JPH02193420A - Regenerative repeater - Google Patents

Abstract

PURPOSE:To simplify the circuit constitution of each terminal station by inverting the polarity of data and sending it, inverting the polarity of the received data, and inverting the polarity of the received data by a repeating station with a control signal, etc., from a base station and repeating it when the base station is under control. CONSTITUTION:In control, the base station 10 switches a switch 15 to send a control signal by a signal sending circuit 14. The repeating station 20 receives the control signal and decodes it by a signal reception part 22, and then a switch 24 is switched to the side of an inverter 23. A signal sent from the terminal station 30 is inverted by the inverter 23 of the repeating station 20, so the signal is not regenerated by any other terminal station 30, but the signal is inverted again by the inverter 12b of the base station 10 to return to the original polarity, so the signal can be regenerated without any error. Therefore, the base station need not send the control signal, etc., periodically and the circuit constitution of each terminal station can be simplified.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a regenerative repeater that regenerates and relays digital signals.

BACKGROUND OF THE INVENTION FIG. 3 shows a conventional two-wave simplex relay type regenerative repeater.

In FIG. 3, 1 is a base station (BASE) that transmits a signal of frequency f1 and receives a signal of frequency f,
The base station l includes a signal transmission circuit (ENC) la for encoding control signals such as control signals. 2 is a relay station (REP) that reproduces and relays the digital signal, and the relay station 2 has a receiver (REP) that receives the signal of frequency f1.
X) 2a and a transmitter (TX) that transmits a signal at frequency f
) 2b.

3 are terminal stations that are mobile stations, and each terminal station 3 has a transceiver 3a that transmits a signal at a frequency f, receives a signal at a frequency f, and decodes a control signal such as a control signal. It includes a signal receiving section (DEC) 3b.

Next, the operation of the above conventional example will be explained.

In FIG. 3, when base station l and terminal station 3 transmit a signal with frequency f1, relay station 2 relays this signal as a signal with frequency f, so base station 1, terminal station 3, and terminal station 3
Comrades can communicate data with each other, but in times of control etc., communication between terminal stations 3 is disabled, and base station 1
It is necessary to enable communication only between the terminal station 3 and the terminal station 3.

In this case, the base station 1 sends out the control signal MUTE through the signal sending circuit 1a, the relay station 2 relays this control signal MUTE, and each terminal station 3 mutes when it detects this control signal MUTE from the signal receiving section 3bK. become a state. Next, the base station 1 transmits a signal to a specific terminal station 3 using the signal transmission circuit 1a.
This terminal station 3
communication between the base station 1 and this specific terminal station 3 is made possible.

Problems to be Solved by the Invention However, in the conventional regenerative repeater described above, when the terminal station 3, which is a mobile station, is located outside the service area of the relay station 2, such as in the corner of a building, when transmitting a control signal, etc., Since the base station 1 cannot receive control signals and the like, there is a problem in that the base station 1 must periodically send out the control signals and the like.

Furthermore, since each terminal station 3 includes a signal detection circuit 3b, there is a problem that the circuit scale becomes large.

In view of the above conventional problems, the present invention provides a regenerative repeater that eliminates the need for a base station to periodically send out control signals such as control signals, and that can simplify the circuit configuration of each terminal station. The purpose is to

Means for Solving the Problems In order to achieve the above object, the present invention inverts the polarity of data and transmits it when the base station is under control, and also inverts the polarity of received data so that the relay station can transmit data from the base station. The polarity of received data is inverted and relayed using a control signal or the like.

The present invention also provides that when the base station is in control, it superimposes a PN code on the data and transmits it, superimposes the received data, and the relay station adds the PN code to the received data using a control signal etc. from the base station.
The codes are superimposed and relayed.

According to the above-mentioned former invention, at the time of control, at the relay station,
The polarity of the data from the terminal station is reversed, making it impossible for other terminal stations to receive it, and the polarity of the received data is reversed at the base station and relay station, returning to the original polarity.
Only communication between the base station and the terminal station is possible.

Furthermore, according to the latter invention, the PN code is superimposed on the data from the terminal station at the relay station during control, so
Reception by other terminal stations becomes impossible, and since the PN code is superimposed on the received data at the base station and the relay station and the data returns to the original data, only communication between the base station and the terminal station becomes possible.

In this case, since the base station does not periodically send out control signals such as control signals, there is no need to provide each terminal station with a circuit for receiving control signals, etc., thus simplifying the circuit configuration of each terminal station. Can be done.

EXAMPLES Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing one embodiment of a regenerative repeater according to the present invention.

In FIG. 1, 10 transmits a signal of frequency 11,
A base station (BASE) receiving a signal of frequency fm, 20
is a relay station (REP) that reproduces and relays digital signals.
) and 30 are terminal stations that are mobile stations, and each terminal station 30 is equipped with a transceiver (TRX) 31 that transmits a signal with a frequency f1 and receives a signal with a frequency f.

In the base station 10, lla is an input terminal for transmission data, 12a is an inverter for inverting the transmission data from the input terminal 11a, and 13a is for selectively outputting the transmission data from the input terminal 11a or the inverter 12a. A switch 14 is a signal transmission circuit (ENC) for encoding a control signal such as a control signal, and 15 is a switch 13a.
Alternatively, the switch 16 for selectively outputting the transmission signal from the signal sending circuit 14 is a transmitter (TX) that transmits the transmission signal from the switch 15 as a wireless signal (frequency f,) via the antenna 17. be.

18 is a wireless signal (frequency f,) via the antenna 17
19 is a switch that switches the antenna 17 for transmission or reception; 12b is an inverter that inverts the received signal from the receiver 18; 13b is a
This is a switch for selectively outputting a received signal from the receiver 18 or the inverter 12b to the output terminal 11b.

In the relay station 20, 21 is a receiver (RX) that receives the signal of frequency f1, 22 is a signal receiving unit that decodes the signal received by the receiver 21, and 23 is the receiver 21.
and an inverter that inverts the signal from the signal receiving section 22;
24 is a switch that selectively outputs signals from the receiver 21 and the signal receiving unit 22 or the inverter 23; 25 is a
This is a transmitter (TX) that transmits the signal from the switch 25 as a wireless signal (frequency f).

Next, the operation of the above embodiment will be explained.

In FIG. 1, first, during normal communication, the switch 13
a, 13b, and 24 are respectively (7 barter 12a.

It is controlled to output a signal that does not go through 12b and 23.

In this case, the data transmitted from the base station 10 is not inverted, nor is it inverted at the relay station 20, so
When the base station 10 and the terminal station 30 transmit a signal of frequency f1, the relay station 20 relays this signal as a signal of frequency f, so that the base station 10, the terminal station 30, and the terminal stations 30 can communicate with each other. data can be communicated to.

On the other hand, during control control, the base station 10 switches the switch 15 to transmit a control signal by the signal sending circuit 14,
Next, switch 15 is returned to its original position, and switch 13 is
a, 13b are switched to the inverter 12a, 12b side, respectively. When the relay station 20 receives the control signal and decodes it using the signal receiving section 22, the relay station 20 switches the switch 24 to the inverter 23 side.

In this state, the signal transmitted from the terminal station 30 is inverted by the inverter 23 of the relay station 20, so it cannot be reproduced by other terminal stations 30, but it is inverted again by the inverter 12b at the base station 10. Since the polarity is returned to the original polarity, playback can be performed without error.

Similarly, a signal from the base station 10 to the terminal station 30 is first inverted by the inverter 12a of the base station 10, and then inverted by the inverter 23 of the relay station 20 to return to the original polarity, so that the signal is reproduced without error at the terminal station 30. can do.

Therefore, according to the above embodiment, during control control, the inverter 23 of the relay station 20 disables mutual communication between the terminal stations 3o, and the inverters 12a, 12 of the base station 1o
b and the inverter 23 of the relay station 20 enable only communication between the base station 10 and the terminal station 30.

In this case, since the terminal station 30 does not receive the control signal, the base station 10 does not need to periodically send out the control signal, and the signal receiving circuit as in the conventional example
It becomes unnecessary at 0.

In the above embodiment, the inverters 12a and 12b.

23 is configured to change the polarity of the signal, but instead, as shown in FIG. 3, an exclusive OR circuit 40 and
By superimposing a PN signal on data using a circuit that generates a PN signal, such as the M-sequence code generators 41 and 42,
During control, etc., communication between the terminal stations 3o can be disabled, or only communication between the base station 10 and the terminal station 3o can be enabled.

Here, the M-sequence code generator 41 shown in FIG. 2(a) is a non-self-synchronizing type circuit, and the M-sequence code generator 42 shown in FIG. 2(b) is a self-synchronizing type circuit. Generator 41.
42 both generate M-sequence codes using the generator polynomial expression %.

As described in detail, the present invention provides that when a base station is in control, it inverts the polarity of data and transmits it, and also inverts the polarity of received data so that the relay station receives the data using a control signal etc. from the base station. The polarity of the data is reversed and relayed, and when the base station is in control, it superimposes a PN code on the data and transmits it, superimposes the received data, and the relay station receives a control signal from the base station, etc. Since the PN code is superimposed on the received data and relayed, there is no need for the base station to periodically send control signals such as control signals, and the circuit configuration of each terminal station can be simplified. .

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing one embodiment of a regenerative repeater according to the present invention, FIG. 2 is a block diagram showing main parts of another embodiment of the regenerative repeater according to the present invention, and FIG. , is a block diagram showing a conventional regenerative repeater. 10-...Base station, 12a, 12b, 23*nharp, 13a, 13b, 15.19.24/CC
Notch 14...Signal transmission circuit (ENC), 16.2
5-...Transmitter (TX), 18゜21...Receiver (
RX), 22... Signal receiving circuit (DEC), 20
. . . relay station, 30 . . . terminal station, 40 . . . exclusive OR circuit, 41, 42 . . . M sequence code generator. Name of agent: Patent attorney Shigetaka Awano and one other person

Claims (2)

[Claims] (1) During control, a base station that inverts the polarity of data and transmits it, and a relay station that inverts the polarity of received data and relays it using a control control signal from the base station. A regenerative relay device with (2) At the time of control, the base station superimposes the PN code on the data and transmits it, and the base station superimposes the PN code on the received data.
A regenerative relay device having a relay station that superimposes and relays codes.