KR102412718B1 - Apparatus and method for interference cancellation in a fixed wireless link system - Google Patents

Abstract

An apparatus and method for canceling interference in a fixed radio link system are disclosed. An operation method of an interference cancellation apparatus includes: generating a transmission signal including a signal requesting channel information; transmitting a transmission signal through each of a plurality of uplinks; receiving a reception signal including the channel information in response to the transmission signal; converting the frequency of the received signal to an intermediate frequency; estimating a channel based on the channel information included in the received signal converted to the intermediate frequency; and removing interference to the received signal based on the estimated channel. Accordingly, the performance of the fixed radio link system can be improved.

Description

APPARATUS AND METHOD FOR INTERFERENCE CANCELLATION IN A FIXED WIRELESS LINK SYSTEM

The present invention relates to a fixed radio link system, and more particularly, to an apparatus and method for canceling interference in a fixed radio link system.

Recently, the amount of mobile data transmission is increasing explosively enough to be called the mobile big bang. Work is underway on a 5G mobile network service vision to meet the increased mobile data transmission volume.

5G mobile communication is expected to evolve into a small cell type to satisfy the transmission capacity per area. Accordingly, it is expected that a fixed wireless link technology capable of communicating in the form of a small cell will play an important role in the construction of a 5G mobile communication network.

The fixed radio link system refers to a communication link that wirelessly connects two fixed points on the ground. The fixed radio link system may provide a digital terrestrial fixed communication system through radio relay, relay between communication nodes, or very high frequency relay. A fixed radio link system may include point to point, point to multiple point, and multiple point to multiple point communication.

The interference cancellation method in a fixed radio link system according to the related art has problems in that it is impossible to accurately estimate a channel due to the use of a narrow bandwidth, and a frame structure of the system needs to be changed for accurate channel estimation.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an apparatus and method for channel estimation and interference cancellation without structural changes to communication objects in a fixed radio link system.

Another object of the present invention is to provide an apparatus and method for channel estimation and interference cancellation based on an intermediate frequency (IF) band in a fixed radio link system.

In order to achieve the above object, there is provided a method of operating an interference cancellation apparatus in a fixed radio link system according to an embodiment of the present invention, by generating at least one or more transmission signals including a signal requesting channel information of at least one or more outdoor devices. generating, transmitting the at least one or more transmission signals through each of at least one or more uplinks; receiving at least one or more reception signals including the channel information in response to the at least one or more transmission signals Step, converting the frequency of the at least one or more received signals to an intermediate frequency, performing channel estimation based on the channel information included in the at least one or more received signals converted to the intermediate frequency, and the channel The method may include performing interference cancellation on the one or more received signals based on a result of the estimation.
The generating includes: generating a first transmission preamble indicating a request for first channel information, which is channel information of a communication channel of a first outdoor device among the at least one or more outdoor devices, and the first transmission preamble generating a first transmission signal, generating a second transmission preamble indicating a request for second channel information that is channel information of a communication channel of a second outdoor device among the at least one or more outdoor devices; and generating a second transmission signal including two transmission preambles.
The transmitting may include transmitting the first transmission signal to a first indoor device through a first uplink, and transmitting the second transmission signal to a second indoor device through a second uplink; and wherein the first and second transmission signals are transmitted to the first and second outdoor devices via the first and second indoor devices.
In the receiving step, a first reception signal including first channel information that is channel information of a communication channel of the first outdoor device and a first reception preamble indicating that the first channel information is included is transmitted to the first indoor device. receiving a second reception signal including second channel information, which is channel information of a communication channel of the second outdoor device, and a second reception preamble indicating that the second channel information is included, from the second indoor device and receiving the first and second received signals through the first and second indoor devices after interference is removed based on the first and second channel information, and transmitting to the Internet network through the first and second indoor devices. can be characterized.
The performing of the channel estimation may include digitally converting the first and second received signals converted to the intermediate frequency to generate first and second digital signals, and the first and second digital signals from the first and second digital signals. Checking first and second channel information, and estimating states of communication channels of the first and second outdoor devices based on the first and second channel information, wherein states of the communication channels may be characterized as including phase and amplitude.
An apparatus for canceling interference in a fixed radio link system according to an embodiment of the present invention for achieving the above object includes a processor, a memory in electronic communication with the processor, and the memory. and stored instructions, wherein when the instructions are executed by the processor, the instructions are transmitted by the interference canceling device at least one or more including a signal requesting channel information of at least one outdoor device. generating signals, transmitting the at least one or more transmission signals through each of at least one or more uplinks, and receiving at least one or more reception signals including the channel information in response to the at least one or more transmission signals; , converting a frequency of the at least one or more received signals to an intermediate frequency, performing channel estimation based on the channel information included in the at least one or more received signals converted to the intermediate frequency, and a result of the channel estimation and perform interference cancellation on the at least one or more received signals based on .
The instructions generate, by the interference cancellation device, a first transmission preamble indicating a request for first channel information, which is channel information of a communication channel of a first outdoor device among the at least one or more outdoor devices, and generate the first transmission preamble. generates a first transmission signal comprising and operative to further cause generating a second transmit signal comprising two transmit preambles.
The commands include, by the interference cancellation device, a first reception signal including first channel information, which is channel information of a communication channel of a first outdoor device, and a first reception preamble indicating that the first channel information is included. The second reception signal is received from the first outdoor device and includes second channel information that is channel information of a communication channel of the second outdoor device, and a second reception preamble indicating that the second channel information is included. 2 receiving from the outdoor device, and transmitting the first and second received signals on which interference cancellation has been performed based on the first and second channel information to the Internet network through the first and second indoor devices It may be characterized in that it operates to cause.
The instructions are that the interference cancellation device generates first and second digital signals by digitally converting the first and second received signals converted to the intermediate frequency, and in the first and second digital signals, the first and confirming second channel information, and estimating states of communication channels of the first and second outdoor devices based on the first and second channel information, wherein states of the communication channels may be characterized as including phase and amplitude.

According to the present invention, since the channel estimation operation and the interference cancellation operation can be performed without changing the structure of the communication objects, it is possible to simplify the circuit structure of the product and reduce the manufacturing cost. In addition, since the channel estimation operation and the interference cancellation operation are performed using a digital signal, the channel estimation performance and the interference cancellation performance may be significantly improved. Also, the interference cancellation operation may be performed based on the IF band, and the performance of the interference cancellation may be improved. Accordingly, the performance of the communication system may be improved.

1 is a conceptual diagram illustrating a communication system according to a first embodiment.
2 is a block diagram illustrating a communication node in the communication system according to the first embodiment.
3A is a conceptual diagram illustrating a fixed radio link system according to a second embodiment.
3B is a block diagram illustrating communication nodes in a fixed radio link system according to the second embodiment.
4 is a block diagram illustrating an outdoor device and an indoor device in the fixed wireless link system according to the second embodiment.
5A is a conceptual diagram illustrating a fixed radio link system according to a third embodiment.
5B is a block diagram illustrating an outdoor device combined with an indoor device in the fixed wireless link system according to the third embodiment.
6 is a block diagram illustrating an outdoor device including an indoor device in the communication system according to the third embodiment.
7A is a conceptual diagram of a fixed radio link system according to the fourth embodiment.
7B is a block diagram illustrating communication nodes in a communication system according to the fourth embodiment.
8A is a flowchart illustrating a signal flow between communication nodes for generating channel information in a communication system according to the fourth embodiment.
8B is a flowchart illustrating a signal flow between communication nodes for channel measurement and interference cancellation in the communication system according to the fourth embodiment.
9 is a flowchart illustrating an operation sequence of an interference cancellation apparatus in a fixed radio link system according to a fourth embodiment.
10A is a conceptual diagram illustrating a fixed radio link system according to a fifth embodiment.
10B is a block diagram illustrating communication nodes in a fixed radio link system according to the fifth embodiment.
11 is a block diagram illustrating an apparatus for canceling interference in a fixed radio link system according to a fifth embodiment.
12A is a conceptual diagram illustrating various signals transmitted and received by an outdoor device and an indoor device in the fixed wireless link system according to the fifth embodiment.
12B is another conceptual diagram illustrating various signals transmitted and received by an indoor device and an outdoor device in the fixed wireless link system according to the fifth embodiment.
13 is a conceptual diagram illustrating an interference cancellation module in a fixed radio link system according to a fifth embodiment.
14 is a block diagram illustrating an apparatus for canceling interference in a fixed radio link system according to a sixth embodiment.
15A is a flowchart illustrating a signal flow between communication nodes for generating channel information in a fixed radio link system according to the sixth embodiment.
15B is a flowchart illustrating a signal flow between communication nodes for channel measurement and interference cancellation in a fixed radio link system according to the sixth embodiment.
16 is a block diagram illustrating an interference cancellation apparatus in a fixed radio link system according to a seventh embodiment.
17 is a block diagram illustrating an indoor device including an interference canceller in a fixed radio link system according to an eighth embodiment.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

Terms such as first, second, etc. may be used to describe various elements, but the elements 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, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component. and/or includes a combination of a plurality of related listed items or any of a plurality of related listed items.

When a component is referred to as being “connected” or “connected” to another component, it may be directly connected or connected to the other component, but it is understood that other components may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

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

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, in order to facilitate the overall understanding, the same reference numerals are used for the same components in the drawings, and duplicate descriptions of the same components are omitted.

1 is a conceptual diagram illustrating a communication system according to a first embodiment.

1, the communication network 100 is a plurality of communication nodes (110-1, 110-2, 110-3, 120-1, 120-2, 130-1, 130-2, 130-3, 130-4, 130-5, 130-6). Each of the plurality of communication nodes may support at least one communication protocol. For example, each of the plurality of communication nodes may include a code division multiple access (CDMA)-based communication protocol, a wideband CDMA (WCDMA)-based communication protocol, a time division multiple access (TDMA)-based communication protocol, and a frequency division multiple (FDMA)-based communication protocol. access) based communication protocol, OFDM (orthogonal frequency division multiplexing) based communication protocol, OFDMA (orthogonal frequency division multiple access) based communication protocol, SC (single carrier)-FDMA based communication protocol, NOMA (non-orthogonal multiple) access)-based communication protocol, space division multiple access (SDMA)-based communication protocol, etc. may be supported. Each of the plurality of communication nodes may have the following structure.

2 is a block diagram illustrating a communication node in the communication system according to the first embodiment.

Referring to FIG. 2 , the communication node 200 may include at least one processor 210 , a memory 220 , and a transceiver 230 connected to a network to perform communication. In addition, the communication node 200 may further include an input interface device 240 , an output interface device 250 , a storage device 260 , and the like. Each of the components included in the communication node 200 may be connected by a bus 270 to communicate with each other.

The processor 210 may execute a program command stored in at least one of the memory 220 and the storage device 260 . The processor 210 may mean a central processing unit (CPU), a graphics processing unit (GPU), or a dedicated processor on which methods according to embodiments of the present invention are performed. Each of the memory 220 and the storage device 260 may be configured as at least one of a volatile storage medium and a non-volatile storage medium. For example, the memory 220 may be configured as at least one of a read only memory (ROM) and a random access memory (RAM).

3A is a conceptual diagram illustrating a fixed radio link system according to a second embodiment.

Referring to FIG. 3A , the fixed radio link system according to the second embodiment includes an antenna 310 , an outdoor unit (ODU) 320 , and an indoor unit (IDU) 330 . can do. The outdoor device 320 may transmit/receive various signals to and from the indoor device 330 . For example, the outdoor device 320 may be connected to the indoor device 330 wirelessly or by wire. The outdoor device 320 may be connected to the indoor device 330 through a coaxial cable (not shown).

3B is a block diagram illustrating communication nodes in a fixed radio link system according to the second embodiment.

Referring to FIG. 3B , the antenna 310 may receive a signal in the air or may radiate a signal in the air. For example, the antenna 310 may receive a radio signal and transmit it to the outdoor device 320 . Also, the antenna 310 may receive a signal from the outdoor device 320 and radiate it into the air.

The outdoor device 320 may perform radio frequency (RF) front-end and transceiver functions. The outdoor device 320 may connect the antenna 310 and the indoor device 330 through the RF front end and transceiver functions.

The outdoor device 320 may include a diplexer 321 , an RF receiver 322 , a first multiplexer/demultiplexer (MUX/DEMUX) 323 , and an RF transmitter 324 . have.

The diplexer 321 may separate the transmit/receive signals so that they do not interfere. For example, the diplexer 321 may receive a transmission signal from the RF transmitter 324 . Also, the diplexer 321 may receive a received signal from the antenna 310 . In this case, the diplexer 321 may separate the transmitted signal and the received signal so as not to interfere with each other.

The RF receiver 322 may transmit the signal received from the diplexer 321 to the first multiplexer/demultiplexer 323 . That is, the RF receiver 322 may RF-process the signal received through the antenna 310 .

The first multiplexer/demultiplexer 323 may transmit/receive various signals to and from the indoor device 330 . For example, the first multiplexer/demultiplexer 323 may be wirelessly or wiredly connected to the second multiplexer/demultiplexer 331 of the indoor device 330 . The first multiplexer/demultiplexer 324 may be connected to the second multiplexer/demultiplexer 331 of the indoor device 330 through a coaxial cable (not shown).

The first multiplexer/demultiplexer 323 may multiplex the signal processed from the RF receiver 322 . The first multiplexer/demultiplexer 323 may transmit the multiplexed signal to the indoor device 330 . Also, the first multiplexer/demultiplexer 323 may demultiplex the signal received from the indoor device 330 . The first multiplexer/demultiplexer 323 may transmit the demultiplexed signal to the RF transmitter 324 .

The RF transmitter 324 may transmit the signal received from the first multiplexer/demultiplexer 323 to the diplexer 321 . That is, the RF transmitter 324 may RF-process a signal to be radiated through the antenna 310 .

The indoor device 330 may be connected to the outdoor device 320 through a wired or wireless communication network. The indoor device 330 may include an analog I/Q modulator (in-phase/quadrature mod/demodulator), a baseband signal processing unit, and a network interface.

The indoor device 330 includes a second multiplexer/demultiplexer 331 , an intermediate frequency (IF) receiver 332 , an analog digital converter (ADC), an analog digital converter 333 , a baseband/Ethernet (baseband/Ethernet). ) a communication unit 334 , a digital analog converter (DAC) 335 , and an IF transmitter 336 .

The second multiplexer/demultiplexer 331 may transmit/receive various signals to and from the outdoor device 320 . For example, the second multiplexer/demultiplexer 331 may be wirelessly or wiredly connected to the first multiplexer/demultiplexer 323 of the outdoor device 320 . The second multiplexer/demultiplexer 331 may be connected to the first multiplexer/demultiplexer 323 of the outdoor device 320 through a coaxial cable.

The second multiplexer/demultiplexer 331 may demultiplex the signal received from the outdoor device 320 . The second multiplexer/demultiplexer 331 may transmit the demultiplexed signal to the IF transmitter 332 .

The IF receiver 332 may process the signal received from the multiplexer/demultiplexer 331 . The IF receiver 332 may transmit the processed signal to the ADC 333 .

The ADC 333 may convert the analog signal received from the IF receiver 332 into a digital signal. The ADC 333 may transmit a signal converted into a digital signal to the baseband Ethernet communication unit 334 .

The baseband/Ethernet communication unit 334 may receive a digital signal from the ADC 333 . Also, the baseband/Ethernet communication unit 334 may transmit a digital signal to the DAC 333 .

The DAC 335 may convert a digital signal received from the baseband/Ethernet communication unit 336 into an analog signal. DAC 335 may transmit an analog signal to IF transmitter 336 .

The IF transmitter 336 may transmit an analog signal to the multiplexer/demultiplexer 331 . The multiplexer/demultiplexer 331 may multiplex the analog signal and transmit it to the outdoor device 320 .

The outdoor device 320 and the indoor device 330 each have a transmit signal, a receive signal, a transmit control signal, a receive control signal, and power. Signals can be sent and received. In this case, the transmission signal may have a frequency of 340/350 MHz. The received signal may have a frequency of 140 MHz. The transmission control signal may have a frequency of several KHz to several MHz. The power signal may have a voltage of -48V.

3A and 3B show one antenna 310, one outdoor device 320, and one indoor device 330 for convenience of explanation, but the antenna 310, the outdoor device 320, and the indoor device are illustrated in FIGS. Each of the devices 330 may be plural.

4 is a block diagram illustrating an outdoor device and an indoor device in the fixed wireless link system according to the second embodiment.

Referring to FIG. 4 , the outdoor device 410 includes a diplexer 411 , a low noise amplifier (LNA) 412 , a reception frequency down converter 413 , and a first multiplexer/demultiplexer. 414 , a transmit frequency up converter 415 , a power amplifier (PA) 416 , a power supply 417 , a central processing unit 418 , a local oscillator (LO) ( 419) may be included.

The diplexer 411 may receive a signal through an antenna (not shown). The diplexer 411 may transmit a signal to the low noise amplifier 412 .

The low noise amplifier 412 may amplify the signal received from the diplexer 411 and transmit it to the reception frequency down converter 413 .

The reception frequency down-converter 413 may down-convert the amplified signal received from the low-noise amplifier 412 . The reception frequency down converter 413 may transmit the down-converted signal to the first multiplexer/demultiplexer 414 .

The first multiplexer/demultiplexer 414 may multiplex or demultiplex various signals transmitted and received with the indoor device 420 . For example, the first multiplexer/demultiplexer 414 may multiplex or demultiplex a transmission signal, a reception signal, an up control signal, a down control signal, a power signal, and the like. The first multiplexer/demultiplexer 414 may multiplex the down-converted signal from the reception frequency down-converter 413 . The first multiplexer/demultiplexer 414 may transmit the multiplexed signal to the indoor device 410 through a wired or wireless interface. Also, the first multiplexer/demultiplexer 414 may demultiplex the signal received from the indoor device 420 . The first multiplexer/demultiplexer 414 may transmit the demultiplexed signal to the transmission frequency up-converter 415 .

The transmission frequency up-converter 415 may up-convert the signal received from the indoor device 420 . The transmit frequency upconverter 415 may transmit the upconverted signal to the power amplifier 416 .

The power amplifier 416 may amplify the up-converted signal. The power amplifier 416 may transmit the amplified signal to the diplexer 411 .

The diplexer 411 may transmit the amplified signal to the antenna. The antenna may radiate a signal received from the diplexer 411 into the air. The antenna may transmit a signal received from the air to the diplexer 411 . The diplexer 411 may separate the transmit/receive signals so that they do not interfere. The diplexer 411 may separate the transmit signal received from the power amplifier 416 and the received signal received from the antenna so as not to interfere with each other.

The power supply 417 may receive power from the indoor device 420 . The power supply 417 may supply power to the outdoor device 410 using power.

The central processing unit 418 may transmit/receive a signal for controlling the outdoor unit 410 . The local oscillator 419 may transmit a reference signal for up- or down-converting the signal to the receiving frequency down-converter 413 and the transmitting frequency up-converter 415 under the control of the central processing unit 418 . .

The low noise amplifier 412 and the reception frequency down converter 413 may be included in one receiver module. In addition, the transmission frequency up-converter 415 and the power amplifier 416 may be included in one transmitter module. The receiver module and the transmitter module may be included in one transceiver module.

The indoor unit 420 includes a second multiplexer/demultiplexer 421, an IF circuit 422, a modem 423, a baseband/Ethernet communication unit 424, and a central processing unit (CPU) ( 425 , an outdoor unit control circuit (ODU control circuit) 426 , a power distribution unit 427 , and a delay circuit 428 may be included.

The second multiplexer/demultiplexer 421 may transmit/receive various signals to and from the outdoor device 410 . For example, the second multiplexer/demultiplexer 421 may transmit and receive a transmission signal, a reception signal, an uplink control signal, a downlink control signal, and the like. The second multiplexer/demultiplexer 421 may receive a multiplexed signal from the outdoor device 410 . The second multiplexer/demultiplexer 421 may demultiplex the multiplexed signal. The second multiplexer/demultiplexer 421 may transmit the demultiplexed signal to the IF circuit 422 .

The IF circuit 422 may perform I/Q modulation for signal connection between the modem 423 and the outdoor device 410 . The IF circuit 422 may I/Q modulate the signal received from the second multiplexer/demultiplexer 421 and transmit it to the modem 423 .

The modem 423 may modulate and demodulate a signal for wireless communication. The modem 423 may include an ADC 423 - 1 and a DAC 423 - 2 . The ADC 423 - 1 may receive a modulated signal from the IF circuit 422 . The ADC 423 - 1 may convert the modulated signal into a digital signal. The modem 423 may transmit a digital signal to the baseband/Ethernet communication unit 424 .

The baseband/Ethernet communication unit 424 may transmit/receive signals through an Internet network (not shown). The baseband/Ethernet communication unit 424 may receive a digital signal from the modem 423 . The baseband/Ethernet communication unit 424 may transmit a digital signal to an Internet network connected to the indoor device 421 .

Also, the baseband/Ethernet communication unit 424 may receive a signal from the Internet network. The baseband/Ethernet communication unit 424 may transmit a signal received from the terminal to the modem 423 .

The modem 423 may convert a signal received from the baseband/Ethernet communication unit 424 into an analog signal through the DAC 423 - 2 . The modem 423 may I/Q modulate the analog signal. The modem 423 may transmit the modulated signal to the IF circuit 422 .

The IF circuit 422 may IF-process the signal received from the modem 423 . The IF circuit 422 may transmit the IF-processed signal to the multiplexer/demultiplexer 421 .

The second multiplexer/demultiplexer 421 may multiplex the signal received from the IF circuit 422 . The second multiplexer/demultiplexer 421 may transmit the multiplexed signal to the outdoor device 410 .

The central processing unit 425 may transmit/receive a signal for controlling the indoor unit 420 . The outdoor device control circuit 426 may generate a control signal for controlling the outdoor device 410 . Also, the outdoor device control circuit 426 may transmit/receive a transmission control signal and a reception control signal.

The power distributor 427 may receive power from the outside to generate power required for the indoor device 420 . Also, the power distributor 427 may transmit power received from the outside to the outdoor device. For example, the power may be -48V.

The delay circuit 428 may receive a delay control signal from the central processing unit 425 . The delay circuit 428 may control the power signal output from the power divider 427 according to the delay control signal.

5A is a conceptual diagram illustrating a fixed radio link system according to a third embodiment.

Referring to FIG. 5A , the fixed radio link system may include an antenna 510 and an outdoor device 520 . The antenna 510 and the outdoor device 520 may be connected through a wired or wireless interface. The antenna 510 may receive a signal from the air. Also, the antenna 510 may transmit a signal in the air. The outdoor device 520 may receive a signal from the antenna 510 . Also, the outdoor device 520 may transmit a signal to the antenna 510 .

5B is a block diagram illustrating an outdoor device combined with an indoor device in the fixed wireless link system according to the third embodiment.

Referring to FIG. 5B , the outdoor device 520 according to the third embodiment may have a structure in which the outdoor device 320 and the indoor device 330 described with reference to FIG. 3B are combined. For example, the diplexer 521 , the RF receiver 522 , the IF transmitter 523 , the ADC 524 , the baseband/Ethernet communication unit 525 , the DAC 526 , and the IF receiver of the outdoor device 520 . Each of 527 and RF transmitter 528 includes a diplexer 321, an RF receiver 322, an IF transmitter 336, an ADC 333, a baseband/Ethernet communication unit 334 shown in FIG. 3B, The DAC 335 , the IF receiver 332 , and the RF transmitter 324 may operate the same or similarly.

However, in comparison with the indoor device 330 and the outdoor device 320 of FIG. 3B , the first and second multiplexers/demultiplexers 323 and 331 in the outdoor device 520 may be omitted. In this case, the RF receiver 522 may be directly connected to the IF receiver 523 , and the RF transmitter 528 may be directly connected to the IF transmitter 527 . Accordingly, the IF receiver 523 may perform an IF processing procedure on the signal received from the RF receiver 522 , and the IF transmitter 527 may transmit a signal on which the IF processing procedure is completed to the RF transmitter 528 .

Accordingly, the outdoor device 520 does not need a separate external connection interface for connecting to the indoor device. Also, the outdoor device 520 does not need to transmit/receive an uplink control signal or a downlink control signal to and from the indoor device. Also, since the outdoor device 520 includes the baseband/Ethernet communication unit 525 , it can connect to the Internet network 530 by itself.

Accordingly, the outdoor device 520 has the effect of increasing the convenience of manufacturing by simplifying the circuit structure. In addition, the outdoor device 520 has the effect of reducing the manufacturing cost by simplifying the included configuration. In addition, the outdoor device 520 supplies power to the outdoor device 520 through a single power distributor (not shown), thereby increasing power efficiency and saving energy.

6 is a block diagram illustrating an outdoor device including an indoor device in the communication system according to the third embodiment.

Referring to FIG. 6 , the outdoor device 520 according to the third embodiment may have a structure in which the outdoor device 410 and the indoor device 420 described in FIG. 4 are combined. For example, the diplexer 601 of the outdoor device 600, the low-noise amplifier 602, the reception frequency down-converter 603, the IF circuit 604, the modem 605, the baseband/Ethernet communication unit 606 , the transmit frequency up-converter 607 , the power amplifier 608 , the central processing unit 609 , the control circuit 610 , the local oscillator 611 , the power divider 612 , and the delay circuit 613 are each shown in FIG. 4 , of the diplexer 411, low noise amplifier 412, receive frequency downconverter 413, IF circuit 422, modem 423, baseband/Ethernet communication unit 424, transmit frequency upconverter 415, The power amplifier 416 , the central processing unit 425 , the outdoor device control circuit 426 , the local oscillator 419 , the power divider 427 , and the delay circuit 428 may operate in the same or similar manner.

However, in comparison with the outdoor device 410 and the indoor device 420 of FIG. 4 , the first and second multiplexers/demultiplexers 414 and 421 , the power supply 417 and the control central processing in the outdoor device 600 . Device 418 may be omitted. In this case, the reception frequency down converter 603 and the transmission frequency up converter 607 may be directly connected to the IF circuit 604 , and the control circuit 610 may be directly connected to the local oscillator 611 .

Accordingly, the IF circuit 604 may perform an IF processing procedure on the signal received from the reception frequency down converter 603 , and transmit a signal on which the IF processing procedure is completed to the transmission frequency up converter 607 . Also, the control circuit 610 may directly control the local oscillator 611 and an antenna (not shown) connected to the outdoor device 600 .

That is, since the outdoor device 600 includes the components of the indoor device, a separate wired/wireless interface (not shown) for connecting to the indoor device is unnecessary. For example, the outdoor device 600 does not need a coaxial cable (not shown) for connecting to the indoor device. Also, the outdoor device 600 may not generate a signal for controlling uplink or downlink. Also, the outdoor device 600 may be connected to the Internet through the baseband/Ethernet communication unit 606 . In other words, the outdoor device 600 includes an Ethernet interface in the integrated system itself, and direct Internet connection is possible through the Ethernet interface.

Accordingly, the outdoor device 600 has the effect of simplifying the circuit through the structure combined with the indoor device. In addition, the outdoor device 600 has the effect of reducing manufacturing cost by simplifying the circuit. In addition, the outdoor device 600 supplies power to the outdoor device 600 through one power distributor 612 , thereby increasing power efficiency and saving energy.

7A is a conceptual diagram of a fixed radio link system according to the fourth embodiment.

Referring to FIG. 7A , the fixed wireless link system may include a line of sight multiple input multiple output (LOS MIMO) system. The line-of-sight multiple-input multiple-output system is a communication system between a transmitter and a receiver that observes each other without an obstacle between the transmitter and the receiver, and each of the transmitter and the receiver may use a plurality of antennas.

The fixed wireless link system includes a first antenna 710 , a first outdoor device 720 , a first indoor device 730 , a second antenna 740 , a first outdoor device 750 , and a first indoor device 760 . ), an interference cancellation device 770 may be included.

The first antenna 710 may transmit/receive a signal through the air through the first channel. The second antenna 730 may transmit/receive a signal through the air through the second channel.

The first outdoor device 720 may transmit/receive various signals to and from the first indoor device 730 . For example, the first outdoor device 720 may be connected to the first indoor device 730 wirelessly or by wire. The first outdoor device 720 may be connected to the first indoor device 730 through a coaxial cable (not shown).

7B is a block diagram illustrating communication nodes in a fixed radio link system according to the fourth embodiment.

Referring to FIG. 7B , the first outdoor device 720 may generate a first RF reception signal hole by radio frequency processing on a signal received from the first antenna 710 . The first outdoor device 720 may include a first multiplexer/demultiplexer (not shown). The first outdoor device 720 may generate a first reception signal by multiplexing the first RF reception signal with various signals through a first multiplexer/demultiplexer (not shown). The first outdoor device 720 may transmit the first received signal to the first indoor device 730 . Also, the first outdoor device 720 may receive a first transmission signal from the first indoor device 730 . The first outdoor device 720 may generate a first RF transmission signal by radio-frequency processing the first transmission signal. The first outdoor device 720 may transmit a first RF transmission signal to the first antenna 710 . The first antenna 710 may radiate a first RF transmission signal into the air.

The first transmission signal may include at least one of a first IF transmission signal and a first uplink control signal. In this case, the first IF transmission signal may include a signal requesting the first channel information. The first outdoor device 720 may determine whether the first IF transmission signal includes a signal requesting first channel information based on the preamble of the first IF transmission signal. When the first IF transmission signal includes a signal for requesting first channel information, the first outdoor device 720 includes the first channel information in the first reception signal to transmit to the first indoor device 730 . have.

The first indoor device 730 may include a second multiplexer/demultiplexer 731 , a first IF receiver 732 , a first ADC 733 , a first DAC 734 , and a first IF transmitter 735 . can

The second multiplexer/demultiplexer 731 may transmit/receive various signals to and from the first outdoor device 720 . For example, the second multiplexer/demultiplexer 731 may be connected to the first multiplexer/demultiplexer of the first outdoor device 720 wirelessly or by wire. The second multiplexer/demultiplexer 731 may be connected to the first multiplexer/demultiplexer through a coaxial cable (not shown).

The second multiplexer/demultiplexer 731 may demultiplex the first received signal received from the first outdoor device 720 and transmit it to the first IF receiver 732 . The first IF receiver 732 may IF-process the first received signal to generate a first IF received signal. The first IF receiver 732 may transmit the first IF received signal to the first ADC 733 .

The first ADC 733 may generate a first digital signal by converting the first IF received signal into a digital signal. The first ADC 733 may transmit a first digital signal to the interference cancellation device 770 .

The first DAC 734 may receive the second digital signal from the interference cancellation device 770 . The first DAC 734 may generate a first analog signal by converting the second digital signal into an analog signal. The DAC 734 may transmit a first analog signal to the first IF transmitter 735 .

The first IF transmitter 735 may generate a first IF transmission signal by IF-processing the first analog signal. The first IF transmitter 735 may transmit the first IF transmission signal to the second multiplexer/demultiplexer 731 . The multiplexer/demultiplexer 731 may generate a first transmission signal by multiplexing the first IF transmission signal with various signals. The multiplexer/demultiplexer 731 may transmit the first transmission signal to the first outdoor device 720 .

The second outdoor device 750 may receive a signal through the second antenna 740 . The second outdoor device 740 may generate a second RF reception signal by radio-frequency processing the received signal. The second outdoor device 740 may include a third multiplexer/demultiplexer (not shown). The second outdoor device 740 may generate a second reception signal by multiplexing the second RF reception signal with various signals through the third multiplexer/demultiplexer. The second outdoor device 740 may transmit the second received signal to the second indoor device 760 . The second outdoor device 740 may receive a second transmission signal from the second indoor device 760 .

The second outdoor device 740 may generate a second RF transmission signal by radio-frequency processing the second transmission signal. The second outdoor device 750 may transmit the second RF transmission signal to the second antenna 740 . The second antenna 740 may radiate a second RF transmission signal into the air.

The second transmission signal may include at least one of a second IF transmission signal and a second uplink control signal. In this case, the second IF transmission signal may include a signal requesting second channel information. The second outdoor device 750 may determine whether the second IF transmission signal includes a signal requesting second channel information based on the preamble of the second IF transmission signal. When the second IF transmission signal includes a signal requesting second channel information, the second outdoor device 750 includes the second channel information in the second reception signal to transmit to the second indoor device 760 . have.

The second indoor device 760 may include a fourth multiplexer/demultiplexer 761 , a second IF receiver 762 , a second ADC 763 , a second DAC 764 , and a second IF transmitter 765 . can

The fourth multiplexer/demultiplexer 761 may transmit/receive various signals to and from the second outdoor device 750 . For example, the fourth multiplexer/demultiplexer 761 may be connected to the third multiplexer/demultiplexer 753 wirelessly or by wire. The fourth multiplexer/demultiplexer 761 may be connected to the third multiplexer/demultiplexer 753 through a coaxial cable (not shown).

The fourth multiplexer/demultiplexer 761 may demultiplex the second reception signal received from the second outdoor device 750 . The fourth multiplexer/demultiplexer 761 may transmit the demultiplexed second reception signal to the second IF transmitter 762 .

The second IF receiver 762 may IF-process the second received signal to generate a second IF received signal. The second IF receiver 762 may transmit the second IF received signal to the second ADC 763 .

The second ADC 763 may generate a third digital signal by converting the second IF received signal into a digital signal. The second ADC 763 may transmit the third digital signal to the interference cancellation device 770 .

The second DAC 764 may receive a fourth digital signal from the interference cancellation device 770 . The second DAC 764 may generate a second analog signal by converting the fourth digital signal into an analog signal. The second DAC 764 may transmit a second analog signal to the second IF transmitter 765 .

The second IF transmitter 765 may IF-process the second analog signal to generate a second IF transmission signal. The second IF transmitter 765 may transmit the second IF transmission signal to the fourth multiplexer/demultiplexer 761 . The fourth multiplexer/demultiplexer 761 may multiplex the second IF transmission signal with various signals. The fourth multiplexer/demultiplexer 761 may transmit the multiplexed second IF transmission signal to the second outdoor device 750 .

The interference cancellation device 770 includes a first channel estimation unit 771 , a first MIMO signal processor 772 , a first baseband/Ethernet communication unit 773 , a first preamble generator 774 , and a second It may include a channel estimator 775 , a second MIMO signal processor 776 , a second baseband/Ethernet communication unit 777 , and a second preamble generator 778 .

The first channel estimator 771 may receive the first digital signal from the first ADC 733 . The first channel estimator 771 may determine whether the first digital signal includes the first channel information based on the preamble of the first digital signal. When the first digital signal includes the first channel information, the first channel estimator 771 may estimate the state of the first channel based on the first channel information. For example, the first channel estimator 771 may estimate the phase and amplitude of the first channel. The first channel estimator 771 may generate first channel estimation information based on the estimation result. Also, the first channel estimator 771 may receive second channel estimation information from the second channel estimator 775 . The first channel estimator 771 may transmit the first channel estimation information and the second channel estimation information together with the first digital signal to the first MIMO signal processor 772 . When the first digital signal does not include the first channel information, the first channel estimator 771 may transmit the first digital signal to the first baseband/Ethernet communication unit 773 .

The first MIMO signal processor 772 may receive the first digital signal, the first channel estimation information, and the second channel estimation information from the first channel estimator 771 . The first MIMO signal processor 772 may remove interference with respect to the first digital signal based on the first channel estimation information and the second channel estimation information. The first MIMO signal processor 772 may transmit an interference-removed signal to the first baseband/Ethernet communication unit 773 .

The first baseband/Ethernet communication unit 773 may baseband-process the interference-removed signal and transmit it to an Internet network (not shown). The first baseband/Ethernet communication unit 773 may receive a first data transmission signal from the Internet network. The first baseband/Ethernet communication unit 773 may baseband-process the first data transmission signal.

The second channel estimator 775 may receive the second digital signal from the second ADC 763 . The second channel estimator 775 may determine whether the second digital signal includes the second channel information based on the preamble of the second digital signal. When the second digital signal includes the second channel information, the second channel estimator 775 may estimate the state of the second channel based on the second channel information. For example, the second channel estimator 775 may estimate the phase and amplitude of the second channel. The second channel estimator 775 may generate second channel estimation information based on the estimation result. Also, the second channel estimator 775 may receive the first channel estimation information from the first channel estimator 771 . The second channel estimator 775 may transmit the first channel estimation information and the second channel estimation information together with the second digital signal to the second MIMO signal processor 776 . When the second digital signal does not include the second channel information, the second channel estimator 775 may transmit the second digital signal to the second baseband/Ethernet communication unit 777 .

The second MIMO signal processor 777 may receive the second digital signal, the first channel estimation information, and the second channel estimation information from the second channel estimator 775 . The second MIMO signal processor 777 may cancel interference with the second digital signal based on the first channel estimation information and the second channel estimation information. The second MIMO signal processor 777 may transmit an interference-removed signal to the second baseband/Ethernet communication unit 777 .

The second baseband/Ethernet communication unit 777 may baseband-process the interference-removed signal and transmit it to the Internet network. The second baseband/Ethernet communication unit 777 may receive a second data signal from the Internet network. The second baseband/Ethernet communication unit 777 may baseband-process the second data signal.

The interference removing device 770 may monitor whether the first indoor device 730 and the second indoor device 760 transmit/receive signals to or from the first outdoor device 720 or the second outdoor device 750 . When the first indoor device 730 and the second indoor device 760 do not transmit and receive signals with the first outdoor device 720 or the second outdoor device 750, the interference canceling device 770 includes a first channel and A signal for estimating at least one of the second channels may be generated.

The interference cancellation apparatus 770 may generate a separate channel estimation request signal for channel estimation or may generate a signal for requesting channel information using a data signal received from an Internet network. For example, the interference cancellation apparatus 770 may generate the first channel information request signal through the first preamble generator 774 . In this case, the preamble of the first channel information request signal may include information requesting the first channel information. The interference cancellation apparatus 770 may set the preamble of the first data signal to include information requesting the first channel information through the first preamble generator 774 .

Also, the interference cancellation apparatus 770 may generate a second channel information request signal through the second preamble generator 778 . In this case, the preamble of the second channel information request signal may include information for requesting the second channel information. The interference cancellation apparatus 770 may set the preamble of the second data signal to include information requesting the second channel information through the second preamble generator 778 .

The interference cancellation device 770 may alternately transmit a signal requesting channel information to the first indoor device 730 and the second indoor device 760 . That is, the interference canceling apparatus 770 may alternately transmit the channel information requesting signal so that the channel information requesting signal is alternately transmitted to the first outdoor device 720 and the second outdoor device 750 .

7A and 7B show two antennas, two outdoor devices, two indoor devices, and one interference canceling device for convenience of explanation, but each of the antenna, outdoor device, and indoor device is one or two. may exceed Also, there may be a plurality of interference canceling devices.

8A is a flowchart illustrating a signal flow between communication nodes for generating channel information in a communication system according to the fourth embodiment.

Referring to FIG. 8A , the fixed wireless link system includes a first outdoor device 810 , a second outdoor device 820 , a first indoor device 830 , a second indoor device 840 , and an interference removing device 850 . may include Each of the first outdoor device 810 , the second outdoor device 820 , the first indoor device 830 , the second indoor device 840 , and the interference canceling device 850 is the first outdoor device shown in FIG. 7A or 7B . The outdoor device 710 , the second outdoor device 750 , the first indoor device 730 , the second indoor device 760 , and the interference removal device 770 may be configured in the same or similar manner. The first outdoor device 810 , the second outdoor device 820 , the first indoor device 830 , the second indoor device 840 , and the interference removing device 850 may be interconnected through a wired or wireless interface, respectively. .

The interference canceller 850 may determine an uplink unused section (S801). The interference removing device 850 generates at least one transmission signal to be transmitted to the first outdoor device 810 and the second outdoor device 820 through the first indoor device 830 and the second indoor device 840 . can do. The interference canceller 850 may transmit at least one transmission signal to the first outdoor device 810 and the second outdoor device 820 through an uplink.

For example, the interference canceling device 850 may generate a first transmission signal and transmit it to the first outdoor device 810 through a first uplink. Also, the interference canceling device 850 may generate a second transmission signal and transmit it to the second outdoor device 820 through a second uplink. In this case, the interference cancellation apparatus 850 may determine a section in which the transmission signal is not transmitted. That is, the interference cancellation apparatus 850 may determine an uplink unused section in which a transmission signal is not transmitted.

The interference cancellation apparatus 850 may generate a signal for requesting channel information in an uplink unused section (S802). For example, the interference canceling apparatus 850 may generate a first transmission signal including a signal requesting information on the first channel that is the communication channel of the first outdoor apparatus 810 . For example, the interference cancellation apparatus 850 may generate a preamble indicating a request for first channel information and may generate a first transmission signal including the generated preamble.

Also, the interference canceling device 850 may generate a second transmission signal including a signal requesting information on a second channel that is a communication channel of the second outdoor device 820 . For example, the interference cancellation apparatus 850 may generate a preamble indicating a request for second channel information and may generate a second transmission signal including the generated preamble.

The interference cancellation device 850 may alternately transmit a signal for requesting channel information (S803). For example, after transmitting the first transmission signal through the first uplink, the interference cancellation apparatus 850 may transmit the second transmission signal through the second uplink. Alternatively, the interference cancellation apparatus 850 may transmit the second transmission signal through the second uplink and then transmit the first transmission signal through the first uplink.

The interference canceling device 850 may transmit a signal requesting the first channel information to the first indoor device 830 (S804). The signal requesting the first channel information may be included in the first transmission signal. That is, the interference cancellation apparatus 850 may transmit a first transmission signal including a signal requesting first channel information to the first indoor apparatus 830 .

The interference canceling device 850 may transmit a signal requesting second channel information to the second indoor device 840 (S805). The signal requesting the second channel information may be included in the second transmission signal. That is, the interference cancellation apparatus 850 may transmit a second transmission signal including a signal requesting second channel information to the second indoor apparatus 840 .

The first indoor device 830 may transmit a signal requesting the first channel information to the first outdoor device 810 (S805). For example, the first indoor device 830 may transmit a first transmission signal including a signal requesting first channel information to the first outdoor device 810 ( S805 ). The first outdoor device 810 may receive a first transmission signal including a signal for requesting first channel information from the first indoor device 830 .

The first outdoor device 810 may generate first channel information (S806). The first outdoor device 810 may identify a signal requesting the first channel information based on the preamble of the first transmission signal. The first outdoor device 810 may generate first channel information according to a signal requesting first channel information. The first outdoor device 810 may include the first channel information in the first data signal to be transmitted to the first indoor device 830 . For example, the first outdoor device 810 may set a preamble indicating that the first channel information is included in the first data signal, and may generate a first data signal including the preamble and the first channel information. have.

The second indoor device 840 may transmit a signal requesting second channel information to the second outdoor device 820 (S807). For example, the second indoor device 840 may transmit a second transmission signal including a signal requesting second channel information to the second outdoor device 820 ( S808 ). The second outdoor device 820 may receive a second transmission signal including a signal for requesting second channel information from the second indoor device 840 .

The second outdoor device 820 may generate second channel information (S809). The second outdoor device 820 may identify a signal for requesting second channel information based on the preamble of the second transmission signal. The second outdoor device 820 may generate second channel information according to a signal requesting second channel information. The second outdoor device 820 may include the second channel information in the second data signal to be transmitted to the second indoor device 840 . For example, the second outdoor device 820 may set a preamble of the second data signal to include the second channel information in the second data signal.

8B is a flowchart illustrating a signal flow between communication nodes for channel measurement and interference cancellation in the communication system according to the fourth embodiment.

Referring to FIG. 8B , the first outdoor device 810 may transmit first channel information to the first indoor device 830 ( S810 ). The first indoor device 830 may transmit the first channel information to the interference cancellation device 850 (S811).

The second outdoor device 820 may transmit the second channel information to the second indoor device 840 (S812). The second indoor device 840 may transmit the second channel information to the interference cancellation device 850 (S813).

The interference cancellation apparatus 850 may digitize the channel information (S814). For example, the interference cancellation device 850 may digitize the first channel information received from the first indoor device 830 . That is, the interference canceling device 850 may convert the first data signal including the first channel information received from the first indoor device 830 into a digital signal. Similarly, the interference canceling device 850 may convert the second data signal including the second channel information received from the second indoor device 840 into a digital signal.

The interference cancellation apparatus 850 may perform channel estimation and interference cancellation (S816). The interference cancellation apparatus 850 may check the first channel information through the preamble of the first data signal converted into a digital signal. Also, the interference cancellation apparatus 850 may check the second channel information through the preamble of the second data signal converted into a digital signal.

The interference cancellation apparatus 850 may estimate the state of the first channel and the state of the second channel based on the first channel information and the second channel information. For example, the interference cancellation apparatus 850 may determine the phase and amplitude of the first channel based on the first channel information. In addition, the interference cancellation apparatus 850 may determine the phase and amplitude of the second channel based on the second channel information. The interference cancellation apparatus 850 may cancel interference between the first data signal and the second data signal based on the state of the first channel and the state of the second channel.

The interference canceling device 850 may transmit an interference-removed data signal (S817). The interference canceling device 850 may transmit the first data signal from which the interference is removed to an Internet network (not shown). Also, the interference canceling device 850 may transmit the second data signal from which the interference is removed to the Internet network.

9 is a flowchart illustrating an operation sequence of an interference cancellation apparatus in a fixed radio link system according to a fourth embodiment.

Referring to FIG. 9 , a signal for requesting channel information may be generated ( S901 ). For example, the interference canceling apparatus may generate a first transmission signal including a signal requesting information about a first channel that is a communication channel of the first outdoor device. The interference cancellation apparatus may generate a preamble indicating a request for first channel information and may generate a first transmission signal including the generated preamble. Also, the interference canceling apparatus may generate a second transmission signal including a signal for requesting information on a second channel that is a communication channel of the second outdoor device. The interference cancellation apparatus may generate a preamble indicating a request for second channel information and may generate a second transmission signal including the generated preamble.

The interference cancellation apparatus may transmit a transmission signal through each of a plurality of uplinks (S903). For example, the interference canceller may transmit a first transmission signal to the first outdoor device through a first uplink and then transmit a second transmission signal to the second outdoor device through a second uplink. Alternatively, the interference canceller may transmit the second transmission signal to the second outdoor device through the second uplink and then transmit the first transmission signal to the first outdoor device through the first uplink.

The interference cancellation apparatus may receive a reception signal including channel information in response to the transmission signal (S903). The interference canceling apparatus may receive a first data signal including first channel information from the first outdoor apparatus in response to the first transmission signal. Also, the interference canceling apparatus may receive a second data signal including second channel information from the second outdoor apparatus in response to the second transmission signal.

The interference canceller may convert the reception frequency to an intermediate frequency (S904). For example, the interference canceling apparatus may generate a first intermediate frequency reception signal by converting a frequency of the first data signal received from the first outdoor apparatus into an intermediate frequency. In this case, the interference cancellation apparatus may convert the first intermediate frequency reception signal into a digital signal. Similarly, the interference canceling apparatus may generate a second intermediate frequency reception signal by converting the frequency of the second data signal received from the second outdoor apparatus into an intermediate frequency. In addition, the interference cancellation device may convert the second intermediate frequency reception signal into a digital signal.

The interference cancellation apparatus may estimate the channel based on the channel information included in the received signal converted to the intermediate frequency (S905). The interference canceller may check the first channel information through the preamble of the first intermediate frequency reception signal. Also, the interference cancellation apparatus may check the second channel information through the preamble of the second intermediate frequency reception signal. The interference cancellation apparatus may estimate the state of the first channel and the state of the second channel based on the first channel information and the second channel information. For example, the interference cancellation apparatus may estimate the phase and amplitude of the first channel based on the first channel information. Also, the interference cancellation apparatus may estimate the phase and amplitude of the second channel based on the second channel information.

The interference cancellation apparatus may cancel interference to the received signal based on the estimated channel (S906). The interference canceling apparatus may cancel interference between the first data signal and the second data signal based on the state of the first channel and the state of the second channel. The interference canceling device may transmit the first data signal and the second data signal from which the interference is removed to the Internet network.

10A is a conceptual diagram illustrating a fixed radio link system according to a fifth embodiment.

Referring to FIG. 10A , the communication system according to the fifth embodiment may be a fixed radio link system. The fixed radio link system includes a first antenna 1010 , a first outdoor device 1020 , a second antenna 1030 , a second outdoor device 1040 , an interference cancellation device 1050 , a first indoor device 1060 , A second indoor device 1070 may be included.

The interference canceling device 1050 may be an independent device separate from the outdoor devices 1020 and 1030 and the indoor devices 1060 and 1070 . The interference canceling device 1050 may be connected to the first outdoor device 1020 , the second outdoor device 1040 , the first indoor device 1060 , and the second indoor device 1070 through a wired or wireless interface. For example, the interference canceling device 1050 may be connected to the first outdoor device 1020 , the second outdoor device 1040 , the first indoor device 1060 , and the second indoor device 1070 through a coaxial cable. .

Here, the first antenna 1010 , the first outdoor device 1020 , the second antenna 1030 , the second outdoor device 1040 , the first indoor device 1060 , and the second indoor device 1070 are shown in FIG. 7 . It may be the same device as the antenna, outdoor device, and indoor device described in FIG. 9 . The transmission power and reception power of the first outdoor device 1020 , the second outdoor device 1040 , the first indoor device 1060 , and the second indoor device 1070 may be controlled to be the same. Also, a reference frequency for a local oscillator (LO) signal of the first outdoor device 1020 , the second outdoor device 1040 , the first indoor device 1060 , and the second indoor device 1070 . may use the same frequency.

10B is a block diagram illustrating communication nodes in a fixed radio link system according to the fifth embodiment.

Referring to FIG. 10B , the interference cancellation device 1050 includes third to sixth multiplexers/demultiplexers 1051-1 to 1051-4, first to fourth IF transmitters 1052-1 to 1052-4, and The first to fourth IF receivers 1053-1 to 1053-4 may include a MIMO signal processor 1054.

The interference canceling device 1050 may be disposed between the first and second outdoor devices 1020 and 1040 and the first and second indoor devices 1060 and 1070 . For example, the third multi-demultiplexer 1051-1 of the interference cancellation apparatus 1050 may be connected to the first outdoor apparatus 1020 . The fourth multi-demultiplexer 1051 - 2 of the interference cancellation device 1050 may be connected to the first indoor device 1060 . The fifth multi-demultiplexer 1051-3 of the interference cancellation device 1050 may be connected to the second outdoor device 1040 . The sixth multi-demultiplexer 1051-4 of the interference cancellation device 1050 may be connected to the second indoor device 1070 .

11 is a block diagram illustrating an apparatus for canceling interference in a fixed radio link system according to a fifth embodiment.

Referring to FIG. 11 , the interference cancellation apparatus 1100 includes a first multiplexer/demultiplexer 1101 , a first IF receiver 1102 , a first ADC 1103 , a first channel estimator 1004 , and a first MIMO signal Processor 1105, second DAC 1106, second IF receiver 1107, second multiplexer/demultiplexer 1108, second IF transmitter 1109, second ADC 1110, first switch 1111 ), a first preamble generator 1112 , a first DAC 1113 , a first IF transmitter 1114 , an algorithm scheduler 1115 , a third multiplexer/demultiplexer 1116 , a third IF receiver 1117 , a third 3 ADC 1118, second channel estimator 1119, second MIMO signal processor 1120, fourth DAC 1121, fourth IF receiver 1122, fourth multiplexer/demultiplexer 1123, fourth It may include an IF transmitter 1124 , a fourth ADC 1125 , a second switch 1126 , a second preamble generator 1127 , a third DAC 1128 , and a third IF transmitter 1129 .

The first multiplexer/demultiplexer 1101 may receive a first reception signal from a first outdoor device (not shown). The first multiplexer/demultiplexer 1101 may transmit a first received signal to the first IF receiver 1102 . The frequency of the first received signal may be 140 MHz.

The first IF receiver 1102 may receive a first reception signal. The first IF receiver 1102 may IF-process the first received signal to generate a first IF received signal. The first IF receiver 1102 may transmit a first IF received signal to the first ADC 1103 .

The first IF receiver 1102 may perform digital IF processing on the first IF received signal. In this case, the first IF receiver 1102 may transmit the digital and IF-processed first digital reception signal to the first channel estimator 1104 .

The first ADC 1103 may receive the first IF reception signal. The first ADC 1103 may generate a first digital reception signal by converting the first IF reception signal into a digital signal. The first ADC 1103 may transmit the first digital received signal to the first channel estimator 1104 .

The first channel estimator 1104 may determine whether the first digital reception signal includes the first channel information based on the preamble of the first digital reception signal. When the first digital reception signal includes the first channel information, the first channel estimator 1104 may estimate the state of the first channel based on the first digital reception signal. For example, the first channel estimator 1104 may estimate the phase and amplitude of the first channel based on the first channel information. The first channel estimator 1104 may generate first channel estimation information based on the state of the first channel. The first channel estimator 1104 may transmit the first channel estimation information to the first MIMO signal processor 1105 and the second MIMO signal processor 1120 .

When the first digital reception signal does not include the first channel information, the first channel estimator 1104 may transmit the first digital reception signal to the second DAC 1106 or the second IF receiver 1107 .

The first MIMO signal processor 1105 may receive the first digital reception signal from the first channel estimator 1104 . Also, the first MIMO signal processor 1105 may receive second channel estimation information from the second channel estimator 1119 .

The first MIMO signal processor 1105 may remove interference with respect to the first digital reception signal based on the first channel estimation information and the second channel estimation information. The first MIMO signal processor 1105 may transmit the first digital reception signal from which the interference is removed to the second DAC 1106 .

When receiving the first digital reception signal from the first channel estimator 1104 or the first MIMO signal processor 1105, the second DAC 1106 converts the first digital reception signal to generate a first analog reception signal. can The second DAC 1106 may transmit the first analog reception signal to the second IF receiver 1107 .

The second IF receiver 1107 may receive the first analog reception signal from the second DAC 1106 . The second IF receiver 1107 may IF-process the first analog reception signal to generate a second IF reception signal. The second IF receiver 1107 may transmit the second IF signal to the second multiplexer/demultiplexer 1108 .

The second multiplexer/demultiplexer 1108 may receive the second IF signal from the second IF receiver 1107 . The second multiplexer/demultiplexer 1108 may multiplex the second IF signal with other signals and transmit it to the first indoor device (not shown).

The second multiplexer/demultiplexer 1108 may receive the first transmission signal from the first indoor device 1300 . The second multiplexer/demultiplexer 1108 may extract the first transmission signal. The second multiplexer/demultiplexer 1108 may transmit the first transmission signal to the second IF transmitter 1109 . The frequency of the first transmission signal may be 350 MHz.

The second IF transmitter 1109 may generate a first IF transmission signal by IF-processing the first transmission signal. The second IF transmitter 1109 may transmit the first IF transmission signal to the second ADC 1110 .

Also, the second IF transmitter 1109 may perform digital IF processing on the first transmission signal to generate a first digital transmission signal. That is, the second IF transmitter 1109 may IF-process the first transmission signal and convert it into a digital signal to generate the first digital transmission signal. In this case, the second IF transmitter 1109 may transmit the first digital transmission signal to the switch 1111 .

The second ADC 1110 may receive the first IF transmission signal from the second IF transmitter 1109 . The second ADC 1110 may generate a first digital transmission signal by converting the first IF transmission signal into a digital signal. The second ADC 1110 may transmit the first digital transmission signal to the switch 1111 .

The first switch 1111 may receive the first digital transmission signal from the second IF transmitter 1109 or the 2 ADCs 1110 . The first switch 1111 may set a preamble of the first digital transmission signal according to a control signal of the algorithm scheduler 1115 .

When receiving the control signal from the algorithm scheduler 1115 , the first switch 1111 may set the preamble of the first digital transmission signal as a channel estimation request through the first preamble generator 1112 . When the first switch 1111 does not receive a control signal from the algorithm scheduler 1115 , a separate setting for the preamble of the first digital transmission signal may not be performed. The first switch 1111 may transmit a first digital transmission signal to the first DAC 1113 .

The first DAC 1113 may generate a first analog transmission signal by converting the first digital transmission signal into an analog signal. The first DAC 1113 may transmit a first analog transmission signal to the first IF transmitter 1114 .

The first IF transmitter 1114 may receive a first digital transmission signal from the first DAC 1113 . The first IF transmitter 1114 may IF-process the first analog transmission signal to generate a second IF transmission signal. The first IF transmitter 1114 may transmit the second IF transmission signal to the first multiplexer/demultiplexer 1101 .

The first multiplexer/demultiplexer 1111 may multiplex the second IF transmission signal with other signals and transmit it to a first outdoor device (not shown).

The third multiplexer/demultiplexer 1116 may receive the second reception signal from the second outdoor device 1160 . The third multiplexer/demultiplexer 1116 may transmit the second received signal to the third IF receiver 1117 . The frequency of the second reception signal may be 140 MHz.

The third IF receiver 1117 may receive the second reception signal. The third IF receiver 1117 may generate a third IF received signal by IF-processing the second received signal. The third IF receiver 1117 may transmit the third IF received signal to the third ADC 1118 .

In addition, the third IF receiver 1117 may generate a second digital reception signal by performing digital IF processing on the second reception signal. In this case, the third IF receiver 1117 may transmit the second digital reception signal to the second channel estimator 1119 .

The third ADC 1118 may receive a third IF reception signal from the third IF receiver 1117 . The third ADC 1118 may generate a second digital reception signal by converting the third IF reception signal into a digital signal. The third ADC 1118 may transmit the second digital received signal to the second channel estimator 1119 .

The second channel estimator 1119 may receive the second digital reception signal from the third IF receiver 1117 or the third ADC 1118 . The second channel estimator 1119 may determine whether the second digital reception signal includes the second channel information based on the preamble of the second digital reception signal.

When the second digital reception signal includes the second channel information, the second channel estimator 1119 may estimate the state of the second channel based on the second digital reception signal. For example, the second channel estimator 1119 may determine the phase and amplitude of the second channel based on the second channel information. The second channel estimator 1119 may generate second channel estimation information based on the state of the second channel. The second channel estimator 1119 may transmit the second channel estimation information to the first MIMO signal processor 1105 and the second MIMO signal processor 1120 .

The second channel estimator 1119 may transmit the second digital reception signal to the fourth DAC 1121 when the second digital reception signal does not include the second channel information.

The second MIMO signal processor 1120 may receive the second digital reception signal and the second channel estimation information from the second channel estimator 1119 . Also, the second MIMO signal processor 1120 may receive second channel estimation information from the first channel estimator 1104 .

The second MIMO signal processor 1120 may cancel interference of the second digital reception signal based on the first channel estimation information and the second channel estimation information. The second MIMO signal processor 1120 may transmit the second digital reception signal from which the interference is removed to the fourth DAC 1121 or the fourth IF receiver 1122 .

When receiving the second digital reception signal from the second channel estimator 1119 or the second MIMO signal processor 1121, the fourth DAC 1121 converts the second digital reception signal to generate a second analog reception signal. can The fourth DAC 1121 may transmit the second analog reception signal to the fourth IF receiver 1122 .

The fourth IF receiver 1122 may receive the second analog reception signal from the second DAC 1121 . The fourth IF receiver 1122 may IF-process the second analog reception signal to generate a fourth IF reception signal. The fourth IF receiver 1122 may transmit the fourth IF signal to the fourth multiplexer/demultiplexer 1123 .

The fourth multiplexer/demultiplexer 1123 may receive a fourth IF signal from the fourth IF receiver 1122 . The fourth multiplexer/demultiplexer 1123 may multiplex the fourth IF signal with other signals and transmit it to a second indoor device (not shown).

The fourth multiplexer/demultiplexer 1123 may receive the second transmission signal from the second indoor device 1160 . The fourth multiplexer/demultiplexer 1123 may extract the second transmission signal. The fourth multiplexer/demultiplexer 1123 may transmit the second transmission signal to the fourth IF transmitter 1124 . The frequency of the second transmission signal may be 350 MHz.

The fourth IF transmitter 1124 may generate a second IF transmission signal by IF-processing the second transmission signal. The fourth IF transmitter 1124 may transmit the second IF transmission signal to the fourth ADC 1125 .

Also, the fourth IF transmitter 1124 may perform digital IF processing on the second transmission signal to generate a second digital transmission signal. That is, the fourth IF transmitter 1124 may IF-process the second transmission signal and convert it into a digital signal to generate a second digital transmission signal. In this case, the fourth IF transmitter 1124 may transmit the second digital transmission signal to the switch 1126 .

The fourth ADC 1125 may receive the second IF transmission signal from the fourth IF transmitter 1124 . The fourth ADC 1125 may generate a second digital transmission signal by converting the second IF transmission signal into a digital signal. The fourth ADC 1125 may transmit a second digital transmission signal to the switch 1126 .

The second switch 1126 may receive the first digital transmission signal from the fourth IF transmitter 1124 or the 4 ADCs 1125 . The second switch 1126 may set the preamble of the second digital transmission signal according to the control signal of the algorithm scheduler 1115 .

When receiving the control signal from the algorithm scheduler 1115, the second switch 1126 generates a preamble instructing the request of the second channel request through the second preamble generator 1127, and the second switch 1126 including the generated preamble 2 Digital transmission signals can be generated. When the second switch 1126 does not receive the control signal from the algorithm scheduler 1115 , a separate setting for the preamble of the second digital transmission signal may not be performed. The second switch 1126 may transmit a second digital transmission signal to the third DAC 1128 .

The third DAC 1128 may receive a second digital transmission signal from the second switch 1126 . The third DAC 1128 may generate a second analog transmission signal by converting the second digital transmission signal into an analog signal. The third DAC 1128 may transmit the second analog transmission signal to the third IF transmitter 1129 .

The third IF transmitter 1129 may receive the second analog transmission signal from the third DAC 1128 . The third IF transmitter 1129 may IF-process the second analog transmission signal to generate a fourth IF transmission signal. The third IF transmitter 1129 may transmit the fourth IF transmission signal to the third multiplexer/demultiplexer 1116 . The third multiplexer/demultiplexer 1116 may multiplex the fourth IF transmission signal with other signals and transmit it to a second outdoor device (not shown).

12A is a conceptual diagram illustrating various signals transmitted and received by an outdoor device and an indoor device in the fixed wireless link system according to the fifth embodiment.

Referring to FIG. 12A , the outdoor device and the indoor device include an IF transmission signal 1212 or 1222 , an IF reception signal 1215 or 1225 , a reception control signal 1215 or 1225 , a transmission control signal 1213 or 1223 , and a power signal. At least one of (1214 or 1224) may be transmitted/received. The frequency of the IF transmit signal 1212 or 1222 may be 150 MHz. The frequency of the IF received signal 1215 or 1225 may be 140 MHz. The frequency band of the reception control signal 1215 or 1225 and the transmission control signal 1213 or 1223 may be several kHz to several MHz. The voltage of the power signal 1214 or 1224 may be -48V.

12B is another conceptual diagram illustrating various signals transmitted and received by an indoor device and an outdoor device in the fixed wireless link system according to the fifth embodiment.

Referring to FIG. 12B , the indoor device 1210 may transmit/receive various signals to and from the outdoor device 1220 through the first multiplexer/demultiplexer 1211 . Similarly, the outdoor device 1220 may transmit/receive various signals to and from the second multiplexer/demultiplexer 1221 with the indoor device 1211 . The indoor device 1211 and the outdoor device 1220 may be connected through a coaxial cable 1230 .

The indoor device 1210 may transmit the IF transmission signal 1212 to the outdoor device 1220 through the first multiplexer/demultiplexer 1211 . The frequency of the IF transmit signal 1212 may be a predefined 340 MHz or 350 MHz.

The indoor device 1210 may transmit the uplink control signal 1213 through the first multiplexer/demultiplexer 1211 . The uplink control signal 1213 may include at least one of output power control information and phase locked loop (PLL) information. The frequency band of the uplink control signal 1213 may be several kHz to several MHz. The indoor device 1210 may transmit a power 1216 of -48V for operating the outdoor device 1220 through the first multiplexer/demultiplexer 1211 .

The indoor device 1210 may receive the downlink control signal 1215 from the outdoor device 1220 through the first multiplexer/demultiplexer 1211 . The downlink control signal 1215 may include at least one of information on the received power strength, information on the received signal strength, and phase-locked loop information. The indoor device 1210 may monitor the state of the outdoor device 1220 through the downlink control signal 1215 . The frequency band of the downlink control signal 1215 may be several kHz to several MHz.

The indoor device 1210 may receive the IF reception signal 1216 from the outdoor device 1220 through the first multiplexer/demultiplexer 1211 . The frequency of the IF receive signal 1216 may be a predefined 140 MHz.

The outdoor device 1220 may receive the IF transmission signal 1222 from the indoor device 1210 through the second multiplexer/demultiplexer 1221 . The frequency of the IF transmit signal 1222 may be a predefined 340 MHz or 350 MHz.

The outdoor device 1220 may receive the uplink control signal 1223 from the indoor device 1210 through the second multiplexer/demultiplexer 1221 . The uplink control signal 1223 may include at least one of output power control information and phase locked loop information. The frequency band of the uplink control signal 1223 may be several kHz to several MHz. The outdoor device 1220 may receive the power 1226 of -48V for operating the outdoor device 1220 through the second multiplexer/demultiplexer 1221 .

The outdoor device 1220 may transmit a downlink control signal 1225 to the indoor device 1210 through the second multiplexer/demultiplexer 1221 . The downlink control signal 1225 may include at least one of information on the received power strength, information on the received signal strength, and phase-locked loop information. The frequency band of the downlink control signal 1225 may be several kHz to several MHz.

The outdoor device 1220 may transmit the IF reception signal 1226 to the indoor device 1210 through the second multiplexer/demultiplexer 1221 . The frequency of the IF receive signal 1226 may be a predefined 140 MHz.

When the interference canceling device (not shown) is disposed between the indoor device 1210 and the outdoor device 1220 , the interference is based on at least one of the IF transmission signal 1211 , the IF reception signal 1226 , and the power 1216 . removal can be performed.

13 is a conceptual diagram illustrating an interference cancellation module in a fixed radio link system according to a fifth embodiment.

The fixed radio link system may include a plurality of antennas, a plurality of outdoor devices, and a plurality of indoor devices in order to increase spectral efficiency. The communication system may include a fixed radio link system. The fixed radio link system may further include an interference cancellation device for canceling mutual interference between the plurality of outdoor devices and the plurality of indoor devices. In addition, the interference removing device may have a structure that can be disposed between the plurality of outdoor devices and the plurality of indoor devices in order to minimize structural changes of the plurality of outdoor devices and the plurality of indoor devices.

For example, referring to FIG. 13 , the fixed wireless link system includes a first indoor device 1310 , a second indoor device 1320 , an interference cancellation device 1330 , a first outdoor device 1340 , and a second outdoor device (1350) may be included. The interference cancellation apparatus 1330 may include a first multiplexer/demultiplexer 1331 , a second multiplexer/demultiplexer 1332 , a third multiplexer/demultiplexer 1333 , and a fourth multiplexer/demultiplexer 1334 . have.

The interference canceling device 1330 is disposed between the first indoor device 1310 , the second indoor device 1320 , the first outdoor device 1340 , and the second outdoor device 1350 to perform interference cancellation, so that the first Structural changes of the indoor device 1310 , the second indoor device 1320 , the first outdoor device 1340 , and the second outdoor device 1350 may be minimized.

That is, the interference cancellation apparatus 1330 performs interference cancellation while minimizing the structural change of objects of the fixed radio link system, thereby simplifying circuit configuration of objects and reducing manufacturing costs for objects. .

14 is a block diagram illustrating an apparatus for canceling interference in a fixed radio link system according to a sixth embodiment.

Referring to FIG. 14 , the interference cancellation device 1430 includes a first multiplexer/demultiplexer 1431 , a first IF circuit 1432 , an interference cancellation module 1433 , a second IF circuit 1434 , and a second multiplexer/demultiplexer 1431 . It may include a demultiplexer 1435 , a third multiplexer/demultiplexer 1436 , a third IF circuit 1437 , a fourth IF circuit 1438 , and a fourth multiplexer/demultiplexer 1439 .

The first multiplexer/demultiplexer 1431 may receive a first transmission signal from a first indoor device (not shown). The first transmission signal may include a first transmission control signal, a first IF transmission signal, and a first power signal. The first multiplexer/demultiplexer 1431 may separate the first transmission control signal, the first IF transmission signal, and the first power signal from the first transmission signal.

The first multiplexer/demultiplexer 1431 may transmit the first transmission control signal to the second multiplexer/demultiplexer 1435 . The first multiplexer/demultiplexer 1431 may use the first power signal as power for driving the interference cancellation device 1430 . The first multiplexer/demultiplexer 1431 may transmit the first IF transmission signal to the first IF circuit 1432 .

The first IF circuit 1432 may convert the first IF transmission signal into an I/Q signal on a DC frequency to generate a first I/Q transmission signal. The first IF circuit 1432 may transmit the converted first I/Q transmission signal to the interference cancellation circuit 1433 .

The interference cancellation module 1433 may include a first ADC 1433 - 1 , a first DAC 1433 - 2 , a second ADC 1433 - 3 , and a second DAC 1433 - 4 .

The interference cancellation module 1433 may generate a first digital signal by converting the first I/Q transmission signal through the first ADC 1433 - 1 . The interference cancellation module 1433 may convert the first digital signal through the first DAC 1433 - 2 to generate the first analog signal. The first analog signal may be referred to as a second I/Q transmission signal. The interference cancellation circuit 1433 may transmit the second I/Q transmission signal to the second IF circuit 1434 .

The second IF circuit 1434 may IF-process the second I/Q transmission signal to generate a second IF transmission signal. The second IF circuit 1434 may transmit the second IF transmission signal to the second multiplexer/demultiplexer 1435 .

The second multiplexer/demultiplexer 1435 may generate a second transmission signal by multiplexing the first transmission control signal and the second IF transmission signal. The interference cancellation apparatus 1430 may transmit the second transmission signal to the first outdoor apparatus (not shown).

The interference cancellation apparatus 1430 may receive the first reception signal from the first outdoor apparatus. The first reception signal may include a first reception control signal and a first IF reception signal. The interference cancellation apparatus 1430 may separate the first reception signal into a first reception control signal and a first IF reception signal through the second multiplexer/demultiplexer 1435 .

The second multiplexer/demultiplexer 1435 may transmit the first reception control signal to the first multiplexer/demultiplexer 1431 . The second multiplexer/demultiplexer 1435 may transmit the first IF received signal to the second IF circuit 1434 .

The second IF circuit 1434 may convert the first IF received signal into an I/Q signal on a DC frequency to generate a first I/Q received signal. The second IF circuit 1434 may transmit the first I/Q received signal to the indirect cancellation device 1430 .

The indirect removal device 1430 may generate a second digital signal by converting the first I/Q received signal through the second ADC 1433 - 3 . The indirect removal apparatus 1430 may generate a second analog signal by converting the second digital signal through the second DAC 1433 - 4 . The indirect cancellation device 1430 may transmit the second analog signal to the first IF circuit 1432 .

The first IF circuit 1432 may IF-process the second analog signal to generate a second IF reception signal. The first IF circuit 1432 may transmit the second IF received signal to the first multiplexer/demultiplexer 1431 .

The first multiplexer/demultiplexer 1431 may receive the first reception control signal from the second multiplexer/demultiplexer 1435 . Also, the first multiplexer/demultiplexer 1431 may receive the second IF signal from the first IF circuit 1432 . The first multiplexer/demultiplexer 1431 may generate a second reception signal by multiplexing the first reception control signal and the second IF signal. The first multiplexer/demultiplexer 1431 may transmit the second received signal to the first indoor device (not shown).

The third multiplexer/demultiplexer 1436 may receive a third transmission signal from the second indoor device (not shown). The third transmission signal may include a second transmission control signal, a third IF transmission signal, and a second power signal. The third multiplexer/demultiplexer 1436 may separate the second transmission control signal, the third IF transmission signal, and the second power signal from the third transmission signal.

The third multiplexer/demultiplexer 1436 may transmit the third transmission control signal to the fourth multiplexer/demultiplexer 1439 . The third multiplexer/demultiplexer 1436 may use a portion of the second power signal as power for driving the interference cancellation device 1430 . The third multiplexer/demultiplexer 1436 may transmit the second IF transmission signal to the third IF circuit 1437 .

The third IF circuit 1437 may generate a third I/Q transmission signal by converting the third IF transmission signal into an I/Q signal on a DC frequency. The third IF circuit 1437 may transmit a third I/Q transmission signal to the interference cancellation module 1433 .

The interference cancellation module 1433 may further include a third ADC 1433 - 5 , a third DAC 1433 - 6 , a fourth ADC 1433 - 7 , and a fourth DAC 1433 - 8 .

The interference cancellation module 1433 may generate a third digital signal by converting the third I/Q transmission signal through the third ADC 1433 - 5 . The interference cancellation module 1433 may convert the third digital signal through the third DAC 1433 - 6 to generate the third analog signal. The third analog signal may be referred to as a third I/Q transmission signal. The interference cancellation module 1433 may transmit the third I/Q transmission signal to the fourth IF circuit 1438 .

The fourth IF circuit 1438 may generate a fourth IF transmission signal by IF-processing the third I/Q transmission signal. The fourth IF circuit 1438 may transmit the fourth IF transmission signal to the fourth multiplexer/demultiplexer 1439 .

The fourth multiplexer/demultiplexer 1439 may generate a fourth transmission signal by multiplexing the second transmission control signal and the fourth IF transmission signal. The interference cancellation apparatus 1430 may transmit a fourth transmission signal to a second outdoor apparatus (not shown).

The interference cancellation apparatus 1430 may receive a third reception signal from a second outdoor apparatus (not shown). The third reception signal may include a second reception control signal and a third IF reception signal. The interference cancellation apparatus 1430 may separate the third reception signal into a second reception control signal and a third IF reception signal through the fourth multiplexer/demultiplexer 1439 .

The fourth multiplexer/demultiplexer 1439 may transmit the second reception control signal to the third multiplexer/demultiplexer 1436 . The fourth multiplexer/demultiplexer 1439 may transmit the third IF received signal to the fourth IF circuit 1438 .

The fourth IF circuit 1438 may convert the third IF received signal into an I/Q signal on a DC frequency to generate a third I/Q received signal. The fourth IF circuit 1438 may transmit the third I/Q received signal to the indirect cancellation device 1430 .

The indirect removal device 1430 may generate a fourth digital signal by converting the third I/Q received signal through the fourth ADC 1433 - 8 . The indirect removal device 1430 may generate a fourth analog signal by converting the fourth digital signal through the fourth DAC 1433 - 7 . The indirect cancellation device 1430 may transmit the fourth analog signal to the third IF circuit 1437 .

The third IF circuit 1437 may generate a fourth IF reception signal by IF-processing the fourth analog signal. The third IF circuit 1437 may transmit the fourth IF received signal to the third multiplexer/demultiplexer 1436 .

The third multiplexer/demultiplexer 1436 may receive the second reception control signal from the fourth multiplexer/demultiplexer 1439 . Also, the third multiplexer/demultiplexer 1436 may receive the fourth IF signal from the third IF circuit 1437 . The third multiplexer/demultiplexer 1436 may generate a fourth reception signal by multiplexing the second reception control signal and the fourth IF signal. The third multiplexer/demultiplexer 1436 may transmit the fourth received signal to the second indoor device (not shown).

The interference cancellation apparatus 1430 may monitor a signal transmitted/received through at least one of a first channel connected to the first outdoor apparatus and a second channel connected to the second outdoor apparatus 1450 . The interference cancellation apparatus 1430 may determine an unused section in which signals are not transmitted/received in at least one of the first channel and the second channel. The interference cancellation apparatus 1430 may transmit the channel estimation control signal through at least one of the first channel and the second channel in the unused section. The interference cancellation apparatus 1430 according to another embodiment may alternately transmit the channel estimation control signal to the first channel and the second channel in a section in which signals are not transmitted/received through both the first channel and the second channel.

15A is a flowchart illustrating a signal flow between communication nodes for generating channel information in a fixed radio link system according to the sixth embodiment.

Referring to FIG. 15A , the fixed wireless link system includes a first outdoor device 1510 , a second outdoor device 1520 , an interference removing device 1530 , a first indoor device 1540 , and a second indoor device 1550 . may include Each of the first outdoor device 1510 , the second outdoor device 1520 , the interference removing device 1530 , the first indoor device 1540 , and the second indoor device 1550 is the first outdoor device ( 1440 ), the second outdoor device 1450 , the first indoor device 1410 , the second indoor device 1420 , and the interference cancellation device 1430 may be configured in the same or similar manner. Each of the first outdoor device 1510 , the second outdoor device 1520 , the interference removing device 1530 , the first indoor device 1540 , and the second indoor device 1550 may be connected through a wired or wireless interface.

The first outdoor device 1510 , the second outdoor device 1520 , the first indoor device 1530 , the second indoor device 1540 , and the interference canceling device 1530 may be interconnected through a wired or wireless interface, respectively. .

The interference canceller 1530 may determine an uplink unused section (S1501). The interference removing device 1530 may generate at least one transmission signal to be transmitted to the first outdoor device 1510 and the second outdoor device 1520 . The interference cancellation apparatus 1530 may transmit at least one transmission signal to the first outdoor apparatus 1510 and the second outdoor apparatus 1520 through an uplink.

For example, the interference cancellation apparatus 1530 may generate a first transmission signal and transmit it to the first outdoor apparatus 1510 through a first uplink. Also, the interference canceling device 1530 may generate a second transmission signal and transmit it to the second outdoor device 1520 through a second uplink. In this case, the interference cancellation apparatus 1530 may determine a section in which the transmission signal is not transmitted. That is, the interference cancellation apparatus 1530 may determine an uplink unused section in which a transmission signal is not transmitted.

The interference cancellation apparatus 1530 may generate a signal for requesting channel information in an uplink unused section (S1502). For example, the interference canceller 1530 may include a signal requesting information on the first channel, which is the communication channel of the first outdoor device 1510 , in the first transmission signal. The interference cancellation apparatus 1530 may include a signal requesting first channel information by changing the preamble of the first transmission signal. Also, the interference canceling device 1530 may include a signal requesting information on the second channel, which is the communication channel of the second outdoor device 1520 , in the second transmission signal. The interference cancellation apparatus 1530 may include a signal requesting second channel information by changing the preamble of the second transmission signal.

The interference canceller 1530 may alternately transmit a signal for requesting channel information (S1503). For example, after transmitting the first transmission signal through the first uplink, the interference cancellation apparatus 1530 may transmit the second transmission signal through the second uplink. Alternatively, after transmitting the second transmission signal through the second uplink, the interference cancellation apparatus 1530 may transmit the first transmission signal through the first uplink.

The interference canceling device 1530 may transmit a signal requesting the first channel information to the first outdoor device 1510 (S1504). The signal requesting the first channel information may be included in the first transmission signal. That is, the interference cancellation apparatus 1530 may transmit the first transmission signal including the signal requesting the first channel information to the first outdoor apparatus 1520 .

The first outdoor device 1510 may generate first channel information (S1505). The first outdoor device 1510 may identify a signal requesting the first channel information based on the preamble of the first transmission signal. The first outdoor device 1510 may generate first channel information according to a signal requesting first channel information. The first outdoor device 1510 may include the first channel information in the first data signal to be transmitted to the first indoor device 1540 . For example, the first outdoor device 1510 may set a preamble of the first data signal to include the first channel information in the first data signal.

The interference canceling device 1530 may transmit a signal requesting second channel information to the second outdoor device 1520 (S1506). The signal requesting the second channel information may be included in the second transmission signal. That is, the interference cancellation apparatus 1530 may transmit a second transmission signal including a signal requesting second channel information to the second outdoor apparatus 1520 .

The second outdoor device 1520 may generate second channel information (S1507). The second outdoor device 1520 may identify a signal for requesting second channel information based on the preamble of the second transmission signal. The second outdoor device 1520 may generate second channel information according to a signal requesting second channel information. The second outdoor device 1520 may include the second channel information in the second data signal to be transmitted to the second indoor device 1540 . For example, the second outdoor device 1520 may set a preamble of the second data signal to include the second channel information in the second data signal.

15B is a flowchart illustrating a signal flow between communication nodes for channel measurement and interference cancellation in a fixed radio link system according to the sixth embodiment.

Referring to FIG. 15B , the first outdoor device 1510 may transmit the first channel information to the interference cancellation device 1530 ( S1508 ). The second outdoor device 1520 may transmit the second channel information to the second indoor device 1530 ( S1509 ).

The interference cancellation apparatus 1530 may digitize the channel information (S1510). For example, the interference cancellation apparatus 1530 may digitize the first channel information received from the first outdoor apparatus 1510 . That is, the interference canceling apparatus 1530 may convert the first data signal including the first channel information received from the first outdoor apparatus 1510 into a digital signal. Similarly, the interference canceling device 1530 may convert the second data signal including the second channel information received from the second outdoor device 1520 into a digital signal.

The interference cancellation apparatus 1530 may perform channel estimation and interference cancellation (S1511). The interference canceller 1530 may check the first channel information through the preamble of the first data signal converted into a digital signal. Also, the interference cancellation apparatus 1530 may check the second channel information through the preamble of the second data signal converted into a digital signal.

The interference cancellation apparatus 1530 may estimate the state of the first channel and the state of the second channel based on the first channel information and the second channel information. For example, the interference canceller 1530 may determine the phase and amplitude of the first channel based on the first channel information. Also, the interference cancellation apparatus 1530 may determine the phase and amplitude of the second channel based on the second channel information. The interference cancellation apparatus 1530 may cancel interference between the first data signal and the second data signal based on the state of the first channel and the state of the second channel.

The interference canceling device 1530 may transmit an interference-removed data signal (S1512). The interference canceling device 1530 may transmit the first data signal from which the interference is removed to the first indoor device 1540 ( S1513 ). Also, the interference canceling device 1530 may transmit the second data signal from which the interference is removed to the second indoor device 1550 .

16 is a block diagram illustrating an interference cancellation apparatus in a fixed radio link system according to a seventh embodiment.

Referring to FIG. 16 , the fixed wireless link system may include an indoor device 1610 , an interference cancellation device 1620 , and an outdoor device 1630 . The indoor device 1610 , the interference removing device 1620 , and the outdoor device 1630 may be interconnected through a predetermined wired or wireless interface.

The interference cancellation apparatus 1620 may include a first field-programmable radio frequency (FPRF) module 1621 , an interference cancellation module 1622 , and a second FPRF module 1623 .

The first FPRF module 1621 includes a third IF circuit 1621-1, a third ADC 1621-2, a third DAC 1621-3, a fourth IF circuit 1621-4, a fourth ADC ( 1621-5) and a fourth DAC 1621-6. The second FPRF module 1623 is a fifth IF circuit 1623-1, a fifth ADC 1623-2, a fifth DAC 1623-3, a sixth IF circuit 1623-4, a sixth ADC ( 1623-5) and a sixth DAC 1623-6.

The interference cancellation module 1622 may be mounted on a commercial field-programmable gate array (FPGA) board. That is, the interference removal module 1622 may be configured as a separate and independent substrate. Accordingly, the interference canceling module 1622 may be inserted into and separated from the interference canceling device 1620 . Also, the interference removing module 1622 may be inserted and separated from the first indoor device 1610 or the second outdoor device 1630 as well as the interference removing device 1620 .

17 is a block diagram illustrating an indoor device including an interference canceller in a fixed radio link system according to an eighth embodiment.

Referring to FIG. 17 , the communication system may include an indoor device 1710 and an outdoor device 1720 . The indoor device 1710 and the outdoor device 1720 may be interconnected through a predefined wired or wireless interface.

The indoor device 1710 may include a baseband/Ethernet communication unit 1711 , a modem and interference cancellation module 1712 , an FPRF module 1723 , and a multiplexer/demultiplexer 1724 . The FPRF module 1723 may include a plurality of digital-to-analog converters, a plurality of digital-to-analog converters, and a plurality of IF circuits.

The modem and interference cancellation module 1712 may be mounted on a commercial FPGA board. That is, the interference removal module 1712 may be configured as a separate and independent substrate. Accordingly, the interference removing module 1712 can be inserted and separated from the indoor device 1710 . In addition, the interference removal module 1712 may be inserted or removed from the indoor device 1710 as well as the outdoor device 1730 . Also, the interference removal module 1712 may be inserted and separated from a communication device (not shown) having a structure in which the first indoor device 1710 and the second outdoor device 1720 are combined.

The present invention relates to a communication system for increasing transmission/reception data capacity by applying LOS MIMO technology. LOS MIMO technology is largely divided into an analog interference cancellation method and a digital interference cancellation method. The analog interference cancellation method has the advantage of being able to remove interference while minimizing changes to the existing system. However, the analog interference cancellation method has disadvantages in that an applicable bandwidth is narrow and channel estimation is inaccurate due to characteristics of an analog circuit.

Although the analog interference cancellation method has a wide applicable bandwidth and accurate channel estimation is possible, there is a problem in that the definition of a new preamble signal and the frame structure for the existing transmission signal control and channel estimation need to be changed. In addition, it is necessary to add a receiver channel estimation and a LOS MIMO algorithm that separates channels based on the estimated information.

The interference cancellation apparatus of the present invention uses an analog method of removing interference using passive elements at the coaxial cable end and a digital method of applying an algorithm using digital data sampled through an ADC in a fixed wireless link system LOS environment MIMO technology can be used to improve spectral efficiency.

The interference cancellation apparatus of the present invention can solve the problem of narrowing the interference cancellation bandwidth due to the self-band characteristics of analog passive elements in the analog method, and the problem of using a digital board connected to a modem for baseband signal processing in the digital method have.

The interference cancellation apparatus of the present invention can solve the problem by using a digital method instead of an analog method at the coaxial cable end. For example, since the interference cancellation apparatus uses the sampled digital data, the interference cancellation bandwidth can be widened, and the installation flexibility can be increased by minimizing the influence on the existing fixed wireless link equipment. In addition, by using FPRF and FPGA, the interference cancellation device can be applied and applied as an independent function block type even in the type of equipment in which the indoor device and the indoor device are integrated, thereby simplifying the system configuration, thereby lowering the overall system price. can

The present invention has the effect of simplifying the circuit structure of a product and reducing manufacturing cost by providing an apparatus and method for channel estimation and interference cancellation without changing the structure of communication objects in a fixed radio link system.

The present invention has the effect of simplifying the circuit structure of a product and reducing manufacturing costs by providing an apparatus for estimating and removing interference that can be inserted into communication objects without changing the structure of the communication objects in a fixed radio link system. .

The present invention provides an apparatus and method for channel estimation and interference cancellation using a digital signal without changing the structure of communication objects in a fixed radio link system, thereby simplifying the circuit structure of the product and reducing manufacturing cost, There is an effect that can significantly improve the channel estimation and interference cancellation performance.

The present invention provides an apparatus that can be inserted into communication objects without changing the structure of the communication objects in a fixed radio link system, and can estimate a channel and cancel interference using a digital signal, thereby simplifying the circuit structure of the product and manufacturing cost In addition to reducing the cost, there is an effect of remarkably improving the channel estimation and interference cancellation performance.

The present invention performs the interference cancellation algorithm of the digital interference cancellation method in the analog stage, which is the IF band, in the line-of-sight multiple input/output system, so that wideband performance and accurate channel estimation, which are the advantages of the digital interference cancellation method, are possible, and the advantages of the analog interference cancellation method By providing a channel estimation and interference cancellation device that can minimize changes to the existing system, the circuit structure of the product is simplified and manufacturing cost is reduced, and the channel estimation and interference cancellation performance can be significantly improved. .

The methods according to the invention may be implemented in the form of program instructions that can be executed by various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the computer-readable medium may be specially designed and configured for the present invention, or may be known and available to those skilled in the art of computer software.

Examples of computer-readable media include hardware devices specially configured to store and carry out program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware device described above may be configured to operate as at least one software module to perform the operations of the present invention, and vice versa.

Although it has been described with reference to the above embodiments, it will be understood by those skilled in the art that various modifications and changes can be made to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. will be able

Claims (9)

A method of operating an interference cancellation device in a fixed radio link system, the method comprising:
determining an unused section in which signal transmission is not performed through antennas of a plurality of outdoor devices;
generating a plurality of transmission signals including a plurality of signals requesting channel information of the plurality of outdoor devices in the determined unused section;
transmitting the plurality of transmission signals to the plurality of outdoor devices through a plurality of indoor devices connected to the interference cancellation device;
receiving a plurality of reception signals including the channel information of the plurality of outdoor devices and a plurality of signals received through the antennas through the plurality of indoor devices;
converting the frequencies of the plurality of received signals into intermediate frequencies;
performing channel estimation based on the channel information of the plurality of outdoor devices included in the plurality of received signals converted to the intermediate frequency; and
and removing interference between the plurality of received signals based on a result of the channel estimation. The method according to claim 1,
The generating step is
generating a first transmission preamble indicating a request for first channel information, which is channel information of a communication channel of a first outdoor device among the plurality of outdoor devices;
generating a first transmission signal including the first transmission preamble;
generating a second transmission preamble indicating a request for second channel information, which is channel information of a communication channel of a second outdoor device among the plurality of outdoor devices; and
and generating a second transmission signal including the second transmission preamble. 3. The method according to claim 2,
The sending step is
transmitting the first transmission signal to a first indoor device among the plurality of indoor devices through a first uplink; and
transmitting the second transmission signal to a second indoor device among the plurality of indoor devices through a second uplink;
and the first and second transmission signals are transmitted to the first and second outdoor devices via the first and second indoor devices. The method according to claim 1,
The receiving step is
A first reception signal including first channel information that is channel information of a communication channel of a first outdoor device among the plurality of outdoor devices and a first reception preamble indicating that the first channel information is included is transmitted to the plurality of outdoor devices. receiving from a first indoor device among indoor devices; and
A second reception signal including second channel information that is channel information of a communication channel of a second outdoor device among the plurality of outdoor devices and a second reception preamble indicating that the second channel information is included is transmitted to the plurality of outdoor devices. Receiving from a second indoor device among indoor devices,
and the first and second received signals are transmitted to an Internet network through the first and second indoor devices after interference is removed based on the first and second channel information. 5. The method according to claim 4,
The step of performing the channel estimation comprises:
generating first and second digital signals by digitally converting the first and second received signals converted to the intermediate frequency;
checking the first and second channel information in the first and second digital signals; and
estimating states of communication channels of the first and second outdoor devices based on the first and second channel information;
wherein the state of the communication channels includes a phase and an amplitude. An apparatus for canceling interference in a fixed radio link system, comprising:
processor;
a memory in electronic communication with the processor; and
including instructions stored in the memory;
When the instructions are executed by the processor, the instructions cause the interference cancellation apparatus to:
determining an unused section in which signal transmission is not performed through antennas of a plurality of outdoor devices;
generating a plurality of transmission signals including a plurality of signals requesting channel information of the plurality of outdoor devices in the determined unused section;
transmitting the plurality of transmission signals to the plurality of outdoor devices;
receiving a plurality of reception signals including the channel information of the plurality of outdoor devices and the plurality of signals received through the antennas;
performing channel estimation based on the channel information of the plurality of outdoor devices included in the plurality of received signals;
cancel interference between the plurality of signals received through the antennas based on a result of the channel estimation; and
and causing transmission of the plurality of signals from which the mutual interference has been canceled to a plurality of indoor devices connected to the interference cancellation device. 7. The method of claim 6,
The instructions are the interference cancellation device,
generating a first transmission preamble indicating a request for first channel information that is channel information of a communication channel of a first outdoor device among the plurality of outdoor devices;
generate a first transmit signal including the first transmit preamble;
generating a second transmission preamble indicating a request for second channel information that is channel information of a communication channel of a second outdoor device among the plurality of outdoor devices; and
and generate a second transmit signal comprising the second transmit preamble. 7. The method of claim 6,
The instructions are the interference cancellation device,
A first reception signal including first channel information, which is channel information of a communication channel of a first outdoor device among the plurality of outdoor devices, and a first reception preamble indicating that the first channel information is included, is transmitted to the first reception signal. receive from an outdoor device;
A second reception signal including second channel information, which is channel information of a communication channel of a second outdoor device among the plurality of outdoor devices, and a second reception preamble indicating that the second channel information is included, is transmitted to the second reception signal. receive from an outdoor device; and
Further causing the first and second reception signals to be subjected to interference cancellation based on the first and second channel information to be transmitted to the Internet network through first and second indoor devices among the plurality of indoor devices An interference cancellation device operable to 9. The method of claim 8,
The instructions are the interference cancellation device,
digitally converting the first and second received signals to generate first and second digital signals;
check the first and second channel information in the first and second digital signals; and
and estimating states of communication channels of the first and second outdoor devices based on the first and second channel information,
wherein the state of the communication channels includes a phase and an amplitude.

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