JP3412992B2 - Wireless information collection system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system for wirelessly collecting information of equipment, devices and sensors connected to measurement / control interfaces of a plurality of terminal stations using a mobile station, and particularly to a gas meter reading system and an automatic system. The present invention relates to a telemeter and a telecontrol system such as an information collecting system for vending machines and an information collecting system for distribution line equipment.

[0002]

2. Description of the Related Art Conventionally, in order to wirelessly collect data from a plurality of terminal stations installed in a specific area, there is a telemeter system for collecting data using a terminal station such as a handy terminal. In such a system, a terminal station adopting a battery drive system performs intermittent reception operation in order to achieve low power consumption and long-time operation. To operate such a system, bring a handy terminal for data collection up to the communicable area and send an individual call signal to each of a plurality of terminal stations, to which individual addresses individually registered are added. Then, communication was sequentially performed with terminal stations having the same address.

[0003]

However, in such a conventional system, it takes a maximum intermittent reception cycle time to establish a communication link with one terminal station, and then a data communication time is added. It was the communication time for each device. Therefore, it took one communication time x n (the number of terminal stations in the area) to collect information from all the terminal stations in the area. Further, when the area where the terminal station is installed covers a wide area, it takes time for the information collector to move.

The present invention solves such a conventional problem, and even if the terminal station adopts the discontinuous reception method, it is possible to collect information from the mobile station and shorten the information collection time. The purpose is to provide a system.

[0005]

A wireless information collecting system according to the present invention comprises one mobile station and a plurality of terminal stations.
In the wireless system having the N operation mode, the mobile station includes a first transceiver and a second transceiver that operate independently of each other, the terminal station includes a third transceiver, and the mobile station and a plurality of mobile stations The data communication is performed with the terminal station.

This wireless information collecting system is basically composed of a mobile station and a plurality of terminal stations. The mobile station
First transceiver (radio A), second transceiver (radio B)
And a communication control unit that controls them, and the terminal station includes a wireless unit, a control unit, and a measurement unit. When wirelessly collecting data from a plurality of terminal stations that perform intermittent reception, the wireless device A of the mobile station transmits a simultaneous call signal for switching the operation of the terminal station from the intermittent reception mode to the data transmission mode to the line frequency ( Continuously transmit at f1). When the terminal station which is performing the intermittent reception at the line frequency (f1) receives the general call signal transmitted from the radio A of the mobile station, the line frequency is switched to f2 and the transmission data of the own station is transmitted to the mobile station. Transmit to radio B. The radio B of the mobile station which has received the data transmitted from the terminal station transmits a confirmation signal to the terminal station at the line frequency (f2), shifts to the reception mode again, and transmits from other terminal stations. Receive data. Information is collected by such a procedure.

With the above structure, the terminal station of the wireless information collecting system of the present invention adopts the battery driving method, and is designed to be small and lightweight, so that it requires no power supply work, is excellent in installation, and is a device for collecting information. Can be easily attached to. Since the mobile station collects the information, it is possible to collect the information in a short time even if the device for collecting the information exists in a wide range. Further, since the terminal station employs a battery-driven system, it performs an intermittent reception operation in order to realize long-time operation with low power consumption. At this time, in order to shorten the communication link establishment time between the mobile station and the terminal station, the mobile station radio A continuously makes a call, and all terminal stations in the communicable area are interrupted at the maximum intermittent reception cycle time. The communication link is established. Therefore, the mobile station and the terminal station become a system in which communication is surely completed within the communicable range.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION The wireless information according to claim 1 of the present invention.
Broadcast collection system, the transfer Dokyoku, use the first line frequency
A first transmitting / receiving unit and a second using a second line frequency
And a transmission / reception unit of
A third transceiver for switching the second frequency,
The first transmitting / receiving unit of the mobile station is the first unit for the plurality of terminal stations.
While transmitting the ringing signal using the frequency of
The second transmission / reception unit receives data from a plurality of terminal stations
Therefore, the terminal station is set to the standby state, and the terminal station
When receiving the ringing signal, switch to the second line frequency
Second transmission / reception of data with mobile station's own address
The mobile station receives data from the terminal station
And add your own address using the second line frequency
Confirmation signal sent to the terminal station, and the terminal station receives the confirmation signal.
After stopping the operation for a certain period of time after receiving the
It is to switch .

Further, the wireless information according to claim 2 of the present invention.
Collection systems are moved Dokyoku, using the first of the line frequency
A first transmitting / receiving unit and a second transmitting / receiving unit that uses a second line frequency.
Transceiver and third transceiver using the third line frequency
And the terminal station has a first line frequency and a second line.
Fourth transmitting / receiving unit for switching frequency and third line frequency
And the first transmitting / receiving unit of the mobile station is compatible with a plurality of terminal stations.
While transmitting the ringing signal using the first frequency,
The second transmitting / receiving unit of the mobile station receives data from a plurality of terminal stations.
The fourth transmission / reception unit of the terminal station in the standby state for receiving
Receives the call signal from the first transceiver, the second
To the line frequency and add its own address.
Data to the second transceiver of the mobile station,
Switching to wave number, mobile station receives data from terminal station
Then, the third transmission / reception unit uses the third line frequency to transmit
Send a confirmation signal with your own address to the terminal station,
The terminal station received the confirmation signal and stopped operating for a certain period of time.
After that, the frequency is switched to the first line frequency .

[0010]

Further, the wireless information according to claim 3 of the present invention.
The collection system uses the first line frequency and the second line frequency.
And any channel on the third line frequency is used
The first line frequency, the second line frequency,
Is an arbitrary line frequency from the third line frequency to the empty channel
To switch .

[0012] The wireless information according to claim 4 of the present invention.
The collection system transmits data at multiple terminal stations.
Set the transmission delay time to delay each by different time
However, the setting of the transmission delay time is set in advance .

Further, the wireless information according to claim 5 of the present invention.
The collection system transmits data at multiple terminal stations .
Set the transmission delay time to delay each by different time
The transmission delay time is set by receiving the ringing signal from the mobile station.
Set by arithmetic processing means that calculates randomly each time it receives
It is what is done.

A wireless information collecting system according to claim 6 of the present invention.
Stem, each in a plurality of terminal stations, the transmission of the data s
Set the transmission delay time to delay by different time, and send
The delay time is set according to the electric field strength of the ringing signal from the mobile station.
It is set by the electric field strength measuring means for measuring the strength .

[0015]

[0016]

According to the first aspect of the present invention, a system is constituted by a mobile station and a terminal station, and a communication link is established with a plurality of terminal stations performing an intermittent reception operation at a line frequency: f1 at a maximum intermittent reception cycle time. The two-channel system (line frequency: f1, which is provided with a transmission / reception unit dedicated to a ringing signal and a transmission / reception unit for receiving data transmitted from a terminal station at a line frequency: f2 and transmitting a confirmation signal to which an individual address is added
When a intermittent call reception operation is performed at a line frequency of f1 with a mobile station adopting f2) and a paging signal is received, the communication control unit switches the transmission / reception unit from the reception mode to the transmission mode, and switches the line frequency to f2. After transmitting data and receiving a confirmation signal from the mobile station, it shifts to the stop mode for a certain period of time, prioritizes communication of other terminal stations, and then again.
It is composed of terminal stations that recover intermittent operation. Therefore, in the conventional system, a series of communications such as a paging signal transmission from the mobile station, a data transmission from the terminal station, and a confirmation signal transmission from the mobile station notifying that the data has been received are handled by one line. Since the frequency was time-divided, when the terminal station performs the discontinuous reception operation, it takes a communication link determination time, and it was difficult for the mobile station to collect information from multiple terminal stations, The invention of claim 1 solves the problems of the conventional system by adopting the above-mentioned two-channel system.

The invention of claim 2 uses three channels by adding a transceiver using the line frequency: f3 to the mobile station of claim 1 and dedicating the transmission of the confirmation signal to the terminal station. Thus, the problems of the conventional system can be solved by enabling parallel processing of transmission of a paging signal, data transmission from a terminal station and transmission of a confirmation signal from a mobile station, respectively.

According to a third aspect of the present invention, when the line frequency used by this system is used by another system, the line frequency used by this system is switched to an empty channel so that the line between the mobile station and the terminal station is changed. Establish communication.

According to claims 4 to 6, a transmission delay time is provided so that the transmission data does not collide when a plurality of terminal stations of the present system simultaneously receive the paging signals from the mobile stations and transmit the respective data. It is a thing. According to the transmission delay time setting of claim 4, different transmission delay times are set in advance for each terminal station. Here, an example of the preset transmission delay time will be described below. First, all the terminal stations installed in the specific area are set to Tk (k = 0 to n), and the data transmission time of the terminal station is set to Td msec including the margin time. If the transmission delay time at this time is TWk = Td × kmsec, different transmission delay times can be set for all the terminal stations. In the transmission delay time setting of claim 5, the transmission delay time is calculated and set by random number calculation each time the terminal station receives the paging signal. Here, a calculation example of the transmission delay time by random number calculation will be described below. First, all the terminal stations installed in the specific area are set to Tk (k = 0 to n), and the data transmission time of the terminal station is set to Td msec including the margin time. The transmission delay time at this time is TWk = Td × kmsec (where
When k is a random number of 0 to n), the terminal station calculates the transmission delay time obtained by the random number calculation each time the call signal is received. According to the sixth aspect of the present invention, the transmission delay time is set by measuring the electric field strength of the paging signal by the transmitting / receiving section having the electric field strength measuring means and calculating and setting the transmission delay time based on the electric field strength.
Here, a calculation example of the transmission delay time will be described below. First, all terminal stations installed in the specific area are set to Tk (k = 0
Up to n), and the data transmission time of the terminal station is Td msec including the allowance time. In addition, the maximum received electric field strength of this system is 80 dBuV, and the received electric field strength when a calling signal is received is p dBuV. The transmission delay time at this time is TW
When x = Td × n × (p / 80) msec, the transmission delay time depending on the received electric field strength can be set for all the terminal stations.

[0021]

Embodiments of the present invention will be described below with reference to the drawings. (Embodiment 1) FIG. 1 shows a principle configuration of a wireless information collecting system according to the present invention. In FIG. 1, 1 is a mobile station, and 2-1 to 2-N are terminal stations. When collecting information from a plurality of terminal stations using one mobile station, the line frequency: f1 is used and a call signal which is a data transmission request signal is transmitted to the plurality of terminal stations. Then, the terminal station that has received the calling signal switches to the line frequency: f2 and transmits data to the mobile station. in this way,
By using two channel frequencies, the mobile station can transmit a paging signal and each terminal station can transmit data.
Can be processed in parallel.

FIG. 2 is a block diagram showing an embodiment of the terminal station shown in FIG. In FIG. 2, the terminal station 2
Is a transmission / reception antenna 3, a transmission / reception unit 4, a communication control unit 5 for switching between transmission / reception and line frequency, a memory 6 for storing own station address, line frequency data, transmission data and receiving data, an external device, The measurement / control unit 7 measures the data collected from the sensor and controls the external device, and the external device / sensor 8. When the terminal station 2 is in the initial state of waiting for reception of the line frequency: f1 and receives a call signal from the mobile station 1, the communication control unit 5 switches the line frequency of the transmission / reception unit 4 to f2, and changes from the reception mode to the transmission mode. Then, the transmission data including the own station address and the measurement data stored in the memory 6 is transmitted.
Further, the external device can be controlled by adding a control command for the external device to the calling signal from the mobile station 1. After the terminal station 2 finishes the data transmission to the mobile station 1 and the control operation of the external device, the communication control unit 5 switches the line frequency of the transmission / reception unit 4 to f1, switches to the reception mode, and shifts to the initial state.

FIG. 3 is a block diagram showing an embodiment of the mobile station shown in FIG. In FIG. 3, the mobile station 1
Is a transmitting / receiving antenna 9, a transmitting / receiving antenna 10, a terminal station 2
Control of the transmission / reception unit 11 for transmitting a call signal, the transmission / reception unit 12 for receiving data from the terminal station 2 and for transmitting a confirmation signal, the communication control unit 13 for controlling the transmission / reception unit 11, and the transmission / reception unit 12. A communication control unit 14 to perform, a memory 15 for storing own station address and line frequency data, collected terminal station data, an operation unit 16 for instructing start and stop of operation,
The display unit 17 displays the data received from the terminal station 2 and the operation status.

When starting the operation of this system, the operation unit 1
When the start SW of 6 is input, the call signal is transmitted from the transmitter / receiver 11 using the line frequency: f1, and at the same time,
The transmission / reception unit 12 enters a reception waiting operation of the line frequency: f2 and receives data from the terminal station.

Next, the control operation of the terminal station of the present invention shown in FIG. 2 will be described with reference to the flow chart shown in FIG. First, the terminal station shown in FIG. 2 switches the line frequency of the transmission / reception unit 4 to f1 by the communication control unit 5 and performs a reception operation. In step S1, the carrier sense operation is started to wait for reception of a calling signal. When the carrier is detected in step S2, the process proceeds to step S3 to analyze the received data, and in step S4 it is determined whether the signal is a ringing signal. If the received data is a calling signal, the process proceeds to step S5. If the received data is a signal other than the calling signal, the process returns to step S1. If it is determined in step S4 that the ringing signal has been received,
After switching the line frequency to f2 in step S5 and performing carrier sensing of f2 in step S6,
In step 7, the data including the individual address and measurement data stored in the memory 6 is transmitted. Then, in step S8, the line frequency is switched to f1, and in step S9 the transmitting / receiving unit 4
Is switched to the reception mode, and the process returns to step S1.

The control operation of transmitting a confirmation signal to the terminal station when the mobile station receives data from the terminal station will be described with reference to the flowchart of FIG. The operation of steps S1 to S7 of FIG. 6 is the same as that of FIG. 5, and after the terminal station transmits data to the mobile station, in order to confirm whether or not the mobile station can normally receive the data, When the mobile station receives data from the terminal station, the mobile station sends and receives a confirmation signal to which the individual address of the received terminal station is added.
To transmit using the line frequency: f2, switch the transmission / reception unit 12 to the reception mode again, and receive data transmitted from another terminal station. In addition, the terminal station
After transmitting the data in step 7, the transmission / reception unit 4 is switched to the reception mode in order to receive the confirmation signal from the mobile station, and step S8 is performed.
Wait for confirmation signal reception. Until the confirmation signal is received, it is determined in step S9 whether or not the time is up. If the time is up, the process proceeds to step S11 to transmit the data again. If the confirmation signal is received from the mobile station without time-up, the communication is normally completed, and thus the operation is stopped for a certain period of time in step S10.
This has the effect of prioritizing communication between other terminal stations and mobile stations.
As an example of the operation stop time in step S10,
Assuming that the communication limit distance between the terminal station and the mobile station is 200 m and the traveling speed of the mobile station is 60 km / h, the time required for the mobile station to travel 200 m is about 12 seconds.

Therefore, when the operation stop time is set to 12 seconds, it is set to 1 when a certain terminal station normally ends the data transmission.
Since the ringing signal from the mobile station is not received for 2 seconds, another terminal station can transmit data to the mobile station during that time. When it returns to the initial state after 12 seconds,
The mobile station is collecting data for the terminal station 200 m away and is transmitting the call signal at a distance greater than the communication limit distance, so the terminal station restored to the initial state cannot receive the call signal, so It does not affect the data transmission of terminal stations existing in other areas. In step S11, in order to return to the initial state, the line frequency is switched to f1, and in step S12 the transmission / reception unit 4 is switched to the reception mode to restore the initial state.

Next, the control operation of the mobile station of the present invention shown in FIG. 3 will be described with reference to the flow chart shown in FIG. First, when starting the operation of this system, step S1
As shown in, the start SW of the operation unit 16 of the mobile station is pressed. When the start SW is pressed, the communication control unit 13 and the communication control unit 14 respectively control the transmission / reception unit 11 to change the line frequency: f.
The transmission / reception unit 12 is switched to the transmission mode of 1 and the reception mode of the line frequency: f2, and the parallel processing operation of steps S3 and S4 is performed. In step S3, the calling signal is transmitted from the transmitting / receiving unit 11 using f1. In step S4, the transceiver 12 receives the terminal station data using f2, analyzes the received data in step S5, and stores the received data in the memory 15 in step S6. Then, in step S7, a confirmation signal is transmitted to the terminal station based on the individual address included in the received data. In step S8, it is determined whether or not the end SW of the operation unit 16 has been pressed, and the parallel processing of steps S3 to S7 is repeated until the end SW is pressed. When the end SW is pressed, the data stored in the memory 15 is converted into a file in the output format in step S9,
In step S10, received data files from a plurality of terminal stations are output to the display unit 17. As described above, the mobile station of this system can process calling signal transmission and data reception from the terminal station in parallel by using a plurality of line frequencies. The effect of improving the processing speed of data collection is higher than that of a system in which transmission and reception are time-divisionally processed.

The ringing signal transmitted by the mobile station is selected from the general ringing signal, the individual ringing signal and the faulty ringing signal. The paging signal is a signal transmitted when it is desired to collect information from all the terminal stations in the area, and each terminal station receiving the paging signal transmits its own data to the mobile station. An example of the transmission data of the terminal station is (individual address) + (measurement data) + (time data). Further, the individual calling signal is transmitted by adding the individual address of the target terminal station to the calling signal when it is desired to collect data of only individual terminal stations in the area. The fault call signal is used when it is desired to collect data of a terminal station having fault information. When the faulty device call command is added to the calling signal and measured from the external device / sensor 8 connected to the terminal station, and the data stored in the memory 6 is the fault information, the terminal station sends the faulty device calling signal. When received,
Send data. As described above, by properly using the calling signal, the mobile station has an effect of obtaining necessary data from the terminal station.

(Embodiment 2) FIG. 4 is a block diagram showing an embodiment of the mobile station shown in FIG. In FIG. 4, the mobile station 1 includes a transmission / reception antenna 18, a transmission / reception antenna 19, a transmission / reception antenna 20, a transmission / reception unit 21 that transmits a calling signal to the terminal station 2, a transmission / reception unit 22 that receives data from the terminal station 2, and a confirmation. Transmitter / receiver 2 for transmitting signals
3, a communication control unit 24 that controls the transmission / reception unit 21, a communication control unit 25 that controls the transmission / reception unit 22, a communication control unit 26 that controls the transmission / reception unit 23, own station address and line frequency data, collected terminal station Memory 27 for storing the data of
The communication control unit 24, the communication control unit 25, and the communication control unit 2 include an operation unit 28 for instructing start and stop of operation, and a display unit 29 for displaying data received from the terminal station 2 and an operation status.
6 operates independently of each other.

The operation unit 2 when starting the operation of this system
When the start SW of 8 is input, the call signal is transmitted from the transmitter / receiver 21 using the line frequency: f1, and at the same time,
The transmission / reception unit 22 enters a reception waiting operation of the line frequency: f2, and when data is normally received from the terminal station, the transmission / reception unit 23 uses the line frequency: f3 to the terminal station that has transmitted the data. , Sends a confirmation signal with the individual address added.

Next, the control operation of the mobile station of the present invention shown in FIG. 4 will be described with reference to the flow chart shown in FIG. First, when starting the operation of this system, step S1
As shown in, the start SW of the operation unit 28 of the mobile station is pressed. When the start SW is pressed, as shown in step S2, the communication control unit 24, the communication control unit 25, and the communication control unit 26.
The transmission / reception unit 21 is switched to the transmission mode of the line frequency: f1, the transmission / reception unit 22 is switched to the reception mode of the line frequency: f2, and the transmission / reception unit 23 is switched to the transmission mode of the line frequency: f3 by the parallel processing of step S3 and step S4. Move to operation. In step S3, the transmission / reception unit 21 uses f1 to transmit a calling signal. In step S4, the transceiver 22 receives the terminal station data using f2, analyzes the received data in step S5, stores the received data in the memory 27 in step S6, and receives the data in step S7. Based on the individual address included in the data, a confirmation signal with the individual address added is transmitted to the terminal station using f3. In step S8, it is determined whether or not the end SW of the operation unit 28 is pressed, and the above step S8 is performed until the end SW is pressed.
The parallel processing of 3 to S7 is repeated. When the end SW is pressed, the data stored in the memory 27 is converted into a file in the output format in step S9, and the received data files from the plurality of terminal stations are output to the display unit 29 in step S10.

Next, the control operation of the terminal station shown in FIG. 2 with respect to the control operation of the mobile station of the present invention shown in FIG. 4 will be described with reference to the flow chart shown in FIG. First, the terminal station shown in FIG. 2 switches the line frequency of the transmission / reception unit 4 to f1 by the communication control unit 5 and performs a reception operation. In step S1, the carrier sense operation is started to wait for reception of a calling signal. When the carrier is detected in step S2, the process proceeds to step S3 to analyze the received data, and in step S4 it is determined whether the signal is a ringing signal. If the received data is a calling signal, the process proceeds to step S5. If the received data is a signal other than the calling signal, the process returns to step S1. Step S
When it is determined that the ringing signal is received in step 4, the line frequency is switched to f2 in step S5, carrier sensing of f2 is performed in step S6, and then the individual address and measurement data stored in the memory 6 are added in step S7. Send the data you have made. Then, in step S8, the transmission / reception unit 4 is switched to the reception mode of the line frequency: f3, and in step S9, the confirmation signal is waited for. Until you receive the confirmation signal,
In step S10, it is determined whether or not the time is up, and if the time is up, the process proceeds to step S12 to transmit the data again. If the confirmation signal is received from the mobile station without the time up, the communication is normally completed, and thus the operation is stopped for a certain period of time in step S11.
This has the effect of prioritizing communication between other terminal stations and mobile stations.
In step S12, in order to return to the initial state, the line frequency is switched to f1, and in step S13 the transmission / reception unit 4 is switched to the reception mode to restore the initial state.

As described above, the mobile station of the present system uses a plurality of line frequencies to process the calling signal from the mobile station, the data reception from the terminal station, and the confirmation signal transmission from the mobile station in parallel. Therefore, there is an effect that the processing speed of data collection is improved as compared with the conventional system in which transmission and reception are time-divisionally processed by using one line frequency.

(Embodiment 3) The line frequency switching control operation of the mobile station of the present invention shown in FIGS. 3 and 4 will be described with reference to the flow chart shown in FIG. First, step S1
, The communication control units (13, 1) shown in FIGS.
4, 24, 25, 26) controls each transmitting / receiving unit (1
1, 12, 21, 22, 23), which are preset as initial values from the line frequencies (f1, f2,
Perform carrier sense of f3). Next, in step S2, it is determined whether or not a carrier is detected. If there is no carrier, the currently set line frequency is used. If the carrier is sensed in step S2, the time during which the carrier exists is counted in step S3. If the time is not up, the process returns to step S1. When the time is up, the process proceeds to step S4 and the line frequency is switched to the next line frequency set in advance. After the line frequency is switched, the process returns to step S1 to check the line frequency that is currently set. By the control operation as described above, the line frequency is switched to the vacant channel when another system uses the preset line frequency used by this system for the preset monitoring time or longer.

Next, the line frequency switching control operation of the terminal station of the present system shown in FIG. 2 will be described with reference to the flow chart shown in FIG. First, in the case of checking the line frequency: f1, in step S1, the carrier sense of the line frequency: f1 used in the present system preset as an initial value from the transmission / reception unit 4 under the control of the communication control unit 5 shown in FIG. I do. Next, in step S2, it is determined whether or not a carrier is detected. If there is no carrier, the currently set line frequency is used. When carrier sense is performed in step S2, the process proceeds to step S4 via step S3. When the ringing signal is recognized in step S4, the currently set line frequency is used. If the signal is not the calling signal in step S4, the time during which the carrier exists is counted in step S5. If the time has not expired, the process returns to step S1. When the time is up, the process proceeds to step S6 and the line frequency is switched to the next line frequency set in advance. After the line frequency is switched, the process returns to step S1 to check the line frequency that is currently set. Also, line frequency: f
When checking 2 and f3, the line frequency is switched by performing the operation without passing through step S4 in the flow of the line frequency: f1. By the control operation as described above, when another system is using the preset line frequency used by this system for the preset monitoring time or longer,
The line frequency can be switched to an empty channel.

(Embodiment 4) The control operation of the terminal station of the present invention shown in FIG. 2 will be described with reference to FIG. First, the terminal station shown in FIG. 2 switches the line frequency of the transmission / reception unit 4 to f1 by the communication control unit 5 and performs a reception operation. In step S1, the carrier sense operation is started to wait for reception of a calling signal. When the carrier is detected in step S2, the process proceeds to step S3 to analyze the received data, and in step S4 it is determined whether the signal is a ringing signal. If the received data is a calling signal, the process proceeds to step S5. If the received data is a signal other than the calling signal, the process returns to step S1.
When it is determined that the ringing signal is received in step S4, the line frequency is switched to f2 in step S5, and step S6 is performed.
Move to. In step S6, a preset transmission delay time is weighted. Here, an example of the preset transmission delay time will be described below.

First, all the terminal stations installed in the specific area are set to Tk (k = 0 to n), and the data transmission time of the terminal station is set to Td msec including the margin time. If the transmission delay time at this time is TWk = Td × kmsec, different transmission delay times can be set for all the terminal stations. After the transmission delay time has elapsed, carrier sensing of f2 is performed in step S7, and then the individual address and measurement data added data stored in the memory 6 is transmitted in step S8. Thereafter, the line frequency is switched to f1 in step S9, the transmission / reception unit 4 is switched to the reception mode in step S10, and the process returns to step S1. As described above, when the mobile station transmits a paging signal to all the terminal stations in the specific area by setting the transmission delay time, even if a plurality of terminal stations simultaneously receive the paging signal, Since the terminal stations transmit data to the mobile station after different transmission delay times, it is possible to avoid collision of respective transmission data.

(Embodiment 5) The control operation of the terminal station of the present invention shown in FIG. 2 will be described with reference to FIG. First, the terminal station shown in FIG. 2 switches the line frequency of the transmission / reception unit 4 to f1 by the communication control unit 5 and performs a reception operation. In step S1, the carrier sense operation is started to wait for reception of a calling signal. When the carrier is detected in step S2, the process proceeds to step S3 to analyze the received data, and in step S4 it is determined whether the signal is a ringing signal. If the received data is a calling signal, the process proceeds to step S5. If the received data is a signal other than the calling signal, the process returns to step S1.
When it is determined that the ringing signal is received in step S4, the line frequency is switched to f2 in step S5, and step S6 is performed.
Move to. In step S6, the transmission delay time is calculated by random number calculation each time. Here, a calculation example of the transmission delay time by random number calculation will be described below. First, all the terminal stations installed in the specific area are set to Tk (k = 0 to n), and the data transmission time of the terminal station is set to Td msec including the margin time. The transmission delay time at this time is TWk = Td × k mse
When c (where k is a random number from 0 to n) is set, the terminal station calculates a transmission delay time obtained by random number calculation each time a call signal is received. After calculating the transmission delay time, the transmission delay time is set in step S7 and the transmission delay time set in step S8 is weighted. After the transmission delay time has elapsed, carrier sensing of f2 is performed in step S9, and then the individual address stored in the memory 6 and the data to which the measurement data is added are transmitted in step S10. Then, step S1
The line frequency is switched to f1 in 1 and the transmission / reception unit 4 is switched to the reception mode in step S12, and the process returns to step S1. As described above, when the mobile station transmits a paging signal to all the terminal stations in a specific area by setting the transmission delay time by calculating a random number, when a plurality of terminal stations receive the paging signal at the same time. However, since each terminal station transmits data to the mobile station after the transmission delay time set by the random number calculation, collision of each transmission data can be avoided.

(Sixth Embodiment) The control operation of the terminal station of the present invention shown in FIG. 2 will be described with reference to FIG. First, the terminal station shown in FIG. 2 switches the line frequency of the transmission / reception unit 4 to f1 by the communication control unit 5 and performs a reception operation. Further, the transmission / reception unit 4 has an electric field strength measuring means. In step S1, the carrier sense operation is started to wait for reception of a calling signal. When the carrier is detected in step S2, the process proceeds to step S3 to analyze the received data, and in step S4 it is determined whether the signal is a ringing signal. If the received data is a calling signal, the process proceeds to step S5. If the received data is a signal other than the calling signal, the process returns to step S1. If it is determined in step S4 that the ringing signal has been received,
In step S5, the transmission / reception unit 4 having the electric field intensity measuring means measures the received electric field intensity of the calling signal, and the process proceeds to step S6. In step S6, the transmission delay time is calculated based on the received electric field strength. Here, a calculation example of the transmission delay time will be described below. First, all the terminal stations installed in the specific area are set to Tk (k = 0 to n), and the data transmission time of the terminal station is set to Td msec including the margin time. In addition, the maximum received electric field strength of this system is 80 dBuV, and the received electric field strength when a calling signal is received is p dBuV. The transmission delay time at this time is TWx = Td × n × (p / 80) m
If sec is set, the transmission delay time that depends on the received electric field strength can be set for all terminal stations. After calculating the transmission delay time, set the transmission delay time in step S7, and
In 8 the line frequency is switched to f2 and the process moves to step S9. In step S9, a wait operation of the transmission delay time obtained from the received electric field strength is performed. After the transmission delay time has elapsed, carrier sensing of f2 is performed in step S10, and then data to which the individual address and measurement data stored in the memory 6 are added is transmitted in step S11. After that, step S
The line frequency is switched to f1 in 12 and the transmitting / receiving unit 4 is switched to the receiving mode in step S13, and the process returns to step S1. As described above, by setting the transmission delay time based on the received electric field strength, the data transmission of the terminal station far from the mobile station or the terminal station having a poor radio wave reception state is prioritized.

(Embodiment 7) FIG. 1 shows the system configuration of the present invention. In FIG. 1, 1 is a mobile station, and 2-
1 to 2-N are terminal stations. When collecting information from multiple terminal stations using one mobile station, the line frequency: f
1 is used to transmit a paging signal which is a data transmission request signal to a plurality of terminal stations, and the terminal station which receives the paging signal switches to the line frequency: f2 and Send data. In this way, by using two channel frequencies, the paging signal transmission from the mobile station and the data transmission from each terminal station can be processed in parallel. FIG. 15 is a timing chart showing an embodiment of the mobile station and the terminal station shown in FIG. In FIG. 15, the horizontal axis is the time axis, (1) represents the transmission operation of the paging signal of the mobile station 1, (2) represents the reception operation of the mobile station 1, and (3) represents the terminal. The transmission / reception operation of the station 2-1 is represented, (4) represents the transmission / reception operation of the terminal station 2-2,
(5) represents the transmission / reception operation of the terminal station 2-3. Communication between the mobile station and the terminal station will be described below with reference to (1), (2), (3) and FIGS. 2 and 3. First, when collecting data from a plurality of terminal stations, the transmitting / receiving unit 11 of the mobile station
To carrier frequency using the line frequency: f1 and then continuously transmits a paging signal. The terminal station 2-1 performs the intermittent reception operation of the line frequency: f1 at the intermittent reception cycle: t, and when the paging signal is received at the time t1, the transmission delay time elapses and the line frequency: f2 is used at the time t2. Then, after carrier sensing is performed to the transmitting / receiving unit 12 of the mobile station, data is transmitted, and the operation shifts to a confirmation signal receiving operation from the mobile station.
The mobile station that has received the data from the terminal station 2-1 at time t2 transmits a confirmation signal to the terminal station 2-1 with an individual address added after carrier sensing at time t3. The terminal station 2-1 that has received the confirmation signal at time t3 stops the transmission operation for a certain period of time and restores the intermittent reception operation again. Therefore,
Even if the paging signal is received at t4, the data transmission operation is not started. The terminal stations 2-2 to 2-n also perform the same operation as above and transmit data to the mobile station. In the receiving operation of the mobile station of (2), when the data is received from the terminal station, it is explained that the confirmation signal is transmitted at the line frequency: f2, but the transmission of the confirmation signal is omitted if not necessary. In this case, the transmitting / receiving unit 12 of the mobile station may be used.
Is receive-only. As described above, by continuously transmitting the paging signal, even when a plurality of terminal stations are performing the intermittent receiving operation asynchronously, the paging signal is transmitted within the intermittent reception cycle time after the transmission is started. Each terminal station will be able to receive the paging signal,
The communication time with the terminal station can be shortened compared to the conventional intermittent call system.

(Embodiment 8) FIG. 1 shows the system configuration of the present invention. In FIG. 1, 1 is a mobile station, and 2-
1 to 2-N are terminal stations. When collecting information from multiple terminal stations using one mobile station, the line frequency: f
1 is used to transmit a paging signal which is a data transmission request signal to a plurality of terminal stations, and the terminal station which receives the paging signal switches to the line frequency: f2 and Send data. In this way, by using two channel frequencies, the paging signal transmission from the mobile station and the data transmission from each terminal station can be processed in parallel. FIG. 16 is a timing chart showing an embodiment of the mobile station and the terminal station shown in FIG. In FIG. 16, the horizontal axis represents the time axis, (6) represents the transmission operation of the paging signal of the mobile station 1, (7) represents the reception operation of the mobile station 1, and (8) represents the terminal. The transmission / reception operation of the station 2-1 is represented, (9) represents the transmission / reception operation of the terminal station 2-2,
(10) represents a transmission / reception operation of the terminal station 2-3. Communication between the mobile station and the terminal station will be described below with reference to (6), (7), (8) and FIGS. 2 and 3. First, when collecting data from a plurality of terminal stations, the transmitting / receiving unit 11 of the mobile station
The carrier frequency and the paging signal transmission are repeatedly performed using the line frequency: f1. The transmission time of the paging signal is (intermittent reception cycle: t) + (margin time: a), and the carrier sense time is the transmission pause time. Terminal station 2-1
Performs an intermittent reception operation with a line frequency: f1 at an intermittent reception cycle: t, and if a paging signal is received at t1 time, the transmission delay time elapses, and then the line frequency: f2 is used at t2 time. After carrier sensing is performed on the transmission / reception unit 12, data is transmitted, and a confirmation signal reception operation from the mobile station is started. The mobile station that has received the data from the terminal station 2-1 at time t2 transmits a confirmation signal to the terminal station 2-1 with an individual address added after carrier sensing at time t3. The terminal station 2-1 that has received the confirmation signal at time t3 stops the transmission operation for a certain period of time and restores the intermittent reception operation again. Therefore, even if the paging signal is received at time t4, the data transmission operation is not started. The terminal stations 2-2 to 2-n also perform the same operation as above and transmit data to the mobile station. In the receiving operation of the mobile station of (7), when the data is received from the terminal station, it is explained that the confirmation signal is transmitted at the line frequency: f2, but the transmission of the confirmation signal is omitted if not necessary. However, in this case, the transceiver unit 12 of the mobile station is dedicated to reception. As described above, the transmission time of the paging signal is set to (intermittent reception cycle: t) + (margin time: a), and the carrier sense time is set to the transmission suspension time, so that a plurality of terminal stations asynchronously intermittently Even when performing the receiving operation, each terminal station can receive the paging signal within the intermittent reception cycle time after the transmission of the paging signal is started. The communication time with the terminal station can be shortened.

[0044]

As described above, according to the present invention, the terminal station performs the intermittent reception operation during the time when the data of a plurality of terminal stations is collected from the mobile station by using the channel frequencies of multiple channels. In this case, the ringing signal from the mobile station can be received within the intermittent reception cycle time, and then the time can be shortened to the sum of the transmission delay time and the data transmission time.

Further, since the terminal station of the wireless information collecting system of the present invention adopts a battery-driven system to reduce its size and weight, it requires no power supply construction, is easy to install, and is easy to use for devices that want to collect information. Can be attached to. Since the information is collected by the mobile station, there is an advantage that the information can be collected in a short time even if the device for collecting the information exists in a wide range. Further, since the terminal station employs a battery-driven system, it performs an intermittent reception operation in order to realize long-time operation with low power consumption. At this time, in order to shorten the time for establishing the communication link between the mobile station and the terminal station, the radio A of the mobile station makes a continuous call, and the communication link is established at the time of the intermittent reception cycle at the maximum. Therefore, the mobile station and the terminal station become a system in which communication is surely completed within the communicable range.

[Brief description of drawings]

FIG. 1 is a conceptual diagram illustrating a principle configuration of a wireless information collecting system of the present invention.

FIG. 2 is a block diagram showing the configuration of an embodiment of a terminal station used in the wireless information collecting system of the present invention.

FIG. 3 is a block diagram showing a configuration example of a mobile station used in the wireless information collecting system of the present invention.

FIG. 4 is a block diagram showing another configuration example of a mobile station used in the wireless information collecting system of the present invention.

FIG. 5 is a flowchart explaining the operation of the first embodiment of the terminal station used in the wireless information collecting system of the present invention.

FIG. 6 is a flowchart explaining another operation of the first embodiment of the terminal station used in the wireless information collecting system of the present invention.

FIG. 7 is a flowchart explaining the operation of the second embodiment of the terminal station used in the wireless information collecting system of the present invention.

FIG. 8 is a flowchart explaining the operation of the first embodiment of the mobile station used in the wireless information collecting system of the present invention.

FIG. 9 is a flowchart explaining the operation of the second embodiment of the mobile station used in the wireless information collecting system of the present invention.

FIG. 10 is a flowchart explaining the operation of the third embodiment of the mobile station used in the wireless information collecting system of the present invention.

FIG. 11 is a flowchart illustrating the operation of the third embodiment of the terminal station used in the wireless information collecting system of the present invention.

FIG. 12 is a flow diagram illustrating a transmission delay operation of the fourth embodiment of a terminal station used in the wireless information collecting system of the present invention.

FIG. 13 is a flow chart for explaining a transmission delay operation of the fifth embodiment of the terminal station used in the wireless information collecting system of the present invention.

FIG. 14 is a flowchart for explaining a transmission delay operation of the sixth embodiment of the terminal station used in the wireless information collecting system of the present invention.

FIG. 15 is a timing chart explaining a communication operation between the mobile station and the terminal station shown in FIG.

16 is a timing chart for explaining another communication operation between the mobile station and the terminal station shown in FIG.

[Explanation of symbols]

1 mobile station 2-1 to 2-n Terminal station 3, 9, 10, 18, 19, 20 Transmitting / receiving antenna 4, 11, 12, 21, 22, 23 Transmitter / receiver 5, 13, 14, 24, 25, 26 Communication control unit 6,15a, 15b, 27a, 27b, 27c memory 7 Measurement control unit 8 External devices / sensors 16, 28 Operation part 17, 29 Display

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Katsuaki Abe 1006 Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Industrial Co., Ltd. (72) Satoru Ta Taku 1006 Kadoma, Kadoma City, Osaka Matsushita Electric Industrial Co., Ltd. (72) Inventor Koichi Shinozaki 3-22 Nakanoshima 3-chome, Kita-ku, Osaka City, Osaka Prefecture Kansai Electric Power Co., Inc. (72) Inventor Ken Sawada 3-3 Nakanoshima, Kita-ku, Osaka City, Osaka Prefecture No. 22 in Kansai Electric Power Co., Inc. (56) Reference JP-A-5-282468 (JP, A) JP-A-5-252073 (JP, A) JP-A-2-97143 (JP, A) (58) Survey Fields (Int.Cl. ⁷ , DB name) H04Q 9/00-9/16 H03J 9/00-9/06 H04B ^7/ 24-7/26 H04Q ⁷ /00-7/38

Claims (6)

(57) [Claims] De between 1. A one mobile station and multiple terminal stations
In the radio information collecting system for Data Communications, the mobile station comprises a first transceiver <br/> signal section using a first line frequency and a second transceiver using the second line frequency , The terminal station is provided with the first frequency and the second frequency.
A third transmitting / receiving unit for switching between the plurality of terminal stations.
While transmitting the ringing signal using the first frequency
Then, the second transceiver of the mobile station is the plurality of terminal stations.
The terminal station is placed in a standby state to receive the data from the
, The second line frequency is switched to self
Data to which the address of
When transmitting to the receiving unit, the mobile station receives the data from the terminal station,
Assign the own address using the second line frequency
The added confirmation signal is transmitted to the terminal station, and the terminal station receives the confirmation signal and operates for a certain period of time.
A wireless information collecting system, characterized by switching to the first line frequency after stopping . Wherein between one mobile station and a plurality of terminal stations
In the radio information collecting system for data communication, the mobile station includes a second transceiver used in the first transceiver <br/> signal section using a first line frequency, the second line frequency,
Third and a third transceiver using line frequency, to the terminal station, the first line frequency and the second round
A fourth transmission for switching between the line frequency and the third line frequency
A first transmitting / receiving unit of the mobile station, the receiving unit being provided to the plurality of terminal stations;
While transmitting the ringing signal using the first frequency
Then, the second transceiver of the mobile station is the plurality of terminal stations.
The fourth transmission / reception unit of the terminal station is in a standby state for receiving data from the first transmission / reception unit.
When the ringing signal of is received, the second line frequency
Switch and move the data with its own address added
To the second transmission / reception section of the station, and to the third line frequency
Switching, the mobile station receives data from the terminal station,
Using the third line frequency from the third transceiver,
Send confirmation signal with own address to the terminal station
However, the terminal station receives the confirmation signal and operates for a certain period of time.
A wireless information collecting system, characterized by switching to the first line frequency after stopping . Wherein when said first line frequency and the second line <br/> frequency and the third one of the channels of the line frequency is <br/> used, the first 1 line frequency , the second
Line frequency or said third radio information collecting system according to claim 1 or 2, wherein the line frequency, characterized in that switching the optionally line frequency to an empty channel. 4. Transmission of data between the plurality of terminal stations
Set a transmission delay time that delays each signal by a different time
And the radio information collecting system according to any one of claims 1 to 3 setting of the transmission delay time is characterized Rukoto preset. 5. Data transmission at the plurality of terminal stations
Set a transmission delay time that delays each signal by a different time
And, setting of the transmission delay time, the calculation processing means for calculating the random each time it receives a call signal from the mobile station
Radio information collecting system according to any one of claims 1 to 3, wherein Rukoto be more set. 6. Data transmission at the plurality of terminal stations
Set a transmission delay time that delays each signal by a different time
However, the setting of the transmission delay time is performed by an electric field strength measuring unit that measures the strength of the electric field strength of the paging signal from the mobile station .
Radio information collecting system according to any one of claims 1 to 3, characterized in that it is set Ri.