KR101781344B1 - Method for transmitting data in machine type communications and apparatus for machine type communications - Google Patents

Abstract

A data communication method for object communication is disclosed. A data transmission method for object communication includes dividing each of a plurality of subframes constituted of time resources and frequency resources into a first area for transmitting control information and a second area for transmitting data, And resources for object communication in the second area of each of the plurality of subframes according to the hopping frequency interval. Therefore, the data transmission rate of the object communication apparatus can be increased.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a data communication method,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a machine type communication technology, and more particularly, to a data transmission method and an object communication apparatus for object communication capable of increasing a data transmission capacity.

In recent years, M2M (Machine-to-Machine) communication, which enables the acquisition and transmission of necessary information anytime and anywhere by connecting all the objects around the network, As a major issue.

M2M is mainly based on sensors and RFID networks targeting local areas, but various wired and wireless networks can be used as the purpose and characteristics of applications are gradually increasing. Recently, based on mobile communication network, considering wide range of service areas including object mobility, book, mountain, and ocean, ease of operation and maintenance of network, security for reliable data transmission, and quality of service guarantee There is a growing interest in M2M.

The 3rd Generation Partnership Project (3GPP), a representative mobile telecommunication standardization organization in Europe, has started a feasibility study for M2M in 2005 and has been carrying out a full-scale standardization work under the name of MTC (Machine Type Communications)

3GPP refers to an entity that does not require the direct manipulation or intervention of a 'machine', and MTC defines it as a form of data communication involving one or more of these 'machines'. That is, the MTC can be defined in the form of data communications associated with one or more entities that do not necessarily require human intervention.

The MTC has a number of different market scenarios, data communications, low costs and effort, a very large number of communicating terminals, And is different from the current human centered optimized mobile network service in terms of small traffic per terminal.

MTC can be applied to various applications. For example, MTC provides a comprehensive set of services including Security, Tracking & Tracing, Payment, Health (eHealth), Remote Maintenance & Control, Smart Metering, Consumer devices and the like.

Meanwhile, the most interesting field in the MTC related standardization process currently underway in 3GPP is low-cost MTC terminal technology.

The requirements for a low-cost MTC terminal based on LTE (Long Term Evolution) are that the data transmission rate will satisfy the minimum downlink of 118.4kbps and the uplink of 59.2kbps, and the frequency efficiency is higher than that of the Global System for Mobile Communications / Enhanced General Packet Radio Service), the service area provided should not be smaller than that provided by the GSM / EGPRS MTC terminal, the legacy LTE terminal and the LTE MTC terminal should be available at the same frequency, Reuse existing LTE / SAE networks, optimize in TDD (Time Division Duplex) mode as well as FDD (Frequency Division Duplex) mode, low cost LTE MTC terminal has limited mobility and low power consumption module And to provide support for such services.

In the 3GPP standardization process, a narrowband support, a single RF chain, a Half duplex FDD, a long DRX (Discontinued Reception) scheme, Modulation, H-ARQ (Hybrid-Automatic Repeat reQuest), rate matching, handover, new category types, and the like.

In particular, a low cost MTC terminal is considered to be a representative technology for the use of narrowband frequency, considering a bandwidth of 1.4 to 5 MHz. However, the setting of the frequency band may vary depending on the field to which the MTC is applied.

On the other hand, when the MTC terminal uses the fixed narrowband frequency band, the biggest problem that can occur is that it is difficult to obtain the frequency diversity gain, and the transmission efficiency of the MTC terminals decreases.

Accordingly, a new data transmission method for solving the problem of the MTC terminal using the narrow band as described above is required.

SUMMARY OF THE INVENTION An object of the present invention to solve the above problems is to provide a data transmission method for object communication capable of increasing a data transmission capacity of an MTC terminal using a narrow band.

According to an aspect of the present invention, there is provided a data transmission method for object communication, including a first region for transmitting control information and a second region for transmitting control information, And allocating resources for object communication to a second region of each of the plurality of subframes according to a predetermined hopping period and a hopping frequency interval.

Here, the resources for the object communication include a plurality of resource blocks, each of which has a frequency band narrower than the plurality of subframes, and the hopping frequency interval includes a number of the minimum resource blocks included in the frequency band for the object communication Can be determined by the corresponding frequency interval. Here, the center frequency of the resource for the object communication, which is allocated to the second area of the predetermined subframe among the plurality of subframes, may be determined by a predetermined hopping frequency interval and a hopping index. In addition, the hopping index is an integer of 0 or more, and the maximum value of the hopping index can be determined by the number of resource blocks included in a plurality of subframes and the number of resource blocks allocated for object communication. In addition, the hopping index can be shared by a transmitting apparatus and a receiving apparatus performing object communication.

Here, the hopping period may be determined based on at least one of an index of the subframe and a maximum value of the hopping index. In addition, the hopping period may be determined to be an integer multiple of the subframe.

Herein, the step of allocating the resources for the object communication may include the step of allocating the resources for the object communication to the second region of the plurality of subframes in consideration of the time difference between the frequency conversion delay time of the receiving apparatus that receives the object communication data, And allocating the resources for the object communication to the time domain of the object communication.

In this case, when the frequency conversion delay time is less than or equal to the time interval of the first area, the resource allocation for the object communication may include allocating resources for the object communication in the same interval as the time interval of the second area, . ≪ / RTI >

Herein, the step of allocating resources for the object communication may include: when the frequency conversion delay time is greater than the time period of the first area and the hopping period corresponds to one subframe length, The resource for the object communication can be allocated from a time point after the time difference between the frequency conversion delay time and the time interval of the first area at the starting point of the second area. In addition, in the step of allocating resources for the object communication, resources for transmitting data among the resources for the object communication may be first allocated in the time domain.

Herein, the step of allocating resources for the object communication may include: when the frequency conversion delay time is greater than the time period of the first area and the hopping period corresponds to one subframe length, The resources for the object communication can be allocated from the starting point of the second area to the time point corresponding to the time difference between the frequency conversion delay time and the time interval of the first area. In addition, in the step of allocating resources for the object communication, resources for transmitting control information among the resources for the object communication may be first allocated in the time domain.

Here, the step of allocating the resources for the object communication may include a step of allocating resources for the object communication from the time when the receiving apparatus for receiving the object communication data transmits the frequency conversion from the end of the region of the resource allocated for the object communication allocated to the second region of each sub- And starting the processing of the object communication.

According to another aspect of the present invention, there is provided an apparatus for communicating objects, comprising: a digital-to-analog converter for converting a baseband digital signal into an analog signal; A frequency up converter for up-converting the center frequency according to a predetermined hopping frequency interval, an amplifier for amplifying the up-converted frequency signal provided from the frequency up converter, and a duplexer for providing the amplified signal provided from the amplifier to the antenna .

Here, the hopping frequency interval is determined as a frequency interval corresponding to the number of the minimum resource blocks included in the frequency band for object communication, and the frequency up converter updates the center frequency according to the hopping frequency interval and the hopping index, can do.

The object communication apparatus includes a low noise amplifier for amplifying a signal provided from the duplexer, a frequency down converter for down-converting a center frequency of the signal provided from the low noise amplifier to a frequency of a baseband band according to a predetermined hopping frequency interval, And an analog-to-digital converter for converting the signal provided from the frequency down converter to a digital signal.

According to the data transmission method and the object communication apparatus for object communication as described above, the resources for the MTC using the narrow band are divided into the hopping period and the hopping frequency interval preset in the frequency domain of the broadband resource used by the existing communication system Hopping and allocating them. In the time domain of the broadband resource, resources for the MTC are allocated in consideration of the frequency conversion time due to the frequency hopping.

Therefore, the diversity gain can be obtained in the frequency domain without increasing the processing burden of the communication system, thereby increasing the data transmission rate of the MTC apparatus.

In addition, by arranging resources for MTC in consideration of an RF tuning delay time according to frequency hopping, it is possible to prevent a data loss problem that may occur due to hopping of a frequency resource.

1 shows an example of a downlink frame structure for supporting a narrowband MTC terminal.
2 shows an example of an uplink frame structure for supporting a narrowband MTC terminal.
3 is a conceptual diagram for explaining characteristics of a radio channel environment in which the MTC terminal operates.
4 is a block diagram schematically showing the configuration of an MTC terminal according to an embodiment of the present invention.
5 is a conceptual diagram for explaining a frequency hopping method among data transmission methods for MTC according to an embodiment of the present invention.
6 illustrates a hopping pattern of an MTC resource according to an embodiment of the present invention.
7 is a flowchart illustrating a data transmission method for an MTC according to an embodiment of the present invention.
8 is a conceptual diagram for explaining a data transmission method for object communication according to an embodiment of the present invention.
9 is a conceptual diagram for explaining a data transmission method for an MTC according to another embodiment of the present invention.
10 is a conceptual diagram for explaining a data transmission method for an MTC according to another embodiment of the present invention.
11 is a conceptual diagram for explaining a data transmission method for an MTC according to another embodiment of the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail.

It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the relevant art and are to be interpreted in an ideal or overly formal sense unless explicitly defined in the present application Do not.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In order to facilitate the understanding of the present invention, the same reference numerals are used for the same constituent elements in the drawings and redundant explanations for the same constituent elements are omitted.

1 shows an example of a downlink frame structure for supporting a narrowband MTC terminal.

FIG. 1 shows a downlink resource allocation method for a MTC terminal using a narrow band of 1.4 MHz in an LTE system using a frequency band of 20 MHz, for example.

For the 3GPP LTE standard (Release-8 or Release-9), LTE terminals are defined to support 1.4, 3, 5, 10, 15, and 20 MHz bands by default. The reason for supporting a plurality of bandwidths that can be expanded as described above is that the bandwidths supported by the base stations may be different for each region or provider. When a bandwidth of 20 MHz is supported, an LTE terminal can receive data up to 150 Mbps in a 2 × 2 multiple input multiple output (MIMO) operation.

However, the larger the bandwidth to be supported, the greater the complexity and the power consumption of the terminal. Therefore, the above-described structure is not suitable for MTC terminals requiring low-speed data and low power, and the downlink 118.4 kbps, The minimum data transmission rate of 59.2kbps in the uplink can be sufficiently supported by using the bandwidth of 1.4MHz.

On the other hand, even if the bandwidth used by the MTC terminal is smaller than the bandwidth supported by the base station, the base station should be able to support not only the legacy LTE terminal but also the MTC terminal in the same cell.

1 shows an example of a downlink frame for supporting an existing LTE terminal using a 20 MHz band and a MTC terminal using a narrowband of 1.4 MHz at the same time. It is. In Fig. 1, the horizontal axis indicates time and the vertical axis indicates frequency.

In FIG. 1, an area A is a region in which control information for a legacy LTE terminal is transmitted, for example, a physical control format indicator channel (PCFICH), a physical hybrid ARQ indicator channel (PHICH), a physical downlink control channel ) May be assigned to the control channel.

The region B is a region in which data is transmitted to the existing LTE UEs, for example, a data channel such as a PDSCH (Physical Downlink Shared CHannel) may be allocated.

Areas C and D are areas allocated for the MTC. The region C is a region for transmitting control information for the MTC terminal operating in a narrow band of 1.4 MHz, and a control channel for the MTC can be allocated. The region D is a region for transmitting data for the MTC terminal operating in the same band Area, for example, a data channel for MTC such as MTC-PDSCH.

As shown in FIG. 1, the MTC resource can simultaneously support the LTE terminal and the MTC terminal by allocating resources for the narrowband MTC terminal to a wide-band resource area provided for the existing LTE system.

2 shows an example of an uplink frame structure for supporting a narrowband MTC terminal.

FIG. 2 shows an example of an uplink frame for simultaneously supporting an existing LTE terminal using a 20 MHz band and a MTC terminal using a narrowband of 1.4 MHz. It is. In Fig. 2, the horizontal axis indicates time and the vertical axis indicates frequency.

In FIG. 2, an area A is a region in which UL data of an existing LTE terminal is transmitted, for example, a data channel such as a PUSCH (Physical Uplink Shared CHannel) may be allocated.

The region B is a region to which a signal for estimating an uplink channel of an existing LTE terminal is transmitted, for example, a sounding reference signal may be allocated.

Areas C and D are areas allocated for uplink transmission of data and control information for the MTC. Area C may be used for transmission of an uplink demodulation reference signal of a MTC terminal operating in a narrow band of 1.4 MHz and area D may be used for transmitting uplink data of a MTC terminal operating in the same band Area, for example, MTC-PUSCH.

As shown in FIG. 2, the uplink resources for the MTC terminal operating in the narrow band can be allocated in a multiplexing manner with the uplink resources of the existing LTE terminal operating in the wide band.

In general, MTC traffic is characterized by a type that transmits data in an uplink every predetermined period at a low data rate, a type that transmits data in an event driven manner under the control of a base station, (Bulky data), and the amount of data transmitted through the uplink is larger than the amount of data transmitted through the downlink.

On the other hand, the wireless channel environment to which MTC is applied generally has many applications in a fixed or low-speed mobile environment rather than a high-speed mobile environment of the MTC terminal.

Accordingly, a method of using a plurality of antennas such as MIMO may be considered as a method of increasing the data transmission capacity of the MTC terminal. However, considering the requirement to implement the MTC terminal at low cost, a plurality of antennas are implemented in the MTC terminal Which can be a cost burden.

In order to solve the above problem, instead of mounting a plurality of antennas in the MTC terminal, it is possible to consider a capacity increase through diversity in the time or frequency domain. Here, when a communication environment in which the MTC terminal is fixedly installed or moves at a low speed is assumed, it is preferable to consider the diversity gain in the frequency domain rather than in the time domain.

Meanwhile, in order to obtain the diversity gain in the frequency domain, the BS scheduler needs to know the channel state for each MTC terminal located in the service area.

However, it is practically difficult for the base station scheduler to grasp the radio channel status of all the MTC terminals. Even if the base station scheduler knows the radio channel status for all the MTC terminals, the MTC terminals It is burdensome to perform adaptive scheduling on the network. Therefore, a method for acquiring the diversity gain in a direction that does not place burden on the existing MAC (Medium Access Control) scheduler is required.

The present invention increases the data rate of the MTC terminal by acquiring the frequency diversity gain through hopping of the frequency resource allocated to the MTC terminal in consideration of the above-mentioned matters. Also, in the present invention, the MTC resources are arranged in the time domain in consideration of the RF tuning delay time, thereby preventing a data loss problem that may occur due to hopping of frequency resources.

Hereinafter, a data transmission method for object communication according to an embodiment of the present invention will be described in more detail with reference to FIG. 3 to FIG.

3 is a conceptual diagram for explaining characteristics of a radio channel environment in which the MTC terminal operates.

3 (a) shows a radio resource allocated for the MTC. In FIG. 3, a frame structure for simultaneously supporting an existing LTE terminal using a wideband of 20 MHz and a MTC terminal using a narrowband of 1.4 MHz, for example, Respectively.

In FIG. 3A, areas C and D are areas allocated for the MTC terminal, area C is an area for transmitting control information for the MTC terminal operating in a narrow band of 1.4 MHz, Indicates an area for transmitting data for an operating MTC terminal.

On the other hand, as shown in FIG. 3 (b), when the wireless channel characteristic is not very good in a frequency band allocated to a MTC terminal that is fixedly installed or moves at a low speed, a problem may occur in data transmission / reception of the MTC terminal. Although the packet transmission period of the MTC terminal can be predicted according to the application environment of the MTC, if the MTC terminal has a transmission period of several tens of msec or more, the performance deterioration becomes inevitable.

In addition, if an error occurs in the data transmitted by the MTC terminal, it is possible to recover the error data through the existing retransmission technique. However, since it is difficult to apply retransmission from a very large number of all MTC terminals in practice, There is a need for a way to cope with poor radio channels, independent of whether or not it is possible.

The present invention provides a method for improving the data transmission performance of the MTC terminal even in a wireless channel environment as shown in FIG.

FIG. 4 is a block diagram schematically showing the configuration of an MTC terminal according to an embodiment of the present invention, and shows components that perform uplink and downlink signal transmission in the MTC terminal, for example.

Referring to FIG. 4, the MTC terminal includes a transmitter 410 for performing a process for transmitting a signal through an uplink, and a receiver 430 for receiving a signal through a downlink and processing the received signal .

The transmitting unit 410 and the receiving unit 430 can receive or transmit signals using one antenna 470. The transmitting unit 410 and the receiving unit 430 can receive signals through the duplexer 450, (470). That is, the duplexer 450 performs a function of branching signals between the antenna 470, the transmitter 410 and the receiver 430.

The transmitter 410 may include a baseband processing unit 411, a digital-to-analog converter 413, a frequency up-converter 415, and an amplifier 417.

The analog-to-digital converter 413 converts the digital data into an analog signal and then outputs the digital data to the frequency up converter 415. The frequency up converter 415 converts the digital data into an analog signal, .

The frequency up converter 415 mixes the signal of the low frequency band provided from the digital-analog converter 413 with the high reference signal f _u of the high frequency provided from the local oscillator or the like to raise the frequency of the analog signal to the RF band Conversion.

The amplifier 417 amplifies the analog signal having the frequency up-converted to the RF band so as to be transmittable through the antenna 470, and provides the amplified analog signal to the duplexer 450.

The receiver 430 may include a low noise amplifier (LNA) 431, a frequency down converter 433, an analog-to-digital converter 435, and a baseband processor 437.

The low noise amplifier 431 receives the weak signal received via the antenna 470 through the duplexer 450 and amplifies the received weak signal to provide the amplified weak signal to the frequency down converter 433. [

The frequency down converter 433 mixes the analog signal provided from the low noise amplifier 431 with the downward reference signal f _{d of} the RF band to down convert the analog signal of the RF band to the frequency of the base band band.

The analog-to-digital converter 435 converts the analog signal having the down-converted frequency band into digital data and provides it to the base band processing means 437. The base bend processing means 437 receives the analog- And processes the provided digital data.

The data transmission method for MTC according to an embodiment of the present invention applies a frequency hopping technique to prevent data transmission / reception errors of the MTC terminal according to frequency selective characteristics as shown in FIG.

Specifically, in the present invention, the up reference signal f _u and the down reference signal f _d input to the frequency up converter 415 and the frequency down converter 433 shown in FIG. 4 are applied as shown in Equation 1 Hopping frequency resources for MTC.

는 주파수 상향변환을 위한 중심 주파수를 의미하며,

는 주파수 하향변환을 위한 중심 주파수를 의미한다. 또한, i는 정수로 구성되는 호핑 인덱스를 의미하고, Δf는 호핑의 기본 단위가 되는 주파수 오프셋(offset) 또는 주파수 간격을 의미한다.In Equation (1)

Denotes a center frequency for frequency up conversion,

Means the center frequency for frequency down conversion. Also, i means a hopping index composed of an integer, and? F means a frequency offset or a frequency interval serving as a basic unit of hopping.

On the other hand, the frequency hopping interval may be determined by the number of resource blocks (RBs) included in the frequency band allocated for the MTC. For example, if the MTC terminal uses the frequency band of 1.4 MHz and the frequency band of 1.4 MHz is composed of six resource blocks in total, assuming that hopped resources do not overlap, Hopping. In addition, when one resource block is composed of 12 subcarriers and the subcarrier interval is 15 kHz, one resource block has a band of 180 kHz, and six resource blocks have a frequency interval of 1.08 MHz , This frequency interval becomes the hopping frequency interval.

The hopping index i may have a value of 0 to i _max -1, and i _max may be determined as shown in Equation (2). Also, i can be shared between the base station and the MTC terminals connected to the specific cell operated by the base station, and can be shared in the form of a table.

는 전체 시스템 대역에 포함된 자원 블록의 수를 의미하고,

는 MTC 단말에 할당된 자원 블록의 수를 의미한다.
In Equation (2)

Denotes the number of resource blocks included in the entire system band,

Denotes the number of resource blocks allocated to the MTC terminal.

FIG. 5 is a conceptual diagram for explaining a frequency hopping method among data transmission methods for MTC according to an embodiment of the present invention. Referring to FIG. 5, frequency hopping when a 1.4 MHz band is allocated as an MTC resource to a 20 MHz band, .

Referring to FIG. 5, a radio resource can be roughly divided into an area A for transmitting control information and an area B for transmitting data in the LTE system in the LTE system, and areas C and D to which radio resources for MTC are allocated And may be multiplexed and allocated in an area B for transmitting data in the LTE system.

As shown in FIG. 5, when a system band of 20 MHz is composed of 110 resource blocks (RB) and a band of 1.4 MHz allocated for MTC is composed of 6 resource blocks, a frequency of 1.4 MHz band for MTC The resource can be hopped at a frequency interval corresponding to six resource blocks, which is a minimum resource block unit.

That is, the interval between the subframe # 0 and the subframe # 1, which are radio resources allocated for the MTC in FIG. 5, may have a frequency interval corresponding to six resource blocks.

Meanwhile, in the data transmission method for object communication according to an embodiment of the present invention, a hopping period can be determined by considering an index of a subframe and i _max , which is a maximum value of a hopping index i, Can be determined by doubling.

FIG. 6 illustrates a hopping pattern of an MTC resource according to an exemplary embodiment of the present invention, and illustrates a hopping pattern when the hopping period is 1, for example.

Referring to FIG. 6, when the hopping period is 1, frequency hopping for an MTC resource is performed for each subframe, so that the resource for MTC is divided into consecutive surf frame n, subframe n + 1, and subframe n + 2 The center frequency may be hopped in such a manner that the center frequency increases by a predetermined frequency interval (for example, the band of the MTC terminal) every time the index n of the subframe increases.

For example, if the frequency band allocated to the MTC terminal is 1.4 MHz and the resource block is composed of 6 resource blocks, the resource for the MTC terminal is increased by a frequency band corresponding to 6 resource blocks every time the index of the subframe increases Resources can be allocated.

In the meantime, when a MTC terminal is allocated a resource by hopping a frequency to transmit and receive a signal, the MTC terminal or the base station receiving the frequency-hopped signal transmits the frequency of the RF element to the frequency hopped according to the hopping period If RF tuning delay time is not taken into account, tuning is not possible and data loss may occur.

Depending on the implementation technology of the RF device, there may be some differences, but the time required for the RF device to tune the frequency is about 300us. Although the frequency tuning time of such an RF device can be shortened according to the development of the device implementation technology, considering that the length of one OFDM symbol defined in the LTE standard specification is less than 70us, It corresponds to the missing time.

Therefore, in the present invention, resources are allocated to the MTC terminal in consideration of the frequency hopping period and the RF tuning delay time (T _{RF_Tuning} ) for the MTC terminal.

FIG. 7 is a flowchart illustrating a data transmission method for object communication according to an embodiment of the present invention, and may be performed in a communication device (for example, a base station) that allocates resources to the MTC terminal. Hereinafter, for convenience of description, the communication apparatus performing the data transfer method shown in FIG. 7 will be referred to as a resource allocation apparatus.

Referring to FIG. 7, the resource allocation apparatus obtains information on an RF tuning delay time (T _{RF_Tuning} ) of an apparatus performing RF tuning (S701). The apparatus for performing RF tuning herein refers to a communication apparatus that receives a frequency hopped signal for the MTC and may include, for example, a base station, a repeater, an MTC terminal, and the like. The RF tuning delay time (T _{RF_Tuning} ) can be obtained by measuring specification information or RF tuning delay time of a corresponding RF element performing frequency conversion in accordance with frequency hopping.

Then, the resource allocation unit is determined whether the RF tuning the delay time (T _{RF_Tuning)} and a control information transmission interval (D _CTL) compared to, RF tuning the delay time (T _{RF_Tuning),} a control information transmission interval (D _CTL) corresponds to less than a (S703). Here, the control information transmission interval D _CTL denotes a time of an area in which control information is transmitted in a resource of an existing communication system (for example, an LTE system).

As a result of the determination in step S703, if the RF tuning delay time T _{RF_Tuning} is less than or equal to the control information transmission interval D _CTL , the resource allocation apparatus allocates resources for the MTC terminal to the frequency domain In step S705, a length corresponding to the time length of the data transmission area of the existing communication system is allocated in each subframe in the time domain. For example, the resources for the MTC in the time domain may be allocated with a length equal to the time length of the data transmission domain of the LTE system.

Here, the hopping period may be set to an integral multiple of the subframe, and the frequency hopped may be determined using Equation (1). Further, the hopping frequency interval? F may be determined to be a frequency interval corresponding to a preset number of resource blocks. For example, if the frequency band used by the MTC terminal is 1.4 MHz and consists of six resource blocks, the frequency interval? F may be set to a frequency interval corresponding to six resource blocks.

If the RF tuning delay time T _{RF_Tuning} is less than or equal to the control information transmission interval D _CTL , since the MTC terminal has already completed the frequency change at the time of receiving the control or data channel allocated thereto, The assigned signal can be normally demodulated. Accordingly, resources for the MTC are allocated to the area between the start and end of the data transmission interval (or data channel allocation interval) in each subframe of the existing communication system (i.e., the start time of the control area of the next subframe) . In this case, the resources for the MTC can be divided into an area in which control information is transmitted and an area in which data is transmitted. In the order in which each area is located, an area in which control information is transmitted is first allocated in the time domain, Lt; / RTI > may be assigned. Alternatively, an area where data is transmitted may be allocated in the time domain and then an area in which the control information is transmitted.

7, if it is determined in step S703 that the RF tuning delay time T _{RF_Tuning} is greater than the control information transmission interval D _CTL , the resource allocation apparatus determines that the hopping period (C _Hopping ) (S707). Here, the hopping period may be set to an integral multiple of the subframe.

If it is determined in step S707 that the hopping period is smaller than 2, it means that the hopping period is every frame. Therefore, the resource allocation apparatus allocates MTC resources to the data transmission area in each subframe of the existing communication system for each subframe , MTC allocates resources taking into account the time difference as much as (ΔT _{RF_Tuning)} of the RF tuning the delay time (T _{RF_Tuning)} and a control information transmission interval (D _CTL) (S709).

For example, if the RF tuning delay time (T _{RF_Tuning} ) is greater than the control information transmission interval (D _CTL ) and the hopping period is less than 2, the resource allocation apparatus allocates, at each subframe, An MTC resource is allocated, and an area for data transmission among the MTC resources is allocated first, and then an area for transmission of control information is allocated next. In this case, since the RF tuning has not been completed at the time when the MTC data is received, the received MTC data may be lost during the RF tuning delay time.

In order to prevent the above-described data loss, in the present invention, when the RF tuning delay time T _{RF_Tuning} is greater than the control information transmission period D _CTL and the hopping period is less than 2, After the time difference (DELTA T _{RF_Tuning} ), the MTC resource is allocated, and the resource for data transmission is first allocated and then the resource for control information transmission is allocated. When the MTC resource is allocated as described above, the number of OFDM symbols that can be allocated to the interval corresponding to the time difference [Delta] T _{RF_Tuning} decreases, and spectrum loss may occur, but no problem occurs in data reception.

Alternatively, in the present invention, when the RF tuning delay time T _{RF_Tuning} is greater than the control information transmission interval D _CTL and the hopping period is less than 2, the MTC resource is allocated from the start point of the data area of each subframe, The MTC data area is allocated in the order of the information area and the MTC data area, and the area for the MTC data is allocated to the area before the time difference DELTA T _{RF_Tuning} at the boundary with the next sub frame. Then, the frequency changing process is started at a time point that is earlier by the time difference (DELTA T _{RF_Tuning} ) than the boundary between the two sub-frames from the second hopping period (i.e., the end of the data transmission region of the first sub-frame). That is, in the present invention, considering the RF tuning delay time, the frequency change is started at a time point earlier by the time difference (DELTA T _{RF_Tuning} ) than the boundary time of each subframe, so that before the control region for MTC starts, Thereby completing the demodulation of the MTC control signal due to the RF tuning delay.

Referring again to FIG. 7, if it is determined in step S707 that the hopping period corresponds to two or more, the resource allocation apparatus determines the position of the subframe to which the MTC resource is to be allocated for each hopping period composed of a plurality of subframes (S711 ), The same method as in step S705 is applied to the subframes located before the last subframe of each hopping cycle, hopping and allocating resources for the MTC terminal in the frequency domain according to the predetermined frequency interval and the hopping period, The length corresponding to the time length of the data transmission area of the existing communication system in each subframe is allocated (S713).

On the other hand, if it is determined in step S711 that the target subframe to be allocated corresponds to the last subframe of each hopping period, the resource allocation apparatus applies RF tuning delay time (T _{RF_Tuning} ) and control information transmission MTC resources are allocated considering the time difference (DELTA T _{RF_Tuning} ) of the interval (D _CTL ).

For example, when the hopping period is configured in units of two subframes, it is not necessary to change frequency between two consecutive subframes included in one hopping period. Therefore, the first subframe is used for data transmission And allocates the MTC resource with the same length as the time length of the area. However, since the center frequency of the MTC resource is changed according to the preset frequency interval in the second subframe corresponding to the last subframe and the first subframe forming the next hopping period among the two subframes constituting the hopping period, RF tuning delays due to changes should be considered. Therefore, as described in step S709, the MTC resource is allocated from the start point of the data area to the MTC control information and the MTC data in the order of the MTC control information and the MTC data, and the resource for the MTC data is time- (? T _{RF_Tuning} ), and starting the frequency changing process from the time point earlier by the time difference? T _{RF_Tuning} than the boundary of each sub-frame can be applied.

8 is a conceptual diagram for explaining a data transmission method for object communication according to an embodiment of the present invention.

8, when the hopping period is 1 (i.e., one subframe length) and the hopping frequency interval is set to the minimum resource block unit, the RF tuning delay time T _{RF_Tuning} is less than the control information transmission interval D _CTL The resource allocation method for the MTC in the case of small or the same is shown as an example.

As shown in FIG. 8, when the RF tuning delay time T _{RF_Tuning} is less than or equal to the control information transmission interval D _CTL , the frequency change is _{detected at the} time when the MTC terminal receives the control and data channels allocated thereto It is possible to normally demodulate the signal that has already been completed and allocated to itself. Therefore, resources for the MTC terminal are hopped and allocated by a preset frequency interval f for each subframe, and MTC resources (CD Is allocated in each subframe by the same length as the time length _Tc of the data transmission area B of the existing communication system.

9 is a conceptual diagram for explaining a data transmission method for an MTC according to another embodiment of the present invention.

9, when the hopping period is 1 (i.e., one subframe length) and the hopping frequency interval is set as a minimum resource block unit, the RF tuning delay time T _{RF_Tuning} is set to be larger than the control information transmission period D _CTL A resource allocation method for MTC in a large case is shown as an example.

When the RF tuning delay time T _{RF_Tuning} is greater than the control information transmission interval D _CTL , as shown in FIG. 9, the frequency hopping is performed by a predetermined frequency interval f according to the index increase of the subframe, .

In the time domain, the MTC resource is allocated after a time difference (DELTA T _{RF_Tuning} ) from the start time of the data area B of each subframe, the resource D for data transmission among the MTC resources is allocated first, And subsequently allocates a resource C for transmission. When the MTC resource is allocated as described above, the number of OFDM symbols that can be allocated to the interval corresponding to the time difference [Delta] T _{RF_Tuning} decreases, and spectrum loss may occur, but no problem occurs in data reception.

10 is a conceptual diagram for explaining a data transmission method for an MTC according to another embodiment of the present invention.

10, when the hopping period is 1 (i.e., one subframe length) and the hopping frequency interval is set to the minimum resource block unit, the RF tuning delay time T _{RF_Tuning} is less than the control information transmission interval D _CTL Another example of the resource allocation method for the MTC in the large case is shown.

Referring to FIG. 10, when the RF tuning delay time T _{RF_Tuning} is greater than the control information transmission interval D _CTL , in the frequency domain, the frequency is hopped by a preset frequency interval f according to the index increase of the subframe, Allocates resources in the order of the area C for the MTC control information and the area D for the MTC data in the time domain, allocating the MTC resources from the starting point of the data area B of each subframe, And the resource for the MTC data is allocated until a time point corresponding to the time difference? T _{RF_Tuning} at the boundary 1001 where the index of the subframe is changed.

As shown in FIG. 10, when the MTC resource is allocated, a process for changing the frequency is performed at a time point earlier than the boundary 1001 of the subframe from the second subframe (i.e., subframe n + 1) by a time difference? T _{RF_Tuning} Start.

That is, in consideration of the RF tuning delay time, the frequency change is started at a time point earlier by the time difference (DELTA T _{RF_Tuning} ) than the boundary time of each subframe, so that frequency change is completed at or before the end of demodulation of the control region in each subframe .

11 is a conceptual diagram for explaining a data transmission method for an MTC according to another embodiment of the present invention.

11, the RF tuning delay time T _{RF_Tuning} is greater than the control information transmission interval D _CTL when the hopping period is 2 (i.e., two sub-frame length units) and the hopping frequency interval is set to the minimum resource block unit An example of the resource allocation method for the MTC case is shown.

Referring to FIG. 11, when the RF tuning delay time T _{RF_Tuning} is greater than the control information transmission interval D _CTL and the hopping period is 2, the interval between consecutive two consecutive subframes included in one hopping period , And subframes n and n + 1 have the same frequency resource, the first subframe (subframe n) allocates time-domain resources in the same manner as in FIG.

However, the second subframe (subframe n + 1) corresponding to the last subframe and the first subframe (subframe n + 2) included in the next hopping period among the subframes constituting the hopping period are divided into a hopping frequency interval (Sub-frame n + 2) of the next hopping cycle, and the RF tuning delay time corresponding thereto must be considered.

Therefore, as shown in FIG. 11, the MTC resource is allocated from the start time 1101 of the data area B of the last subframe (subframe n + 1) among the subframes constituting the hopping cycle, Resources are allocated in the order of the region C and the MTC data region D and resources for the MTC data are allocated to the time point (or region) as early as the time difference? T _{RF_Tuning} at the boundary 1103 of the subframe, A method of starting the frequency changing process from a time point earlier by the time difference? T _{RF_Tuning} than the boundary is applied.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. It will be possible.

410: Transmitting section 411: Baseband processing means
413: digital-to-analog converter 415: frequency up converter
417: Amplifier 430: Receiver
431: low noise amplifier 433: frequency down converter
435: Analog-to-digital converter 437: Baseband processor
450: Duplexer 470: Antenna

Claims (17)

A data transmission method for object communication performed in a communication device supporting object communication,
Dividing each of a plurality of subframes constituted of time resources and frequency resources into a first control region for transmitting control information of a first communication and a first data region for transmitting data of the first communication; And
A second control region for transmitting the control information of the object communication to the first data region of each of the plurality of subframes according to a predetermined hopping period and a hopping frequency interval and a second control region for transmitting the object communication data And allocating a second data area to the second data area. The method according to claim 1,
Wherein each of the second control region and the second data region includes a plurality of resource blocks each having a frequency band narrower than the plurality of subframes and wherein the hopping frequency interval includes a minimum resource included in a frequency band for the object communication Wherein the frequency interval is determined by a frequency interval corresponding to the number of blocks. The method according to claim 1,
The center frequency of the resource for the object communication allocated to each of the second control region and the second data region of the predetermined subframe among the plurality of subframes is determined by a predetermined hopping frequency interval and a hopping index. A method for data transmission for object communication. The method of claim 3,
Wherein the hopping index is an integer equal to or greater than 0 and the maximum value of the hopping index is determined by the number of resource blocks included in a plurality of subframes and the number of resource blocks allocated for object communication. / RTI > The method of claim 3,
Wherein the hopping index is shared by a transmitting device and a receiving device that perform object communication. The method of claim 3,
Wherein the hopping period is determined based on at least one of an index of the subframe and a maximum value of the hopping index. The method according to claim 1,
Wherein the hopping period is determined to be an integer multiple of the subframe. The method according to claim 1,
Wherein the assigning comprises:
And a second control section for receiving the object communication data in the time domain of the first data area in consideration of the time difference between the frequency conversion delay time of the receiving device for receiving the object communication data and the time interval of the first control area, 2 < / RTI > control area and the second data area. The method of claim 8,
Wherein the assigning comprises:
When the frequency conversion delay time is less than or equal to a time interval of the first control area, the second control area and the second data area for the object communication are allocated in the same interval as the time interval of the first data area And transmitting the data to the object communication device. The method of claim 8,
Wherein the assigning comprises:
When the frequency conversion delay time is larger than the time interval of the first control region and the hopping period corresponds to one subframe length, the frequency conversion delay time at the start time of the first data region of each subframe And the second control region and the second data region for the object communication are allocated from a time point after a time difference between the first control region and the time interval of the first control region. The method of claim 10,
Wherein the assigning comprises:
Wherein resources for transmitting data among the resources for the object communication are first allocated in the time domain. The method of claim 8,
Wherein the assigning comprises:
When the frequency conversion delay time is greater than a time interval of the first control region and the hopping period corresponds to one subframe length, Wherein the second control region and the second data region are allocated to the second control region and the second control region for the object communication until a time point corresponding to a time difference between the frequency conversion delay time and the time interval of the first control region, And a data area is allocated to the data area. The method of claim 12,
Wherein the assigning comprises:
Wherein resources for transmitting control information among the resources for the object communication are first allocated in the time domain. The method of claim 12,
Wherein the assigning comprises:
Wherein the receiving apparatus for receiving the object communication data starts the frequency conversion process from the point of time when the region of the resource allocated for the object communication allocated to the first data region of each subframe ends. Data transmission method. A digital-to-analog converter for converting a digital signal of a baseband band into an analog signal;
A frequency up converter for up-converting the center frequency of the analog signal provided from the digital-analog converter according to a predetermined hopping frequency interval;
An amplifier for amplifying the frequency up-converted signal provided from the frequency up-converter; And
And a duplexer for providing an amplified signal provided from the amplifier to the antenna,
Wherein each of the plurality of subframes in the amplified signal is divided into a first control region for transmitting control information of a first communication and a first data region for transmitting data of the first communication, Wherein a second control area for transmitting control information of object communication and a second data area for transmitting data of the object communication are allocated to the first data area of each of the plurality of subframes in accordance with a frequency interval, Device. 16. The method of claim 15,
The hopping frequency interval is determined as a frequency interval corresponding to the number of the minimum resource blocks included in the frequency band for object communication, and the uplink frequency converter up-converts the center frequency according to the hopping frequency interval and the hopping index Wherein the object communication device comprises: 18. The method of claim 16,
The object communication apparatus includes:
A low noise amplifier for amplifying a signal provided from the duplexer;
A frequency down converter for down-converting a center frequency of a signal provided from the low noise amplifier to a frequency of a baseband band according to a predetermined hopping frequency interval; And
Further comprising an analog-to-digital converter for converting a signal provided from said frequency down-converter into a digital signal.

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