delay time.

  In the second embodiment, ten delay times Td1 to Td10 are prepared in advance as delay times that can be selected by the sensor units U1 to U4. For example, five to nine delay times, or Eleven types or more of delay times may be prepared in advance.

  In the second embodiment, the delay times Td1 to Td4 are assigned to the sensor units U1 to U4 after the delay times of the sensor units U1 to U4 are once determined so that the response signal Sr does not interfere. However, the process of assigning the delay times Td1 to Td4 to the sensor units U1 to U4 may be omitted. Even with such a configuration, it is possible to obtain the effect (7) described above.

  -If the specific receiving antenna which is easy to receive a response signal according to delay time Td1-Td4 is selected like the said 3rd Embodiment, in the monitoring apparatus 10, certainly from sensor unit U1-U4. The response signal to be transmitted can be appropriately received. However, for example, a situation in which wireless communication between a specific receiving antenna and the sensor unit is hindered afterwards due to, for example, luggage brought into the passenger compartment by a vehicle occupant. In such a situation, if a response signal is received only through a specific receiving antenna, there is a risk that a state in which wireless communication cannot be performed between the monitoring device 10 and the specific sensor unit may continue. is there. Therefore, for example, when it is detected that it is difficult to properly receive the response signal in the period corresponding to the delay times Td1 and Td2 of the sensor units U1 and U2, the second receiving antenna 12a is replaced with the second receiving antenna 12a. The receiving antenna 12b may be selected. Whether or not it is difficult to properly receive the response signal is determined based on, for example, detecting that the response signal cannot be continuously received a plurality of times, or through the RRSI circuit. This is based on detecting that a state in which the signal level is lower than a predetermined threshold continues. According to such a configuration, even if the above situation occurs, wireless communication between the monitoring device 10 and the specific sensor unit can be ensured, and thus the reliability of wireless communication between them can be ensured. Can be increased.

  In the third embodiment, by providing the first and second receiving antennas 12a and 12b in the vehicle and selecting a receiving antenna that can easily receive a response signal according to the delay times Td1 to Td4, The response signal is received via one of the receiving antennas. Instead, for example, the response signals are received via the two receiving antennas 12a and 12b, and the response signals received via these receiving antennas are combined by the vehicle control device 14. Good. According to such a configuration, the response signal transmitted from the sensor units U1 to U4 can be suitably received via the first and second receiving antennas 12a and 12b while omitting the switch 15. It becomes like this. Therefore, the reliability of wireless communication between the monitoring device 10 and the sensor units U1 to U4 can be ensured accurately.

  In the third embodiment, the first and second receiving antennas 12a and 12b are arranged on the front side and the rear side of the vehicle, respectively. Instead, for example, they are arranged on the right side and the left side of the vehicle, respectively. You may do it.

  -In the said 3rd Embodiment and its modification, two receiving antennas from which the arrangement | positioning position in a vehicle differs are each provided as a receiving antenna which can receive the response signal each transmitted from sensor unit U1-U4. I did it. Instead of this, for example, two receiving antennas may be provided, that is, a receiving antenna with directional characteristics on the front wheels W1, W2 side and a receiving antenna with directional characteristics on the rear wheels W3, W4 side. Such a configuration is particularly effective when the tire pressure monitoring system according to the present invention is applied to a vehicle in which it is difficult to place two receiving antennas apart from each other.

  In the third embodiment, the two receiving antennas 12a and 12b are provided in the vehicle, but instead, for example, three or more receiving antennas may be provided in the vehicle. If such a configuration is adopted and a reception antenna that can easily receive a response signal is selected according to the delay times Td1 to Td4, a response signal transmitted from the sensor units U1 to U4 is sent to a plurality of reception antennas. Therefore, the radio communication between the monitoring device 10 and the sensor units U1 to U4 can be more reliably ensured.

  In each of the above-described embodiments, it is determined that all the response signals transmitted from the sensor units U1 to U4 have been received when the response signals having different identification codes are received by the number of the sensor units U1 to U4. I did it. Instead, the fact that all the response signals transmitted from the sensor units U1 to U4 could be received by simply receiving the four response signals without being based on the identification codes of the sensor units U1 to U4. You may make it judge.

  In each of the above embodiments, when determining the delay time of each of the sensor units U1 to U4, any one of a plurality of preset delay times is randomly selected. After a predetermined delay time, a delay time shorter than the longest delay time may be determined at random.

  In each of the above-described embodiments, one transmission antenna 11 is provided in the vehicle as a transmission antenna for transmitting the activation signal Ss and the first to fifth command signals Sc1 to Sc5. For example, two or more transmission antennas may be provided in the vehicle. When two or more transmission antennas are provided in the vehicle as described above, it is not necessary to transmit the start signal Ss and the first to fifth command signals Sc1 to Sc5 to the wheels W1 to W4 at the same time. The activation signal Ss and the first to fifth command signals Sc1 to Sc5 may be transmitted separately for each communication area of the transmission antenna.

The tire pressure monitoring system according to the present invention is not limited to a system that determines which of the sensor units U1 to U4 of the wheels W1 to W4 has transmitted the response signal based on the geomagnetism applied to the vehicle, and is appropriately This method can be applied to a system that determines which sensor unit U1 to U4 of each wheel W1 to W4 has transmitted a response signal. Further, a warning is given when an abnormality occurs in any of the tires of the wheels W1 to W4 without determining which of the sensor units U1 to U4 of the wheels W1 to W4 is the response signal. It is also possible to apply the tire pressure monitoring system according to the present invention to a tire pressure monitoring system that performs the above.
(Appendix)
Next, a technical idea that can be grasped from the above embodiment and its modifications will be additionally described.

  (A) In the tire pressure monitoring system according to claim 9, when the monitoring device determines that it is difficult to receive the response signal via the selected receiving antenna, the monitoring device receives the response signal. A tire pressure monitoring system, wherein the antenna is switched to another receiving antenna different from the selected receiving antenna. As described above, if a specific receiving antenna that can easily receive a response signal is selected in accordance with the delay time set for each sensor unit, the monitoring device can properly respond to the response signal transmitted from the sensor unit. Will be able to receive. However, for example, a situation in which wireless communication between a specific receiving antenna and the sensor unit is hindered afterwards due to, for example, luggage brought into the passenger compartment by a vehicle occupant. In such a situation, if a response signal is received only through a specific receiving antenna, there is a possibility that a state in which wireless communication cannot be performed between the monitoring device and the specific sensor unit may continue. . In this regard, as in the above system, when it is determined that it is difficult to receive the response signal via the selected receiving antenna, the receiving antenna for receiving the response signal is different from the selected receiving antenna. If the switching is performed, the wireless communication between the monitoring device and the specific sensor unit can be ensured even if the above situation occurs, and the reliability of the wireless communication between them is improved. Will be able to.

  A1 ... communication area, Sc ... command signal, Sc1 to Sc5 ... first to fifth command signals, Sr ... response signal, Ss ... start signal, U1-U4 ... sensor unit, W1 ... right front wheel, W2 ... left front wheel, W3 ... right rear wheel, W4 ... left rear wheel, 10 ... monitoring device, 11, 27 ... transmitting antenna, 12, 26 ... receiving antenna, 12a ... first receiving antenna, 12b ... second receiving antenna, 13 ... indicator , 14 ... Vehicle control device, 14a, 25 ... Geomagnetic sensor, 14b ... Vehicle speed sensor, 14c, 28a ... Non-volatile memory, 15 ... Switch, 21 ... Unit body, 21a ... Air hole, 21b ... Sensor hole, 22 ... Valve, 23 ... Air pressure sensor, 24 ... Temperature sensor, 28 ... Control device.

Claims (10)

A sensor unit that detects the tire air pressure of each wheel of the vehicle and wirelessly transmits a response signal including information on the detected air pressure, and an activation signal for causing the sensor unit to transmit the response signal to each wheel. A tire pressure monitoring system comprising: a monitoring device that transmits and monitors the tire pressure of each wheel based on the information on the air pressure included in the response signal when the response signal is received;
When the sensor unit receives a command signal transmitted from the monitoring device, the sensor unit randomly determines a delay time from when the activation signal is received until the response signal starts to be transmitted, and the determined delay The monitoring device transmits the response signal after waiting for a time, and the monitoring device interferes with the response signals transmitted from the plurality of sensor units when the command signal is transmitted to the plurality of sensor units. The tire pressure monitoring system, wherein the command signal is transmitted again to the plurality of sensor units on the condition that the effect is detected. The monitoring device needs to be reset in the delay time determined by the plurality of sensor units based on the presence or absence of interference of the response signal according to the plurality of delay times when the command signal is transmitted. When determining a certain delay time and transmitting the command signal again, the command signal includes information on the delay time that needs to be reset, and the sensor unit transmits the command signal. 2. The tire according to claim 1, wherein when the signal is received, it is determined whether or not to reset the delay time based on information on the delay time that needs to be reset included in the command signal. 3. Air pressure monitoring system. Detection of interference of the response signal is transmitted from the plurality of sensor units in a period from when the command signal is transmitted to the plurality of sensor units until all of the plurality of sensor units complete transmission of the response signal. The tire pressure monitoring system according to claim 1 or 2, which is performed based on detecting that any one of the response signals received is not received. After detecting that all of the plurality of sensor units have completed transmission of the response signal, the longest delay time of the delay time has elapsed since the time when the command signal was transmitted to the plurality of sensor units. The tire pressure monitoring system according to claim 3, further performed based on detecting that a transmission time of one frame of the response signal has elapsed. The plurality of sensor units include identification information set separately for each sensor unit, and transmit the response signal.
Detection that one of the response signals transmitted from the plurality of sensor units cannot be received detects that the response signals including the identification information different from each other cannot be received by the number of the plurality of sensor units. The tire pressure monitoring system according to claim 3 or 4, which is performed based on the above. The determination of the delay time by the sensor unit is performed by randomly selecting one of a plurality of preset delay times with a time interval longer than the transmission time of the response signal. The tire pressure monitoring system according to any one of claims 1 to 5. The tire pressure monitoring system according to claim 6, wherein the predetermined number of the plurality of delay times selected is set to be larger than the number of the plurality of sensor units. The delay time of the plurality of sensor units is once determined so that interference of the response signal does not occur, and then the plurality of delay times are respectively allocated to the plurality of sensor units in order from the shortest. Tire pressure monitoring system. The monitoring device includes a plurality of receiving antennas capable of receiving the response signals transmitted from the plurality of sensor units, respectively, and the response signal is set according to a delay time set for each sensor unit. The tire pressure monitoring system according to any one of claims 1 to 8, wherein a reception antenna that easily receives the signal is selected and the response signal is received via the selected reception antenna. 10. The sensor unit prohibits transmission of the response signal based on reception of the activation signal during a period until a predetermined time elapses after the response signal is transmitted. The tire pressure monitoring system according to claim 1.

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