JPH0530006A - Radio communication system and radio communication equipment used for the system - Google Patents

Abstract

PURPOSE:To improve the service quality by reducing the effect of momentary fluctuation such as fading or multi-path onto the system so as to decrease a time required for the establishment of slot synchronization and keeping stably the establishing state of slot synchronization. CONSTITUTION:Information representing a synchronizing signal inserted to a time slot other than a time slot assigned to a mobile station is sent from a base station to the mobile station, the mobile station receives the information and stores it, the mobile station sets its reception gate period sets a period including a reception period of the time slot allocated to its own mobile station for the locking period of the slot synchronization and during communication after the establishment and a reception period of a succeeding time slot, receives and detects each synchronizing signal, identifies the received time slot based on the detected synchronizing signal and the stored information and controls the operation relating to slot synchronization based on the result of the identification.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio communication system such as an automobile / portable radio telephone system or a cordless telephone system, and particularly uses a digital system as a radio communication system between a base station device and a mobile station device. The present invention relates to a wireless communication system and a wireless communication device used in this system.

[0002]

2. Description of the Related Art Recently, as one of wireless communication systems,
For example, a system adopting a dual mode wireless communication system has been proposed. The dual mode is a system that uses both an analog mode and a digital mode.

This type of system, for example, as shown in FIG. 4, has a control station CS connected to a wired telephone network NW and a plurality of control stations CS connected via wired lines CL1 to CL3, respectively. It comprises base stations BS1 to BSn and a plurality of mobile stations PS1 to PSm. Each of the above base stations BS1
~ BSn form radio zones E1 to En, respectively. The wireless mobile stations PS1 to PSm correspond to the base stations BS1 to BSn.
Within the wireless zones E1 to En of the base stations BS1 to BS1.
It is connected to BSn via a wireless line.

As described above, the analog mode and the digital mode are used for the communication system using the wireless line. The analog mode is a method in which the transmitting side angularly modulates a carrier wave with a voice signal and data and transmits the signal, and the receiving side receives the modulated carrier wave sent from the transmitting side and performs angle demodulation to reproduce the voice and data. . On the other hand, in the digital mode, the transmitting side encodes a voice signal and data, modulates a carrier wave with this encoded signal to transmit, and the receiving side receives and demodulates the modulated carrier wave sent from the transmitting side. After that, it is a method of reproducing a voice signal and data by decoding the demodulated signal.

By the way, a time division multiple access (TDMA) system is generally used for the wireless communication in the digital mode. In the TDMA method, a format of a transmission signal transmitted by one radio frequency has a time frame structure in which a plurality of time slots are time-division multiplexed, and a vacant slot among these time slots is allocated to a mobile station which is going to perform communication. As a result, each mobile station can perform wireless communication with the base station. Therefore, when communication is performed using such a method, the wireless communication device of the mobile station needs to establish slot synchronization for the transmission signal coming from the base station.

FIG. 5 is for explaining a conventional slot synchronization establishing operation. In the figure, it is assumed that, for example, one frame of a transmission signal consists of 6 time slots as shown in (a) of the figure, and slot 2 of these time slots is assigned to an arbitrary mobile station BSi. Then, the mobile station BSi first sets a reception gate period corresponding to one slot, receives the signal sent from the base station while shifting the position of the reception gate period, and synchronizes from the received signals. Detect the signal. Then, when the synchronization signal SYNC2 corresponding to the slot 2 is detected, slot synchronization is established at this point, and thereafter, in the figure,
As shown in (d), the position of the reception gate period is fixed and the reception of the data in slot 2 is started. At this time, the mobile station transmits data to the base station BS during the receiving period T of slot 1 as shown in (b) in the figure, and becomes idle during the receiving period I of slot 3.

In addition, during data communication, the mobile station monitors the reception state of the synchronization signal during the reception gate period, and when the synchronization signal cannot be received correctly, it is determined that out-of-synchronization has occurred, and slot synchronization is established. Return to the retracting operation of.

[0008]

However, the conventional device which performs such a slot synchronization operation has the following problems to be improved. That is, a mobile station of a mobile radio communication system is more likely to experience fading and instantaneous multipath fluctuations during mobile communication than a fixed station. When this instantaneous fluctuation occurs, the mobile station may not be able to receive the synchronization signal of its own slot depending on the timing of occurrence. As described above, the conventional device monitors only the reception status of the synchronization signal in its own slot during communication, so if the synchronization signal in its own slot cannot be received as described above, it will be mistaken as an immediate loss of synchronization. I had to make a decision.

Further, in the process of establishing the slot synchronization, even when the synchronization signal cannot be received temporarily due to the influence of fading or multipath, the synchronization establishment fails even if the slot synchronization is established. Therefore, there is a problem that the time required to establish the slot synchronization becomes long as a result. When the time required to establish slot synchronization becomes long, for example, when switching a wireless line used during communication from an analog line to a digital line, or when performing a so-called handoff for switching a connected base station as a mobile station moves, This is very unfavorable in terms of service quality because there is a problem that the communication suspension time becomes long and the speaker feels uneasy, and in some cases the speaker misrecognizes it as a line disconnection and performs an end call operation. .

The present invention has been made in view of the above circumstances. An object of the present invention is to reduce the influence of fading and instantaneous fluctuations of multipaths, shorten the time required for establishing slot synchronization, and reduce the number of slots. It is an object of the present invention to provide a wireless communication system and a wireless communication device thereof that can maintain the synchronization establishment state more stably and thereby improve the service quality.

Another object of the present invention is to eliminate the need for transmission of information representing a synchronization signal from the base station to the mobile station, thereby enabling synchronization pull-in or synchronization protection operation without changing the control procedure of the base station. It is to provide a wireless communication device that can be easily performed.

[0012]

In order to achieve the above object, a radio communication system of the present invention is a synchronization system in which a base station sends a mobile station a time slot other than a time slot assigned to the mobile station. Information representing a signal is transmitted, and the mobile station receives the information representing the synchronization signal transmitted from the base station and stores it in the storage means. Then, during at least one of the slot synchronization pull-in period and the communication after establishment in the mobile station, the reception period of the time slot assigned to the own station and the reception period of another selected time slot subsequent to this time slot. To perform a reception operation to detect a synchronization signal, identify the received time slot based on the detected synchronization signal and the information stored in the storage means, and perform slot synchronization based on the identification result. The operation related to is controlled.

In order to achieve the above-mentioned other object, the wireless communication apparatus of the present invention has a storage means for storing in advance information representing a synchronization signal inserted in each time slot, and a synchronization control means. . Then, the synchronization control means, during at least one of the pull-in period of the slot synchronization and the communication after the establishment, the reception period of the time slot assigned to the own station and the selected other following this time slot. The reception operation is performed during the reception period of each time slot, the synchronization signal is detected, the received time slot is identified based on the synchronization signal and the information stored in the storage means, and the identification result is identified. It is designed to be used for a synchronous operation for a time slot assigned to a station.

[0014]

As a result, according to the wireless communication system and the wireless communication apparatus of the present invention, the mobile station not only receives the time slot assigned to its own station but also other selected time slots following this time slot. The sync signal is detected even during the reception period of, and the sync pull-in or sync protection operation is performed based on the plurality of sync signals. Therefore, even if the received signal is momentarily interrupted due to fading or multipath in the time slot assigned to the own station, and the synchronization signal of the time slot of the own station is not detected, the other time slots are It is possible to perform synchronization pull-in or synchronization protection operation based on the detected synchronization signal. Therefore, the time required to establish slot synchronization can be shortened,
Further, the established state of slot synchronization can be stably maintained.

Further, in the case of the wireless communication device of the present invention, since the information indicating the synchronization signal of the time slot other than the time slot assigned to the own station is stored in the storage means in advance, the base station transfers to the mobile station. It is not necessary to transmit information representing the synchronization signal of other time slots. For this reason,
The present invention can be implemented without changing the control procedure of the base station.

[0016]

1 is a circuit block diagram showing the overall configuration of a mobile station wireless communication apparatus according to an embodiment of the present invention.

In FIG. 1, a radio communication signal sent from a base station (not shown) in a predetermined time slot is received by a receiving circuit (R) via an antenna 1 and a duplexer (DUP) 2.
X) 3, where the frequency synthesizer (SY
N) is combined with the local oscillation signal output from the N4 and converted into an intermediate frequency signal. Then, the received intermediate frequency signal is input to a digital modulation / demodulation circuit (MOD) 6 which will be described later, where it is digitally demodulated after bit synchronization and slot synchronization are established. The synchronization information obtained when establishing the bit synchronization and the slot synchronization is supplied to the control circuit (CONT). The digital demodulation signal output from the digital modulation / demodulation circuit 6 includes a digital speech signal and a digital control signal, of which the digital control signal is supplied to the control circuit 20 for identification. On the other hand, the digital speech signal is subjected to error correction decoding by the error correction code decoding circuit (CH-COD) 8. Then, after being decoded by the voice code decoding circuit (SP-COD) 9 and returned to an analog call signal, it is supplied to the handset 11 through the voice switch 10 and voice is output from the handset 11.

On the other hand, the speaker's transmission signal input from the transmitter 12 is input to the voice code decoding circuit 9 via the voice switch 13 and encoded therein. The digital transmission signal obtained by this encoding is subjected to error correction coding in the error correction code decoding circuit 8 together with the digital control signal output from the control circuit 20, and then input to the digital modulation / demodulation circuit 6. In this digital modulation / demodulation circuit 6,
The intermediate frequency signal is, for example, QPSK modulated by the digital transmission signal supplied from the error correction code decoding circuit 8, and the modulated intermediate frequency signal is input to the transmission circuit (TX) 5. In the transmission circuit 5, the modulated intermediate frequency signal is combined with the local oscillation signal output from the frequency synthesizer 4 and converted into a high frequency signal, which is amplified to a predetermined transmission level and then passed through the duplexer 2. And transmitted from the antenna 1 to the base station. The transmission of the high frequency signal is performed in a burst in a time slot assigned in advance.

The apparatus of this embodiment has a structure applicable to a system in which a digital system and a current analog system coexist, that is, a dual mode wireless telephone system. That is, when the wireless communication is performed by the analog method rather than the digital method, the voice switches 10 and 13 are controlled by the voice switch 10 and 13 by the control of the control circuit 20.
Side to the analog voice processing circuit (A-AUD) 14 side. The demodulated signal output from the receiving circuit 3 is converted into a voice signal by the analog voice processing circuit 14 and then supplied to the handset 11 via the voice switch 10.
The voice is output from the handset 11.

On the other hand, the transmission signal output from the transmitter 12 is input to the analog voice processing circuit 14 via the voice switch 13, where it is converted into an intermediate frequency signal and then transmitted by the transmission circuit 5 to a high frequency. It is converted into a signal and transmitted from the antenna 1.

Reference numeral 15 is a console unit (CU) in which switches such as a dial key and a transmission switch and a liquid crystal display are provided, and 16 is a predetermined operating voltage Vcc based on the electric power of a car battery 17, for example. It is a power circuit.

By the way, the digital modulation / demodulation circuit 6 is constructed as follows. FIG. 2 is a circuit block diagram showing the configuration. That is, this digital modulation / demodulation circuit 6
Includes a detection circuit 61 having an equalizer (hereinafter referred to as an equalization detection circuit) 61 and a delay detection circuit 62. The reception intermediate frequency signal output from the reception circuit 3 is detected by these detection circuits. Demodulated at 61 and 62, respectively. The demodulated signals obtained by the detection circuits 61 and 62 are selectively selected by the changeover switch 67 and then output to the error correction code decoding circuit 8 and the slot synchronization circuit 63.
And the reception state detection circuits 65 and 66. Among these circuits, the reception state detection circuits 65 and 66 detect the code error rate, the reception power or D / U from the demodulated signals output from the equalization detection circuit 61 and the delay detection circuit 62, respectively, The detection result is supplied to the detection method selection circuit 67. The detection method selection circuit 67 sets the changeover switch 68 so as to selectively output the demodulated signal having good reception quality to the error correction code decoding circuit 8 according to the detection results of the reception state detection circuits 65 and 66. Switch control.

By the way, the slot synchronization circuit 63 is not limited to the time slot period assigned to its own station during the slot synchronization pull-in and during the communication period after the establishment of the slot synchronization, and the time slots of other subsequent time slots. Also, the receiving operation is performed to detect the sync signals, and the sync pull-in operation and the sync protection operation are performed based on the detection results of these sync signals. In addition, in order to detect the synchronization signal of the other time slot, R
Information representing a synchronization signal of another time slot is previously stored in the storage circuit 64 made of AM. This information is transmitted as control data from a base station (not shown) prior to the sync pull-in operation and the sync protection operation.

Reference numeral 69 is a modulation circuit, which maps the transmission signal output from the error correction coding / decoding circuit 8 by, for example, π / 4 differential coding, and performs QPSK modulation of the intermediate frequency signal by the mapping data. Is.

Next, the operation of the system according to this embodiment will be described based on the above configuration. Here, as shown in FIG. 3 (a), a transmission signal composed of six time slots in one frame is transmitted from the base station to the mobile station, and slot 2 is transmitted to the mobile station which is about to perform communication. The explanation will be given assuming that it is assigned.

First, when the mobile station in question performs slot synchronization pull-in for the time slot 2 of the transmission signal due to call origination / termination or handoff, the base station uses the control channel to communicate with the mobile station. When transmitting and receiving control data for connection, not only the synchronization signal information of time slot 2 assigned to this mobile station, but also the synchronization signal information of the next time slot 3 following this time slot 2 is transmitted to the mobile station. .

On the other hand, when the mobile station detects that the synchronization signal information of the next time slot 3 (hereinafter referred to as the next slot) is inserted in the control data transmitted by the control radio frequency, The synchronization signal information of the next slot 3 is stored in the storage circuit 64 of the digital modulation / demodulation circuit 6 together with the synchronization signal information of the time slot 2 (hereinafter referred to as the own slot) assigned to the own station.

When the transfer of control data is completed in this way, the mobile station starts the sync pull-in operation for slot 2 with respect to the transmission signal transmitted by the slot synchronizing circuit 63 at the radio frequency for communication. That is, first, the slot synchronization circuit 63 is in a state of always monitoring the synchronization signal of its own slot 2. In this state, the synchronization signal SYNC of its own slot
When 2 is detected, the slot synchronization circuit 63 sets the reception gate period based on the detection timing. As shown in FIGS. 3 (c) and 3 (d), this reception gate period includes the entire period R of the own slot 2 and the period corresponding to the insertion position of the synchronization signal SYNC3 of the next slot 3 which is the idle slot I. Is set to. Then, in this state, the slot synchronization circuit 63 refers to the synchronization signal information stored in the storage circuit 64 to obtain the synchronization signal SY of its own slot.
When the sync signal SYNC3 of the NC2 and the next slot 3 is detected and the sync signal SYNC2 of its own slot is correctly detected a predetermined number of times in succession, the slot synchronization circuit 63 establishes slot synchronization at this timing.

By the way, in the synchronization establishing operation, it is assumed that the synchronization signal SYNC2 of the own slot is temporarily not correctly detected due to the influence of fading or multipath. Then, in this case, the detection state of the synchronization signal SYNC3 of the next slot 3 is determined, and the synchronization signal S
If YNC3 is correctly detected, it is considered that the synchronization is not lost even if the synchronization signal SYNC2 is not detected, and slot synchronization is established. Therefore, the synchronization signal SYNC
The time required to establish slot synchronization can be shortened as compared with the case where only 2 is monitored.

On the other hand, during the communication period after the slot synchronization is established, the slot synchronization circuit 63 performs the slot synchronization protection operation as follows. That is, as shown in FIG. 3 (d), the slot synchronization circuit 63 receives the synchronization signals SYNC2 and SYNC3 in the reception gate period including the reception period R of its own slot 2 and the synchronization signal reception period of the next slot 3.
Is being monitored. Then, in this state, for example, it is assumed that the received radio wave is continuously disconnected for a certain time or longer due to the mobile station entering the tunnel. Then, the slot synchronization circuit 63 cannot detect both the synchronization signal SYNC2 of its own slot 2 and the synchronization signal SYNC3 of the next slot 3, so it determines that the synchronization is lost and shifts to the synchronization pull-in operation.

On the other hand, when the received radio wave of the own slot 2 is temporarily cut off due to fading or multipath, the synchronization signal SYNC2 of the own slot 2 cannot be detected, but the synchronization signal of the next slot 3 is detected. SYNC3 is detected. For this reason, the slot synchronization circuit 63 does not determine that this is out of synchronization, and maintains the synchronization established state as it is. Therefore, even if the reception radio wave of its own slot 2 is temporarily cut off due to the influence of fading or multipath,
The synchronization establishment state is stably maintained without being affected by this.

As described above, according to the present embodiment, the reception gate period is set to the entire reception period of the own slot 2 and the synchronization signal of the next slot 3 even when the slot synchronization is pulled in and the slot synchronization is established. The reception signal is set to a period including a reception period, the respective synchronization signals SYNC2 and SYNC3 are received and detected, and these synchronization signals SYNC2 and SYNC3 are detected.
Since the synchronization pull-in operation and the synchronization protection operation are executed based on the reception detection state of, even if the reception radio wave is temporarily cut off due to fading or multipath,
The influence can be reduced to establish slot synchronization in a short time, and the established state of slot synchronization can be stably maintained.

Further, in the present embodiment, the reception gate period is set so as to include not only the reception period of the own slot but also the partial period of the next slot.
The detection period at 66 can be extended compared to the case of 1 slot. Therefore, for example, the number of samples when detecting the line error rate can be increased, and thereby the detection accuracy can be increased and the detection method can be selected more appropriately.

Further, in this embodiment, the reception gate period is specified as a period including the entire reception period of the own slot 2 and the synchronization signal reception period of the next slot 3, so that the period of the transmission slot T is excluded, for example. The power consumption can be reduced as compared with the case where other slots are constantly received and the synchronization signal is detected, and thus the battery life can be kept long. This effect is extremely important in a mobile radio communication device that uses a battery as a power source.

The present invention is not limited to the above embodiment. For example, a ROM or E ² for writing the synchronization signal information of each time slot into a wireless communication device used as a mobile station. A nonvolatile memory such as a ROM may be provided, and the manufacturer or seller may write the synchronization signal information in the nonvolatile memory at the time of manufacturing or selling the device. With this configuration, the base station does not need to transmit the synchronization signal information to the mobile station,
This can simplify the control procedure of the base station and the mobile station. That is, in such an embodiment,
There is an advantage that the configuration can be implemented by slightly changing the configuration of the mobile station without changing the configuration of the base station, that is, the configuration of the system.

Further, in the above-mentioned embodiment, the transmission of the synchronization signal information from the base station to the mobile station is performed as a part of the control data by using the control channel, but it is transmitted from the base station separately from the transmission signal. The synchronization signal information may be transmitted by using the SAT signal (carrier signal of 6 kHz) that is generated. Further, the synchronization signal information may be transmitted during the training period in the wireless line connection procedure.

Further, in the above-mentioned embodiment, the information representing the synchronizing signal of the next slot 3 is transmitted from the base station to the mobile station as it is, but when there is a regularity such as the order between the synchronizing signals of each time slot. The information indicating this regularity (correlation information) may be transmitted to the computer.

Further, in the above embodiment, the receiving gate period is set to a period including the entire period of the own slot and the synchronizing signal receiving period of the next slot, but it may be set longer than that if necessary. In addition, the configuration of the wireless communication device and its digital modulation / demodulation circuit, the control procedure of the synchronization pull-in and synchronization protection operations, the type of the wireless communication system to be applied, and the like can be variously modified and implemented without departing from the scope of the present invention.

[0039]

As described in detail above, according to the present invention, the base station transmits to the mobile station information representing a synchronization signal inserted in a time slot other than the time slot assigned to the mobile station, and the mobile station moves. The station receives the information representing the synchronization signal transmitted from the base station and stores it in the storage means.
Then, during at least one of the slot synchronization pull-in period and the communication after establishment in the mobile station, the reception period of the time slot assigned to the own station and the reception period of another selected time slot subsequent to this time slot. To perform a reception operation to detect a synchronization signal, identify the received time slot based on the detected synchronization signal and the information stored in the storage means, and perform slot synchronization based on the identification result. The operation related to is controlled.

Therefore, according to the present invention, it is possible to reduce the influence of fading and instantaneous fluctuation of multipath,
As a result, it is possible to provide a wireless communication system and its wireless communication device that can shorten the time required to establish slot synchronization and stably maintain the established state of slot synchronization to improve the quality of service.

Still another aspect of the present invention has a storage means for storing in advance information representing a synchronization signal to be inserted in each time slot, and a synchronization control means. With this synchronization control means,
During at least one of the slot synchronization pull-in period and the communication after establishment, during the reception period of the time slot assigned to the own station and the reception period of other selected time slots subsequent to this time slot, respectively. The receiving operation is performed to detect the synchronizing signal, the received time slot is identified based on the synchronizing signal and the information stored in the storage means, and the identification result is compared with the time slot assigned to the own station. It is designed to be used for synchronous operation.

Therefore, according to another aspect of the present invention, it is possible to eliminate the need to transmit the information representing the synchronization signal from the base station to the mobile station, and thereby the synchronization pull-in can be performed without changing the control procedure of the base station. Alternatively, it is possible to provide a wireless communication device that can easily perform the synchronization protection operation.

[Brief description of drawings]

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

FIG. 2 is a circuit block diagram showing a configuration of a digital modulation / demodulation circuit of the device shown in FIG.

FIG. 3 is a timing diagram for explaining a slot synchronization operation of the device shown in FIG.

FIG. 4 is a schematic configuration diagram showing an example of a cellular radio telephone system.

FIG. 5 is a timing diagram for explaining a slot synchronization operation of a conventional wireless communication device.

[Explanation of symbols]

1 ... Antenna, 2 ... Duplexer (DUP), 3 ... Reception circuit (RX), 4 ... Frequency synthesizer circuit, 5 ... Transmission circuit (TX), 6 ... Digital modulation / demodulation circuit (MOD), 8 ...
Error correction code decoding circuit (CH-COD), 9 ... Voice code decoding circuit (SP-COD), 10, 13 ... Changeover switch, 11 ... Speaker, 12 ... Microphone, 14 ... Analog voice processing circuit (A-AUD), 15 ... Console unit (CU), 20 ... Control circuit (CONT), 61 ...
Equalization detection circuit, 62 ... Delay detection circuit, 63 ... Slot synchronization circuit, 64 ... Storage circuit, 65, 66 ... Reception state detection circuit, 67 ... Detection method selection circuit, 68 ... Changeover switch, 6
9 ... Modulation circuit.

Claims (4)

[Claims] 1. A plurality of base stations, and a plurality of mobile stations connected to the base stations via wireless lines, wherein a plurality of sync signals having different formats of transmission signals transmitted by the wireless lines are inserted. In a wireless communication system for performing wireless communication between a mobile station and a base station by selectively allocating these time slots to each mobile station, the base station Means for transmitting to the mobile station information representing a synchronization signal inserted in a time slot other than the time slot assigned to the mobile station, each mobile station being provided with a synchronization signal transmitted from the base station. Storage means for receiving and storing information indicating the time slot, and during at least one of the slot synchronization pull-in period and communication after establishment. During the receiving period of the time slot assigned to the own station and the receiving period of another selected time slot subsequent to this time slot, the receiving operation is performed to detect the synchronizing signal, and the detected synchronizing signal and the storage means. And a synchronization control means for identifying the received time slot on the basis of the information stored in, and using the identification result for the synchronization operation for the time slot assigned to the own station. Communications system. 2. The wireless communication system according to claim 1, wherein the base station transmits, as the information indicating the synchronization signal, information indicating a slot number or information indicating the order of slots. 3. The synchronization control means of the mobile station performs a reception operation during the reception period of the time slot assigned to the mobile station and the reception period of the next time slot following this time slot, and detects the synchronization signal. The wireless communication system according to claim 1, wherein: 4. A plurality of base stations and a plurality of mobile stations connected to the base stations via wireless lines, wherein a plurality of sync signals having different formats of transmission signals transmitted by the wireless lines are inserted. Mobile stations used in a radio communication system for performing radio communication between a mobile station and a base station by selectively allocating these time slots to each mobile station in a time frame structure in which time slots of time slots are multiplexed. In a wireless communication device for a station, a storage unit that stores in advance information indicating a synchronization signal to be inserted into each of the time slots, and at least one of the slot synchronization pull-in period and the established communication, During the reception period of the time slot assigned to the own station and the reception period of other selected time slots following this time slot. Each receiving operation is performed to detect a synchronizing signal, the received time slot is identified based on the synchronizing signal and the information stored in the storage means, and this identification result is assigned to the own station. A wireless communication device comprising: a synchronization control unit used for a synchronization operation for a time slot.