JP3436919B2 - Automatic meter reading system - Google Patents

Description

Description: BACKGROUND OF THE INVENTION [0001] 1. Field of the Invention [0002] The present invention relates to an automatic meter reading system for automatically measuring the usage of gas, water, electricity, and the like. The present invention relates to an automatic meter reading system capable of communicating various communication data such as request data such as meter reading request data and response data such as meter reading value data by wireless communication between slave stations. 2. Description of the Related Art In recent years, a system for automatically reading meter readings from a gas meter or the like installed in a general household has been developed.
Automatic meter reading systems using wireless communication have been developed. The conventional automatic meter reading system generally includes a head office that controls various controls, a master station connected to the head office via a telephone line, and a plurality of master stations connected to the master station via a wireless communication line. And a plurality of meter devices connected to each of the slave stations via a wired line. In addition, the master station and the slave station are generally constructed so as to be able to communicate with each other by a master station-side wireless device and a slave station-side wireless device configured by a specific low power wireless device. In this case, in this automatic meter reading system, one communication channel (available channel) is set in advance for each of the master station wireless device and the plurality of slave station wireless devices in the same system. Data communication is performed between the master station and the slave stations using possible channels. In this conventional automatic meter reading system, at the time of automatic meter reading, first, a head office transmits meter reading request data to a master station via a telephone line. Next, the master station transmits the meter reading request data to the slave station via the wireless line. Specifically, the master station side radio receives the available channel and determines the presence or absence of a signal input (carrier sense). At this time,
If there is a signal input in the available channel, the transmission of the meter reading request data is interrupted, and the fact is transmitted to the head office. On the other hand, when it is determined that there is no signal input,
The meter reading request data is transmitted to the slave station on the available channel. Next, the slave station transmits the received meter reading request data to the meter device via the wired line. Thereafter, the meter device transmits the meter reading value data to the slave station, and the slave station sends the meter reading value data to the master station. Subsequently, the master station transmits the meter reading value data transmitted from the slave station to the head office via the telephone line. The head office collects meter reading data from all meter devices by performing these processes for each slave station. [0004] However, the conventional automatic meter reading system has the following problems. That is, in the conventional automatic meter reading system, usable channels of the master station radio and the slave station radio are preset to a specific one channel. On the other hand, in the communication between the master station and the slave station, when external noise is superimposed on the available channel or when the available channel is used by another system, the master station side radio is not used. It is necessary to wait before sending the meter reading request data. In this case, in gas metering system and water metering system,
A communication procedure has been established on the premise of communication using a wired line. For this reason, if a communication standby state occurs in the system, not only the collection of meter reading data is delayed, but also the communication procedure itself may not be established due to a communication error, resulting in serious operation of the system. There is a problem of causing trouble. The present invention has been made in view of the above problems, and has as its main object to provide an automatic meter reading system that enables smooth transmission and reception of communication data. In order to achieve the above object, an automatic meter reading system according to a first aspect of the present invention includes a master station having a master station-side radio device capable of transmitting and receiving communication data, and a master station having a master station wireless device capable of transmitting and receiving communication data. In an automatic meter reading system including a plurality of slave stations having a slave station-side wireless device capable of transmitting and receiving to and from the side wireless device, and a meter device capable of communicating with the slave station via a wired line, a master station The side radio device and the slave station radio device are configured so that any two or more communication channels fixedly selected in advance from a plurality of communication channels can be set as available channels, respectively. An available communication channel is selected by sequentially receiving available channels, and communication is performed with the slave station radio using the selected communication channel, and the slave station radio enables intermittent reception. Composed
When receiving available communication channels in sequence and receiving communication data addressed to the own station, communication is performed with the master station side wireless device using the communication channel. Preferred embodiments of an automatic meter reading system according to the present invention will be described below with reference to the accompanying drawings. The automatic meter reading system 1 shown in FIG. 1 is a system for automatically reading, for example, gas usage and the like, and is conceptually a head office 2 having a central collection device composed of a host computer and the like. And the headquarters 2 provided in a condominium, for example, via a public line network such as a telephone line.
(Hereinafter, also referred to as "master station 3" when not distinguished) and a plurality of slave stations 4a arranged in an apartment house and connected to the master station 3 via a wireless line. ~ 4
d (hereinafter, also referred to as “slave station 4” when no distinction is made). The master station 3 includes a control device 5 that communicates various communication data with the head office 2, and a master station-side radio 6 that transmits and receives various communication data with the slave station 4 and the control device 5. Have. On the other hand, the slave station 4 is provided with meter devices Ma to Md (hereinafter, referred to as “Meters”) that are provided for each house in the apartment house.
And a slave station-side wireless device 7 connected to the meter device M via a wired line and transmitting and receiving various communication data to and from the master station 3. . Although not shown, the head office 2
More master stations 3, 3,... Are connected.
More slave stations 4, 4,... Are connected via wireless lines. In this case, the master station-side radio 6 and the slave station-side radio 7 are each constituted by a specific low-power radio apparatus capable of communicating on any of the communication channels ch1 to ch41. In addition, the master station radio 6 and the slave station radio 7 are configured to arbitrarily select any two channels (for example, ch.
1, 2) are set as available channels. Further, the slave station-side radio device 7 performs an intermittent reception operation of starting and receiving at predetermined time intervals from the standby state, and upon starting, receives two available channels and transmits communication data addressed to the own station. When it is being transmitted, continuous reception is performed, and when communication data addressed to its own station is not being transmitted, it shifts to a standby state. Therefore, since the power consumption of the slave station-side wireless device 7 can be reduced, the slave station-side wireless device 7 operates for a long time by being driven by a battery. On the other hand, communication data (for example, connection request data DCP) is composed of packet-type data as shown in FIG. 3, and each communication packet P is composed of a bit synchronization signal SBC, a frame synchronization signal SFC, a system ID data. DID1, individual ID data DID2, signal identifier DSD and test code DAP
It is constituted by. On the other hand, for example, when the master station 3a transmits communication data to the slave station 4a, as shown in FIG. 2, the master station radio 6 waits for the slave station radio 7 (t1 to t3). , Intermittent cycle) and the reception time (t3 to t5, t5 to t7) that can reliably recognize that the communication packet P addressed to the own station is included in ch1 and ch2 (t2 to t7). The same communication packet P is repeatedly transmitted for t8). In this case, each reception time (t3 to t5)
Or t5 to t7) is the minimum time required for the slave station radio device 7 started during transmission of the communication packet P to reliably receive the communication packet P, that is, the time length of the communication packet P (t4 to t6). ) Is defined as twice as long. Therefore, according to the automatic meter reading system 1, as shown in FIG. 2, the slave station-side wireless device 7 can reliably receive the communication packet addressed to the own station (communication packet Pa). Outbreaks are reliably avoided. Note that the number of transmissions of the communication packet P is represented by the following equation. The number of transmissions = intermittent cycle / 1 communication packet length + 2 · number of usable channels ························································· | The explanation will be focused on. In collecting meter reading value data, first, the head office 2 transmits meter reading request data to the master stations 3a and 3b. At this time, for example, the master station 3a executes a transmission process to the slave stations 4a and 4b in response to receiving the meter reading request data. In this transmission process, as shown in FIG. 4, the master station side radio device 6 receives the communication channel (for example, ch1) set as an available channel and determines the presence or absence of a signal input (carrier sense, step 21). ). At this time,
When the channel of ch1 is used by another communication device (for example, the master station wireless device 6 of the master station 3b) or when external noise occurs, the available channel is set to c.
h2 (step 22), and returns to step 21 to determine the presence or absence of a signal input. When it is determined in step 21 that ch1 is an empty channel, the master station side radio 6 continuously transmits the connection request data DCP to, for example, the slave station 4a a plurality of times (step 23). Thereafter, when the connection confirmation data transmitted by the slave station 4a is received, the master station side wireless device 6 executes a meter reading process in a predetermined procedure (step 2).
4). In this process, the master station side radio 6 transmits the meter reading request data to the master station side radio 6 of the slave station 4a, and receives the meter reading value data transmitted from the master station side radio 6 in response thereto. And outputs it to the control device 5. Next, the control device 5 of the master station 3a
Transmits the meter reading data to the head office 2 via the public network. In this case, the head office 2 transmits disconnection request data to the master station 3a when determining that the meter reading value data for all the slave stations 4a has been collected. At this time, the parent station 3
The control device 5a determines whether or not the head office 2 has transmitted the disconnection request data (step 25). When detecting the transmission of the disconnection request data, the control device 5 transmits the disconnection request data to the master station side radio 6. The slave station-side wireless device 7 is caused to transmit (step 26). Thereby, the communication between the master station wireless device 6 and the slave station wireless device 7 of the slave station 4a is disconnected. On the other hand, at the time of transmission processing by the master station 3a, the slave station side radio device 7 of the slave station 4a executes the reception processing shown in FIG. In this receiving process, the slave station side radio 7
An available channel (for example, ch1) is received, and the presence or absence of a signal input is determined (step 31). At this time, ch1
When it is determined that is used, the available channel is changed to ch2 (step 32), and in step 31, the presence or absence of a signal input on ch2 is determined. Next, ch
When it is determined that a signal is being input in the second available channel, the slave station wireless device 7 determines whether or not the bit synchronization signal SBC and the frame synchronization signal SFC have been detected (step 33). The slave station-side wireless device 7 receives ch2 for a time corresponding to two packet lengths of the frame synchronization signal SFC until detecting the synchronization signal SBC and the frame synchronization signal SFC (step 34). If the synchronizing signal SBC and the frame synchronizing signal SFC cannot be detected within this time, it is determined whether all available channels have been received (step 35). Move to On the other hand, if reception for all available channels has not been completed, the process returns to step 32 to change the available channels. In step 34, the frame synchronization signal SFC cannot be detected within the time of one packet length at the time of receiving noise or the like. In this case, step 35 is executed when the time of one packet length has elapsed. May be configured. When the synchronizing signal SBC and the frame synchronizing signal SFC are detected in step 33, the connection request data DCP is stored in the master station 3 in the same system based on the system ID data DID1 in the connection request data DCP.
It is determined whether or not the communication data is transmitted by a (step 36). At this time, if it is determined that the communication data is transmitted by another system such as the master station 3b, the reception of the connection request data DCP is canceled and the above-described step 35 is executed. When it is determined that the communication data is transmitted by the master station 3a in the same system, the communication data addressed to the own station (the slave station 4a in this case) is determined based on the individual ID data DID2 in the connection request data DCP. It is determined whether or not there is (step 37).
When it is determined that the communication data is addressed to the own station, the meter reading process is executed in a state where the communication data is fixed to the currently available channel (step 38). Specifically, the slave station-side wireless device 7 of the slave station 4a outputs the meter reading request data and inputs the meter reading value data from the meter device Ma, and also transmits the meter reading value data to the master station side wireless device of the master station 3a. Send to 6. Next, the slave station-side radio device 7 determines whether or not the disconnection request data transmitted by the master station 3a has been received (step 39), and upon receiving the disconnection request data, the master station of the master station 3a. Side radio 6
Disconnects communication with and shifts to the standby state. In addition, the master station side radio device 6 similarly performs the transmission process on the slave station 4b, and similarly, the slave station 4b performs the above-described reception process. As described above, according to the automatic meter reading system 1, two available channels are set for the master station radio 6 and the slave station radio 7, and the available channels are set when transmitting communication data. The adoption of a configuration that uses an available channel allows for smooth transmission and reception of communication data compared to a conventional automatic meter reading system that transmits and receives communication data using one fixed communication channel. can do. As a result, it is possible to avoid an unsuccessful communication procedure in the automatic meter reading system for gas or water supply on the premise of transmitting and receiving communication data by wire communication, and thus it is possible to construct an automatic meter reading system having extremely high reliability. it can. In addition, since the local station wireless device 7 in the local station 4 is configured to be capable of intermittent reception, it can be operated continuously over a long period of time by battery driving. The present invention is not limited to the configuration shown in the embodiment of the present invention. For example, in the embodiment of the present invention, an example has been described in which any two channels out of a plurality of communication channels are set as usable channels in the master station wireless device 6 and the slave station wireless device 7, but the present invention is not limited to this. Instead, three or more channels can be set as available channels. Further, in the embodiment of the present invention, an automatic meter reading system 1 for metering the amount of gas used and the like.
Although described as an example, the present invention is not limited thereto,
The present invention can be applied to an automatic meter reading system for metering the amount of water or electricity used. As described above, according to the automatic meter reading system according to the first aspect, the master station side radio device selects an available communication channel by sequentially receiving each available channel. And communicates with the local station radio using the selected communication channel, and when the local station radio sequentially receives available channels and receives communication data addressed to itself, the communication is performed. By communicating with the master station side wireless device using the channel, the communication is compared with the conventional automatic meter reading system which transmits and receives communication data using one fixed communication channel. Data can be transmitted and received smoothly. As a result, it is possible to avoid the failure of the communication procedure in the automatic meter reading system for gas or water supply on the premise of transmission and reception of communication data by wire communication, thereby constructing an automatic meter reading system having extremely high reliability. be able to. [0019] Also, by constructing the capable daughter radios intermittent reception, it is possible to reduce power consumption, it can be operated for example continuously for a long time with battery power.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an automatic meter reading system 1 according to an embodiment of the present invention.
FIG. 3 is a block diagram showing the configuration of FIG. FIG. 2 is an automatic meter reading system 1 according to the embodiment of the present invention.
FIG. 9 is an explanatory diagram for describing an operation example of a master station 3a and a slave station 4a in FIG. FIG. 3 shows connection request data D transmitted by a master station 3a.
It is a data structure figure showing an example of CP. FIG. 4 is a flowchart for explaining a transmission process of the master station side wireless device 6 in the automatic meter reading system 1. FIG. 5 is a flowchart for explaining a reception process of the slave station-side wireless device 7 in the automatic meter reading system 1. [Description of Signs] 1 Automatic meter reading system 3a, 3b Master station 4a-4d Slave station 5 Controller 6 Master station radio 7 Slave station radio DCP connection request data Ma-Md Meter device SBC Bit synchronization signal P Communication packet

────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI H04Q 9/00 311 H04Q 9/00 311J H04L 11/00 310B (72) Inventor Tsutomu Yagami 3967 Wada, Matsumoto-shi, Nagano 10 Toyo Keiki Co., Ltd. (72) Inventor Eiki Motoyama 1163, Shimoseiplane, Inari-cho, Nagano City, Nagano Pref. Nagano Japan Radio Co., Ltd. , A) (58) Fields investigated (Int. Cl. ⁷ , DB name) G08C H04B 7/24 H04L 12/28 H04M 11/00 301 H04Q 9/00

Claims (1)

(57) [Claim 1] A master station having a master station radio capable of transmitting and receiving communication data, and a slave station capable of transmitting and receiving the communication data to and from the master station radio An automatic meter reading system including a plurality of slave stations each having a side wireless device and a meter device capable of communicating with the slave station via a wired line, wherein the master station side wireless device and the slave station side wireless device Is configured so that any two or more communication channels fixedly selected in advance from a plurality of communication channels can be set as available channels, respectively, and the master station side wireless device sequentially receives the available channels. By selecting an idle communication channel and communicating with the slave station-side radio using the selected communication channel, the slave station-side radio is configured to be capable of intermittent reception. Sometimes the above An automatic meter reading system for communicating with the master station side wireless device using the communication channel when the communication data addressed to the own station is received by sequentially receiving channels.