KR20220032946A - Radio Unit - Google Patents

Abstract

The present invention relates to a radio unit (RU) connected with a main hub unit (MHU) through an optical cable in a distributed antenna system. The radio unit includes: a photoconversion part receiving an optical signal from the main hub unit, and then, converting the optical signal into an electric signal; a separation part receiving the electric signal from the photoconversion part, and then, separating a radio signal and a TDD signal from the electric signal; a switching signal generation part generating a switching signal by applying a time delay, which is estimated based on the length of the optical cable between the main hub unit and the radio unit, to the TDD signal; and a switching part receiving a millimeter wave band signal from the frequency conversion part, and switching a downlink signal and an uplink signal by using the switching signal received from the switching signal generation part. Therefore, the present invention is capable of reducing the signal interference of the uplink and downlink signals.

Description

radio unit

The present invention relates to a radio unit, and more particularly, to a radio unit that is a component of a Distributed Antenna System (DAS).

A Distributed Antenna System (DAS) is an antenna system used to solve the problem of high traffic capacity in an indoor environment by spatially distributing antennas. In general, when a single antenna covers a large area, a radio shadow area problem occurs. In order to solve this problem, a distributed antenna system is to distribute and install an antenna having a relatively small output in several places.

In the distributed antenna system, a main hub unit (MHU) connected to a base station and a radio unit (RU) connected to a wireless terminal communicate with each other through an optical cable to exchange large amounts of data. At this time, the main hub unit and the radio unit can exchange time division duplex (TDD) signals with each other. Since the optical cable located between the main hub unit and the radio unit has a predetermined length, there is a time delay problem. There was a problem in that an error occurred in the TDD signal due to such a time delay.

Korean Patent Laid-Open Patent No. 10-2006-0036656 (published date: May 2, 2006, title of invention: method for determining switching time for time delay compensation of tdd optical repeater in WiBro system and tdd optical repeater therefor)

An object of the present invention is to provide a radio unit capable of compensating for a time delay of a TDD signal generated by an optical cable positioned between a main hub unit and the radio unit.

The radio unit of the present invention for solving the above problem is a radio unit (RU) connected to a main hub unit (MHU) by an optical cable in a distributed antenna system, receiving an optical signal from the main hub unit, and converting it into an electric signal An optical conversion unit, a separation unit for receiving the electrical signal from the optical conversion unit and separating a radio signal and a TDD signal from the electrical signal, based on the TDD signal, based on the length of the optical cable between the radio unit and the main hub unit A switching signal generator that generates a switching signal by applying the estimated time delay, and receives a millimeter wave band signal from the frequency converter, and uplinks with a downlink signal using the switching signal received from the switching signal generator It is a radio unit including a switching unit for switching a link signal.

The radio unit according to an embodiment of the present invention further comprises an information receiver for receiving information on the length of the optical cable, and the switching signal generator receives information on the length of the optical cable from the information receiver to receive the information on the length of the optical cable, the time It may be a radio unit that applies a delay.

In the radio unit according to an embodiment of the present invention, the information receiving unit may be a radio unit that receives information on the length of the optical cable from an external terminal connected to the radio unit through wired or short-range wireless communication.

In the radio unit according to an embodiment of the present invention, the information receiving unit may be a radio unit that receives information on the length of the optical cable from the main hub unit.

The radio unit according to an embodiment of the present invention further comprises a length calculating unit for calculating the length of the optical cable by measuring the time that light is transmitted and reflected through the optical cable, and the switching signal generating unit is the length calculating unit It may be a radio unit that receives information on the length of the optical cable from the radio unit and applies the time delay.

In the radio unit according to an embodiment of the present invention, the switching signal generator may be a radio unit that generates the switching signal by adjusting the level of the TDD signal.

In the radio unit according to an embodiment of the present invention, the radio signal may be a radio unit having a frequency band of 1 to 2 GHz.

In the radio unit according to an embodiment of the present invention, the TDD signal may be a radio unit having a frequency band of 1 MHz to 100 MHz.

The radio unit according to an embodiment of the present invention is effective in reducing signal interference between an uplink signal and a downlink signal by compensating for a time delay caused by an optical cable positioned between the main hub unit and the radio unit.

1 is a conceptual diagram of a distributed antenna system according to an embodiment of the present invention.
2 is a diagram illustrating a method in which a radio unit applies time delay compensation according to an embodiment of the present invention.
3 is a diagram illustrating a method for a radio unit to apply time delay compensation according to an embodiment of the present invention.
4 is a diagram illustrating a method for a radio unit to apply time delay compensation according to an embodiment of the present invention.
5 is a diagram illustrating a method in which a radio unit applies time delay compensation according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that adding a detailed description of a technique or configuration already known in the field may make the gist of the present invention unclear, some of it will be omitted from the detailed description. In addition, the terms used in this specification are terms used to properly express embodiments of the present invention, which may vary according to a person or custom in the relevant field. Accordingly, definitions of these terms should be made based on the content throughout this specification.

The terminology used herein is for the purpose of referring to specific embodiments only, and is not intended to limit the invention. As used herein, the singular forms also include the plural forms unless the phrases clearly indicate the opposite. As used herein, the meaning of 'comprising' specifies a particular characteristic, region, integer, step, operation, element and/or component, and other specific characteristic, region, integer, step, operation, element, component, and/or group. It does not exclude the existence or addition of

Hereinafter, the radio unit 200 according to an embodiment of the present invention will be described with reference to the accompanying FIGS. 1 to 5 .

The radio unit 200 of the present invention is a component of a distributed antenna system used to solve the problem of high traffic capacity in an indoor environment by spatially distributing antennas. The radio unit 200 receives a large amount of data from the main hub unit 200 in the distributed antenna system and communicates with the mobile device 300 through the antenna. When a single antenna covers a large area, a radio wave shadow area problem occurs. In order to solve this problem, antennas having a relatively small output are distributed and installed in several places to solve this problem. That is, it is possible to eliminate a shadow area generated when one base station 10 communicates with the mobile device 300 through an antenna through several radio units 200 . The radio unit 200 may be particularly useful in a mobile communication network using a high-bandwidth frequency capable of processing large-capacity data, for example, a millimeter-wave band frequency.

The radio unit 200 is connected to the main hub unit 200 by an optical cable 20 . At this time, a time delay occurs due to the predetermined length of the optical cable 20, which causes an error in the TDD signal. In order to solve this problem, the radio unit 200 generates a switching signal by compensating for a time delay according to the length of the optical cable 20, thereby reducing this error.

As shown in FIG. 2 , the radio unit 200 includes a wavelength division multiplexing unit for multiplexing signals to other radio units 200 , an optical conversion unit 120 for receiving an optical signal from the main hub unit 200 , and an optical conversion unit ( The separation unit 130 for separating the electrical signal received from 120), the frequency conversion unit 140 for converting the radio signal into a millimeter wave band signal, the ASK demodulator 150 for generating the demodulated TDD signal, and the switching signal A switching signal generator generating unit, a switching unit 170 for switching a downlink signal and an uplink signal, an FSK demodulator generating a demodulated NMS signal, a controller 190 controlling the radio unit 200, and an optical cable 20 ) may include a length calculating unit 101 for calculating the length.

1 파장의 광신호를 사용하고, 그와 연결된 별개의 라디오 유닛(200)이

2 파장의 광신호를 사용하는 경우에 있어서, 메인 허브 유닛(200)으로부터

1 과

2 가 결합된 광신호를 수신하게 되면,

1 파장의 광신호는 하위 단인 광전환부(120)로 송신하고,

2 파장의 광신호는 별개의 라디오 유닛(200)으로 송신한다. 이는 다운링크에 해당하는 하나의 예로서 업링크도 이와 동일하게 파장대별로 역다중화할 수 있다.The wavelength division multiplexer may multiplex and demultiplex the optical signal to the plurality of radio units 200 . An optical signal is received from the main hub unit 200 , and the optical signal is multiplexed by frequency wavelength among the received optical signals to transmit the optical signal to another radio unit 200 connected to the radio unit 200 . For example, the radio unit 200 to which the wavelength division multiplexing unit belongs

Using an optical signal of one wavelength, a separate radio unit 200 connected thereto

In the case of using an optical signal of two wavelengths, from the main hub unit 200

1 lesson

When 2 receives the combined optical signal,

An optical signal of one wavelength is transmitted to the optical conversion unit 120, which is a lower stage,

The two-wavelength optical signal is transmitted to a separate radio unit 200 . This is an example corresponding to the downlink, and the uplink may be demultiplexed for each wavelength in the same way.

The optical conversion unit 120 receives the optical signal received by the radio unit 200 from the main hub unit 200 . In this case, the optical signal received by the optical conversion unit 120 may be formed as an analog optical signal. The analog optical signal has an advantage in that it is easier to extend the frequency compared to the digital optical signal. In addition, excellent call quality can be secured with low propagation delay. The optical conversion unit 120 converts the optical signal received from the main hub unit 200 into an electrical signal.

The wavelength division multiplexing unit or the optical conversion unit 120 transmits an optical signal to the main hub unit 200 and may measure a time at which the optical signal is reflected and returned. In this case, the wavelength division multiplexing unit or the optical conversion unit 120 may include a function such as an optical time domain reflectometer (OTDR). In particular, OTDR measures in the time domain with respect to the signal returned by incident on the optical path. The distance to the other side of the connection can be calculated mainly by measuring the characteristics of the optical line, contact loss, loss point, and chromatic dispersion. Measurement information measured by the wavelength division multiplexing unit or the optical conversion unit 120 may be transmitted to a length calculating unit 101 to be described later.

The length calculating unit 101 may calculate the length of the optical cable 20 installed between the main hub unit 200 and the radio unit 200 . The length calculating unit 101 may receive measurement information about the length of the optical cable 20 from the optical conversion unit 120 . The measurement information may refer to information about a signal that is reflected and returned by the wavelength division multiplexer or the optical conversion unit 120 incident on the main hub unit 200 with an optical signal. The length calculating unit 101 may calculate the length of the optical cable 20 through the measurement information. The length calculating unit 101 may transmit the calculated length of the optical cable 20 to the controller 190 or calculate a delay time generated through the length of the optical cable 20 .

The separation unit 130 receives an electrical signal from the light conversion unit 120 . At this time, the electrical signal received by the separation unit 130 is combined with a radio signal corresponding to data, a TDD signal modulated by an amplitude shift modulation method, and an NMS signal modulated by a frequency shift modulation method. Here, the NMS signal may mean a kind of management data signal generated by the NMS 11 (Network Management Server). Since each signal cannot be demodulated into a signal before being modulated with the combined signal, the separation unit 130 separates the electrical signal into a radio signal, a TDD signal, and an NMS signal. At this time, the separated radio signal is a radio signal of an intermediate frequency band. In this case, the separated TDD signal and the modulated TDD signal are signals of a frequency band of 1 MHz to 100 MHz. At this time, the separated NMS signal is a frequency band of 1 MHz to 100 MHz. However, the TDD signal and the NMS signal are signals of different frequency bands. The separation unit 130 transmits the radio signal to the frequency converter, transmits the modulated TDD signal to the ASK demodulator, and transmits the modulated NMS signal to the FSK demodulator, respectively.

The frequency conversion unit 140 receives a radio signal from the separation unit 130 . The frequency converter 140 may convert the received radio signal of the intermediate frequency band into a millimeter wave band signal. The radio signal converted into the millimeter wave band signal is transmitted to the switching unit 170 .

The ASK demodulator 150 receives the modulated TDD signal from the separation unit 130 . Since the TDD signal received by the ASK demodulator 150 is an amplitude shift modulated signal, the ASK demodulator 150 demodulates the modulated TDD signal to generate a demodulated TDD signal. Since the demodulation method of the amplitude shift-modulated signal is a known technique, a detailed description thereof will be omitted. The ASK demodulator 150 transmits the demodulated TDD signal to the switching signal generator.

The FSK demodulator receives the modulated NMS signal from the separation unit 130 . Since the NMS signal received by the FSK demodulator is a frequency shift modulated signal, the FSK demodulator demodulates the modulated NMS signal to generate a demodulated NMS signal. Since the demodulation method of the frequency shift-modulated signal is a known technique, a detailed description thereof will be omitted. The FSK demodulator transmits the demodulated NMS signal to the controller 190 .

The control unit 190 receives the demodulated NMS signal from the FSK demodulator. The controller 190 may control the radio unit 200 using the received NMS signal. In this case, the radio unit 200 may control the switching time of the switching unit 170 by transmitting time delay data to the switching signal generating unit.

The control unit 190 may further include an information receiving unit 191 that can receive information on the length of the optical cable 20 from the external terminal 400 . An installer who builds a distributed antenna system may know in advance length information of the optical cable 20 configured between the main hub unit 200 and the radio unit 200 . In this case, the installer may input length information of the optical cable 20 through the information receiving unit 191 of the radio unit 200 through the external terminal 400 . The external terminal 400 and the information receiver 191 may be connected to each other wirelessly or wired to communicate with each other. The information receiving unit 191 receiving the length information of the optical cable 20 from the external terminal 400 may calculate the delay time of the optical signal according to the length of the corresponding optical cable 20 . The information receiving unit 191 may transmit time delay data to the switching signal generating unit so that the switching unit 170 may perform delayed switching using the calculated delay time.

The NMS signal received by the controller 190 may include length information of the optical cable 20 , and this length information may be transmitted to the information receiver 191 . An installer constituting the distributed antenna system may input length information of the optical cable 20 configured between the main hub unit 200 and the radio unit 200 through the NMS 11 . The length information of the optical cable 20 input to the NMS 11 is transmitted to the radio unit 200 through the base station 10 and the main hub unit 200 . The radio unit 200 receiving the length information of the optical cable 20 transmits the corresponding information to the control unit 190 or the information receiving unit 191 according to the signal transmission flow as described above. That is, the length information of the optical cable 20 may be included in the NMS signal separated by the separation unit 130 .

The control unit 190 may separate the length information of the optical cable 20 from the demodulated NMS signal received from the FSK demodulator. The separated length information may be transmitted to the information receiving unit 191 . The information receiver 191 may calculate the delay time of the optical signal using the separated information. The controller 190 or the information receiver 191 may transmit time delay data to the switching signal generator so that the switching unit 170 may perform delayed switching using the calculated delay time.

The switching signal generator receives the demodulated TDD signal from the ASK demodulator 150 . The switching signal generator generates a switching signal from the demodulated TDD signal. The generated switching signal is transmitted to the switching unit 170 , and the switching unit 170 may perform switching synchronization between the uplink and the downlink by using the switching signal. The switching signal generator may generate a switching signal by reflecting a time delay in the demodulated TDD signal. A time delay may occur in the TDD signal due to the distance between the main hub unit 200 and the radio unit 200 . Accordingly, the switching signal generating unit generates a switching signal by reflecting the time delay so that the switching signal can accurately provide synchronization information. In this case, the switching signal generator may use the time delay data received from the control unit 190 . The switching signal generator may generate a switching signal by adjusting the level of the demodulated TDD signal. The level of the demodulated TDD signal may be different from that transmitted from the main hub unit 200 . Accordingly, in order to generate an accurate switching signal, the switching signal generator adjusts the level of the demodulated TDD signal to generate the switching signal.

The switching unit 170 receives a radio signal of the millimeter wave band from the frequency conversion unit 140 . In addition, the switching signal is received from the switching signal generator. The switching unit 170 switches the uplink signal and the downlink signal by using the received switching signal. The switching unit 170 transmits a downlink signal to the antenna, and the antenna transmits the received downlink signal to the mobile device 300 .

5 shows that the main hub unit measures the length of the optical cable. The main hub unit may transmit an optical signal to the radio unit and measure the time the optical signal is reflected and returned. In this case, as described above, the main hub unit may include a function such as an optical time domain reflectometer (OTDR).

In general, the main hub unit may be connected to a plurality of radio units. In this case, the radio unit may be connected to the main hub unit by a cascading method. That is, in the main hub unit, the measurement information measured by the plurality of main hub units may be transmitted to the length calculating unit of the radio unit.

The technical features disclosed in each embodiment of the present invention are not limited only to the embodiment, and unless they are mutually incompatible, the technical features disclosed in each embodiment may be combined and applied to different embodiments.

In the above, embodiments of the radio unit of the present invention have been described. The present invention is not limited to the above-described embodiments and the accompanying drawings, and various modifications and variations will be possible from the point of view of those of ordinary skill in the art to which the present invention pertains. Accordingly, the scope of the present invention should be defined not only by the claims of the present specification, but also by those claims and their equivalents.

10: base station
11: NMS
20: optical cable
200: radio unit
101: length calculation unit
110: wavelength division multiplexing unit
120: light conversion unit
130: separation unit
140: frequency conversion unit
150: ASK demodulator
160: FSK demodulator
180: switching signal generator
170: switching unit
190: control unit
191: Information Receiving Department
300: mobile device
400: external terminal
200: main hub unit

Claims (8)

In a radio unit (RU) connected to a main hub unit (MHU) by an optical cable in a distributed antenna system,
an optical conversion unit that receives an optical signal from the main hub unit and converts it into an electrical signal;
a separation unit for receiving the electrical signal from the optical conversion unit and separating a radio signal and a TDD signal from the electrical signal;
a switching signal generator for generating a switching signal by applying a time delay estimated based on the length of the optical cable between the radio unit and the main hub unit to the TDD signal; and
a switching unit for receiving a millimeter wave band signal from the frequency converter and switching a downlink signal and an uplink signal using the switching signal received from the switching signal generator;
A radio unit comprising a. According to claim 1,
Further comprising an information receiving unit for receiving information on the length of the optical cable,
The switching signal generator receives information on the length of the optical cable from the information receiver and applies the time delay. 3. The method of claim 2,
The information receiver is a radio unit for receiving information on the length of the optical cable from an external terminal connected to the radio unit through wired or short-range wireless communication. 3. The method of claim 2,
The information receiving unit is a radio unit for receiving information on the length of the optical cable from the main hub unit. According to claim 1,
Further comprising a length calculation unit for calculating the length of the optical cable by measuring the time that light is transmitted and reflected through the optical cable,
The switching signal generator receives information on the length of the optical cable from the length calculator and applies the time delay. According to claim 1,
The switching signal generator adjusts the level of the TDD signal to generate the switching signal. According to claim 1,
The radio signal is a radio unit having a frequency band of 1 to 2 GHz. According to claim 1,
The TDD signal is a radio unit having a frequency band of 1 MHz to 100 MHz.

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