JP3502481B2 - Automatic meter reading device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic meter reading device for intermittent communication, and more particularly to a method of periodic synchronization, and more particularly to a process when synchronization fails.

[0002]

2. Description of the Related Art Conventionally, various methods have been invented for accurately retransmitting a synchronization signal. For example, the present applicant has previously proposed a method for synchronous recovery of wireless transmission / reception in an automatic meter reading device. This has a structure as shown in FIG.

To explain this, the automatic meter-reading device comprises a first wireless communication device 41 shown in FIG. 3 (a) and a second wireless communication device 42 shown in FIG. 3 (b). . As shown in FIG. 3A, the first wireless communication device 41 has a transmitting / receiving unit 21, a signal generating unit 22, and a PLL unit 2.
3, carrier detection means 31, timing change determination means 3
2, timing control means 33, lock time measuring means 34
And the intermittent control means 35, and the transmission / reception means 21 has a gas flow meter 19 provided in the middle of the gas pipe 18 connected to the home for measuring the amount of gas used in the target home, and the storage means 20. Connected through.

The second wireless communication means 42, as shown in FIG. 3B, is a transmission / reception means 28 and a signal generation means 2.
9, PLL means 30, carrier detection means 36, timing change determination means 37, timing control means 38, lock time measurement means 39, and intermittent control means 40 constitute a second wireless communication device 42, and transmission / reception means 28 includes: The data collecting means 27 is connected. Data collection means 2
A T-NCU 25, which is a telephone line network control device connected to a public telephone line 24, is connected to a transmitting / receiving means 28 via an interface means 26.

These first and second wireless communication devices 41, 42
Are both driven by a battery, and an intermittent receiving system is adopted by the intermittent control means 35 and 40 respectively provided to extend the battery life. The operation of the intermittent control means 35 and the intermittent control means 40 will be described with reference to FIG.

FIG. 4A shows the operation timing of the intermittent control means 40, and FIG. 4B shows the operation timing of the intermittent control means 35. As shown in FIG. 4A, the intermittent control means 40 puts the transmission / reception means 28 into the reception state at the reception operation timing every T1 seconds. T1 second is 30
Seconds. Then, the transmitting / receiving means 28 transmits the synchronization signal at the transmission timing every T2 seconds which is an integral multiple of T1 seconds. T2 seconds are, for example, 10 minutes.

On the other hand, the intermittent control means 35, as shown in FIG. 4 (b), puts the transmitting / receiving means 21 in the receiving state at the receiving operation timing every T1 seconds in synchronization with FIG. 4 (a). Then, the synchronization signal is received every T2 seconds. Upon receiving the synchronization signal, the intermittent control means 35 adjusts its own reception timing to the transmission timing of the intermittent control means 40 based on the received synchronization signal. Thereby, the intermittent control means 3
5 and the transmission / reception timing error between the intermittent control means 40 is T2.
It can be corrected every second.

FIG. 4 (c) shows an interfering signal to the transmitting / receiving means 28. When an interfering signal occurs at the reception timing of every T1 seconds as shown in FIG. 4C, the carrier detecting means 36 detects the occurrence of the interfering signal and notifies the timing change determining means 37. Timing change determination means 37
Then, count how many times there is an interfering signal during T2 seconds,
When a predetermined number of times is exceeded, it is determined that the timing should be changed. Then, the timing control means 38 determines the timing change time.

The timing change time is determined by using the measurement value of the lock time measuring means 39. The lock time measuring means 39 uses the PLL means 30 at the transmission / reception timing.
The time from setting the data to the time until the oscillation frequency of the signal generating means 29 falls within a certain range is measured. This time varies every time depending on environmental conditions such as temperature and various conditions. Therefore, a random value can be obtained.

When the timing change determination means 37 determines that the timing should be changed, the timing control means 38 determines T3 seconds corresponding to the measured value as the timing change time. Then, at the next transmission timing of T2 seconds, the transmission / reception unit 28 notifies the communication partner of the timing change request and the timing change time T3 seconds.

After that, the intermittent control means 40 is controlled to perform the next receiving operation at T3 seconds.

This is shown in FIG. 4 (a). In the example of FIG. 4A, T3 seconds = 15 seconds. On the other hand, when the transmission / reception means 21 receives the timing change request and the timing change time T3 seconds, the intermittent control means 35 sets the next operation time after T3 seconds.

This is shown in FIG. 4 (b). By changing the timing in this way, it is possible to avoid the timing at which an interfering signal is generated thereafter.

In the above description, the wireless communication device 42 is described as being disturbed, but when the wireless communication device 41 is disturbed as well, the operation timing change judging means 3 is similarly provided.
2 and the timing control means 33 determine the timing change and the change time. Then, at the time of transmitting a response signal to the synchronization signal from the wireless communication device 41, the timing change request and the timing change time are transmitted. Based on this, both the wireless communication device 41 and the wireless communication device 42 change the timing time. Note that the timing change time is not determined by the wireless communication device 42, the wireless communication device 42 transmits only the timing change request, and the wireless communication device 41 determines the timing change time based on the measurement value of the lock time measuring means 34. The timing change time is notified to the wireless communication device 42.

Next, a case where the synchronization signal cannot be transmitted / received due to interference in the transmission / reception timing of the synchronization signal will be described with reference to FIG. 5A shows the operation timing of the wireless communication device 42, and FIG. 5B shows the operation timing of the wireless communication device 41. FIG. 5C shows an interference signal.

If interference occurs during transmission / reception of the synchronization signal every T2 seconds, the radio communication device 50 cannot transmit the synchronization signal. Even if the synchronization signal can be transmitted, if the wireless communication device 41 is disturbed, the response signal will not be returned. Therefore, the wireless communication device 42 transmits a synchronization signal as shown in FIG. 5A at the next T1 second timing.

On the other hand, when the radio communication device 41 cannot receive the synchronization signal at the timing of T1 seconds, the intermittent control means 35 operates to receive a plurality of times at the timing of the next T1 seconds as shown in FIG. 5B. I do. FIG. 5D shows the synchronization signal, and FIG. 5E shows the timing of the multiple reception operation of the wireless communication device 41. The receiving operation is performed a plurality of times at shorter intervals than the bit synchronization signal of the synchronization signal. With this configuration, even if the operation timings of the wireless communication device 41 and the wireless communication device 42 are slightly deviated from each other, the bit synchronization signal is detected and synchronized at any one of the multiple reception times of the wireless communication device 41. A signal can be received.

When the activation message is sent from the center device connected to the telephone line 24 to the wireless communication device 42 via the data collection means 27, the activation message is wirelessly communicated via the transmission / reception means 28 at the transmission / reception timing of T1 seconds. To the device 41. The wireless communication device 41 and the wireless communication device 42 enter the communication mode by the activation message.

When the radio communication device 41 receives the activation message, the storage means 20 is activated and the meter reading value data stored in the storage means 20 is transmitted to the radio communication device 50 via the transmission / reception means 21. The meter reading value data received by the wireless communication device 42 is sent to the center device via the data collecting means 27 and the telephone line 24. Thereafter, after the data is exchanged several times between the center device and the storage means 20, when the end message is transmitted from the center device, the wireless communication device 41 and the wireless communication device 42 end the communication mode.

In the communication mode, transmission / reception is performed at a timing of every T4 seconds (for example, 2 seconds) obtained by dividing T1 seconds by an integer. Further, after the data collecting means 27 sends the data to the wireless communication device 42, if the data is not received within a certain time (for example, 10 seconds) from the wireless communication device 42, the data collecting means 27 disconnects from the telephone line 24 due to timeout. is there.

Therefore, the wireless communication device 42 sends a dummy electronic message to the data collecting means 27 before the data collecting means 27 disconnects from the telephone line 24. The data collection means 27 transmits the dummy electronic message to the center device via the telephone line 24. When the center device receives the dummy message, it returns a dummy response. In this way, the time-out of the data collecting means 27 can be avoided.

A time-out time is also set in the center device, and the time-out of the center device is also avoided by the dummy telegram. Storage means 20 and flow meter 19
Is installed in a meter called a micom meter and is already installed in ordinary households. In this microcomputer meter, a timeout time is set for exchanging data with the wireless communication device 41. In order to avoid this timeout, the wireless communication device 41 transmits a retransmission request signal as a dummy message to the storage unit 20. Then, the storage means 20
Transmits the previous data to the wireless communication device 49. This previous data is discarded by the wireless communication device 41 and is not transmitted to the wireless communication device 42.

An example of the case where the synchronization fails for a predetermined number of times or for a predetermined time or more and the synchronization is deviated is described in JP-A-5-252093 as a conventional example of a wireless mobile device. .

This conventional example will be described with reference to FIGS. 6 and 7. As shown in FIG. 6, the wireless mobile device 45 connects to the fixed connection device 44 and a wireless switching center (not shown) by radio waves. The wireless mobile device 45 periodically and intermittently drives the wireless radio wave reception unit to save power.

As shown in FIG. 7, the wireless mobile device 45 receives a radio wave from the fixed connection device 44, a receiving part 53 for controlling the operation, a control part 51 for controlling the operation, and a receiving part for intermittently driving the receiving part 41 with a fixed period. It has a reception period setting timer 54 of a unit driving timer and a transmission unit 52 for transmitting radio waves to the fixed connection device 44.

The conventional fixed connection device 44 is a wireless mobile device 45.
An incoming call detection unit 46 that receives an incoming call to the mobile phone, a control unit 47 that controls the operation, and a transmission unit 4 that sends a radio wave to the wireless mobile device 45
8 and a receiving unit 49 for receiving, and a reception cycle management timer 50 for measuring the reception time of the wireless mobile device 45.

Next, the operation procedure will be described. First, in the wireless mobile device 45, when the power is turned on or the identification signal is registered, the control unit 51 confirms the availability of the wireless control channel, drives the transmission unit 52, transmits the synchronization establishment request signal, and sets the reception cycle. The time measurement of the timer 54 is started, and the reception unit 53 is driven to the radio wave reception state.

The reception cycle setting timer 54 measures the duration T2 of the reception state and the cycle T1 of repeating the reception state, and outputs a drive signal to the receiver 53. The reception cycle setting timer 54 measures the duration T2 of the reception state and the cycle T1 of repeating the reception state, and outputs a drive signal to the reception unit 53. When the receiving unit 53 receives the incoming call signal before the reception period setting timer 54 has elapsed the duration T2, the control unit 51 executes the incoming call process.

When the duration T2 has elapsed, the control unit 51
Stops the receiving state of the receiving unit 53. When the cycle T1 has elapsed, the control unit 51 returns the time measurement of the reception cycle setting timer 54 to the initial state and restarts it.

On the other hand, in the fixed connection device 44, the reception cycle management timer 50 is the reception cycle setting timer 5 of the wireless mobile device 45.
Similar to 4, the reception state duration T2 and the cycle T1 of the wireless mobile device 45 are measured. When the receiver 49 receives the synchronization establishment request signal, the controller 47 resets the measurement of the reception cycle management timer 50 to the initial value and restarts the measurement. When the incoming call detection unit 54 receives the incoming call signal, the control unit 47 controls the reception cycle management timer 5
An incoming signal is sent to the idle control channel for a duration T2 of zero.

[0031]

However, even in the above-mentioned proposal and the conventional invention, it is conceivable that interference occurs every time the synchronization signal is transmitted. That is, even if the intermittent timing is shifted or the receiving operation time on the receiving side at the intermittent timing is lengthened, it is impossible to cope with the occurrence of interference each time.

That is, the flow meter 19 and the data collecting means 27
Even if there is no interference when transmitting communication data from, it cannot be said that interference may occur only when transmitting and receiving the synchronization signal.

On the other hand, considering the entire automatic meter-reading apparatus, it is necessary to determine in advance what kind of processing is to be performed when synchronization cannot be performed for a predetermined time or more. In other words, if synchronization is not performed for a certain period of time, the clocks of the other devices will be displaced due to the oscillation accuracy of the crystal itself or the oscillation accuracy that changes due to changes in the environment, and it will inevitably be impossible to send and receive synchronization signals. .

Therefore, before that, the abnormality of the operating state is visually displayed to the outside, and in the automatic meter-reading apparatus of the previously proposed example, the data collecting means 27 is provided via the T-NCU 25.
I have to inform you.

At the same time, in general, the device ends the wireless communication operation and shifts to the operation of notifying the abnormal operation state. In other words, in order to return to the original operating state when the state becomes out of synchronization, it is necessary to go to the site where the device is installed and turn on the power again.

The device connected to the telephone line 24 can be restored by communication from the data collecting means 27, but the device connected to the flow meter 27 cannot communicate in the wireless section, so that the device can be restored. There is a problem that the return operation in is essential.

On the other hand, when the conventional mobile radio device is used, the fixed connection device 44 has the reception cycle management timer 50 corresponding to each radio mobile device 45, and the radio mobile device 45 requests synchronization establishment first. Since the signal is transmitted and the time measurement is started together with the built-in timer, the fixed connection device 44 and the mobile wireless device 53 are separated from each other when the power supply for transmitting the synchronization establishment request signal and the identification signal registration are delayed. There is a problem that the timers of both of them are often out of synchronization, and the transmission of the synchronization establishment request signal leads to power consumption of the wireless mobile device 45.

[0038]

According to a first aspect of the invention, in order to automatically return to the initial mode even if synchronization correction fails, the flow rate integrated value of the meter and the like are wirelessly data-communicated. The wireless communication means B has a wireless communication means A for performing wireless data communication between the wireless communication means B and information transmission with a line terminal device, and the wireless communication means A and B wirelessly perform data communication. A wireless communication unit for activating the wireless communication unit, a first operation mode control unit for activating the wireless communication unit, and a first operation mode control unit for setting the activation signal detection unit in an operating state when the power is turned on and for inactivating the wireless communication unit; A second operation mode control unit that performs initial synchronization for intermittent communication between the wireless communication units A and B after the activation signal is detected, and intermittent synchronization correction is performed at predetermined time intervals after the completion of initial synchronization. Went A third operation mode control unit that enables communication and a central control unit that controls each unit are respectively provided, and the central control unit has a predetermined time or number of times for synchronization correction in the third operation mode control unit. It is characterized in that the first operation mode control unit is operated when the above-mentioned failure occurs.

According to the invention of claim 2, in addition to the invention of claim 1, the central control of the wireless communication means A is intended to avoid the inconvenience that the center cannot recognize due to the automatic response when the synchronization correction fails. When the synchronization correction in the third operation mode control unit fails for a predetermined time or more times, the unit activates the first operation mode control unit and informs the line terminal device of the failure of the synchronization correction. Try to make a report.

Other objects and features will be made clear by the following description and drawings.

[0041]

In the above configuration of the invention of claim 1, each of the first to third operation mode control units in the wireless communication means A and B is controlled by the corresponding central control unit, and the power is turned on. The operation mode control means 1 sets the wireless communication means A and B in a so-called sleep mode in which the activation signal detection means is activated and the wireless communication section is deactivated. Next, after the activation signal detection means of the wireless communication means A and B detect an artificial activation signal by a switch or the like,
The second operation mode control section operates to operate the wireless communication means A, B.
Is set as a second operation mode to perform initial synchronization for intermittent communication between the two. When the initial synchronization is completed, the third operation mode control unit operates to intermittently perform synchronization correction at predetermined time intervals so that communication can be performed. However, if this synchronization correction fails for a predetermined time or more times, the central control unit activates the first operation mode control unit to stop the operation of the wireless communication unit, and again enters the sleep signal waiting state for the activation signal. Since it is automatically returned, communication can be restarted from the start without any special recovery operation, and the inconvenience of having to keep artificially avoiding the state where synchronization correction fails and wasteful work before avoiding it. Power consumption can be prevented.

According to the above configuration of the invention of claim 2,
In addition, when the synchronization correction by the third operation mode control unit fails, the central control unit of the wireless communication means A activates the first operation mode control unit, and the synchronization correction failure message is transmitted. Since the notification is sent to the terminal device, even if the synchronization correction fails automatically, the center side recognizes that the synchronization correction has failed and is in the state of waiting for the start signal detection, and various measures and management are immediately performed. Therefore, the reliability can be improved.

[0043]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT An embodiment of an automatic meter reading device of the present invention will be described below with reference to FIGS. The automatic meter-reading device is composed of a meter-reading side wireless communication means A shown in FIG. 1A and a meter-reading side wireless communication means B shown in FIG. ing.

The wireless communication means B on the side of the needle to be inspected is shown in FIG.
As shown in (1), it is connected to a meter 1 having a communication function with the outside that measures a flow rate value and performs remote control. As shown in FIG. 1A, the wireless communication means A on the meter-reading side is connected to a T-NCU3 which is a telephone line network control device for performing communication with a telephone line, and a telephone line is connected to the T-NCU3. A data collection means 4 for communicating via is connected.

Here, the wireless communication unit B may have the meter 1 and the wireless communication unit A may have the T-NCU 3 therein.

As shown in FIG. 1A, the wireless communication means A has a first operation mode control section 6 which is activated when the power is turned on.
A second operation mode control unit 7 which is operated when a start signal is received in the first operation mode, and a second operation mode control unit 7 which operates after initial synchronization in the second operation mode and performs synchronization correction for communication. 3 operation mode control unit 8, a wireless communication unit 10 that exhibits the wireless function, a start signal detection unit 11 that detects the start signal, and the first to third operation control units 6 to 8 and wireless. Communication unit 10 and activation signal detection means 1
1 and a central control unit 9 for controlling the control unit 1.

When the first operation mode control unit 6, the second operation mode control unit 7, the third operation mode control unit 8 and the central control unit 9 each use a microcomputer, All of them can be the internal functions of one microcomputer, or they can be divided into various functions by appropriate control means in place of them.

The wireless communication means B is, as shown in FIG. 1B, a first operation mode control section 1 which is activated when the power is turned on.
2 and the second operation mode control unit 13 that operates when there is a start signal in the first operation mode, and the second operation mode controller 13 that operates after the initial synchronization in the second operation mode and performs synchronization correction for communication. 3 operation mode control unit 14, a wireless communication unit 16 that exhibits the wireless function, a start signal detection unit 17 that detects the start signal, the first to third operation control units 12 to 14, and wireless It has a communication section 16 and a central control section 15 for controlling the activation signal detecting means 17. The configuration of each of these control units can be variously configured similarly to the case of the wireless communication means A.

The operation of these wireless communication means A and wireless communication means B is as shown in the flow chart of FIG.

This will be described. When the power is turned on in step # 1, the wireless communication means A and the wireless communication means B are connected to the first operation mode control unit 6 as shown in step # 2.
12 becomes the first operation mode. This first operation mode is called a "sleep mode". In this "sleep mode", for example, the power supply of the wireless communication unit that performs wireless communication with the wireless communication unit on the other side and the wired unit that communicates with the meter 1 or the T-NCU 3 are all turned off, and the activation signal detection unit 11 , 17 ON
It is in the ultra-low power consumption operating state.

From this "sleep mode", if there is a manual operation of a switch or the like in the wireless communication means A and B, the wireless communication means on the side where this is discriminated by its own central control unit as in step # 4, now wireless communication. Assuming that the central control unit 9 of the means A determines first, in the wireless communication means A, whether the second operation mode control unit 7 of itself operates in place of the first operation mode control unit 6 as in step # 5. Then, the second operation mode is set. This second operation mode is called a so-called "initial synchronization mode". This "initial synchronization mode" is a mode in which wireless communication between the wireless communication means A and the wireless communication means B is synchronized. That is, the wireless communication unit A is in the continuous transmission state of the initial synchronization signal by the wireless communication unit 10 in the "initial synchronization mode", and is in the state of waiting for the response signal from the wireless communication unit B. On the other hand, the wireless communication means B has a second delay due to manual operation delayed from the wireless communication means A.
The operation mode is set to the reception state.

Here, the operation of the wireless communication means A is an operation on the center side, and the operation of the wireless communication means B is an operation on each process side. Usually, the worker on the center side uses the wireless communication means A.
After the start of the wireless communication is completed, the wireless communication means B on each home side is sequentially started by the patrol worker so that the center side can grasp the situation in which the wireless communication means B becomes the communication state by the start. However, the order is not limited to this, and the boot order can be reversed.

When the wireless communication means B receives the initial synchronization signal sent from the wireless communication means A by the wireless communication section 16 as in step # 6, a response signal to the initial synchronization signal is shown in step # 7. After transmitting from the wireless communication unit 16 to the wireless communication means B5 as described above, the third operation mode control unit 14 shifts to the third operation mode.
This third operation mode is called "data communication mode". The series of operations of the wireless communication means B2 is performed by the central control unit 1.
Controlled by 5.

At this time, since the wireless communication means A is waiting for the initial synchronization response signal sent from the wireless communication means B by the operation in step # 5 described above, the initial synchronization response signal is received. Is received by the wireless communication unit 10, and the wireless communication device B enters the third operation mode as shown in step # 7. The above-described series of operations of the wireless communication means A is controlled by the central control unit 9.

As described above, both the wireless communication means A and B are in the third operation mode. This third operation mode is the "data communication mode". In the "data communication mode", the wireless communication units 10 and 16 of the wireless communication means A and B operate intermittently as shown in step # 8. That is,
The wireless communication unit 10 and the wireless communication unit 16 are powered on only at the time of a periodical clock adjustment operation or when communication is started from the meter 1 or the data collection unit 4 and the data is transmitted to the wireless communication unit on the other side. Others are low power operation.

In this "data communication mode", the periodic synchronization communication may fail for various reasons as described in the description of the prior art. In this case, it suffices if the synchronous communication can be performed again and recovered. However, if the synchronous communication fails for a certain period of time or a certain number of times or more, the clocks of the wireless communication means A and the wireless communication means B are deviated from each other. Cannot communicate.

In this case, this is determined in step # 9, the process proceeds to step # 11, and since the communication has not been completed, the wireless communication means A indicates NG as the NG of the synchronous communication in step # 12. -Notifying the data collecting means 4 through the NCU 3 and returning to the "sleep mode" of step # 2. Therefore, communication can be restarted from the start without any special recovery operation, and the inconvenience of artificially avoiding the state where the synchronization correction fails and the unnecessary power consumption until avoiding are prevented. can do.

Further, even if the synchronization correction fails automatically, the center side is made aware that the synchronization correction has failed and is in the state of waiting for the start signal detection, so that various measures and management can be performed immediately. Therefore, the reliability can be improved.

In the present embodiment, the wireless communication means A
The operation in which the positions of the wireless communication means B are switched, that is, the operation when the wireless communication means B is activated first can be performed in the same manner. In this case, the wireless communication means B2 transmits the synchronization signal, and after step # 4, step # 4
After 5a to # 7a, the process proceeds to step # 8. Also,
Meter 1, wireless communication means B, wireless communication means A, T-NC
It is conceivable that there are a plurality of U3s and data collecting means 4 and that intermittent operation is performed in the area. Also in this case, the automatic meter reading device can be assembled in the same manner by using the specific wireless communication means as the base station.

Further, in the above embodiment, the automatic meter reading of the household gas flow meter 1 is described, but the present invention is not limited to this, and may be adopted for household electric meters and various individual meters thereof.

[0061]

According to the invention of claim 1, the wireless communication means A and B are activated from the sleep mode which is the first operation mode to the second operation mode, and the wireless communication means A and B are connected to each other. In order to perform initial synchronization for intermittent communication and to perform communication by intermittently performing synchronization correction at every predetermined time, if this synchronization correction fails for a predetermined time or more times, wireless communication is performed. Since the operation of the part is stopped and it automatically returns to the state of the sleep mode waiting for the activation signal to be detected again, communication can be restarted from the startup without special recovery operation, and the state of synchronization correction failure continues as it is. The inconvenience that you have to avoid artificially,
It is possible to prevent wasteful power consumption until avoidance.

According to the invention of claim 2, in addition to the invention of claim 1, if the synchronization correction by the third operation mode control unit fails, the line terminal is returned to the sleep mode and the failure of the synchronization correction is notified. Since it notifies the device, even if the synchronization correction fails automatically, the center side recognizes that the synchronization correction has failed and is in the state of waiting for a start signal detection, and various measures and management are immediately performed. Thus, the reliability can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing an automatic meter-reading device as an embodiment of the present invention.

FIG. 2 is a flow chart showing an automatic meter reading operation by the apparatus of FIG.

FIG. 3 is a block diagram showing a wireless communication device as a first conventional example.

FIG. 4 is an operation timing chart of the wireless communication device in the above proposed example.

FIG. 5 is another operation timing chart of the wireless communication device in the above proposed example.

FIG. 6 is a block diagram of an intermittent communication device using a wireless mobile device in a conventional example.

FIG. 7 is a block diagram of each of a fixed connection device and a mobile wireless device that constitute an intermittent communication device in a conventional example.

[Explanation of symbols]

A, B wireless communication means B 1 meter 3 T-NCU 4 Data collection means 6, 12 First operation mode controller 7, 13 Second operation mode control unit 8, 14 Third operation mode control unit 9, 15 Central control unit 10, 16 Wireless communication section 11, 17 Starting signal detecting means

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI H04M 11/00 301 H04L 7/02 B (72) Inventor Masahiro Yamamoto 1006 Kadoma, Kadoma-shi, Osaka Prefecture Matsushita Electric Industrial Co., Ltd. (72) Terue Matsumura, 1006 Kadoma, Kadoma City, Osaka Prefecture, Matsushita Electric Industrial Co., Ltd. (72) Yoshio Horiike, 1006, Kadoma, Kadoma City, Osaka Prefecture (72) Inventor, Fujiwara Jun 1-5-20 Kaigan, Tokyo Minato-ku Tokyo Gas Co., Ltd. (72) Inventor Kiyohisa Ishikawa Tokyo 1-5-20 Minato-ku Kaigan, Tokyo Gas Co., Ltd. (72) Inventor Hajime Furusawa Tokyo Port 1-5-20 Kaigan, Tokyo Gas Co., Ltd. (72) Inventor Masahiro Yasui 4-1-2, Hiranocho, Chuo-ku, Osaka-shi, Osaka Prefecture Osaka Gas Co., Ltd. (72) Inventor, Akihiko Yokoyama Toho Gas Co., Ltd. 19-18 Sakurada-cho, Atsuta-ku, Nagoya-shi, Japan (72) Inventor Koichi Ikegawa 19-18 Sakurada-cho, Atsuta-ku, Nagoya-shi, Aichi Toho Gas Co., Ltd. (56) Reference JP 5 -259977 (JP, A) JP-A-5-252093 (JP, A) JP-A-7-67164 (JP, A) JP-A-7-143580 (JP, A) (58) Fields investigated (Int.Cl) . ⁷ , DB name) H04L 7/10 G08C 15/06 H04B 7/24 H04B 7/26 H04L 7/033 H04M 11/00 301

Claims (2)

(57) [Claims] 1. A wireless communication unit B for wirelessly performing data communication of a flow rate integrated value of a meter and the like, and wireless communication for wirelessly data communication between the wireless communication unit B and information transmission with a line terminal device. The wireless communication means A and B have means A, and the wireless communication means A and B wirelessly communicate data, a start signal detection means for starting the wireless communication portion, and the start signal detection means in an operating state when power is turned on. A first operation mode control unit that puts the wireless communication unit into a non-operation state; and a second operation mode control unit that performs initial synchronization for intermittent communication between the wireless communication units A and B after detection of a start signal, After the completion of the initial synchronization, a third operation mode control unit that intermittently performs synchronization correction at predetermined time intervals to enable communication and a central control unit that controls the respective units are provided, and the central control unit The automatic meter-reading device, wherein the control unit activates the first operation mode control unit when the synchronization correction in the third operation mode control unit fails for a predetermined time or more times. 2. The central control unit of the wireless communication means A activates the first operation mode control unit when the synchronization correction in the third operation mode control unit fails for a predetermined time or more times. At the same time, the automatic meter-reading device according to claim 1, which notifies the line terminal device of the fact that the synchronization correction has failed.