KR20090088779A - A method for transmitting a frame according to time division duplexing - Google Patents

Abstract

A frame transmission method according to a TDD(Time Division Duplexing) mode is provided to transmit data without interference in case a frame structure having a CP(Cyclic Prefix) length is adjacent. A first frame is set up. The first frame comprises one or more first downlink subframe, a switching point and one or more first uplink subframe. The second frame is set up. The second frame comprises a plurality of second down link subframe, and the idle frame and plurality of second uplink subframe. The second frame is transmitted. A part all overlaps of the switching point. The subframes are made of a plurality of OFDM(Orthogonal Frequency Division MultIPlexing) symbol.

Description

Frame transmission method according to TD method {A METHOD FOR TRANSMITTING A FRAME ACCORDING TO TIME DIVISION DUPLEXING}

The present invention relates to wireless communication, and more particularly, to a frame transmission method according to the TDD scheme in a wireless communication system.

The Institute of Electrical and Electronics Engineers (IEEE) 802.16 standard provides technologies and protocols to support Broadband Wireless Access. Standardization has been in progress since 1999, and IEEE 802.16-2001 was approved in 2001. This is based on the Single Carrier physical layer called 'WirelessMAN-SC'. Later, in the IEEE 802.16a standard approved in 2003, 'WirelessMAN-OFDM' and 'WirelessMAN-OFDMA' were added to the physical layer in addition to 'WirelessMAN-SC'. After the completion of the IEEE 802.16a standard, the revised IEEE 802.16-2004 standard was approved in 2004. In order to correct bugs and errors in the IEEE 802.16-2004 standard, IEEE 802.16-2004 / Cor1 (hereinafter referred to as IEEE 802.16e) was completed in 2005 in the form of 'corrigendum'.

Currently, standardization of IEEE 802.16m, which is a new technical standard standard, is progressing based on IEEE 802.16e. IEEE 802.16m, a newly developed technical standard, should be designed to support the IEEE 802.16e designed earlier. That is, the existing technology (IEEE 802.16e) of the technology of the newly designed system (IEEE 802.16m) should be configured to efficiently encompass and operate. This is called backward compatibility. The following support factors are considered when designing IEEE 802.16m.

First, the terminal of the new technology must operate with the same performance as the base station and the terminal of the existing technology. Second, the system of the new technology and the system of the existing technology must operate in the same radio frequency (RF) carrier and the same bandwidth. Third, the base station of the new technology should support the case where the terminal of the new technology and the terminal of the existing technology coexist on the same RF carrier, the performance of the entire system should be improved by the ratio of the terminal of the new technology. Fourth, the base station of the new technology should support the handover of the terminal of the existing technology and the handover of the terminal of the new technology to match the handover performance between the existing base stations. Fifth, the base station of the new technology should support the terminal of the existing technology while supporting the terminal of the new technology, and should be able to support the level provided by the base station of the existing technology to the terminal of the existing technology.

The base station of the new technology schedules a radio resource for the terminal of the existing technology or the terminal of the new technology within the bandwidth that can be supported. The scheduling of radio resources may be performed in a logical frame including a plurality of OFDM symbols in a time domain and a plurality of subchannels in a frequency domain. Therefore, studies on the structure of a frame that can satisfy the back support for the IEEE 802.16e system in the IEEE 802.16m system.

In particular, when a frame structure according to a time division duplexing (TDD) scheme having different lengths of cyclic prefixes (CPDs) coexists in adjacent cells, interference between the downlink and uplink may occur. Therefore, it is necessary to design a TDD frame structure so that interference does not occur between TDD frame structures that coexist in adjacent cells.

An object of the present invention is to provide a method for transmitting data using a TDD frame having a CP of various lengths.

A frame transmission method according to a time division duplexing (TDD) scheme according to an aspect of the present invention configures a first frame including at least one first downlink subframe, a switching point, and at least one first uplink subframe And setting a second frame including a plurality of second downlink subframes, an idle frame, and a plurality of second uplink subframes, and transmitting the second frame. All or part of the switching point and the idle frame overlap.

According to the present invention, when frame structures having various CP lengths supporting the IEEE 802.16m format are transmitted adjacent to each other, data may be transmitted so as not to interfere with each other.

1 is a block diagram illustrating a wireless communication system. Wireless communication systems are widely deployed to provide various communication services such as voice and packet data.

Referring to FIG. 1, a wireless communication system includes a user equipment (UE) 10 and a base station 20 (BS). The terminal 10 may be fixed or mobile and may be referred to by other terms such as a mobile station (MS), a user terminal (UT), a subscriber station (SS), and a wireless device. The base station 20 generally refers to a fixed station for communicating with the terminal 10 and may be referred to in other terms such as a NodeB, a base transceiver system (BTS), and an access point. . One or more cells may exist in one base station 20.

Hereinafter, downlink means communication from the base station 20 to the terminal 10, and uplink means communication from the terminal 10 to the base station 20. In downlink, the transmitter may be part of the base station 20 and the receiver may be part of the terminal 10. In uplink, the transmitter may be part of the terminal 10 and the receiver may be part of the base station 20.

The wireless communication system may be an orthogonal frequency division multiplexing (OFDM) / orthogonal frequency division multiple access (OFDMA) based system. OFDM uses multiple orthogonal subcarriers. OFDM utilizes orthogonality between Inverse Fast Fourier Transform (IFFT) and Fast Fourier Transform (FFT). At the transmitter, data is sent by performing an IFFT. The receiver performs FFT on the received signal to recover the original data. The transmitter uses an IFFT to combine multiple subcarriers, and the receiver uses a corresponding FFT to separate multiple subcarriers.

2 shows an example of a frame structure. A frame is a sequence of data for a fixed time used by physical specifications. This may be referred to section 8.4.4.2 of the IEEE standard 802.16-2004 "Part 16: Air Interface for Fixed Broadband Wireless Access Systems" (hereafter reference 1).

Referring to FIG. 2, the frame includes a downlink (DL) frame and an uplink (UL) frame. In Time Division Duplex (TDD), uplink and downlink transmissions share the same frequency but occur at different times. The downlink frame is temporally ahead of the uplink frame. The downlink frame starts with a preamble, a frame control header (FCH), a downlink (DL) -MAP, an uplink (MAP) -MAP, and a burst region. A guard time for distinguishing the uplink frame and the downlink frame is inserted in the middle part (between the downlink frame and the uplink frame) and the last part (after the uplink frame) of the frame. A transmit / receive transition gap (TGT) is a gap between a downlink burst and a subsequent uplink burst. A receive / transmit transition gap (RTG) is a gap between an uplink burst and a subsequent downlink burst.

The preamble is used for initial synchronization, cell search, frequency offset, and channel estimation between the base station and the terminal. The FCH includes the length of the DL-MAP message and the coding scheme information of the DL-MAP.

DL-MAP is an area where a DL-MAP message is transmitted. The DL-MAP message defines the connection of the downlink channel. The DL-MAP message includes a configuration change count of the downlink channel descriptor (DDC) and a base station identifier (ID). DCD describes the Downlink Burst Profile applied to the current map. The downlink burst profile refers to a characteristic of a downlink physical channel, and the DCD is periodically transmitted by the base station through a DCD message.

The UL-MAP is an area in which the UL-MAP message is transmitted. The UL-MAP message defines the access of an uplink channel. The UL-MAP message includes a configuration change count of an uplink channel descriptor (UCD) and a valid start time of uplink allocation defined by UL-MAP. UCD describes an Uplink Burst Profile. The uplink burst profile refers to characteristics of an uplink physical channel, and the UCD is periodically transmitted by the base station through a UCD message.

Hereinafter, a new TDD frame structure that satisfies backward support for the existing system will be described. Here, the time division duplexing (TDD) frame refers to a frame that uses the entire frequency band as an uplink or a downlink and distinguishes the uplink and the downlink in the time domain. A frame that satisfies backward support for an existing system is called a dual frame. The dual frame includes a resource region supporting a legacy system and a resource region supporting a new / evolved system. The existing system may mean an IEEE 802.16e system, and the new system may mean IEEE 802.16m. The term used in the frame structure of IEEE 802.16e described in FIG. 2 may be defined and used in the frame structure of IEEE 802.16m, or may be partially changed.

First, Table 1 below shows parameters for a frame.

Transmission Bandwidth (MHz) 5 10 20 Over Sampling Factor 28/25 Sampling Frequency (MHz) 5.6 11.2 22.4 FFT Size 512 1024 2048 Subcarrier Spacing (KHz) 10.94 OFDM Symbol Time, Tu (μs) 91.4 Cyclic Prefix (CP) Ts (μs) OFDM Symbols per Frame Idle Time (μs) Tg = 1 / 4Tu 91.4 + 22.85 = 114.25 43 87.25 Tg = 1 / 8Tu 91.4 + 11.42 = 102.82 48 64.64 Tg = 1 / 16Tu 91.4 + 5.71 = 97.11 51 47.39 Tg = 1 / 32Tu 91.4 + 2.86 = 94.26 53 4.22

In order to satisfy the backward support for frames of the existing IEEE 802.16e frame, the new system can follow the frame parameters of the IEEE 802.16e frame such as transmission bandwidth, sampling band, FFT size, subcarrier spacing, and the like. In addition, the CP length is set to 1 / 8Tu, and 48 OFDM symbols are included in one frame, so that it can be applied in the legacy system support mode for supporting IEEE 802.16e. In Legacy Support Disabled Mode, the length of the new CP can be set to 1 / 4Tu, 1 / 16Tu or 1 / 32Tu, thus 43, 51 or 53 OFDM symbols in one frame. This may be included. For example, when one subframe is composed of six OFDM symbols, a frame having a length of 1 / 4Tu of CP has seven subframes, one remaining OFDM symbol, and eight frames having a length of 1 / 16Tu of CP. A subframe, three residual OFDM symbols, and a frame having a length of 1 / 32Tu of CP may include eight subframes and five residual OFDM symbols.

Here, CP is a copy of the final Tg, which is a useful symbol period, and may be expressed as a ratio with respect to a useful symbol time (Tu).

Table 2 below shows the lengths of TTG and RTG in the TDD structure of the IEEE 802.16e standard. Hereinafter, TTG may be expressed in terms such as a switching point or an idle frame.

Bandwidth 5M 10M 8.75M 7M 14M PS (ns) (= 4 / Fs) 714.286 357.142 400 500 250 TTG (μs) 148PS = 105.71 296PS = 105.71 218PS = 87.2 376PS = 188 752PS = 188 RTG (μs) 84PS = 60.00 168PS = 60.00 186PS = 74.4 120PS = 60 240PS = 60 TTG: RTG 1.76: 1 1.76: 1 1.17: 1 3.13: 1 3.13: 1

3 is a case where the ratio of downlink and uplink is 4: 4, FIG. 4 is a case where the ratio of downlink and uplink is 5: 3, and FIG. 5 is a case where the ratio of downlink and uplink is 6: 2. 6 illustrates an example of a TDD frame structure in which a CP length of 1 / 8Tu when the ratio of downlink and uplink is 7: 1.

3 to 6, a new TDD frame that satisfies backward support is based on an existing TDD frame structure, values of Table 1 and Table 2 above. That is, a new TDD frame to satisfy the back support has a length of 5ms, a CP length of 1 / 8Tu, a bandwidth of 10MHz, and includes 48 OFDM symbols. In addition, basic control information such as preamble, FCH, MAP can be defined according to the IEEE 802.16e standard, and have TTG and RTG sizes as shown in Table 2 above.

3 to 6, one TDD frame consists of eight subframes. Here, a subframe is a basic unit of data allocation and scheduling, and generally consists of six OFDM symbols. When one subframe is composed of six OFDM symbols, the ratio between downlink and uplink can be efficiently set, the number of OFDM symbols in the uplink period can be adjusted to a multiple of 3, and the data delay performance can be improved. have. However, the number of OFDM symbols constituting one subframe is not limited thereto. That is, the subframes may be composed of any number of OFDM symbols, and each subframe may have a different size.

A transmit / receive transition gap (TGT) is located between the downlink (DL) region and the uplink (UL) region, and a receive / transmit transition gap (RTG) is located between the uplink region and the following frame. The TTG or RTG may include an idle time according to the size of the CP to prevent intersymbol interference.

Specifically, referring to FIG. 3, a 2364.86 μs point including 23 OFDM symbols having a CP length of 1 / 8Tu from a start point of a frame is set as a downlink period, and the TTG intervals of Table 2 from the 2364.86 μs point. 2472.32μs including the 107.46μs interval corresponding to a part of the idle time is set as the TTG interval, and from 2472.32μs to the 4940μs including 24 OFDM symbols having a CP length of 1 / 8Tu as an uplink interval Then, the point from the 4940μs point to the last point of the frame including the 60μs interval corresponding to the RTG interval of Table 2 is set as the RTG interval. Therefore, all subframes except the fourth subframe of the downlink interval are composed of six OFDM symbols, the fourth subframe of the downlink interval is composed of five OFDM symbols, and the other one OFDM symbol is TTG and RTG. Allocate for interval.

Referring to FIG. 4, a 2981.78 μs point including 29 OFDM symbols having a CP length of 1 / 8Tu from a start point of a frame is set as a downlink period, and the TTG interval and idle time of the TTG interval of Table 2 from 2981.78 μs are set. Up to 3089.24μs, which includes some corresponding 107.46μs, is set as TTG, and up to 4940μs, which includes 18 OFDM symbols having CP length of 1 / 8Tu, is set as uplink, and 4940μs, from 3089.24μs. From the point to the last point of the frame including the 60μs section corresponding to the RTG section of Table 2 is set as the RTG section. Therefore, all subframes except the fifth subframe of the downlink period consist of six OFDM symbols, the fifth subframe of the downlink period consists of five OFDM symbols, and the other one OFDM symbol is TTG and RTG. Allocate for interval.

Referring to FIG. 5, a point 3598.7 μs including 35 OFDM symbols having a CP length of 1 / 8Tu from a start point of a frame is set as a downlink interval, and the TTG interval and idle time of Table 2 from 3598.7 μs are set. Up to 3706.16μs including some corresponding 107.46μs interval is set as TTG interval, up to 4940μs including 12 OFDM symbols having CP length of 1 / 8Tu from 3706.16μs and configured as uplink interval, 4940μs From the point to the last point of the frame including the 60μs section corresponding to the RTG section of Table 2 is set as the RTG section. Therefore, all subframes except the sixth subframe of the downlink period consist of six OFDM symbols, the sixth subframe of the downlink period consists of five OFDM symbols, and the other one OFDM symbol is TTG and RTG. Allocate for interval.

Referring to FIG. 6, the 4215.62μs point including 41 OFDM symbols having a CP length of 1 / 8Tu from the start point of the frame is set as a downlink interval, and the TTG interval and idle time of the table 2 from the 4215.62μs point are shown. Up to 4323.08μs, which includes a portion of 107.46μs, is set as a TTG interval, and from 4323.08μs to 4940μs, which includes six OFDM symbols having a CP length of 1 / 8Tu, is set as an uplink interval, and 4940μs From the point to the last point of the frame including the 60μs section corresponding to the RTG section of Table 2 is set as the RTG section. Therefore, all subframes except the seventh subframe of the downlink interval are composed of six OFDM symbols, the seventh subframe of the downlink interval is composed of five OFDM symbols, and the other one OFDM symbol is TTG and RTG. Allocate for interval.

In Figures 3 to 6 RTG is 60.0μs and idle time (Idle time) to drive the TTG to 107.46μs, TTG is 105.71μs as shown in Table 2 and idle time (Idle time) RTG Can be configured to 61.77μs.

If the CP length is 1 / 8Tu, if the frame is configured as shown in Figs. 3 to 6, not only the backward support for the existing system can be satisfied, but also if the existing frame and the new frame coexist in adjacent cells, Interference between terminals can be prevented.

FIG. 7 is a diagram illustrating a TDD frame structure having CP lengths of 1 / 4Tu, 1 / 16Tu, and 1 / 32Tu according to an embodiment of the present invention when the downlink and uplink ratios are 4: 4.

Referring to FIG. 7, the reference frame has the same structure as that of FIG. 3, and has a total length of 5 ms, a CP length of 1/8 Tu, and 8 subframes.

Looking at the TDD frame structure with a CP length of 1 / 4Tu, the total length is 5ms, and the downlink period is set from the beginning of the frame to a 2399.25μs point including 21 OFDM symbols having a CP length of 1 / 4Tu, The TTG interval from 2399.25μs to 2540.75μs, including the 141.5μs interval corresponding to a portion of the TTG interval and the idle time in Table 2, is set as the TTG interval and 21 OFDM symbols with a CP length of 1 / 4Tu from 2540.75μs The up to 4940 μs point is set as an uplink interval, and the RTG interval is set from the 4940 μs point to the last point of the frame including the 60 μs interval corresponding to the RTG interval in Table 2. Therefore, if one subframe is composed of five OFDM symbols, one remaining OFDM symbol is further allocated to the downlink period, one remaining OFDM symbol is further allocated to the uplink period, and the remaining one remaining OFDM symbol is Allocates between TTG and RTG intervals. In FIG. 7, although the first subframe of the downlink period and the last subframe of the uplink period are configured with six OFDM symbols, any one subframe belonging to the downlink period and one subframe belonging to the uplink period. The frame may consist of six OFDM symbols. In addition, the downlink period is composed of a plurality of subframes consisting of five OFDM symbols and one independent OFDM symbol, and the uplink period is composed of a plurality of subframes consisting of five OFDM symbols and one independent OFDM symbol. It can also be configured as. The configuration of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

Next, looking at the TDD frame structure of CP length 1 / 16Tu, the total length is 5ms, from the start of the frame to the 2427.8μs point containing 25 OFDM symbols having a CP length of 1 / 16Tu as a downlink section The TTG section is set from the 2427.8μs point to the 2511.6μs point including the 84.5μs section corresponding to a part of the TTG section and the idle time in Table 2, and is set to 25 TGs having a CP length of 1 / 16Tu from the 2511.6μs point. The up to 4940 μs point including the OFDM symbol is configured as an uplink period, and the up to the last point of the frame including the 60 μs period corresponding to the RTG period shown in Table 2 is set as the RTG period from the 4940 μs point. Therefore, if one subframe is composed of six OFDM symbols, three remaining OFDM symbols remain, and one OFDM symbol among the three remaining OFDM symbols is further allocated to a downlink period, and one OFDM symbol is an uplink period. The remaining one OFDM symbol is further allocated to the TTG and RTG intervals. In FIG. 7, the first subframe of the downlink period is composed of seven OFDM symbols, and the last subframe of the uplink period is composed of seven OFDM symbols. One OFDM symbol may be configured, and one subframe belonging to an uplink period may be configured by seven OFDM symbols. In addition, the downlink period is composed of a plurality of subframes consisting of six OFDM symbols and the remaining one independent OFDM symbol, and the uplink period is composed of a plurality of subframes consisting of six OFDM symbols and the remaining one independent OFDM symbol. It can also be configured as. The configuration of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

Next, looking at the TDD frame structure having a CP length of 1 / 32Tu, the total length is 5ms, and from the beginning of the frame to the point 2450.76μs including 26 OFDM symbols having a CP length of 1 / 32Tu, the downlink interval is performed. The TTG interval is set from 2450.76μs to 2583.5μs, which includes the 132.42μs interval corresponding to a portion of the TTG interval and idle time in Table 2, and is set as the TTG interval and 25 CP lengths of 1 / 32Tu from 2583.5μs The up to 4940 μs point including the OFDM symbol is configured as an uplink period, and the up to the last point of the frame including the 60 μs period corresponding to the RTG period shown in Table 2 is set as the RTG period from the 4940 μs point. Therefore, if one subframe consists of six OFDM symbols, five remaining OFDM symbols remain, and two OFDM symbols among the five remaining OFDM symbols are further allocated to the downlink period, and one OFDM symbol is assigned to the uplink period. The remaining two OFDM symbols are further allocated to the TTG and RTG intervals. In FIG. 7, the first subframe and the last subframe of the downlink period are composed of seven OFDM symbols, and the last subframe of the uplink period is composed of seven OFDM symbols. One subframe may consist of seven OFDM symbols, and one subframe belonging to an uplink period may consist of seven OFDM symbols. In addition, the downlink period is composed of a plurality of subframes consisting of six OFDM symbols and the remaining two independent OFDM symbols, and the uplink period is composed of a plurality of subframes consisting of six OFDM symbols and the remaining one independent OFDM symbol. It can also be configured as. The configuration of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

When the TDD frame is configured as shown in FIG. 7, even when frame structures having different CP lengths coexist in adjacent cells, interference does not occur. That is, the downlink section of a frame having a CP length of 1 / 8Tu and the uplink section of a frame having a CP length of 1 / 4Tu, 1 / 16Tu, or 1 / 32Tu do not overlap, but an uplink of a frame having a CP length of 1 / 8Tu Since the link section and the downlink section of a frame having a CP length of 1 / 4Tu, 1 / 16Tu, or 1 / 32Tu do not overlap, interference does not occur with each other.

8 is a diagram illustrating a TDD frame structure having CP lengths of 1 / 4Tu, 1 / 16Tu, and 1 / 32Tu according to an embodiment of the present invention when the ratio of downlink and uplink is 5: 3.

Referring to FIG. 8, a reference frame has the same structure as that of FIG. 4 and has a total length of 5 ms, a CP length of 1/8 Tu, and 8 subframes.

Looking at a TDD frame structure having a CP length of 1 / 4Tu, the total length is 5ms, and a downlink period is set from a starting point of the frame to a 2856.25μs point including 25 OFDM symbols having a CP length of 1 / 4Tu. From 2856.25μs to 2997.75μs, including the TTG section of Table 2 and 141.5μs corresponding to a part of the idle time, the TTG section is set, and 17 OFDM symbols with a CP length of 1 / 4Tu from 2997.75μs are selected. The up to 4940 μs point is set as an uplink interval, and the RTG interval is set from the 4940 μs point to the last point of the frame including the 60 μs interval corresponding to the RTG interval in Table 2. Therefore, if one subframe consists of six OFDM symbols, one remaining OFDM symbol is further allocated to a downlink period, the first subframe of the uplink period consists of five OFDM symbols, and the uplink period One OFDM symbol located before the first subframe of Puncture is disabled. In FIG. 8, although the first subframe of the downlink period is composed of seven OFDM symbols, any one subframe belonging to the downlink period may be composed of seven OFDM symbols. In addition, the downlink period may be composed of a plurality of subframes consisting of six OFDM symbols and one independent OFDM symbol. This subframe structure is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

As another example, in a TDD frame structure having a CP length of 1 / 4Tu, when one subframe includes 5 OFDM symbols, one remaining OFDM symbol is further allocated to a downlink period, and one residual OFDM symbol is uplink. Further allocation to the interval, the remaining one OFDM symbol may have a structure to assign to the TTG interval.

Next, looking at the TDD frame structure having a CP length of 1 / 16Tu, the total length is 5ms, and from the start of the frame to the 3010.41μs point including 31 OFDM symbols having a CP length of 1 / 16Tu as a downlink section 19 points with a CP length of 1 / 16Tu from 3094.91μs from 3010.41μs to 3094.91μs, including 84.5μs for the TTG section and a portion of idle time. The up to 4940 μs point including the OFDM symbol is configured as an uplink period, and the up to the last point of the frame including the 60 μs period corresponding to the RTG period shown in Table 2 is set as the RTG period from the 4940 μs point. Therefore, if one subframe is composed of six OFDM symbols, three remaining OFDM symbols remain, and one OFDM symbol among the three remaining OFDM symbols is further allocated to a downlink period, and one OFDM symbol is an uplink period. The remaining one OFDM symbol is further allocated to the TTG and RTG intervals. In FIG. 8, although the first subframe of the downlink period is composed of seven OFDM symbols and the last subframe of the uplink period is composed of seven OFDM symbols, any one subframe belonging to the downlink period is 7 One OFDM symbol may be configured, and one subframe belonging to an uplink period may be configured by seven OFDM symbols. In addition, the downlink period is composed of a plurality of subframes consisting of six OFDM symbols and the remaining one independent OFDM symbol, and the uplink period is composed of a plurality of subframes consisting of six OFDM symbols and the remaining one independent OFDM symbol. It can also be configured as. This subframe structure is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

Next, looking at the TDD frame structure of CP length 1 / 32Tu, the total length is 5ms, and from the start of the frame to the 3016.32μs point containing 32 OFDM symbols having a CP length of 1 / 32Tu as a downlink section 20 points with a CP length of 1 / 32Tu from 3054.80μs from 3016.32μs to 3054.80μs, including 38.48μs for the TTG section and part of the idle time. The up to 4940 μs point including the OFDM symbol is configured as an uplink period, and the up to the last point of the frame including the 60 μs period corresponding to the RTG period shown in Table 2 is set as the RTG period from the 4940 μs point. Therefore, if one subframe consists of six OFDM symbols, five remaining OFDM symbols remain, and two OFDM symbols among the five remaining OFDM symbols are further allocated to the downlink period, and two OFDM symbols are the uplink period. The remaining one OFDM symbol is further allocated to the TTG and RTG intervals. In FIG. 8, the first subframe and the last subframe of the downlink period are composed of seven OFDM symbols, and the first subframe and the last subframe of the uplink period are composed of seven OFDM symbols. Any two subframes belonging to the interval may consist of seven OFDM symbols, and any two subframes belonging to the uplink interval may consist of seven OFDM symbols. In addition, the downlink period consists of a plurality of subframes consisting of six OFDM symbols and the remaining two independent OFDM symbols, and the uplink period consists of a plurality of subframes consisting of six OFDM symbols and the remaining two independent OFDM symbols. It can also be configured as. The structure of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

If the TTG section requires a longer section than 38.48 μs, one of OFDM symbols additionally allocated to the downlink section or the uplink section may be allocated for the TTG section. For example, one of OFDM symbols additionally allocated to the uplink interval may be further allocated for the TTG interval, thereby making the TTG interval 132.74 μs.

If a TDD frame is configured as shown in FIG. 8, even when frame structures having different CP lengths coexist in adjacent cells, interference does not occur. That is, the downlink section of a frame having a CP length of 1 / 8Tu and the uplink section of a frame having a CP length of 1 / 4Tu, 1 / 16Tu, or 1 / 32Tu do not overlap, but an uplink of a frame having a CP length of 1 / 8Tu Since the link section and the downlink section of a frame having a CP length of 1 / 4Tu, 1 / 16Tu, or 1 / 32Tu do not overlap, interference does not occur with each other.

9 is a diagram illustrating a TDD frame structure having CP lengths of 1 / 4Tu, 1 / 16Tu, and 1 / 32Tu according to an embodiment of the present invention when the ratio of downlink and uplink is 6: 2.

Referring to FIG. 9, a reference frame has a total length of 5ms, a CP length of 1 / 8Tu, and 8 subframes as shown in FIG. 5.

Looking at the TDD frame structure having a CP length of 1 / 4Tu, the total length is 5ms and a downlink period is set from the start point of the frame to the point 3541.8μs including 31 OFDM symbols having a CP length of 1 / 4Tu. From 3541.8μs to 3683.25μs including T141 interval and 141.45μs corresponding to a part of the idle time, the TTG interval is set and 11 OFDM symbols with CP length of 1 / 4Tu from 3683.25μs The up to 4940 μs point is set as an uplink interval, and the RTG interval is set from the 4940 μs point to the last point of the frame including the 60 μs interval corresponding to the RTG interval in Table 2. Therefore, if one subframe consists of six OFDM symbols, one remaining OFDM symbol is further allocated to a downlink period, the first subframe of the uplink period consists of five OFDM symbols, and the uplink period One OFDM symbol located before the first subframe of Puncture is disabled. In FIG. 9, although the first subframe of the downlink period consists of seven OFDM symbols, any one subframe belonging to the downlink period may consist of seven OFDM symbols. In addition, the downlink period may be composed of a plurality of subframes consisting of six OFDM symbols and one independent OFDM symbol. The structure of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

As another example, in a TDD frame structure having a CP length of 1 / 4Tu, when one subframe includes 5 OFDM symbols, one remaining OFDM symbol is further allocated to a downlink period, and one residual OFDM symbol is uplink. Further allocation to the interval, the remaining one OFDM symbol may have a structure to assign to the TTG interval.

Next, looking at the TDD frame structure of CP length 1 / 16Tu, the total length is 5ms, 3593.07μs including 37 OFDM symbols having a CP length of 1 / 16Tu from the start of the frame to the downlink period 13 points with a CP length of 1 / 16Tu from 3677.57μs, from 3593.07μs to 3677.57μs, including the 84.5μs interval corresponding to a portion of the TTG interval and idle time in Table 2. The up to 4940 μs point including the OFDM symbol is configured as an uplink period, and the up to the last point of the frame including the 60 μs period corresponding to the RTG period shown in Table 2 is set as the RTG period from the 4940 μs point. Therefore, if one subframe is composed of six OFDM symbols, three remaining OFDM symbols remain, and one OFDM symbol among the three remaining OFDM symbols is further allocated to a downlink period, and one OFDM symbol is an uplink period. The remaining one OFDM symbol is further allocated to the TTG and RTG intervals. In FIG. 9, the first subframe of the downlink period is composed of seven OFDM symbols, and the last subframe of the uplink period is composed of seven OFDM symbols. One OFDM symbol may be configured, and any one subframe belonging to an uplink period may be configured by seven OFDM symbols. In addition, the downlink period is composed of a plurality of subframes consisting of six OFDM symbols and the remaining one independent OFDM symbol, and the uplink period is composed of a plurality of subframes consisting of six OFDM symbols and the remaining one independent OFDM symbol. It can also be configured as. The structure of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

Next, looking at the TDD frame structure having a CP length of 1 / 32Tu, the total length is 5ms, and from the start of the frame to the 3581.88μs point including 38 OFDM symbols having a CP length of 1 / 32Tu as a downlink section The TTG section is set from 3581.88 μs to 3620.36 μs, which includes the 38.48 μs of the TTG section and a portion of the idle time in Table 2, and is set as the TTG section and has 14 CP lengths of 1 / 32Tu from 3620.36 μs. The up to 4940 μs point including the OFDM symbol is configured as an uplink period, and the up to the last point of the frame including the 60 μs period corresponding to the RTG period shown in Table 2 is set as the RTG period from the 4940 μs point. Therefore, if one subframe consists of six OFDM symbols, five remaining OFDM symbols remain, and two OFDM symbols among the five remaining OFDM symbols are further allocated to the downlink period, and two OFDM symbols are the uplink period. The remaining one OFDM symbol is further allocated to the TTG and RTG intervals. In FIG. 9, although the first subframe and the last subframe of the downlink period are configured with seven OFDM symbols, any two subframes belonging to the downlink period may be configured with seven OFDM symbols. In addition, the downlink period consists of a plurality of subframes consisting of six OFDM symbols and the remaining two independent OFDM symbols, and the uplink period consists of a plurality of subframes consisting of six OFDM symbols and the remaining two independent OFDM symbols. It can also be configured as. The structure of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

In addition, when the TTG section requires a longer section than 38.48 μs, one of OFDM symbols additionally allocated to the downlink section or the uplink section may be allocated for the TTG section. For example, one of OFDM symbols additionally allocated to the uplink interval may be further allocated for the TTG interval, thereby making the TTG interval 132.74 μs.

If a TDD frame is configured as shown in FIG. 9, even when frame structures having different CP lengths coexist in adjacent cells, interference does not occur. That is, the downlink section of a frame having a CP length of 1 / 8Tu and the uplink section of a frame having a CP length of 1 / 4Tu, 1 / 16Tu, or 1 / 32Tu do not overlap, but an uplink of a frame having a CP length of 1 / 8Tu Since the link section and the downlink section of a frame having a CP length of 1 / 4Tu, 1 / 16Tu, or 1 / 32Tu do not overlap, interference does not occur with each other.

10 is a diagram illustrating a TDD frame structure having CP lengths of 1 / 4Tu, 1 / 16Tu, and 1 / 32Tu according to an embodiment of the present invention when the ratio of downlink and uplink is 7: 1.

Referring to FIG. 10, a reference frame has a total length of 5 ms, a CP length of 1/8 Tu, and 8 subframes as shown in FIG. 6.

Looking at the TDD frame structure having a CP length of 1 / 4Tu, the total length is 5ms, and the downlink period is set from a start point of the frame to a point 4227.25μs including 37 OFDM symbols having a CP length of 1 / 4Tu. From 4227.25μs to 4368.75μs, which includes the 141.5μs interval corresponding to the TTG interval and the idle time portion of Table 2, the TTG interval is set, and 5 OFDM symbols having a CP length of 1 / 4Tu from 4368.75μs The up to 4940 μs point is set as an uplink interval, and the RTG interval is set from the 4940 μs point to the last point of the frame including the 60 μs interval corresponding to the RTG interval in Table 2. Therefore, if one subframe consists of six OFDM symbols, one remaining OFDM symbol is further allocated to a downlink period, the first subframe of the uplink period consists of five OFDM symbols, and the uplink period One OFDM symbol located before the first subframe of Puncture is disabled. In FIG. 10, although the first subframe of the downlink period consists of seven OFDM symbols, any one subframe belonging to the downlink period may consist of seven OFDM symbols. In addition, the downlink period may be composed of a plurality of subframes consisting of six OFDM symbols and one independent OFDM symbol. The structure of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

As another example, in a TDD frame structure having a CP length of 1 / 4Tu, when one subframe includes 5 OFDM symbols, one remaining OFDM symbol is further allocated to a downlink period, and one residual OFDM symbol is uplink. In addition, the remaining one OFDM symbol may be allocated to the TTG and RTG intervals.

Next, looking at the TDD frame structure of the CP length 1 / 16Tu, the total length is 5ms, from the start of the frame to the 4175.73μs point containing 43 OFDM symbols having a CP length of 1 / 16Tu as a downlink section The TTG section is set from 4175.73μs point to 4260.23μs point including 84.5μs section corresponding to a part of the TTG section and idle time in Table 2, and is set as a TTG section from 7260 having a CP length of 1 / 16Tu from 4260.23μs point. The up to 4940 μs point including the OFDM symbol is configured as an uplink period, and the up to the last point of the frame including the 60 μs period corresponding to the RTG period shown in Table 2 is set as the RTG period from the 4940 μs point. Therefore, when one subframe consists of a plurality of OFDM symbols, three remaining OFDM symbols remain, and one OFDM symbol among the three remaining OFDM symbols is further allocated to a downlink period, and one OFDM symbol is an uplink period. The remaining one OFDM symbol is further allocated to the TTG and RTG intervals. In FIG. 10, although the first subframe of the downlink period consists of seven OFDM symbols, any one subframe belonging to the downlink period may consist of seven OFDM symbols. In addition, the downlink period may be composed of a plurality of subframes consisting of six OFDM symbols and one independent OFDM symbol. The structure of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of arbitrary OFDM symbols, and each subframe may have a different size.

Next, looking at the TDD frame structure having a CP length of 1 / 32Tu, the total length is 5ms, and from the beginning of the frame to the point 4241.7μs including 45 OFDM symbols having a CP length of 1 / 32Tu, the downlink interval is performed. It is set, and from the 4241.7μs point to 4280.18μs point including the 38.48μs section corresponding to a part of the TTG section and the idle time in Table 2, it is set as the TTG interval, and has 7 CP lengths of 1 / 32Tu from 4280.18μs point. The up to 4940 μs point including the OFDM symbol is set as an uplink period, and the up to the last point of the frame including the 60 μs period corresponding to the RTG period in Table 2 is set as the RTG time period from the 4940 μs point. Therefore, if one subframe consists of six OFDM symbols, five remaining OFDM symbols remain, and three OFDM symbols among the five remaining OFDM symbols are further allocated to a downlink period, and one OFDM symbol is an uplink period. The remaining one OFDM symbol is further allocated to the TTG and RTG intervals. In FIG. 10, although the first subframe and the sixth and seventh subframes of the downlink period are configured with seven OFDM symbols, any three subframes belonging to the downlink period may be configured with seven OFDM symbols. . In addition, the downlink period consists of a plurality of subframes consisting of six OFDM symbols and the remaining three independent OFDM symbols, and the uplink period consists of a subframe consisting of six OFDM symbols and the remaining one independent OFDM symbol. You may. The structure of such a subframe is only an example. That is, subframes belonging to the downlink period may consist of any number of OFDM symbols, subframes belonging to the uplink period may consist of any number of OFDM symbols, and each subframe may have a different size. have.

In addition, when the TTG section requires a longer section than 38.48 μs, one of OFDM symbols additionally allocated to the downlink section or the uplink section may be allocated for the TTG section. For example, one of OFDM symbols additionally allocated to the uplink interval may be further allocated for the TTG interval, thereby making the TTG interval 132.74 μs.

If a TDD frame is configured as shown in FIG. 10, even when frame structures having different CP lengths coexist in adjacent cells, interference does not occur. That is, the downlink section of a frame having a CP length of 1 / 8Tu and the uplink section of a frame having a CP length of 1 / 4Tu, 1 / 16Tu, or 1 / 32Tu do not overlap, but an uplink of a frame having a CP length of 1 / 8Tu Since the link section and the downlink section of a frame having a CP length of 1 / 4Tu, 1 / 16Tu, or 1 / 32Tu do not overlap, interference does not occur with each other.

Table 3 below shows a frame structure having different CP lengths that coexist with the reference frame structure.

Parameters Values or Features DL / UL Ratio with a CP of 1 / 8Tu 4: 4 5: 3 6: 2 7: 1 4: 4 5: 3 6: 2 7: 1 4: 4 5: 3 6: 2 7: 1 CP lengths (μs) 1 / 4Tu 1 / 16Tu 1 / 32Tu Total No.of Symbols per 5ms Frame (Nsym) 43 51 53 No.of Residue Symbols (= Nsym mod 6) 1 (In case of Nsym mod 5, 3 Residue Symbols) 3 5 Positions of Residue Symbols One in DL (In case of Nsym mod 5, One in DL, One in UL and One in TTG) One in DL, One in UL, and One in TTG Two in DL, Two in UL, and One in TTG (+) In case of 7: 1, Three in DL, One in UL, and One in TTG (+) In case of 4: 4, Two in DL, One in UL, and Two in TTG No.of Punctured Symbols in Regular Subframes 1 (In case of Nsym mod 5, 0 Punctured Symbol) 0 0 Size of DL (μs) 2399.25 (Nsym mod 5) 2856.25 3541.8 4227.25 2427.8 3010.41 3593.07 4175.73 2450.76 3016.32 3581.88 4241.7 Size of UL (μs) 2399.25 (Nsym mod 5) 1942.25 1256.75 571.25 2428.4 1845.09 1262.43 679.77 2356.5 1885.2 1319.64 659.82 No.of Regular Subframes 5 (In case of Nsym mod 5, 6 Regular Subframes) 6 4 Size of Irregular Subframes (*) 5 and 7 OFDM Symbols (In case of Nsym mod 5, 6 OFDM Symbols) 7 OFDM Symbols 7 OFDM Symbols No.of Irregular Subframes (*) 2 2 4

In the TDD frame structure in which the ratio of downlink and uplink in Table 3 is 4: 4 and CP length is 1 / 4Tu, it is assumed that one subframe is composed of five OFDM symbols, and the TDD frame structure is 1 / 32Tu. In the TTG interval, one more OFDM symbol is allocated. In addition, in the TDD frame structure in which the ratio of the downlink and the uplink is 7: 1 and the CP length is 1 / 32Tu, only one subframe is allocated for the downlink, and the remaining OFDM symbols are further allocated to the uplink. In addition, the following two rows with an asterisk (*) are different depending on how many OFDM symbols a subframe consists basically. In addition, in the configuration of Table 3, one symbol may be further disabled in downlink or uplink as needed when the system is applied.

The invention can be implemented in hardware, software or a combination thereof. In hardware implementation, an application specific integrated circuit (ASIC), a digital signal processing (DSP), a programmable logic device (PLD), a field programmable gate array (FPGA), a processor, a controller, and a microprocessor are designed to perform the above functions. , Other electronic units, or a combination thereof. In the software implementation, the module may be implemented as a module that performs the above-described function. The software may be stored in a memory unit and executed by a processor. The memory unit or processor may employ various means well known to those skilled in the art.

As mentioned above, preferred embodiments of the present invention have been described in detail, but those skilled in the art to which the present invention pertains should understand the present invention without departing from the spirit and scope of the present invention as defined in the appended claims. It will be appreciated that various modifications or changes can be made. Accordingly, modifications to future embodiments of the present invention will not depart from the technology of the present invention.

1 is a block diagram illustrating a wireless communication system.

2 shows an example of a frame structure.

3 shows an example of a TDD frame structure having a CP length of 1 / 8Tu when the ratio of downlink and uplink is 4: 4.

4 shows an example of a TDD frame structure having a CP length of 1 / 8Tu when the ratio of downlink and uplink is 5: 3.

FIG. 5 shows an example of a TDD frame structure having a CP length of 1 / 8Tu when the ratio of downlink and uplink is 6: 2.

FIG. 6 shows an example of a TDD frame structure having a CP length of 1 / 8Tu when the ratio of downlink and uplink is 7: 1.

FIG. 7 is a diagram illustrating a TDD frame structure having CP lengths of 1 / 4Tu, 1 / 16Tu, and 1 / 32Tu according to an embodiment of the present invention when the downlink and uplink ratios are 4: 4.

8 is a diagram illustrating a TDD frame structure having CP lengths of 1 / 4Tu, 1 / 16Tu, and 1 / 32Tu according to an embodiment of the present invention when the ratio of downlink and uplink is 5: 3.

9 is a diagram illustrating a TDD frame structure having CP lengths of 1 / 4Tu, 1 / 16Tu, and 1 / 32Tu according to an embodiment of the present invention when the ratio of downlink and uplink is 6: 2.

10 is a diagram illustrating a TDD frame structure having CP lengths of 1 / 4Tu, 1 / 16Tu, and 1 / 32Tu according to an embodiment of the present invention when the ratio of downlink and uplink is 7: 1.

Claims (5)

In the frame transmission method according to the time division duplex (TDD) method, Setting a first frame comprising at least one first downlink subframe, a switching point and at least one first uplink subframe; Setting a second frame including a plurality of second downlink subframes, an idle frame, and a plurality of second uplink subframes; And Transmitting the second frame; And all or part of the switching point and the idle frame overlap. The method of claim 1, And the first downlink subframe, the first uplink subframe, the second downlink subframe, and the second uplink subframe comprise a plurality of OFDM symbols. The method of claim 2, The OFDM symbol constituting the first frame and the OFDM symbol constituting the second frame have different cyclic prefix lengths. The method of claim 3, wherein CP length of the OFDM symbol constituting the first frame is 1/8 times the effective symbol time (Tu), and CP length of the OFDM symbol constituting the second frame is 1/4 times the effective symbol time , 1/16 times or 1/32 times frame transmission method. The method of claim 1, The ratio of the at least one first downlink subframe and the at least one first uplink subframe is 4: 4, 5: 3, 6: 2 or 7: 1.

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