JP3289718B2 - Time division multiple access method, reference station device, terminal station device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a time-division multiplex access between one reference station and a plurality of terminal stations by a demand assignment method, and more particularly to a time-division multiplex access method to which an assignment queue is added and a reference station apparatus. And a terminal station device.

[0002]

2. Description of the Related Art Many communication stations have finite line resources (Re
In the multiple access method in which access and communication are performed by sharing a source, it is inevitable that there is a possibility that a shortage of resources may occur temporarily.

FIG. 7 is a diagram showing a sequence in a conventional multiple access system. Reference station B and multiple terminal stations T
1,... Tn, Tn + 1, Tn + 2, showing a sequence in which a plurality of terminal stations transmit a time slot allocation request to the reference station by the demand assignment method, and the terminal stations transmit and receive transmission data by the time slot allocated by the reference station. ing. In the sequence A, data is generated in the terminal station T1, an allocation request is transmitted by random access, the allocation of the time slot of the slot number n from the reference station is received, and the transmission of the data is started.
In the sequence B, data is generated in the terminal station Tn + 1,
Similarly, an assignment request is transmitted, but a notification (NG) indicating that a time slot cannot be assigned due to the absence of an empty time slot is received from the reference station, and the assignment request is retransmitted.

As described above, when an access control method in which data slots are allocated to a plurality of terminal stations based on the conventional control of a reference station is used, in a state where there is no available data slot and the reference station cannot be allocated, FIG. As shown in sequence B, in response to the response that the reference station cannot allocate, the terminal station retransmits the allocation request at fixed intervals, and as shown in sequence C in FIG. The retransmission of the assignment is repeated until a time slot release request and a reference station release confirmation due to the end of data transmission.

[0005]

In the conventional multiple access system, an allocation request from a terminal station is transmitted by a slot Aloha (Slot Aloha).
ted Aloha) is performed by random access, etc., so retransmission of an allocation request from a terminal station caused by the elimination of empty time slots causes congestion in the allocation request area and an increase in collisions, resulting in system instability. Cause.

Therefore, as a method of avoiding congestion due to retransmission of an allocation request, a terminal station, which has been notified of non-allocation, does not immediately retransmit an allocation request but generates an empty slot from a reference station. It is also conceivable to wait until the notification is made. However, even in a system that performs such control, there is a high possibility that there are a plurality of terminal stations that have received the assignment failure notification, and such a plurality of terminal stations are notified from the reference station that an empty slot has occurred. As shown in the sequence D of FIG. 7, control is performed to simultaneously retransmit the allocation request simultaneously.
Again, congestion of the allocation request area may occur, and there is a problem that the allocation waiting time of the terminal station due to the occurrence of collision is inevitably increased.

(Object of the Invention) An object of the present invention is to provide a time-division multiple access method, a reference station apparatus, and a terminal station apparatus capable of suppressing the congestion of a time slot allocation request in a state where line resources are insufficient. Is to do.

An object of the present invention is to provide a time division multiple access method, a reference station apparatus, and a terminal station apparatus, which can realize a stable system by shortening a recovery time from a shortage of line resources. .

[0009]

A time division multiple access method according to the present invention is a time division multiple access method using a demand assignment method between one reference station and a plurality of terminal stations, wherein the reference station comprises a time slot from the terminal station. When there is no free time slot for the allocation request, the allocation request is stored in a queue and the allocation requesting terminal station is notified of the storage in the queue. A time slot is allocated to the terminal station of the allocation request stored in the terminal station, and when the terminal station is notified of the storage in the queue from the reference station after the allocation request, the terminal station does not make the same allocation request to the reference station. Features.

In the above time division multiple access method, the time slot allocation request includes a time slot increase allocation request, and the time slot allocation request is transmitted from a terminal station that has not allocated a time slot after the time slot increase allocation request. When there is a time slot allocation request, the time slot allocation request is stored in a queue prior to the increase allocation request.

The time division multiple access method is characterized in that when the number of stored queues exceeds a predetermined value, the queue for the allocation request for increasing the time slot is deleted.

A reference station apparatus according to the present invention is a reference station apparatus for controlling time-division multiplexing access of a demand assignment system for allocating time slots to a plurality of terminal station apparatuses and performing communication, wherein a time from the terminal station apparatus is controlled. When there is no vacant time slot in response to a slot allocation request, the allocation request is stored in a queue and the allocation request source terminal station device is notified of the storage in the queue, and the same allocation request is It is characterized in that retransmission is controlled to be stopped, and a time slot is allocated to a terminal station device of an allocation request stored in a queue each time a time slot becomes free.

In the reference station apparatus, the time slot allocation request includes a time slot increase allocation request, and a time from a terminal station apparatus to which no time slot has been allocated after the time slot increase allocation request. When there is a slot allocation request, the request is stored in the queue in preference to the increase allocation request. Further, when the number of stored queues exceeds a predetermined value, the queue for the allocation request for increasing the time slot is deleted.

The terminal station apparatus according to the present invention stores the allocation request in a queue when there is no empty time slot in response to the time slot allocation request from the terminal station apparatus, and places the request into the queue for the terminal station apparatus. Communication with a reference station apparatus that controls time-division multiple access of a demand assignment system that allocates a time slot to a terminal station apparatus of an allocation request stored in a queue every time a time slot becomes free. The terminal station apparatus that performs re-sending of the same allocation request in response to a time slot allocation request to the reference station apparatus and a notification of storage of the allocation request in a queue from the reference station apparatus. It is characterized in that control is performed, and the time slot allocation request includes a time slot increase allocation request.

More specifically, one reference station and a plurality of terminal stations perform data communication via a plurality of downlink lines from the reference station to the terminal station and a plurality of uplink lines from the terminal station to the reference station. In a channel radio communication system, as a multiple access method for sharing a uplink of the same frequency by a plurality of terminal stations, a time slot in which the terminal station time-divides the uplink when data to be transmitted from the terminal station to the reference station is generated. When the base station uses the demand assignment method of requesting the base station to allocate a time slot to the base station, even if all the time slots have already been allocated to any of the terminal stations, the reference station is newly assigned. Receives the time slot allocation request arriving at the terminal station and stores it in a queue, and informs the requesting terminal station that the allocation request is enqueued. By notifying to stops that the terminal station retransmits the allocation request. After any terminal station has finished using the time slot and a time slot is vacant, the reference station processes the queued allocation request and allocates a new time slot to the terminal station.

That is, when the reference station B receives a time slot allocation request from a certain terminal station Tn + 1 and there is no empty slot to be allocated, the reference station stores this request in a queue and The terminal station Tn + 1 is notified that the assignment request has been queued. As a result, the terminal station Tn + 1 does not retransmit the allocation request and waits for the notification of the slot allocation. The reference station waits for the time slot allocated to the other terminal station T1 to be released, and when an empty slot occurs, extracts the allocation request for the terminal station Tn + 1 from the queue as shown in sequence D. And a time slot is newly assigned to the terminal station T1 (FIG. 6).

(Operation) When there is no free time slot of the reference station in response to the allocation request from the terminal station, the allocation request is stored as a queue and retransmission from the terminal station is suppressed, thereby avoiding congestion of the allocation request. At the same time, a time slot is allocated to the allocation request from the reference station as soon as an empty time slot is generated, thereby reducing the allocation waiting time of the terminal station.

DETAILED DESCRIPTION OF THE INVENTION

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an embodiment of a time division multiple access system with an assignment queue, a reference station apparatus and a terminal station apparatus according to the present invention will be described.

(Explanation of Configuration) FIG. 1 is a diagram showing a configuration of a multi-channel radio communication system and a radio communication apparatus to which the time division multiple access method of the present embodiment is applied. 1
One reference station B and a plurality of terminal stations T1, T2... The reference station B includes a plurality of directional antennas, and forms a plurality of communication zones A and B covered by the respective antennas. Each terminal station belongs to one communication zone according to the geographical position, and the terminal stations belonging to the same communication zone can use the same frequency. Communication between the reference station B and the terminal station group belonging to one communication zone is performed via a plurality of downlinks from the reference station to the terminal station and a plurality of uplinks from the terminal station to the reference station. When a single uplink frequency is used by a plurality of terminal stations, a demand-assigned time division multiple access method (TDMA method) is used.

The configuration shown in FIG. 1 is a basic unit of the system, and communication between terminal stations belonging to different reference stations is possible by connecting a plurality of reference stations via a terrestrial communication network.

FIG. 2 shows a reference station B and terminal stations T1, T2.
FIG. 3 is a diagram showing a format of a wireless line signal between the wireless communication device and the wireless communication device.
FIG. 2A shows a downlink signal format transmitted from the reference station to the terminal station. The downlink signal is time-divided into frames of a fixed time length, and a frame synchronization pattern is transmitted at the beginning of each frame, thereby enabling a terminal station that receives this to perform frame synchronization. After the frame synchronization pattern, a data slot containing actual user data and control data transmitted from the reference station to the terminal station follows.

Each terminal station receives all data slots transmitted on the downlink frequency, but fetches only the data addressed to itself by identifying the destination terminal station ID added to each data. In this example, the downlink frame is divided into data slots of a fixed time length, and the data transmitted from the reference station to the terminal station has a fixed-length packet format. HD
It is also possible to take a variable-length packet format conforming to the LC format.

FIG. 2B shows an uplink signal format transmitted from the terminal station to the reference station. The uplink signal is also time-divided into frames of a fixed time length, and the time length of this frame is the same as the time length of the downlink frame. Each frame of the uplink is divided into two, an allocation request area and a data slot area. The allocation request area is composed of a time slot transmitted from the terminal station to the reference station and used only for the allocation request message.

When each terminal station sends an allocation request message to a slot in the allocation request area, the slotted Aloha system is used. The data slot area is composed of data slots containing actual user data and control data transmitted from the terminal station to the reference station. The data slot in the data slot area can be used only by the terminal station to which the slot number is assigned from the reference station. At this time, it is assumed that the terminal station to which data slot n is allocated can use data slot n of each frame. In addition, the lengths of the time slots constituting the allocation request area and the data slot area must each be a fixed time length, but the slot length of the allocation request area may be shorter than the slot length of the data slot area. .

FIG. 3 shows a reference station B according to an embodiment of the present invention.
FIG. 3 is a diagram showing an example of the configuration of FIG.

The reference station B is an IP (Internet Protocol)
I / F that controls the interface with the terrestrial communication network such as ATM and Asynchronous Transfer Mode (ATM)
A control unit 1, a packetizing unit 2 for changing data input from the protocol I / F control unit 1 into a packet format transmitted and received on a wireless line, and a router for distributing each packet to a downstream line used by a destination terminal station 3 is provided. The packetizing unit 2 also has a function of buffering data.

The reference station B includes a resource allocation control unit 4 for holding the used frequencies of the terminal stations under its control.
The resource allocation control unit 4 refers to the used frequency information of the terminal station.

The resource allocation control unit 4 manages the frequency used by the terminal station and also controls the allocation of uplink data slots requested to be allocated by the terminal station. When a terminal station requests allocation of an uplink data slot, if there is a vacancy in the data slot, the resource allocation control unit 4 immediately determines the allocation of the uplink data slot and sends an allocation notification to the corresponding terminal station. create. If all uplink data slots are allocated to one of the terminal stations and there is no free space, an allocation request from the terminal station is stored in a built-in storage unit as a queue.

The assignment notification created by the resource assignment control unit 4 takes the same packet format as the user data, and is sent out on the downlink data slot. In addition, Resource
The allocation control unit 4 also has a function of monitoring the congestion state of the downlink and the uplink, determining a frequency used by the terminal station, and notifying the terminal station of the frequency.

Next, the reference station B includes a synchronization control unit 5 serving as a reference for frame synchronization between the own station and the terminal stations under the control of the reference station B. The synchronization control unit 5 supplies a reference clock in the reference station and communicates with the terminal station. A frame synchronization signal serving as a frame synchronization reference is output. Further, the reference station B includes a multiplexing unit 6, an encoder (Encoder) 7, and a modulator (MOD) 8 for each downlink used. The multiplexing unit 6 multiplexes the data packet output from the router 3, the allocation notification output from the resource allocation control unit 4, and the frame synchronization signal output from the synchronization control unit 5 by time division multiplexing. Is Enco
It is transmitted from the radio frequency transmitting / receiving device 9 covering each communication zone via der7 and MOD8.

An uplink signal received by the radio frequency transmitting / receiving device 9 is demodulated by a demodulator (DEM) 10 provided for each uplink reception frequency, and is decoded by a decoder (Decode).
r) After being decoded in 11, it is output to the separation unit 12. Separating section 12 separates the received uplink information into a terminal station slot assignment request message and a data packet, and outputs the assignment request message to Resource assignment control section 4 and the data packet to multiplexing section 13. The multiplexing unit 13 multiplexes data packets for all uplink frequencies, and outputs the multiplexed data packets to the data reconfiguration unit 14. The data reconfiguration unit 14 restores a data packet input from the wireless line into a format processed by the terrestrial communication network, transmits the data packet to the terrestrial communication network via the protocol I / F control unit 1, and has a buffering function. Having.

The reference station B includes an external control terminal 15 for inputting registration / addition of a terminal station and for displaying the status of the system.

Next, FIG. 4 is a diagram showing an example of the configuration of a terminal station T according to an embodiment of the present invention.

The terminal station T is connected to the radio frequency transmitting / receiving
And D for demodulating the received downlink signal.
EM17 and Decode that decodes the output of DEM17
r18, and further includes a separation unit 19 for separating downlink information output from the decoder 18 into data, a frame synchronization signal, and an allocation notification. The separation unit 19
Outputs data to the data reconfiguration unit 20 and sends an allocation notification to Reso
The signal is output to the urce assignment control unit 23, and the frame synchronization signal is output to the synchronization control unit 25. The data reconfiguration unit 20 restores data received on the downlink to a format processed by the terrestrial communication network, and outputs the data to the protocol I / F control unit 21. The protocol I / F control unit 21 controls an interface with a terrestrial communication network, and is sometimes connected to a terminal in a point-to-point manner.

The terminal station T further includes a packetizing unit 22 for converting data input from the protocol I / F control unit 21 into a packet format to be transmitted and received on a wireless line and buffering the data.

Further, the terminal station T has a resource assignment control unit 23 for managing assignment of uplink data slots for data transmission to the reference station. When the transmission data is buffered in the buffer of the packetizing unit 22 and there is no or insufficient uplink data slot allocated to the own station, the Resource allocation control unit 23 transmits an allocation request message to the reference station B. Create At the same time, the resource allocation control unit 23 receives the allocation notification from the reference station B, and holds the uplink data slot number allocated to the own station.

The resource allocation control unit 23 has a function of setting a new allocated frequency to the demodulator DEM17 and the modulator MOD28 when the allocation notification from the reference station includes the allocation of a new frequency.

In the case of a terminal station to which one or more uplink data slots have already been assigned, the packetizing unit 2
The transmission data output from the resource allocation management unit 23 and the allocation request message output from the resource allocation management unit 23 are
4 and buffered in FIFO format.
On the other hand, in the case of a terminal station to which no uplink data slot has been allocated yet, a direct allocation request message is output from the resource allocation control unit 23 to the transmission control unit 26.

Further, the terminal station T includes a synchronization control unit 25. The synchronization control unit 25 synchronizes the frame with the reference station based on the frame synchronization signal separated by the separation unit 19, and synchronizes its own TDMA transmission. To establish. Next, based on the transmission synchronization established by the synchronization control unit 25, the transmission control unit 26 transmits the output of the multiplexing unit 24 to the own station uplink data slot held in the resource allocation control unit 23. If the terminal station has not yet allocated one uplink data slot, the transmission control unit 26 randomly selects an uplink allocation request area time slot, and
An assignment request message output from the source assignment control unit 23 is transmitted. The output of the transmission control unit 26 is an encoder Enc
The signal is output to the radio frequency transmitting / receiving device 16 via an order 27 and a modulator MOD 28.

(Explanation of Operation) FIG. 5 is a diagram showing a basic example of an uplink data slot allocation sequence according to the present embodiment. The example shown in FIG. 5 is assumed to start from a state in which one uplink data slot is not allocated to the terminal station T1.

First, in sequence A, transmission data is generated in the terminal station T1, and an allocation request message is transmitted from the terminal station T1 to the reference station B. The reference station B receiving this transmits an allocation notification to the terminal station T1 in order to notify the allocated uplink data slot number “1”.

Next, in the sequence B, since the transmission data of the terminal station T1 has increased and it has become necessary to add an assigned slot, the terminal station T1 transmits a slot increase assignment request (increase request) message. It is assumed that the slot increase assignment request message is transmitted not to the uplink assignment request area slot but to the data slot “1” already assigned to the terminal station T1. If there is a data slot that has not been allocated yet, the reference station B notifies the terminal station T1 of the additionally allocated data slot number “2”.

In the sequence C, since the transmission data of the terminal station T1 has been completed and the allocation of the uplink data slot is no longer necessary, a request for releasing the allocated data slot is transmitted from the terminal station T1 to the reference station B. The data slots "1" and "2" allocated to the data slot are released, and are treated as empty data slots thereafter.

FIG. 6 is a diagram showing an example of a case where control by a queue which is a feature of the present invention is added to the basic sequence shown in FIG.

Here, n-1 terminal stations from T1 to Tn-1 have already been assigned data slots "1" to "n-
Assume a state where "1" is assigned. Assuming that the maximum number of data slots that can be allocated to the terminal station in one uplink is n, at the time when the n-th terminal station Tn in the sequence A is allocated the data slot “n”, the empty data slot becomes Disappears.

At this time, assuming that transmission data is generated in the terminal station Tn + 1 in the sequence B and an allocation request message is transmitted from the terminal station Tn + 1, the resource allocation control unit 4 of the reference station transmits the terminal station Tn + One assignment request message is stored in the queue, and the terminal station Tn + 1 is notified of a pending assignment notification (Pending) indicating that the assignment request has been connected to the queue. Terminal station T notified of Pending
n + 1 waits until a data slot is allocated without retransmitting the allocation request.

When the data slot to which the terminal station T1 is allocated is released in the sequence C, an empty data slot is generated.
Retrieves and processes the allocation request of terminal station Tn + 1 from the allocation request queue and allocates a new data slot to terminal station Tn + 1, which allows terminal station Tn + 1 to start data transmission become.

When a new allocation request arrives from a terminal station at the same time that an empty data slot is generated, the base station B
The resource assignment control unit 4 processes the assignment request in the queue with priority. In this case, the newly arrived allocation request is linked to the end of the queue.

The resource allocation control unit 4 of the reference station B
Also stores in the queue an increase request from a terminal station already assigned a data slot, but if an allocation request arrives from a terminal station that has not yet been assigned a data slot, It is assumed that the assignment request is processed with priority over the first-come-first-served increase request. Further, when the number of queued allocation requests and increase requests exceeds a certain limit, allocation requests from terminal stations having no data slot allocation are not discarded, but allocation increase requests are discarded. Shall be.

The present invention is applicable not only to communication between a reference station and a terminal station to a communication system on the ground, but also to a satellite communication system via a satellite.

[0050]

According to the present invention, the retransmission of an allocation request from a terminal station is stopped by storing a time slot allocation request (increase allocation request) in a queue when there is no empty time slot. Therefore, it is possible to suppress the congestion of the allocation request in a state where the line resources are insufficient. Furthermore, even when there are no free time slots, a time slot is immediately allocated from the reference station to the allocation request stored in the queue when a free time slot occurs. The waiting time for allocating a time slot to a terminal station that has already been completed can be reduced, and the recovery time from congestion can also be reduced.

The storage in the queue at the reference station may be such that a priority is given to a time slot allocation request from a terminal station to which no time slot has been allocated, over an allocation request for time slot increase, or if the number of queues stored is large. When the predetermined value is exceeded, the queue of the allocation request for the increase of the time slot is deleted, so that the time slot allocation can be made uniform.

Therefore, in time division multiplex access in which limited line resources are allocated to a large number of communication stations, congestion due to shortage of line resources is suppressed, recovery time from a resource shortage state is reduced, and time slots are not allocated. It is possible to achieve uniformity and realize a more stable multi-channel wireless communication system.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a multi-channel wireless communication system to which a wireless communication device of the present invention is applied.

FIG. 2 is a diagram showing a format of a radio channel signal between a reference station B and terminal stations T1, T2,...

FIG. 3 is a diagram illustrating an example of a configuration of a reference station B according to an embodiment of the present invention.

FIG. 4 is a diagram illustrating an example of a configuration of a terminal station T according to an embodiment of the present invention.

FIG. 5 is a diagram showing a basic example of an uplink data slot allocation sequence according to the present embodiment.

FIG. 6 is a diagram showing an example of a case where control by a queue which is a feature of the present invention is added to the basic sequence shown in FIG. 5;

FIG. 7 is a diagram showing a sequence in a conventional multiple access scheme.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Protocol I / F control part 2, 22 Packetization part 3 Router 4, 23 Resource allocation control part 5, 25 Synchronization control part 6 Multiplexing part 7, 27 Encoder 8, 28 Modulator (MOD) 9, 16 Transmitter / receiver 10, 17 Demodulator (DEM) 11, 18 Decoder (Decoder) 12, 19 Demultiplexer 13, 24 Multiplexer 14, 20 Data reconstructor 15 External control terminal

Claims (7)

(57) [Claims] Claims: 1. A demarcation between one reference station and a plurality of terminal stations.
Time-division multiple access method using the indoor assign methodAh
hand, Uplink signal format transmitted from terminal station to reference station
The frames are time-divided into frames of a fixed time length, and each frame is
The system comprises an allocation request area and a data slot area,
The allocation request area is the allocation request area transmitted from the terminal station to the reference station.
Request timeslots only.
And the downlink signal format transmitted from the reference station to the terminal station.
Format is time-divided into frames of a fixed time length,
The frame is transmitted with a frame synchronization pattern at the beginning,
From the reference station to the terminal station after the
User and control data, including assigned notifications
Consists of data slots to be accommodated,  The reference station isThe uplink channel response to the allocation request from the terminal station
Performs allocation control of time slot and used frequency,Terminal station
fromAn assignment request message in the uplink assignment request area.
Request to send a message, already assigned to the uplink
To the assigned data slot
Send a messageTime slot increase allocation request
When there is no free time slot for
Stored in the queue and transmitted to the requesting terminal station.
And store in the queueThe downlink data slot
ThroughNotify and wait every time slot becomes available
The time for the terminal station of the allocation request stored in the
The lot is assigned, and the terminal station sends
Memory in the queueThe downlink data slot is
ThroughWhen notified, the same assignment request to the reference station
A time-division multiple access method characterized by not performing the above. 2. When a time slot allocation request is received from a terminal station to which no time slot has been allocated after a time slot increase allocation request, the reference station stores the time slot increase request in a queue prior to the time slot increase request. 2. The time division multiple access method according to claim 1, wherein: 3. The reference station, when the number of stored queues exceeds a predetermined value, waits for a time slot increase allocation request queue.
3. The time division multiple access method according to claim 1, wherein only the data is erased. 4. A time slot for a plurality of terminal stations.
Hours and minutes in the demand assignment method in which communication is performed by assigning
A reference station device for controlling split multiple access,Uplink signal transmitted from terminal station equipment to reference station equipment
The format is time-divided into frames of a fixed time length,
Each frame includes an allocation request area and a data slot area.
And the allocation request area extends from the terminal station apparatus to the reference station apparatus.
Times used only for outgoing assignment request messages
Composed of lots and transmitted from reference station equipment to terminal equipment
The downlink signal format used is a fixed length
Time-division into frames, with each frame synchronized at the beginning
Pattern is sent out and after the frame sync pattern
Transmits the assignment notification transmitted from the reference station device to the terminal station device.
Data containing user data and control data, including
Composed of lots, The reference station device is Uplink time for allocation request from terminal station
Perform allocation control of lots and operating frequencies, Terminal station equipment
From these terminal stationsAssignment required to the uplink allocation request area
Request to send a request message,
Data slots assigned to
Send assignment request messageTime slot increase
If there is no free time slot for the allocation request,
Stores the allocation request in the queue and
Queue storage for terminal equipmentThe downlink
Via data slotNotify and resend the same assignment request
Is controlled to stop the time slot
To the terminal station of the assignment request stored in the queue for each
Time slots are assigned to
Quasi station equipment. 5. When a time slot allocation request is issued from a terminal station device to which no time slot has been allocated after the time slot increase allocation request, the time slot is stored in a queue prior to the increase allocation request. The reference station device according to claim 4, wherein: 6. The reference station apparatus according to claim 4, wherein when the number of stored queues exceeds a predetermined value, only the queue for the allocation request for increasing the time slot is deleted. 7.Uplink for time slot allocation request
Performs allocation control of line time slots and operating frequencies
WithFree tie for time slot allocation request
When there is no slot, the request is stored in the queue
To notify the queue that the time slot is free.
Assignment request stored in the queue for each occurrence ofAgainstTa
Hours and minutes of the demand assignment method to assign time slots
Communicate with a reference station device that controls split multiple access
A terminal station device,Uplink signal transmitted from terminal station equipment to reference station equipment
The format is time-divided into frames of a fixed time length,
Each frame includes an allocation request area and a data slot area.
And the allocation request area extends from the terminal station apparatus to the reference station apparatus.
Times used only for outgoing assignment request messages
Composed of lots and transmitted from reference station equipment to terminal equipment
The downlink signal format used is a fixed length
Time-division into frames, with each frame synchronized at the beginning
Pattern is sent out and after the frame sync pattern
Transmits the assignment notification transmitted from the reference station device to the terminal station device.
Data containing user data and control data, including
Composed of lots, The terminal station device  To the reference station equipmentAssignment request to the uplink assignment request area
Assignment request to send a message, the uplink already
The percentage of the slot increase is assigned to the assigned data slot.
Send this request messageTime slot increase
In response to this request,Data of the downlink
Through the slotStorage of the allocation request in the queue
In response to the notification, control to stop retransmission of the same assignment request
A terminal station device characterized by performing the above.