JP3288162B2 - Wireless system for automatic meter reading - 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 system for collecting data such as gas, water, and electricity usage from a terminal device to a center device using a telephone line. The present invention relates to a wireless system for automatic meter reading that is partially wireless so that devices can be connected via a wireless line.

[0002]

2. Description of the Related Art An automatic meter reading radio system of this type calls a terminal network controller by a no-ringing communication method from a center device via a telephone line, and further calls the terminal device from the terminal network controller via a radio line. And collects data from the terminal device via the reverse route in the center device, or calls a terminal network control device via a wireless line from the terminal device in response to a call request from the terminal device, The center device is called from the terminal network control device via a telephone line, and data from the terminal device is collected in the center device.

In such a wireless system for automatic meter reading,
A wireless device is connected to each of the terminal device and the terminal network control device, so that the terminal device and the terminal network control device communicate with each other via a wireless line using the respective wireless device. More specifically, a master unit of a wireless device that is a network control wireless device (hereinafter, referred to as a master wireless device) is connected to the terminal network control device connected to the telephone line,
The terminal device is connected to a slave unit of a wireless device that is a terminal wireless device (hereinafter, referred to as a child wireless device), and the terminal network control device and the terminal device wirelessly communicate via a parent wireless device and a child wireless device, respectively. Perform communication.

As described above, in the wireless system for automatic meter reading using a wireless line, it is difficult to use a commercial power supply of 100 V AC as an operating power supply for the parent wireless device and the child wireless device due to its installation conditions and the like. Is a necessary condition.

[0005] As described above, the communication method of the automatic meter reading wireless system using the battery-operated parent wireless device and the child wireless device includes a method of using both the parent wireless device and the child wireless device in order to minimize battery consumption. Built-in clock synchronized with
Only when a predetermined wireless communication time has come, the wireless device is activated to perform wireless communication between the two wireless devices, thereby reducing battery consumption.

In such a method, in performing wireless communication, it is premised that the clocks incorporated in the master wireless device and the slave wireless device are completely the same, but the respective clocks are independent. Therefore, when used for a long time, a time lag occurs, and a means for correcting this time lag is required. As a method of correcting such a time lag, for example, a method of performing wireless communication for clock synchronization of a master wireless device and a slave wireless device at a rate of about once a day has been conventionally considered.

[0007] Such clock synchronization communication between the parent wireless device and the child wireless device is indispensable in performing battery-driven wireless communication. If the clock synchronization cannot be performed, the time lag increases. As a result, there is a possibility that wireless communication cannot be performed. Therefore, it is the point of the automatic meter reading wireless system that this time synchronization synchronization communication is reliably performed.

The radio used in the automatic meter reading radio system uses a specific low-power radio (transmission output of 10 mW or less) having a relatively large transmission output, and its radio range is about 100 even in a general urban area. Meters, and the wireless device for the automatic meter reading wireless system is gas,
When installed in a general home for meter reading of water, electricity, etc., a plurality of wireless devices may be present in the wireless reachable area.

[0009]

As described above, when clock synchronization synchronization communication is performed between the master wireless device and the slave wireless device at a rate of, for example, about once a day, a plurality of wireless communication areas are located within the wireless reachable area. When the device exists, there is a problem that the wireless communication of another system may collide, and the clock synchronization between the parent wireless device and the child wireless device may not be performed properly.

[0010] The present invention has been made in view of the above,
The purpose is to enable reliable clock synchronization communication without interference with other systems even when a plurality of wireless devices are present in the wireless reach area, and thus to perform wireless communication reliably. It is an object of the present invention to provide a wireless system for automatic meter reading.

Another object of the present invention is to provide a radio system for automatic meter reading that can easily synchronize the clocks of a master radio device and a slave radio device when a radio device is installed.

Still another object of the present invention is to provide an automatic meter reading radio system capable of appropriately correcting a slight time lag between the clocks of the master radio device and the slave radio device.

[0013]

Further, the radio system for automatic meter reading according to the present invention is connected from a center device to a terminal network control device via a telephone line, and transmitted from the network control radio device connected to the terminal network control device to the terminal device. A terminal device is called via a terminal wireless device connected to the terminal device, data is collected from the terminal device by a center device, and a clock circuit incorporated in each of the network control wireless device and the terminal wireless device and synchronized with each other. Wireless communication for data collection and wireless communication for synchronizing the clock circuit at a predetermined time based on the time of the automatic meter reading, wherein the storage means stores the clock synchronization communication time for each customer Setting means for setting the clock synchronization communication time for each customer stored in the storage means in the wireless device of the customer; and clock synchronization set by the setting means. Becomes a signal time, and summarized in that and a radio communication execution means combined clock synchronization for implementing the wireless communication combined clock synchronization between the network control wireless device and the terminal for the wireless device.

Further, the wireless system for automatic meter reading according to the present invention connects a center device to a terminal network control device via a telephone line, and transmits a signal from the network control wireless device connected to the terminal network control device to the terminal device. A terminal device is called via a terminal wireless device connected to the terminal device, data is collected from the terminal device by a center device, and a clock circuit incorporated in each of the network control wireless device and the terminal wireless device and synchronized with each other. Wireless communication for data collection and wireless communication for synchronizing the clock circuit at a predetermined time based on the time of the automatic meter reading, wherein the network control wireless device is periodically transmitted from the center device. Storage means for storing the time at which the meter reading request is received by the no-ringing communication as a clock synchronization communication time, and clock synchronization communication stored in the storage means. Becomes a time, and summarized in that and a radio communication execution means combined clock synchronization for implementing the wireless communication combined clock synchronization between the network control wireless device and the terminal for the wireless device.

Still further, the automatic meter reading radio system of the present invention connects a center device to a terminal network control device via a telephone line, and transmits a signal from the network control radio device connected to the terminal network control device to the terminal device. A terminal device is called via a terminal wireless device connected to the device, data is collected from the terminal device by a center device, and the network control wireless device and the terminal wireless device are respectively built in and synchronized with each other. A wireless system for automatic meter reading that performs wireless communication for data collection at a predetermined time based on the time of a circuit and wireless communication for synchronizing the clock circuit, wherein the network control wireless device is provided by a no-ringing communication from a center device. Storage means for storing the meter reading call date and time data transmitted at the time of a meter reading request as a clock synchronization communication time; Becomes a communication time, it is summarized in that and a radio communication execution means combined clock synchronization for implementing the wireless communication combined clock synchronization between the network control wireless device and the terminal for the wireless device.

According to the wireless metering system of the present invention, a center device connects to a terminal network control device via a telephone line, and a network control wireless device connected to the terminal network control device connects to a terminal device. The terminal device is called via the specified terminal wireless device, data is collected from the terminal device by the center device, and the time of the clock circuit incorporated in the network control wireless device and the terminal wireless device is synchronized with each other. A wireless communication for data collection and a wireless communication for synchronizing the clock circuit at a predetermined time based on a wireless communication system for automatic meter reading, wherein the network control wireless device transmits a test communication request from a master device setting device. In response, the terminal wireless device continuously transmits transmission data to which information for identifying the number of transmissions is added, and the terminal wireless device transmits the transmission data in response to the test communication request from the slave unit setting device. Initiate a carrier sense operation for detecting a carrier, receive transmission data from the network control wireless device, identify the last transmission data from transmission frequency information included in the received transmission data, and A gist is that a response is sent back a predetermined time after reception, and the time when the response is completed is set as a start time of a time interval until the next wireless communication, thereby providing a means for performing clock synchronization when the wireless device is installed.

Further, the radio system for automatic meter reading of the present invention connects a center device to a terminal network control device via a telephone line, and transmits a signal from the network control radio device connected to the terminal network control device to the terminal device. A terminal device is called via a terminal wireless device connected to the terminal device, data is collected from the terminal device by a center device, and a clock circuit incorporated in each of the network control wireless device and the terminal wireless device and synchronized with each other. A wireless communication for data collection and a wireless communication for synchronizing the clock circuit at a predetermined time based on the time of the automatic meter reading, wherein the network control wireless device performs a test from a base unit setting device. In response to the communication request, the terminal wireless device continuously transmits transmission data to which information for identifying the number of transmissions is added, and responds to the test communication request from the slave unit setting device. Starts a carrier sense operation for detecting a transmission carrier, receives transmission data from the network control radio device, and transmits the final data from the partner radio device based on the transmission count information included in the received transmission data. A response is returned after a predetermined time from the final transmission data transmission end time, and the response completion time is set as a start time of a time interval until the next wireless communication, thereby setting a wireless device installation time. The gist of the present invention is to have a means for synchronizing the clocks.

Further, the wireless system for automatic meter reading according to the present invention connects a center device to a terminal network control device via a telephone line, and transmits a signal from the network control wireless device connected to the terminal network control device to the terminal device. A terminal device is called via a terminal wireless device connected to the terminal device, data is collected from the terminal device by a center device, and a clock circuit incorporated in each of the network control wireless device and the terminal wireless device and synchronized with each other. Wireless communication for data collection and wireless communication for synchronizing the clock circuit at a predetermined time based on the time of the automatic meter reading wireless system, wherein the network control wireless device is information for identifying the number of transmissions Has a means for transmitting the transmission data with the added, the terminal wireless device starts a carrier sense operation for detecting the transmission carrier from the network control wireless device, The transmission data from the control wireless device is received, the last transmission data is identified from the transmission count information included in the received transmission data, and the time from the start of reception to the completion of the final transmission data reception is measured. The point is to have a means for correcting the time from the start to the next wireless communication.

Still further, the automatic meter reading wireless system of the present invention connects a terminal device to a terminal network control device via a telephone line, and transmits a signal from the network control wireless device connected to the terminal network control device to the terminal device. A terminal device is called via a terminal wireless device connected to the device, data is collected from the terminal device by a center device, and the network control wireless device and the terminal wireless device are respectively built in and synchronized with each other. An automatic meter reading wireless system that performs wireless communication for data collection and synchronization wireless communication of the clock circuit at a predetermined time based on the time of a circuit, wherein the network control wireless device is for identifying the number of transmissions. Means for transmitting transmission data to which information has been added, and the terminal wireless device starts a carrier sense operation for detecting a transmission carrier from the network control wireless device. , While receiving the transmission data from the network control wireless device, measuring the time from the start of reception to the completion of reception, and measuring the time from the transmission count information included in the received transmission data until the final transmission data is transmitted. It is essential to have means for calculating the time from the calculated time to the time until the next wireless communication is performed.

[0021]

In the radio system for automatic meter reading of the present invention, the clock synchronization communication time for each customer is stored, and the clock synchronization communication time for each customer is set in the wireless device of the customer. When the clock-synchronized communication time is reached, the wireless communication for network control and the wireless device for the terminal perform clock-synchronized wireless communication.

Further, in the radio system for automatic meter reading according to the present invention, the network control radio device stores the time at which a meter reading request is received from the center device by the no-ringing communication periodically as a clock synchronization communication time, and this storage is performed. When the clock synchronized communication time comes, the wireless communication for network synchronization and the wireless device for the terminal perform the clock synchronized wireless communication.

Further, in the automatic meter reading radio system of the present invention, the network control radio device stores the meter reading call date and time data transmitted at the time of a meter reading request by the no ringing communication from the center device as a clock synchronization communication time. When the stored clock synchronization communication time comes, the clock synchronization wireless communication is performed between the network control wireless device and the terminal wireless device.

In the automatic meter reading radio system of the present invention, the network control radio device continuously transmits transmission data to which information for identifying the number of transmissions is added in response to a test communication request from the master unit setting device. In response to the test communication request from the slave unit setting device, the terminal wireless device starts a carrier sense operation for detecting a transmission carrier and receives transmission data from the network control wireless device. Then, the final transmission data is identified from the transmission count information included in the received transmission data, a response is returned a predetermined time after the reception of the final transmission data, and the response completion time is set at the start of the time interval until the next wireless communication. At this time, the clock synchronization at the time of installing the wireless device is performed.

In the automatic meter reading wireless system according to the present invention, the network control wireless device responds to a test communication request from the master unit setting device and transmits transmission data to which information for identifying the number of transmissions is added. Transmitting continuously, the terminal wireless device starts a carrier sense operation for detecting a transmission carrier in response to a test communication request from the slave unit setting device,
Receives transmission data from the network control wireless device, calculates the time until the final data is transmitted from the partner wireless device from the transmission count information including the received transmission data,
A response is returned after a predetermined time from the final transmission data transmission end time, and the time at which the response is completed is set as the start time of the time interval until the next wireless communication, thereby performing clock synchronization when the wireless device is installed.

Further, in the automatic meter reading radio system according to the present invention, the network control radio device has means for transmitting transmission data to which information for identifying the number of transmissions is added, and the terminal radio device has a network control radio device. A carrier sense operation for detecting a transmission carrier from the radio device is started, transmission data from the network control radio device is received, and final transmission data is identified from transmission frequency information included in the received transmission data. , The time from the start of reception to the completion of reception of the final transmission data is measured, and the time from the measured time to the next wireless communication is corrected.

Still further, in the automatic meter reading radio system according to the present invention, the network control radio device has means for transmitting transmission data to which information for identifying the number of transmissions has been added, and the terminal radio device has a network control radio device. To start the carrier sense operation for detecting the transmission carrier from the wireless device for receiving, while simultaneously receiving the transmission data from the wireless device for network control, measuring the time from the start of reception to the completion of reception, the received The time until the final transmission data is transmitted is calculated from the transmission frequency information included in the transmission data, and the time until the next wireless communication is performed is corrected from the calculated time.

[0029]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the entire configuration of a wireless system for automatic meter reading according to a first embodiment of the present invention. The wireless system for automatic meter reading shown in FIG. 1 is installed in, for example, a general home, and collects meter reading data from a meter 29 which is a terminal device for metering usage of gas, water, electricity, etc., in a center device 21. The meter 29 is connected to the child wireless device 28, connected to the parent wireless device 27 via a wireless line from the child wireless device 28, and connected to the terminal network control device (T-NCU) 26 from the parent wireless device 27. It is connected to the exchange 24 through the switch. The center device 21 is connected to the exchange 24 via a network controller for center (C-NCU) 22 or a network controller for automatic incoming call (MA-NCU) 23. Switch 24 has no ringing trunk 2
5 is connected.

The center device 21 includes the storage device 10.
This storage device 10 stores a clock synchronization communication time setting file 211 for each customer, a meter reading date and time setting file 212 by no-ringing communication for each customer, and a meter reading call date and time setting file 213 for each customer. I am getting it.

In the above configuration, when the center device 21 attempts to collect meter reading data from the meter 29, the center device 21 transmits the data via the center network control device 22, the exchange 24, and the no-ringing trunk 25. When no ringing is received by the terminal network controller 26 and the terminal network controller 26 requests the parent wireless device 27 for meter reading data, the parent wireless device 27 sends the meter reading data to the meter 29 via the child wireless device 28. A request is made, and the meter reading data from the meter 29 is transmitted along the reverse route.
Will be collected.

When collecting data or transmitting information to the center device 21 by calling a terminal from the meter 29, when the meter 29 makes a call request to the child radio device 28, the child radio device 28 The wireless device 27 is called, and the terminal network control device 26, the exchange 24,
An incoming call arrives at the center device 21 via the automatic incoming call network control device 23, whereby meter reading data or information from the meter 29 can be transmitted to the center device 21.

FIG. 2 is a block diagram showing a detailed internal configuration of parent wireless device 27 and child wireless device 28 shown in FIG. Note that the parent wireless device 27 and the child wireless device 28 are shown in FIG.
Have the same circuit configuration as shown in FIG.

As shown in FIG. 2, the master radio apparatus 27 and the slave radio apparatus 28 have an antenna 11 for a radio, and the antenna 11 is connected via a radio section (RF) circuit 12 to a modem (modem). 13 is connected. Modulation / demodulation circuit 13
Is supplied with transmission data from the CPU 14 and supplies received data to the CPU 14. The CPU 14 is connected to a clock circuit 17, a clock synchronization communication time / communication channel setting circuit 18, a call code setting circuit 19, and an interface circuit 20. Further, a battery 16 which is an operation power supply of the wireless device is directly connected to the CPU 14, but is connected to the wireless circuit 12 and the modulation / demodulation circuit 13 via the power switch 15, whereby the wireless circuit 12 and the modem are connected. The supply of the operating voltage from the battery 16 to the circuit 13 is controlled by the CPU 14.

The radio unit circuit 12 is, for example, 400 MHz
This circuit performs FM modulation and demodulation in the z radio frequency band.
The modulation / demodulation circuit 13 modulates the digital signal from the CPU 14 into an analog signal in a voice band (300 Hz to 3.4 kHz band) such as a binary FSK signal or an MSK signal, or demodulates the reverse.

The clock circuit 17 is a circuit for managing the time of the wireless device. For example, the clock circuit 17 has a time period for performing a carrier sense operation for periodically detecting whether or not there is a transmission from the partner wireless device ( Cycle) or, in the case of the parent wireless device 27, the clock synchronization synchronization communication time and communication channel setting circuit 1
8, a clock synchronization communication time is set, and at this communication time, a start signal is output from the clock circuit 17 to the CPU 14.

The clock synchronization synchronizing communication time and communication channel setting circuit 18 is a circuit for setting the clock synchronizing communication time and the communication channel for performing the clock synchronizing communication. The call code setting circuit 19 is a circuit for setting an identification code of the wireless device. When using the radio of the low power security standard (RCR STD-30), it is necessary to previously set an ID number, which is a 12-digit number, provided by an RCR (Radio System Development Center) for each wireless device. is there.

The interface circuit 20 includes the parent wireless device 2
7 is an interface circuit for connecting to the terminal network control device 26, and the slave radio device 28 is an interface circuit for connecting to the meter 29. For example, level conversion of the data signal from the processor 29 is performed.

Further, the CPU 14 has a function of constantly stopping its operation and starting its operation in response to a start signal from the clock circuit 17, and also receives a signal from the meter 29 or the terminal network control device 26 through the interface circuit 20. It has a function to start operation when a message is received.

Next, the operation of the first embodiment configured as described above will be described with reference to the operation explanatory diagram of FIG.

[0042] In a device using wireless communication, it is legally required to assign individual call codes to the wireless device. For example, when the wireless system of the "low power security standard (RCR STD-30)" is used for the automatic meter reading wireless system, a 12-digit number is set as a calling code.

Accordingly, in the first embodiment, the parent wireless device 2
This call code is used to disperse the communication channel and the clock synchronization communication time in the wireless communication performed between the wireless communication device 7 and the child wireless device 28 and to avoid interference with the wireless communication of another system.

That is, as shown in FIG. 3, for example, when the communication time is dispersed for 24 hours (every hour), as shown in FIG. Is set as the communication time, thereby randomly setting the clock synchronization communication time for each wireless device.

As the communication channel, "the remainder (remainder) obtained by dividing the number of the call code (12 digits) by the number n of communication channels" is set as the communication channel. For example, when wireless communication of the low power security standard (RCR STD-30) is used, there are 48 available communication channels, and therefore, as shown in FIG.
The remainder (remainder) obtained by dividing the (two-digit) number by 48 is set as the communication channel, thereby randomly setting the communication channel for each wireless device.

Then, using the communication channel and the clock synchronization time set in this way, the clock synchronization communication is performed as shown in FIG. 3, whereby a plurality of wireless devices are placed in the same wireless reach area. Even if it exists,
Communication can be performed without mutual interference.

Next, referring to the operation explanatory diagram shown in FIG.
A second embodiment of the present invention will be described.

The wireless system for automatic meter reading, the parent wireless device 27 and the child wireless device 28 in the second embodiment.
The circuit configurations of the two wireless devices are the same as those shown in FIGS. 1 and 2, respectively.

In the embodiment shown in FIG. 4, a clock synchronization communication time setting file 211 for each customer stored in the storage device 10 connected to the center device 21 as shown in FIG. The clock synchronization synchronization time that is different for each customer and stored in the file 211 is set in the parent wireless device 27 installed in the customer. That is, the center device 21 receives a call to the parent wireless device 27 via the terminal network control device 26 of the customer by the no-ringing communication, thereby setting the clock synchronization synchronization communication time setting file 211 with the parent wireless device 27. Set the synchronization synchronization time. And the parent wireless device 2
7 calls the slave wireless device 28 at the set clock synchronization synchronization communication time and performs clock synchronization communication, whereby the times of the clock circuits 17 of both the master wireless device 27 and the slave wireless device 28 are matched. It is.

That is, as shown in FIG. 4, the center device 21 activates the center network control device 22 in order to make a clock synchronization communication time and communication channel setting request. A no-ringing call is received by the terminal network controller 26 via the no-ringing trunk 25, and a meter activation request is issued to the terminal network controller 26. When the terminal network control device 26 further issues a start request to the parent wireless device 27, a pseudo meter reading response is returned from the parent wireless device 27 to the center network control device 22.
The center network controller 22 transmits the clock synchronization communication time (for example, y hour) setting data stored in the clock synchronization communication time setting file 211 for each customer to the parent wireless device 27. As a result, the parent wireless device 27 receives the clock synchronization communication time setting data, and returns a response signal to the center network control device 22, whereby the center network control device 22 ends the communication.

As a result, a different clock synchronization communication time is set in the parent wireless device 27 for each customer.
When the set clock synchronization communication time comes, the parent wireless device 27 calls the child wireless device 28 and performs clock synchronization communication.
The time of each clock circuit 17 of the slave wireless device 28 is completely synchronized and coincident.

Since the clock synchronization communication time stored in the clock synchronization communication time setting file 211 for each customer is different for each customer, a plurality of wireless devices exist in the same wireless arrival area. In this case, communication can be performed without mutual interference.

Next, referring to the operation explanatory diagram shown in FIG.
A third embodiment of the present invention will be described.

Incidentally, the wireless system for automatic meter reading, the parent wireless device 27 and the child wireless device 28 in the third embodiment.
The circuit configurations of the two wireless devices are the same as those shown in FIGS. 1 and 2, respectively.

In the embodiment shown in FIG. 5, the clock synchronization communication time setting file 211 for each customer stored in the storage device 10 connected to the center device 21 as shown in FIG. Setting a different clock synchronization communication time for each customer stored in the file 211 in the parent wireless device 27 installed in the customer is the same as in the second embodiment. In the second embodiment, however, the center device 21 accesses the parent wireless device 27 by the no-ringing communication, and thereby the clock synchronization communication time stored in the clock synchronization communication time setting file 211 for each customer is used as the master wireless communication time. In contrast to the setting in the wireless device 27, in the third embodiment, the parent wireless device 2
7, a test call request is made, and the center device 21 is called from the parent wireless device 27 via the terminal network control device 26, the exchange 24, and the automatic call receiving network control device 23, thereby connecting to the center device 21. The clock synchronization communication time setting data is read from the clock synchronization communication time setting file 211 for each consumer, and the read clock synchronization communication time setting data is transmitted to the parent wireless device 27 for setting. Are different.

That is, as shown in FIG. 5, the parent wireless device 27 makes a test call request to the terminal network control device 26, whereby the terminal network control device 26 switches the exchange 24, the automatic reception network control device. When a call arrives at the center device 21 via the center device 23, the center device 21 transmits the clock synchronization communication time setting data (for example, y hour) stored in the clock synchronization communication time setting file 211 for each customer to the parent wireless device 27.
Send to As a result, the parent wireless device 27 receives the clock synchronization communication time setting data, and returns a response signal to the center network control device 22, whereby the center network control device 22 ends the communication.

As a result, a different clock synchronization communication time is set in the parent wireless device 27 for each customer.
When the set clock synchronization communication time comes, the parent wireless device 27 calls the child wireless device 28 and performs clock synchronization communication.
The time of each clock circuit 17 of the slave wireless device 28 is completely synchronized and coincident.

Since the clock synchronization communication time stored in the clock synchronization communication time setting file 211 for each customer is different for each customer, a plurality of wireless devices exist in the same wireless arrival area. In this case, communication can be performed without mutual interference.

Next, referring to the operation explanatory diagram shown in FIG.
A fourth embodiment of the present invention will be described.

Incidentally, the wireless system for automatic meter reading, the parent wireless device 27 and the child wireless device 28 in the fourth embodiment.
The circuit configurations of the two wireless devices are the same as those shown in FIGS. 1 and 2, respectively.

In the embodiment shown in FIG. 6, as shown in FIG. 1, the meter reading date and time setting file 212 by the no-ringing communication for each customer stored in the storage device 10 connected to the center device 21 is used. The collection date and time of the meter reading data performed from the center device 21 at the time of meter reading by the no ringing communication stored for each customer stored in the file 212 is used as the clock synchronization communication time as the master wireless device 27 installed at the customer. Is set to

In other words, the meter reading data collection processing performed by the center device 21 for each customer by the no-ringing communication is performed by the center device 21 calling each of the customers on which the meter 29 is installed one by one by the no-ringing communication. , The metering data is collected, so that the no-ringing communication time is naturally different.
Therefore, the time at which the meter reading data is obtained by the no-ringing communication is stored in the parent wireless device 27, and this time is used as the clock synchronization communication time, whereby the clock synchronization communication time is dispersed, and thereby the same wireless arrival time is reached. Even when a plurality of wireless devices exist in the area, communication can be performed without interference with each other.

That is, in FIG. 6, when the center device 21 issues a meter reading request by the no-ringing communication to the center network control device 22, the center network control device 22 sends the meter reading request via the exchange 24 and the no-ringing trunk 25 to the terminal. Since no ringing is received by the network control device 26 and the parent wireless device 27 is activated from the terminal network control device 26, the parent wireless device 27 determines the time at which the meter reading by the no ringing communication from the center device 21 was performed. It is stored as the clock synchronization synchronization communication time. Thereafter, the clock synchronization communication is performed between the parent wireless device 27 and the child wireless device 28 at the stored clock synchronization communication time, whereby the clock circuits 1 of the parent wireless device 27 and the child wireless device 28 are connected.
The time 7 is a time that is completely synchronized and coincident.

Next, referring to the operation explanatory diagram shown in FIG.
A fifth embodiment of the present invention will be described.

The wireless system for automatic meter reading, the parent wireless device 27 and the child wireless device 28 in the fifth embodiment.
The circuit configurations of the two wireless devices are the same as those shown in FIGS. 1 and 2, respectively.

In the embodiment shown in FIG. 7, as shown in FIG. 1, a meter reading call date and time setting file 213 for each customer stored in the storage device 10 connected to the center device 21.
Is used as the communication time for clock synchronization.

More specifically, in the wireless metering system for automatic meter reading, in order to reliably perform meter reading, when meter reading is performed by no-ringing communication, the next time set in the meter reading call date and time setting file 213 for each customer is set. The function of setting the meter reading call date and time of the (next month) in the meter 29, transmitting the terminal call communication from the meter 29 based on the set meter reading call date and transmitting the meter reading data to the center device 21, is a function of the meter reading by the no ringing communication. Used in conjunction with data collection. Accordingly, the parent wireless device 27 uses the meter reading / calling date / time data transmitted from the center device as the clock synchronization communication time.

That is, when the no-ringing communication is performed, the meter reading / calling date and time is updated, so that the meter reading / calling is not performed in the current month. If the reading is not performed, the meter reading can be performed by the terminal calling communication.

In FIG. 7, first, the center device 21 activates the center network control device 22 to perform meter reading at the meter reading date and time by the no ringing communication stored in the meter reading date and time setting file 212 by the no ringing communication for each customer. The center network controller 22 receives no ringing from the terminal network controller 26 via the exchange 24 and the no ringing trunk 25, and the terminal network controller 26 requests the parent wireless device 27 to be activated. When the parent wireless device 27 returns the pseudo meter reading response to the center network control device 22, the center network control device 22 reads the meter reading call date and time setting data stored in the meter reading call date and time setting file 213 for each customer as the parent. Since the data is transmitted to the wireless device 27, the parent wireless device 27 stores this meter-reading / calling date / time setting data as a clock synchronization communication time. Thereafter, the clock synchronization synchronization communication is performed between the parent wireless device 27 and the child wireless device 28 using the stored clock synchronization synchronization time.

Next, a radio system for automatic meter reading according to a sixth embodiment of the present invention will be described with reference to FIG.

As described above, the automatic meter reading radio system is based on the premise that the clock circuits incorporated in the master radio device 27 and the slave radio device 28 are synchronized. From the time of shipment to the time of installation at the customer, the parent wireless device 27 and the child wireless device 28
Since the wireless communication is not performed between the master wireless device 27 and the slave wireless device 28, the clock circuits included in the master wireless device 27 and the slave wireless device 28 are not synchronized. If synchronization is not established, wireless communication cannot be performed between the two wireless devices as described above. Therefore, when the wireless devices are installed, the clock circuits included in the master wireless device 27 and the slave wireless device 28 are respectively installed. Need to synchronize. Therefore, in the sixth embodiment, when the wireless device is installed in the customer, the clock circuits incorporated in both wireless devices are synchronized with each other.

FIG. 8 is a block diagram showing the overall configuration of the wireless system for automatic meter reading according to the sixth embodiment.
The wireless system for automatic meter reading shown in FIG. 3 has a configuration in which the storage device 10 is removed from the wireless system for automatic meter reading shown in FIG. The difference is that the setting unit 31 is connected. The other configuration and operation are the same as those in FIG. 1, and the same components are denoted by the same reference numerals.

FIG. 9 is a block diagram showing the configuration of the parent wireless device 27 and the child wireless device 28 used in the automatic meter reading wireless system of FIG. The master wireless device 27 and the slave wireless device 28 shown in the figure are different from the wireless device shown in FIG. 2 only in that the clock synchronization communication time and communication channel setting circuit 18 and the call code setting circuit 19 are removed.

Note that the parent device setting device 30 and the child device setting device 31 shown in FIG. 8 correspond to the interface circuit 20 of the parent radio device 27 and the child radio device 28 shown in FIG. 9, respectively.
The test communication request commands are respectively transmitted to the CPU 1 through the interface circuit 20.
4. And the parent wireless device 2
7 receives the test communication command from the master unit setting device 30, starts the test transmission, and further adds information for identifying the number of transmissions to the test transmission data. When receiving the test communication command from the setting device 31 for the child device, the child wireless device 28 starts the carrier sense operation, receives the test transmission from the parent wireless device 27, and further transmits the transmission count information in the received data. , The last transmission time point is detected, and the subsequent response is returned. Then, by setting the time point when the response is returned as the time count start time point until the next wireless communication, synchronization is established between the parent wireless device 27 and the child wireless device 28.

FIG. 10 is an explanatory diagram of the transmission time on the transmission side and the timing of carrier sense on the reception side in the sixth embodiment.

In the automatic meter reading radio system, when a specific low-power radio (transmission output of 10 mW or less) that does not require a radio station license is used as a radio type, the transmission time T ₁ and the transmission suspension time T ₂ has a time limit. For example, the low power security standard (R
In the case of CR STD-30), the transmission time T ₁ is less than 3 seconds, the transmission suspension time T ₂ are has become more than 2 seconds.

Therefore, as shown in FIG. 10, when the transmitting side continuously repeats transmission → pause → transmission..., Carrier sense at the receiving side is assumed on the precondition that pause time T ₂ <transmission time T _1. setting the period T ₃ as follows, by performing carrier sense twice, so that it is possible to detect the transmission carrier at the receiving side.

Pause time T ₂ <Carrier sense period T ₃ <Transmission time T ₁ Next, referring to the operation explanatory diagram shown in FIG. 11 and the transmission message format of the parent wireless device shown in FIG. 12, the sixth embodiment The operation when a test communication request command is transmitted from the parent device setting device 30 to the parent wireless device 27 in the above will be described.

First, when the parent device setting device 30 transmits a test communication request command, the command is supplied to the CPU 14 via the interface circuit 20 of the parent wireless device 27, and the CPU 14 is started, and the format shown in FIG. The test transmission data is transmitted a predetermined number of times (in this embodiment, n times).

In the test transmission data shown in FIG. 12, the bit synchronization signal, the frame synchronization signal, and the call signal are legally defined portions when a specific low power radio is used, and the subsequent portions are the following. This is a portion that can be freely set by the user side, and in this portion, in addition to data to be wirelessly transmitted, transmission count information, test transmission data, and the like are set.

As described above, after the parent wireless device 27 has transmitted the test transmission data a predetermined number of times (n times), it waits for a response from the child wireless device 28. If there is no response from the child wireless device 28, the above-described test transmission operation is repeated again.

Next, from the slave unit setting device 31 to the slave wireless device 2
8 transmits a test communication request command. This test communication request command is sent from the slave unit setting device 31 to the slave wireless device 2.
8 is supplied to the CPU 14 of the child wireless device 28 through the interface circuit 20 of the
The PU 14 is activated to start the carrier sense operation, and the child wireless device 28 receives the test transmission data from the parent wireless device 27.

When receiving the test transmission data from the parent radio device 27, the child radio device 28 identifies the number of transmissions in the test transmission data, and thereby determines the final transmission data (in this embodiment, the transmission message n ) after receiving the waits for a transmission halt period T _2, performing the subsequent response transmission.

After completion of the response transmission, a time count until the next wireless communication with the parent wireless device 27 is started, and a test communication response response is sent to the slave unit setting unit 31 to perform a series of operations. The test communication operation ends, and the CPU 14 also stops operating.

Also, the master wireless device 27 starts counting the time until the next wireless communication with the slave wireless device 28 after receiving the response, and sets the master device setting device 3
A test communication response response is sent to 0, a series of test communication operations is completed, and the CPU 14 also stops operating.

As described above, the end point of the test communication is the start point of the time counting until the next wireless communication of the master wireless device 27 and the slave wireless device 28, and the two can be synchronized.

Next, the operation of the seventh embodiment will be described with reference to the operation explanatory diagram shown in FIG.

The circuit configurations of the wireless system for automatic meter reading and the wireless devices of the master wireless device 27 and the slave wireless device 28 in the seventh embodiment are the same as those shown in FIGS. 8 and 9, respectively.

In the seventh embodiment, the parent wireless device 2
7 is the same as that of the sixth embodiment described above, except that the method of determining the test reception completion time on the receiving side is different.

That is, in the case of the sixth embodiment described above, the reception was performed up to the final message (transmission message (n)). However, in the seventh embodiment, the reception from the normal message reception to the final message (transmission The only difference is that the reception time T ₄ up to the electronic message (n) is obtained from the following equation.

[0091]

T ₄ = (T ₁ + T ₂ ) × (n−number of transmissions of normal received message) Therefore, in the seventh embodiment, the final message (transmitted message (n)) is assumed to be normal in wireless communication. Even if the reception is not possible, a response can be transmitted from the child wireless device 28.

In the above-described sixth and seventh embodiments, the dedicated master device setting device 30 and the slave device setting device 31 are provided, thereby transmitting the test communication request command and receiving the test communication response response. However, since the communication operation by the setting device is performed via the interface circuit 20 of the wireless device, the same operation can be obtained even if the meter 29 is provided with the same function as the function of the slave device setting device 31. It can be carried out. The same effect is obtained by providing the center device with the same function as that of the base unit setting device 30 so that the message transmitted from the terminal network control device 26 by the no ringing communication from the center device becomes a test communication request. be able to.

Next, an eighth embodiment will be described with reference to FIGS.

As described above, the automatic meter reading wireless system is based on the premise that the clock circuits incorporated in the master wireless device 27 and the slave wireless device 28 are synchronized. Due to the influence of the installed temperature environment and the like, the clocks of the master wireless device and the slave wireless device have a slight time lag. Therefore, in this embodiment, a means for correcting the time lag will be described.

The basic idea in the present embodiment is that first, transmission data is transmitted a plurality of times from the parent wireless device that starts radio communication, and transmission number information for identifying the number of transmissions is added to the transmission data. . The child wireless device that receives the wireless communication measures the time until the transmitting device completes the transmission from the transmission count information in the received data, and corrects the time until the next wireless communication from the measurement result. It is.

The overall configuration of the wireless system for automatic meter reading in the eighth embodiment is the same as that shown in FIG. 1, and the parent wireless device 27 and the child wireless device used in the wireless system for automatic meter reading are used. 28 is the same as that shown in FIG.

The transmission time on the transmission side and the carrier sense timing on the reception side in this embodiment are the same as those shown in FIG. That is, as shown in FIG.
If the transmitting side continuously repeats transmission → pause → transmission... Under the precondition that the pause time T ₂ <transmission time T ₁ , the carrier sense period T ₃ on the receiving side is set as follows. By performing the sensing twice, the transmitting carrier can be detected on the receiving side.

Pause time T ₂ <Carrier sense period T ₃ <Transmission time T ₁ FIG. 14 shows the relationship between the clock error and the transmission time of the clock built in the wireless device and the concept of the clock synchronization method in this embodiment. FIG.

As shown in FIG. 14, for example, assuming that the clock in the wireless device generates an error of ± ΔT during the wireless communication period T (see FIG. 15), the worst combination of the clock error will cause It can be seen that if transmission is performed for ± 2ΔT before and after the transmission time, reception becomes possible. In addition, correction of the clock cycle on the transmitting side and the receiving side is performed beforehand on the receiving side by ± 2 times the transmission time width.
With setting the information of the [Delta] T, by measuring the time T _a of the receiving side from the "start of reception to the reception completion,
The correction time is calculated as in the following equation, and the synchronous correction can be performed using the correction time.

Correction time = T _a −2ΔT Next, the operation of the eighth embodiment will be described with reference to the operation explanatory diagram shown in FIG.

In this embodiment, for example, as shown in FIG. 16, bidirectional transmission is performed such that transmission is performed from the master wireless device 27 to the slave wireless device 28, and then a response is returned from the slave wireless device 28. Consider the communication procedure. In this case, the wireless transmission message from the parent wireless device 27 is the same as that shown in FIG.
The format is the same as shown in.

FIG. 15 shows the operation of measuring the “time T _a from the start of reception to the completion of reception” in the slave radio device 28 on the receiving side, as described above.

As shown in FIG. 15, while the parent wireless device 27 starts transmission, the child wireless device 28 reaches the reception time, and from the time when carrier sense is started, the clock circuit 17 is controlled by the CPU 14. By operating and counting the time until the transmission count information in the received message reaches the final “n”, “the time T _a from the start of reception to the completion of reception” can be measured.

[0104] Therefore, by fitting the measured time T _a to the above equation (modification time = T _a -2ΔT), can be determined clock modification time.

Next, a ninth embodiment of the present invention will be described with reference to the operation explanatory diagram shown in FIG.

The entire configuration of the wireless system for automatic meter reading in the ninth embodiment is the same as that shown in FIG. 1, and the parent wireless device 27 and the child wireless device used in the wireless system for automatic meter reading are used. 28 is the same as that shown in FIG. 9, and the communication procedure and the format of the radio transmission message are the same as those in FIGS. 16 and 12, respectively.

The ninth embodiment also describes a means for correcting the time lag between the clocks of the parent wireless device and the child wireless device as in the eighth embodiment. However, the method of calculating the “time T _a from the start of reception to the completion of transmission” on the receiving side is different.

That is, in the present embodiment, as shown in FIG. 17, the time T ₅ from the point in time when the carrier sensing starts at the reception time to the time when the message is normally received (in the present embodiment, the transmission message (Time until completion of (3)).

At the same time, a reception time T ₄ from the reception of the normal message to the final message (transmission message (n)) is calculated by the following equation.

[0110]

## EQU2 ## T ₄ = (T ₁ + T ₂ ) × (n−the number of transmissions of the normal received message) Then, by adding the time T ₄ and the time T ₅ , “from the start of reception” The time T _a until the transmission is completed can be calculated.

T _a = T ₄ + T ₅ Therefore, this time Ta is _calculated by the above equation (correction time = T _a −
By applying 2ΔT), the clock correction time can be obtained.

The merit of this embodiment is that the clock correction time can be obtained even if the final message (transmission message (n)) cannot be normally received by wireless communication.

As in the eighth and ninth embodiments described above, for example, two-way communication is performed in which transmission is performed from the master wireless device 27 to the slave wireless device 28, and then a response is returned from the slave wireless device 28. In this case, there is a possibility that a plurality of transmissions from the first parent wireless device 27 and a response from the child wireless device 28 may collide with each other. In these eighth and ninth embodiments, the completion of the final message reception is determined. Because it can be detected, after detection,
By so returns a response from the slave radio device 28 at intervals of a transmission pause time T _2, it is possible to prevent a collision.

Next, a tenth embodiment of the present invention will be described with reference to FIGS.

The overall configuration of the wireless system for automatic meter reading in the tenth embodiment is the same as that shown in FIG. 1, and the master wireless device 27 and the slave wireless device 27 used in the automatic meter reading wireless system. 28 is the same as that shown in FIG. 9, and the format of the radio transmission message is also the same as that of FIG.

The tenth embodiment also corrects the time lag between the clocks of the master wireless device and the slave wireless device, as in the eighth embodiment. Generally, the wireless communication by automatic meter reading is performed. Is about once / month, the wireless communication cycle T is very long, and the clock error ΔT increases in proportion to the wireless communication cycle T. Need to be transmitted a number of times.

Therefore, in order to prevent this, as shown in FIG. 18, unidirectional communication for clock synchronization is performed from the parent wireless device 27 on the transmission side, for example, once per day. An increase in clock error can be prevented.

In the unidirectional communication in this case, as shown in FIG. 19, the clock of the slave radio device 28 on the receiving side can be adjusted by the same method as in the eighth embodiment.

Next, referring to FIG. 20, an eleventh embodiment of the present invention will be described.
An example will be described.

In the eleventh embodiment, in the one-way communication for synchronizing the clock in the above-described tenth embodiment, the clock is corrected by the same method as in the ninth embodiment.

In other words, in this embodiment, as shown in FIG. 20, the time T ₅ from the point in time when the carrier sensing starts at the reception time until the message is normally received (in this embodiment, the transmission message (Time until completion of (3)).

At the same time, the reception time T ₄ from the reception of the normal message to the final message (transmission message (n)) is calculated by the following equation.

[0123]

T ₄ = (T ₁ + T ₂ ) × (n−number of transmissions of the normal received message) Then, by adding this time T ₄ and the time T ₅ , “from the start of reception” as in the following equation: The time T _a until the transmission is completed can be calculated.

T _a = T ₄ + T ₅ Therefore, this time Ta is _calculated by the above equation (correction time = T _a −
By applying 2ΔT), the clock correction time can be obtained.

[0125]

Further, according to the present invention, a test communication request command is sent from the master unit setting device, and the network control radio apparatus starts test transmission while adding transmission number information to the test transmission data. The wireless communication device detects the last transmission time from the information on the number of transmissions in the received data, and then returns a response.The time when this response is returned is the time count start time until the next wireless communication. When the device and the terminal wireless device are installed, the clocks of both devices can be easily synchronized.

Further, according to the present invention, the transmission count information is added to the transmission data from the network control radio apparatus, and the transmission is performed a plurality of times in accordance with the clock error generated during the radio communication cycle. The wireless device measures the time from the start of reception to the completion of transmission on the basis of the transmission count information in the received data, and corrects the time of the internal clock from the measurement result. Even if a slight time lag occurs in the clock of the wireless device, this can be corrected appropriately and the clocks of both can be synchronized.

[Brief description of the drawings]

FIG. 1 is a block diagram showing the overall configuration of a wireless system for automatic meter reading according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a detailed internal configuration of a parent wireless device and a child wireless device shown in FIG.

FIG. 3 is an operation explanatory diagram showing an operation of the first exemplary embodiment of the present invention.

FIG. 4 is an operation explanatory view showing the operation of the second embodiment of the present invention.

FIG. 5 is an operation explanatory view showing the operation of the third embodiment of the present invention.

FIG. 6 is an operation explanatory view showing the operation of the fourth embodiment of the present invention.

FIG. 7 is an operation explanatory view showing the operation of the fifth embodiment of the present invention.

FIG. 8 is a block diagram showing an overall configuration of a wireless system for automatic meter reading according to a sixth embodiment of the present invention.

FIG. 9 is a block diagram showing the configurations of a parent wireless device and a child wireless device used in the automatic meter reading wireless system of the sixth embodiment shown in FIG.

FIG. 10 is an explanatory diagram of a transmission time on a transmission side and a timing of carrier sense on a reception side in a sixth embodiment of the present invention.

FIG. 11 is an operation explanatory view showing the operation of the sixth embodiment of the present invention.

FIG. 12 is a diagram illustrating a transmission message format of a parent wireless device according to a sixth embodiment of the present invention.

FIG. 13 is an operation explanatory view showing the operation of the seventh embodiment of the present invention.

FIG. 14 is an explanatory diagram showing a relationship between a clock error and a transmission time of a clock built in a wireless device according to an eighth embodiment of the present invention and a concept of a clock synchronization method.

FIG. 15 is an operation explanatory view showing the operation of the eighth embodiment of the present invention.

FIG. 16 is an explanatory diagram showing a communication procedure between a parent wireless device and a child wireless device according to the eighth embodiment of the present invention.

FIG. 17 is an operation explanatory view showing the operation of the ninth embodiment of the present invention.

FIG. 18 is an explanatory diagram showing a communication procedure between a parent wireless device and a child wireless device according to the tenth embodiment of the present invention.

FIG. 19 is an operation explanatory view showing the operation of the tenth embodiment of the present invention.

FIG. 20 is an operation explanatory view showing the operation of the eleventh embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 10 storage device 11 antenna 12 radio circuit 13 modulation / demodulation circuit 14 CPU 17 clock circuit 20 interface circuit 21 center device 22 center network control device 24 exchange 26 terminal network control device 27 parent radio device 28 child radio device 29 meter

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Jun Fujiwara 2-3, Nakase, Mihama-ku, Chiba-shi, Chiba Tokyo Gas Co., Ltd. Information Technology Research Laboratories (72) Inventor Toshihiko Kawai 70, Yanagicho, Yuki-ku, Kawasaki-shi, Kanagawa Prefecture Inside the Toshiba Yanagimachi Plant (72) Inventor Tetsuya Hara 70, Yanagimachi, Kochi-ku, Kawasaki City, Kanagawa Prefecture Inside the Toshiba Yanagimachi Plant (72) Inventor Tetsuya Oki 70, Yanagicho, Yukicho, Kawasaki-shi, Kanagawa Prefecture Toshiba Corporation Yanagimachi Plant (56) References JP-A-1-245793 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H04Q 9/00

Claims (7)

(57) [Claims] 1. A center device is connected to a terminal network control device via a telephone line, and a network control wireless device connected to the terminal network control device is connected via a terminal wireless device connected to the terminal device. The terminal device is called, and data is collected from the terminal device to the center device. The data is stored at a predetermined time based on the time of a clock circuit which is built in each of the network control wireless device and the terminal wireless device and synchronized with each other. What is claimed is: 1. An automatic meter reading wireless system for performing wireless communication for collection and wireless communication for synchronizing said clock circuit, comprising: a storage unit storing a clock synchronization communication time for each customer; and a demand stored in said storage unit. Setting means for setting the clock synchronization communication time for each house in the wireless device of the consumer; and, when the clock synchronization communication time set by the setting means has been reached, the network control wireless device and the terminal Wireless systems for automatic meter reading, characterized by having a combined clock synchronous radio communication means for executing wireless communication combined clock synchronization with the use wireless devices. 2. A center device is connected to a terminal network control device via a telephone line, and a network control wireless device connected to the terminal network control device is connected via a terminal wireless device connected to the terminal device. The terminal device is called, and data is collected from the terminal device to the center device. The data is stored at a predetermined time based on the time of a clock circuit which is built in each of the network control wireless device and the terminal wireless device and synchronized with each other. An automatic meter reading wireless system that performs wireless communication for collection and wireless communication for synchronizing the clock circuit, wherein the network control wireless device receives a meter reading request by a non-ringing communication periodically performed from a center device. As a clock synchronization communication time, and when the clock synchronization communication time stored in the storage means is reached, the network control wireless device and the terminal Wireless systems for automatic meter reading, characterized by having a combined clock synchronous radio communication means for executing wireless communication combined clock synchronization with the line device. 3. A terminal device is connected to a terminal network control device via a telephone line from a center device, and a network control wireless device connected to the terminal network control device is connected to the terminal device via a terminal wireless device connected to the terminal device. The terminal device is called, and data is collected from the terminal device to the center device. The data is stored at a predetermined time based on the time of a clock circuit which is built in each of the network control wireless device and the terminal wireless device and synchronized with each other. What is claimed is: 1. A wireless system for automatic meter reading that performs wireless communication for collection and wireless communication for synchronizing said clock circuit, wherein a network control wireless device is a meter reading call date and time data transmitted at the time of a meter reading request by no ringing communication from a center device. As a clock synchronization communication time, and when the clock synchronization communication time stored in the storage means is reached,
An automatic meter reading wireless system, comprising: clock synchronization wireless communication performing means for performing clock synchronization wireless communication between a network control wireless device and a terminal wireless device. 4. A center device is connected to a terminal network controller via a telephone line, and a network control wireless device connected to the terminal network controller is connected to the terminal device via a terminal wireless device connected to the terminal device. The terminal device is called, and data is collected from the terminal device to the center device. The data is stored at a predetermined time based on the time of a clock circuit which is built in each of the network control wireless device and the terminal wireless device and synchronized with each other. An automatic meter reading wireless system that performs wireless communication for collection and wireless communication for synchronizing the clock circuit, wherein the network control wireless device responds to a test communication request from the master unit setting device to reduce the number of transmissions. The transmission data to which the information for identification is added is continuously transmitted, and the terminal wireless device responds to the test communication request from the setting device for the slave unit, and carries the carrier for detecting the transmission carrier. Start the sensing operation, receive the transmission data from the network control wireless device, identify the last transmission data from the transmission count information included in the received transmission data, and send a response a predetermined time after receiving the final transmission data. The wireless system for automatic meter reading, comprising means for returning the response and setting the time point of completion of the response as the start time point of the time interval until the next wireless communication, thereby performing clock synchronization when the wireless device is installed. 5. A center device is connected to a terminal network control device via a telephone line, and a network control wireless device connected to the terminal network control device is connected via a terminal wireless device connected to the terminal device. The terminal device is called, and data is collected from the terminal device to the center device. The data is stored at a predetermined time based on the time of a clock circuit which is built in each of the network control wireless device and the terminal wireless device and synchronized with each other. An automatic meter reading wireless system that performs wireless communication for collection and wireless communication for synchronizing the clock circuit, wherein the network control wireless device responds to a test communication request from the master unit setting device to reduce the number of transmissions. The transmission data to which the information for identification is added is continuously transmitted, and the terminal wireless device responds to the test communication request from the setting device for the slave unit, and carries the carrier for detecting the transmission carrier. Start the sensing operation, receive the transmission data from the network control wireless device, calculate the time until the final data is transmitted from the partner wireless device from the transmission count information included in the received transmission data, A response is returned after a predetermined time from the final transmission data transmission end time, and the time when the response is completed is set as a start time of a time interval until the next wireless communication, thereby having means for performing clock synchronization at the time of installing the wireless device. A wireless system for automatic meter reading, characterized in that: 6. A center device is connected to a terminal network control device via a telephone line, and a network control wireless device connected to the terminal network control device is connected to the terminal device via a terminal wireless device connected to the terminal device. The terminal device is called, and data is collected from the terminal device to the center device. The data is stored at a predetermined time based on the time of a clock circuit which is built in each of the network control wireless device and the terminal wireless device and synchronized with each other. An automatic meter reading wireless system that performs wireless communication for collection and wireless communication for synchronizing the clock circuit, wherein the network control wireless device includes means for transmitting transmission data to which information for identifying the number of transmissions is added. The terminal wireless device starts a carrier sense operation for detecting a transmission carrier from the network control wireless device and receives transmission data from the network control wireless device. The final transmission data identifies the transmission count information included in the transmitted data the received, measures the time from reception start to the last transmission data reception completion,
A wireless system for automatic meter reading, comprising means for correcting the time from the measured time until the next wireless communication is performed. 7. A terminal device is connected to a terminal network control device via a telephone line from a center device, and a network control radio device connected to the terminal network control device is connected to the terminal device via a terminal radio device connected to the terminal device. The terminal device is called, and data is collected from the terminal device to the center device. The data is stored at a predetermined time based on the time of a clock circuit which is built in each of the network control wireless device and the terminal wireless device and synchronized with each other. An automatic meter reading wireless system that performs wireless communication for collection and wireless communication for synchronizing the clock circuit, wherein the network control wireless device includes means for transmitting transmission data to which information for identifying the number of transmissions is added. The terminal wireless device starts a carrier sense operation for detecting a transmission carrier from the network control wireless device and receives transmission data from the network control wireless device. At the same time, the time from the start of reception to the end of reception is measured, and the time until the last transmission data is transmitted is calculated from the transmission count information included in the received transmission data, and the next time is calculated from the calculated time. A wireless system for automatic meter reading, comprising means for correcting the time until wireless communication is performed.