JP2002252587A - TDMA relay system - Google Patents

Abstract

(57) [Summary] (Modified) [Problem] In a TDMA digital radio system, TD
In MA (TDD) digital wireless systems, expand the area to blind zones. A relay station is provided, and a base station and a relay zone are provided.
In the TDMA (TDD) digital radio system, a relay station is provided for relaying with a base station, and the channel implemented in the base zone 6 is a base station carrier. By relaying to another carrier with a greater separation, or by using the carrier for the base station and changing the slot, and relaying, communication with terminal stations in the relay zone becomes possible.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a TDMA (Time Divis
The present invention relates to a relay of a digital wireless system by an ion multiple access method.

[0002]

2. Description of the Related Art A conventional relay system will be described with reference to FIGS. FIG. 5 is a diagram for explaining a conventional TDMA relay system. The TDMA digital mobile communication system is composed of a base station and a terminal station, and communication mainly includes a case where communication is performed between the base station and the terminal station and a case where communication is performed between the terminal station and the terminal station. One is to divide one wireless carrier into frames and divide the frames into slots corresponding to the number of multiplexes to form a multi-channel. Also,
When communication is performed between terminal stations, the base station is mainly used as a relay station. As a standard for such a communication system, for example, there is RCR STD-39. In FIGS. 5 and 10, the radio carrier has one frequency for each of uplink and downlink (multiplexing number: 4). The modulation method is π / 4 shift QPSK (Quadrature Phase Shift Keying).

[0003] A line control device 1 is connected to a base station 2 by a wired line, a microwave line, or the like. The base station 2 and the communication is capable zone (base zone) 6, the vehicle-mounted device, mobile device, Okugaiko station, the terminal station 3, such as door-to-door receiving device there is at least one. Further, since it is difficult to connect a line controller and a base station with a wired entrance line in a dead zone where radio waves transmitted from the base station 2 do not directly reach and in a mountainous zone or the like, another base station is used. In a place where a station cannot be set up, the relay station 4 is set up in a place near the place where communication is desired and farthest from the base station 2 in the base zone 6. A terminal station 5a and a terminal station 5b exist in a zone (relay zone) 7 where communication with the relay station 4 is possible. FIG. 10 is a diagram illustrating a connection example between the base station 2-the terminal station 3, the base station 2-the relay station 4-the terminal 5 a, and the base station 2-the relay station 4-the terminal 5 b. In FIG. 10, the time axis is taken in the horizontal direction, and the frame and each slot (slot 1, slot 2, slot 3, slot 4) constituting the frame are shown, and the base station 2, the terminal station 3, the relay An example of connection for each of the radio carriers used for the station 4 and the terminal stations 5a and 5b is shown.

In FIG. 5, a base station 2 and a terminal station 3
Transmission (up) carrier f1 and reception (down) carrier
Communicate using f2. For example, the base station 2 transmits on the carrier f1 using the slot 2 of the frame 1,
It receives this. This is represented in FIG.
The f1 carrier, from TX2 slot 2 of the frame 1, arrows, the f1 carrier of the terminal station 3, the connection RX2 to the slot 2 of the frame 1. Further, the terminal station 3 transmits on the carrier f2 using the slot 4 of the frame 1,
Receives slot 4. If this is represented in FIG. 10, the arrow indicates the connection from the TX2 of the slot 4 of the frame 1 of the f2 carrier of the terminal station 3 to the RX2 of the slot 4 of the frame 1 of the f2 carrier of the base station 2. As described above, two-way communication with the terminal station 3 in the base zone 6 becomes possible.

Next, in FIG. 5, the base station 2 and the terminal station 5a
Communicates via the relay station 4. At this time, the base station 2 and the relay station 4 perform communication using the transmission carrier f1 and the reception carrier f2, and the relay station 4 and the terminal station 5a communicate with each other.
Communication is performed using the transmission carrier f3 and the reception carrier f4. For example, the base station 2 transmits on the carrier f1 using the slot 1 of the frame 1, and the relay station 4 receives this. When this is represented in FIG. 10, the f1 carrier of the base station 2
From TX1 in slot 1 of the frame, as indicated by the arrow,
RX of slot 1 of frame 1 of f1 carrier of relay station 4
Connection to 1. Then, the relay station 4 replaces the signal of the carrier f1 received from the base station 2 with the carrier f3,
Transmission is performed using slot 1 of the next frame (frame 2), and slave station 5a receives this. If this is represented in FIG. 10, the slot 1 of the frame 2 of the f3 carrier of the relay station 4
As shown by the arrow, the connection of the f3 carrier of the terminal station 5a to the RX1 'of the slot 1 of the frame 2 is made from the TX1'. In response to the reception, the terminal station 5a transmits the next frame 3
The transmission is performed on the carrier f4 using the slot 1 and the relay station 4 receives the slot 1. This is shown in FIG. 10, from the TX1 'of the f4 carrier of the terminal station 5a in the slot 1 of the frame 3 to the RX1' of the f4 carrier of the relay station 4 in the slot 1 of the frame 3 as indicated by the arrow. Connection. And
The relay station 4 transfers the signal of the carrier f4 received from the terminal station 5a to the carrier f2 and transmits the signal using the slot 1 of the frame 4, and the base station 2 receives the signal. Figure 1
0, from the TX1 'of the slot 1 of the frame 4 of the f4 carrier of the terminal station 5a, as indicated by the arrow, the relay station 4
Is connected to RX1 'of slot 1 of frame 4.

[0006] Similarly, in FIG. 5, the base station 2 and the terminal station 5 b communicate via the relay station 4. At this time, the base station 2 and the relay station 4 perform communication using the transmission carrier f1 and the reception carrier f2, and the relay station 4 and the terminal station 5b use the transmission carrier f3 and the reception carrier f4. To communicate. For example, the base station 2 transmits on the carrier f1 using the slot 3 of the frame 1, and the relay station 4 receives this. When this is represented in FIG. 10, the connection of the f1 carrier of the base station 2 from the TX3 of the slot 3 of the frame 1 to the connection of the f1 carrier of the relay station 4 to the RX3 of the slot 3 of the frame 1 as indicated by the arrow. Become. Then, the relay station 4 transfers the signal of the carrier f1 received from the base station 2 to the carrier f3 and transmits the signal using the slot 3 of the next frame (frame 2), and the slave station 5b receives this. This is represented in FIG. 10, from the TX3 'of the f3 carrier of the relay station 4 in the slot 3 of the frame 2 to the RX3' of the f3 carrier of the terminal station 5b in the slot 3 of the frame 2 as indicated by the arrow. It is a connection. When responding to the reception, the terminal station 5b transmits on the carrier f4 using the slot 3 of the next frame (frame 3), and the relay station 4 receives this. Figure 1
Expressed in 0, the f4 carrier terminal station 5b, the TX3 'slot 3 of frame 3, as indicated by the arrow, the relay station 4
Is connected to RX3 'in slot 3 of frame 3. Then, the relay station 4 replaces the signal of the carrier f4 received from the terminal station 5b with the carrier f2, transmits the signal using the slot 3 of the frame 4, and the base station 2 receives the signal. Expressing this in Figure 10, the f2 carrier relay station 4, TX3 slot 3 of the frame 4 'from, as indicated by an arrow, the f2 carrier of the base station 2, the slot 3 of the frame 4 RX3' to Connection. As described above, two-way communication is possible between the terminal stations 5a and 5b in the relay zone 7 and the base station 2. In addition to the above connection examples, communication is possible if f1 or f2 is empty in each slot shown in FIG. The prior art shown here uses FDD (Frequency
This is a relay system in a wireless system that performs communication in the quency division duplex (TDM) system.
In a digital wireless system using the e Division Duplex method, there is no relay method.

[0007]

In the above-mentioned prior art,
When the transmission delay between the base station and the relay station and between the relay station and the terminal station in the relay zone is large, there is a disadvantage that the collision of the burst signal occurs and the receiving performance is deteriorated. In addition, the above-mentioned conventional technology is a relay system of a TDMA (FDD) system, and since there is no relay system in a TDMA (TDD) system, a dead zone where radio waves do not reach from a base station or a mountain zone For example, when it is difficult to connect the line control device and the base station via an entrance line such as a cable, there is a disadvantage that the communicable area is reduced. An object of the present invention is to provide a relay system in a TDMA (TDD) communication system by eliminating the above-mentioned drawbacks.

[0008]

In order to achieve the above object, a TDMA communication system according to the present invention uses a notification from a base station to transmit a signal to a base station in response to a notification from the base station in order to prevent reception performance from deteriorating. By performing control, collision of burst signals due to transmission delay in a wireless section is prevented. Also, the relay station notifies that the terminal station in the relay zone controls transmission timing to the relay station, thereby preventing burst signal collision due to transmission delay between the relay station and the terminal station in the relay zone.
Also, in a digital wireless system communicated by the TDD system, a relay system that prevents burst signal collision is used, and the carrier implemented in the base station zone is transferred to another carrier that is sufficiently separated from the base station carrier. It relays and enables communication with the blind zone. Still further, relaying the channel implemented in the base station zone with the carrier for the base station, and changing the slot of the channel implemented in the base station zone to another slot at the relay station for relaying. Thus, communication with the dead zone is enabled. When the transmission slot and the reception slot are asymmetrical within one frame, the carrier implemented in the base station zone is relayed to another carrier which is separated from the carrier for the base station by a sufficient distance. In this case, the relay station changes the slot of the channel implemented in the above to another slot and relays the same, thereby enabling communication with the dead zone.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the relay system according to the present invention will be described with reference to FIGS. FIG. 1 is a diagram for explaining an embodiment of the TDD TDMA relay system of the present invention.
6 shows the base station 2 to the terminal station 5 of the TDMA relay system shown in FIG.
FIG. 6 is a diagram for explaining an embodiment of connection between a and a base station 2 to a terminal 5b and transmission / reception timing. This embodiment is a diagram for explaining an embodiment of a relay system that prevents deterioration of reception performance. In FIGS. 1 and 6, the radio carrier has one frequency for each of uplink and downlink (the number of multiplexing: 4). The modulation method is π / 4 shift QPSK (Quadrature Phase Shift Keyin
g). The number of multiplexes is four.

The configuration of FIG. 1 is the same as that of FIG. 5 described above, and the basic connection is the same as that of FIG. In Figure 1, for example, the base station 2 and the terminal station 3, and a base station second communication have been performed between the relay station 4, the transmission of the relay station 4 slot 1 (TX1), the transmission of the terminal station 3 It is assumed that the operation is performed in slot 2 (TX2). In this case, the propagation delay of the transmitted signal from the relay station 4 received at the base station 2 is received n times delayed from the reference timing with the base station 2 (in FIG. 6) (in FIG. 6). At this time, the transmission signal (TX2) from the terminal station 3 and the transmission signal (TX1) from the relay station 4 received by the base station 2 are n as shown in FIG.
The reception is repeated for a certain amount of time, which causes deterioration of the reception performance. Therefore, the base station 2 calculates a delay time n from the reference timing, notifies the calculated delay time n to the relay station 4, and advances the transmission timing to the relay station 4 by n hours. The relay station 4 receives the notification and advances the transmission timing, so that the reception timing at the base station 2 returns to the reference timing and normal reception is possible.

Similarly, in the relay zone 7, for example,
RS 4 and the terminal station 5a, and the relay station 4 and communication between the terminal station 5b has been performed, the transmission of the terminal station 5a slot 2 (T
X2), assume that the transmission of the terminal station 5b is performed in the slot 1 (TX1). At this time, due to the propagation delay of the transmission signal from the terminal station 5b received by the relay station 4, the signal is received n hours later than the reference timing (FIG. 6) of the relay station 4 (FIG. 6). Therefore, the transmission signal (Tx1) from the terminal station 5b and the transmission signal (TX2) from the terminal station 5a received by the relay station 4
Is received for n hours as shown in FIG. 6, which causes deterioration of the reception performance. Therefore, the relay station 4 calculates the propagation delay time n ', notifies the terminal station 5b of the calculated propagation delay time n', and advances the transmission timing by n 'time. The terminal station 5b receives the notification and advances the transmission timing by n 'time, so that the reception timing at the relay station 4 returns to the reference timing, and normal reception is enabled.

Next, another embodiment of the present invention will be described with reference to FIGS. FIG. 2 is a diagram for explaining an embodiment of the TDD TDMA relay system of the present invention. FIG.
FIG. 4 is a diagram showing an example of connection between base station 2 and terminal station 3 and between base station 2 and relay station 4 and terminal station 5 and an example of transmission and reception timing. In FIG. 7, the time axis is taken in the horizontal direction, and the frame and each slot (slot 1, slot 2, slot 3, slot 4) constituting the frame are shown, and the base station 2, the terminal station 3, the relay station 4 shows an embodiment of a connection example and reception timing of each radio carrier used for the terminal station 5. This embodiment is an embodiment of a carrier switching relay system in a TDD communication system. In the following description of the embodiment, it is assumed that the transmission timing control described with reference to FIGS. 1 and 6 is performed to prevent burst signal collision. In FIGS. 2 and 7,
The radio carrier uses the same one frequency (multiplex number: 4) for both uplink and downlink, but the radio carrier used in the base zone 6 and the radio carrier used in the relay zone 7 have the frequency f1 (base zone), respectively. 6) Use different frequencies of f2 (relay zone 7). The modulation method is
π / 4 shift QPSK (Quadrature Phase Shift Keying).

In FIG. 2, a line controller 1 connects to a base station 2. Zone where communication with the base station 2 is possible, that is,
In the base zone 6, there is at least one terminal station 3 such as an in-vehicle device, a portable device, an outdoor slave station, and a door-to-door receiving device. Also,
The relay station 4 is installed in a dead zone where radio waves from the base station 2 do not reach, near a place where communication is desired, and in a place farthest from the base station 2 in the base zone 6. The terminal station 5 exists in a zone in which communication with the relay station 4 is possible, that is, in the relay zone 7. The dead zone is, for example, a mountainous zone or the like, and is a place where it is particularly difficult to connect the line control device and the base station with an entrance line such as a cable.

The base station 2 is a carrier for transmission and a carrier for reception.
The communication with the terminal station 3 is performed using f1. For example, the base station 2 transmits (TX2) using slot 2 and the terminal station 3 receives (RX2). When this is represented in FIG. 7, the connection is made from TX2 of slot 2 of frame 1 of base station 2 to RX2 of slot 2 of frame 1 of terminal station 3, as indicated by the arrow. When transmitting from the terminal station 3, the terminal station 3 transmits (TX2) using slot 4 and the base station 2 receives (RX2). When this is represented in FIG. 7, the connection is made from TX2 of slot 4 of frame 1 of terminal station 3 to RX2 of slot 4 of frame 1 of base station 2 as indicated by an arrow. By doing the same in the following, bidirectional communication between the base station 2 and the terminal station 3 in the base zone 6 becomes possible. When communicating with the terminal station 5 in the relay zone 7, the communication is performed with the relay station 4 using the transmission / reception carrier f1, and the carrier is switched to the carrier f2 at the relay station.
Communication is performed with the terminal station 5 at f2. For example, base station 2 transmits (TX1) using slot 1 and relay station 4 receives it (RX1), and uses slot 3 to transmit (TX1 ') on carrier f2. The terminal station 5 receives this (RX1 ').
When this is represented in FIG. 7, the connection is made from TX1 'of slot 3 of frame 1 of the f2 carrier of relay station 4 to RX1' of slot 3 of frame 1 of terminal station 5, as indicated by the arrow. When transmitting from the terminal station side to the base station side in response to the reception, the terminal station 5 transmits (TX1 ') on the carrier f2 using the slot 1 of the next frame (frame 2). The relay station 4 receives this (RX1 '), and transmits (TX1) to the base station 2 on the carrier f1 using the next slot 3.
In FIG. 7, the connection is made from TX1 'of slot 1 of frame 2 of the f2 carrier of terminal station 5 to RX1' of slot 1 of frame 2 of relay station 4, as indicated by the arrow, and further relayed. The connection from TX1 in slot 3 of frame 2 of the f1 carrier of station 4 to RX1 in slot 3 of frame 2 of base station 2 as indicated by the arrow. By doing the same in the following, two-way communication between the base station and the terminal station 5 in the relay zone 7 becomes possible. In addition, other than the above connection example, when it is necessary to start communication from a terminal station,
In each slot shown in FIG. 7, if f1 or f2 is free, communication is possible.

Next, another embodiment of the present invention will be described with reference to FIGS. FIG. 3 is a diagram for explaining one embodiment of the TDD TDMA relay system of the present invention. FIG.
FIG. 4 is a diagram showing an example of connection between base station 2 and terminal station 3 and between base station 2 and relay station 4 and terminal station 5 and an example of transmission and reception timing. This embodiment is an embodiment of a slot transfer relay system in a TDD communication system. still,
In the following description of the embodiment, it is assumed that the transmission timing control described with reference to FIGS. 1 and 6 is performed to prevent burst signal collision. In FIGS. 3 and 8, it is assumed that the radio carrier uses the same one frequency (the number of multiplexes: 4) for both uplink and downlink. The modulation method is π / 4 shift QPSK (Qu
adraturePhase Shift Keying).

The line controller 1, base station 2, terminal station 3, relay station 4, terminal station 5 in relay zone, base zone 6,
The installation status and functions of the relay zone 7 are almost the same as those in FIG. In FIG.
The base station 2 communicates with the terminal station 3 using the transmission and reception carriers f1. For example, from base station 2 slot 2
(TX2), and the terminal station 3 receives it (RX2).
I do. When this is represented in FIG. 8, the connection is made from TX2 of slot 2 of frame 1 of base station 2 to RX2 of slot 2 of frame 1 of terminal station 3, as indicated by the arrow. When transmitting from the terminal station side, the terminal station 3 transmits (TX2) using slot 4 and the base station 2 receives (RX2). When this is represented in FIG. 8, the connection is made from TX2 of slot 4 of frame 1 of terminal station 3 to RX2 of slot 4 of frame 1 of base station 2 as indicated by an arrow. Hereinafter, by performing the same operation, bidirectional communication with the terminal station 3 in the base zone 6 becomes possible. In addition, the terminal station 5 in the relay zone 7
When communicating with the base station 2, the base station 2 uses the slot 1 to transmit (TX1) on the carrier f1 and the relay station 4 receives it (RX1).
1) Yes. If this is represented in FIG. 8, the frame 1 of the base station 2
From TX1 in slot 1 of the relay station 4 as indicated by the arrow.
Is connected to RX1 of slot 1 of frame 1. Since the relay station communicates with the terminal station 5 on the same carrier f1,
Submit instead placed in slot 4 of frame 1 (TX1 ') to. When this is represented in FIG. 8, the connection is made from TX1 'of slot 4 of frame 1 of relay station 4 to RX1' of slot 4 of frame 1 of terminal station 5, as indicated by the arrow. When this is received (RX1 ') and transmitted from the terminal station side, the terminal station 5 sends the next frame (frame 2) slot 2
(TX1 '). This is represented in FIG. 8, from the TX1 ′ of the slot 2 of the frame 2 of the terminal station 5 to the RX of the slot 2 of the frame 2 of the relay station 4 as indicated by the arrow.
This is received (RX1 ') by the relay station 4 which is connected to 1',
The transmission is transmitted (TX1) to the base station 2 by changing to the slot 3 of the next frame (frame 3). The base station 2 receives this (slot 3 of frame 3: RX1). Expressing this in FIG. 8, TX1 slot 3 of frame 3 of the relay station 4
Thus, as indicated by the arrow, the connection is made to RX1 of slot 3 of frame 3 of base station 2. Hereinafter, by performing the same operation, the base station 2 can perform bidirectional communication with the terminal station 5 in the relay zone 7. In addition, in cases other than the connection example described above, such as when it is necessary to start communication from a terminal station, communication is possible if each slot shown in FIG. 8 is vacant.

Next, another embodiment of the present invention will be described with reference to FIGS. Figure 4 is a diagram for explaining an example of a TDMA trunking the TDD system of the present invention. The installation conditions and functions of the line control device 1, the base station 2, the terminal station 3, the relay station 4, the terminal station 5 in the relay zone, the base zone 6, and the relay zone 7 in FIG. 4 are substantially the same as those in FIG. since, the description thereof is omitted. FIG. 9 is a diagram showing an example of a connection example between the base station 2 and the terminal station 3 and between the base station 2 and the relay station 4 and the terminal station 5 and an example of transmission and reception timing. In this embodiment, the TD
Is an example of a carrier resynchronization relay scheme in a communication system of the D type, whereas the embodiment of FIG. 2 is directed to the allocation of transmission and reception slots, asymmetric, i.e.,
FIG. 4 shows an example of a relay system when the transmission slot and the reception slot are asymmetric in one frame. In the following description, performs transmission timing control described in FIGS. 1 and 6, it is assumed that prevents collision of the burst signal. In FIGS. 4 and 9, the radio carrier is uplink /
Downlink with the same first frequency (the number of multiplexed: 4) but use a wireless carrier to be used in the wireless carrier and the relay zone 7 for use in the base zone 6, respectively frequency f1 (the base zone 6), f2 (relay Use different frequencies in zone 7). The modulation method is π / 4 shift QPSK (Quadrature
Phase Shift Keying).

In FIG. 4, the number of transmission / reception slots in one frame is (transmission 3: reception 1) or (transmission 1: reception 3)
It is. The line controller 1, the base station 2, the terminal station 3, the relay station 4, the terminal station 5 in the relay zone, the base zone 6, and the relay zone 7 are the same as those in FIG. First, FIGS. 4 and 9 show an embodiment in which the number of transmission / reception slots in one frame is (transmission 3: reception 1).
This will be described with reference to (a). The base station 2 communicates using the carrier f1 for transmission and reception, transfers the carrier to f2 at the relay station, and communicates with the terminal station 5 using the carrier f2 for transmission and reception. For example, in the base station 2, slot 1 is a reception slot (RX1), and slots 2, 3, and 4 are transmission slots (TX1, TX2, and TX3). The base station 2 transmits (TX2) using slot 3 and the relay station 4 receives (RX2). As shown in FIG. 9A, the connection is made from TX2 of slot 3 of frame 1 of base station 2 to RX2 of slot 3 of frame 1 of relay station 4 as indicated by the arrow. Then, the relay station 4, the next frame (frame 2)
Is transmitted (TX2 ') on carrier f2 using slot 1 of. The terminal station 5 receives this (RX2 '). This is shown in FIG.
Expressing in (a), the TX of the slot 1 of the frame 2 of the relay station 4
From 2 ', as indicated by the arrow, the connection is made to RX2' of slot 1 of frame 2 of terminal station 5. Next, when transmitting from the terminal station side, the terminal station 5 transmits (TX1 ') on the carrier f2 using the slot 3 of the frame 2, and receives it (RX1') on the relay station 4. If this is represented in FIG. 9A, from TX1 ′ of slot 3 of frame 2 of terminal station 5,
As indicated by the arrow, slot 3 of frame 2 of relay station 4
Connection to RX1 '. The relay station 4 transmits (TX1) to the base station 2 on the carrier f1 using the slot 1 of the next frame (frame 3). When this is represented in FIG. 9 (a), as indicated by the arrow, from the TX1 of the slot 1 of the frame 3 of the relay station 4, the
Connects to RX1. Hereinafter, by performing in the same manner, the base station 2, bidirectional communication can be performed with the terminal station 5 in the relay zone 7. In addition, in cases other than the connection example described above, such as when it is necessary to start communication from the terminal station, communication is possible if each slot and the wireless carriers f1 and f2 shown in FIG. 9A are free.

Similarly, FIG. 4 shows an embodiment in which the number of transmission / reception slots in one frame is (transmission 1: reception 3).
This will be described with reference to FIG. In this case, for example, in base station 2, slot 1 is a transmission slot (TX1),
Slots 2, 3, and 4 are receive slots (RX1, RX2, RX3)
And Transmission from base station 2 using slot 1 (TX1)
And, receiving it at the relay station 4 (RX1). This is shown in FIG.
In this case, the connection from TX1 of slot 1 of frame 1 of base station 2 to RX1 of slot 1 of frame 1 of relay station 2 as indicated by the arrow. Then, the relay station 4 transmits (TX1 ') on the carrier f2 using the slot 3, and the terminal station 5 receives (RX1'). When this is represented in FIG. 9B, from TX1 'of slot 3 of frame 1 of relay station 4,
As indicated by the arrow, slot 3 of frame 1 of terminal station 5
Connection to RX1 '. In response to this, when transmitting from the terminal station side, the terminal station 5 transmits on the carrier f2 using the slot 1 of the next frame (frame 2) (TX
2 '). The relay station 4 receives this (RX2 '). When this is represented in FIG. 9B, the connection is made from TX2 'of slot 1 of frame 2 of terminal station 5 to RX1' of slot 1 of frame 2 of relay station 4 as indicated by the arrow. Then, the relay station 4 transmits (TX2) to the base station 2 on the carrier f1 using the slot 3. When this is represented in FIG. 9B, the connection is made from TX2 of slot 3 of frame 2 of relay station 4 to RX2 of slot 3 of frame 2 of base station 2 as indicated by the arrow. Hereinafter, by performing the same operation, the base station 2
, And the terminal station 5 in the relay zone 7. In addition, in cases other than the connection example described above, such as when it is necessary to start communication from the terminal station, communication is possible if each slot and the wireless carriers f1 and f2 shown in FIG. 9B are free.

In the above embodiment, the modulation method is π / 4 shift QP
Although SK is used, it is obvious that any method such as 16QAM modulation may be used.

[0021]

According to the present invention, it is possible to provide a relay system in a TDMA digital radio system in which collision of burst signals due to transmission delay in a radio section is prevented and deterioration of reception performance is prevented. In a digital wireless system that performs communication using the TDMA (TDD) method, the line controller and the base station are connected by a wired entrance line in a dead zone where radio waves do not reach from the base station or in a mountainous zone. It is possible to communicate even in a place where it is difficult to perform, and it is possible to extend the area.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining an embodiment of a TDMA relay system of the present invention.

FIG. 2 is a diagram for explaining an embodiment of the TDMA relay system of the present invention.

FIG. 3 is a diagram for explaining an embodiment of the TDMA relay system of the present invention.

FIG. 4 is a diagram for explaining an embodiment of the TDMA relay system of the present invention.

FIG. 5 is a diagram for explaining a conventional TDMA relay system.

FIG. 6 is a diagram for explaining an embodiment of connection and transmission / reception timing of the TDMA relay system of the present invention.

FIG. 7 is a diagram for explaining one embodiment of connection and transmission / reception timing of the TDMA relay system of the present invention.

FIG. 8 is a diagram for explaining one embodiment of connection and transmission / reception timing of the TDMA relay system of the present invention.

Figure 9 is a diagram for explaining an embodiment of a connection and transmission and reception timings of the TDMA relay system of the present invention.

FIG. 10 is a diagram for explaining an example of connection and transmission / reception timing of a conventional TDMA relay system.

[Explanation of symbols]

1: Line control device, 2: Base station, 3: Terminal station in base zone, 4: Relay station, 5, 5a, 5b: Terminal station in relay zone, 6: Base zone, 7: Relay zone.

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5K028 AA01 AA11 BB06 CC02 DD01 DD02 DD04 HH00 KK12 LL12 RR02 5K067 AA22 CC04 DD25 EE02 EE06 EE10 EE16 EE61 EE71 HH21 5K072 AA29 BB25 BB27 CC15

Claims (9)

[Claims] 1. A TDM having a base station and a plurality of terminal stations.
In a digital wireless system based on the A (Time Division Multiple Access) method, a relay station for communicating with a terminal station located in a dead zone of the base station is provided, and one of the terminal stations located in the dead zone and the base station, A TDMA relay method for performing communication by a TDD (Time Division Duplex) method via a relay station. 2. The TDMA relay system according to claim 1, wherein a radio carrier used in the base station and a radio carrier used in the dead zone are radio carriers having different frequencies. . 3. The TDMA relay system according to claim 1, wherein a slot used between the base station and the relay station is different from a slot used between the relay station and a terminal station located in the dead zone. A TDMA relay system in which one of the terminal stations in the dead zone communicates with the base station by switching to a slot. 4. The TDMA relay system according to claim 3, wherein a wireless carrier used in said base station and a wireless carrier used in said blind zone are the same wireless carrier. 5. The TDMA relay system according to claim 1, wherein the number of transmission slots and reception slots constituting one frame are different. 6. The TDMA relay method according to any one of claims 1 to 5, TDMA to the relay station by notification from the base station and performs transmission timing control to the base station
Relay method. 7. The TDMA relay scheme according to claim 6, wherein the base station calculates the delay time from the reference timing with the said base station of the transmission signal received from said relay station,
Notifying the calculated delay time to the relay station, wherein the relay station controls transmission timing to the base station by advancing transmission timing by the notified delay time. TDMA relay system. 8. The TDMA relay system according to claim 6, wherein a terminal station in the dead zone controls transmission timing to the relay station in response to a notification from the relay station. A TDMA relay system characterized by the above-mentioned. 9. The TDMA relay system according to claim 6, wherein the relay station calculates a propagation delay time of a transmission signal transmitted from a terminal station in the dead zone. Notifying the calculated delay time to a terminal station in the dead zone, the terminal station in the dead zone advances the transmission timing by the notified delay time so that the terminal station in the dead zone relays the relay time. A TDMA relay system for controlling transmission timing to a station.