JP3266342B2 - Wireless relay method and wireless relay device using the method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for relaying radio signals in a radio section in a mobile communication system.

[0002]

2. Description of the Related Art As a countermeasure against a radio wave insensitive area such as a tunnel in a car telephone or the like, a method using a repeater using a common amplifier has conventionally been adopted.

FIG. 9 is a diagram showing the configuration of such a conventional relay system, in which 900 is a repeater, 901 is a base station, 902 and 904 are antennas, 903 and 906 are amplifiers, 905 is a mobile station, Reference numeral 907 denotes a tunnel.

In FIG. 1, a repeater 900 is connected to a base station 9.
01 is received by the base station antenna 902,
Commonly amplified by the down-stream amplifier 903 and the antenna 9 for mobile station
At 04, the radio wave is re-emitted to the mobile station 905 in the tunnel. Conversely, the radio wave from the mobile station 905 in the tunnel is received by the antenna 904 for the mobile station, is commonly amplified by the uplink amplifier 906, and is amplified by the antenna for the mobile station. Base station 901 at base station 902
Mobile station 9 in the tunnel by re-radiating
05 and the base station 901.

[0005]

Since the conventional relay system as described above is a direct relay that re-radiates at the same frequency, the radio wave received by the base station antenna 902 and re-radiated by the mobile station antenna 904 is used. Although there is a loss of wraparound, the signal is received by the base station antenna 902. Therefore, if the gain from the antenna 902 for the base station to the antenna 904 for the mobile station is GdB and the loss of the wraparound is LdB, oscillation occurs if G> L.

Therefore, it is necessary to satisfy G 器 L in order to operate the repeater stably. If the antenna for mobile station is in a tunnel etc., the condition is good and L is 70-80 dB
G can be about 60 dB. However, if the antenna for the base station and the antenna for the mobile station are not cut off, the condition is bad, L may be about 40 to 60 dB, and G is only about 30 db. There was a problem that did not become.

The present invention has been made to solve such a conventional problem, and provides a relay system capable of increasing the gain of an amplifier even when the loop-back loss between both antennas of a relay device is small. It is intended to be.

[0008]

According to the present invention, the above-mentioned problems can be solved by the means described in the claims. That is, the invention described in claim 1 is:
And medium-splicing device receives a radio wave transmitted from the base station, after decoding, and stores the signal after No.該復, transmission time to which the transmission signal reception time and all slots of the base station and mobile station To avoid overlapping, after a certain period of time, transmit to the mobile station, while receiving the transmission radio wave from the mobile station,
After decoding, the decoded signal is stored and transmitted to the base station after a predetermined time so that the transmission time does not overlap with the reception time of the transmission radio wave from the base station and the mobile station in all slots. Communication between the base station and mobile station in a time-division
A radio relay method in a mobile communication system for signal, before
The relay device receives the control channel transmitted from the base station.
And extract TDMA timing from the control channel
Then, using the extracted timing of the TDMA,
A wireless relay method is characterized in that transmission timing of a relay device is created . The invention according to claim 2 is characterized in that:
In a mobile communication system in which a mobile station communicates in a time-division manner
A relay device, which transmits and receives radio waves to and from a base station.
A first antenna means for transmitting and receiving radio waves to and from a mobile station
The second antenna means, and the first antenna means
Of decoding a received radio signal from a base station
Decoding means, received by the second antenna means
A second decoding means for decoding a radio signal from the mobile station, before
Storing the signal decoded by the first decoding means,
A first delay means for, in said second decoding means
A second for storing and delaying the more decoded signal.
Delay means, and a signal decoded by the first decoding means
TDMA timing of base station from control channel included in
Timing extracting means for extracting timing, the timing
TDMA type of the base station extracted by the extracting means
And the first decryption means and the second decryption means.
Used by the relay device from the signal decoded by the stage
Timing creation means for creating TDMA timing
And the timing created by the timing creation means.
The signal stored in the second delay means is changed by using the
To transmit to the base station via the first antenna means
A first transmission means for creating a transmission radio wave to the Timing
Using the timing created by the
The signal stored in the first delay means is modulated, and
Radio wave transmitted to mobile station via antenna means 2
And a second transmission means for generating, the relay device
Receives the radio waves transmitted from the base station and the mobile stations
When transmitting the transmission radio waves to the mobile station and the base station.
The time is the reception time of the transmitted radio waves from the base station and mobile station and all
Each transmitting means so that they do not overlap in the slot of
A wireless relay device for relaying.

[0009]

According to the present invention, a relay apparatus decodes a signal transmitted by a base station, delays the signal for a predetermined time, and then transmits the signal to the mobile station at a time when the mobile station normally transmits. Similarly, in the relay device, the signal transmitted by the mobile station is received,
After decoding and delaying for a predetermined time, the data is transmitted to the base station at the time when the base station should transmit.

That is, conventionally, in a relay apparatus, a received signal is amplified and transmitted at the same time as receiving the signal. However, in the present invention, the transmission signal is prevented from overlapping with the reception time so that the transmission signal is not transmitted. The feature of the configuration is that it does not go around to the receiving side.

The operation of the present invention will be described below with reference to FIG. FIG. 1 shows one-channel TDD for ease of explanation.
Is taken as an example. In the figure, 101 is the timing of the base station, 102 is a transmission slot, and 103 is a reception slot.

Reference numeral 111 denotes a timing of the relay apparatus for the base station, 112 denotes a reception slot, and 113 denotes a transmission slot. Reference numeral 121 denotes a timing of the relay apparatus for the mobile station, 122 denotes a transmission slot, and 113 denotes a reception slot.

Reference numeral 131 denotes the timing of the mobile station.
2 indicates a reception slot, and 133 indicates a transmission slot. The downlink signal is relayed from the base station to the transmission slot 102.
Transmits a signal to the mobile station. This signal is received by the relay apparatus in the reception slot 112 and is transmitted to the mobile station by the transmission slot 122 after a certain time delay.

For relaying an uplink signal, a signal is transmitted from a mobile station to a base station in a transmission slot 133. This signal is received by the relay apparatus in the reception slot 123 and is transmitted to the base station through the transmission slot 113 after a predetermined time delay.

With the above operation, the base station and the mobile station can communicate via the relay device. In the relay device,
Since the reception slot 112 and the reception slot 123 overlap, the reception slot 112 receives a signal transmitted from the base station as a desired wave and a signal transmitted from the mobile station as an interference wave in the transmission slot 133.

However, since the antenna for the base station and the antenna for the mobile station are usually directional antennas and are installed so as not to interfere with each other, the signal received in the receiving slot 112 is a desired wave >> an interference wave. Therefore, no problem occurs. Similarly, receiving slots 123, 103 and 132
No problem occurs because the signal received at is also a desired wave >>> an interference wave.

[0017]

FIG. 2 is a block diagram showing an example of a device configuration for implementing the present invention.
1 is a duplexer for distributing transmission / reception radio waves, 202 is a downlink receiver, 203 is a downlink delay circuit, 204-1 and 204-2 are timing extraction circuits, 205 is a control unit, 206 is a downlink transmitter, and 207 is a duplexer. , 212 are antennas for mobile stations,
Reference numeral 208 denotes an upstream receiver, 209 denotes an upstream delay circuit, and 210 denotes an upstream transmitter.

FIG. 3 shows a frame configuration according to an embodiment of the present invention.
4 shows the timing of the control channel in the case of the continuous transmission of the embodiment, FIG. 5 shows the timing of the control channel in the case of the intermittent transmission of the embodiment, and FIG. 6 shows the timing of the communication channel of the embodiment.

FIG. 7 shows the timing of the mobile station, and FIG. 8 shows the relay timing of another embodiment of the present invention. Hereinafter, embodiments of the present invention will be described with reference to these drawings.

(1) FIG. 3 shows T in the case of the first embodiment.
The frame configuration of the DMA-TDD signal will be described (this embodiment shows a case of 4 channels and 8 slots). Reference numeral 301 denotes a frame configuration having one cycle, and the cycle is T. One frame is divided into two, transmission and reception, and each is T / 2. Reference numeral 302 denotes a transmission slot, which is further divided into four, and 302-n indicates the n-th slot.

In this specification, the transmission slot is shown on the positive side and the reception slot is shown on the negative side for convenience. Also, 3
Numeral 03 denotes a receiving slot, similar to 302, which is further divided into four, and 303-n indicates the n-th slot. Let t be the period of each of these slots. That is,
T / 2 = 4 × t.

(2) The operation of the embodiment will be described with reference to FIGS. The radio wave transmitted by the base station is received by the base station antenna 211 and input to the down receiver 202 by the duplexer 201. The signal decoded by the downlink receiver 202 is input to the downlink delay circuit 203 and also to the timing extraction circuit 204-1.

On the other hand, the signal delayed by four slots by the delay circuit 203 is modulated by the downlink transmitter 206 and
Is transmitted from the mobile station antenna 212 to the mobile station.

The radio wave transmitted by the mobile station is received by the mobile station antenna 212 and passes through the duplexer 207 to the uplink receiver 2.
08, and after decoding, it is delayed by 4 slots by the delay circuit 209, modulated by the uplink transmitter 210, and
After that, the signal is transmitted to the base station by the base station antenna 211.

The output of the downlink receiver 202 is input to the timing extraction circuit 204-1 and the control unit 205. The timing extraction circuit 204-1 outputs signals 403 and 40
4 and the timing extraction circuit 204-2 extracts the signals 405 and 406. The control unit 205 controls the output of the downlink receiver 202 and the signals 405 and 406-1 to 4.
408-1 to 408-4 and 409-1 from 06-4
To 409-4.

The numeral 401 in FIG. 4 indicates the timing of signals transmitted and received by the base station.
02 is a downlink control channel slot transmitted by the base station, and 407 is an uplink control channel slot corresponding to 402 and is a slot for receiving an uplink control channel from a mobile station. The base station constantly receives 407 slots.

(3) The operation of the timing extraction circuit and the control unit will be described. In this embodiment, the relay device is the TD of the base station.
By grasping the timing of the MA and operating in synchronization therewith, it is possible to predict the timing of transmission by the base station or mobile station. Therefore, even if radio waves are transmitted from these stations to the relay device, the relay device immediately transmits the signal. , Can be received, and relaying can be efficiently realized.

In order to grasp the TDMA timing of the base station, it is necessary to decode and decode the signal transmitted by the base station. However, the signal transmitted by the base station can be roughly classified into a control channel for performing call control and a voice. There are two types of communication channels for transmitting data. A method for extracting timing from these signals will be described below.

(4) A method for extracting the timing of the base station from the signal of the control channel or the communication channel will be described. Since a slot number (corresponding to "n" of 302-n in FIG. 3) is encoded in each signal of the control channel or the communication channel, it is decoded and a signal synchronized with the signal of the control channel or the communication channel is decoded. , The timing of the base station can be extracted.

However, since the base station and the mobile station stop transmitting radio waves when the communication of the communication channel ends, it is generally not possible for the relay apparatus to receive the signal of the communication channel and extract the timing. It is not preferable because certainty remains. Hereinafter, a case where the timing is extracted from the control channel will be described.

The timing extraction circuit 204-1 decodes the control channel signal 402 intermittently transmitted by the base station, and then decodes the control channel timing 40 of the base station.
3 and a slot clock 404 are created. These signals are input to the timing extraction circuit 204-2, where
RX timing 405 and TX timing 406-1 to
Create 406-4.

Next, RX timing 405, TX timings 406-1 to 406-4, and uplink receiver 208
And the decoded output of the downlink receiver 202 are input to the control unit 205. The control unit 205 determines the slot-on signals 408-1 to 408- of the downlink transmitter from these signals.
4, and the slot-on signal 409-1 of the uplink transmitter
409-4 is created.

(5) The operation timing of the relay device according to the embodiment of the present invention will be described with reference to FIGS. The RX timing 405 is the transmission timing of the base station when the level is H. Therefore, it is also the reception timing of the relay device and the transmission timing of the mobile station. In the relay device, the receiver is not limited to the control channel and the communication channel, and it is necessary to be able to immediately receive the radio wave if any.
2 and 208 are always on, there is no problem, but when the level of the RX timing 405 is H, the receivers 202 and 2
By turning on 08, the efficiency can be increased.

Also, TX timings 406-1 to 406
-4 is the reception timing of the base station when the level is H, and also the transmission timing of the relay device and the reception timing of the mobile station. That is, the TX timing 406
-N is the transmission timing of slot n. In the relay apparatus, when the level of TX timing 406-n is H and there is a signal to be relayed, slot n of transmitter 206 or transmitter 210 is turned on.

Since the delay circuit needs to delay all the signals in the slots 1 to 4, the power supply is always turned on.

(6) The operation of the control channel will be described. In the embodiment shown in FIG. 4, the base station transmits continuously every slot, and FIG. 5 shows the case where transmission is performed every slot. Although the second slot is used for the position of the slot, any one of 1 to 4 may be used.

The control channel needs to relay a single signal. In the following, the way of relaying will be described with two examples.

(7) The timing of turning on the transmitter in the case of FIG. 4 will be described. FIG. 4 shows a case where the base station is continuously transmitting a signal of the control channel. The control unit 205 uses the signal from the downlink receiver 202 and the signal from the uplink receiver 208 to turn on the slot of the downlink transmitter. Signal 408-
By turning on the slot-on signal 409-2 of the uplink transmitter 2 and the uplink transmitter as shown in FIG. 4 or FIG. 5, the relay apparatus can relay the signals of the uplink and downlink control channels.

(8) The timing for turning on the transmitter in the case of FIG. 5 will be described. FIG. 5 shows a case where the base station is transmitting the control channel signal 501 intermittently, and the downlink control channel signal is transmitted every other frame (502-1 and 502-1).
-3). Since the relay device needs to relay the signal of the second slot, 502-1 and 502-1
H is the slot of 508-2-1 and 508-2-3 corresponding to -3.

Reference numeral 510 denotes a signal transmitted by the mobile station, and reference numeral 511 denotes a slot in which the mobile station can transmit. Here, only 511-2 is transmitted. Since the relay apparatus needs to relay the signal of the second slot, the slot of 509-2-2 corresponding to 511-2 is set to H. As described above, the relay device can delay the received control channel signal and relay the control channel signal to turn on the transmitter.

(9) The details of the timing of the communication channel according to the embodiment of the present invention will be described with reference to FIG. FIG. 6 shows the operation timing of a communication channel for transmitting a signal such as voice, and the base station is now performing communication with the mobile station using the first slot. Here, 601 indicates the timing of the base station, 602 indicates the transmission slot of the communication channel, and 603 indicates the reception slot of the communication channel.

Reference numeral 611 denotes the timing of the relay apparatus for the base station, 612 denotes a reception slot, 613 denotes a transmission slot, and the signal of 602 transmitted by the base station is
The signal 613 received by the relay apparatus and transmitted by the relay apparatus is received by the base station 603, and the base station and the relay apparatus can communicate with each other.

Reference numeral 621 denotes a timing of the relay device for the mobile station, 622 denotes a transmission slot, and 623 denotes a reception slot. 631 is the timing of the mobile station,
632 is a reception slot, 633 is a transmission slot,
The 633 signal transmitted by the mobile station is received at 623,
The signal 622 transmitted by the relay device is received by the base station 632, and the mobile station and the relay device can communicate with each other.

In the above relay apparatus, the signal received at 612 is a signal of a specified time, here, after a delay of 4 slots, 622
Similarly, the signal received at 623 is transmitted at 613 after a specified time delay.

At the above timing, the base station, the relay device, and the mobile station operate, and the relay device can relay the signal of the communication channel.

(10) Transmission of a communication channel will be described. The relay device can receive all radio waves transmitted by the relaying base station. Therefore, when a mobile station exists in an area other than the area to be relayed by the relay apparatus and the mobile station and the base station are communicating with each other via the communication channel, the relay apparatus transmits the downstream receiver, the delay circuit, and the transmitter. When the switch is turned on, the radio wave is relayed even if the mobile station does not exist in the area targeted by the relay device.

Therefore, according to the present invention, when the relay apparatus can receive the radio wave of the uplink communication channel from the mobile station and can receive the downlink communication channel of the same channel, the uplink transmitter and the downlink transmission By turning on the device, the relay device can efficiently relay radio waves only to mobile stations in the area to be relayed.

(11) A case of a frame configuration different from that of the present embodiment will be described. In the embodiment described above, 4CH T
In the frame configuration of DMA-TDD, from the viewpoint of the mobile station,
The timing is shown in FIG. That is, FIG.
In the case where t1 = t2 = T / 8 t3 = t4 = 3 × t1, the frame configuration is the same as that of a digital cordless telephone called PHS in Japan, and the same system can be applied.

In the present invention, t1, t2, t
3, t4 may be any value of 0 or more. For example, if t1 = t2 = t3 = T / 3 t4 = 0, it is a 3CH3 slot TDMA, which has the same frame structure as the digital car telephone system called JDC in Japan, and t1 = t2 = T / 8 t3 = If t1 × 2 t4 = t1 × 4, the 8-slot TDMA is the case of the European unified car telephone system called GSM, and the present invention can be applied to these two examples.

Hereinafter, the case of the PDC system will be described as another embodiment.

(12) Another embodiment will be described. This embodiment is basically the same as the previous embodiment except that t1 = t2
= T4 = T / 3 and t3 = 0, so that the previous embodiments can be applied. The relay timing will be described with reference to FIG.

In the figure, reference numeral 801 denotes the timing of the base station, 802 denotes a transmission slot, 803 denotes a reception slot, and 804 denotes an empty slot. Reference numeral 811 denotes the timing of the relay apparatus for the base station, 812 denotes a reception slot, 813 denotes a transmission slot, and 814 denotes an empty slot. The signal of the transmission slot 802 transmitted by the base station is received by the reception slot 812, Are transmitted in the reception slot 803.

Reference numeral 821 denotes the timing of the repeater for the mobile station, 822 indicates a transmission slot, 823 indicates a reception slot, and 824 indicates an empty slot. 831 is the timing of the mobile station, 832 is the reception slot, 833
Is a transmission slot, and 834 is an empty slot. The signal of 833 transmitted by the mobile station is received at 823, the signal of 822 transmitted by the relay apparatus is received at 832 of the mobile station, and the mobile station and the relay apparatus communicate. it can.

In this embodiment, the receiving slot 812
Is delayed by one slot, and the transmission slot 82
2 and the signal received in the receiving slot 823 is 2
The data is transmitted in the transmission slot 813 with a slot delay.

As described above, the base station, the relay device, and the mobile station operate at the timing shown in FIG. 8, and the relay device can relay the signal of the communication channel.

[0056]

As described above, according to the present invention,
After the received signal is decoded by the relay device, the signal is transmitted after a certain time delay, so that even if the coupling amount between the antennas is somewhat large, the radio wave can be amplified without any oscillation. There is an advantage that it can be applied to places where the amount of binding is large.

[0057]

Further, in the embodiment , the delay time is T / 2,
That is, the case of 1/2 the TDMA cycle is taken as an example.
As described above, in this case, in the relay device, the transmission time and the reception time do not completely overlap in all slots. That is, since the reception time is not transmitted, there is an advantage that sensitivity suppression does not occur at all.

It should be noted that the present invention can be applied to all TDD schemes having one or more channels.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating the operation of the present invention.

FIG. 2 is a block diagram showing an example of an apparatus for implementing the present invention.

FIG. 3 is a diagram illustrating a frame configuration according to an embodiment of the present invention.

FIG. 4 is a diagram illustrating the timing of a control channel in the case of continuous transmission.

FIG. 5 is a diagram illustrating control channel timing in the case of intermittent transmission.

FIG. 6 is a diagram showing timing of a communication channel.

FIG. 7 is a diagram illustrating timing of a mobile station.

FIG. 8 is a diagram showing a relay timing according to another embodiment of the present invention.

FIG. 9 is a diagram showing a configuration of a conventional relay system.

[Explanation of symbols]

101,601,801 Base station timing 102,113,122,133,302,613,6
22, 633, 802, 815, 822, 833 Transmission slots 103, 112, 123 , 132, 303, 612, 6
23, 632, 803, 812, 823, 832 Receiving slot 111, 811 Timing of repeater for base station 121 Timing of repeater for mobile station 131, 631, 831 Timing of mobile station 201, 207 Duplexer 202, 208 Receivers 203, 209 Delay circuits 204-1 and 204-2 Timing extraction circuits 205 Control units 206 and 210 Transmitters 211 and 212 Antenna 301 Configuration of one cycle frame 401 Timing of signals transmitted and received by base station 402, 407 and 508 −2-1, 508-2-3, 5
09-2-2 Control channel slots 403 to 405, 406-1 to 409-4 Signals 501, 502-1 to 502-4 Signals of base station control channel 510 Signals transmitted by mobile station 511-1 to 511- 4 Slot in which mobile station can transmit 602 Transmission slot of communication channel 603 Receiving slot of communication channel 611 Timing of relay device for base station 621, 821 Timing of relay device for mobile station 804, 814, 824 Free slot

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-63-299529 (JP, A) JP-A-6-140970 (JP, A) JP-A-5-259956 (JP, A) JP-A-4-1992 324794 (JP, A) (58) Fields studied (Int. Cl. ⁷ , DB name) H04B ^7/ 24-7/26 H04Q ⁷ /00-7/38

Claims (2)

(57) [Claims] 1. A RELAY apparatus receives transmission radio waves from the base station, after decoding, and stores the signal after No.該復, transmission radio wave reception time from the transmission time base station and mobile station to which Is transmitted to the mobile station after a certain period of time so that it does not overlap with all the slots. On the other hand, after receiving and decoding the transmission radio wave from the mobile station,
Storing the signal after No.該復, this such that the transmission time do not overlap in the transmission signal reception time and all slots of the base station and the mobile station, after a predetermined time, and transmits to the base station, the base station And mobile stations communicate in a time-division manner
Wireless relay method in a communication system, wherein the relay device transmits a control channel transmitted from a base station.
Receive and extract TDMA timing from the control channel.
And using the extracted TDMA timing,
The transmission timing of the relay device is created.
Wireless relay method. 2. A relay device in a mobile communication system in which a base station and a mobile station communicate in a time-division manner, the relay device comprising: first antenna means for transmitting and receiving radio waves to and from the base station; Second antenna means for transmitting and receiving radio waves; first decoding means for decoding radio signals from the base station received by the first antenna means; and mobile stations received by the second antenna means. Second decoding means for decoding the radio wave signal of the above, a first delay means for storing and delaying the signal decoded by the first decoding means, and a signal decoded by the second decoding means Second delay means for storing and delaying the delay time, and control included in the signal decoded by the first decoding means.
Timing extracting means for extracting the TDMA timing of the base station from the control channel ; timing of the TDMA of the base station extracted by the timing extracting means; and decoding by the first decoding means and the second decoding means. A timing generation unit that generates a TDMA timing used by the relay device from the received signal, and modulating the signal stored in the second delay unit using the timing generated by the timing generation unit. A first transmitting unit for generating a transmission radio wave to be transmitted to the base station via the first antenna unit; and a signal stored in the first delay unit using the timing generated by the timing generating unit. And a second transmitting means for generating a transmission radio wave to be transmitted to the mobile station via the second antenna means. The relay device receives the transmission radio wave of the base station, and the transmission radio wave of the mobile station, and the transmission time of each of the transmission radio waves to the mobile station and the base station is the transmission time of the transmission radio wave from the base station and the mobile station. A wireless relay device for relaying each of the transmitting means so as not to overlap with a reception time in all slots.