KR20010056132A - Data transmission method for compressed mode - Google Patents

Abstract

PURPOSE: A data transmission method for a compression mode is provided to implement a compression mode capable of minimizing an interference between physical channels in the case that different scrambling codes are used in a compression mode. CONSTITUTION: A dummy bit having a certain chip length is transmitted through a physical channel at the time when a compression mode is started so that a certain difference is obtained in a transmission time of a physical channel transmitted in a compression mode and a physical channel transmitted in a standard mode, and a dummy bit having a certain chip length is transmitted through a physical channel at the time when a compression mode is ended, whereby there is a transmission time difference of the physical channels having different scrambling codes used until the compression mode is maintained. The dummy bit having a certain chip length transmitted at the time when the compression mode is started and ended has a half-chip length, so that the physical channel is transmitted based on a transmission time difference of the half chip length for thereby minimizing the interference between two physical channels.

Description

Data transmission method for compressed mode

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wideband code division multiple access communication system (hereinafter, abbreviated as W-CDMA), and is particularly different in a compression mode in which data is compressed and transmitted to secure a transmission gap period. A data transmission method for a compression mode in which a scrambling code is suitable for minimizing interference between allocated physical channels.

In general, a W-CDMA communication system performs a compressed mode for compressing and transmitting data in order to perform smooth inter-frequency handoff.

1 is a diagram illustrating a transmission structure of a physical channel in a compression mode in a conventional W-CDMA communication system.

Referring to FIG. 1, the compression mode is a mode in which no data transmission is performed for a certain period of time. That is, when the compression mode is started, the system does not transmit data from one slot (N _first slot) to another slot (N _last slot) of the physical channel (3GPP, TSG RAN, WG1, Multiplexing and channel coding (FDD). ), See Technical specification 25.212 v3.0.0 (1999-10)

Therefore, in this compression mode, the system compresses the data to be transmitted during one frame, transmits it quickly, and reserves the remaining time as a transmission gap. In compression mode, the processing gain is reduced during the frame to ensure transmission white space.

In order to make up for the reduction of the processing gain in the compression mode, the instantaneous transmission power is increased to improve the transmission quality such as bit error rate (BER) or frame error rate (FER). Keep at a constant level.

Here, the system decides the type of compression frame and the compression period. The compression cycle depends on the demand and the compression frequency is variable depending on the wireless environment and measurement requirements.

2A to 2B are diagrams illustrating a downlink frame structure in the compression mode shown in FIG. 1.

2A to 2B, two types of frame structures exist in a down-link in which a signal is transmitted from a base station (BTS) to a terminal in a compression mode.

The first form is a basic structure for maximizing the transmission gap, as shown in FIG. 2A, and the second form is a structure optimized for power control in the compression mode, as shown in FIG. 2B. This second form is used when there is room in the length of the transmission gap.

Here, in the case of the frame structure of a first type base station is the last slot of the transmission space from the transmission format combination identifiers of the first slot (N _first slot) of the transport space (also referred to as Transport Format Combination Indicator, hereinafter TFCI) field (N _last slot Stops data transmission up to the second data field.

Then, the two cases of the frame structure of the second type base station stops transmitting data from the second data field of the first slot _(first slot N) of the transmission space to a second data field of the last slot (N _last slot). The two TFCI field and a first data field of the second form of the first slot (N _first slot) of the transmission space in the frame structure, the dummy bit (Dummy bit) are transmitted, and the base station and the terminal is the first slot of the transport space (N _first Only the power control command (TPC) field of the slot is utilized.

3A to 3B illustrate transmission spaces having fixed positions in the compression mode shown in FIG. 1, and FIGS. 4A to 4B illustrate transmission spaces having variable positions in the compression mode shown in FIG. 1.

Referring to FIG. 3, the transmission gap obtained in the compression mode has a fixed position or a variable position for power measurement on different frequencies, acquisition of control channels for different systems or carriers, and application to actual handover. Have

3A shows a case of having a fixed transmission blank position during a single frame, and FIG. 3B shows a case of having a fixed transmission blank position during two frames. In this Figure 3b, the transmission blank is located in the middle of two frames.

Table 1 below shows the parameters according to the position of the fixed transmission space.

Single frame Two frames Transmission slot N _first N _last N _first N _last 3 7 9 14 of the first frame 1 of the second frame 4 6 9 13 of the first frame 1 of the second frame 7 6 12 12 of the first frame 3 of the second frame 10 N.A. N.A 10 of the first frame 4 of the second frame 14 N.A. N.A 8 of the first frame 6 of the second frame

4A illustrates a case where a transmission blank position is variably set as needed during a single frame, and FIG. 4B illustrates a case where the position of a transmission blank is changed as needed during two frames.

4A to 4B mean that the position of the transmission space is adjusted to obtain data of a specific position, and also as shown in FIG. 4B, the transmission space in each frame when the transmission space spans two consecutive frames. Non-slot is chosen such that at least 8 slots can be transmitted.

Meanwhile, the W-CDMA communication system implements the compression mode described so far by changing the code rate or reducing the spreading factor (SF) through puncturing.

Herein, the present invention focuses on a method of implementing a compression mode by reducing the spread rate (SF). For this purpose, the W-CDMA communication system reduces the spread rate (SF) by half to obtain a transmission space of a certain period, and transmit space. Data is transmitted for the remaining slot time except. The maximum transmission gap that can be obtained is 7 slots for 1 frame of 15 slots.

Meanwhile, in the compression mode, the base station may instruct the terminal to use a scrambling code different from the standard mode. Therefore, when the base station is instructed to use a different scrambling code in the compression mode, there is a one-to-one correspondence between the scrambling code used in the standard mode and the scrambling code used in the compression mode (3GPP, TSG RAN, WG1, Spreading and modulation). (FDD), Technical specification 25.213 v3.0.0 (1999-10)

However, the method of performing compression mode transmission by reducing the spread rate (SF) is different from the scrambling code used in the standard mode and the scrambling code used in the compressed mode, so that the physical channel in the standard mode and the physical mode in the compressed mode are different. Orthogonal Variable Spreading Factor (OVSF) is not orthogonal between channels, so interference occurs between two physical channels.

In addition, when the transmission time of the physical channel in the standard mode and the physical channel in the compressed mode spread with different scrambling codes coincides with each other, the interference between the two physical channels increases to the maximum, thereby degrading communication quality.

Accordingly, an object of the present invention is to provide a data transmission method for a compression mode for minimizing interference between physical channels when using different scrambling codes in the compression mode in view of the problems of the prior art mentioned above. It is for.

According to an aspect of the present invention for achieving the above object, the data transmission method for a compression mode is a compression mode for compressing and transmitting data, the dummy information of a predetermined chip length at the time of starting the compression mode A first transmission step of transmitting, and a second transmission step of retransmitting the dummy information at the end of the compression mode.

Preferably, the dummy information has a half chip length.

1 is a diagram showing a transmission structure of a physical channel in a compression mode in a conventional W-CDMA communication system.

2a to 2b show a downlink frame structure in the compression mode shown in FIG.

3A-3B show transmission spaces with a fixed position in the compression mode shown in FIG.

4A-4B show transmission spaces with variable positions in the compression mode shown in FIG.

5 is a diagram illustrating a transmission structure of a physical channel in a compression mode in a W-CDMA communication system according to the present invention.

6 is a diagram illustrating an embodiment of a data transmission method for a compression mode according to the present invention.

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

The present invention proposes a data transmission method for a compression mode for minimizing interference between physical channels using different scrambling codes in the compression mode.

To this end, the present invention additionally transmits a dummy bit of a predetermined chip length at the start of the compression mode and at the time of exiting the compression mode. This is to set the transmission time of the physical channel transmitted in the standard mode and the physical channel transmitted in the compression mode to be different by a predetermined chip.

Therefore, the physical channel in the compression mode is delayed by a predetermined chip by dummy bits inserted at the beginning of the compression mode, and the transmission time of the physical channel delayed by the dummy bits inserted in the compression mode is additionally inserted at the time of leaving the compression mode. Because of this recovery, the physical channel transmitted in the compressed mode and the physical channel transmitted in the standard mode have a difference in transmission time by a predetermined chip while the compression mode is set.

5 is a diagram illustrating a transmission structure of a physical channel in a compression mode in a W-CDMA communication system according to the present invention.

Referring to FIG. 5, the W-CDMA communication system according to the present invention transmits a dummy bit of a predetermined chip length at the moment of starting the compression mode, and transmits a dummy bit of a predetermined chip length at the moment of leaving the compression mode. This dummy bit is transmitted with minimal power and is not utilized by the terminal and is ignored.

The reason for transmitting the dummy bit of the predetermined chip length is to set the difference between the transmission time of the physical channel transmitted in the compressed mode and the transmission time of the physical channel transmitted in the standard mode.

In more detail, different scrambling codes are allocated to the physical channel transmitted in the compressed mode and the physical channel transmitted in the standard mode.

In this case, as described above, the orthogonality of the orthogonal variable spreading rate (OVSF) code is not maintained between the physical channel transmitted in the compressed mode and the physical channel transmitted in the standard mode. Therefore, interference occurs between the physical channel transmitted in the compressed mode and the physical channel transmitted in the standard mode, and the interference is maximum when the transmission time of the physical channel transmitted in the compressed mode and the physical channel transmitted in the standard mode coincide with each other. To increase.

Accordingly, in the present invention, in order to set the transmission time of the physical channel transmitted in the compressed mode and the physical channel transmitted in the standard mode to have a predetermined difference, a dummy bit of a predetermined chip length is transmitted through the physical channel at the start of the compression mode At the instant of exiting the compression mode, a dummy bit of a predetermined chip length is transmitted through the physical channel, so that the scrambling code used differs in transmission time of different physical channels while the compression mode is maintained.

Here, the dummy bits of a predetermined chip length transmitted at the moment of starting the compression mode and at the moment of leaving the compression mode have a half chip length. This is because the interference between the two physical channels is minimized when the physical channel transmitted in the compressed mode and the physical channel transmitted in the standard mode are transmitted with a half chip length transmission time difference.

In more detail, the physical channel in the compressed mode and the physical channel in the standard mode are different from the scrambling code used, so that the two physical channels do not maintain orthogonality of the orthogonal variable spreading rate (OVSF) code. In this case, the interference between two physical channels having no orthogonality depends on the transmission time difference between the two physical channels.

That is, the greater the transmission time difference between the two physical channels, the less the interference. However, if the transmission time difference between the two physical channels is half chip, the interference is minimal, and when the transmission time difference between the two physical channels exceeds half chip, the interference starts to increase again.

Therefore, in the present invention, the dummy chip of half chip length is transmitted so that the transmission time difference between two physical channels becomes half chip.

6 is a diagram illustrating an embodiment of a data transmission method for a compression mode according to the present invention.

Referring to FIG. 6, the A scheme represents a conventional compression mode transmission and does not transmit dummy bits of a predetermined chip length. Therefore, the transmission time of the physical channel transmitted in the compressed mode and the physical channel transmitted in the standard mode coincide with each other. This A scheme increases the interference power with other physical channels having different scrambling codes.

The B scheme shows a compression mode transmission according to the present invention, and transmits a dummy bit of a predetermined chip length at the start of the compression mode and the moment out of the compression mode. Accordingly, the physical channel transmitted in the compressed mode and the physical channel transmitted in the standard mode have a difference in transmission time of a predetermined chip length. Therefore, interference power with other physical channels having different scrambling codes is reduced. In this case, when the half-chip length dummy bit is transmitted, the interference power is minimized.

As described above, the channel transmission method for the compression mode according to the present invention differs in the compression mode by transmitting dummy bits of a predetermined chip length in order to make a difference in the transmission time of the physical channels transmitted in the compression mode and the standard mode. The interference between the physical channels using the code is reduced, thereby maintaining the communication quality.

Claims (4)

In a compression mode in which data is compressed and transmitted, A first transmission step of transmitting dummy information of a predetermined chip length at the time of starting the compression mode; And a second transmission step of retransmitting the dummy information at the time when the compression mode is terminated. The method of claim 1, wherein the dummy information has a half chip length. In the transmission method of the first channel to which the first scrambling code is assigned and the second channel to which the second scrambling code is assigned, A first transmission step of transmitting predetermined dummy information at a transmission start time of the second channel; And a second transmission step of retransmitting the dummy information at the end of transmission of the second channel. Transmitting a first channel to which a first scrambling code is assigned; Adjusting a spreading rate (SF) of the first channel to obtain a transmission blank period; A third step of setting a second channel by allocating a second scrambling code to the first channel according to the adjusted spread ratio SF; A fourth step of transmitting predetermined dummy information at a transmission start time of the second channel; And a fifth step of retransmitting the dummy information at the end of transmission of the second channel.