KR102449701B1 - Multi-numerology based data transmitting and receiving method and apparatus capable of frequency hopping in an ofdm system - Google Patents

Abstract

The present invention relates to a data transmission/reception method and apparatus in an orthogonal frequency division multiple access system, and more particularly, to a data transmission/reception method and apparatus capable of frequency hopping.
A method according to an embodiment of the present invention provides a data transmission method in a base station of an orthogonal frequency division multiple access system, the method comprising: transmitting a message requesting capability information of a terminal for subcarrier spacing to a terminal connected to the base station; transmitting information on subbands of a group usable by the terminal when receiving a terminal capability response message from the terminal; allocating a resource by selecting one of the subbands of a group usable by the terminal when a scheduling request message is received from the terminal; and transmitting data through the allocated resource after transmitting the resource allocation message.

Description

MULTI-NUMEROLOGY BASED DATA TRANSMITTING AND RECEIVING METHOD AND APPARATUS CAPABLE OF FREQUENCY HOPPING IN AN OFDM SYSTEM

The present invention relates to a data transmission/reception method and apparatus in an orthogonal frequency division multiple access system, and more particularly, to a data transmission/reception method and apparatus capable of frequency hopping.

Efforts are being made to develop an improved 5G communication system or pre-5G communication system in order to meet the increasing demand for wireless data traffic after commercialization of the 4G communication system. For this reason, the 5G communication system or the pre-5G communication system is called a 4G network after (Beyond 4G Network) communication system or an LTE system after (Post LTE) system.

In order to achieve a high data rate, the 5G communication system is being considered for implementation in a very high frequency (mmWave) band (eg, such as a 60 gigabyte (60 GHz) band). In order to alleviate the path loss of radio waves and increase the propagation distance of radio waves in the very high frequency band, in the 5G communication system, beamforming, massive MIMO, and Full Dimensional MIMO (FD-MIMO) are used. ), array antenna, analog beam-forming, and large scale antenna technologies are being discussed.

In addition, to improve the network of the system, in the 5G communication system, an evolved small cell, an advanced small cell, a cloud radio access network (cloud radio access network: cloud RAN), an ultra-dense network (ultra-dense network) , Device to Device communication (D2D), wireless backhaul, moving network, cooperative communication, Coordinated Multi-Points (CoMP), and reception interference cancellation Technology development is underway.

In addition, in the 5G system, the advanced coding modulation (ACM) methods FQAM (Hybrid FSK and QAM Modulation) and SWSC (Sliding Window Superposition Coding), and advanced access technologies FBMC (Filter Bank Multi Carrier), NOMA (non orthogonal multiple access), and sparse code multiple access (SCMA) are being developed.

On the other hand, the 5G system, which is being developed recently, has an orthogonal frequency division with a cyclic prefix symbol applying a wideband (support up to 100 MHz in a single cell) multi-numerology for the purpose of resource utilization and large-capacity data transmission. Multiple (cyclic prefix orthogonal frequency division multiplexing: hereinafter referred to as "CP-OFDM") was adopted in an enhanced mobile broadband (eMBB) system. Multi-Numerology OFDM is a technique in which sub-carrier spacing is applied differently depending on the type and purpose of data traffic. In 5G, 15 kHz, 30 kHz, 60 kHz, … , we are considering multi-numerology with a tone spacing equal to (15*2n)kHz.

In the multi-numerology scheme, a frequency-time resource grid may be applied in various forms according to the type of data traffic. As such, when data having different subcarrier spacings overlap in the symbol region, since the symbol duration is different according to the subcarrier spacing, interference occurs by the multi-neumatic subcarriers.

Accordingly, the present invention provides a data transmission/reception method and apparatus capable of reducing interference due to multi-neumatic subcarriers.

In addition, the present invention provides a data transmission/reception method and apparatus capable of efficiently using a frequency hopping scheme in a system using a multi-numerology subcarrier.

A method according to an embodiment of the present invention is a data transmission method in a base station of an orthogonal frequency division multiple access system, comprising: transmitting a message requesting capability information of a terminal for subcarrier spacing to a terminal connected to the base station; transmitting information on subbands of a group usable by the terminal when receiving a terminal capability response message from the terminal; allocating a resource by selecting one of the subbands of a group usable by the terminal when a scheduling request message is received from the terminal; and transmitting data through the allocated resource after transmitting the resource allocation message.

An apparatus according to an embodiment of the present invention is a base station apparatus for transmitting data in an orthogonal frequency division multiple access system, comprising: a base station transmitter for converting data or signals to be transmitted to a terminal into a radio band and transmitting the data with transmit power; a base station receiving unit for down-converting and outputting a signal received from the terminal; and generating a terminal capability information request message for subcarrier spacing to the terminal connected to the base station and controlling it to be transmitted through the base station transmitter, and when receiving a terminal capability response message from the terminal through the base station receiver, in the terminal Information on subbands of a usable group is generated and controlled to be transmitted through the base station transmitter, and when a scheduling request message is received from the base station through the base station receiver, subbands of a group usable by the terminal It may include a base station control unit for allocating resources by selecting one group from among, generating and controlling the resource allocation message to transmit through the base station transmitter, and then controlling to transmit data through the allocated resource.

When CUF-OFDM according to the present invention is applied, subband hopping can be performed in OFDM using transmit filtering, so that a frequency diversity gain can be obtained within a subband. In addition, there is an advantage in that the implementation complexity of the base station can be reduced by placing terminals using the same numerology in a specific subband in the base station. In addition, when a high subcarrier is mapped to a terminal user having a large tone spacing in a wideband, system performance robust to a Doppler frequency can be secured.

1 is an exemplary diagram of subcarrier spacing in the case of applying multi-neumatology for resource utilization in a recently developed 5G system.
2 is a conceptual illustration for explaining a band for transmitting data having different tone spacing in sub-bands according to the present invention in a wideband system.
3 is a conceptual illustration for explaining a case in which frequency hopping is applied to each terminal by configuring a multi-neumatic band according to the present invention in a broadband system.
4 is a diagram for explaining an example of resource block indexing for allocating resources to a multi-numerology band according to an embodiment of the present invention.
5A and 5B are functional block diagrams of a base station apparatus according to an embodiment of the present invention.
6A and 6B are functional block diagrams of a terminal device according to an embodiment of the present invention.
7 is a signal flow diagram during data transmission/reception according to subcarrier spacing between a base station and a terminal according to the present invention.

Hereinafter, various embodiments will be described in detail with reference to the accompanying drawings. In this case, it should be noted that in the accompanying drawings, the same components are denoted by the same reference numerals as much as possible. In addition, it should be noted that the drawings of the present invention attached below are provided to help the understanding of the present invention, and the present invention is not limited to the form or arrangement illustrated in the drawings of the present invention. In addition, detailed descriptions of well-known functions and configurations that may obscure the gist of the present invention will be omitted. In the following description, only parts necessary for understanding the operation according to various embodiments of the present invention will be described, and it should be noted that descriptions of other parts will be omitted so as not to obscure the gist of the present invention.

First, the subcarrier spacing in the case of applying multi-neumerology in the recently developed 5G system will be described with reference to the accompanying drawings.

1 is an exemplary diagram of subcarrier spacing in the case of applying multi-neumatology for resource utilization in a recently developed 5G system.

Referring to FIG. 1, a resource (PRB) 110 having a tone spacing of 15 kHz and a resource (PRB) having a tone spacing of 30 kHz at the bottom right of FIG. 1 and a resource (PRB) 130 having a tone spacing of 60 kHz were illustrated. . Each of the resources (PRBs) has a different symbol length (symbol length) according to the frequency band. In the following description, for convenience of explanation, a resource (PRB) 110 having a tone spacing of 15 kHz will be referred to as a first resource, and a resource (PRB) 120 having a tone spacing of 30 kHz will be referred to as a second resource, and 60 kHz A resource (PRB) 130 having a tone spacing of will be referred to as a third resource. Also, although not illustrated in FIG. 1, as described above, in the 5G system, the tone spacing is greater than that of 60 kHz, and one or more tone spacing resources following the rule of (15*2n) kHz may be further provided.

Also, in the following description, only the resources having the tone spacing of the first resource 110 to the third resource 130, which are the resources illustrated in FIG. 1 of the description, will be used. In the first resource 110, the second resource 120, and the third resource 130 illustrated in FIG. 1, subcarrier spacing is applied differently according to the type and purpose of data traffic. According to this subcarrier spacing, when the third resource 130 indexes the first resource 130 as illustrated in FIG. 1 in the entire band of the system, the third resource 0 (PRB 0) 131, the third resource 1 (PRB 1) 132, Third resource 2 (PRB 2) 133, … , the third resource N-3 (PRB N-3) 134, the third resource N-2 (PRB N-2) 135, and the third resource N-1 (PRBN-1) 136 may be indexed.

In addition, the third resource 130 has a band of 60 kHz as described above. Therefore, if the second resource 120 having a band of 30 kHz, which is half the band, is indexed, the second resource 0 (PRB 0) 121, ... , the second resource 2N-1 (PRB 2N-1) 122 has a double indexing value. That is, it can be further subdivided into many resources from a PRB point of view. Therefore, if the first resource 110 having a band of 15 kHz is indexed, the first resource 0 (PRB 0) 111, ... , like the first resource 4N-1 (PRB 4N-1) 112, it has an indexing value four times that of the third resource 130.

As described above, when data is transmitted with different subcarrier spacings as shown in FIG. 1, data with different spacings overlaps (overlapping) data in the symbol region in which actual data is transmitted. do. Due to this overlapping phenomenon, interference occurs between subcarriers having different spacings.

In order to reduce the interference between the subcarriers, the interference may be reduced by using a Tx filtering method for a signal having out-of-band emission (hereinafter, referred to as “OOBE”). A waveform to which Tx filtering is applied to data transmitted in the OFDM method is referred to as "orthogonal frequency division multiplexing (CP-OFDM) with filtered cyclic prefix".

In the present invention described below, a method and apparatus for applying frequency hopping in filtered CP-OFDM, and an apparatus and method for transmitting/receiving a control signal according thereto. do it with

In general, in order to use filtered CP-OFDM, that is, to apply filtering to CP-OFDM data, data must be transmitted in continuous sub-bands. This is a necessary condition for applying filtered CP-OFDM because filtering is applied to confine OOBE occurring in a specific sub-band.

Meanwhile, in a broadband communication system, since the band itself is very wide, data transmission characteristics may be different for each sub-band. That is, in the case of a specific sub-band, data transmission characteristics may be very good, and in other specific sub-bands, data transmission characteristics may be poor.

In this case, data may be allocated to consecutive sub-bands in a specific band in the broadband communication system. There may be a case in which the characteristic of a specific sub-band among the consecutive sub-bands allocated for data transmission is poor. As such, a case in which the transmission characteristic of a specific sub-band among consecutive sub-bands allocated for data transmission is poor is referred to as "sub-band null". Of course, when a poor sub-band exists among consecutive sub-bands allocated for data transmission, there is a disadvantage in that data reception performance is deteriorated in the receiver.

In addition, when sub-band filtering is applied, when the base station applies filtering for each user, transmission filtering must be applied to a time domain signal for each user. Therefore, when there are many users who use a large amount of data, for example, eMBB data in a broadband system, a problem in that the complexity of implementing a base station is greatly increased may also occur.

Therefore, in the present invention described below, it is possible to solve the reception performance degradation caused by sub-band nulling that may occur when data is transmitted through continuous sub-bands using the filtered OFDM scheme that can solve the above problems. An apparatus and method are provided for

In addition, in the present invention, a method for providing a common user filtered OFDM (hereinafter referred to as "CUF-OFDM") method to which frequency hopping and sub-band hopping can be applied using the filtered OFDM method, and provide the device.

In addition, the CUF-OFDM proposed in the present invention allocates users having the same numerology to a specific sub-band and applies the same filtering and inverse fast Fourier transform (IFFT) to reduce the complexity of the system. provide a way

In addition, a method and an apparatus for signaling between a base station and a terminal for allocating the same numerology to a specific sub-band are provided.

In addition, the present invention provides a multi-numerology (multi-numerology) arrangement method for each sub-band capable of improving terminal reception performance and an apparatus for using the same.

2 is a conceptual illustration for explaining a band for transmitting data having different tone spacing in sub-bands according to the present invention in a wideband system.

First, referring to FIG. 2, in the broadband system according to the present invention, the entire bandwidth is divided into a plurality of sub-bands that the system can provide. In the example of FIG. 2, some sub-bands that are continuous in the entire band are divided into first group subbands 210, second group sub-bands 220, and third group sub-bands 230 based on spacing. did. Here, the subcarrier spacing is a case in which three subcarrier spacings are assumed as described above with reference to FIG. 1 . That is, only a resource (PRB) 110 having a tone spacing of 15 kHz, a resource (PRB) 120 having a subcarrier spacing of 30 kHz, and a resource (PRB) 130 having a tone spacing of 60 kHz are exemplified. However, as described above, there may be resources having a subcarrier spacing greater than a subcarrier spacing of 60 kHz. In this case, as described above, the rule of (15*2n)kHz is followed during subcarrier spacing.

In the present invention, the entire band is divided into groups having two or more subcarriers based on the spacing of two or more subcarriers, and each group may be configured in a form including a plurality of subbands based on the corresponding subcarrier spacing. In the following description, such a form will be referred to as "multi-numerology".

Also, the subcarrier spacing according to the present invention may be referred to as subcarrier tone spacing, tone spacing, subcarrier spacing, subcarrier tone spacing, or the like.

The form of configuring the frequency band in the base station as a multi-neumatology is possible in various forms. For example, the entire band may be configured as multi-neumerology, or only some preset bands among the entire band may be configured as multi-neumerology. Even at this time, some of the bands preset as the multi-numerology band may be a plurality of bands. For example, when only one multi-neumerology band is configured in some of the entire bands, the multi-neumerology band may be configured from the lowest frequency band to a specific frequency band among all bands. As another example, only a part of the band from the highest frequency band among the entire band may be configured as a multi-neumatic band. As another example, a multi-neumerology band may be configured in a band at a predetermined intermediate position among all bands. In addition, in the case of having two or more multi-numerology bands, the above examples may be used in combination.

Next, a case in which a resource is allocated to a terminal when a multi-neumatic band is configured will be described. The case of allocating resources to the terminal can be roughly divided into two cases. First, one group subband among the first group subbands 210, the second group subbands 220, and the third group subbands 330 may be allocated according to the capability of the terminal. For example, when the terminal supports only tone spacing corresponding to the first group subbands 210, the base station should allocate only the resources of the first group subbands 210 when allocating resources to the terminal. This is because, if subbands of different groups are allocated, the terminal cannot process the received data.

If the capability of the terminal supports only the second group subbands 220, the base station should allocate only the resources of the second group subbands 220 when allocating resources to the terminal. Similarly, when the terminal supports only the third group subbands 230, the base station should allocate only the resources of the third group subbands 230 when allocating resources to the terminal. In this way, the base station may allocate resources of the multi-neumatic band based on the capability of the terminal.

Next, when the terminal can support subbands of all groups, the base station selects one of the multi-neumerology resources in consideration of the requested service transmission rate, the amount (size) of data, and the requested service quality. can be transmitted

In this way, even if the terminal has a transmission/reception capability based on one subcarrier spacing or a transmission/reception capability based on two or more subcarrier spacings, data only through a specific group of resources set when communication is performed in the base station can be transmitted/received. For example, when the base station allocates the resources of the first group subband 210 to a specific terminal, data can be transmitted/received using only the resources of the first group subband 210 between the base station and the terminal during data communication.

With this configuration, users using a specific subband can apply the same subcarrier spacing. Accordingly, data to be transmitted to terminals to which the same subcarrier spacing is applied may be subjected to an inverse fast Fourier transform of the same size and the same transmission filtering. In addition, the terminal may receive data using only one subcarrier spacing. In addition, when a specific terminal performs communication in a specific group of subbands among bands composed of multi-neumerology, the base station may perform subband hopping when transmitting data to the terminal. As such, by performing subband hopping, it is possible to minimize deterioration due to nulling of the subband and to obtain a subband diversity gain.

Referring back to FIG. 2 , as illustrated in FIG. 2 , when subbands of each group are configured as multi-neumerology using all or a part of the entire band, the first group subbands 210 and the second group The positions of the subbands 220 and the third group subbands 230 may be different from those illustrated in FIG. 2 .

For example, the first group subbands 210 may be disposed in the highest frequency band or the second group subbands 220 may be disposed in the middle frequency band. Similarly, the second group subbands 220 and the third group subbands 230 may also be disposed in different frequency bands in the frequency band.

In addition, when the first group subbands 210, the second group subbands 220, and the third group subbands 230 are configured as multi-neumerology, the number of subbands in each group may be variably configured. For example, when users located in the base station use more data allocable to the resource (PRB) 110 having a tone spacing of 15 kHz, the frequency resources of the first group subbands 210 may be further increased. On the other hand, when users located in the base station use more data allocable to the resource (PRB) 120 having a tone spacing of 30 kHz, the frequency resources of the second group subbands 220 may be further increased. Similarly, when users located in the base station use more data allocable to the resource (PRB) 130 having a tone spacing of 60 kHz, the frequency resources of the third group subbands 230 may be further increased.

In the case of using the method described above, if the frequency resource set as the multi-neumatic band in the base station is limited to the frequency resource of the preset range, if the number of subbands in one specific group increases, the group with relatively little data transmission The number of subbands may be configured to be reduced.

However, if a method of increasing or decreasing the number of subbands in a specific group is adopted, communication of other terminals may be disturbed.

Therefore, the base station may provide information on the multi-neumerology band and configuration to the terminal that enters the base station in advance or attempts initial access by using system information or higher level signaling.

3 is a conceptual illustration for explaining a case in which frequency hopping is applied to each terminal by configuring a multi-neumatic band according to the present invention in a broadband system.

Referring to FIG. 3 , each terminal is divided into one user. As illustrated in FIG. 3 , each user may perform communication by being allocated resources in specific group subbands. More specifically, the first user 301 and the second user 302 are allocated resources to the first group subbands 210, and the third user 303 and the fourth user 304 are allocated resources to the second group subbands 220. In this state, the fifth user 305 and the sixth user 306 are allocated resources to the third group subbands 230 .

Let's take a closer look at this. The base station may transmit data to be transmitted to the first user 301 and data to be transmitted to the second user 302 among the resources of the first group subbands 210 from time t00 to time t01. As illustrated in FIG. 3 , the base station transmits data transmitted to the second user 302 using the resource of the lowest band among the subbands 210 of the first group, and transmits the data transmitted to the first user 301 to the first Transmission may be performed using a resource of a higher band among the group subbands 210 . The frequency hopping method may be applied from the time t01 to the time t02 of the next time point. That is, from time t01 to time t02, the base station transmits data transmitted to the first user 301 using the resource of the lowest band among the first group subbands 210, and the data transmitted to the second user 302 may be transmitted using a resource of a higher band among the subbands 210 of the first group.

In FIG. 3, the same form is exemplified in the case of other users. That is, the third user 303 and the fourth user 304 are allocated to the second group subbands 220 . Therefore, the base station transmits data to each of the users 303 and 304 by using the allocated resources from the time t00 to the time t01, and performs frequency hopping from the time t01 to the time t02, Data can be transmitted to each of the users 303 and 304 using different subbands.

In addition, a fifth user 305 and a sixth user 306 are allocated to the subbands 230 of the third group. Therefore, the base station transmits data to each user 305 306 by using the allocated resources from the time t00 to the time t10, and performs frequency hopping from the time t10 to the time t20, which is the next time point, to perform other subbands among the subbands of the second group. It is possible to transmit data to each of the users 305 and 306 using the bands.

In the embodiment of FIG. 3 , the same time period as the first group subbands 210 is used for convenience of description. That is, in the example of FIG. 3 , the second group subbands 220 and the third group subbands 230 during the same time period as the first group data transmission period t00-t01 and the time period t01-t02. A case in which data is transmitted and frequency hopping is performed in the same unit is exemplified.

However, in the second group subbands 220, frequency hopping is possible in a more granular unit than in the first group subbands 210 . Accordingly, in the second group subbands 220, a period different from the frequency hopping period in the first group subbands 210 may be set. Similarly, frequency hopping may be performed on the third group subbands 230 at a more subdivided cycle than the frequency hopping cycle of the first group subbands 210 and the second group subbands 220 . For example, the second group of data may use a frequency hopping period divided from a time point t00 to a time point t01 and from a time point t01 to a time point t10. As such, when the frequency hopping period is changed, the terminal receiving data in the second group may receive data in the frequency hopping method according to the corresponding period. Accordingly, from the time point of t10 to the time point of t20 can be divided into a more subdivided time point from t10 to t11 and from a time point t11 to a time point t20.

Therefore, if the subbands 230 of the third group may also set the hopping period in the same form as the subband of the second group, the frequency hopping period may be set in a more granular unit of time.

As such, when the frequency hopping period is different for each group, information on the frequency hopping period of each group may be set as a standard, or may be transmitted to the terminal through system information or higher layer signaling.

On the other hand, in the above case, since the same subcarrier spacing is applied to users assigned to each of the group subbands 210, 220, and 230, the base station performs inverse fast Fourier transform (IFFT) with the same size for data transmitted to a terminal in a specific group. and transmit filtering can be applied. Also, as described above, since all terminals (users) allocated to subbands 210, 220, and 230 of each group have the same subcarrier spacing, frequency hopping to other subcarriers in the same group can also be easily performed. Through this, deterioration due to sub-band nulling can be minimized, and a sub-band diversity gain can be obtained within the same group.

4 is a diagram for explaining an example of resource block indexing for allocating resources to a multi-numerology band according to an embodiment of the present invention.

In order for the base station to transmit data, PRB indexing for each subcarrier spacing is defined in advance, and a specific PRB index is indicated to each user (terminal) to allocate resources. In this case, as described above, a group for using subcarrier spacing may be first set between the base station and the terminal according to the capability of the terminal and/or the type of data. In this way, resources may be allocated using the resource index allocated within the previously set subcarrier spacing.

Then, with reference to FIG. 4, a PRB mapping for resource allocation will be described. First, the first group subbands 210 have a PRB of 15 kHz as described above. Assuming that there are n PRBs, which are resource blocks included in the first group subbands 210, PRB0 411 at 15 kHz, PRB1 412 at 15 kHz, PRB2 413 at 15 kHz, ... , indexing can be performed up to PRB(n-3) 414 at 15 kHz, PRB(n-2) 415 at 15 kHz, and PRB(n-1) 416 at 15 kHz.

In the same manner, the second group subbands 220 have a PRB of 30 kHz as described above. The PRBs, which are resource blocks included in the second group subbands 220, require twice as many indexing as the PRBs of 15 kHz. Therefore, if there are n PRBs of 15 kHz, there may be 2 n PRBs of 30 kHz. Therefore, 30 kHz PRBs can perform indexing from PRB0 421 to 30 kHz PRB(2n-1) 422.

The third group subbands 230 also have a PRB of 60 kHz as described above in the same manner. The PRBs, which are resource blocks included in the third group subbands 230, require four times the indexing of the PRBs of 15 kHz. Therefore, if there are n PRBs of 15 kHz, there may be 4 n PRBs of 60 kHz. Therefore, 60 kHz PRBs can perform indexing from PRB0 431 to 30 kHz PRB(4n-1) 432.

In the above method, as described above, the indexes of the PRB having the resource of 15X2 ⁿ can be mapped.

As described above, the base station can perform resource allocation by classifying the entire band or a part of the band for each numerology and allocating only the resource index to a terminal (user) using the same numerology. In the case of allocating resources as described above, even in the case of frequency hopping, a frequency hopping scheme and a position of a hopping subcarrier may be obtained using only the allocated resource index.

In this case, when the base station uses frequency hopping using a frequency resource index, the base station may apply frequency hopping according to a method of providing channel quality information preset with the terminal. Let's look at this in more detail.

The terminal may report the channel quality information at a preset period or a time point indicated by the base station. For example, the terminal may provide channel quality information to the base station by using a PRB channel quality indication (P-CQI) or sub-band channel quality information (SB-CQI). Through this, the base station acquires resource information for providing frequency hopping to the terminal, and when subcarrier hopping is provided to the terminal, the base station can allocate resources by appropriately selecting the hopping subcarrier. For this, the following operations may be required.

First, in order to use subcarrier hopping, it is necessary to negotiate on subcarriers that can be used by the terminal according to the numerology between the base station and the terminal. Thereafter, a terminal hopping pattern that can be used within a predetermined subcarrier is required.

Second, in order to use subcarrier hopping, a feed-back channel through which the base station can receive PRB channel quality indication information or sub-band channel quality indication information for knowing the channel state of the terminal is required. In addition, the base station must provide resource mapping information including PRB mapping information on which PRB to use to the terminal.

By using the above method, the base station according to the present invention can more efficiently provide frequency hopping when using the multi-numerology method. In addition, it is possible to reduce the complexity of the base station, it is possible to prevent sub-band nulling in the terminal.

5A and 5B are functional block diagrams of a base station apparatus according to an embodiment of the present invention.

Referring to FIG. 5A , the base station may include a backhaul interface 501, a base station controller 503, a base station receiver 505, and a base station transmitter 507.

The base station backhaul interface 501 may provide an interface with an upper node or another base station. The interface between the base station and other nodes above it and the interface with other base stations may be different interfaces. In the present invention, these interfaces will be collectively referred to as a backhaul interface.

The base station controller 503 may control overall operations of the base station. In addition, the base station control unit 503 may perform processing for resource allocation, communication using the allocated resources, frequency hopping, reception of channel quality information for resource allocation, etc. The base station controller 503 may be configured with one processor or a plurality of processors. In addition, the base station controller 503 may further include a memory (not shown) for storing control information as necessary. In addition, the base station controller 503 may include a communication processor that performs encoding and decoding, and may include a scheduler for transmitting data to the terminal.

The base station receiver 505 may convert a radio band signal received from the terminal into a baseband signal, convert an analog signal into a digital signal, and provide it to the base station controller 503 . In addition, the base station receiver 505 may receive channel quality information received from the terminal according to the present invention and provide it to the base station controller 503 .

The base station transmitter 507 may transmit the digital signal to be transmitted from the base station received from the base station controller 503 by converting it into an analog signal, increasing the bandwidth, and increasing the power by transmission power.

5B is a functional internal block diagram of a base station transmitter 507 according to an embodiment of the present invention.

The inside of the base station transmitter 507 may include each group transmitter corresponding to the multi-neumerology scheme. In FIG. 5B, as in the example of FIG. 3 described above, each subcarrier is configured in three different groups. Accordingly, the first transmitter 510 is configured to map and transmit the first group subcarriers, the second transmitter 520 is configured to map and transmit the second group subcarriers, and the third transmitter 530 transmits the third group subcarriers. It is a configuration for mapping and transmitting.

Each of the transmitters 510, 520, and 530 has a functionally identical configuration. For example, the first transmission unit 510 may include a first sub-carrier mapping unit 511, a first inverse fast Fourier transform unit 512, a first cyclic prefix symbol addition unit 513, and a first transmission filter 514. The second transmitter 520 may include a second sub-carrier mapping unit 521, a second inverse fast Fourier transform unit 522, a second cyclic prefix symbol adder 523, and a second transmission filter 524. Finally, the third transmitter 530 may include a third sub-carrier mapping unit 531, a third inverse fast Fourier transform unit 532, a third cyclic prefix adder 533, and a third transmission filter 534.

First, each of the group subcarrier mapping units 511, 521, and 531 included in the first group transmitter 510 to the third group transmitter 530 may map data to be transmitted to a band of a corresponding subcarrier, respectively. This may be in the form of mapping the data to be transmitted in FIG. 3 described above to the subcarrier spacing of the corresponding group.

The data mapped to each subcarrier is input to the inverse fast Fourier transform units 512, 522, and 532 according to the mapped form to the corresponding subcarrier spacing. Accordingly, the inverse fast Fourier transform units 512, 522, and 532 may perform inverse fast Fourier transform on each input data. Thereafter, the signals output from each of the inverse fast Fourier transform units 512, 522, and 532 may be input to the corresponding cyclic prefix symbol adders 513, 523, and 533. The cyclic prefix symbol adders 513, 523, and 533 may generate an OFDM symbol by adding a cyclic prefix symbol having a size corresponding to the subcarrier spacing to the output signal.

Thereafter, each OFDM symbol generated by each of the cyclic prefix symbol adders 513, 523, and 533 is input to the corresponding transmission filters 514, 524, and 534. Each of the transmit filters 514, 524, and 534 may be filters for removing sub-carrier interference as described above. That is, the OOBE phenomenon may be removed by the transmit filters 514, 524, and 534. Signals processed by each of the transmitters 510, 520, and 530 may be combined into the entire band by the combiner 540, and the combined signal may be transmitted through an antenna.

Although only one type of antenna is illustrated in FIG. 5B , in reality, it may be composed of a plurality of antennas, and in particular, a MIMO method may be applied.

Since only one inverse fast Fourier transform unit and one transmission filter are provided for subcarriers existing in one group using the configuration of FIG. 5B described above, the complexity of the base station can be reduced.

6A and 6B are functional block diagrams of a terminal device according to an embodiment of the present invention.

Referring to FIG. 6A , the terminal may include a terminal controller 601 , a terminal receiver 603 , and a terminal transmitter 605 . In addition, the terminal may additionally include a memory (not shown), a display (not shown), a user input unit (not shown), and the like, and may further include other additional functional blocks as necessary. However, blocks not related to the present invention are not shown in FIG. 6A.

The terminal controller 601 may control the overall operation of the terminal. In addition, the terminal control unit 601 may receive data through the resources allocated in the system to which the multi-numerology is applied according to the present invention, and may provide channel quality information periodically or based on the request of the base station. Such channel quality information may be one of the PRB channel quality indication information or sub-band channel quality indication described above. The terminal control unit 601 may include one or a plurality of processors.

The terminal receiver 603 may convert a radio band signal received from the base station into a baseband signal, convert an analog signal into a digital signal, and provide the converted signal to the terminal controller 601 . In addition, the terminal receiving unit 603 may receive the data of the multi-numerology method received from the base station and provide it to the terminal control unit 601 .

The terminal transmitter 605 may transmit a digital signal to be transmitted to the base station by converting the digital signal to an analog signal, increasing the bandwidth, and increasing the transmission power.

6B is a functional internal block diagram of the terminal receiving unit 603 according to an embodiment of the present invention.

The inside of the terminal receiver 603 may include receivers corresponding to each group corresponding to the multi-numerology scheme. However, it may be configured to include only one receiver according to the capability of the terminal. Referring to the configuration of FIG. 6B , an antenna, a splitter 640, and one or more receivers 610, 620, and 630 may be included. In this case, when only one receiver is included, the terminal may not include the distributor 640. In addition, each receiver in the terminal may include one or a plurality of receivers according to the capability of the terminal as described above.

6B exemplified in the drawings is a configuration for a case in which each subcarrier is composed of three different groups as in the example of FIG. 3 described above in the same manner as in FIG. 5B described above. Accordingly, the first receiver 610 is configured to receive the first group subcarriers, the second receiver 620 is configured to receive the second group subcarriers, and the third receiver 630 is configured to receive the third group subcarriers. to be.

Each of the receivers 610, 620, and 630 has a functionally identical configuration. For example, the first receiving unit 610 may include a first receiving filter 611, a first cyclic prefix removing unit 612, a first fast Fourier transform unit 613, and a first subcarrier demapping/detecting unit 614. In addition, the second receiving unit 620 may include a second receiving filter 621, a second cyclic prefix remover 622, a second fast Fourier transform unit 623, and a second subcarrier demapping/detecting unit 624. Finally, the third receiver 630 may include a third receive filter 631, a third cyclic prefix remover 632, a third fast Fourier transform unit 633, and a third subcarrier demapping/detector 634.

First, each of the reception filters 611, 621, and 631 included in the first group receiving unit 610 to the third group receiving unit 630 may filter and output the received signal. In this case, in most cases, the terminal includes only one receiver or, in most cases, only the receiver corresponding to one group even if it includes two or more receivers. Therefore, in the following description, the first receiver 610 will be described as an operation representing the three receivers 610 , 620 , and 630 .

The first reception filter 611 of the first reception unit 610 filters the received signal and outputs it to the first cyclic prefix remover 612 . The first cyclic prefix symbol remover 612 removes the cyclic prefix symbol according to the subcarrier spacing according to the 15 kHz band, which is a corresponding band, and outputs it to the first fast Fourier transform unit 613 . The first fast Fourier transform unit 613 may also perform fast Fourier transform according to subcarrier spacing according to a corresponding band, 15 kHz. As such, the fast Fourier-transformed signal in the first fast Fourier transform unit 613 is input to the first subcarrier demapping/detection unit 614 . The first subcarrier demapping/detection unit 614 may detect and output data allocated to the terminal itself by demapping the subcarrier allocated to the terminal itself in the 15 kHz band. Data output from the first subcarrier demapping/detector 614 may be processed by the terminal controller 601 .

7 is a signal flow diagram during data transmission/reception according to subcarrier spacing between a base station and a terminal according to the present invention.

Referring to FIG. 7 , the terminal and the base station may perform a RACH procedure in step 710 . The RACH procedure may be performed in various cases, such as when the terminal first enters the area of the base station, when the power is changed from an off state to an on state, or handover during cell reselection.

Thereafter, the base station may transmit a terminal capability request message for subcarrier spacing (SCS) to the terminal in step 720 . The terminal capability request message may be information inquiring which subcarrier spacing the terminal can use.

When the terminal capability request message is received in step 722, the terminal may generate a terminal capability response message for subcarrier spacing and transmit it to the base station. In this case, the terminal capability response message may include capability information on subcarrier spacing that can be used in the terminal. For example, if the base station can use three subcarrier spacings as described above, the terminal may transmit a terminal capability response message including information on which subcarrier spacing is possible among them. In addition, when the base station can provide more subcarrier spacing than the method in FIG. 3 described above, information on this may be included in the terminal capability response message and transmitted. When the terminal capability response message is transmitted based on a predefined mapping rule, the amount of transmitted messages can be reduced. Also, the terminal capability response message may be included in another message and transmitted. Other messages may be used with messages that inquire about other capabilities of the terminal.

When the base station receives the terminal capability response message from the terminal in step 722, the base station may transmit information on subbands of a group that can be allocated to the terminal in step 724, that is, the terminal can use as a message. For example, the terminal can use three groups of subbands, and among them, when the base station can use all three, it is possible to provide information on available subbands to the terminal by setting all to be available. . As another example, although the base station may use seven groups of subbands and the terminal may use three groups of subbands, only two subbands of a group that the base station can provide may exist. In this case, the base station may transmit by setting two types of information on subbands of a group usable by the terminal.

When the terminal receives information on subbands of an usable group in step 724 , it may generate a subband response message and transmit it to the base station in step 726 . In this case, the subband response message may be configured to simply inform that it has been received, or information indicating that it is available in the base station together with the received information may be retransmitted to the base station again.

Thereafter, when the terminal needs communication, the terminal may transmit a scheduling request message to the base station in step 730 . In this case, if necessary, the terminal may transmit the channel quality information together with or separately from the scheduling request message.

Then, the base station may allocate resources based on the channel quality information in step 732 and provide the allocated resource information to the terminal. In this case, the resource allocated to the terminal may use the indexing information described above.

Thereafter, the base station may transmit data to the terminal using the allocated resource in step 734 . In this case, subcarrier hopping may be performed based on the indexing information, and as described above, the subcarrier hopping may be performed within subcarriers within a corresponding group.

Also, as in step 740, the terminal may transmit channel quality information to the base station in a predetermined period unit or at the request of the base station. Then, the base station may proceed to step 742 to allocate a new resource based on the received channel quality information, and transmit data to the terminal using the allocated resource.

In FIG. 7 described above, a case in which data is transmitted based on the scheduling request message in the terminal has been described. However, even when data to be transmitted from the upper node to the corresponding terminal is received, it may be formed in the same form. For example, when data to be transmitted from the upper node to the terminal is received, the base station may generate and transmit a paging signal to the terminal. Accordingly, the terminal may transmit a paging response message to the base station when there is an input in response to the paging signal. Accordingly, when a paging response is received from the corresponding terminal, the base station may allocate resources based on the previously received terminal capability response message and transmit the allocated resource information to the terminal. Thereafter, the base station may transmit data using the allocated resource information.

Even at this time, when channel quality information is periodically received from the terminal or requested by the base station, it can be utilized, and the frequency hopping method described above can be applied in the same way. In addition, as described above, the resource allocation method may use PRB indexing.

In addition, the embodiments disclosed in the present specification and drawings are merely provided for specific examples to easily explain the contents of the present invention and help understanding, and are not intended to limit the scope of the present invention. Therefore, the scope of the present invention should be construed as including all changes or modifications derived based on the technical spirit of the present invention in addition to the embodiments disclosed herein are included in the scope of the present invention.

210, 220, 230: subbands of each group
501: backhaul interface
503: base station control unit
505: base station receiver
507: base station transmitter
510, 520, 530: transmitter
511, 521, 522: group subcarrier mapping unit in each transmitter
512, 522, 532: Inverse fast Fourier transform unit in each transmitter
513, 523, 533: cyclic prefix symbol relief part in each transmitter
514, 524, 534: transmission filter in each transmission unit (window)
540: coupling part
601: terminal control unit
603: terminal receiving unit
605: terminal transmitter
610, 620, 630: each group receiver
640: distribution unit
611, 621, 631: receive filters in each receiver
612, 622, 632: cyclic prefix symbol remover in each receiver
613, 623, 633: Fast Fourier transform unit in each receiver
614, 624, 634: subcarrier demapping/detection unit in each receiving unit

Claims (24)

A method for transmitting data in a base station of an orthogonal frequency division multiple access system, the method comprising:
transmitting a terminal capability information request message to the terminal;
receiving a terminal capability information message from the terminal in response to the terminal capability information request message;
transmitting subband group information including subcarrier spacing information indicating a bandwidth for transmitting one resource block to the terminal;
receiving a scheduling request message for the terminal;
transmitting a resource allocation message including resource information allocated according to the subcarrier spacing information included in the subband group information to the terminal in response to the scheduling request message; and
Transmitting the data to the terminal using resources allocated based on the allocated resource information; According to claim 1,
The subcarrier spacing information includes information supporting one subband group of subband groups in the entire bandwidth of the base station including the entire band of the base station as multiple neurology bands. Data in the base station of an orthogonal frequency division multiple access system How to send. According to claim 1,
receiving channel quality information from the terminal;
allocating a second resource of subcarriers of a subband group based on the channel quality information;
transmitting information based on the allocated second resource to the terminal; and
The method of transmitting data in a base station of an orthogonal frequency division multiple access system further comprising; transmitting data using the allocated second resource. According to claim 1,
generating and transmitting a paging signal to the terminal in response to reception of data to be transmitted from a higher layer node to the terminal;
allocating a third resource based on the received terminal capability information message in response to receiving a paging response from the terminal;
transmitting information on the allocated third resource to the terminal; and
The method of transmitting data in a base station of an orthogonal frequency division multiple access system further comprising; transmitting data to the terminal by using the information on the allocated third resource. According to claim 1, wherein the resource,
A data transmission method in a base station of an orthogonal frequency division multiple access system, which allocates using indexing for subbands of subband groups usable in the terminal. According to claim 1, wherein the resource,
A data transmission method in a base station of an orthogonal frequency division multiple access system, which allocates by performing frequency hopping within subbands of subband groups usable in the terminal using a preset rule. A base station apparatus for transmitting data in an orthogonal frequency division multiple access system, comprising:
a transmitter configured to convert one of data or signals into a radio band and transmit one of the converted data or signals to a terminal;
a receiver configured to perform band down-converting and output the signal received from the terminal; and
A controller comprising:
Controls the transmitter to transmit a terminal capability information request message to the terminal,
Control the receiver to receive a terminal capability information message from the terminal,
controlling the transmitter to transmit subband group information including subcarrier spacing information to the terminal;
controlling the receiver to receive a scheduling request message for the terminal;
controlling the transmitter to transmit a resource allocation message including resource information allocated according to the subcarrier spacing information included in the subband group information to the terminal, and
Controls the transmitter to transmit data to the terminal based on the allocated resource information,
The subcarrier spacing information indicates a bandwidth for transmitting one resource block, a base station for transmitting data in an orthogonal frequency division multiple access system. 8. The method of claim 7,
The subcarrier spacing information includes information for supporting one subband group of subband groups in the entire bandwidth of the base station including the entire band of the base station as multiple neurology bands. Transmitting data in an orthogonal frequency division multiple access system base station for The method of claim 7, wherein the controller,
Further controlling the receiver to receive the channel quality information from the terminal,
Allocating a second resource of subcarriers of a subband group based on the channel quality information,
Further controlling the transmitter to transmit information based on the allocated second resource to the terminal, and
A base station for transmitting data in an orthogonal frequency division multiple access system, further controlling the transmitter to transmit data using the allocated second resource. 8. The method of claim 7,
Further comprising a backhaul interface for communicating with higher layer nodes or other base stations,
The controller is
generating a paging signal to the terminal in response to reception of data to be transmitted from a higher layer node to the terminal through the backhaul interface;
controlling the transmitter to transmit the paging signal to the terminal in response to receiving data to be transmitted to the terminal,
Allocating a third resource based on the received terminal capability information message in response to receiving a paging response from the terminal through the receiver,
Control to transmit information on the allocated third resource to the terminal through the transmitter,
A base station for transmitting data in an orthogonal frequency division multiple access system, which controls the transmitter to transmit data to the terminal by using the information on the allocated third resource. The method of claim 7, wherein the controller,
A base station for transmitting data in an orthogonal frequency division multiple access system, allocating the resource using indexing for subbands of subband groups usable in the terminal. The method of claim 7, wherein the controller,
A base station for transmitting data in an orthogonal frequency division multiple access system, configured to allocate the resource by performing frequency hopping within subbands of subband groups usable in the terminal using a preset rule. The method of claim 7, wherein the subband group information comprises:
A base station for transmitting data in an orthogonal frequency division multiple access system, further comprising at least one of subbands capable of communicating with the terminal. The method of claim 7, wherein the subcarrier spacing information comprises:
A base station for transmitting data in an orthogonal frequency division multiple access system, further comprising at least one of 15 kHz spacing, 30 kHz spacing, and 60 kHz spacing. The method of claim 1, wherein the subband group information comprises:
The method of transmitting data in a base station of an orthogonal frequency division multiple access system, further comprising at least one of subbands capable of communicating with the terminal. The method of claim 1, wherein the subcarrier spacing information comprises:
A method of transmitting data in a base station of an orthogonal frequency division multiple access system, further comprising at least one of 15 kHz spacing, 30 kHz spacing, and 60 kHz spacing. A method for receiving data in a terminal of a Jakgyo frequency division multiple access system, the method comprising:
Receiving a terminal capability information request message from the base station;
transmitting a terminal capability information message to the base station in response to the terminal capability information request message;
Receiving subband group information including subcarrier spacing information indicating a bandwidth for one resource block transmission from the base station;
Transmitting a scheduling request message to the base station:
receiving, from the base station, a resource allocation message including resource information allocated according to the subcarrier spacing information included in the subband group information; and
Receiving the data from the base station using resources allocated based on the allocated resource information; 18. The method of claim 17,
measuring the signal quality received from the base station;
transmitting channel quality information to the base station based on the measured received signal quality;
receiving a second resource allocation message indicating a second resource of subcarriers of a subband group; and
Receiving data using the second resource allocation message;
The second resource of the subcarriers of the subband group is determined based on the channel quality information, data receiving method in a terminal of a frequency division multiple access system. 18. The method of claim 17, wherein the subband group information is
The method for receiving data in a terminal of a frequency division multiple access system, further comprising at least one subband capable of communicating between the base station and the terminal. The method of claim 17, wherein the subcarrier spacing information comprises:
15 kHz spacing, 30 kHz spacing, and further comprising at least one of 60 kHz spacing, data receiving method in the terminal of the jakgyo frequency division multiple access system. A terminal device for receiving data in an orthogonal frequency division multiple access system, comprising:
a transmitter configured to convert one of data or signals into a radio band and transmit one of the converted data or signals to a base station;
a receiving unit configured to perform band down-converting and output the signal received from the base station; and
A controller comprising:
Controls the receiver to receive a terminal capability information request message from the base station,
controlling the transmitter to transmit a terminal capability information message to the base station in response to receiving the terminal capability information request message;
controlling the receiver to receive subband group information including subcarrier spacing information from the base station,
controlling the transmitter to transmit a scheduling request message to the base station;
controlling the receiver to receive, from the base station, a resource allocation message indicating resource information allocated according to the subcarrier spacing information included in the subband group information, and
Controls the receiving unit to receive data from the base station through the allocated resource based on the allocated resource information,
The subcarrier spacing information indicates a bandwidth for transmitting one resource block, a terminal device for receiving data in an orthogonal frequency division multiple access system. 22. The method of claim 21,
Control the receiver to measure the signal quality received from the base station,
controlling the transmitter to transmit channel quality information to the base station based on the measured received signal quality,
controlling the receiver to receive a second resource allocation message indicating a second resource of subcarriers of a subband group, and
controlling the receiver to receive data using the second resource allocation message;
The second resource of the subcarriers of the subband group is determined based on the channel quality information, a terminal device for receiving data in an orthogonal frequency division multiple access system. The method of claim 21, wherein the subband group information comprises:
A terminal device for receiving data in an orthogonal frequency division multiple access system, further comprising at least one subband capable of communicating between the base station and the terminal. The method of claim 21, wherein the subcarrier spacing information comprises:
A terminal device for receiving data in an orthogonal frequency division multiple access system, further comprising at least one of 15 kHz spacing, 30 kHz spacing, and 60 kHz spacing.

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