JPH06140967A - Relay station and reduction method of relay processing time for relay station - Google Patents

Abstract

PURPOSE:To realize the method for reducing a relay time by turning on a power supply for a data reception section and a data transmission section at the start of relay of a relay station and turning off the power supply at the end of the relay with respect to the method reducing the relay processing time of the relay station relaying data between a master station and a slave station. CONSTITUTION:The station is provided with an antenna connection section 123 connecting an output of a data transmission section 121 to an antenna A or a termination resistor R and an antenna connection control section 124 outputting a control signal controlling the connection of the antenna connection section 123, and when the start of relaying is discriminated, the power of the data transmission section 121 is turned on and an output of the data transmission section 121 is fed to the antenna A at data transmission and the output of the data transmission section 121 is connected to the termination resistor R when the data transmission is stopped and when the end of relaying is discriminated, the power of the data transmission section 121 is turned off.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for shortening the relay processing time of a relay station which relays data between a master station and a slave station.

For example, a disaster occurs in a telemeter system including a master station (monitoring station), a plurality of slave stations (observation stations), and a relay station that relays observation data between the master station and the slave stations. In this case, it is necessary to transmit the observation data to the master station as soon as possible and take appropriate countermeasures. Therefore, it is required to shorten the relay time of the relay station data as much as possible.

[0003]

2. Description of the Related Art FIG. 4 shows a block diagram for explaining a conventional example. 100A in the figure is a parent station 200 and a plurality of child stations 301 to
It is a relay station that relays data between 30n.

The receiving unit and the transmitting unit of the relay station 100A have a dual structure in order to increase the reliability thereof. The received radio signal is divided into two by the hybrid circuit 114, and the carrier detection units 111a and 111b and the data reception unit 112 are separated.
a and 112b. Here, the data receiving unit 112
a and 112b are carrier detection units 111 in the reception unit.
All except a and 111b are collectively referred to.

The branch / coupling unit 131 causes the data receiving unit 11 to operate.
The output of 2a is connected to the data transmitting unit 121b, or the output of the data receiving unit 112b is connected to the data transmitting unit 121a, and the data is transmitted through the antenna A.

The frequency of the radio signal received by relay station 100A is f1 and the frequency of transmission is f2. Modulation / demodulation section 132 performs modulation / demodulation, and the reception signal is processed by relay processing section 13
It is sending to 0.

The relay processing section 130 determines whether or not there is a received signal, that is, whether or not to perform a relay operation, and the data receiving section 112.
a, 112b and the data transmission units 121a and 121b, which generate a control signal for controlling "on / off" of the power supplies. The reception power control unit 113 and the transmission power control unit 1
22 is controlled so that the power is turned on only when the relay operation is performed.

[0008]

In the above-mentioned conventional example, when data is transmitted from the radio 210 of the master station 200, the carrier receiving section 111a in the relay station 100A.
Alternatively, the carrier is detected by 111b, and the power of the data receiving units 112a and 112b is turned on only when the carrier is detected.

The data transmission units 121a and 121b turn on the power supply by the transmission power supply control unit 122 only when the data to be transmitted is input. In this way, the data receiving units 111a and 111a are used each time data is received and transmitted.
Since the power is supplied to b and the data transmission units 121a and 121b, the time until the respective outputs reach the rated value is the delay time of the data processing.

FIG. 5 is a diagram for explaining the delay of the relay time in the conventional example. (A) is from the master station 200, for example, the slave station 30
It is a figure at the time of transmitting data to 1.

The transmission data is transmitted from the master station 200 to the wireless device 21.
Enter 0. Radio 210 transmits data at frequency f1, but there is a delay. The carrier detecting unit 111a of the relay station 100A detects the carrier, powers on the data receiving unit 112a, and receives the data.

The received data is transmitted at the frequency f2. At this time as well, there is a delay time until the data transmission unit 121a starts up. The sum t1 of the time shaded by .is the delay of the relay time at the relay station 100A.

This is reception determination by detecting the carrier of frequency f2 in the slave station 301. td is the master station 20
0 inputs the relay data to the wireless device 210, and then the slave device 3
01 is the entire delay time until the received data is judged.

FIG. 3B is a diagram when data is returned from the child device 301 to the parent station 200. The transmission data is input to the wireless device 310 by the slave device 301. The radio 310 transmits data at the frequency f1, but there is a delay.

The carrier detection unit 11 of the relay station 100A
1a detects the carrier, determines that it is in the data reception state,
The data receiving unit 112a is powered on to receive data. The received data is transmitted at the frequency f2. At this time as well, there is a delay time until the data transmission unit 121a starts up. The sum t2 of the time shaded by the is the delay of the relay time at the relay station 100A.

This is the reception determination by detecting the carrier of the frequency f2 in the master station 200. td is the handset 30
1 inputs relay data to the wireless device 310, and then the master station 2
00 is the entire delay time until the received data is determined.

In the above description, the duplicated a series, b
Since the operation is the same regardless of which of the series operates, the series a is described as a representative. As described above, since the data receiving units 112a and 112b and the data transmitting units 121a and 121b are turned on and operated each time data is relayed, a delay due to the rise time occurs and the slave station 301
When the number of ~ 30n and the number of relay stations 100A increase, the delay time is accumulated due to rising, which increases the data collection time of the entire system.

The present invention intends to realize a method of shortening the relay time by turning on the power of the data receiving unit and the data transmitting unit at the start of the relay of the relay station and turning off the power at the end of the relay.

[0019]

FIG. 1 is a block diagram for explaining the principle of the present invention. Reference numeral 100 in the figure denotes a relay station that relays data between the master station and the slave station, and 110 in the relay station 100 includes a carrier detection section 111, a data reception section 112, and a reception power control section 113. Reference numeral 120 denotes a transmission unit that includes a data transmission unit 121 that converts a received signal into a radio signal having a different frequency and sends the radio signal, and a transmission power supply control unit 122. Reference numeral 130 denotes a reception unit 11
0 is a relay processing unit that controls 0 and the transmission unit 120.

Reference numeral 123 denotes the relay station 100 according to the present invention.
Is an antenna connection unit that switches the output of the data transmission unit 121 to the antenna A and the terminating resistor R.
Reference numeral 24 denotes an antenna connection control unit that outputs a signal for controlling the operation of the antenna connection unit 123, and the carrier detection unit 11
When the relay processing unit 130 determines from the output of 1 that the relay operation has started, the transmission power supply control unit 122 turns on the power of the data transmission unit 121, and the antenna connection unit 123.
Thus, when transmitting data, the output of the data transmitting unit 121 is supplied to the antenna A, and when the data transmitting is stopped, the output of the data transmitting unit 121 is connected to the terminating resistor R, and the relay processing unit 130 determines that the relay operation is completed. At this time, the power of the data transmission unit 121 is turned “off”.

Further, the power supply of the carrier detection unit 111 is always "ON", and when the relay processing unit 130 determines from the output of the carrier detection unit 111 that the relay operation is started, the reception power supply control unit 113 receives the data. Part 112
When the relay processing unit 130 determines from the output of the carrier detection unit 111 that the relay operation has ended, the power of the data reception unit 112 is turned off.

[0022]

The receiving section 110 is composed of a carrier detecting section 111 and a data receiving section 112 which performs other receiving operation. The carrier detecting section 111 of the receiving section 110 is always turned on to detect the carrier. Is going.

Here, when a carrier from a master station or a slave station (not shown) is detected, it is judged that the relay operation is started, and the transmission power control unit 122 turns on the power of the data transmission unit 121 to relay the data. It remains in the "on" state until the end of the operation.

Further, when relaying data, the data transmission unit 1 is controlled by the control signal from the antenna connection control unit 124.
The output of 21 is connected to the antenna A, and when there is no data transmission, the output of the data transmission unit 121 is connected to the terminating resistor R so that only the carrier is not transmitted.

Also in the receiving section 110, when the carrier detecting section 111 detects a carrier, it is judged that the relay operation is started, and the reception power control section 113 turns on the power of the data receiving section 112 to perform the relay operation. It remains in the "on" state until the end of the operation.

As described above, when the relay operation is started, the power supply of the data receiving section 112 and the data transmitting section 121 is turned "on".
Then, by turning off the power at the end of the relay operation, it is possible to eliminate the influence of the delay of the rising time of the data receiving unit 112 and the data transmitting unit 121.

[0027]

FIG. 2 is a block diagram illustrating an embodiment of the present invention. In the embodiment shown in the figure, the carrier detecting section, the data receiving section, and the data transmitting section have a dual structure.

Reference numeral 100 in the figure denotes a relay station, which includes carrier detection units 111a and 111b and data reception units 112a and 11b.
2b, the receiving power supply control unit 113 constitutes the receiving unit 110,
Data transmission units 121a and 121b, transmission power control unit 12
2, antenna connection unit 123, antenna connection control unit 124
The transmission unit 120 is configured by.

Further, the relay processing 130 and the branch / coupling unit 13
1, a modulator / demodulator 132, termination resistors Ra and Rb, and an antenna A. When transmitting data from the master station 200 to the slave station 301, the data from the master station 200 is transmitted to the wireless device 21.
0 from the data receiving unit 112a of the relay station 100
Through the branch / coupling unit 131 from the data transmission unit 121b
And is input to the wireless device 310 of the slave station 301.

The data from the slave station 301 follows the reverse route, from the wireless device 310 of the slave station 301, the data receiving section 112b of the relay station 100, the branch coupling section 131, the data transmitting section 121a, and the parent station. Radio 2 of station 200
Input to 10. Here, the slave station is 301, but the operation is the same for any of the slave stations 301 to 30n.

FIG. 3 is a diagram for explaining the relay operation of the embodiment of the present invention. (A) is an example in the case of individual control. The master station 200 activates the relay station 100, and the power supplies of the data receiving unit and the data transmitting unit of the relay station 100 are turned on. Slave station 30 in this state
1 is transmitted and data is transmitted, and the slave station 301 transmits the requested data.

The master station 200 receives the data from the slave station 301, sends a relay end instruction to the relay station 100, and turns off the power of the data receiving section and the data transmitting section of the relay station 100.

The data transmission unit is connected to the antenna A only when transmitting data, and prevents unnecessary transmission of only the carrier.
By the above operation, the delay time (t1 + t2) described in the conventional example of FIG. 5 can be eliminated.

(B) is a case of simultaneous command. Master station 20
0 instructs the relay station 100 to start relaying, turns on the power sources of the data receiving unit and the data transmitting unit, and instructs all the slave stations 301 to 30n to transmit data.

The relay station 100 sequentially transmits the data from the slave stations 301 to 30n to the master station 200. At this time, the output of the data transmission unit 121a is connected to the antenna A only when data is transmitted from the relay station 100.

By the above operation, the delay time (t1 + t2 × n) explained in the conventional example of FIG. 5 can be eliminated.

[0037]

According to the present invention, the power of the data receiving section and the data transmitting section of the relay station, which relays data between the master station and the slave station, is turned on by carrier transmission from the master station, and the master station is turned on. By turning off the carrier by stopping the carrier transmission from the station, it is possible to realize a method of shortening the relay processing time of the relay station, which can shorten the relay time.

[Brief description of drawings]

FIG. 1 is a block diagram illustrating the principle of the present invention.

FIG. 2 is a block diagram illustrating an embodiment of the present invention.

FIG. 3 is a diagram illustrating a relay operation according to an embodiment of the present invention.

FIG. 4 is a block diagram illustrating a conventional example.

FIG. 5 is a diagram for explaining delay of relay time in a conventional example.

[Explanation of symbols]

 100, 100A Relay station 110 Reception unit 111, 111a, 111b Carrier detection unit 112, 112a, 112b Data reception unit 113 Reception power supply control unit 114 Hybrid circuit 120 Transmission unit 121, 121a, 121b Data transmission unit 122 Transmission power supply control unit 123 Antenna Connection unit 124 Antenna connection control unit 130 Relay processing unit 131 Branch / coupling unit 132 Modulation / demodulation unit R, Ra, Rb Termination resistance A Antenna 200 Master station 210, 310 Radio equipment 301 to 30n Slave station

Claims (3)

[Claims] 1. A method for shortening the relay processing time of a relay station (100) for relaying data between a master station and a slave station, the method comprising: a carrier detecting section (111) and a data receiving section (112).
And a reception unit (11) including a reception power control unit (113)
0), a data transmission unit (121) for converting a received signal into a radio signal having a different frequency and transmitting the radio signal, a transmission unit (120) including a transmission power supply control unit (122), the reception unit (110) and In the relay station (100) including a relay processing unit (130) that controls the transmission unit (120), the output of the data transmission unit (121) is switched and connected to an antenna (A) and a terminating resistor (R). Antenna connection (1
23) and an antenna connection control unit (124) that outputs a signal for controlling the connection of the antenna connection unit (123), and the relay processing unit (130) performs the relay operation from the output of the carrier detection unit (111). When it is determined that the data transmission unit (122) is turned on, the power supply of the data transmission unit (121) is turned “on”, and the antenna connection unit (123) transmits the data when the data transmission unit is turned on. The output of (121) is supplied to the antenna (A), and when the data transmission is stopped, the output of the data transmitting unit (121) is connected to the terminating resistor (R), and the relay processing unit (130) relays it. A method for shortening the relay processing time of a relay station, characterized in that the power supply of the data transmission unit (121) is turned off when it is determined that the operation has ended. 2. The relay station (100) according to the preceding paragraph,
The power supply of the carrier detection unit (111) is always “on”, and when the relay processing unit (130) determines from the output of the carrier detection unit (111) that the relay operation is started, the reception power supply control is performed. The section (113) turns on the power supply of the data receiving section (112), and the relay processing section (13) starts from the output of the carrier detecting section (111).
The method for reducing the relay processing time of a relay station according to claim 1, wherein the power of the data receiving unit (112) is turned "OFF" when it is determined that the relay operation is finished (0). 3. A carrier detecting section (111), a data receiving section (112), a receiving section (110) including a reception power control section (113), and a received signal converted into a radio signal of a different frequency. A data transmission unit (121) for transmission,
Transmission unit (120) including transmission power control unit (122)
And a relay processing unit (130) for controlling the receiving unit (110) and the transmitting unit (120).
00), an antenna connection unit (1) for switching and connecting the output of the data transmission unit (121) to the antenna (A) and the terminating resistor (R).
23) and an antenna connection control unit (124) that outputs a signal for controlling the connection of the antenna connection unit (123), and the relay processing unit (130) relays from the output of the carrier detection unit (111). When it is determined that the operation is started, the reception power control unit (113) and the transmission power control unit (1
22) turns on the power sources of the data receiving unit (112) and the data transmitting unit (121), and outputs the data of the data transmitting unit (121) by the antenna connecting unit (123) when transmitting data. When the data transmission to the antenna (A) is stopped and the data transmission is stopped, the data transmission unit (1
When the output of 21) is connected to the terminating resistor (R) and the relay processing unit (130) determines that the relay operation has ended,
The data receiving unit (112) and the data transmitting unit (12
A relay station characterized by turning off the power supply of 1).