JPH0746660A - Radio communication equipment - Google Patents

Abstract

PURPOSE:To establish frame synchronization among radio base stations for performing communication by a TDMA-TDD system. CONSTITUTION:Information for indicating the position of a slot inside a frame is inserted to the slot of control signals transmitted from the radio base station 12. In the radio base station 13 for performing the frame synchronization, the control signal transmission timing of the present station is synchronized with the reception timing of the control signals and the frame synchronization is established corresponding to the position of the slot of the reception control signals inside the frame.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention is used in a time division multiple access communication system. In particular, a communication system in which transmission / reception slots are time-multiplexed with the same carrier frequency, that is, TDMA-TDD
Regarding the scheme. The present invention is suitable for use in a multi-zone type digital cordless telephone.

[0002]

2. Description of the Related Art FIG. 8 is a block diagram showing a conventional radio communication apparatus of TDMA-TDD system, and FIG. 10 shows an example of its frame structure.

This wireless communication device comprises a wireless base station 82 connected to a fixed network 81, and this wireless base station 82 communicates with a plurality of mobile terminals by the TDMA-TDD system.
In the TDMA-TDD system, one frame is composed of a transmission slot side for multiplexing n transmission slots and a reception slot side for multiplexing n reception slots.

Communication between the radio base station 82 and the mobile terminals 83 and 84 will be described. Wireless base station 8
2 is a predetermined slot, which is the first slot in this example
The slot is used to transmit a control signal including information necessary for line setting. F1 is used as the carrier frequency of the control signal. The radio base station 82 further transmits a call signal to the mobile terminal 83 in the second slot and a call signal to the mobile terminal 84 in the third slot. A frequency different from f1 is used as the carrier frequency of the call signal. Further, the call signal is transmitted to the other mobile terminals using the fourth slot and thereafter. In the mobile terminals 83, 84, ..., After the predetermined time has passed from the reception slot of the mobile terminal 83, 84, ...
Send a telephone signal to. The radio base station 82 receives the signal from each mobile terminal at the reception slot position corresponding to the transmission slot in one frame.

In this example, the case where there is one radio base station is shown, but in applications where a plurality of radio base stations are provided, for example, in applications such as multi-zone cordless telephones, it is necessary to prevent control signal collisions. Therefore, it is necessary to synchronize the radio base stations.

As an example of synchronization between radio base stations, an example of a conventional car telephone system is shown in FIG. However, in this case, neither the TDMA method nor the TDD method is used, and only one wireless channel can be accessed at the same time.
Transmission and reception radio channels are multiplexed by frequency.

This car telephone system includes a control station 102 connected to a fixed network 101, and radio base stations 105 to 107 are connected to the control station 102. The control station 102 includes variable delay circuits 103 and 104 for adjusting the propagation delay.
Is provided. The control signal for the mobile terminal 108 is transmitted from the control station 102 via the radio base stations 105 to 107. The radio base stations 105 to 107 transmit control signals in synchronization with each other by using frequencies set so that their zones do not overlap each other.

In order to synchronize the control signal, for example, the radio base station 105 is used as a reference station, and the radio base station 106 receives the control signal from the radio base station 105 and measures the time difference from the transmission timing of its own station. This measurement result is notified to the control station 102, and the control station 102 adjusts the corresponding variable delay circuit 103 so that the time difference becomes zero. The radio base station 107 receives the control signal from the radio base station 106, measures the time difference from its own transmission timing, and notifies the control station 102 of the result. The control station 102 adjusts the corresponding variable delay circuit 104 so that the time difference becomes zero.

FIG. 11 shows a control station 102 and a radio base station 1.
The timing of sending the control signal from 05 to 107 is shown.
The control station 102 delays the control signal with the variable delay circuits 103 and 104, and sends the control signal to the radio base stations 105 to 107 at timings t0 to t2, respectively. These control signals pass through the signal line between the control station 102 and the radio base stations 105 to 107, and thus a propagation delay occurs, and the control signals are transmitted from the radio base stations 105 to 107 all together at time t3.

In this way, the control signals transmitted from a plurality of radio base stations reach the mobile terminal almost at the same time, and the control signals from the radio base stations are received at the same level. Even when the mobile terminal passes through the boundary area, the mobile terminal can switch the other party's radio base station while maintaining the synchronized state.

[0011]

When a plurality of radio base stations transmit control signals at frequencies different from each other, each radio base station receives a control signal from another radio base station. The transmission timing of the station can be set.

However, in the case of the TDMA-TDD system, since the same frequency is used, it is necessary for the radio base stations to transmit control signals at different timings.
Nevertheless, the frame of the signal transmitted and received by each radio base station to and from the mobile terminal needs to be synchronized at least between adjacent radio base stations. This is because if they are not synchronized, when one radio base station is transmitting, the other is receiving, and this causes interference, which causes deterioration of communication quality and deterioration of frequency utilization efficiency. Therefore, it is not possible to directly use the method like the conventional car telephone device.

It is an object of the present invention to provide a radio communication device capable of synchronizing control signal transmission timings between radio base stations in the TDMA-TDD system.

[0014]

A radio communication apparatus of the present invention communicates with a plurality of mobile terminals by a time division multiple access system using a frame in which a transmission slot and a reception slot are time-multiplexed at the same carrier frequency. In a wireless communication device including a plurality of radio base stations, each of the plurality of radio base stations includes a unit that transmits and receives a control signal to and from a mobile terminal using at least one slot in a frame, At least one radio base station includes an intra-frame position notification means for inserting slot position information indicating the position in the frame of the slot into the slot for transmitting the control signal, the reception timing of the control signal in each radio base station and the A frame that adjusts the timing of frames transmitted and received by the station according to the received slot position information. Characterized by comprising a beam synchronization means.

One of a plurality of radio base stations is set as a reference station, at least this reference station, and in some cases all reference stations are provided with in-frame position notification means, and frame synchronization means is provided in all radio base stations other than the reference station. Is good.

It is also possible to establish the frame synchronization of each radio base station in order. However, in order to establish frame synchronization, it is necessary to receive a control signal from another radio base station, and the frame transmission / reception in that radio base station must be interrupted. Therefore, as long as the control signals are installed within the reachable range, it is desirable that the control signals from one radio base station cause the other radio base stations to simultaneously perform the frame synchronization operation.

[0017]

The information indicating the position of the slot in the frame is inserted into the slot of the control signal transmitted from at least one radio base station. A radio base station that performs frame synchronization receives the control signal and position information, and refers to the timing of the control signal and its slot position to set its own frame transmission / reception timing. Thereby, the transmission timing of the control signal of the station is also set.

In a small-sized wireless communication device such as a cordless telephone, the wiring is complicated in the configuration in which the control station is connected between the wireless base station and the fixed network, so that the wireless base stations are individually connected to the fixed network. However, it is desirable to correct the propagation delay between the fixed network and the radio base station in each radio base station.

[0019]

1 is a block diagram showing the configuration of a wireless communication apparatus according to an embodiment of the present invention. The apparatus of this embodiment includes a plurality of radio base stations 12 to 14 that communicate with a plurality of mobile terminals by a time division multiple access method using a frame in which a transmission slot and a reception slot are time-multiplexed at the same carrier frequency, Each of the plurality of radio base stations 12 to 14 transmits / receives a control signal to / from the mobile terminal using at least one slot in the frame. In the following description, it is assumed that the radio base stations 12 to 14 respectively transmit and receive the control signal by using the second, third and first time slots.

FIG. 2 shows a format example of the control signal slot. This slot has 4 ramp bits R used for signal rise, 2 bit start symbol SS used for start bit, 62 bit preamble PR used for establishing bit synchronization, and frame synchronization establishment. 32-bit unique word U to use
W, 124-bit CAC for transmitting the actual control signal, and used for collision prevention between time slots 16
It is composed of a signalless guard bit G.

In the normal operating state, the radio base stations 12-1
The transmission and reception timings of 4 are synchronized, and the wireless base station 1
The control signals transmitted by 2 to 14 are not received by other radio base stations. However, it is necessary to synchronize the transmission / reception timings of the wireless base stations 13 and 14 with the transmission / reception timings of the wireless base station 12 at the start of operation or at the timing adjustment. For this purpose, originally, the function for receiving the control signal from the mobile terminal is used, and the radio base station 1
2 receives the transmitted control signal.

FIG. 3 is a flow chart showing the flow of the synchronizing operation in the radio base station 13. The wireless base station 12 is
A signal indicating the position of the slot in the frame is transmitted by the bit pattern of the unique word UW shown in FIG. 2 or by providing the CAC with two dedicated bits. When the radio base station 12 receives this slot,
The preamble PR establishes bit synchronization, and the unique word UW establishes frame synchronization for a slot. At this time, the time difference between the reception timing and the timing when the local station tries to transmit the control signal is measured, and first, the variable delay circuit 15 is adjusted so that the time difference becomes zero. Then, the control signal received in the slot is decoded, the position of the received slot in the frame is confirmed, and the variable delay circuit 15 is adjusted again so that the delay time difference in one frame becomes zero. After the synchronization is established in this way, the wireless base station 13 starts transmitting the control signal.

Similarly, the radio base station 14 also has the radio base station 12
The variable delay circuit 16 is adjusted according to the control signal from to establish frame synchronization, and the transmission of the control signal is started.
If the installation location of the wireless base station 14 is a location where the control signal from the wireless base station 12 does not reach, frame synchronization is established according to the control signal from the wireless base station 13.

4 to 7 show an operation example. FIG. 4 shows a state before frame synchronization is established. In this state,
There is a possibility that the transmission of the radio base station 12 and the reception of the radio base stations 13 and 14 may overlap or control signals may collide. Therefore, first, as shown in FIG. 5, the timing of control signal transmission of the own station (radio base station 13 in this example) is set to the timing of control signal reception from another radio base station (radio base station 12 in this example). Sync to. Then, based on the position of the slot in the frame indicated by the control signal, the timing of the frame transmitted / received by the local station is adjusted so that the slot of the same number is synchronized. FIG. 6 shows the wireless base station 1.
7 shows a state in which frame synchronization has been established between 2 and 13.
Indicates a state in which frame synchronization has been established in all the radio base stations 12-14.

In the above embodiment, the configuration of the radio base station 12 serving as the reference station is shown as being different from that of the other radio base stations 13 and 14, but generally the same configuration can be used.

[0026]

As described above, the radio communication apparatus of the present invention inserts information regarding the position in the frame into the slot of the control signal transmitted from at least one radio base station, thereby performing TDMA-TDD. Frame synchronization can be established between wireless base stations in the system. Therefore, when one radio base station is transmitting, the other is also transmitting, and when one radio base station is receiving, the other is also receiving, so that the communication quality can be improved,
Moreover, the frequency effective rate can be increased.

[Brief description of drawings]

FIG. 1 is a block configuration diagram showing a wireless communication device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a format example of a control signal slot.

FIG. 3 is a flowchart showing a flow of a synchronization operation in one wireless base station.

FIG. 4 is a diagram showing an operation example, showing a state before frame synchronization is established.

FIG. 5 is a diagram showing an operation example, showing a state in which the timings of control signals are synchronized.

FIG. 6 is a diagram showing a state where frame synchronization is established between two wireless base stations.

FIG. 7 is a diagram showing a state where frame synchronization is established in all wireless base stations.

FIG. 8 is a block configuration diagram showing a conventional wireless communication device of a TDMA-TDD system.

FIG. 9 is a diagram showing a frame structure.

FIG. 10 is a block configuration diagram showing a conventional car telephone device, and a diagram for explaining synchronization between the radio base stations.

FIG. 11 is a diagram showing transmission timing of control signals by the control station and the radio base station.

[Explanation of symbols]

 11, 81, 101 Fixed network 12-14, 82, 105-107 Radio base station 15, 16, 103, 104 Variable delay circuit 83, 84, 108 Mobile terminal 102 Control station

Claims (2)

[Claims] 1. A plurality of radio base stations for communicating with a plurality of mobile terminals by a time division multiple access system using a frame in which a transmission slot and a reception slot are time-multiplexed at the same carrier frequency, and the plurality of radio base stations are provided. Each of the base stations is a radio communication device including means for transmitting and receiving a control signal to and from a mobile terminal using at least one slot in the frame, wherein at least one radio base station of the plurality of radio base stations is the control unit. Including in-frame position notifying means for inserting slot position information indicating a position in the frame of the slot into a slot for transmitting a signal, according to the reception timing of the control signal in each radio base station and the received slot position information, It must be equipped with frame synchronization means to adjust the timing of frames transmitted and received by the station. And a wireless communication device. 2. One of the plurality of radio base stations is set as a reference station, at least the reference position is provided with the in-frame position notifying means, and the frame synchronizing means is provided at least in all radio base stations other than the reference station. The wireless communication device according to claim 1.