KR100953630B1 - Method for operating a physical channel for data rate - Google Patents

Abstract

The present invention includes the steps of using a second physical channel to transmit the data rate of transmission of the data to the base station when transmitting data through the first physical channel from the terminal to the base station; The present invention relates to a physical channel for transmitting a data rate and a method of operating the same, comprising transmitting the transmission data rate to a base station during a minimum basic transmission unit time of the basic transmission unit time of the second physical channel. Since the transmission data rate of the R-PDCH being used is considered to be the fastest data rate among the possible transmission data rates, there is no need to operate. Therefore, almost all terminals transmit data using the fastest data rate at one time. Therefore, it is possible to build hardware using storage memory less than L * J.

Transfer data rate transfer

Description

Method for operating a physical channel for data rate

1 is a view for explaining a physical channel operating method for transmission data rate transmission according to the prior art

2 is a diagram illustrating a transmission chain of a physical channel for transmitting data rate transmission according to a first embodiment of the present invention.

3 is a diagram illustrating a transmission chain of a physical channel for transmitting data rate transmission according to a second embodiment of the present invention.

4 is a diagram illustrating a transmission chain of a physical channel for transmitting data rate transmission according to a third embodiment of the present invention.

5 is a view for explaining an example of the information bit transmission method in the physical channel for transmission data rate transmission according to the present invention.

FIG. 6 is a view for explaining a transmission time point between a transmitting end and a receiving end in an information bit transmission method in a physical channel for transmitting a data rate according to a first embodiment of the present invention.

7 to 20 are diagrams for explaining a physical channel operating method for transmission data rate transmission according to the first to fourteenth embodiments of the present invention for the information bit transmission method shown in FIG.                 

FIG. 21 is a diagram illustrating a transmission time point between a transmitting end and a receiving end in the method for transmitting information bits in a physical channel for transmitting a data rate according to a second embodiment of the present invention.

22 to 24 are diagrams for explaining a physical channel operating method for transmission data rate transmission according to the first to third embodiments of the present invention for the information bit transmission method shown in FIG.

* Description of the symbols for the main parts of the drawings *

10,11,12: encoder 20,21,22: thermal repeater

30,31,32: Signal Mapper 40,41,42: Channel Gain

50,51,52: Modulator

The present invention relates to a physical channel for transmitting a transmission data rate, and when transmitting data using a physical channel, for transmitting a transmission data rate for providing an efficient operation method of another physical channel for transmitting the transmission data rate of the data. It relates to a method of operating a physical channel.

In wired and wireless communication systems, it is often necessary to additionally use another physical channel to transmit information on a data rate of data when transmitting data using a certain physical channel.

For example, when A transmits some data to B, it may not necessarily use a specific transmission data rate as needed. In such a case, there is a lot of difficulty in receiving exactly the transmitted data if B does not know exactly at what data rate the received data was transmitted. Thus, A needs to additionally use another physical channel to inform information about the data rate of data being transmitted.

Hereinafter, a physical channel for transmitting a data rate and an operation method thereof according to the prior art will be described with reference to the accompanying drawings.

1 is a diagram illustrating a physical channel for transmission data rate transmission and a method of operating the same according to the related art.

In FIG. 1, the following assumptions are used for convenience of description.

A is a terminal (or something similar) and B is a base station (or something similar).

Reverse Packet Data Channel (R-PDCH) is a physical channel used by a terminal to transmit data to a base station. The R-PDCH refers to a channel that is difficult for the base station to accurately know the transmission data rate of data transmitted through the channel.

Reverse Rate Indicator Channel (R-RICH) is a physical channel used by a mobile station to transmit information related to the transmission of an R-PDCH to a base station. The information includes a transmission data rate of data transmitted on the R-PDCH. Collective channel is called.

The Forward Rate Control Channel (F-RCCH) is a physical channel transmitted by the base station to the terminal in connection with the transmission of the R-PDCH, and refers to a channel including information for controlling the transmission data rate of the R-PDCH. That is, when the terminal determines the transmission data rate to use when transmitting the R-PDCH, it determines with reference to the information transmitted through the F-RCCH.

There is no transmission time delay between the base station and the terminal.

x is the time in the basic transmission unit of R-RICH, R-PDCH, F-RCCH. That is, the R-RICH, R-PDCH, and F-RCCH start transmission at a time corresponding to a multiple of this unit.

y is any value that can be divided evenly into x.

Referring to the principle of operation of Figure 1 based on the above assumptions are as follows.

The base station transmits the F-RCCH during the t + t time interval from t.

The terminal interprets the received F-RCCH during t + 4 to t + 8 time intervals, and transmits to the next time interval t + 8 to t + 12 with reference to the interpretation. -Determine the transmission data rate of PDCH.

Thereafter, the terminal transmits the R-PDCH and the R-RICH to the base station for the same time interval t + 8 to t + 12. That is, the information on the R-RICH transmitted during the time interval t + 8 to t + 12 includes the transmission data rate of the R-PDCH transmitted during the time interval t + 8 to t + 12.

However, in this conventional technology, T, which is the time when the base station finally receives all one R-RICH, cannot know the transmission data rate of the R-PDCH after interpreting the information of the R-RICH only after t + 12. Will be. Therefore, the base station considers and transmits the transmission data rate of the R-PDCH as the fastest data rate among the possible transmission data rates during the time intervals t + 8 and t + 12 that are receiving the R-PDCH. However, in general, as the transmission data rate is faster, the complexity of hardware required for the number of storage memories required for processing the same increases. Therefore, if the base station should always consider and operate the transmission data rate of the R-PDCH being received as the fastest data rate among the possible transmission data rates, the maximum number of R-PDCHs of terminals that the base station can simultaneously receive is L and When the storage memory size required to process data received at the fastest data rate is J, the base station should basically have as much storage memory as L * J.

Therefore, as L (the maximum number of R-PDCHs of a terminal that a base station can simultaneously receive) increases, the base station needs too much storage memory, thereby increasing hardware complexity and hardware manufacturing cost.

An object of the present invention is to reduce the hardware complexity of a receiver receiving a corresponding physical channel by efficiently designing another physical channel for transmitting the data rate of the data when transmitting data using the physical channel. It is to provide a method of operating a physical channel for data rate transmission.

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In accordance with an aspect of the present invention, there is provided a method of operating a physical channel for transmitting a data rate, in order to transmit a data rate of the data to a base station when transmitting data through a first physical channel from a terminal to a base station. Using a second physical channel; And transmitting the transmission data rate to the base station during the minimum basic transmission unit time of the basic transmission unit time of the second physical channel.
Preferably, the transmitting step is to repeatedly transmit the transmission data rate transmitted during the minimum basic transmission unit time until the basic transmission unit time.
Also, the minimum basic transmission unit time is a time divided evenly by the basic transmission unit time.
In the transmitting step, the transmission data rate is transmitted for one of two times, three times, or four times the minimum basic transmission unit time.
In this case, the transmission time is a continuous or discontinuous time within the basic transmission unit time when transmitting for the double or triple times.
In addition, the first physical channel is a Reverse Packet Data Channel, and the second physical channel is a Reverse Rate Indicator Channel.
Also, the base station determines a data rate for processing data received from the terminal through the first physical channel according to the transmission data rate transmitted during the minimum basic transmission unit time.
In addition, the method of operating a physical channel for transmission data rate transmission according to the present invention, when transmitting data through a reverse packet data channel (R-PDCH) from the terminal to the base station, transmission of the data Using a Reverse Rate Indicator Channel (R-RICH) to transmit a data rate to the base station; And transmitting the transmission data rate to the base station in multiples of the minimum basic transmission unit time of the R-RICH 'basic transmission unit time.
In this case, the drainage is any one of one, two, three.
In this case, the multiples and triples are points that are continuous in the minimum basic transmission unit time.
In addition, according to the present invention, a method of operating a physical channel for transmitting data rate transmission includes a reverse packet data channel (F-RCCH) during a basic transmission unit time of a forward rate control channel (F-RCCH) from a base station to a terminal. Transmitting a signal for controlling a transmission data rate of a reverse packet data channel (hereinafter, 'R-PDCH'); Determining the transmission data rate during the basic transmission unit time of the F-RCCH according to the control signal received at the base station; And repeatedly transmitting the determined transmission data rate to the base station for the basic transmission unit time at the minimum basic transmission unit time.
Hereinafter, a physical channel for transmission data rate transmission and an operation method thereof according to the present invention will be described with reference to the accompanying drawings.

2 is a diagram illustrating a transmission chain of a physical channel for transmission data rate transmission according to the first embodiment of the present invention, and FIG. 3 is a diagram of a transmission chain of the physical channel for transmission data rate transmission according to the second embodiment of the present invention. 4 is a diagram for explaining a transmission chain of a physical channel for transmitting data rate transmission according to the third embodiment of the present invention, and FIG. 5 is a diagram for a physical channel for transmitting data rate transmission according to the present invention. A diagram for describing an example of an information bit transmission method.

First, in the present invention, when the transmitting side is called A, and the receiving side is called B, when A transmits certain data to B through a specific physical channel, another physical channel transferring the transmission data rate of the data is described. It transmits a certain time ahead of a specific physical channel.

The assumptions used to describe the invention below are as follows.

When A transmits some data to B, B uses a physical channel that is difficult to know exactly the transmission data rate of the data being transmitted. Then, A additionally uses another physical channel to inform information about the transmission data rate of the data being transmitted.

A is a terminal (or something similar) and B is a base station (or something similar).

Reverse Packet Data Channel (R-PDCH) is a physical channel used by a terminal to transmit data to a base station. The R-PDCH refers to a channel for which the base station does not know exactly the transmission data rate of data transmitted through the channel.

Reverse Rate Indicator Channel (R-RICH) is a physical channel used by a mobile station to transmit information related to the transmission of an R-PDCH to a base station. The information includes a transmission data rate of data transmitted on the R-PDCH. Collective channel is called.

The Forward Rate Control Channel (F-RCCH) is a physical channel transmitted by the base station to the terminal in connection with the transmission of the R-PDCH, and refers to a channel including information for controlling the transmission data rate of the R-PDCH. That is, when the terminal determines the transmission data rate to use when transmitting the R-PDCH, it determines with reference to the information transmitted through the F-RCCH.

There is no transmission time delay between the base station and the terminal (However, no problem occurs even if the present invention is applied to the actual situation where the transmission time delay exists).

x is time of basic transmission unit of R-PDCH, F-RCCH. That is, the R-PDCH and the F-RCCH start transmission at a time corresponding to a multiple of this unit.

y is the time of the minimum basic transmission unit of the R-RICH. That is, the time of the basic transmission unit of R-RICH is y or a multiple of y. For example, if y is 5, the time of the basic transmission unit of the R-RICH may be any one of 5, 10, 15, 20, and the like, which is a multiple of five. At this time, the R-RICH starts transmission at a time corresponding to a multiple of the time of the basic transmission unit.

x is 20 m seconds and y is 5 m seconds. That is, the time of the basic transmission unit of the R-PDCH, F-RCCH is 20 msec, the R-PDCH, F-RCCH starts transmission at a time corresponding to a multiple of 20 m seconds. In addition, the time of the basic transmission unit of the R-RICH may be any one of multiples of five. If the time of the basic transmission unit of the R-RICH is 5m seconds, the R-RICH starts transmission at a time corresponding to a multiple of 5m seconds. And, if the time of the basic transmission unit of the R-RICH is 10m seconds, the R-RICH starts transmission at a time corresponding to a multiple of 10m seconds.

An efficient structure and operation scheme of R-RICH (physical channel for transmitting data rate) according to the present invention are as follows.

According to the above assumption, when the time of the basic transmission unit of the R-PDCH and the F-RCCH is 20 m seconds, the time of the basic transmission unit of the R-RICH is 5 m seconds or 10 m seconds. In this case, it is assumed that the information bits to be transmitted through the R-RICH consist of 6 bits. 2 is an exemplary structure diagram of an R-RICH having a time of a basic transmission unit of 5m seconds. 3 is an exemplary structure diagram of an R-RICH having a time of a basic transmission unit of 10m seconds. 4 illustrates another structure of the R-RICH in which the time of a basic transmission unit is 10m seconds. The important features of R-RICH presented here are as follows.

The time of the basic transmission unit of R-RICH is shorter than the time of the basic transmission unit of R-PDCH and F-RCCH.

The structure of the R-RICH is a structure that enables the receiving end to simply receive n received R-RICHs if the same information bit is repeatedly transmitted n times through the R-RICH.

FIG. 5 is a diagram illustrating a case where a basic transmission unit of R-RICH has a time of 10m seconds and transmits the same information bit through three consecutive R-RICHs. In FIG. 5, R-RICH (i, j) Denotes R-RICH delivering the i-th information bit j-th repeatedly. That is, R-RICH (k, 1) R-RICH (k, 2) R-RICH (k, 3) means R-RICH which sends the same information bit three times in succession.

The principle of operation of each part of FIGS. 2, 3 and 4 is as follows.

The (m, n) encoder blocks 10, 11, and 12 are code units for outputting a code word consisting of m bits to an input consisting of n bits, for example, an encoder generating an orthogonal code, or both. Or an encoder that generates a Bi-orthogonal code.

The column repeater blocks 20, 21, and 22 repeat the m-bit codewords output from the (m, n) encoder blocks 10, 11, and 12 a predetermined number of times. For example, when the codewords output from the (m, n) encoder blocks 10, 11, 12 are {A, B, C, D}, and the predetermined number of repetitions is twice, the column repeater blocks 20, 21 The output of (22) is {A, B, C, D, A, B, C, D}.

The signal mapper blocks 30, 31, and 32 serve to convert the input signals into specific symbols according to predetermined rules.

는 신호 매핑기의 출력을 확산(spreading) 시키기 위하여 사용하는 왈쉬 코드(Walsh code)를 의미한다.

Denotes a Walsh code used to spread the output of the signal mapper.

The length of the Walsh code is determined based on the output speed of the signal mapper blocks 30, 31, and 32, and the degree of spreading. It is assumed here that the Walsh code used is the ath code of the Walsh code having a length of 64. The channel gain blocks 40, 41, and 42 are blocks that multiply variables that determine the transmit power size of the R-RICH. The result output through the above process is finally transmitted through the modulator block (50, 51, 52).

Referring to the structure of R-RICH shown in FIGS. 2, 3, and 4, a simple coder such as an orthogonal coder can be used without using a channel interleaver. That is, when the same information bit is repeatedly transmitted through the R-RICH, the receiver may simply add the received symbols and then decode the decoder.

FIG. 6 is a diagram for describing a transmission time point between a transmitting end and a receiving end in an information bit transmission method in a physical channel for transmitting a data rate according to a first embodiment of the present invention.

6 illustrates the operation of each channel according to the present invention when the time of the basic transmission unit of the R-RICH is 5 m seconds.                     

Referring to the operation principle according to Figure 6 as follows.

The base station transmits the F-RCCH during the t + t time interval from t.

The terminal interprets the received F-RCCH during the t + 4 and t + 5 time intervals, and transmits the T-times from t + 5 to t + 12 with reference to the interpreted contents. -Determine the transmission data rate of PDCH.

In this case, since the time required to determine the transmission data rate of the R-PDCH to be transmitted during the next time interval t + 5 to t + 12 time intervals after interpreting the received F-RCCH is not very long, the terminal It is possible to do this during time intervals t + 4 and t + 5.

Thereafter, the terminal repeatedly transmits the same information to the base station four times during the time interval t + 5 to t + 9, and transmits the R-PDCH to the base station for the time interval t + 8 to t + 12. At this time, the information on the R-RICH transmitted during the time interval t + 5 to t + 9 includes the transmission data rate of the R-PDCH transmitted during the time interval t + 8 to t + 12.

Meanwhile, the base station analyzes one R-RICH received from the terminal during the time intervals t + 5 and t + 6, using a certain transmission data rate for the R-PDCH to be received during the time intervals t + 8 to t + 12. Decide if you want to proceed.

The base station uses the two, three, and four R-RICHs received during the time intervals t + 6 and t + 7, the time intervals t + 7 and t + 8, and the time intervals t + 8 and t + 9, respectively. To repeat. Of course, the operation can be stopped in unnecessary time intervals among the four time intervals.

That is, since the terminal does not necessarily need to repeatedly send the R-RICH four times during the time interval t + 5 to t + 9 as described in FIG. 6, if necessary to save transmission power, the partial exclusion interval is excluded. You can also do it.

This is illustrated in FIGS. 7 to 20.

In this case, in FIG. 7 to FIG. 10, when the transmission data rate is determined and the R-RICH is transmitted to the base station, t + 5 and t + 6, t + 6 and t + 7, t + 7 and t + 8 and a time interval t + It shows that it transmits only in one time interval of 8 and t + 9.

11 to 16 show that when the transmission data rate is determined, the R-RICH is transmitted to the base station through two consecutive or discontinuous sections. In FIGS. 17 to 20, the R-RICH is transmitted to the base station. When transmitting the data, the transmission is shown through three consecutive or discontinuous intervals.

FIG. 21 is a diagram illustrating a transmission time point between a transmitting end and a receiving end in an information bit transmitting method in a physical channel for transmitting a data rate according to a second embodiment of the present invention.

In FIG. 21, when the time of the basic transmission unit of the R-RICH is 10m seconds, an exemplary diagram illustrating the operation of each channel according to the present invention will be described.

The base station transmits the F-RCCH for t + 4 from time interval t.

The terminal interprets the received F-RCCH during the time intervals t + 4 and t + 5 and the time interval t through t + 4, and then transmits the data to the next time interval t + 5 to t + 12 with reference to the interpretation. -Determine the transmission data rate of PDCH.

Since the time required to determine the transmission data rate of the R-PDCH to be transmitted to the next time interval t + 5 to t + 12 after interpreting the received F-RCCH is not very long, the terminal It is possible to do this during (t + 4, t + 5).

Thereafter, the terminal repeatedly transmits the same information to the base station twice during the time interval t + 5 to t + 9, and transmits the R-PDCH to the base station for the time interval t + 8 to t + 12. . At this time, the information on the R-RICH transmitted during the time interval t + 5 to t + 9 includes the transmission data rate of the R-PDCH transmitted during the time interval t + 8 to t + 12.

Meanwhile, the base station analyzes one R-RICH received during the time interval t + 5 to t + 7 to process the R-PDCH to be received for the time interval t + 8 to t + 12 using a certain transmission data rate. Decide if you want to.

The base station repeats this operation using two R-RICHs received during the time interval t + 7 to t + 9. Of course, the operation may be stopped in an unnecessary time interval among the two time intervals.

As shown in FIG. 21, the terminal does not necessarily need to send R-RICH repeatedly two times during the time interval t + 5 to t + 9. If necessary to save transmission power or the like, some repetition sections may be omitted. 22 and 23 are exemplary diagrams illustrating a case where some repetition intervals are excluded from transmission.

When one repetition period is excluded from transmission, as shown in FIGS. 22 and 23, the transmission period of the R-RICH may be changed for efficiency of transmission.

FIG. 24 shows an example of such a case and illustrates an example in which an R-RICH is transmitted during a time interval (t + 6, t + 8).

Then, the terminal and the base station continuously repeats the mutual operation described in FIGS. 6 to 24 until the required moment.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

In the method of operating a physical channel for transmitting data rate transmission as described above, the base station needs to consider that the transmission data rate of the R-PDCH being received is the fastest data rate among the possible transmission data rates. Therefore, since almost every terminal transmits data using the fastest data rate at one time, it is possible to build hardware using storage memory less than L * J.

Claims (14)

Using a second physical channel to transmit the data rate of transmission of the data to the base station when transmitting data through the first physical channel from the terminal to the base station; And And transmitting the transmission data rate to a base station during the minimum basic transmission unit time of the basic transmission unit time of the second physical channel. The method of claim 1, In the transmitting step, the transmission data rate transmitted during the minimum basic transmission unit time is repeatedly transmitted until the basic transmission unit time, the method of operating a physical channel for transmission data rate. The method of claim 1, The minimum basic transmission unit time is a time divided equally divided by the basic transmission unit time, the method of operating a physical channel for transmission data rate. The method of claim 1, The transmitting may include transmitting the transmission data rate for one of two times, three times, or four times the minimum basic transmission unit time. The method of claim 4, wherein In the case of transmitting for the double or triple times, the transmission time is a continuous or discontinuous time in the basic transmission unit time, characterized in that the operating method of the physical channel for transmission data rate. The method of claim 1, The first physical channel is a reverse packet data channel, And the second physical channel is a reverse rate indicator channel. The method of claim 1, The base station determines a data rate for processing data received from the terminal through the first physical channel according to the transmission data rate transmitted during the minimum basic transmission unit time. Method of physical channel. When transmitting data through a reverse packet data channel (R-PDCH) from a terminal to a base station, a reverse rate indicator channel for transmitting the data rate of the data to the base station Using the following 'R-RICH'); And And transmitting the transmission data rate to a base station in multiples of the minimum basic transmission unit time of the basic transmission unit time of the R-RICH '. The method of claim 8, And wherein the multiple is one of multiples, multiples of multiples, triples of multiples. The method of claim 9, The multiples and triples are times that are continuous in the minimum basic transmission unit time. Control the transmission data rate of the Reverse Packet Data Channel (R-PDCH) during the basic transmission unit time of the Forward Rate Control Channel (F-RCCH) from the base station to the terminal. Transmitting a signal for; Determining the transmission data rate during the basic transmission unit time of the F-RCCH according to a control signal received at the base station; And And repeatedly transmitting the determined transmission data rate to the base station at the minimum basic transmission unit time for the basic transmission unit time. delete delete delete

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