KR20170057853A - Terminal and method for performing of self interference channel sounding thereof - Google Patents

Abstract

A method for performing self interference channel sounding in a UE includes transmitting a sounding request signal including a reference signal for self-interference channel estimation and a parameter used for determining whether self peer channel sounding is successful, Estimating a self interference channel using the sounding request signal received through the antenna of the mobile station; waiting for reception of a sounding response signal from a counterpart terminal that has received the sounding request signal; And transmitting a sounding report signal for notifying the self interference channel sounding completion status to the counterpart terminal when the dormant response signal is received and the self interference channel sounding of the terminal is completed.

Description

TECHNICAL FIELD [0001] The present invention relates to a self-interference channel sounding method,

The present invention relates to a method for performing self interference channel sounding in a terminal and a terminal, and more particularly, to a method for performing self interference channel sounding in a terminal and a terminal in a same band full duplex wireless communication system.

In a half duplex (HD) system currently used in a wireless communication system, transmission / reception is performed by distributing time / frequency. Therefore, orthogonality between transmission and reception can be maintained in a wireless communication system using the HD scheme. On the other hand, in the wireless communication system using the HD scheme, time / frequency resources are wasted.

In-band Full Duplex (IFD) is a solution to overcome the inefficiency of the HD system and is a technology capable of transmitting and receiving simultaneously in the same band. The IFD scheme can theoretically increase the link capacity up to twice as much as the HD scheme.

On the other hand, the IFD scheme has a problem that a self-interference signal (SI) signal is generated which is stronger than the effective reception signal due to the self-transmission signal being introduced into the receiver. Therefore, it is necessary to remove the SI in order to perform smooth communication by the IFD method.

A problem to be solved through embodiments of the present invention is to provide a method for performing self interference channel sounding of a terminal and a terminal to improve the accuracy of self interference channel estimation.

According to another aspect of the present invention, there is provided a method for performing self interference channel sounding in a terminal, the method comprising: receiving a reference signal for self-interference channel estimation and a self- A step of estimating a self interference channel using the sounding request signal received through an antenna of the terminal, a step of estimating a self interference channel using the sounding request signal received through the antenna of the terminal, Waiting for reception of a ding response signal, and, when the sounding response signal is received and the self interference channel sounding of the terminal is completed, transmitting a sounding report signal for notifying the self interference channel sounding completion status to the mating side To the terminal.

According to the embodiment of the present invention, the magnetic interference signal can be effectively reduced by improving the magnetic interference channel estimation accuracy.

Figure 1 schematically illustrates a terminal according to embodiments.
Figure 2 shows an example of an IFD transceiver.
3 schematically shows a method of performing SI channel sounding of a UE according to an embodiment of the present invention.
4 schematically illustrates a method for performing SI channel sounding of a UE according to another embodiment of the present invention.
5 schematically illustrates a method for performing SI channel sounding of a UE according to another embodiment of the present invention.
FIG. 6 illustrates an example in which the SI channel sounding method according to the embodiments is performed in a wireless LAN environment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification and claims, when a section is referred to as "including " an element, it is understood that it does not exclude other elements, but may include other elements, unless specifically stated otherwise.

Throughout the specification, a terminal is referred to as a mobile terminal (MT), a mobile station (MS), an advanced mobile station (AMS), a high reliability mobile station (HR- A subscriber station (SS), a portable subscriber station (PSS), an access terminal (AT), a user equipment (UE) , HR-MS, SS, PSS, AT, UE, and the like.

Also, a base station (BS) is an advanced base station (ABS), a high reliability base station (HR-BS), a node B, an evolved node B, eNodeB), an access point (AP), a radio access station (RAS), a base transceiver station (BTS), a mobile multihop relay (MMR) (RS), a relay node (RN) serving as a base station, an advanced relay station (ARS) serving as a base station, a high reliability relay station (HR) A femto BS, a home Node B, a HNB, a pico BS, a metro BS, a micro BS, ), Etc., and all or all of ABS, Node B, eNodeB, AP, RAS, BTS, MMR-BS, RS, RN, ARS, HR- And may include negative functionality.

Throughout the specification, a transceiver may be a terminal, a mobile terminal (MT), a mobile station (MS), an advanced mobile station (AMS), a high reliability mobile station , An HR-MS, a subscriber station (SS), a portable subscriber station (PSS), an access terminal (AT), user equipment (UE) MS, AMS, HR-MS, SS, PSS, AT, UE, and the like.

In addition, the transceiver includes a base station (BS), an advanced base station (ABS), a high reliability base station (HR-BS), a node B, an evolved node B, an eNodeB, an access point (AP), a radio access station (RAS), a base transceiver station (BTS), a mobile multihop relay (MMR) And may be referred to as a relay station (RS), a high reliability relay station (HR-RS) serving as a base station, etc., and may be referred to as an ABS, a Node B, an eNodeB, an AP, a RAS, a BTS, BS, RS, HR-RS, and the like.

Hereinafter, with reference to necessary drawings A self-interference (SI) channel estimation method for a terminal and a terminal in an in-band full duplex (IFD) wireless communication system according to embodiments of the present invention will be described in detail.

Figure 1 schematically illustrates a terminal according to embodiments.

Referring to FIG. 1, a terminal 100 according to embodiments may include a processor 130, a transceiver 110, and a memory 130. Figure 2 shows an example of an IFD transceiver.

The transceiver 110 can transmit and receive a signal in the IFD scheme under the control of the processor 130.

2, the transceiver 110 for communicating by the IFD method may include one antenna ANT10, an antenna ANT10, a distributor D10, an analog circuit section, and a digital circuit section.

The distributor D10 is connected between the antenna ANT10 and the analog circuitry.

The distributor D10 transmits the transmission signal to the transmission path, and transmits the reception signal to the reception path to distribute the transmission signal and the reception signal. The distributor D10 receives a transmission signal from an analog circuit (for example, a power amplifier (PA) or the like) and transmits it to the antenna ANT10. The distributor D10 receives the received signal from the antenna ANT10 and delivers it to an analog circuitry (e.g., a Low Noise Amplifier (LNA)).

The distributor D10 has a characteristic of separating the transmission path and the reception path from each other in communication using the IFD method as described above. Due to this characteristic, the distributor D10 can perform SI Cancellation (SIC) which suppresses the occurrence of self interference (SI). That is, since the transmission path and the reception path are separated from each other by the distributor D10, generation of SI that causes interference with the reception signal transmitted along the reception path of the transmission signal transmitted along the transmission path can be suppressed. SI denotes an interference caused by the transmission signal of the transceiver 110 communicating in the IFD scheme to its received signal. SI may be generated by a signal transmitted through the antenna ANT10 of the transceiver 110 into the antenna ANT10 of the transceiver 110 or by reflection or leakage on the internal circuit of the transceiver 110 .

The transceiver 110 can transmit and receive signals simultaneously via the antenna ANT10 by using the distributor D10 in the IFD method.

The distributor D10 may include a circulator, an electrical balance duplexer (EBD), and the like. The EBD may include a hybrid transformer and a balance network.

The analog circuit unit of the transceiver 110 performs a function of converting an analog received signal from the antenna ANT10 into a digital received signal. A received signal converted into a digital signal by each analog circuit section is transmitted to a corresponding digital circuit section and processed.

To this end, the analog circuit portion may include a low noise amplifier (LNA) 10, an integrator (INT10), and an analog to digital converter (ADC10).

The low noise amplifier LNA10 removes noise from the analog received signal received via the antenna ANT10, amplifies the noise-removed analog receive signal, and outputs it to the integrator INT10.

The integrator INT10 receives an analog reception signal of a radio frequency (RF) band and converts it into an analog reception signal of a baseband using a carrier frequency signal f _C.

The analog-to-digital converter (ADC10) converts an analog reception signal converted from the integrator (INT10) to baseband into a digital reception signal and outputs it to the digital circuitry.

The analog circuit section performs a function of converting a digital transmission signal from the corresponding digital circuit section into an analog transmission signal. The transmission signal converted into the analog signal by the analog circuit unit is transmitted to the antenna ANT10 by the corresponding distributor D10.

To this end, the analog circuitry of the transceiver 110 may include a digital to analog converter (DAC) 10, a mixer MIX 10, and a power amplifier PA 10.

The digital-to-analog converter (DAC10) converts a digital transmission signal from a digital circuit unit into an analog transmission signal of a baseband and outputs the analog transmission signal.

Mixer (MIX10) is when the analog signal transmitted from the baseband input from the digital-to-analog converter (DAC10), using a carrier frequency signal (f _C) and converts it into an analog transmission signal of the RF band.

The power amplifier PA10 receives the analog reception signal converted into the RF band from the mixer MIX10, amplifies and outputs the analog reception signal.

The analog transmission signal amplified by the power amplifier PA10 is transmitted to the antenna ANT10 via the distributor D10 and transmitted by the antenna ANT10.

The analog circuit portion of the transceiver 110 is connected to a finite impulse response filter FIR10 and a coupler C10 in order to remove SI that is not removed by the distributor D10, ).

The FIR filter FIR10 uses the transmission signal of the transceiver 110 to generate an interference cancellation signal for eliminating the SI generated due to the transmission signal of the transceiver 110 from the transmission signal.

The FIR filter FIR10 receives the transmission signal of the transceiver 110 from the power amplifier PA10 and generates an interference cancellation signal from the transceiver 110 therefrom. The FIR filter (FIR10) uses the SI channel information in the analog domain to generate an interference cancellation signal. The SI channel in the analog domain can be estimated through a sounding process to be described later, and the FIR filter FIR10 can receive it and use it to generate an interference cancellation signal.

The interference cancellation signal generated by the FIR filter FIR10 is input to the combiner C10.

The coupler C10 is connected between the distributor D10 and the low noise amplifier LNA10 to receive the received signals from the distributor D10.

The combiner C10 removes the SI from the received signal using the interference cancellation signal generated by the FIR filter FIR10 and outputs it when the received signal is input from the distributor D10. That is, the combiner C10 removes the SI from the received signal by combining the received signal transmitted through the distributor D10 and the interference elimination signal input from the FIR filter FIR10, and outputs the SI.

The reception signal from which SI is removed by the coupler C10 is output to the low noise amplifier LNA10.

The digital circuit section of the transceiver 110 decodes the digital received signal from the analog circuit section and outputs the received data. In addition, the digital circuit of the transceiver 110 encodes the transmission data and outputs a digital transmission signal.

To this end, the digital circuitry of the transceiver 110 may include a decoder DEC10 and an encoder ENC10.

The decoder DEC10 decodes the analog received signal from the analog circuit (for example, the analog-to-digital converter ADC10) of the transceiver 110 and outputs the received data.

The encoder ENC10 encodes the transmission data of the transceiver 110 and generates a digital transmission signal. The digital transmit signal generated by the encoder ENC10 is delivered to the analog circuitry of the transceiver 110 (e.g., the digital-to-analog converter DAC10).

The digital circuit part of the transceiver 110 can not be removed from the analog circuit part and may be introduced into the digital circuit part or a digital interference eliminator (Digital SIC) (DSIC 10) and a digital reference generator (DRG10).

The digital interference canceller DSIC10 may be connected between the analog circuitry of the transceiver 110 (for example, the analog-to-digital converter ADC10) and the decoder DEC10.

The digital interference canceller DSIC10 removes the remaining SI from the digital received signal that is transmitted from the analog circuitry (e.g., the analog-to-digital converter ADC10) to the decoder DEC10 using the digital transmit signal of the transceiver 110 .

The digital reception signal inputted from the analog circuit section of the transceiver 110 to the digital interference eliminator DSIC 10 is supplied to the elements constituting the reception path (distributor, adder, low noise amplifier, Digital converter, etc.). As a result, the SI component of the transmission signal flowing into the reception signal is also distorted while being input to the digital circuit section through the reception path.

On the other hand, as shown in FIG. 2, when a digital transmission signal used in the digital SIC is received from the encoder ENC10 in the digital interference eliminator (DSIC) 10, the distorted SI component can not be sufficiently removed have.

Accordingly, the digital reference generator DRG10 distorts the digital transmission signal output from the encoder ENC10 similarly to the distortion on the reception path, and outputs the distortion to the digital interference eliminator DSIC10. The digital interference eliminator DSIC10 performs digital SIC using the digital transmission signal distorted by the digital reference generator DRG10. The digital reference generator DRG10 distorts the digital transmission signal output from the encoder ENC10 , It uses the SI channel information in the digital domain. In the digital domain, the SI channel can be estimated through a sounding process described later, and the digital reference generator DRG10 can receive the signal and use it to distort the digital transmission signal.

2 illustrates an example in which the transceiver 110 supports the IFD communication scheme. However, the present invention is not limited thereto, and thus the transceiver 110 may perform a half duplex (HD) communication in addition to the IFD communication scheme It can also support additional methods.

Referring again to FIG. 1, the memory 120 stores instructions for performing operations in the processor 130 or may temporarily store an instruction loaded from a storage device (not shown).

The memory 120 is connected to the processor 130 via a bus (not shown), and an input / output interface (not shown) may also be connected to the bus. At this time, the transceiver 110 is connected to the input / output interface, and peripheral devices such as an input device, a display, a speaker, and a storage device may be connected.

The processor 130 may execute instructions stored in or loaded in the memory 120 and control the overall operation of the terminal 100. [

The processor 130 may control the transceiver 110 to communicate in an IFD manner. The processor 130 activates the modules (the digital circuit portion, the analog circuit portion, the distributor D10, the antenna ANT10 and the like in Fig. 2) supporting the IFD communication in the transceiver 110 when the IFD communication is determined, .

Processor 130 may control transceiver 110 to communicate in a half duplex (HD) manner. When the HD communication is determined, the processor 130 activates modules (not shown) supporting HD communication in the transceiver 110 and sets HD related parameters.

The processor 130 may perform a sounding process for SI channel estimation in a preprocessing step when the terminal 100 desires to communicate using the IFD scheme. A method of performing sounding for SI channel estimation when the terminal 100 intends to perform IFD communication will be described in detail with reference to FIG.

The processor 130 may perform a sounding process for SI channel estimation for IFD communication with a corresponding terminal if sounding related to the SI channel estimation is requested from another terminal to communicate with the IFD system. A method of performing a sounding of the terminal 100 in a case where sounding for SI channel estimation is requested from another terminal to communicate by the IFD method will be described in detail with reference to FIG.

When the sounding is completed and the SI channel is estimated, the processor 130 can remove the SI signal from the signal received in the IFD communication process based on the estimated SI channel.

The processor 130 may re-perform the sounding process for estimating the SI channel during the IFD communication. A method for re-performing the sounding process for SI channel estimation while the terminal 100 is communicating by the IFD method will be described in detail with reference to FIG.

Hereinafter, a method of performing sounding when the terminal 100 desires to communicate using the IFD communication method will be described in detail with reference to FIG.

3 schematically shows a method of performing SI channel sounding of a UE according to an embodiment of the present invention. The sounding method of FIG. 3 may be performed by the processor 130 of the terminal 100 described with reference to FIG.

Referring to FIG. 3, when the IFD communication is determined, the AT 100 enters the IFD mode (SlOO).

In step S100, the IFD terminal 100 activates modules supporting IFD communication in the transceiver 110 to enter the IFD mode, and can set relevant parameters of the transceiver 110 to support the IFD communication scheme. The IFD terminal 100 includes all paths (a digital circuit section, an analog circuit section, a distributor, an antenna, and the like) and a transceiver (hereinafter, referred to as a " transceiver ") through which a transmission signal is generated and transmitted through the transceiver 110, The IFD-related parameter of the transceiver 110 can be set to reflect the characteristic of the radio channel through which the signal transmitted through the IFFT unit 110 is transmitted. In particular, the IFD terminal 100 may activate the modules (FIR, combiner, digital interference eliminator, digital reference generator, etc.) added to the transceiver 110 to remove the SI signal and set related parameters.

In operation S100, the IFD terminal 100 may perform preparations for SI channel estimation by activating modules necessary for sounding and setting related parameters in order to operate in the IFD mode.

Upon entering the IFD mode, the terminal 100 generates a sounding request signal for SI channel estimation (S101). In addition, the generated sounding request signal is transmitted through the transceiver 110 (S102).

In step S101, the sounding request signal may be used for SI channel estimation of the terminal 100 itself. For this purpose, the sounding request signal may include a reference signal of a specific pattern for SI channel estimation of the AT.

In step S101, the sounding request signal may include various information necessary for sounding.

The sounding request signal may include channel region information indicating an SI channel region. The SI channel region is an area to which SI channel estimation is applied, that is, a channel region in which reference signals of a specific pattern used for SI channel estimation are transmitted.

The sounding of the terminal 100 may be divided into a plurality of sounding steps. For example, sounding can be performed by dividing into at least one analog sounding step performed in the analog domain and a digital sounding step performed in the digital domain. In this case, the reference signal may be changed according to the sounding step, and the channel region in which the reference signal is transmitted may also be changed. For example, the reference signal transmitted in the analog sounding step and the reference signal transmitted in the digital sounding step may be designed differently according to the characteristics of each SI channel, and may be transmitted through different channel regions. When the sounding is divided into a plurality of steps, the terminal 100 may generate channel region information corresponding to a channel region in which the reference signal is transmitted for each step, and may include the channel region information in the sounding request signal. Also, the terminal 100 may generate the channel region information so that the channel region in which the reference signal is transmitted is included in each step.

Instead of including the channel region information used for SI channel region estimation in the sounding request signal, the terminal 100 may directly transmit the channel region information to the analog circuit portion and the digital circuit portion of the transceiver 110 through the internal interface .

The sounding request signal may include information on the state of sounding for SI channel estimation of the AT.

Sounding of the terminal 100 may be performed sequentially through a plurality of steps. In this case, the terminal 100 may transmit a sounding request signal at least once every step, and may include its sounding progress state information for each sounding request signal transmitted. The sounding progress status information may include information about the sounding completion level of the terminal 100 by the current stage or the sounding stage to be performed using the sounding request signal transmitted by the terminal 100. [ Accordingly, the counterpart terminal, which has received the sounding request signal of the terminal 100, can predict the sounding progress state for the SI channel estimation of the terminal 100. [

The sounding request signal may include configuration information (hereinafter, referred to as 'sounding configuration information') necessary for sounding for SI channel estimation of the peer terminal.

The sounding configuration information of the other terminal may include information necessary for the other terminal to perform sounding for its SI channel estimation.

The sounding configuration information of the counterpart terminal may include a parameter used by the counterpart terminal to determine whether sounding is completed (or succeeded) for its SI channel estimation. For example, the sounding configuration information includes an SI signal strength threshold value (hereinafter, referred to as a 'first threshold value') used as an index for determining whether the sounding process for estimating the SI channel of the other party terminal is completed ). If the signal strength of the remaining SI signal is less than the first threshold value, the counterpart terminal can complete the sounding for the SI channel estimation through the sounding process for estimating its SI channel, . On the other hand, when sounding for SI channel estimation is performed by dividing into a plurality of steps, the first threshold value may be set separately for each step or may be set to the same value for all steps.

The sounding configuration information of the peer terminal may include a parameter used by the peer terminal to determine re-performance of sounding for SI channel estimation. For example, the sounding configuration information includes an SI signal strength threshold value (hereinafter, referred to as a 'second threshold value') used as an indicator for determining whether or not the counterpart terminal performs sounding reuse for SI channel estimation during IFD communication ). If the signal strength of the residual SI signal remaining after removing the SI using the SI channel estimated through previous sounding during the IFD communication is less than the second threshold value, the counterpart terminal receiving the signal strength estimates the sounding for SI channel estimation Can be performed.

The sounding configuration information is not included in the sounding request signal, and sounding configuration information set in advance may be used according to the type of the sounding request signal. In this case, the counterpart terminal can perform sounding for its own SI channel estimation using the preset sounding configuration information, so that the terminal 100 need not separately transmit the counterpart sounding configuration information.

At least one of the channel region information, the progress state information, and the sounding configuration information is not embedded in the sounding request signal, but may be a separate signal (hereinafter referred to as a sounding control signal) May be generated and transmitted. In this case, the sounding request signal and the sounding control signal may be sequentially transmitted through signaling. For example, the sounding control signal may be transmitted prior to the sounding request signal.

In step S102, the terminal 100 can transmit a sounding request signal in a broadcast manner without specifying the other terminal. The terminal 100 may generate a sounding request signal so as to include information for specifying a peer terminal to participate in sounding for its SI channel estimation. In this case, the receiving address of the sounding request signal may include information of the other-side terminal desiring to participate in its sounding.

On the other hand, the other terminal capable of participating in sounding for SI channel estimation of the terminal 100 supports the IFD communication function, or even if the terminal 100 does not support the IFD function, the terminal 100 transmits the uplink and downlink in the same band And can be used simultaneously to communicate with each other.

In step S102, the terminal 100 may transmit a sounding request signal in a multi-user transmission mode. For example, the IFD terminal 100 may transmit a sounding request signal based on OFDMA (Orthogonal Frequency-Division Multiple Access) or MU MIMO (multi-user multiple input & multiple output). In this case, the terminal 100 itself may be included in a plurality of terminals participating in multi-user transmission.

In step S102, the sounding request signal transmitted through the transceiver 110 is also received by the transceiver 110 of the terminal 100 itself (step S103). When the terminal 100 receives its sounding request signal through the transceiver 110, the terminal 100 performs SI channel estimation for SI removal (S104).

In step S104, the UE 100 extracts a reference signal for SI channel estimation from the sounding request signal transmitted from the UE 100, and estimates the SI channel using the extracted reference signal. If the sounding is performed in a plurality of stages, the reference signal used for SI channel estimation may differ depending on the step. Therefore, if the terminal 100 extracts the reference signal from the sounding request signal, the terminal 100 can perform the SI channel estimation in accordance with the corresponding step. For example, if the received sounding request signal is for the analog sounding stage, the terminal 100 can perform SI channel estimation in the analog domain using the reference signal extracted from the received sounding request signal .

Meanwhile, according to the structure of the estimation module, the convergence time of the initial estimation may become longer in the SI channel estimation. Therefore, the IFD terminal 100 may transmit / receive the sounding request signal more than once to estimate the SI channel in each step, or vary the length of the sounding request signal according to the structure of the channel estimation module in each step.

After transmitting the sounding request signal for SI channel estimation, the terminal 100 waits for a predetermined time to receive the corresponding sounding response signal (S105).

The sounding request signal transmitted through step S102 may operate as a trigger signal for instructing the other terminal to perform SI channel sounding. That is, the other terminal, which has received the sounding request signal transmitted from the terminal 100, can perform sounding for its own SI channel estimation in a time division manner. In addition, a sounding response signal for the sounding request signal can be transmitted to the terminal 100. The sounding response signal may include a reference signal for estimating the SI channel of the other terminal itself, sounding progress status information of the other terminal, and the like.

If the terminal 100 does not receive a sounding response signal from the other terminal even after waiting for a predetermined time, the terminal 100 determines that the SI channel sounding of the other terminal has failed. In addition, if information indicating successful reception of the sounding request signal of the other terminal is not included even though the sounding response signal is received from the other terminal, it is determined that the SI channel sounding of the other terminal is failed (S106).

If it is determined that the sounding for SI channel estimation of the counterpart terminal has failed, the terminal 100 retransmits the sounding request signal and requests sounding of the counterpart terminal again (S107).

In FIG. 3, when a sounding response signal is not received from the other terminal even after waiting for a predetermined time, the sounding request signal is retransmitted. However, the present invention is not limited thereto. In another embodiment, if a sounding response signal is not received from the other terminal even after waiting for a predetermined time, the terminal 100 may re-execute the steps S101 to S104 to perform the sounding process at the current step again. In another embodiment, if a sounding response signal is not received from the other terminal after waiting for a predetermined time, the terminal 100 may transmit a separate trigger signal to instruct the other terminal to perform the sounding process.

When the terminal 100 receives the sounding response signal from the other terminal, it determines whether the sounding is completed (S108).

The sounding process can be performed by dividing into a plurality of sounding steps. In this case, the terminal 100 can determine that the sounding process is completed only after all the sounding steps are completed. For example, if the sounding process for SI channel estimation is divided into an analog SI channel sounding step and a digital SI channel sounding step and the terminal 100 has performed only the current analog SI channel sounding step, 100) may determine that the sounding process is not completed.

The terminal 100 may repeat steps S101 through S105 until all the sounding steps are completed and the sounding process is completed. In this process, if the SI channel estimation in the previous sounding step is completed, the terminal 100 can generate a sounding response signal to perform the next sounding step. For example, if the terminal 100 has completed the current analog SI channel sounding step, the terminal 100 may generate a sounding request signal so that the digital SI channel sounding step is performed.

When it is determined that the sounding of the other party's terminal has successfully started and the sounding process of the other party's terminal has been completed, the terminal 100 transmits a sounding report signal (S109).

In step S109, the sounding report signal may be transmitted to obtain the SI channel estimation accuracy.

After transmitting the sounding report signal, the terminal 100 receives the sounding report signal through its own transceiver 110 and acquires the estimation accuracy of the SI channel using the received sounding report signal (S110). Then, it is determined whether or not SI channel sounding has failed based on this (S111).

In step S110, the UE 100 estimates the SI signal by multiplying the pre-transmission sounding report signal by the SI channel estimation value. The estimated SI signal is removed from the sounding report signal received in step S109, and the accuracy of the SI channel estimation can be calculated based on the signal strength of the remaining residual SI signal.

In step S110, the SI channel estimation accuracy can be calculated by dividing the accuracy of the analog SI channel estimation and the accuracy of the digital SI channel estimation. The terminal 100 calculates the analog SI channel estimation accuracy using the SI channel estimation value obtained through the analog SI channel sounding step and calculates the digital SI channel estimation value using the SI channel estimation value obtained through the digital SI channel sounding step. The accuracy can be calculated.

In step S111, if the SI channel estimation accuracy is less than a predetermined level, the terminal 100 determines that the SI channel sounding has failed and can perform the sounding process for the SI channel estimation (steps S101 to S109) again have.

If at least one of the analog SI channel estimation accuracy and the digital SI channel estimation accuracy is less than a predetermined level, if the SI channel estimation accuracy is divided into the analog SI channel estimation accuracy and the digital SI channel estimation accuracy, It is determined that the sounding has failed and the sounding process for estimating the SI channel (S101 to S109) can be performed again.

The terminal 100 determines that the SI channel sounding is successful if the SI channel estimation accuracy is higher than a predetermined level, and ends the sounding process.

As the sounding process is terminated, the terminal 100 communicates with another terminal using the IFD communication method (S112).

In step S112, the UE 100 may remove the SI signal from the signal received in the IFD communication process using the SI channel estimation value obtained through the sounding process.

Although not shown in FIG. 3, the terminal 100 may further perform a step of receiving a sounding report signal of the counterpart terminal from the counterpart terminal after transmitting the sounding report signal. The sounding report signal of the counterpart terminal can be used to determine whether decoding of the signal received from the counterpart terminal is successfully performed as the same signal as the sounding report signal transmitted by the terminal 100. [ The terminal 100 removes the SI signal from the sounding report signal received from the counterpart terminal using the SI channel estimation value estimated through the sounding process, and then decodes the sounding report signal from which the SI signal has been removed, Can be determined.

Also, the terminal 100 can acquire various information necessary for IFD communication using the sounding report signal received from the counterpart terminal. For example, the terminal 100 may acquire a signal strength of a residual SI signal, a received signal size of a desired signal, and a signal-to-noise ratio after removing an SI signal from a received signal using a sounding report signal . This information can be used to control the Modulation and Coding Scheme (MCS) or the transmission power level in the course of performing IFD communication thereafter. The desired signal can be obtained by removing the SI signal from the received sounding report signal as a signal that the terminal 100 desires to receive.

When frame synchronization is required to receive a sounding report signal of a counterpart terminal from a counterpart terminal, the terminal 100 calculates an air propagation time based on an end of a sounding response signal transmitted last by the counterpart terminal, So that the signal transmission timing can be set so that the difference between the starting point of the sounding report signal transmitted and received between the terminal 100 and the counterpart terminal is larger than the cyclic prefix.

Although not shown in FIG. 3, the terminal 100 may perform the SI channel sounding process again after receiving the sounding report signal from the counterpart terminal. For example, when the terminal 100 fails to decode the sounding report signal received from the counterpart terminal, it can be determined that the SI channel sounding has failed and the sounding process can be performed again.

The terminal 100 acquires the sounding success or failure of the counterpart terminal from the sounding report signal. If it is determined that the sounding process of the counterpart terminal fails, the terminal 100 retransmits the sounding request signal to trigger the sounding re- You may.

3, the terminal 100 transmits a sounding report signal when all the sounding steps are completed. However, the present invention is not limited thereto. The terminal 100 may transmit a sounding report signal each time the sounding step is completed. For example, if the sounding process for SI channel estimation is divided into an analog SI channel sounding step and a digital SI channel sounding step, the terminal 100 transmits a sounding report signal And transmit the sounding report signal again after the digital SI channel sounding step is completed. In this case, the terminal 100 acquires the SI channel estimation accuracy at the corresponding step for each sounding step, and if the SI channel estimation accuracy at the corresponding step does not satisfy the preset level, the terminal 100 re-performs the corresponding sounding step Can be determined.

Instead of allocating a separate radio resource for the transmission of the sounding report signal, the terminal 100 and the counterpart terminal may transmit the sounding request signal and the sounding response signal to the sounding report signal so that the sounding request signal and the sounding response signal include the signaling signal serving as the sounding report signal. Request signal and a sounding response signal. For example, the terminal 100 and the counterpart terminal may alternately transmit a signal for sounding and a signaling signal to the sounding request signal and the sounding response signal, respectively. In this case, the terminal 100 transmits and receives a signaling signal to and from the counterpart terminal at each sounding stage, and can determine whether or not SI channel sounding at each sounding stage has failed.

Meanwhile, the terminal 100 may perform a sounding process in response to a request for sounding from another terminal for which IFD communication is determined.

Hereinafter, a method of performing sounding when the terminal 100 is requested to perform sounding from another terminal for which IFD communication has been determined will be described in detail with reference to FIG.

4 schematically illustrates a method for performing SI channel sounding of a UE according to another embodiment of the present invention. The sounding method of FIG. 4 may be performed by the processor 130 of the terminal 100 described with reference to FIG.

Referring to FIG. 4, the terminal 100 may receive a sounding request signal from another terminal for which IFD communication is determined (S200). When the sounding request signal is received, the terminal 100 decodes it and enters the IFD mode (S201).

In step S201, the IFD terminal 100 activates modules supporting IFD communication in the transceiver 110 to enter the IFD mode, and can set related parameters of the transceiver 110 to support the IFD communication method. Also, in order to participate in the sounding process of the peer terminal that has transmitted the sounding request signal, the module for the SI channel sounding may be activated and the related parameters may be set to perform the preparation process for the SI channel estimation.

In step S201, the IFD terminal 100 can acquire the sounding progress status of the counterpart terminal that has transmitted the sounding request signal from the sounding request signal. Also, the IFD terminal 100 may acquire sounding configuration information necessary for sounding for its SI channel estimation. The sounding configuration information may include a parameter that is used by the IFD terminal 100 to determine whether or not sounding for its own SI channel estimation has been completed. For example, the sounding configuration information may include an SI signal strength threshold value used by the IFD terminal 100 as an indicator for determining whether or not the sounding process for estimating its SI channel is successful. The sounding configuration information may include parameters that are used by the IFD terminal 100 to determine re-execution of the sounding process. For example, the sounding configuration information may include an SI signal strength threshold used as an indicator for determining whether the IFD terminal 100 performs sounding re-estimation for SI channel estimation during IFD communication.

The sounding request signal is a trigger signal for instructing the terminal 100 to perform sounding.

Accordingly, the terminal 100 receiving the signal generates a sounding response signal for sounding its SI channel (S202), and transmits the sounding request signal to the transmitting terminal (S203).

In step S202, the sounding response signal may include information indicating a successful reception of the sounding request signal by the terminal 100. [ Accordingly, if the sounding response signal does not include information indicating a successful reception of the sounding request signal, the counterpart terminal can determine that the sounding start of the terminal 100 has failed.

The sounding response signal may be used for SI channel estimation of the terminal 100 itself. To this end, the sounding response signal may include a reference signal of a specific pattern for SI channel estimation of the UE 100. [

The sounding response signal may contain various information needed for sounding.

The sounding response signal may include channel region information indicating an SI channel region.

The sounding response signal may include sounding progress status information of the AT 100. [ The sounding progress status information may include information about the sounding completion level of the terminal 100 by the current level or the sounding level to be performed using the sounding response signal that the terminal 100 is currently transmitting. Accordingly, the counterpart terminal, which has received the sounding response signal of the terminal 100, can predict the sounding progress state for SI channel estimation of the terminal 100. [

The sounding response signal may include sounding configuration information necessary for sounding for SI channel estimation of the other terminal. The sounding configuration information of the counterpart terminal may include a parameter used by the counterpart terminal to determine whether sounding is completed for SI channel estimation of the counterpart terminal. For example, the sounding configuration information may include an SI signal strength threshold value used by the peer terminal as an indicator for determining whether the sounding process for estimating the SI channel is completed. The sounding configuration information of the peer terminal may include a parameter used by the peer terminal to determine re-performance of sounding for SI channel estimation. For example, the sounding configuration information may include an SI signal strength threshold used as an indicator for determining whether or not to perform a sounding reuse for estimating an SI channel during IFD communication by the counterpart terminal.

Sounding configuration information is not included in the sounding response signal, and predetermined sounding configuration information may be used. In this case, the counterpart terminal can perform sounding for its own SI channel estimation using the preset sounding configuration information, so that the terminal 100 need not separately transmit the counterpart sounding configuration information.

Meanwhile, at least one of the channel region information, the progress state information, and the sounding configuration information may not be embedded in the sounding response signal, but may be generated as a separate signal (sounding control signal) and transmitted . In this case, the sounding response signal and the sounding control signal may be sequentially transmitted through signaling. For example, the sounding control signal may be transmitted prior to the sounding response signal.

The sounding response signal transmitted through the transceiver 110 in step S203 is also received by the transceiver 110 of the terminal 100 itself (S204). When the terminal 100 receives its sounding response signal through the transceiver 110, the terminal 100 performs SI channel estimation for SI removal (S205).

In step S205, the UE 100 extracts a reference signal for SI channel estimation from the sounding response signal transmitted from the UE 100, and estimates the SI channel using the extracted reference signal. When the sounding process is performed by dividing into a plurality of steps, the reference signal used for the SI channel estimation may be different depending on the step. Therefore, when the UE 100 extracts the reference signal from the sounding response signal, the UE 100 can perform SI channel estimation in accordance with the corresponding step. For example, if the received sounding response signal is for the analog sounding stage, the terminal 100 can perform the SI channel estimation in the analog domain using the reference signal extracted from the received sounding response signal .

The terminal 100 may repeat steps S202 through S205 until all the sounding steps are successfully performed and the sounding process is completed (S206). In this process, if the SI channel estimation in the previous sounding step is completed, the terminal 100 can generate a sounding response signal to perform the next sounding step. For example, if the terminal 100 has completed the current analog SI channel sounding step, the terminal 100 may generate a sounding response signal so that the digital SI channel sounding step is performed.

When all the sounding steps for SI channel estimation are successfully performed and the sounding process is completed, the terminal 100 transmits a sounding report signal to the counterpart terminal (S207).

In step S207, the sounding report signal may be transmitted to obtain the SI channel estimation accuracy.

4, the sounding report signal is transmitted when all the sounding steps are successfully performed and the sounding process of the terminal 100 is completed. However, the present invention is not limited thereto. For example, the terminal 100 may transmit a sounding report signal when a sounding report signal is received from the counterpart terminal. Also, for example, the terminal 100 may synchronize the sounding report signal with the counterpart terminal, and transmit the sounding report signal simultaneously with the counterpart terminal. Also, for example, the terminal 100 may transmit a sounding report signal each time each sounding step is completed.

After transmitting the sounding report signal, the terminal 100 receives the sounding report signal through its own transceiver 110 and acquires the estimation accuracy of the SI channel using the received sounding report signal (S208). Then, it is determined whether or not the SI channel sounding has failed based on this (S209).

In step S208, the SI channel estimation accuracy can be calculated by dividing the accuracy of the analog SI channel estimation and the accuracy of the digital SI channel estimation. The terminal 100 calculates the analog SI channel estimation accuracy using the SI channel estimation value obtained through the analog SI channel sounding step and calculates the digital SI channel estimation value using the SI channel estimation value obtained through the digital SI channel sounding step. The accuracy can be calculated.

In step S209, if the SI channel estimation accuracy is less than the predetermined level, the UE 100 determines that the SI channel sounding has failed. When it is determined that the SI channel sounding has failed, the AT 100 may transmit a sounding report signal indicating that the SI channel sounding has failed to the counterpart terminal (S210).

The other terminal receives the sounding report signal indicating that the SI channel sounding has failed from the terminal 100 and transmits a signal (e.g., a sounding request signal) requesting the terminal 100 to perform the sounding procedure again (100). The terminal 100 receiving the data can re-estimate the SI channel by performing the sounding process again. In this case, the terminal 100 may not re-perform all the sounding steps, but may re-execute only the sounding step in which channel estimation has failed. For example, if the terminal 100 succeeds in analog SI channel sounding but fails in digital SI channel sounding, only the digital SI channel sounding step may be performed again.

In step S209, if the SI channel estimation accuracy is equal to or greater than a preset level, the terminal 100 determines that the SI channel sounding of the terminal 100 is successful and performs IFD communication (S211).

In step S211, the UE 100 may remove the SI signal from the signal received in the IFD communication process using the SI channel estimation value obtained through the sounding process.

Meanwhile, the terminal 100 may re-perform the sounding process during the IFD communication.

Hereinafter, a method of performing sounding during IFD communication by the AT 100 will be described in detail with reference to FIG.

5 schematically illustrates a method for performing SI channel sounding of a UE according to another embodiment of the present invention. The sounding method of FIG. 5 may be performed by the processor 130 of the terminal 100 described with reference to FIG.

Referring to FIG. 5, the AT 100 continuously calculates a signal-to-interference noise ratio of a received signal during IFD communication (S300).

If the signal to interference noise ratio of the received signal is lower than a preset threshold (S301), the terminal 100 performs a sounding process to update the SI channel estimation (S302).

In step S302, the terminal 100 generates a sounding trigger signal corresponding to each sounding step for SI channel estimation. Then, the sounding step is sequentially performed by transmitting a sounding trigger signal corresponding to each sounding step. When the sounding trigger signal transmitted by the terminal 100 is received by the transceiver 110 of the terminal 100, the terminal 100 can perform the sounding process by performing the SI channel estimation in each sounding stage using the received sounding trigger signal.

The sounding trigger signal can be generated by aggregating a general data signal and a reference signal for SI channel estimation as a signal for SI channel estimation of the UE 100. [

5, the sounding process is performed when the signal-to-interference noise ratio of the received signal is less than the threshold value. However, the present invention is not limited to this, Process can be performed. Also in this case, the terminal 100 can perform the sounding process using the sound trigger signal generated by collecting the general data signal and the reference signal.

FIG. 6 illustrates an example in which the SI channel sounding method according to the embodiments is performed in a wireless LAN environment.

In FIG. 6, the two terminals 100-1 and 100-2 are terminals supporting IFD communication, and sounding can be performed by dividing into an analog SI channel sounding step and a digital SI channel sounding step.

Referring to FIG. 6, the first terminal 100-1 determining IFD communication in a wireless LAN environment transmits an RTS (Request to Send) to acquire a channel (S400), and attempts resource reservation. If the channel reserved by the first terminal 100 is idle, the second terminal 100-2 transmits CTS (Clear to Send) to the first terminal 100-1 (S401). A network allocation vector (NAV) of peripheral devices of the first and second terminals 100-1 and 100-2 is set through transmission and reception of RTS and CTS.

The first terminal 100-1 receiving the CTS from the second terminal 100-2 transmits a sounding request signal for analog SI channel sounding (S402). In step S403, the analog SI channel of the first terminal 100-1 is estimated using the sounding request signal transmitted in step S402.

Upon receiving the sounding request signal for analog SI channel sounding from the first terminal 100-1, the second terminal 100-2 transmits a sounding response signal to the first terminal 100-2 after the short interframe space (SIFS) 100-1) (S404). Also, the analog SI channel of the second terminal 100-2 itself is estimated using the sounding response signal transmitted in step S404 (S405).

When the first terminal 100-1 receives the sounding response signal from the second terminal 100-2 while the analog SI channel estimation has been successfully completed, the first terminal 100-1 performs sounding for the digital SI channel sounding after the SIFS time, And transmits a request signal (S406). Also, the digital SI channel of the first MS 100-1 is estimated using the sounding request signal transmitted in step S406 (S407).

Upon receiving the sounding request signal for digital SI channel sounding from the first terminal 100-1, the second terminal 100-2 transmits a sounding response signal to the first terminal 100-1 after SIFS time (S408). The digital SI channel of the second terminal 100-2 is estimated using the sounding response signal transmitted in step S408 (S409).

When both the analog SI channel sounding step and the digital SI channel sounding are successfully completed, the first and second terminals 100-1 and 100-2 transmit a sounding report signal to inform the counterpart terminal of the sounding result And simultaneously transmits them to the counterpart terminal (S410).

On the other hand, if it is determined that the sounding process is failed because the accuracy of the SI channel estimation value acquired through the sounding process is low, the first and second terminals 100-1 and 100-2 can notify the counterpart terminal of the sounding failure .

For example, if the first terminal 100-1 determines that its own analog SI channel estimation has failed, it can additionally transmit a sounding request signal for analog SI channel estimation in a self-request form . In this case, after the SIFS from the time when the sounding response signal for analog SI channel estimation is received from the second terminal 100-2, the first terminal 100-1 transmits a sounding response And may be transmitted after SIFS from the time when the signal is received.

For example, if the second terminal 100-2 determines that its digital SI channel estimation has failed, the second terminal 100-2 may transmit the sounding report signal including information on the sounding report signal. Accordingly, the first MS 100-1 transmits a sounding trigger signal (or sounding request signal) for instructing the second MS 100-2 to perform digital SI channel sounding to the second MS 100-2, And the second terminal 100-2, which has received the signal, transmits a sounding response signal after SIFS to redo the digital SI channel sounding step.

In FIG. 6, the two terminals 100-1 and 100-2 synchronously transmit the sounding report signal at the transmission time point. In this case, the two terminals 100-1 and 100-2 can examine whether a desired signal is properly received in a state in which both the previously performed analog SI channel estimation value and the digital SI channel estimation value are reflected .

The first and second terminals 100-2 and 100-2 correctly receive the sounding report signal from the other terminal and judge that both the terminals 100-1 and 100-2 have successfully completed the SI channel sounding The data is transmitted / received by the IFD method (S411). In step S411, the first and second terminals 100-1 and 100-2 can transmit and receive data signals by synchronizing frame synchronization based on a sounding report signal.

According to the above-described embodiments, the terminal 100 to communicate with the IFD communication method performs SI channel sounding with handshake with the counterpart terminal, and transmits its SI channel sounding progress status to the counterpart terminal SI channel sounding can be performed efficiently. That is, it is possible to check the progress of the SI channel sounding among the UEs, thereby preventing the IF channel from starting when the SI channel estimation is not sufficiently performed.

Also, if the SI channel estimation is not sufficiently performed, SI channel sounding is further performed to improve the SI channel estimation accuracy, thereby improving the SI signal cancellation performance. Accordingly, the signal-to-noise ratio (SNR) of a desired signal is improved in IFD communication.

In addition, the SNR of the desired signal can be estimated in the SI channel sounding process, and the throughput of the radio channel can be improved through link adaptation in IFD communication.

The embodiment of the present invention is not limited to the above-described apparatus and / or method, but may be applied to a program recorded on a recording medium or a recording medium on which the program is recorded to realize a function corresponding to the configuration of the embodiment of the present invention And the present invention can be easily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (1)

A method for performing self interference channel sounding in a terminal,
Transmitting a sounding request signal including a reference signal for self-interference channel estimation and a parameter used for determining whether a counterpart terminal has succeeded in self-interference channel sounding,
Estimating a self interference channel using the sounding request signal received through an antenna of the terminal,
Waiting for reception of a sounding response signal from the counterpart terminal that has received the sounding request signal, and
And transmitting to the counterpart terminal a sounding report signal for notifying the self interference channel sounding completion status when the sounding response signal is received and the self interference channel sounding of the terminal is completed, How to do sounding.

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