KR100705919B1 - Method for managing data in mobile system - Google Patents

Abstract

In order to implement multiplexing and demultiplexing of IMT-2000 WCDMA, the present invention provides a frame area (slot) as much as the time required to set a function block and perform the function block. ), And an instruction decoder determines whether or not the function block operation is completed by a predetermined binary value.

The present invention comprises the steps of setting a function block to be performed for each frame (Function Block); Allocating slots to be performed in operation of each of the functional blocks; Setting a functional block to check whether the operation of each slot is completed; Displaying in binary form whether the function block is completed; And determining whether to perform the next slot among the slots using the binary value.

Mobile communication, frame, slot, demultiplexing, multiplexing

Description

{Method for managing data in mobile system}             

1 is a configuration of the DPDCH channel

2 is a block diagram for performing demultiplexing (DEMUX) or multiplexing (MUX) in a mobile station (UE) in a forward or reverse direction;

3 is an example of allocating slots according to processing time of each function block to implement demultiplexing

4 is a diagram used by the instruction decoder of FIG. 2 to operate without interruption.

The present invention relates to a data processing method in a mobile communication system, and in particular, to implement multiplexing and demultiplexing of IMT-2000 WCDMA, By allocating a frame area (slot) for the time required to perform a function block, and determining whether the function block is completed by a constant binary value, the instruction decoder executes a slot command corresponding to the next function block. The present invention relates to a data processing method in a mobile communication system for minimizing system error suppression and processing time.

In more detail, the function blocks required for performing the multiplexing and the demultiplexing are respectively set, and since the processing time of each of the function blocks is different, the number of slots (frame areas) corresponding thereto are differently assigned. In order to perform a function block, the instruction decoder executes a predetermined binary value ("0" or "1") after determining whether the slot allocated to the current function block is operated.

In other words, since each channel does not operate all of the functional blocks but operates differently according to the characteristics of each channel, it is determined whether the next channel is performed based on the binary value.

Hereinafter, the prior art according to the present invention will be described.

First, the frame described in the present application and a frame region (hereinafter referred to as a slot) constituting the frame will be briefly described.

In general, 3GPP systems such as IMT-2000 have a downlink shared channel (DSCH) as a channel for data type transmission.

1 shows the configuration of a DPDCH channel.

1, the DPDCH channel is composed of a radio frame having a frame period (T _f ) = 10 ms, has a structure of 15 slots (Slot # 0 to Slot # 14), and any one slot T _slot. = 2560 chips, N _data bits of 20 * 2 ^k bits (k = 0..6).

2 is a block diagram for performing demultiplexing (DEMUX) or multiplexing (MUX) at a mobile station (UE) in either forward or reverse direction.

As shown in the figure, a receiver 20 for receiving an RF signal, a shared memory 22 for storing data received at the receiver, and a function block 23 for performing demultiplexing. ), An instruction decoder 24 for determining whether to perform the next slot by reading a binary value indicating whether the slots allocated to the functional blocks are completed, and a controller (MCU) for controlling the components. It consists of 21.

Currently, a technique for implementing multiplexing and demultiplexing in the IMT-2000 WCDMA method has not been specifically illustrated since IMT-2000 is not commercialized yet.

Meanwhile, parallel processing architecture was proposed in the Design Implementation Document (DID) of the Newton project, a joint project with Cadence.

In other words, a function block to be executed in each slot is prepared in advance, and an instruction decoder instruction is written to each function block whenever necessary.

However, this method requires that the instruction decoder must execute a slot interrupt whenever necessary to write an instruction to each functional block, and each functional block is not terminated when the next slot instruction is executed. Otherwise, a fatal error can occur in the system.

That is, in the method of notifying the instruction decoder of timing information about a slot, the slot interrupt is conventionally performed.

Therefore, the present invention is to solve the above-mentioned conventional problems, and in order to inform the instruction decoder of timing information for executing the instruction of the next slot, binarization whether or not the operation completion for the slot allocated to each functional block is completed in a certain table. In this paper, we propose a scheme that does not require a separate slot interrupt because it is processed by software.

A data processing method in a mobile communication system of the present invention includes the steps of setting a function block to be performed for each frame; Allocating slots to be performed in operation of each of the functional blocks; Setting a functional block to check whether the operation of each slot is completed; Displaying in binary form whether the function block is completed; And determining whether to perform the next slot among the slots using the binary value.

In addition, the present invention is characterized in that the instruction decoder is performed after checking whether the operation of the function block for the current slot is completed when determining whether the next slot in the slot.

Also, in the present invention, the operation completion check of the function block for the current slot is characterized in that the instruction decoder is performed by checking the slot value state of the decoder.

First, the present invention will be described in general, by setting a function block to be executed in each slot in advance, and writing an instruction decoder instruction (binary value "0" or "1") in each function block whenever necessary. The next slot operation can be performed without a slot interrupt.

The present invention uses an array of the number of slots * number of functional blocks and has a slot to check whether the operation is completed among the slots allocated to each functional block in order to perform the next slot operation.

Therefore, the instruction decoder checks whether the slots of the functional blocks necessary for demultiplexing or multiplexing are terminated (in the case of binary value "1"), and executes the instruction of the next slot when all are terminated.

In the above description, the slot is not essential as a basic unit. For convenience of the present invention, the slot may be arbitrarily selected according to the person who implements the functional block in hardware or software.

Other objects and features of the present invention will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.                     

In order to implement demultiplexing according to the present invention with reference to the accompanying drawings, the instruction decoder command value without a separate slot interrupt to allocate the number of slots for each functional block processing, and to perform the next functional block, that is, the next slot It explains using.

3 illustrates an example of allocating slots according to processing time of each function block to implement demultiplexing.

As shown in the figure, SDI represents a second interleaver and is applied to all channels A, B, C, D, and E, and slots 0, 1, and 2 are allocated to perform the SDI.

DEMUX stands for transport channel demultiplexing. Slot 3 is assigned to channel A, slot 4 is assigned to channel B, slot 5 is assigned to channel C, and slot 6 is assigned to channel E.

The FDI represents a first interleaver. Slot 4 is assigned to channel A, slot 5 is assigned to channel B, and slot 6 is assigned to channel C.

DRM indicates rate matching. Slots 3 and 4 are assigned to channel D, slot 5 is to channel A, slot 6 is to channel B, and slot 7 is to channel C.

TD represents a turbo decoder, and slots 5 to 14 are allocated to the D channel.

VD stands for a Viterbi decoder. Slot 6 is assigned to channel A, slot 7 is assigned to channel B, and slot 8 is assigned to channel C.                     

DCRC stands for cyclic redundancy check (CRC) check. Slot A is allocated to channel A.

According to the above, channel A operates functional blocks of SDI, DEMUX, FDI, DRM, VD and DCRC.

4 is a diagram used by the instruction decoder 24 of FIG. 2 to operate without interruption.

The diagram of FIG. 4 may be stored in a register or transmitted to the instruction decoder 24 in a separate instruction.

3 and 4, as shown in FIG. 3, each functional block allocates one or more slots.

The instruction decoder checks whether the operation of the previous slot is completed for each slot and performs the slot operation allocated to the next functional block.

For example, in order to execute the slot 3 command in FIG. 4, the slot 3 operation is performed after checking whether the slot 2 is “1” among binary values 0, 1, and 2 allocated to the functional block SDI.

That is, to perform slot 3, the slot 3 is performed after confirming that the functional block SDI, which is set to "1" in slot 2, is terminated.

The binary value " 1 " in the above is a value given for confirming completion of each functional block operation to operate the next slot.

In addition, in the case of slot 6, since the functional blocks set to "1" are DEMUX, FDI, DRM, and VD, it is necessary to check whether the functional blocks are terminated and perform the operation of the next slot.

In each of the above functional blocks, when the operation is completed, the binary value “1” indicating that the operation is completed may be written in the register.

As described above, in the present invention, a function block necessary for performing demultiplexing is set, and the processing time of each of the function blocks is different, so that the corresponding number of slots (frame area) is allocated differently. In order to perform the slot allocated to the instruction decoder, the instruction decoder executes a predetermined binary value ("0" or "1") after determining whether the slot allocated to the current functional block is operated.

Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments.

 Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

According to the present invention, in order to implement demultiplexing of IMT-2000 WCDMA, a corresponding function block is allocated and a frame area (slot) is allocated as long as it takes to perform the function block. The instruction decoder determines whether the functional block operation is completed based on a constant binary value and executes a slot command corresponding to the next functional block, thereby minimizing system error suppression and processing time.

Claims (3)

In performing data processing in the mobile communication system, Setting a function block to be performed for each frame; Allocating slots to be performed in operation of each of the functional blocks; Setting a functional block to check whether the operation of each slot is completed; Displaying in binary form whether the function block is completed; And determining whether to perform the next slot among the slots using the binary value. The data processing method of claim 1, wherein the instruction decoder checks whether the function block has been completed for the current slot when the next slot is performed. The method according to claim 2, wherein the operation completion check of the functional block with respect to the current slot is performed by the instruction decoder confirming the slot value state of the decoder.

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