JPH08194022A - Wireless automatic meter inspection system - Google Patents

Abstract

PURPOSE: To provide a wireless automatic meter inspection system capable of reducing consumption of electric power of a wireless device. CONSTITUTION: Operation of a CPU 5 is stopped in a stand-by state, and a receiving electric power source control circuit 38 is intermittently driven by a low speed working clock of very low frequency by a first timer circuit 370. Voltage of a battery 61 is supplied to a wireless receiving circuit 3 through a transistor TR 381 of the receiving electric power source circuit 38. Consequently, consumption of electric power of the battery 61 can be reduced by making the wireless receiving circuit 3 carry out intermittent carrier sense motion and detecting a transmission carrier from a remote wireless device.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless automatic meter reading system for automatically collecting usage data of water, electricity, gas, etc., via a telephone line and a wireless line.

[0002]

2. Description of the Related Art FIG. 7 is a block diagram showing a general structure of a wireless automatic meter reading system of this type. As shown in the figure, the wireless automatic meter reading system has a meter 19 which constitutes a terminal device for measuring the usage amount of, for example, water, electricity, gas, etc. The meter 19 is, for example, water, electricity, gas, etc. Will be installed at the customer's place.

The meter 19 is connected to a wireless device slave unit 18, and is connected to the wireless device master unit 17 from the wireless device slave unit 18 via a wireless line. In addition, the wireless device base unit 1
7 is connected to a terminal network control unit (T-NCU) 16 and is connected from the terminal network control unit 16 to a telephone exchange 14 via a telephone line. The telephone exchange 14 is a center side network control unit (C-NCU) 12 which is a no-ringing communication network control unit or an automatic receiving network control unit (MA-NC) which is a terminal calling communication network control unit via a telephone line.
U) 13 is connected to the center device 11. Further, a no ringing trunk 15 is connected to both ends of the telephone exchange 14.

In the wireless automatic meter reading system configured as described above, in order for the center device 11 to collect usage data of water, electricity, gas, etc. measured by the meter 19, the center device 11 controls the center side network control device. 12, a telephone exchange 14, and a no-ringing trunk 15 to receive a no-ringing call to a terminal network control device 16, and the terminal network control device 16 further receives a wireless device master device 17 and a wireless device slave device 1.
8 to call the meter 19 to perform data communication between the center device 11 and the meter 19, whereby the usage data measured by the meter 19 is sent from the meter 19 to the center device 11 via the reverse route. Transmission, center device 1
It is supposed to be collected in 1.

In addition, when an abnormal situation occurs in the meter 19, the wireless device slave unit 18, the wireless device master unit 17, the terminal network controller 16, the telephone exchange 14, and the automatic incoming call are made from the meter 19 by the terminal calling communication. The center device 11 is called via the network control device 13, data communication is performed between the meter 19 and the center device 11, and alarm information for notifying an abnormal situation of the meter 19 is transmitted from the meter 19 to the center device 11. It has become.

[0006]

In the above-described wireless automatic meter reading system, the wireless device master device 17 and the wireless device slave device 18, particularly the wireless device slave device 18, is provided with a water meter, a gas meter or the like of a customer. Since it is installed near a place and it is difficult to use a commercial power source as an operating power source of the wireless device, it is essential to use a battery as the operating power source.

[0007] Also, the useful life of the wireless device is the meter 1
It is required to operate for the same period as 9 usage periods, for example, about 8 to 10 years.

As described above, since the wireless device is driven by a battery and has a considerably long useful life, it is required to reduce the power consumption so as to reduce the consumption of the battery as much as possible.

The present invention has been made in view of the above,
An object of the invention is to provide a wireless automatic meter reading system capable of reducing power consumption of a wireless device.

[0010]

In order to achieve the above object, a wireless automatic meter reading system of the present invention connects a wireless device master unit to a telephone line via a terminal network control device, and the wireless device master unit is connected to the wireless device master unit. Wireless device connected via wireless line By connecting a handset to a terminal device, information including meter reading data of the terminal device is collected from the telephone line by no ringing communication, and from the terminal device by terminal call communication from the terminal device. In a wireless automatic meter reading system that collects information of via a telephone line, in order for each wireless device of one of the wireless device master unit and wireless device slave unit to detect a transmission carrier from each of the other wireless devices, In the state where the operation of the control unit is stopped, there is no predetermined intermittent carrier sense interval based on the low speed operation clock whose frequency is much lower than the frequency of the high speed operation clock of the control unit. A timer means which occupies performed intermittently carrier sense operation in the receiving circuit, and summarized in that and a starting means for starting the control unit only when the radio receiver circuit detects the transmission carrier.

Further, the wireless automatic meter reading system of the present invention is
Each of the other wireless devices uses, as the transmission carrier, one frame of telegram including a predetermined bit synchronization signal, frame synchronization signal and ringing signal a plurality of times so as to be at least one frame telegram time longer than the intermittent carrier sense interval. The gist is to have a transmitting means for continuously transmitting.

Further, the wireless automatic meter reading system of the present invention is
After the one wireless device detects the transmission carrier from each of the other wireless devices, the frame synchronization signal and the calling signal of the wireless communication message transmitted from each of the other wireless devices are compared with a predetermined signal. The comparison / matching means for detecting whether or not they match and determining that the wireless communication is normal only when they match, and the comparison operation in the comparison / matching means are arranged to match only the time corresponding to the telegram time of the one frame. When the coincidence cannot be detected within the telegram time of the one frame counted by the counting unit that counts the telegram time of one frame, it is determined that the wireless communication is not normal, and the operation of the control unit is performed. And a resuming means for resuming the intermittent carrier sense operation.

[0013]

In the wireless automatic meter reading system of the present invention, each wireless device on one side operates at a low speed with a very low frequency in a state in which the operation of the control unit is stopped in order to detect the transmission carrier from each wireless device on the other side. The intermittent carrier sensing operation based on the clock is performed, and the control unit is activated only when the radio receiving circuit detects the transmission carrier.

Further, in the wireless automatic meter reading system of the present invention, each of the other wireless devices includes a predetermined bit sync signal, frame sync signal and call signal as a transmission carrier.
The telegram of the frame is continuously transmitted a plurality of times so as to be at least one frame telegram time longer than the intermittent carrier sense interval.

Further, in the wireless automatic meter reading system of the present invention, one wireless device detects the transmission carrier from each of the other wireless devices, and then the frame of the wireless communication message transmitted from each of the other wireless devices. The synchronization signal and the ringing signal are compared with a predetermined signal to detect whether or not they match. Only when they match, it is determined that the wireless communication is normal, and within one frame of telegram time counted by the counting means. If no match can be detected, it is determined that the wireless communication is not normal, the operation of the control unit is stopped, and the intermittent carrier sense operation is restarted.

[0016]

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

FIG. 1 is a block diagram showing the configuration of a wireless device used in a wireless automatic meter reading system according to an embodiment of the present invention. The wireless device shown in the figure constitutes the wireless device master device 17 or the wireless device slave device 18 shown in FIG. 7 described above, and the wireless device is connected to the terminal network control device 16 as shown in FIG. When connected, the wireless device master unit 1
7, and when the wireless device is connected to the meter 19, the wireless device slave unit 18 is configured.

That is, the wireless device shown in FIG. 1 has a CPU 5 which is a control unit for controlling the overall operation of the wireless device.
The interface circuit 6 is connected to the PU 5,
When the interface circuit 6 is connected to the terminal network control device 16 as shown in FIG. 7, the wireless device master device 17 is configured, and when the interface circuit 6 is connected to the meter 19, the wireless device slave device 18 is configured. Configure.

Further, a high-speed clock crystal oscillator 51 for generating a high-speed clock is connected to the CPU 5,
This allows the CPU 5 to operate at high speed.

The wireless device shown in FIG. 1 constitutes either one of the wireless device master unit and the wireless device slave unit, and has an antenna 1 for transmitting and receiving a wireless signal to and from the other wireless device. Have. The antenna 1 is connected to the FM demodulation circuit 31 of the wireless reception circuit 3 or the FM modulation circuit 41 of the wireless transmission circuit 4 via the switch 2.

The radio receiving circuit 3 is an FM-modulated circuit 400.
An FM demodulation circuit 31 for demodulating a radio signal in the radio frequency band of MHz into a serial digital signal and a carrier detection circuit 3 for detecting a carrier transmitted from a partner radio device.
It consists of two. In addition, the carrier detection circuit 32
The carrier detection signal output from the second timer circuit 33
Is supplied to the CPU 5 as a carrier detection signal while starting the timing operation of the second timer circuit 33. The second timer circuit 33 counts the telegram time of one frame, which will be described later, and when the telegram time of one frame is exceeded after carrier detection, a time-over signal is set to C.
Supply to PU5.

The FM demodulation circuit 31 of the radio receiving circuit 3
The demodulated serial digital signal is supplied to the N-bit shift register 34, where it is serially shifted, and its contents are transferred in the N-bit comparison / match circuit 35 from the frame sync signal setting circuit 36 to the frame sync signal and the call signal. The calling signal from the setting circuit 37 is compared. The N-bit shift register 34 and the N-bit comparison / match circuit 35 are activated by a comparison / match circuit activation signal from the CPU 5, and the match detection signal detected by the N-bit comparison / match circuit 35 is supplied to the CPU 5.

The radio receiving circuit 3 including the FM demodulating circuit 31 and the carrier detecting circuit 32 has a transistor T.
The reception power control circuit 38 including the R381 and the transistor TR382 is connected to the transistor TR3.
The voltage of the battery 61 connected to the emitter of the transistor TR381 is supplied to the wireless reception circuit 3 via the transistor TR381 or is stopped by the transistor 81 turning on / off the transistor TR382.

The reception power control circuit 38 is controlled by the first timer circuit 370. The first timer circuit 370 operates by the low-speed clock crystal oscillator 371, and for example, a very low-speed clock (3
2 kHz), and the reception power supply control circuit 38 is driven by this low-speed clock signal, whereby the voltage of the battery 61 is supplied as the operating voltage of the wireless reception circuit 3, and the wireless reception circuit 3 intermittently performs carrier detection operation. Is supposed to do.

The radio transmission circuit 4 includes an FM modulation circuit 41.
The FM modulation circuit 41 converts the serial digital signal, which is the transmission data from the CPU 5, to 400 MHz.
FM modulation is performed on a radio signal in the radio frequency band of. The FM modulation circuit 41 operates by being supplied with the operating voltage from the battery 61 by the transmission power supply control circuit 42 including the transistor TR421 and the transistor TR422, and the transmission power supply control circuit 42 is operated by the transmission circuit ON signal from the CPU 5. It is supposed to do.

It should be noted that the CPU 5 is in a stopped state in a normal standby state and is constructed so as not to consume electric power as much as possible.
9 or when a start signal is supplied from the terminal network control device 16 or when a carrier detection signal is supplied from the wireless reception circuit 3, the high-speed clock crystal oscillator 51 starts high-speed operation. There is. Also, CPU
When 5 is in the standby state, the transmission power supply control circuit 42 does not operate, so the wireless transmission circuit 4 is in the stopped state, and the power of the battery 61 is not consumed. Further, the wireless receiving circuit 3 is also supplied with the operating voltage from the battery 61 intermittently through the receiving power supply control circuit 38 by the low speed operation from the first timer circuit 370, whereby the carrier detecting operation is intermittently performed, The power of 61 is not consumed as much as possible.

In the wireless device of the wireless automatic meter reading system configured as described above, FIG. 2 is a timing chart showing a communication protocol in the case of no ringing communication.

As shown in FIG. 2A, when a start command message is sent from the terminal network controller (T-NCU) 16 to the wireless device master unit 17, the CPU 5 of the wireless device master unit 17 operates. Start and receive this activation command message. Then, the CPU 5 of the wireless device master unit 17 sends this activation command message to FIG.
2B, the activation command message is continuously transmitted to the wireless device slave device 18 a plurality of times as shown in FIG. 2B.

More specifically, this activation command message is a "bit synchronization" for synchronizing radio devices as standardized by a specific low power radio standard (RCRSTD-16) for telemeter / telecontrol. Signal ”,“ frame synchronization signal ”indicating the beginning of a telegram,“ call signal ”for identifying each wireless device, and terminal network control device 16
The basic structure is one frame consisting of a command portion indicating a start instruction from the.

The radio device master unit 17 that has received this activation command message transmits this message to the radio device slave unit 18. However, the radio device slave unit 18 uses the radio receiving circuit 3 to reduce power consumption. Since the wireless device slave unit 18 cannot receive this message by simply transmitting this message once because it is operated intermittently, the wireless device master device 17 causes the wireless device master device 17 to receive the message as shown in FIG. The activation command message is continuously transmitted for the number of times equal to or longer than the carrier sense interval T ₂ which is the intermittent radio reception operation cycle of the slave unit 18.

That is, as shown in FIG. 3, the radio device master unit 17 has a period T consisting of a command portion including a bit synchronizing signal, a frame synchronizing signal, a calling signal and a start instruction.
One frame of _send is multiplied by an integer (L) to calculate a value L larger than the carrier sense interval T ₂ (T ₂ <T _send ×
L), 1 is added to the value L (L + 1) times, and the same activation command message is transmitted to the wireless device slave device 18.

As described above, the wireless device master unit 17
As shown in (b), the start command message is sent a plurality of times (L +
1) By continuously transmitting, the wireless device slave device 18 can reliably receive the activation command message.

The wireless device slave unit 18 includes a first timer circuit 37.
The wireless reception circuit 3 is intermittently operated via the reception power control circuit 38 by the control of 0, and as shown in FIG.
In the intermittent carrier sense cycle of cycle T ₂ , the activation command message is received from the wireless device master unit 17.

When the wireless device slave device 18 receives the activation command message, the CPU 5 of the wireless device slave device 18 starts operating, and the activation command message is converted into a startup command message for wired communication, as shown in FIG. , (D) as shown in FIG.
When the meter 19 receives the activation command message from the wireless device slave device 18, it returns a response message to the wireless device slave device 18. When the wireless device slave device 18 receives the response message from the meter 19, the wireless device slave device 18 converts it into a wireless communication message by the same procedure and returns it to the wireless device master device 17 to perform real-time communication.

FIG. 4 is a timing chart showing the operation of the wireless device master device 17 from the reception of the activation command message in the wireless device master device 17 to the transmission to the wireless device slave device 18 described above.

In FIG. 4, when the activation command message is transmitted from the terminal network control device 16 to the wireless device master device 17, the activation command message is sent to the wireless device master device 17 as shown in FIG. 4 (a). Received by the interface circuit 6 of the CPU 5
Is supplied to. The CPU 5 is activated at the rising edge of the mark of the activation command message and receives the activation command message. Then, this activation command message is converted into a message for wireless communication shown in FIG. 3, and then the CPU 5 supplies a transmission circuit ON signal to the transmission power control circuit 42 as shown in FIG. 4B.
As shown in FIG. 4C, the operating voltage of the battery 61 is supplied to the FM modulation circuit 41 of the wireless transmission circuit 4 to bring the FM modulation circuit 41 into the operating state. When the FM modulation circuit 41 enters the operating state, the CPU 5 supplies the transmission data of the activation command message to the FM modulation circuit 41, and the transmission data is transmitted as shown in FIG.
As shown in (1), the signal is supplied from the FM modulation circuit 41 to the antenna 1 through the switch 2 and is transmitted from the antenna 1 to the wireless device slave device 18.

FIGS. 5 and 6 are timing charts showing the operation of the wireless device slave unit 18 when there is no ringing incoming call. FIG. 5 shows a case where there is no regular transmission carrier from the wireless device master unit 17 which is the partner wireless device. That is, for example, FIG. 6 is a timing diagram showing an operation at the time of abnormality when the wireless device slave device 18 is activated by noise or wireless communication in another wireless system, and FIG. 6 is a normal transmission carrier from the wireless device master device 17. FIG. 9 is a timing diagram showing a normal operation when receiving a “P”.

First, referring to FIG. 5, the wireless device master unit 17
From FIG. 3, there will be described an operation at the time of abnormality when there is no regular transmission carrier and the wireless device slave unit 18 is activated by noise or wireless communication in another wireless system.

First timer circuit 370 of wireless device slave unit 18
Supplies the operating voltage of the battery 61 to the wireless reception circuit 3 via the reception power control circuit 38 at a cycle T ₂ of, for example, 20 seconds to 30 seconds, and the FM demodulation circuit 31 and the carrier detection circuit of the wireless reception circuit 3 are supplied. 32 is activated to perform the intermittent carrier sense operation. It should be noted that the period T ₁ during which the radio receiving circuit 3 is in the operating state in this cycle T ₂ is usually 5 ms to 10 ms.
It is about ms.

Since the carrier sense operation is performed at the very low speed clock (for example, 32 kHz) of the low speed clock crystal oscillator 371, the current consumption due to the operation of the radio receiving circuit 3 is, for example, It is a very small value of about several μA, achieving low power consumption.

In this way, when the radio receiver circuit 3 operates by the action of the first timer circuit 370, for example, when the radio carrier circuit 17 cannot detect the transmission carrier at the time of the first carrier sensing operation, the CPU 5 also operates. Therefore, the battery 61 is not started up, and accordingly, useless power is not consumed from the battery 61.

At the time of the next carrier sensing operation, if the carrier is erroneously detected as shown in the latter half of FIG. 5 (c) by noise which is not an authorized transmission carrier, wireless communication in another wireless system, or the like, this carrier is erroneously detected. The detection signal is supplied from the carrier detection circuit 32 of the wireless reception circuit 3 to the CPU 5,
As a result, the CPU 5 is activated. At the same time, the output signal of the carrier detection circuit 32 activates the second timer circuit 33 as shown in FIG. 5 (e) to start counting the time (T _send ) for receiving one frame.

When the CPU 5 is activated, the CPU 5
A reception circuit ON signal is supplied to the reception power supply control circuit 38 via the timer circuit 370, whereby the radio reception circuit 3 is held in the operating state as shown in FIG.
The PU 5 activates the N-bit shift register 34 and the N-bit comparison / match circuit 35 as shown in FIG. 5 (f), and outputs the serial digital signal FM-demodulated by the FM demodulation circuit 31 of the wireless reception circuit 3 to the N-bit shift register. It is supplied to the N-bit comparison / match circuit 35 via 34 and compared with the frame synchronization signal and the calling signal from the frame synchronization signal setting circuit 36 and the calling signal setting circuit 37.

In this case, in the normal wireless communication from the wireless device master device 17, the start command message of the same frame is continuously transmitted as described above, so the second timer circuit 3
The N-bit comparison / match circuit 35 detects a match between the frame synchronization signal and the calling signal within the time of one frame in which 3 is performing the counting operation. The circuit 35 cannot detect the coincidence, and during this time, the second timer circuit 33 operates as shown in FIG.
A time-over signal is generated as shown in (e). This time-over signal is supplied to the CPU 5, and the CPU 5
Control to turn off the wireless reception circuit 3 via the first timer circuit 370 and the reception power supply control circuit 38, turn off the N-bit comparison / match circuit 35, and immediately turn off the CPU 5 itself. . In the case of such unauthorized wireless communication, the CPU 5 and related circuits are immediately turned off, so that the power of the battery 61 is not wasted. Since the second timer circuit 33 can identify whether the wireless communication is normal or not in a very short time of one frame, the consumption of the battery 61 can be reduced as much as possible. There is.

Further, as shown in FIG. 6, the wireless device base unit 1
A regular transmission carrier from the wireless communication device 7 is transmitted to the wireless device slave device 18, and this is transmitted to the first timer circuit 370 of the wireless device slave device 18.
When the carrier detection circuit 32 detects a transmission carrier from the wireless device master device 17 by receiving through the wireless reception circuit 3 by the intermittent carrier sensing operation in which the wireless reception circuit 3 is operated under the control of While the CPU 5 is activated by the carrier detection signal from the detection circuit 32,
The second timer circuit 33 also starts the time counting operation.

When the CPU 5 is activated, the receiving circuit ON signal from the CPU 5 keeps the wireless receiving circuit 3 in the continuous operation state via the first timer circuit 370 and the receiving power supply control circuit 38, and also the N-bit shift register 34. And the N-bit comparison / match circuit 35 are activated, whereby the N-bit comparison / match circuit 35 compares the frame synchronization signal and the calling signal as shown in FIG. The detection signal is shown in Fig. 6 (g).
As shown in, C before the second timer circuit 33 times out.
When it is supplied to the PU 5, the CPU 5 determines that it is a legitimate call to its own wireless device slave device 18, and continues the wireless communication operation.

In the above embodiment, the operation at the time of no ringing communication is explained, but the operation at the time of the terminal calling communication from the meter 19 is also performed by the wireless device slave unit 18 as the transmitting side and the wireless device master unit. The operation is exactly the same except that 17 is the receiving side.

[0048]

As described above, according to the present invention,
In order to detect the transmission carrier, the intermittent carrier sense operation based on the low-speed operation clock with a very low frequency is performed while the operation of the control unit is stopped, and control is performed only when the radio reception circuit detects the transmission carrier. Since the unit is activated, battery consumption in the wireless device can be reduced as much as possible, and low power consumption of the wireless device can be achieved.

Further, according to the present invention, a plurality of telegrams of one frame including a predetermined bit sync signal, frame sync signal and call signal as a transmission carrier are set to be at least one frame telegram time longer than the intermittent carrier sense interval. Since the transmission is performed continuously, the transmission carrier can be accurately detected even when the power consumption is reduced by performing the intermittent carrier sensing operation.

Further, according to the present invention, after the transmission carrier is detected, the coincidence of the frame synchronization signal and the calling signal is detected, and only when they coincide with each other, it is determined that the wireless communication is normal, and within the telegram time of one frame. If no match is detected, it is determined that the wireless communication is not normal, the operation of the control unit is stopped, and the intermittent carrier sense operation is restarted, so the operation when not normal wireless communication is shortened as much as possible. The consumption of the battery can be reduced as much as possible.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a wireless device used in a wireless automatic meter reading system according to an embodiment of the present invention.

FIG. 2 is a timing diagram showing a communication protocol in the case of no ringing communication.

FIG. 3 is an explanatory diagram showing a configuration of a start command message.

FIG. 4 is a timing chart showing an operation in the wireless device master unit from the reception of the start command message in the wireless device master unit to the transmission to the wireless device slave unit.

FIG. 5 is a timing chart showing the operation of the wireless device slave unit when there is no ringing incoming call, and is a timing diagram showing the operation at the time of abnormality when the wireless device slave unit is activated especially when there is no regular transmission carrier. .

FIG. 6 is a timing chart showing the operation of the wireless device slave unit at the time of no ringing incoming call, in particular, the timing chart showing the operation when a regular transmission carrier is received.

FIG. 7 is a diagram showing a configuration of a conventional device.

[Explanation of symbols]

 3 wireless receiving circuit 4 wireless transmitting circuit 5 CPU 6 interface circuit 16 terminal network control device 17 wireless device master device 18 wireless device slave device 19 meter 31 FM demodulation circuit 32 carrier detection circuit 35 N-bit comparison matching circuit 38 reception power control circuit 42 transmission power control circuit 370 first timer circuit

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical indication location H04Q 9/00 311 H (72) Inventor Jun Fujiwara 2-3 Nakase, Mihama-ku, Chiba-shi, Chiba Tokyo Gas (72) Inventor Toshihiko Kawai, 70 Yanagicho, Sachiku-ku, Kawasaki-shi, Kanagawa Toshiba Yanagimachi Co., Ltd. (72) Inventor, Tetsuya Hara, 70, Yanagicho, Sachi-ku, Kawasaki-shi, Kanagawa (72) Inventor Tetsuya Oki 70 Yanagimachi, Saiwai-ku, Kawasaki City, Kanagawa Prefecture Toshiba Yanagimachi Factory

Claims (3)

[Claims] 1. A wireless device master unit is connected to a telephone line via a terminal network controller, and a wireless device slave unit connected to the wireless unit master unit via a wireless line is connected to a terminal unit. In a wireless automatic meter reading system for collecting information including meter reading data of a terminal device from a telephone line by no ringing communication, and collecting information from the terminal device by terminal calling communication from the terminal device via a telephone line, the wireless device parent In order to detect the transmission carrier from each of the other wireless devices, one of the wireless devices of the wireless device and the wireless device slave device, in the state where the operation of the control unit is stopped, Also, a timer means for performing an intermittent carrier sense operation to a radio receiving circuit at a predetermined intermittent carrier sense interval based on a low speed operation clock of a very low frequency, and the radio means. Wireless automatic meter reading system, wherein a signal circuit and a starting means for starting the control unit only when it detects the transmission carrier. 2. Each of the other wireless devices transmits, as the transmission carrier, one frame of telegram including a predetermined bit synchronization signal, frame synchronization signal and call signal at least one frame telegram time longer than the intermittent carrier sense interval. The wireless automatic meter-reading system according to claim 1, further comprising a transmitting unit that continuously transmits a plurality of times so as to be long. 3. The one wireless device, after detecting a transmission carrier from each of the other wireless devices, determines a frame synchronization signal and a calling signal of a wireless communication message transmitted from each of the other wireless devices. The comparison and matching means for detecting whether or not the signals match with each other and determining that the wireless communication is normal only when they match, and the comparison operation in the comparison and matching means correspond to the telegram time of the one frame. Counting means for counting the telegram time of the one frame so as to match only the time, and if the coincidence cannot be detected within the telegram time of the one frame counted by the counting means, it is determined that the wireless communication is not normal. , Stop the operation of the control unit,
The wireless automatic meter-reading system according to claim 2, further comprising: a restarting unit that restarts the intermittent carrier sense operation.