KR102033360B1 - Method and apparatus of resource allocation for machine type communication device, method and apparatus for receiving data for machine type communication - Google Patents

Abstract

Disclosed is a resource allocation method for a MTC device. A method of allocating a resource for a MTC device may include allocating a control channel for a user terminal in a first time domain of a subframe, a control channel for at least one MTC device in a second time domain of a subframe, and a user terminal. And allocating at least one of a data channel for and a data channel for the MTC device. Therefore, it is possible to transmit and receive control information and data to the MTC device while maintaining compatibility with the user terminal in the wireless communication system.

Description

TECHNICAL AND METHOD AND APPARATUS FOR RECEIVING DATA FOR MACHINE TYPE COMMUNICATION}

The present invention relates to machine type communication, and more particularly, to a method and apparatus for allocating a resource for an IoT communication device in a mobile communication system, and a method and apparatus for receiving IoT communication data.

Machine type communication or machine to machine communication refers to a form of data communication associated with one or more entities for which human intervention is not necessary. Services optimized for telecommunications differ from services optimized for human-to-human communications, including: a) different market scenarios, b) data communications, c) lower cost and effort, and d) a very large number of potential communications. Terminals, e) differ from current mobile network communications in that they relate to characteristics such as very little traffic per terminal, up to a large range.

IoT can appear in various forms of services, such as Smart Metering, Tracking & Tracing, Remote Maintenance & Control, and eHealth.

Recently, 3GPP is also progressing MTC (Machine Type Communication) standardization for intelligent communication between people and objects, and between objects and objects. A large number of MTC devices are deployed and operated for various MTC applications, such as smart metering and remote control.

In the 3GPP LTE system, both the MTC device and the general terminal are treated as one terminal (UE) and must be individually registered in the LTE network. The arrangement of the plurality of MTC devices causes scheduling competition for channel allocation, exhaustion of radio resources, overload due to signal generation, and so on, and thus adversely affects the existing general terminal.

In addition, in a 3GPP LTE system, a UE may access an eNodeB having a bandwidth of 1.4 MHz, 3 MHz, 5 MHz, 10 MHz, 15 MHz, or 20 MHz, but the MTC device generally transmits a small amount of data. Supporting a bandwidth of up to 20 MHz, such as a terminal, to an MTC device is a waste of frequency resources, and a significant cost is wasted for an MTC device for low cost.

An object of the present invention for solving the above problems is to provide a resource allocation method for a MTC device having a narrow bandwidth while maintaining compatibility with the user terminal.

Another object of the present invention is to provide an apparatus for allocating a resource for an MTC device having a narrow bandwidth while maintaining compatibility with a user terminal.

Another object of the present invention is to provide a method for receiving MTC data having a narrow bandwidth while maintaining compatibility with a user terminal.

Further, another object of the present invention is to provide an MTC data receiving apparatus having a narrow bandwidth while maintaining compatibility with a user terminal.

According to an aspect of the present invention, there is provided a method for allocating resources to at least one MTC device, the method comprising: allocating a control channel for a user terminal in a first time domain of a subframe; And allocating at least one of a control channel for the at least one MTC device, a data channel for the user terminal, and a data channel for the MTC device in the second time domain of the subframe. have.

Here, the control channel for the MTC device and the data channel for the MTC device may be divided into a data channel for the user terminal and a frequency division multiplexing (FDM).

Here, the control channel for the MTC device may be any one of a data channel and a time division multiplexing (TDM), frequency division multiplexing, and time division multiplexing and frequency division multiplexing combined for the MTC device. Can be distinguished.

In addition, the method for allocating a resource for an IoT communication device may further include transmitting information about an area occupied by a control channel of the IoT communication device to the IoT communication device.

Here, the transmitting of the information about the area occupied by the control channel for the MTC device to the MTC device may include higher layer signaling of a physical layer or higher for information on the area occupied by the control channel for the MTC device; The apparatus may transmit to the at least one MTC device through any one of a broadcast channel for the user terminal for transmitting system information to the user terminal and a separate physical control channel for the MTC device.

Here, the information about the area occupied by the control channel for the MTC device may include a start symbol number of the control channel for the MTC device, an end symbol number, a start symbol number of the data channel for the MTC device, and the MTC. And at least one of the number of symbols occupied by the control channel for the device, the number of resource blocks (RBs), the number of subcarriers, the number of subcarrier groups, the number of resource block groups, and a configuration index. have.

An apparatus for allocating resources to at least one MTC device according to an embodiment of the present invention for achieving another object of the present invention, allocates a control channel for a user terminal to a first time domain of a subframe And a resource allocator configured to mix and allocate at least one of a control channel for the at least one MTC device, a data channel for the user terminal, and a data channel for the MTC device in the second time domain of the subframe. have.

The apparatus for allocating a resource for an MTC device may further include a transmitter configured to transmit information regarding an area occupied by a control channel of the MTC device to the MTC device.

Here, the transmitter may be configured to transmit information about a region occupied by the control channel of the MTC device to a higher layer signaling of a physical layer or higher, a broadcast channel to a user terminal for transmitting system information to the user terminal, and the MTC device. It may transmit to the at least one MTC device through any one of a separate physical control channel.

According to another aspect of the present invention, there is provided a method for receiving MTC data, comprising: information about a region occupied by a control channel of an MTC device including higher layer signaling above a physical layer; Receiving through one of a broadcast channel for a user terminal for transmitting system information from a base station to a user terminal and a separate physical control channel for the MTC device, and occupied by a control channel for the MTC device; And receiving the MTC data based on the information about the area.

Here, the information about the area occupied by the control channel for the MTC device may include a start symbol number of the control channel for the MTC device, an end symbol number, a start symbol number of the data channel for the MTC device, and the MTC. And at least one of the number of symbols occupied by the control channel for the device, the number of resource blocks (RBs), the number of subcarriers, the number of subcarrier groups, the number of resource block groups, and a configuration index. have.

According to another aspect of the present invention, there is provided an apparatus for receiving telecommunication data, wherein information about an area occupied by a control channel for an MTC device includes higher layer signaling, which is higher than a physical layer, A receiver which receives a broadcast channel for a user terminal for transmitting system information from a base station to a user terminal and a separate physical control channel for the MTC device, and a control channel for the MTC device It may include a control unit for receiving the MTC data based on the information on the area.

According to the resource allocation method and apparatus for an IoT communication device and the IoT communication data receiving method and apparatus according to the present invention, for example, with a user terminal in a wireless communication system such as a 3GPP LTE-based mobile communication system Control information and data can be transmitted to the MTC device while maintaining compatibility, thereby providing the MTC service.

1 is a conceptual diagram illustrating a structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
2 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an IoT communication device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
3 is a conceptual diagram illustrating yet another structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
4 is a conceptual diagram illustrating a structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
5 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
FIG. 6 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
7 is a conceptual diagram illustrating a structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
8 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
FIG. 9 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an IoT communication device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
10 is a flowchart illustrating a resource allocation method for at least one MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.
11 is a flowchart illustrating a method of receiving MTC data while maintaining compatibility with a user terminal according to an exemplary embodiment of the present invention.
12 is a block diagram illustrating a configuration of a resource allocation apparatus and an IoT communication data receiving apparatus for an IoT communication device according to an embodiment of the present invention.

As the invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the drawings, similar reference numerals are used for similar elements.

Terms such as first, second, A, and B may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component. The term and / or includes a combination of a plurality of related items or any item of a plurality of related items.

When a component is referred to as being "connected" or "connected" to another component, it may be directly connected or connected to that other component, but other components may be present in between. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that no other component exists in the middle.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination 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. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art, and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

In the present specification, embodiments of the present invention focus on resource allocation for data transmission and reception between a base station and a user terminal, a base station and a machine type communication device, and the base station directly communicates with the user terminal and the IoT device. It may be a terminal node of a network that performs the operation. In addition, certain operations described as being performed by the base station herein may be performed by an upper node of the base station in some cases.

In the present specification, the base station may be replaced with terms such as a fixed station, a Node B, an eNode B (eNB), an access point, and the like, and the user terminal may be a mobile station (MS) or a UE (User). Equipment, Subscriber Station (SS), Mobile Subscriber Station (MSS), Mobile Terminal (Mobile Terminal) and the like can be replaced with. The mobile terminal includes various devices such as a PDA (Personal Digital Assistant), a cellular phone, a Personal Communication Service (PCS) phone, a Global System for Mobile (GSM) phone, a Wideband CDMA (WCDMA) phone, and a Mobile Broadband System (MBS) phone. Can be.

In addition, the machine application type (Machine Application Type) of the communication device is increasing, and the type of application of the device is Security (Security), Public Safety (Tracking), Tracing (Tracing), Payment (Payment) , Logistics Management in Healthcare, Remote Maintenance and Control, Metering, Consumer Device, Point of Sales and Security-Related Applications Management, vending machine-to-device communication, remote monitoring of machines and facilities, time measurement on construction machinery and smart metering to automatically measure heat or electricity usage, surveillance video from surveillance cameras (Surveillance Video) communication, but the present invention is not limited thereto. The MTC device may include various apparatuses that perform types other than the above-described application type. Can be.

Meanwhile, embodiments of the present invention may be implemented by various means such as hardware, firmware, software, or a combination thereof. For hardware implementations, at least one Application Specific Integrated Circuits (ASICs), Digital Signal Processors (DSPs), Digital Signal Processing Devices (DSPDs), Programmable Logic Devices (PLDs), Field Programmable Gate Arrays (FPGAs), processors, It may be implemented through a controller, a microcontroller, a microprocessor, or the like.

In the case of an implementation by firmware or software, it may be implemented in the form of a module, procedure, or function that performs a function or an operation, and the software code may be executed by a processor stored in a memory device, and the memory device may be internal to the processor or It may be located outside to transmit and receive data with the processor by various means.

On the other hand, the user terminal data channel described herein refers to a channel used by the base station for transmitting data for the user terminal, for example, Physical Downlink Shared CHannel specified in the 3GPP LTE-based wireless communication standard ) May be used.

In addition, the MTC device data channel refers to a channel used by a base station to transmit data for an MTC device. For example, a physical downlink shared channel (PDSCH), etc., which is specified in a 3GPP LTE-based wireless communication standard. This may mean used as a channel (MTC-PDSCH) for the MTC device.

In addition, the user terminal control channel described in this specification is for the base station to transmit control information for demodulating a data channel (eg, PDSCH specified in the 3GPP LTE-based wireless communication standard) for the user terminal to the user terminal. The channel may be used, and may mean, for example, a physical downlink control channel (PDCCH) specified in a 3GPP LTE-based wireless communication standard.

In addition, the MTC device control channel refers to a channel used by the base station to transmit control information for demodulating a data channel for the MTC device to the MTC device. For example, the 3GPP LTE-based wireless communication standard may be used. It may mean that the specified physical downlink control channel (PDCCH) or the like is used as a channel (MTC-PDSCH) for the MTC device.

In addition, the user terminal control format indicator channel described herein refers to a channel for transmitting information about the number of OFDM symbols occupied by the control channel for the user terminal, for example, specified in the 3GPP LTE-based wireless communication standard It may mean a Physical Control Format Indicator CHannel (PCFICH).

In addition, the MTC device control format indicator channel means a channel for transmitting information on the number of OFDM symbols occupied by the control channel for the MTC device, and is, for example, the PCFICH specified in the 3GPP LTE-based wireless communication standard. Etc. may be used as a channel (MTC-PCFICH) for the MTC device.

In addition, the user terminal HARQ indicator channel described herein refers to a channel for transmitting ACK / NACK information for the uplink of the data channel for the user terminal, for example, which is specified in the 3GPP LTE-based wireless communication standard It may mean PHICH (Physical Hybrid-ARQ Indicator CHannel).

In addition, the communication device HARQ indicator channel means a channel for transmitting the ACK / NACK information for the uplink of the data channel for the IoT communication device, for example, PHICH specified in the 3GPP LTE-based wireless communication standard, etc. This may mean used as a channel (MTC-PHICH) for the MTC device.

In addition, the user terminal broadcast channel described herein refers to a channel used by a base station to transmit system information to a plurality of user terminals. For example, PBCH (Physical Broadcasting) specified in the 3GPP LTE-based wireless communication standard. CHannel) and the like.

In addition, the MTC broadcast channel means a channel used by a base station to transmit system information to a plurality of MTC devices. For example, a PBCH or the like specified in the 3GPP LTE-based wireless communication standard may be a MTC device. This may mean used as a channel (MTC-PBCH) for.

Hereinafter, embodiments of the present invention may allocate a downlink physical channel dedicated to an IoT communication device capable of transmitting control information and data information for an IoT communication device while maintaining a compatibility with a user terminal. In addition, the physical channel for the MTC device may be allocated to a specific preset position in the subframe, or the physical channel may be variably allocated to various locations.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram illustrating a structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 1, the horizontal direction of the subframe 1000 represents a time axis, the vertical direction represents a frequency axis, and the subframe 1000 includes a predetermined number of symbols along the time axis, and has a predetermined bandwidth along the frequency axis. In this case, each region of the subframe 1000 refers to a radio resource determined in a time and frequency domain.

In the first time domain 1100 of the subframe 1000, a user terminal control channel 1110 for transmitting control information from the base station to the user terminal may be allocated, and the second time region 1200 of the subframe 1000 may be allocated. ) May be allocated an IoT communication device control channel 1210 for transmitting control information to an IoT communication device and an IoT communication device data channel 1220 for transmitting data to the IoT communication device. In addition, the MTC device control channel 1210 may be allocated to the first slot, and the MTC device data channel 1220 may be allocated to the second slot.

In addition, the MTC device control channel 1210 and the MTC device data channel 1220 allocated to the second time domain 1200 of the subframe 1000 are the user terminal data channel 1230 as shown in FIG. 1. And the frequency division multiplexing (FDM), and the MTC device control channel 1210 may be divided into the MTC device data channel 1220 and the time division multiplexing (TDM).

Also, the last symbol of the MTC device 1210 may be fixedly allocated to the last symbol of the first slot.

Meanwhile, as illustrated in FIG. 1, the MTC device control channel 1210 includes control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220 and the MTC device data channel 1220. Control information (UL grants) for uplink resource allocation may be transmitted together.

In addition, a first MTC device control channel for transmitting control information (DL grants) regarding downlink resource allocation of the MTC device data channel 1220 and control regarding uplink resource allocation of the MTC device data channel 1220. A second MTC device control channel for transmitting information (UL grants) may be divided and allocated.

2 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an IoT communication device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 2, as in FIG. 1, the horizontal direction of the subframe 1000 represents the time axis, the vertical direction represents the frequency axis, and the subframe 1000 includes a predetermined number of symbols along the time axis. Occupying a predetermined bandwidth along the axis, each region of the subframe 1000 refers to a radio resource determined in the time and frequency domain.

In the first time domain 1100 of the subframe 1000, a user terminal control channel 1110 for transmitting control information from the base station to the user terminal may be allocated, and the second time region 1200 of the subframe 1000 may be allocated. ) May be allocated an IoT communication device control channel 1210 for transmitting control information to an IoT communication device and an IoT communication device data channel 1220 for transmitting data to the IoT communication device. In addition, the MTC device control channel 1210 may be allocated over a first slot and a second slot.

In addition, the MTC device control channel 1210 and the MTC device data channel 1220 of the second time domain 1200 of the subframe 1000 have a user terminal data channel 1230 and a frequency as shown in FIG. 2. Frequency division multiplexing (FDM) may be divided, and the MTC device control channel 1210 may be divided into a MTC device data channel 1220 and a time division multiplexing (TDM).

Meanwhile, as illustrated in FIG. 2, the MTC device control channel 1210 transmits control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220. 1211 and a second MTC device control channel 1212 that transmits UL grants related to uplink resource allocation of the MTC device data channel.

3 is a conceptual diagram illustrating yet another structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 3, as in FIG. 1 or 2, the horizontal direction of the subframe 1000 represents the time axis, the vertical direction represents the frequency axis, and the subframe 1000 includes a predetermined number of symbols along the time axis. And occupies a predetermined bandwidth along the frequency axis, and each region of the subframe 1000 refers to a radio resource determined in a time and frequency domain.

In the first time domain 1100 of the subframe 1000, a user terminal control channel 1110 for transmitting control information from the base station to the user terminal may be allocated, and the second time region 1200 of the subframe 1000 may be allocated. ) May be allocated an IoT communication device control channel 1210 for transmitting control information to an IoT communication device and an IoT communication device data channel 1220 for transmitting data to the IoT communication device. In addition, the MTC device control channel 1210 may be allocated over a first slot and a second slot.

In addition, the MTC device 1210 and the MTC device 1220 may be divided into a user terminal data channel 1230 and a frequency division multiplexing (FDM) as illustrated in FIG. 3. The MTC device 1210 may be classified into an MTC device data channel 1220 and a time division multiplexing (TDM).

Meanwhile, as illustrated in FIG. 3, the MTC device control channel 1210 includes control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220 and the MTC device data channel 1220. Control information (UL grants) regarding the uplink resource allocation of the first MTC device control channel 1211 and the MTC device data channel 1220, together with the control information (UL grants) regarding uplink resource allocation, are transmitted. The second MTC device 1212 may be divided and allocated.

As shown in FIGS. 1 to 3, the base station allocates the MTC device control channel 1210 to a predetermined region of a resource for transmitting control information about the MTC device, and transmits data for the MTC device. In order to allocate the MTC device data channel 1220 to a predetermined region of resources, semi-static signaling using information on a region occupied by the MTC device control channel 1210 using higher layer signaling above the physical layer is performed. signaling to the MTC device, a base station to the MTC device using a user terminal broadcast channel for transmitting system information to the user terminal, or dynamic signaling using a separate physical control channel for the MTC device ( dynamic signaling) to the MTC device.

In detail, when the information on the area occupied by the MTC device control channel 1210 is transmitted to the MTC device through higher layer signaling of the physical layer or more, the BS transmits the subframe 1000 in the structure shown in FIG. 1. If the last symbol position of the MTC device control channel area 1210 is fixedly assigned to the last symbol of the first slot, the information regarding the area occupied by the MTC device control channel 1210 is assigned to the MTC device control channel. 1210 may be a symbol number starting from.

In addition, when the base station allocates the subframe 1000 with the structure as shown in FIG. 1, and the last symbol position of the MTC device control channel region 1210 is not fixedly assigned to the last symbol of the first slot, the MTC device control The information about the area occupied by the channel 1210 may be a symbol number at which the MTC device control channel 1210 starts and a symbol number at which the MTC device control channel 1210 ends.

Here, the symbol number at which the MTC device control channel 1210 ends may be replaced with a symbol number at which the MTC device data channel 1220 starts.

Table 1 below shows the MTC device control channel 1210 through higher layer signaling above the physical layer when the last symbol position of the MTC device control channel region 1210 is not fixedly assigned to the last symbol of the first slot. ) Shows an example of a parameter that may be information about an area occupied by.

Table 1 shows an example of a parameter that may be information about an area occupied by the MTC device 1210. The start symbol number of the MTC device 1210 as a parameter of higher layer signaling, At least one of an end symbol number of the MTC device control channel 1210 and a configuration index matched using the start symbol number and the end symbol number of the MTC device control channel 1210 may be used.

Accordingly, the base station allocates the subframe 1000 as shown in FIG. 1, and provides information about the area occupied by the MTC device 1210 and the start symbol number of the MTC device 1210 and the MTC device control. At least one of an end symbol number of the channel 1210 and the configuration index may be provided to the MTC device using higher layer signaling of a physical layer or higher.

In addition, when the last symbol position of the MTC device control channel region 1210 in FIG. 1 is fixedly allocated to the last symbol of the first slot, the end symbol number of the MTC device control channel 1210 in Table 1 is May not be used.

Meanwhile, Table 2 below shows a first MTC device control channel 1211 and a second MTC device control channel 1212 transmitted through higher layer signaling of a physical layer or more in the subframe 1000 described with reference to FIG. 2 or FIG. 3. ) Shows an example of a parameter that may be information about an area occupied by.

Referring to Table 2, the start symbol number of the first MTC device control channel region 1211, the start symbol number of the second MTC device control channel region 1212, and the second thing as parameters of higher layer signaling. The end symbol number of the communication device control channel region 1212 may be used.

In addition, as shown in Table 2, the start symbol number of the first MTC device control channel region 1211, the start symbol number of the second MTC device control channel region 1212, and the second MTC device control channel region 1212. The matched configuration index may be used as a higher layer signaling parameter by using an end symbol number of.

Here, the end symbol number of the second MTC device control channel region 1212 may be replaced with a symbol number from which the MTC device data channel 1220 starts.

Meanwhile, when the last symbol position of the second MTC device control channel region 1212 is fixedly allocated to the last symbol of the first slot in FIG. 2 or FIG. 3, the second MTC device control channel 1212 in Table 2 above. The terminating symbol number of) may not be used.

Meanwhile, hereinafter, the transmission of information about the area occupied by the MTC device control channel 1210 to the MTC device through dynamic signaling using a separate physical control channel for the MTC device will be described in detail.

When the base station allocates the subframe 1000 in the structure as shown in FIG. 1 and the last symbol position of the MTC device control channel region 1210 is fixedly allocated to the last symbol of the first slot, the MTC device control channel 1210 Information about the area occupied by the CDMA may be transmitted through the MTC device control format indicator channel.

Accordingly, the information about the area occupied by the MTC device control channel 1210 is occupied by the MTC device 1210 from the symbol position where the MTC device control format indicator channel is detected to the last symbol of the first slot. It can be information about the area.

On the other hand, without transmitting information about the area occupied by the MTC device control channel 1210 through the MTC device control format indicator channel, the last of the first slot from the symbol position where the MTC device control channel 1210 is detected By detecting the symbol position, information on the area occupied by the MTC device 1210 may be known.

When the base station allocates the subframe 1000 in the structure as shown in FIG. 1, and the last symbol position of the MTC device control channel region 1210 is not fixedly allocated to the last symbol of the first slot, the MTC device control channel ( The information about the area occupied by 1210 may be a symbol number at which the MTC device control channel 1210 ends or a number of symbols occupied by the MTC device control channel 1210.

Here, the symbol number at which the MTC device control channel 1210 ends may be replaced with a symbol number at which the MTC device data channel 1220 starts.

Table 3 below shows an example of parameters that may be information about an area occupied by the MTC device control channel 1210 in FIG. 1 which may be transmitted through the MTC device control format indicator channel.

Table 3 shows an example of a parameter that may be information about an area occupied by the IoT communication device control channel 1210, and the number of symbols occupied by the IoT communication device control channel 1210 and the IoT communication device control. The channel 1210 may transmit the information to at least one of the configuration index matched with the number of symbols occupied by the channel 1210 to the MTC device through the MTC device control format indicator channel.

Meanwhile, Table 4 below shows the first MTC device control channel 1211 and the second MTC device that may be transmitted through the MTC device control format indicator channel in the subframe 1000 described with reference to FIG. 2 or FIG. 3. An example of a parameter that may be information about an area occupied by the control channel 1212 is shown.

Referring to Table 4, the number of symbols occupied by the first MTC device control channel 1211 or the end symbol number of the first MTC device control channel 1211, the second MTC device control channel 1212 ) May be transmitted to the MTC device through the MTC control format indicator channel including information on the number of symbols occupied or information about the end symbol number of the second MTC device control channel 1212.

Alternatively, the object communication includes information on at least one of the number of symbols occupied by the first MTC device control channel 1211 and a configuration index matched with the number of symbols occupied by the second MTC device control channel 1212. The control format indicator channel may transmit the MTC device.

Here, the end symbol number of the second MTC device control channel 1212 may be replaced with the start symbol number of the MTC device data channel 1220.

Meanwhile, when the last symbol position of the second MTC device control channel region 1212 is fixedly allocated to the last symbol of the first slot in FIG. 2 or FIG. 3, the second MTC device control channel 1212 of Table 4 above. The number of symbols occupied by) may not be used as information about an area occupied by the second MTC device control channel 1212.

Also, in the subframe 1000 illustrated in FIG. 2, a second MTC device control channel 1212 for transmitting control information (UL grants) regarding uplink resource allocation of the MTC device data channel 1220 exists. If there is no first MTC device control channel 1211 that transmits control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220, the first MTC device control channel 1211 exists. The area 1211 may be allocated as an area for a user terminal.

In addition, in the subframe 1000 illustrated in FIG. 3, a second MTC device control channel 1212 that transmits control information (UL grants) regarding uplink resource allocation of the MTC device data channel 1220 exists. And transmitting control information (DL grants) for downlink resource allocation of the MTC device data channel 1220 and control information (UL grants) for uplink resource allocation of the MTC device data channel 1220 together. When the first MTC device control channel 1211 does not exist, resources allocated for the MTC device other than the second MTC device control channel area 1212 may be allocated to the area for the user terminal.

In addition, the first MTC device control channel 1211 for transmitting control information (DL grants) for downlink resource allocation of the MTC device data channel 1220 in the subframe 1000 illustrated in FIG. 2 or 3. (See FIG. 2) or control information (DL grants) regarding downlink resource allocation of the telecommunication device data channel 1220 and control information (UL grants) regarding uplink resource allocation of the telecommunication device data channel 1220. The first MTC device control channel 1211 (see FIG. 3) which transmits the WMN is present, and the second thing that transmits control information (UL grants) related to uplink resource allocation of the MTC device data channel 1220. When the communication device control channel 1212 does not exist, the second MTC device control channel region 1212 may be used as the MTC device data channel region 1220.

Here, the fact that the second MTC device control channel region 1212 is not used means that the number of symbols occupied by the second MTC device control channel 1212 is '0', or the MTC device data channel region ( A start symbol number of 1220 is the same as a start symbol number of the second MTC device control channel region 1212, and is transmitted to the MTC device through quasi-static signaling using higher layer signaling of the physical layer or the base station. The second MTC device control channel 1212 may be transmitted to the MTC device using a user terminal broadcast channel for transmitting system information to the user terminal, or by dynamic signaling using a separate physical control channel for the MTC device. What is not used may be sent to the MTC device.

4 is a conceptual diagram illustrating a structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 4, the horizontal direction of the subframe 1000 represents the time axis, the vertical direction represents the frequency axis, and the subframe 1000 includes a predetermined number of symbols along the time axis, and has a predetermined bandwidth along the frequency axis. In this case, each region of the subframe 1000 refers to a radio resource determined in a time and frequency domain.

In the first time domain 1100 of the subframe 1000, a user terminal control channel 1110 for transmitting control information from the base station to the user terminal may be allocated, and the second time region 1200 of the subframe 1000 may be allocated. ) May be allocated an IoT communication device control channel 1210 for transmitting control information to an IoT communication device and an IoT communication device data channel 1220 for transmitting data to the IoT communication device.

In addition, the MTC device control channel 1210 and the MTC device data channel 1220 allocated to the second time domain 1200 of the subframe 1000 are the user terminal data channel 1230 as shown in FIG. 4. And the frequency division multiplexing (FDM), and the MTC device control channel 1210 may be divided into the MTC data channel 1220 and the frequency division multiplexing (FDM).

Meanwhile, as illustrated in FIG. 4, the MTC device control channel 1210 includes control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220 and the MTC device data channel 1220. Control information (UL grants) for uplink resource allocation may be transmitted together.

5 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 5, the horizontal direction of the subframe 1000 represents the time axis, the vertical direction represents the frequency axis, and the subframe 1000 includes a predetermined number of symbols along the time axis, and has a predetermined bandwidth along the frequency axis. In this case, each region of the subframe 1000 refers to a radio resource determined in a time and frequency domain.

In the first time domain 1100 of the subframe 1000, a user terminal control channel 1110 for transmitting control information from the base station to the user terminal may be allocated, and the second time region 1200 of the subframe 1000 may be allocated. ) May be allocated an IoT communication device control channel 1210 for transmitting control information to an IoT communication device and an IoT communication device data channel 1220 for transmitting data to the IoT communication device.

In addition, the MTC device control channel 1210 and the MTC device data channel 1220 allocated to the second time domain 1200 of the subframe 1000 are the user terminal data channel 1230 as shown in FIG. 5. And the frequency division multiplexing (FDM), and the MTC device control channel 1210 may be divided into the MTC data channel 1220 and the frequency division multiplexing (FDM).

Meanwhile, as illustrated in FIG. 5, the MTC device control channel 1210 transmits control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220. A second MTC device control channel 1212 that transmits control information (UL grants) regarding uplink resource allocation of the 1211 and the MTC device data channel 1220 may be divided and allocated by time division multiplexing (TDM). have.

In addition, the first MTC device control channel 1211 may be allocated to a first slot, and the second MTC device control channel 1212 may be allocated to a second slot.

In addition, a boundary between the first MTC device control channel 1211 and the second MTC device control channel 1212 may be divided into a boundary between the first slot and the second slot, or the first slot and the first slot. It may be divided by the position of the symbol before or after the two slot boundary.

FIG. 6 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an IoT communication device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 6, the horizontal direction of the subframe 1000 represents the time axis, the vertical direction represents the frequency axis, the subframe 1000 includes a predetermined number of symbols along the time axis, and the predetermined bandwidth along the frequency axis. In this case, each region of the subframe 1000 refers to a radio resource determined in a time and frequency domain.

In the first time domain 1100 of the subframe 1000, a user terminal control channel 1110 for transmitting control information from the base station to the user terminal may be allocated, and the second time region 1200 of the subframe 1000 may be allocated. ) May be allocated an IoT communication device control channel 1210 for transmitting control information to an IoT communication device and an IoT communication device data channel 1220 for transmitting data to the IoT communication device.

In addition, the MTC device control channel 1210 and the MTC device data channel 1220 allocated to the second time domain 1200 of the subframe 1000 are the user terminal data channel 1230 as shown in FIG. 6. And the frequency division multiplexing (FDM), and the MTC device control channel 1210 may be divided into the MTC data channel 1220 and the frequency division multiplexing (FDM).

Meanwhile, as illustrated in FIG. 6, the MTC device control channel 1210 includes control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220 and the MTC device data channel 1220. Transmit control information (UL grants) regarding the uplink resource allocation of the first MTC device control channel 1211 and the MTC device data channel 1220 together with the control information (UL grants) regarding uplink resource allocation. The second MTC device 1212 may be divided and allocated to time division multiplexing (TDM).

In addition, the first MTC device control channel 1211 may be allocated to a first slot, and the second MTC device control channel 1212 may be allocated to a second slot.

In addition, a boundary between the first MTC device control channel 1211 and the second MTC device control channel 1212 may be divided into a boundary between the first slot and the second slot, or the first slot and the first slot. It may be divided by the position of the symbol before or after the two slot boundary.

As shown in FIG. 4 to FIG. 6, the base station allocates the MTC device control channel 1210 to a predetermined region of the resource to transmit the control information for the MTC device, and transmits data for the MTC device. In order to allocate the MTC device data channel 1220 to a predetermined region of resources, semi-static signaling using information on a region occupied by the MTC device control channel 1210 using higher layer signaling above the physical layer is performed. signaling to the MTC device, a base station to the MTC device using a user terminal broadcast channel for transmitting system information to the user terminal, or dynamic signaling using a separate physical control channel for the MTC device ( dynamic signaling) to the MTC device.

Specifically, when the base station allocates the subframe 1000 in the structure as shown in FIG. 4 to transmit information about the area occupied by the MTC device control channel 1210 to the MTC device through higher layer signaling. It will be described with reference to Table 5 below.

Table 5 above is a parameter that may be information about an area occupied by the MTC device control channel 1210 to be transmitted to the MTC device through higher layer signaling in the subframe 1000 illustrated in FIG. 4. For example, the parameter may be a configuration index that matches a symbol number at which the MTC device control channel 1210 starts or a symbol number at which the MTC device control channel 1210 starts.

Meanwhile, when the first MTC device control channel 1211 and the second MTC device control channel 1212 are divided into slots as in the subframe 1000 illustrated in FIGS. 5 to 6, higher layer signaling. Start symbol number of the first MTC device control channel region 1211, start symbol number of the second MTC device control channel region 1212, and end symbol number of the second MTC device control channel region 1212. Can be used.

Further, a start symbol number of the first MTC device control channel region 1211, a start symbol number of the second MTC device control channel region 1212, and an end symbol number of the second MTC device control channel region 1212 may be determined. The configuration index matched using the PSI may be used as a higher layer signaling parameter.

Meanwhile, in Table 6, unlike the subframe 1000 illustrated in FIGS. 5 to 6, the first MTC device control channel 1211 and the second MTC device control channel 1212 are not divided into slots. An example of parameters of higher layer signaling that can be used in a case is shown.

Referring to Table 6, the parameters of the higher layer signaling that can be used include a start symbol number of the first MTC device control channel region 1211 and a start symbol number of the second MTC device control channel region 1212, Alternatively, the configuration index may be matched with a start symbol number of the first MTC device control channel region 1211 and a start symbol number of the second MTC device control channel region 1212.

Meanwhile, hereinafter, the transmission of information about the area occupied by the MTC device control channel 1210 to the MTC device through dynamic signaling using a separate physical control channel for the MTC device will be described in detail.

The base station allocates the subframe 1000 to the structure as shown in FIG. 4 and relates to the symbol position occupied by the MTC device control channel 1210, which is an example of information about the area occupied by the MTC device control channel 1210. The information may be transmitted to the MTC device through the MTC device control format indicator channel.

Accordingly, the MTC device may recognize that the MTC device from the symbol position where the MTC device control format indicator channel is detected to the last symbol position of the subframe 1000 is information about an area occupied by the MTC device 1210.

On the other hand, the MTC device does not transmit information about the area occupied by the MTC device control channel 1210 through the MTC device control format indicator channel, and the sub-device from the symbol position where the MTC device control channel 1210 is detected is transmitted. The last symbol position of the frame 1000 may be detected to obtain information about an area occupied by the MTC device control channel 1210.

Table 7 below shows a case in which the first MTC device control channel 1211 and the second MTC device control channel 1212 are not divided into slots, unlike the subframe 1000 illustrated in FIG. 5 or 6. An example of a parameter that can be used as information about an area occupied by the MTC device control channel 1210 is shown.

Referring to Table 7, the information on the symbol position occupied by the MTC device control channel 1210, which is an example of information about the area occupied by the MTC device control channel 1210, refers to the MTC device control format indicator channel. May be transmitted to the MTC device.

Specifically, the number of symbols occupied by the first MTC device control channel 1211 or the number of symbols occupied by the end symbol number of the first MTC device control channel 1211 and the second MTC device control channel 1212. Alternatively, a symbol position occupied by the IoT communication device control channel 1210 is transmitted to the IoT communication device through the transmission of the IoT communication device control format indicator channel including information on an end symbol number of the second IoT communication device control channel 1212. It can be seen.

The MTC device control format indicator channel including a configuration index that matches the number of symbols occupied by the first MTC device control channel 1211 and the number of symbols occupied by the second MTC device control channel 1212. The MTC device may know a symbol position occupied by the MTC device control channel 1210 through the transmission of.

Meanwhile, in the subframe 1000 illustrated in FIG. 5 or 6, the second MTC device control channel 1212 transmitting control information (UL grants) regarding uplink resource allocation of the MTC device data channel 1220. ) Is present, the second MTC device 1211 when the first MTC device control channel 1211 that transmits control information (DL grants) regarding downlink resource allocation of the MTC device data channel 1220 does not exist. Resources allocated for the MTC device other than the control channel region 1212 may be allocated to the region for the user terminal.

In addition, the first MTC device control channel 1211 for transmitting control information (DL grants) for downlink resource allocation of the MTC device data channel 1220 in the subframe 1000 illustrated in FIG. 5 or 6. (See FIG. 5) or control information (DL grants) regarding downlink resource allocation of the telecommunication device data channel 1220 and control information (UL grants) regarding uplink resource allocation of the telecommunication device data channel 1220. The first MTC device control channel 1211 (see FIG. 6) that transmits the WMN is present, and the second thing that transmits control information (UL grants) related to uplink resource allocation of the MTC device data channel 1220. When the communication device control channel 1212 does not exist, the second MTC device control channel region 1212 may be used as the MTC device data channel region 1220.

Here, the fact that the second MTC device control channel region 1212 is not used means that the number of symbols occupied by the second MTC device control channel 1212 is '0', and the higher layer signaling of the physical layer or higher is used. Dynamic transmission using the quasi-static signaling to the IoT communication device, the base station using the user terminal broadcasting channel for transmitting system information to the user terminal to the IoT communication device, or using a separate physical control channel for the IoT communication device The signaling may transmit to the MTC device that the second MTC device control channel 1212 is not used.

7 is a conceptual diagram illustrating a structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 7, the horizontal direction of the subframe 1000 represents the time axis, the vertical direction represents the frequency axis, and the subframe 1000 includes a predetermined number of symbols along the time axis, and has a predetermined bandwidth along the frequency axis. In this case, each region of the subframe 1000 refers to a radio resource determined in a time and frequency domain.

In the first time domain 1100 of the subframe 1000, a user terminal control channel 1110 for transmitting control information from the base station to the user terminal may be allocated, and the second time region 1200 of the subframe 1000 may be allocated. ) May be allocated an IoT communication device control channel 1210 for transmitting control information to an IoT communication device and an IoT communication device data channel 1220 for transmitting data to the IoT communication device.

In addition, the MTC device control channel 1210 and the MTC device data channel 1220 allocated to the second time domain 1200 of the subframe 1000 may have a user terminal data channel 1230 and a frequency division multiplexing (FDM). The MTC device control channel 1210 may be divided into a multiplex having a combination of the MTC device data channel 1220, time division multiplexing (TDM), and frequency division multiplexing (FDM).

Meanwhile, as illustrated in FIG. 7, the MTC device control channel 1210 may include control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220 and the MTC device data channel 1220. Control information (UL grants) for uplink resource allocation may be transmitted together.

In addition, the MTC device control channel 1210 may be allocated to a first slot, and the boundary between the MTC device control channel 1210 and the MTC device data channel 1220 is located in front of the first slot boundary or It can also be separated by the symbol position.

8 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 8, the horizontal direction of the subframe 1000 represents the time axis, the vertical direction represents the frequency axis, the subframe 1000 includes a predetermined number of symbols along the time axis, and the predetermined bandwidth along the frequency axis. In this case, each region of the subframe 1000 refers to a radio resource determined in a time and frequency domain.

In the first time domain 1100 of the subframe 1000, a user terminal control channel 1110 for transmitting control information from the base station to the user terminal may be allocated, and the second time region 1200 of the subframe 1000 may be allocated. ) May be allocated an IoT communication device control channel 1210 for transmitting control information to an IoT communication device and an IoT communication device data channel 1220 for transmitting data to the IoT communication device.

In addition, the MTC device control channel 1210 and the MTC device data channel 1220 allocated to the second time domain 1200 of the subframe 1000 may have a user terminal data channel 1230 and a frequency division multiplexing (FDM). It can be divided into.

Meanwhile, the MTC device control channel 1210 is a first MTC device control channel 1211 and a MTC device for transmitting control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220. The second MTC device control channel 1212 transmitting control information (UL grants) regarding the uplink resource allocation of the data channel 1210 may be included.

As illustrated in FIG. 8, the first MTC device control channel 1211 may be divided into multiplexing in which a MTS data channel 1220 is combined with time division multiplexing (TDM) and frequency division multiplexing (FDM). have.

In addition, the second MTC device control channel 1212 may be divided into the MTC device data channel 1220 and frequency division multiplexing (FDM).

In addition, the first MTC device control channel 1211 may be allocated to a first slot, and the boundary of the first MTC device control channel 1211 and the MTC device data channel 1220 is the first slot boundary. It can also be separated by the symbol position before or after.

As illustrated in FIG. 7 or FIG. 8, the base station allocates the MTC device control channel 1210 to a predetermined region of a resource to transmit control information about the MTC device, and transmits data for the MTC device. In order to allocate the MTC device data channel 1220 to a predetermined region of resources, semi-static signaling using information on a region occupied by the MTC device control channel 1210 using higher layer signaling above the physical layer is performed. signaling to the MTC device, a base station to the MTC device using a user terminal broadcast channel for transmitting system information to the user terminal, or dynamic signaling using a separate physical control channel for the MTC device ( dynamic signaling) to the MTC device.

In detail, when information about the area occupied by the MTC device control channel 1210 is transmitted to the MTC device through higher layer signaling of the physical layer or more, the base station may have a subframe ( 1000 may be allocated, and information about a symbol position occupied by the MTC device control channel 1210 may be transmitted to the MTC device through higher layer signaling.

Table 8 below shows an example of a parameter that may be information about an area occupied by the MTC device control channel 1210 through higher layer signaling in FIG. 7 or FIG. 8.

Referring to Table 8, the start symbol number of the MTC device control channel 1210 (start symbol number of the first MTC device control channel region 1210 in FIG. 8) and the parameters of the higher layer signaling. End symbol number of the MTC device control channel region 1210 (end symbol number of the first MTC device control channel region 1211 in the case of FIG. 8) and start symbol number of the MTC device control channel region 1210. 8, the start symbol number of the first MTC device control channel region 1211 and the end symbol number of the MTC device control channel region 1210 (the first MTC device control channel in FIG. 8). At least one of configuration indexes matched using the terminating symbol number of the area 1211 may be used.

In addition, when the last symbol position of the MTC device control channel region 1210 of FIG. 7 or the first MTC device control channel region 1211 of FIG. 8 is allocated to the last symbol position of the first slot, the above-mentioned symbol of FIG. The start symbol number of the MTC device control channel region 1210 or the first MTC device control channel region 1211 of FIG. 8 may be used as a parameter for higher layer signaling, and the second MTC device control channel region of FIG. 8 may be used. The start symbol number of 1212 may be the same as the start symbol number of the first MTC device control channel region 1211.

Accordingly, the base station allocates the subframe 1000 as shown in FIG. 7 or FIG. 8 and transmits information about the area occupied by the MTC device control channel 1210 to the MOT device by using higher layer signaling of the physical layer or higher. Can provide.

Meanwhile, hereinafter, the transmission of information about the area occupied by the MTC device control channel 1210 to the MTC device through dynamic signaling using a separate physical control channel for the MTC device will be described in detail.

The base station allocates the subframe 1000 in a structure as shown in FIG. 7 or 8, and the number of symbols occupied by the MTC device 1210, the end symbol number of the MTC device channel 1210, and the thing An area occupied by the MTC device control channel 1210 as the MTC device through the MTC device control format indicator channel including information on at least one of the configuration indexes matched by the number of symbols occupied by the communication device control channel 1210. Information about can be transmitted.

Table 9 shows an example of a parameter that may be information about an area occupied by the MTC device control channel 1210 in FIG. 7 or FIG. 8 that may be transmitted through the MTC device control format indicator channel. .

Meanwhile, when the last symbol position of the MTC device control channel region 1210 of FIG. 7 or the last symbol position of the first MTC device control channel region 1211 of FIG. 8 is fixedly allocated to the last symbol of the first slot, Instead of transmitting information about the area occupied by the MTC device control channel 1210 through the MTC device control format indicator channel, the last symbol position of the first slot from the symbol position where the MTC device control channel 1210 is detected. To detect information about the area occupied by the MTC device 1210.

Meanwhile, in the subframe 1000 illustrated in FIG. 8, a second MTC device control channel 1212 for transmitting control information (UL grants) regarding uplink resource allocation of the MTC device data channel 1220 exists. If there is no first MTC device control channel 1211 that transmits control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220, the second MTC device control channel Resources allocated for the MTC device other than the area 1212 may be allocated to the area for the user terminal.

In addition, a first MTC device control channel 1211 for transmitting control information (DL grants) related to downlink resource allocation of the MTC device data channel 1220 is present in the subframe 1000 illustrated in FIG. 8. If there is no second MTC device control channel 1212 that transmits UL grants for uplink resource allocation of the MTC device data channel 1220, the second MTC device control channel 1212 exists. The region 1212 can be used as the MTC device data channel region 1220.

Here, it is necessary to inform that the second MTC device control channel region 1212 is not used, and the number of symbols occupied by the second MTC device control channel 1212 is set to '0', and the physical layer The quasi-static signaling using the higher layer signaling described above is transmitted to the MTC device, the base station is transmitted to the MTC device using a user terminal broadcast channel for transmitting system information to the user terminal, or a separate physical for the MTC device. Dynamic signaling using a control channel may transmit to the MTC device that the second MTC device control channel 1212 is not used.

FIG. 9 is a conceptual diagram illustrating another structure of a subframe capable of transmitting control information and data for an IoT communication device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 9, the horizontal direction of the subframe 1000 represents the time axis, the vertical direction represents the frequency axis, and the subframe 1000 includes a predetermined number of symbols along the time axis, and has a predetermined bandwidth along the frequency axis. In this case, each region of the subframe 1000 refers to a radio resource determined in a time and frequency domain.

In the first time domain 1100 of the subframe 1000, a user terminal control channel 1110 for transmitting control information from the base station to the user terminal may be allocated, and the second time region 1200 of the subframe 1000 may be allocated. ) May be allocated an IoT communication device control channel 1210 for transmitting control information to an IoT communication device and an IoT communication device data channel 1220 for transmitting data to the IoT communication device.

In addition, the MTC device control channel 1210 and the MTC device data channel 1220 allocated to the second time domain 1200 of the subframe 1000 may have a user terminal data channel 1230 and a frequency division multiplexing (FDM). It can be divided into.

In addition, the MTC device control channel 1210 may be divided into the MTC device data channel 1220 and frequency division multiplexing (FDM).

As shown in FIG. 9, the base station allocates the MTC device control channel 1210 to a predetermined region of a resource for transmitting control information about the MTC device, and transmits data for the MTC device. By assigning the communication device data channel 1220 to a predetermined area of resources, information about the area occupied by the MTC device control channel 1210 is semi-static signaling using higher layer signaling above the physical layer. Dynamic signaling using the user terminal broadcasting channel for transmitting to the MTC device, the user terminal broadcasting channel for transmitting system information to the user terminal, or using a separate physical control channel for the MTC device. Can be transmitted to the MTC device.

In conclusion, as described above with reference to FIGS. 1 through 9, the base station allocates the MTC device control channel 1210 to a predetermined region of a resource for transmitting control information about the MTC device, and the data for the MTC device. The MTC device data channel 1220 is allocated to a predetermined area of the resource to transmit the information, so that the information regarding the area occupied by the MTC device control channel 1210, information on the resource allocation type, bits The MTC device transmits map information or the like to the MTC device through semi-static signaling using higher layer signaling of the physical layer or the like, or uses a user terminal broadcast channel for transmitting the system information to the user terminal by the base station. Or by using a separate physical control channel for the IoT device. The signaling (dynamic signaling) may be transferred to the object communication device.

Each bit in the bitmap information is a resource block (RB) unit or a group of resource blocks, and the resource block or a resource grouping the resource block is assigned to the resource allocation of the MTC device 1210. Can tell whether it is used.

In addition, the information regarding the resource allocation type (Resourec Allocation Type) means information about which resource allocation method is used by the MTC device control channel 1210.

Meanwhile, as illustrated in FIGS. 4 to 9, when the MTC device control channel region 1210 and the MTC device data channel region 1220 are divided into frequency division multiplexing, frequency division multiplexing, and time division multiplexing, the MTC device control is performed. When the number of resource blocks, subcarriers, a plurality of resource blocks, or a plurality of subcarriers are grouped in the frequency domain occupied by the channel 1210, at least one of the number of groups is transmitted to the MTC device through the higher layer signaling. Can be.

4 to 9, the MTC device control channel region 1210 and the MTC device data channel region 1220 are divided into frequency division multiplexing, frequency division multiplexing, and time division multiplexing. When the number of resource blocks in the frequency domain occupied by the channel 1210, the number of subcarriers, a plurality of resource blocks, or a plurality of subcarriers are grouped, at least one of the number of groups is determined through the MTC device control format indicator channel. Transmit to a communication device.

 Table 10 shows the things communication when the MTC device control channel region 1210 and the MTC device data channel region 1220 are divided into frequency division multiplexing, frequency division multiplexing, and time division multiplexing as shown in FIGS. 4 to 9. An example of a parameter that can be used as information about an area occupied by the device control channel 1210 is shown.

Accordingly, the base station determines information about the number of resource blocks in the frequency domain occupied by the communication device control channel region 1210 or the number of resource blocks in the frequency region occupied by the MTC device control channel region 1210. At least one of the matched configuration indexes may be transmitted to the MTC device through the MTC device control format indicator channel so that the MTC device may know information about an area occupied by the MTC device 1210.

The object communication device control format indicator channel may include at least one of information on symbol positions in a time domain occupied by the communication device control channel region 1210 and information on the number of resource blocks in the frequency domain. Transmit to a communication device.

Meanwhile, a resource element (RE) used for transmission of a reference signal (RS) in one symbol in one resource block as a unit A for resource allocation of the MTC device control channel 1210 is represented. Except for this, a group of resource elements consisting of available N resource elements may be used. In addition, another unit B consisting of a group of M units A may be used, and indexes (eg, unit A index and unit B index) for each of the units may be used for resource allocation.

In detail, a symbol index may be used as an index in a time domain for resource allocation of the MTC device control channel 1210, and a subcarrier index, a resource block index, and a plurality of subcarriers are used as a frequency resource index in a frequency domain. At least one of the index of the group and the index of the group consisting of a plurality of resource blocks may be used.

Meanwhile, the allocated MTC device control channel 1210 is scrambled using a predetermined scrambling code, and the scrambled MTC device control channel is a predetermined method such as quadrature phase shift keying (QPSK) or quadrature amplitude modulation (QAM). The symbol may be modulated by being mapped to the time-frequency resource region through layer mapping and precoding.

In addition, downlink control information (DCI) for the MTC device from an upper layer of the physical layer or more may be one DCI or a plurality of DCIs, and each DCI may be a set of bits. The DCI may be transmitted through one MTC device control channel.

Specifically, bits for one DCI are scrambled through a predetermined scrambling code, symbol-modulated by a predetermined method such as QPSK, QAM, etc., and mapped into a time-frequency resource region through layer mapping and precoding. It may be modulated to the communication device control channel and allocated to the allocated MTC device control channel region 1210.

In addition, all bits consisting of all DCIs to be transmitted through the MTC device control channel in the corresponding subframe are scrambled through a predetermined scrambling code, and symbol-modulated by a predetermined method such as QPSK, QAM, and the like. By being mapped to the time-frequency resource region through coding, it may be modulated into one MTC device control channel and allocated to the allocated MTC device control channel region.

Meanwhile, a method of mapping the allocated MTC device control channel to time-frequency resources will be described below.

The time domain resources may be mapped to the time domain resources allocated to the MTC device control channel region, and then the resources of the time domain may be mapped.

Specifically, starting from the start symbol index in the time domain and the start frequency resource index in the frequency domain of the allocated MTC device control channel region, the frequency resource index in the frequency domain is increased to allocate the MTC device control channel region. After mapping the resource to the end frequency resource index of, the resource is mapped in the above-described manner in the next symbol index of the start symbol index in the time domain and allocated to the last symbol of the allocated MTC device control channel region.

In addition, the time domain resources may be mapped first to the time domain resources allocated to the MTC device channel region, and then the resources of the frequency domain may be mapped.

Specifically, starting from the start symbol index in the time domain and the start frequency resource index in the frequency domain of the allocated MTC device control channel region, the symbol index in the time domain is increased to increase the symbol index in the time domain of the allocated MTC device control channel region. After mapping a resource to an end symbol index, the resource is mapped in the above-described manner from the next frequency resource index of the start frequency resource index in the frequency domain to the last frequency resource index of the allocated MTC device channel region.

On the other hand, an additional control channel other than the MTC device control channel for the MTC device may be allocated to the MTC device control channel region, and in this case, the MTC in the remaining region except for the area occupied by the additional control channel. The device control channel can be assigned.

10 is a flowchart illustrating a resource allocation method for at least one MTC device while maintaining compatibility with a user terminal according to an embodiment of the present invention.

Referring to FIG. 10, in the method of allocating a resource for an MTC device, a control channel for a user terminal is allocated to a first time domain of a subframe (S100), and at least one MTC device is allocated to a second time domain of a subframe. At least one of a control channel for a data channel, a data channel for a user terminal, and a data channel for a MTC device may be mixed and allocated (S110).

Specifically, in step 110, the control channel for the MTC device and the data channel for the MTC device are allocated to the subframe so as to be divided into the data channel for the user terminal and the frequency division multiplexing (FDM). The control channel for the device is divided into subchannels such that the data channel for the MTC device is divided into any one of a combination of time division multiplexing (TDM), frequency division multiplexing, and time division multiplexing and frequency division multiplexing. Can be assigned.

Next, information about an area occupied by the control channel for the MTC device may be transmitted to the MTC device (S120).

In detail, step 120 includes information on a region occupied by the control channel for the MTC device higher layer signaling above the physical layer, a broadcast channel for the user terminal for transmitting system information to the user terminal, and a separate for the MTC device. It may transmit to at least one MTC device through any one of the physical control channels.

Here, the separate physical control channel for the MTC device may be a broadcast channel for the MTC device for transmitting system information to the MTC device or an MTC device control format indicator channel for the MTC device.

Here, the information about the area occupied by the control channel for the MTC device may include a start symbol number of the control channel for the MTC device, an end symbol number of the control channel for the MTC device, and start of a data channel for the MTC device. Symbol number, the number of symbols occupied by the control channel for the MTC device, the number of resource blocks (RB) occupied by the control channel for the MTC device, and the subcarrier occupied by the control channel for the MTC device. The number may include at least one of the number of subcarrier groups occupied by the control channel for the MTC device, the number of resource block groups occupied by the control channel for the MTC device, and a configuration index.

11 is a flowchart illustrating a method of receiving MTC data while maintaining compatibility with a user terminal according to an exemplary embodiment of the present invention.

Referring to FIG. 11, in the MTC data receiving method, information about an area occupied by a control channel of an MTC device may be transmitted to a user terminal for transmitting higher layer signaling of a physical layer or more and system information from the base station to a user terminal. The broadcast channel and the separate physical control channel for the MTC device (S200), and may receive MOT data based on information about an area occupied by the control channel for the MTC device. There is (S210).

Here, the information about the area occupied by the control channel for the MTC device may include a start symbol number of the control channel for the MTC device, an end symbol number of the control channel for the MTC device, and start of a data channel for the MTC device. Symbol number, the number of symbols occupied by the control channel for the MTC device, the number of resource blocks (RB) occupied by the control channel for the MTC device, and the subcarrier occupied by the control channel for the MTC device. The number may be at least one of the number of subcarrier groups occupied by the control channel for the MTC device, the number of resource block groups occupied by the control channel for the MTC device, and a configuration index.

12 is a block diagram illustrating a configuration of a resource allocation apparatus and an IoT communication data receiving apparatus for an IoT communication device according to an embodiment of the present invention.

Referring to FIG. 12, an apparatus 100 for allocating a resource for an MTC device may include a resource allocator 110, a transmitter 120, an antenna 130, and a receiver 140.

The resource allocator 110 allocates a control channel for the user terminal to the first time domain of the subframe, a control channel for at least one MTC device, and a data channel for the user terminal to the second time domain of the subframe. And at least one of a data channel for the MTC device may be mixed.

In detail, the resource allocator 110 may divide the control channel for the MTC device and the data channel for the MTC device into data channels for the user terminal and frequency division multiplexing (FDM). The control channel for the MTC device is divided into one of a combination of a data channel and a time division multiplexing (TDM), frequency division multiplexing, and time division multiplexing and frequency division multiplexing. Can be assigned.

The transmitter 120 may transmit information about an area occupied by the control channel for the MTC device allocated by the resource allocator 110 to at least one MTC device.

Specifically, the transmitter 120 may transmit information on a region occupied by the control channel of the MTC device to higher layer signaling of a physical layer or higher, a broadcast channel for the user terminal for transmitting system information to the user terminal, and the MTC device. It can be transmitted to at least one MTC device through any one of a separate physical control channel.

Here, the separate physical control channel for the MTC device may be a broadcast channel for the MTC device for transmitting system information from the base station to the MTC device or the MTC device control format indicator channel for the MTC device.

Here, the information about the area occupied by the control channel for the MTC device may include a start symbol number of the control channel for the MTC device, an end symbol number of the control channel for the MTC device, and start of a data channel for the MTC device. Symbol number, the number of symbols occupied by the control channel for the MTC device, the number of resource blocks (RB) occupied by the control channel for the MTC device, and the subcarrier occupied by the control channel for the MTC device. The number may include at least one of the number of subcarrier groups occupied by the control channel for the MTC device, the number of resource block groups occupied by the control channel for the MTC device, and a configuration index.

The antenna 130 converts information about the area occupied by the control channel for the MTC device provided by the transmitter 120 into a radio signal, and transmits the signal to the outside through a predetermined method determined by the transmitter 120. And a reception antenna configured to receive a wireless signal from an external source and transmit the wireless signal to a reception unit, and the antenna 130 may be provided with two or more when a multi-antenna (MIMO) function is supported.

The receiver 140 may provide the resource allocator 110 with a radio signal from at least one of the user terminal and the MTC device received through the antenna 130.

The MTC device 200 may include an antenna 210, a receiver 220, a controller 230, and a transmitter 240.

The antenna 210 converts a radio signal including information about an area occupied by a control channel of the MTC device received from the outside, and transmits the radio signal to the receiver 220 from the receiver antenna and the transmitter 240. It may include a transmit antenna for converting the received signal into a radio signal to transmit to the outside, the antenna 210 may be provided with two or more when the multi-antenna (MIMO) function is supported.

The receiver 220 may receive information about an area occupied by the control channel for the MTC device.

In detail, the receiver 220 includes higher layer signaling of a physical layer or higher, information about a region occupied by a control channel of the MTC device, a broadcast channel for the user terminal for transmitting system information to the user terminal, and the MTC device. It can be received through any one of a separate physical control channel for.

The controller 230 may receive the IoT communication data based on the information about the area occupied by the control channel of the IoT communication device provided from the receiver 220.

The transmitter 240 may provide the antenna 210 with a predetermined signal provided from the controller 230 by performing a predetermined encoding and modulation with a wireless signal.

Here, the information about the area occupied by the control channel for the MTC device may include a start symbol number of the control channel for the MTC device, an end symbol number of the control channel for the MTC device, and start of a data channel for the MTC device. Symbol number, the number of symbols occupied by the control channel for the MTC device, the number of resource blocks (RB) occupied by the control channel for the MTC device, and the subcarrier occupied by the control channel for the MTC device. The number may include at least one of the number of subcarrier groups occupied by the control channel for the MTC device, the number of resource block groups occupied by the control channel for the MTC device, and a configuration index.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

100: resource allocation device 110: resource allocation unit
120: transmitter 130: antenna
140: receiver 200: receiver
210: antenna 220: receiver
230: control unit 240: transmission unit
1000: subframe 1100: first time domain
1110: user terminal control channel 1200: second time domain
1210: communication device control channel
1211: first MTC device control channel
1212: second MTC device control channel
1220: MTC device data channel
1230: user terminal data channel

Claims (16)

A method of allocating resources to at least one IoT device,
Allocating a control channel for the user terminal in a first time domain of the subframe;
Allocating at least one of a control channel for the at least one MTC device, a data channel for the user terminal, and a data channel for the MTC device in the second time domain of the subframe; And
Transmitting information regarding the area occupied by a control channel for the MTC device to the MTC device;
The information about the area occupied by the control channel for the MTC device,
A start symbol number of the control channel for the MTC device, an end symbol number, a start symbol number of the data channel for the MTC device, the number of symbols occupied by the control channel for the MTC device, and a resource block (RB) Resource block), the number of subcarriers, the number of subcarrier groups, the number of resource block groups, and a configuration index. The method according to claim 1,
The control channel for the MTC device and the data channel for the MTC device,
And a data channel and frequency division multiplexing (FDM) for the user terminal. The method according to claim 2,
The control channel for the MTC device,
The MTC device may be divided into any one of a data channel, a time division multiplexing (TDM), a frequency division multiplexing, and a time division multiplexing and a frequency division multiplexing for the MTC device. Resource allocation method. delete The method according to claim 1,
Transmitting the information about the area occupied by the control channel for the MTC device to the MTC device,
Upper layer signaling of a physical layer or more for information about an area occupied by a control channel for the MTC device, a broadcast channel for a user terminal for transmitting system information to the user terminal, and a separate physical control for the MTC device And transmitting to the at least one MTC device through any one of channels. delete An apparatus for allocating resources to at least one IoT device,
Allocating a control channel for the user terminal in the first time domain of the subframe, and a control channel for the at least one MTC device, a data channel for the user terminal and the MTC device in the second time domain of the subframe A resource allocator for mixing and allocating at least one of data channels; And
A transmitting unit which transmits information on an area occupied by a control channel of the MTC device to the MTC device,
The information about the area occupied by the control channel for the MTC device,
A start symbol number of the control channel for the MTC device, an end symbol number, a start symbol number of the data channel for the MTC device, the number of symbols occupied by the control channel for the MTC device, and a resource block (RB) And at least one of a number of Resource Blocks, a number of subcarriers, a number of subcarrier groups, a number of resource block groups, and a configuration index. The method according to claim 7,
The control channel for the MTC device and the data channel for the MTC device,
And a data channel and frequency division multiplexing (FDM) for the user terminal. The method according to claim 8,
The control channel for the MTC device,
The MTC device may be divided into any one of a data channel, a time division multiplexing (TDM), a frequency division multiplexing, and a time division multiplexing and a frequency division multiplexing for the MTC device. Resource Allocation Device. delete The method according to claim 7,
The transmitting unit,
Higher layer signaling for information on an area occupied by a control channel for the MTC device, physical layer or higher signaling, a broadcast channel for a user terminal for transmitting system information to the user terminal, and a separate physical control for the MTC device Apparatus for allocating channels to the at least one MTC device through any one of the channels. delete In the method for receiving MTC data from a base station,
Upper layer signaling above the physical layer for information about the area occupied by the control channel for the MTC device, a broadcast channel for the user terminal for transmitting system information from the base station to the user terminal, and a separate physical for the MTC device Receiving via any one of the control channels; And
Receiving the MTC data based on information about an area occupied by a control channel for the MTC device,
The information about the area occupied by the control channel for the MTC device,
A start symbol number of the control channel for the MTC device, an end symbol number, a start symbol number of the data channel for the MTC device, the number of symbols occupied by the control channel for the MTC device, and a resource block (RB) And at least one of a number of resource blocks), a number of subcarriers, a number of subcarrier groups, a number of resource block groups, and a configuration index. delete An apparatus for receiving MTC data from a base station,
Higher layer signaling above the physical layer for information about the area occupied by the control channel for the MTC device, a broadcast channel for the user terminal for transmitting system information from the base station to the user terminal, and a separate physical for the MTC device Receiving unit for receiving via any one of the control channel; And
And a controller configured to receive the MTC data based on the information about the area occupied by the control channel for the MTC device.
The information about the area occupied by the control channel for the MTC device,
A start symbol number of the control channel for the MTC device, an end symbol number, a start symbol number of the data channel for the MTC device, the number of symbols occupied by the control channel for the MTC device, and a resource block (RB) And at least one of a number of Resource Blocks, a number of subcarriers, a number of subcarrier groups, a number of resource block groups, and a configuration index. delete

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