JP2001148675A - Asymmetrical communication system and method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an asymmetrical communication system and the method for efficiently requesting a band size for incoming transmission information and efficiently transmitting the incoming transmission information. SOLUTION: This asymmetrical communication system connects one or more terminal stations to one base station. In the case that the constitution part of the base station for generating the request size value of an incoming band for incoming information transmission requested from the terminal station is provided with the constitution of allocating an incoming excess band exceeding an incoming band request size requested by the terminal station, an efficient circuit for calculating the next request band size for the next incoming transmission information considering the incoming excess band allocation as well is provided and efficient band size request for the incoming transmission information considering the past incoming band allocation size as well is performed in the terminal station.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circuit and a method for calculating a requested size of a next upstream band, and more particularly to a circuit for calculating a requested size of a next upstream band in consideration of the allocation of a surplus upstream band in asymmetric communication.

[0002]

2. Description of the Related Art At present, TDMA (Time Division Multip
le Access) In asymmetric communication by the method, there is a reservation method in which communication is performed after allocating in advance the frequency and use of time. Typical channel allocation methods in this reservation method include a fixed allocation method in which a unit is fixedly allocated to each terminal station and a unit allocation request when data to be transmitted occurs. And a request assignment method for assigning a channel based on the request assignment method.

Further, as a method of more efficiently allocating uplink transmission information to an uplink information unit by applying the above-mentioned fixed allocation method and request allocation method, there are a round robin method, a random method, a sequential reservation method, and the like. I do.

In the above-mentioned reservation system, as shown in FIG. 5 as an example, in a frame transmitted from a base station to each terminal station, a head unit is further divided so that each terminal station can be divided. The reservation information of the allocation unit is notified.

In the asymmetric communication system using the above-mentioned reservation system, there is a technique called a polling system in which a terminal requests a base station to permit transmission.

In this polling system, there is further proposed a technique for promptly granting a transmission permission in response to a transmission permission request from a plurality of terminal stations and efficiently allocating a transmission band.

[0007] For example, Japanese Patent Application Laid-Open No. 10-2 as a prior art example
According to Japanese Patent No. 42981, a method for efficiently using an upstream bandwidth by providing a polling system with a polling waiting buffer and a shared band control unit for allocating a time unit to an empty area of the minimum guaranteed polling according to the amount of polling waiting information. Is disclosed.

[0008]

However, in the system using the asymmetric communication as described above, conventionally, the amount of information determined by the terminal side and requested to the base station is calculated in the upstream band calculation circuit requested by the terminal side. Generally, the size of the uplink band allocation notified by the downlink reception information from the base station is not changed until the size is received.

For this reason, when transmitting the uplink information,
There has been a problem that the excessively allocated band cannot be used effectively, and that an extra band is used.

[0010] Therefore, in recent years, by changing the amount of information determined by the terminal side and requested to the base station until the amount of uplink band allocation notified from the base station by downlink information is received, each terminal can be more efficiently used. It is required to use the band allocated to the station.

[0011] The problems in the method disclosed in the above-mentioned prior art example will be described in more detail. The prior art example has a configuration that always grasps the bandwidth request of the uplink information to be requested next. Not. Therefore, before obtaining a response to the bandwidth allocation for the uplink transmission information from the base station, the uplink transmission for sequentially changing the bandwidth request size in consideration of the uplink surplus bandwidth allocation for the uplink information including the newly added information. It does not have a circuit for calculating the required bandwidth size of information.

[0012] Therefore, in the embodiment according to the prior art, the information determined by the terminal side and requested to the base station considers the amount of uplink band allocation notified by the uplink information from the base station and also considers the uplink surplus band allocation. While the terminal station does not sequentially update the data until it is received, the terminal station simply receives the uplink bandwidth allocation and then simply requests the bandwidth allocation of new next uplink transmission information.

As a result, not only is it impossible to request a bandwidth size for efficient uplink transmission information, but also it is not possible to transmit uplink transmission information efficiently, causing a problem that system capacity is wasted. I was

[0014] Accordingly, the present invention has been made in view of the above problem, and takes into account the past uplink bandwidth allocation size, thereby efficiently requesting a bandwidth size for uplink transmission information.
An object of the present invention is to provide an asymmetric communication system and a method for efficiently transmitting uplink transmission information.

[0015]

In order to achieve the above object, according to the present invention, there is provided an asymmetry in which a base station allocates an extra bandwidth to a required bandwidth size of uplink transmission information requested by a terminal station. A communication system, wherein the terminal station comprises:
A next requested bandwidth size calculation circuit that sequentially calculates the next requested bandwidth size to the base station immediately before completing the transmission of the uplink transmission information that satisfies the requested bandwidth size according to the allocated bandwidth size allocated by the base station. It is characterized by having.

According to a second aspect of the present invention, there is provided an asymmetric communication system in which a base station allocates a surplus bandwidth to a requested bandwidth size of uplink transmission information requested by a terminal station, wherein the terminal station is a base station. A request presence / absence signal indicating whether there is a unit allocation request, a request unit number signal indicating the number of requested units, and a continuation presence indicating whether there is a continuation of the allocation request, according to the requested bandwidth size calculated based on the uplink information transmitted to And a request size / unit number converter for transmitting a request signal, a request unit number signal, and a continuation / non-continuation signal to the base station; a request presence / absence signal transmitted by the request size / unit number converter; After receiving the number of allocation units divided at least once in the base station with respect to the number signal and the continuation presence / absence signal, the number of allocation units and the unit band previously held A multiplier for multiplying the size by the size, a down counter for subtracting the allocated bandwidth size obtained by the multiplier from the required bandwidth size, and a first adder for subtracting the unit bandwidth size from the calculation result by the down counter. Determining whether the calculation result of the first adder is equal to or less than a threshold value held in advance, and when the result is equal to or less than the threshold value, a threshold value determiner that outputs an uplink transmission completion signal; And a next requested bandwidth size calculation circuit that calculates a requested bandwidth size to be requested next, based on the untransmitted uplink information, when the input is received.
A request presence / absence signal, a required unit number signal, and a continuation presence / absence signal are specified in accordance with the required bandwidth size calculated by the next required bandwidth size calculation circuit.

According to a third aspect of the present invention, in the asymmetric communication system according to the first or second aspect, it is determined whether or not the allocation unit allocated by the base station is continuously allocated. And a time T display at the time of a continuation request for outputting the next required bandwidth size calculation circuit, wherein the next required bandwidth size calculation circuit stores a first storage for storing uplink information requested by the user, and a final write in the first storage unit. A second memory for storing the address point, a third memory for storing the last address point of the last packet of the uplink information which has been transmitted to the base station, and an uplink transmitted to the base station. And a fourth storage unit for storing the last read address point of the information. The next required band size calculation circuit is configured to continuously receive the determination result input from the time T display for the continuation. When to be the last write address points last read from the address
The bandwidth size obtained by subtracting the points is used as the required bandwidth size, and if the result of the determination inputted from the time T indicator indicates that the bandwidth is discontinuous, the final write address point , The bandwidth size obtained by subtracting the last address point of the last packet from.

According to a fourth aspect of the present invention, in the asymmetric communication system according to the third aspect, a request presence / absence signal, a required unit number signal, and a continuity presence / absence signal are transmitted to the terminal, and thereafter, are obtained by the multiplier. A second adder that accumulates all the allocated bandwidth sizes, the required bandwidth size calculated by the next required bandwidth size calculation circuit, and the untransmitted uplink information are added, and the second addition is performed based on the addition result. And a third adder for subtracting the result of the adder. The next required bandwidth size calculation circuit, if the addition result of the third adder is smaller than 0, the next required bandwidth to the base station. When the size is set to 0 and the addition result of the third adder is 0 or more, a request bandwidth size requested next to the base station is determined according to the determination result by the time T display at the time of the continuation request. Bandwidth size The features.

The invention according to claim 5 is an asymmetric communication method in which the base station allocates an extra bandwidth to the requested bandwidth size of the uplink transmission information requested by the terminal station,
The terminal station, according to the allocated bandwidth size allocated by the base station, immediately before completing the transmission of the uplink transmission information that satisfies the requested bandwidth size, successively calculates the next required bandwidth size to be requested next to the base station. It is characterized by having a band size calculation step.

The invention according to claim 6 is an asymmetric communication method in which the base station allocates an extra bandwidth to the required bandwidth size of the uplink transmission information requested by the terminal station,
The terminal station, according to the requested bandwidth size calculated based on the uplink information transmitted to the base station, a request presence / absence signal indicating presence / absence of a unit allocation request, a request unit number signal indicating the number of requested units, and a continuation of the allocation request. And a continuation presence / absence signal indicating the presence / absence of the request, a request signal / requested unit number signal and a continuation presence / absence signal are transmitted to the base station in the request size / unit number conversion step and the request size / unit number conversion step Multiplication for multiplying the number of allocation units by the unit bandwidth size held in advance after receiving the number of allocation units divided at least once in the base station for the request presence / absence signal, the required unit number signal, and the continuation presence / absence signal Process and
A subtraction step of subtracting the allocated bandwidth size obtained in the multiplication step from the required bandwidth size, a first addition step of subtracting the unit bandwidth size from the calculation result in the subtraction step, and a first addition step of It is determined whether or not the calculation result is equal to or less than a threshold value held in advance. If the calculation result is equal to or less than the threshold value, a threshold determination step of outputting an uplink transmission completion signal; And a next requested bandwidth size calculating step of calculating a requested bandwidth size to be requested next based on the uplink information, wherein the requested size / unit number conversion step includes the requested bandwidth calculated in the next requested bandwidth size calculating step. According to the size, a request presence / absence signal, a required unit number signal, and a continuation presence / absence signal are specified.

According to a seventh aspect of the present invention, in the asymmetric communication method according to the fifth or sixth aspect, it is determined whether or not allocation units allocated by the base station are continuously allocated. The next required bandwidth size calculating step further comprises a step of displaying a time T at the time of a continuation request to output the last write address in the first memory for storing the upstream information requested by the user. Time based on the point, the last address point of the last packet of the uplink information transmitted to the base station, and the last read address point of the uplink information transmitted to the base station. Subtract the last read address point from the last write address point if the result of the judgment output in the display process is considered to be continuous. The determined bandwidth size is defined as the required bandwidth size, and if it is determined that the bandwidth is discontinuous as a result of the determination output in the continuation time T display step, the last write address point to the last packet The bandwidth size obtained by subtracting the tail address point is set as a required bandwidth size.

The invention according to claim 8 is the asymmetric communication method according to claim 7, wherein the request presence / absence signal, the required unit number signal, and the continuation presence / absence signal are transmitted to the terminal, and thereafter, are obtained by the multiplier. Adding the requested bandwidth size calculated in the next requested bandwidth size calculation step and the untransmitted uplink information to the second addition step of accumulating all the allocated bandwidth sizes, and further performing the second addition based on the result of the addition; A third addition step of subtracting the result in the step, wherein the next required bandwidth size calculation step includes, when the addition result in the third addition step is smaller than 0, a required bandwidth to be subsequently requested to the base station. When the size is set to 0 and the addition result in the third addition step is 0 or more, the requested bandwidth size to be requested next to the base station is obtained according to the determination result in the time T display step at the time of the continuation request. Characterized in that the obtained requested bandwidth size.

[0023]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of an asymmetric communication system according to the present invention;

(Characteristics of the present invention) First, as a characteristic of the present invention, there is a request from a terminal station in an asymmetric communication system in which one or more terminal stations are connected to one base station. In the configuration of the base station that generates the required size value of the uplink bandwidth for uplink information transmission, the uplink bandwidth allocation exceeding the uplink bandwidth request size requested by the terminal station, that is, when having a configuration that allocates an uplink surplus bandwidth, At the terminal station,
By providing an efficient next requested bandwidth size calculation circuit for next uplink transmission information that also takes into account this uplink surplus bandwidth allocation, an efficient upstream transmission information bandwidth size request that takes into account the past uplink bandwidth allocation size is made. It is configured as follows. As a result, the terminal station can efficiently transmit the uplink transmission information.

Referring to FIG. 1, in an asymmetric communication system and method according to the present invention, in a configuration of a required size value generation unit of an upstream band possessed by a terminal station of an asymmetric communication system, an uplink surplus bandwidth allocation is considered according to the present invention. It is configured to provide an efficient next requested band size calculation circuit 4 for next uplink transmission information.

The next required bandwidth size calculation circuit 4 for the next uplink transmission information, which also takes into account this uplink surplus bandwidth allocation, receives the previously transmitted uplink transmission information UPn (t) from the terminal station to the base station. Based on the uplink bandwidth allocation size accompanying the surplus bandwidth size, a required bandwidth size RSIZ _UPn (t) for uplink transmission information to be requested next to the base station is calculated. At this time, the next required bandwidth size calculation circuit 4 calculates the required bandwidth size RSIZ _UPn (t) by considering a surplus bandwidth allocation size that will be determined in the base station.

Therefore, in the asymmetric communication system and method according to the present invention, the base station does not always require the requested size RSIZ _UPn (t) for the uplink transmission information requested by the terminal station. Even if the same uplink bandwidth size is not allocated, and a surplus bandwidth size is allocated as a result, the time during which the terminal station transmits the uplink transmission information UPn (t) is effectively used, and The required bandwidth size RSIZ _UPn (t + 1) for the uplink transmission information to be transmitted to the base station is calculated. Can be efficiently transmitted without waste.

(First Embodiment) Next, a first embodiment of an asymmetric communication system and a method thereof according to the present invention will be described in detail with reference to the drawings.

Referring to FIG. 2, the asymmetric communication system and method according to the present invention include a plurality of terminal stations T1, T2,..., Tn connected to one base station BS via a communication medium connecting them. I have.

The base station BS in FIG. 2 transmits, via a communication medium, downlink transmission information DN (t + 1) of each of the terminal stations time-division multiplexed to a plurality of terminal stations. The downlink transmission information DN (t + 1) includes the required size RSIZ _UP1 (t), RSI
, Z _UP2 (t),..., RSIZ _UPn (t) are arbitrated, and the band allocation size to each terminal station is SIZE _DN1 (t + 1), SIZ
E _DN2 (t + 1),..., SIZE _DNn (t + 1) are also included.

The base station also has a function of transferring uplink transmission information transmitted from the terminal station to another base station.

The terminal stations extract only information necessary for each terminal station from the downlink transmission information DN (t + 1) received from the base station. Each terminal station transmits downlink transmission information UP1 (t).
, UP2 (t),..., UPn (t) are transmitted to the base station.
The request including the request of _UP1 (t), RSIZ _UP2 (t),..., RSIZ _UPn (t) is transmitted. In response to this request, the base station determines the size of the uplink transmission information SIZE _DN1 (t + 1), SIZ
_{E DN2 (t + 1),} ..., arbitrates SIZE _DNn (t + 1), notifies each terminal station to the appropriate it.

Each terminal station transmits the notified uplink transmission information size SIZE _DN1 (t + 1), SIZE _DN2 (t + 1) _,.
In accordance with ISE _DNn (t + 1), upstream transmission information UP1 (t),
, UPn (t) are sequentially transmitted to the base station via the communication medium.

FIG. 3 shows the terminal station Tn in FIG.
FIG. 3 is a block diagram showing a part of the circuit configuration of FIG. FIG. 3 shows a required bandwidth size RS for uplink transmission information in the terminal station Tn.
It mainly shows a functional unit for efficiently calculating and determining IZ _UPn (t) based on the present invention.

The configuration shown in FIG. 3 includes a request size / unit number converter 401 and a time T display 4 at the time of a continuation request.
02, adder 403, adder 404, RSIZ latch circuit 405, down counter 406, multiplier 407, threshold value determiner 408, and RSIZ calculation circuit 40
9, an adder 410, and a switch 411.

The down counter 406 includes a switch 4061 and an adder 4062.

The RSIZ calculating circuit 409 includes a switch 33 and a dual port memory (DPM) 31
, A flag detector 32, a write address memory 36 at the time of a write stop, and read address memories 37 and 38 at the time of a read stop.
DLC data 34, transmission HDLC data 35, write timing signal 7, read timing signal 8
And the requested band size RSIZ to be next requested to the base station using the start read address selection signal S
Calculate _{UP n} (t). In FIG. 3, the buffer input upstream transmission information 5 and the buffer output upstream transmission information 6 in FIG.
C data 35 is used.

(Operation According to First Embodiment) The operation of the first embodiment will be described in detail with reference to the drawings. FIG. 4 is a sequence diagram showing a general operation flow of transmitting and receiving main information between the base station and the terminal station based on FIG. With reference to FIG. 4, the grounds for realizing efficient communication by the next required bandwidth size calculation circuit for the next uplink transmission information, which also takes into account the excess uplink bandwidth allocation based on the present invention, will be described.

Referring to FIG. 4, individual uplink transmission information sizes SIZE _DNn (t + 1) allocated to each terminal station by the base station.
And the size sent from the base station is SIZE _DNn (t + 1)
The downlink transmission information DN (t + 1) is time-division multiplexed and transmitted from the base station for each terminal station. In addition, each uplink transmission information size is SIZE _UP1 (t), SIZE
_UP2 (t), ..., UP1 which is SIZE _UPn (t)
(t), UP2 (t),..., UPn (t) are sequentially transmitted from the terminal station T1 to the terminal station Tn so that the uplink transmission information between the terminal stations does not collide.

When the uplink transmission information is transmitted from each terminal station, the required bandwidth size RSIZ _UP1 (t), RSIZ _UP2 (t),..., RSIZ of the next desired uplink transmission information at each terminal station.
_UPn (t) does not always have the same length in each of the n terminal stations.

For this reason, in the method in which the base station always allocates the bandwidth for transmitting uplink transmission information equally to n terminal stations, the communication medium can be transmitted without depending on whether or not each terminal station has uplink transmission information. It is inefficient because it is always assigned to each terminal station.

Therefore, in order to solve the above-mentioned problem, the base station considers the required bandwidth size RSIZ _UPN (t) of the uplink transmission information from each terminal station and considers the uplink transmission information suitable for each terminal station. Bandwidth size SIZE _DN1 (t + 1), SI
Conventionally, there is a method of increasing the utilization efficiency of a communication medium by designating ZE _DN2 (t + 1),..., SIZE _DNn (t + 1).

In this prior art 1, the required bandwidth size RSIZ _UPn (t) of the uplink transmission information desired by each terminal station is determined by the bandwidth size SIZE _DNn of the uplink transmission information suitable for each terminal station.
It is not always equal to (t + 1), and the latter bandwidth size SIZE _DNn (t + 1) is often larger.

Accordingly, as a technique for further improving the efficiency of using the communication medium when a surplus bandwidth size is allocated by the base station as described above, there is a method as described in Prior Art 2.

However, according to the prior art 2, when the base station allocates a surplus bandwidth size to the request, each terminal station transmits the required bandwidth size RSIZ of the desired uplink transmission information.
_{After requesting UPn} (t) from the base station, while receiving the bandwidth size SIZE _DNn (t + 1) of uplink transmission information suitable for each terminal station, the newly accumulated uplink transmission information is first transmitted to the terminal station. Is transmitted to the communication medium continuously with transmission of the desired uplink transmission information.

Therefore, in the operation according to the general method as described above, the required bandwidth size RSIZ _UPn (t + 2) of the uplink transmission information desired by each terminal station is previously transmitted with the surplus bandwidth size. It must be calculated and requested in consideration of the transmission amount of new uplink transmission information.

Therefore, the present invention provides this new calculation circuit,
That is, a circuit for calculating the requested size of the next upstream band in consideration of the excess upstream band allocation is realized in the asymmetric communication system and the method thereof.

(Conventional Operation) Here, an outline of the operation according to the prior art will be described with reference to FIG. Referring to FIG.
The terminal station Tn uses the request size / unit number converter 401 to determine whether or not the request is made R1, the number of requested units R2, and whether or not to continue R3.
Are transmitted to the base station.

The base station receiving these three types of signals,
The number mi of allocated units is calculated from these requests, and the calculation result is transmitted to the terminal station. When the terminal station receives the number mi of allocated units transmitted from the base station, the terminal station
07, the received allocation unit mi is multiplied by the previously received unit band size B, and based on the multiplication result, the i-th allocated band size ai is obtained.

Therefore, every time the i-th bandwidth size ai is allocated, the down counter 406 subtracts the required bandwidth size RSIZ of the initial uplink transmission information by this bandwidth size ai.

When i = 1, the switch 4061 is connected to the RSIZ latch circuit 405 side, and the initial value RS
The IZ is taken into the down counter 406. Where i
When> 1, the switch 4061 is connected to the side other than the RSIZ latch circuit 405 side, whereby the band size a assigned to the i-th time from the acquired initial value RSIZ is set.
The subtraction of i is repeated.

On the other hand, the subtraction result repeated by the down counter 406 is the required size / unit size number converter 4
01, and is used to sequentially and sequentially request the remaining size less than the required bandwidth size RSIZ of the initial uplink transmission information.

The subtraction result repeated by the down counter 406 is input to the adder 410 on the other side.
This is compared with the unit band size B. As a result of this comparison, when the subtraction result is smaller than the unit band size, that is, when the output of the threshold value judgment unit 408 indicates minus, the uplink transmission completion signal F is output as valid.

The validity of the upstream transmission completion signal F is determined by setting the switch 4061 in the down counter 406 to RSIZ
It works by connecting to the latch circuit 405 side, and RSIZ
An operation of taking the required bandwidth size of newly desired uplink transmission information from the calculation circuit 409 into the down counter 406 as an initial value is caused to function.

Therefore, according to the present invention, when the sum of the allocated bandwidth sizes ai up to the i-th time becomes larger than the requested bandwidth size RSIZ of the uplink transmission information initially requested due to the surplus allocation size, the next requested uplink transmission information This operation is always realized by the circuit for calculating the requested size of the next uplink band in consideration of the surplus uplink band allocation based on the present invention, that is, the RSIZ calculation circuit 409 in FIG.

(Operation of the Present Invention) Based on the above operation summary, the operation of the next upstream band size calculation circuit in consideration of the surplus upstream band allocation according to the first embodiment of the present invention will be described.
The transmission symmetric data will be concretely described as HDLC.

In FIG. 3, the circuit for calculating the next uplink bandwidth request size in consideration of the surplus uplink bandwidth allocation according to the present invention is composed of R
This is applied to the SIZ calculation circuit 409.

In FIG. 3, two outputs from the RSIZ calculation circuit 409 according to the present invention are the sum of the i-th allocated band size ai, that is, the output of the adder 404,
After determining the required size RSIZ of the upstream transmission information and the required band size RSIZ of the upstream transmission information, three data sizes N of a plurality or a single input HDLC data 34 to be written into the DPM 31 following the required size are input. Switch 411 that operates on the output result of adder 403
Is used to select one of them.

That is, when the output of the adder 403 is smaller than 0, it means that the required bandwidth size RSIZ of the requested uplink transmission information is not substantially in the DPM 31, so that RSIZ = 0.

When the output of the adder 403 is 0 or more, the required band size RSIZ of the next uplink transmission information is
Last write address pointer ADRm on PM31
From ADRinside indicating the address of the last flag of the packet read last on the DPM 31.

The last write address pointer AD
Rm is stored in the write address storage 36 at the time of write stop. ADRinside is the sending H
When the read timing signal 8 indicating the period for sending the DLC data 35 becomes invalid, that is, until the read stop time, this flag is set to the DPM 31 based on the position of the flag detected last by the flag detector 32. The above address is calculated backward, and this address is used as the read address on the DPM 31 where the last flag of the last packet that was sent out while the read timing signal 8 was valid was located at the time of read stop. It is stored in the read address storage 38.

Similarly, ADRlast sends the HDL
When the read timing signal 8 indicating the period during which the C data 35 is transmitted becomes invalid, that is, at the time of the read stop, the DPM3 of the packet whose transmission has been completed last is completed.
1 is stored in the read address storage 37 at the time of read stop as the upper read address.

The RSIZ calculation circuit 409 described above is
These are summarized below.

That is, the input HD written in the DPM 31
Two outputs from the RSIZ calculating circuit 409 are selected depending on the following A and B as the states of the LC data 34.

First, A is a case where the uplink information band size SIZE notified from the base station is allocated to be equal to or less than the data amount of all the input HDLC data 34 written in the DPM 31. B is a case where the uplink information band size SIZE notified from the base station is assigned to exceed the data amount of all the input HDLC data 34 written in the DPM 31.

The determination of the cases A and B can be realized by the following equation.

That is, the required bandwidth size RS of the upstream transmission information
After determining the IZ, assuming that the data size of a plurality or single input HDLC data 34 written to the DPM 31 subsequent to the requested size is N, here, the required allocated bandwidth RSIZ of the upstream transmission information is added to the total allocated bandwidth. In order to determine that the size is larger than the required size of one uplink bandwidth allocation, the i-th allocation size is ai allocation size, the cumulative size of the upstream bandwidth size allocated k times in total, and the requested size Judgment can be made by using the following [Equation 1], which is the difference from RSIZ.

[0068]

(Equation 1)

Here, in the case of A, that is, when the uplink information band size SIZE notified from the base station is allocated to be equal to or less than the data amount of all the input HDLC data 34 written in the DPM 31, 1] is as follows.

[0070]

(Equation 2)

In the case of B, that is, when the uplink information band size SIZE notified from the base station is allocated so as to exceed the data amount of all the input HDLC data 34 written in the DPM 31, [Equation 1] becomes It looks like this:

[0072]

(Equation 3)

Therefore, as can be seen from these calculation expressions (Equation 1, Expression 2, and Expression 3), the switch 411 operating on the output result of the adder 403 selects one of the two outputs of the RSIZ calculation circuit 409. Is done.

Considering the results obtained as described above, as shown in FIG. 3, the base station determines the bandwidth request size RSIZ _UPn (t + 2) of the uplink transmission information requested by the terminal station to the base station. When the upstream transmission information band SIZE _DNn (t + 3) is allocated as the upstream band size, UPn (t +
It can be seen that the base station side can continuously receive the end of the data transmitted upstream in 2) and the beginning of the data transmitted upstream in UPn (t + 4).

However, in response to the new uplink transmission information band request RSIZ _UPn (t + 2) to the base station, the following uplink transmission information band SIZE _DNn (t + 1) that is currently allocated from the base station is not transmitted. Uplink transmission information bandwidth size SIZE _DNn (t + 5):
(Uplink bandwidth size from the base station to RSIZ _UPn (t + 2)) is allocated, the end of the data transmitted upstream in UPn (t + 2) and the upstream in UPn (t + 6). The head of the data to be transmitted cannot be continuously received by the base station.

This is because it is another terminal station that can receive the allocation SIZE _DNn (t + 3) of the upstream transmission information bandwidth size at this timing and transmit data upstream.

As described above, immediately after the bandwidth request for the new uplink transmission information to the base station is made, if the next downlink transmission information has its own uplink allocation bandwidth size, the continuous transmission to the last transmitted data is performed. Then, the transmitted HDLC data 35 on the DPM 31 may be read out from ADRlast. However, if the next downlink transmission information does not have its own uplink allocation bandwidth size, the transmitted HDLC data 35 on the DPM 31 is read out from ADRlast. Even if the base station reads out the data, the base station cannot receive it as data continuous with the data received recently, so it is necessary to read out from ADR inside on the DPM 31.

It is the time T indicator 402 at the time of a continuation request that determines the presence or absence of the continuity. When the assignment for the request is made within time T, ie, immediately, the switch 33
To the ADRlast side and read out to ADRla
Start from st.

As described above, even if the excess surplus allocation occurs, the two address pointers ADR on the DPM 31
By using last and ADRinside properly, the required bandwidth size for the next upstream transmission information to be requested can be set to ADRm-ADR
By always calculating inside, the size of the uplink information transmitted with the surplus bandwidth size is considered, and the uplink transmission information can be efficiently transmitted without waste.

Therefore, as described above, by using the circuit for calculating the next uplink bandwidth request size in consideration of the excess uplink bandwidth allocation used in the present invention, the bandwidth allocation request for transmitting the uplink transmission information and the request The transmission of the upstream transmission information in accordance with the request for abandonment of the upstream transmission information obtained as a result of the above can be efficiently performed in consideration of the size of the upstream information transmitted with the surplus bandwidth size. That is, while the uplink transmission information is being transmitted, the amount of information to be transmitted next to the base station can be efficiently determined by using the next uplink bandwidth request size calculation circuit in consideration of the excess uplink bandwidth allocation.

(Second Embodiment) A second embodiment of the present invention will be described below in detail with reference to the drawings. Book second
In the second embodiment, the basic configuration is the same as that of the first embodiment, but the uplink transmission standby buffer memory, that is, the control method of the DPM 31 shown in FIG. The configuration is such that a further effect can be obtained by configuring so as to appropriately respond to the above. Therefore, since the basic configuration is the same as that of the first embodiment,
The second embodiment will be described with reference to FIG.

In the first embodiment, the upstream transmission band buffer unit 3 in FIG. 1 is included in the next required band size calculation circuit 4 for the next upstream transmission information that also takes into account the allocation of the surplus upstream band transmitted from the base station. It is controlled by the address management function of the buffer unit. That is, when the terminal station receives the uplink bandwidth allocation from the base station for the requested bandwidth size RSIZ _UPn (t) for the uplink transmission information, the terminal uses the read timing signal 8 to read data corresponding to the uplink bandwidth allocation size.・ Read up to the address from the buffer.

Therefore, the read address memory 37 at the time of the read stop always stores, as ADRlast, an address corresponding to the upstream transmission information band size SIZE _DNn (t-1) that has been permitted immediately before. Therefore, when there is a request for retransmission of uplink transmission information from the base station side, there is an advantage that the same uplink transmission information can be easily retransmitted.

This is because when the terminal receives the retransmission request from the base station by the status notification included in the downlink reception information DN (t), the configuration according to the first embodiment is used as it is, The next required bandwidth size calculation circuit 4 for the next upstream transmission information, which also takes into account the above, makes it possible to easily and efficiently retransmit past upstream transmission information from the upstream transmission band buffer unit 3. .

[0085]

As described above, according to the first embodiment of the asymmetric communication system and the method thereof according to the present invention, by using the circuit for calculating the next uplink bandwidth request size in consideration of the uplink surplus bandwidth allocation. A request for a bandwidth allocation for transmitting upstream transmission information, a request for transmission of upstream transmission information in accordance with a bandwidth request of the obtained upstream transmission information, and a size of upstream information transmitted in a surplus bandwidth size. It is possible to provide an asymmetric communication system and a method thereof that can be implemented efficiently while taking into account the above.

That is, while transmitting the upstream transmission information, the amount of the next upstream transmission information is efficiently determined by using the calculation circuit of the next upstream band request size in consideration of the uplink surplus bandwidth allocation. This is because it becomes possible.

Further, according to the second embodiment of the asymmetric communication system and the method thereof according to the present invention, in the configuration of the first embodiment, it always matches the bandwidth size of the upstream transmission information previously permitted. Since the stored address is stored, the same uplink transmission information can be easily and immediately retransmitted in response to a retransmission request from the base station.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a requested size value generation unit for an uplink band of a terminal station according to the present invention.

FIG. 2 is a block diagram showing a configuration of asymmetric communication according to the present invention.

FIG. 3 is a block diagram showing a part of a circuit configuration of a terminal station Tn according to the present invention.

FIG. 4 is a sequence diagram showing a general operation flow of transmission and reception of main information between a base station and a terminal station based on FIG. 2;

FIG. 5 is a diagram showing a configuration of a frame transmitted from a base station according to the related art.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 transfer data amount controller 2 memory 3 upstream transmission band buffer unit 4 next required band size calculation circuit for next transmission information in consideration of uplink surplus band allocation 5, 6 buffer input upstream transmission information 7 write timing signal 8 read timing Signal 31 Dual port memory (DPM) 32 Flag detector 33, 411, 4061 Switch 34 Input HDLC data 35 Sending HDLC data 36 Write address storage at write stop 37, 38 Read address at read stop Storage unit 401 Request size / unit size number converter 402 Time T display at continuation request 403 to 404, 410, 4062 Adder 405 RSIZ latch circuit 406 Down counter 407 Multiplier 408 Threshold decision unit 409 RSIZ calculation circuit AD m, ADRlast, ADRinside address pointer ai bandwidth allocation size BS base station B unit band size DN (t) downlink transmission information F uplink transmission completion signal RSIZ _UPn (t) required bandwidth size R1 requests presence R2 requesting unit number R3 continued presence S Start read address selection signal SIZE (t) Bandwidth allocation size T1 to Tn Terminal UPn (t) Up information

Claims (8)

[Claims] 1. An asymmetric communication system in which a base station allocates a surplus bandwidth to a requested bandwidth size of uplink transmission information requested by a terminal station, wherein the terminal station has an allocated bandwidth allocated by the base station. According to the size,
An asymmetric communication system comprising a next requested band size calculating circuit for calculating a requested band size to be sequentially requested to the base station immediately before completing transmission of uplink transmission information satisfying the requested band size. . 2. An asymmetric communication system in which a base station allocates an extra bandwidth to a requested bandwidth size of uplink transmission information requested by a terminal station, wherein the terminal station transmits uplink information to be transmitted to the base station. According to the requested bandwidth size calculated based on the request, the presence or absence of a request for presence or absence of a unit allocation request, the required number of units that is the number of units requested, and a continuation presence or absence signal that indicates whether or not the allocation request is continued, A request size / unit number converter for transmitting the request signal, the request unit number signal, and the continuation presence / absence signal to the base station; and the request presence / absence signal transmitted by the request size / unit number converter, After receiving the number of allocation units divided at least once in the base station for the request unit number signal and the continuation presence / absence signal, the number of allocation units and A multiplier for multiplying the unit bandwidth size held in advance; a down counter for subtracting the allocated bandwidth size obtained by the multiplier from the required bandwidth size; and A first adder for subtracting the band size; determining whether a calculation result of the first adder is equal to or less than a threshold value held in advance;
A threshold determiner that outputs an uplink transmission completion signal; and, when the uplink transmission completion signal is input, a next requested bandwidth size calculation circuit that calculates a requested bandwidth size to be requested next based on untransmitted uplink information. The request size / unit number converter specifies the request presence / absence signal, the request unit number signal, and the continuation presence / absence signal in accordance with the required bandwidth size calculated by the next required bandwidth size calculation circuit. An asymmetric communication system, comprising: 3. A time T indicator at the time of a continuation request, which determines whether or not the allocation units allocated by the base station are continuously allocated, and outputs a result of the determination, The requested bandwidth size calculation circuit includes: a first storage unit that stores uplink information requested by a user; a second storage unit that stores a final write address point in the first storage unit; A third storage unit that stores the last address point of the last packet of the uplink information that has been transmitted to the station, and a fourth storage unit that stores the final read address point of the uplink information that has been transmitted to the base station. The next required band size calculation circuit, when the result of the determination input from the continuation time T display is determined to be continuous, the Light The bandwidth size obtained by subtracting the final read address point from the address point is defined as the required bandwidth size, and the result of the determination input from the time T indicator during the continuation indicates discontinuity. If so, the requested bandwidth size is obtained by subtracting the last address point of the last packet from the last write address point. 3. The asymmetric communication system according to 1 or 2. 4. After transmitting the request presence / absence signal, the request unit number signal, and the continuation presence / absence signal to the terminal,
A second adder for accumulating all the allocated bandwidth sizes obtained by the multiplier, and adding the requested bandwidth size calculated by the next required bandwidth size calculation circuit to the untransmitted uplink information. ,
A third adder for subtracting the result of the second adder from the result of the addition; and the next required band size calculation circuit, wherein the addition result of the third adder is If it is smaller than 0, the requested bandwidth size to be requested next to the base station is set to 0, and if the addition result of the third adder is 0 or more, the requested bandwidth size to be requested next to the base station is: 4. The asymmetric communication system according to claim 3, wherein the requested bandwidth size is obtained in accordance with a result determined by a time T display at the time of the continuation request. 5. An asymmetric communication method in which a base station allocates an extra bandwidth to a requested bandwidth size of uplink transmission information requested by a terminal station, wherein the terminal station allocates an allocated bandwidth from the base station. According to the size,
Immediately before completing transmission of uplink transmission information that satisfies the requested bandwidth size, comprising a next required bandwidth size calculation step of sequentially calculating a required bandwidth size to be requested of the base station. . 6. An asymmetric communication method in which a base station allocates an extra bandwidth to a requested bandwidth size of uplink transmission information requested by a terminal station, wherein the terminal station transmits uplink information to be transmitted to the base station. According to the requested bandwidth size calculated based on the request, the presence or absence of a request for presence or absence of a unit allocation request, the required number of units that is the number of units requested, and a continuation presence or absence signal that indicates whether or not the allocation request is continued, A request size / unit number conversion step of transmitting the request signal, the request unit number signal and the continuation presence / absence signal to the base station; and the request presence / absence signal transmitted in the request size / unit number conversion step, After receiving the number of allocation units divided at least once in the base station in response to the request unit number signal and the continuation presence / absence signal, And a multiplication step of multiplying by a unit bandwidth size held in advance, a subtraction step of subtracting the allocated bandwidth size obtained in the multiplication step from the required bandwidth size, and a calculation result in the subtraction step. A first addition step of subtracting the unit band size, and it is determined whether or not the calculation result in the first addition step is equal to or less than a threshold value held in advance. A threshold determination step of outputting an uplink transmission completion signal; and a next requested bandwidth size calculation step of calculating a next requested bandwidth size based on untransmitted uplink information when the uplink transmission completion signal is input. In the request size / unit number conversion step, the request presence / absence signal, the request unit number signal, and the request number signal are calculated according to the request band size calculated in the next request band size calculation step. Asymmetric communication method characterized by identifying a continuous existence signal. 7. A time T display step at the time of a continuation request for determining whether or not the allocation units allocated by the base station are continuously allocated, and outputting a result of the determination, The requested bandwidth size calculating step includes: a last write address point in the first storage for storing the uplink information requested by the stored user; and a final packet of the uplink information transmitted to the base station. Based on the last address point and the last read address point of the uplink information transmitted to the base station, the result of the determination output in the continuation time T display step is continuously If it is determined that there is a request, the bandwidth size obtained by subtracting the final read address point from the final write address point If the result of the determination output in the time T display step during continuation is discontinuous, the last address point of the last packet from the last write address point 7. The asymmetric communication method according to claim 5, wherein a bandwidth size obtained by subtracting the above is set as a required bandwidth size. 8. After transmitting the request presence / absence signal, the request unit number signal, and the continuation presence / absence signal to the terminal,
A second adding step of accumulating all the allocated bandwidth sizes obtained by the multiplier, and adding the requested bandwidth size calculated in the next requested bandwidth size calculating step and the untransmitted uplink information. And a third addition step of subtracting the result of the second addition step from the result of the addition, wherein the next required bandwidth size calculation step includes the addition result in the third addition step. Is smaller than 0, the requested bandwidth size to be requested next to the base station is set to 0, and if the addition result in the third addition step is 0 or more, the requested bandwidth size to be requested next to the base station is set to ,
8. The asymmetric communication method according to claim 7, wherein the requested bandwidth size is determined according to a result of the determination in the time T displaying step at the time of the continuation request.