KR101082022B1 - digital repeater of mobile communication system and method thereof - Google Patents

Abstract

Disclosed are a digital repeater and a relay method using the same in a telecommunication system according to the present invention. When the digital repeater according to the present invention receives a radio frequency (RF) signal, the digital repeater divides the received RF signal into N (N≥2) narrowband signals having a predetermined bandwidth, and the separated N narrowbands. A DU (Donor Unit) for combining the signal according to the channel bonding scheme and transmitting through a transmission line; And at least one remote unit (RU) for converting a signal transmitted through the transmission line into the RF signal. In addition, when the RF signal is received, the present invention divides the received RF signal into N (N≥2) narrowband signals having a predetermined bandwidth, and divides the separated N narrowband signals into channels. Combining through a bonding scheme and transmitting through a transmission line; And converting a signal transmitted through the transmission line into the RF signal. Through this, the present invention is capable of high speed transmission using a low cost coaxial cable, it is possible to reduce the construction and maintenance costs of the relay system.

Digital Repeater, DU, RU, Coaxial Cable, Modulation, Channel Bonding Technique

Description

Digital repeater of mobile communication system and relay method using same

The present invention relates to a digital repeater of a mobile communication system and a relay method using the same.

In general, it is difficult to reach the base station of the base station, or to use the repeater to improve the coverage and coverage of the call quality of the radio wave blocking area due to the feature. In particular, in the case of an in-building repeater, a DU (Donor Unit) and a RU (Remote Unit) are connected to each other by wire, and various transmission methods include an optical / coaxial / UTP (Unshielded Twisted Pair) cable.

When using an optical cable among these cables, it can transmit up to several tens of kilometers, but is mainly used for high power equipment because of the high cost of maintaining the line and the cost of the optical element. In addition, coaxial cables are used for low power equipment because the transmission distance is much smaller than optical cables, but the maintenance cost and equipment cost are low. However, in both cases, since DU transmits IF or RF analog signal, if multiple RUs are connected to one DU, line compensation according to the length should be provided.

In this case, a coaxial cable may use a digital method through a modem, but such a digital method generally has a limitation that can be transmitted from several tens of Mbps up to 100 Mbps, which is necessary for a mobile communication requiring a transmission speed of several hundred Mbps to several Gbps. Inadequate

On the other hand, when using UTP cable, unlike optical / coaxial cable, digital compensation is not required. However, the Gigabit Ethernet method is not efficient in large buildings because the length of the line is limited to 100 m or less.

The present invention is to solve the problems of the prior art as described above, using a modulation scheme having a predetermined modulation level in a DU (donor unit) in a digital repeater and a channel bonding technique for combining a plurality of low-speed channels The present invention provides a digital repeater of a mobile communication system and a relay method using the same by transmitting an RF signal to at least one remote unit (RU) to enable high speed transmission even when using a low cost coaxial cable.

In addition, the present invention enables the use of low-cost coaxial cable as a high-speed transmission line between the DU and at least one RU in the digital repeater, thereby reducing the cost of construction and maintenance of the relay system digital repeater of the mobile communication system And to provide a relay method using the same.

To this end, when the digital repeater of the mobile communication system according to an aspect of the present invention receives an RF signal, the received RF signal is divided into N narrowband signals having a predetermined bandwidth (N≥2). A DU (Donor Unit) for separating and transmitting the separated N narrowband signals according to a channel bonding technique and transmitting them through a transmission line; And at least one remote unit (RU) for converting a signal transmitted through the transmission line into the RF signal.

In a relay method using a digital repeater of a mobile communication system according to another aspect of the present invention, if a radio frequency (RF) signal is received, N (N≥2) narrowband signals having a predetermined bandwidth are received. Separating the N narrowband signals according to a channel bonding technique and transmitting the separated N narrowband signals through a transmission line; And converting a signal transmitted through the transmission line into the RF signal.

Hereinafter, a digital repeater of a mobile communication system and a relay method using the same according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 6. That is, the present invention uses a modulation scheme having a predetermined modulation level in a DU (Donor Unit) in a digital repeater using a coaxial cable and a channel bonding technique combining a plurality of low-speed channels from a base station. The radio frequency (RF) signal is transmitted to at least one remote unit (RU) at high speed.

1 is an exemplary view showing the configuration of a schematic mobile communication system according to an embodiment of the present invention.

As shown in FIG. 1, a mobile communication system according to the present invention includes a base station 110, a digital repeater 120, that is, a DU 122, at least one RU 124, a mobile terminal 130, and the like. Can be configured.

The digital repeater 120 is installed between a base station 110 and the mobile terminal 130, that is, in a shadow area where mobile communication service cannot be provided from the base station 110, and receives a signal from the base station 110. The amplification may be provided to the mobile terminal 130, and the signal from the mobile terminal 130 may be amplified and provided to the base station 110. Here, the digital repeater 120 is an in-building repeater, which is a transmission between the DU 122 receiving the RF signal from the base station 110 and at least one RU 124 transmitting the RF signal to the mobile terminal 130. Coaxial cable can be used for the track.

In particular, the digital repeater 120 according to the present invention not only performs digital transmission so that loss on a transmission line does not occur, but also enables high-speed transmission for a mobile communication signal requiring a transmission speed of several hundred Mbps to several Gbps. An RF signal may be relayed using a modulation scheme having a modulation level of, for example, Quadrature Phase Shift Keying (QPSK), Quadrature Amplitude Modulation (QAM), and the like, and a channel bonding technique for combining and transmitting a plurality of low-speed channels.

Briefly describing this process, the DU 122 converts the RF signal received from the base station 110 into a baseband digital signal, and separates the separated digital signal into a plurality of narrowband signals having a predetermined bandwidth. After modulating each of the plurality of narrowband signals in a predetermined modulation scheme, the modulated plurality of narrowband signals may be combined according to a channel bonding technique and transmitted to the RU 124 through a transmission line.

Conversely, the RU 124 separates the signal received from the DU 122 through the transmission line into a plurality of narrowband signals, and demodulates each of the separated plurality of narrowband signals in a demodulation scheme having a preset demodulation level. In addition, the demodulated multiple narrowband signals may be recombined, converted into original digital signals, and then converted into RF signals and transmitted to the mobile terminal 130.

As such, the present invention transmits an RF signal received from a base station to at least one RU using a modulation scheme having a predetermined modulation level in a DU in a digital repeater and a channel bonding technique combining a plurality of low speed channels, thereby providing a low cost. High speed transmission may be possible even with coaxial cables.

In this case, the digital repeater according to the present invention is not limited to relaying the RF signal received from the base station to the mobile terminal as mentioned above, and considering the form in which a plurality of repeaters are cascaded between the base station and the mobile terminal, RF signals received from other repeaters may also be relayed to the mobile terminal.

The digital repeater according to the present invention may transmit the received RF signal from the base station or the repeater to the mobile terminal or transmit the received RF signal from the mobile terminal to the repeater or the base station. Only a process for transmitting an RF signal received from the mobile terminal to an example will be described.

FIG. 2 is a first exemplary diagram showing a detailed configuration of the DU 122 in the digital repeater shown in FIG. 1.

As illustrated in FIG. 2, the DU 122 according to the present invention includes a receiving antenna 210, a first RF processor 220, a first signal processor 230, a transmission line 240, and the like. The first signal processor 230 may include a first digital signal processing (DSP) 231, a modulator 232, a combiner 233, and the like.

When the RF signal is received from the base station or the repeater through the receiving antenna 210, the first RF processing unit 220 converts the received RF signal into an IF (Intermediate Frequency) signal and converts it into a baseband signal and then baseband Can be converted into a digital signal. As such, the present invention converts the received RF signal into a digital signal and transmits the same through the transmission line, so that a loss on the transmission line does not occur, thereby eliminating the need for a separate circuit to compensate for the loss.

However, because these baseband digital signals are wideband signals, it is not possible to handle them at typical low modem speeds. Thus, the first signal processor 230 according to the present invention separates and processes a baseband digital signal into a plurality of narrowband signals having a predetermined bandwidth. This process will be described with reference to FIG. 3.

3 is an exemplary diagram for describing a signal processing process of a DU according to an embodiment of the present invention.

As shown in FIG. 3, the first DSP 231 in the first signal processor 230 according to an embodiment of the present invention has a predetermined bandwidth because the converted baseband digital signal A is a wideband signal. It can be separated into a plurality of narrowband signal (B) having a.

The modulator 232 compresses a plurality of narrowband signals B separated from the first DSP 231 by using a modulation method having a predetermined modulation level and modulates them into narrower narrowband signals C. In particular, for example, 64QAM, 128QAM, 256QAM, etc., which are high-speed modulation schemes, can be used.

In this case, according to the present invention, the modulation level of the modulation scheme for modulating it according to the number N (N≥2) of the plurality of narrowband signals separated for high speed transmission of 1 Gbps for mobile communication or according to the modulation level of the modulation scheme The number of narrowband signals may vary. That is, the present invention provides a plurality of narrowband signals such that the number of narrowband signals N) × (transmission rate S _channel according to a predetermined channel bandwidth and modulation scheme) ≥ (target transmission rate S _target ) can be satisfied. The number of and the modulation level of the modulation scheme can be adjusted appropriately.

For example, if the channel bandwidth of 10 MHz is used, the 64QAM modulation scheme yields a transmission speed of approximately 60 Mbps. Therefore, in order to obtain a transmission rate of 1 Gbps for mobile communication, a 17 Mbps that meets 60 Mbps x 17 = 1020 Mbps (≥1 Gbps) is required. Channels, that is, narrowband signals may be required. In addition, 256QAM, which is a higher speed modulation method, has a speed of approximately 85 Mbps, and thus, a transmission rate of 1 Gbps may require 12 channels, that is, narrowband signals, satisfying 85 Mbps × 12 = 1020 Mbps (≥1 Gbps). have.

The combiner 233 combines a plurality of modulated narrowband signals C according to a channel bonding technique, that is, multiplies different center frequencies so that the plurality of narrowband signals do not overlap each other (D). (E). The combiner 233 may transmit the combined signal E to the at least one RU through the transmission line 240, which is similar to that transmitted by each channel with a very wide bandwidth as in the original broadband signal in the frequency axis. same.

4 is an exemplary view showing a detailed configuration of the RU 124 in the digital repeater shown in FIG.

As shown in FIG. 4, the RU 124 according to the present invention includes a transmission line 410, a second signal processor 420, a second RF processor 430, a transmit antenna 440, and the like. Here, the second signal processor 440 may include a separator 441, a demodulator 442, a second DSP 443, and the like.

When the signal is received from the DU through the transmission line 410, the second signal processor 420 may convert the received signal into an original RF signal and transmit the RF signal to at least one mobile terminal. The process will be described with reference to FIG. 5.

5 is an exemplary diagram for describing a signal processing procedure of an RU according to an embodiment of the present invention.

As shown in FIG. 5, the separation unit 441 in the second signal processing unit 420 of the present invention may divide the received signal E into a plurality of narrowband signals, that is, in front of the received signal. In DU, different center frequencies applied according to the channel bonding technique may be remultiplied (D) to be separated into a plurality of original narrowband signals (C). For example, a frequency product f1 × f1 produces signals of an upper band with a frequency of 2f1 (= f1 + f1) and a lower band with a frequency of 0 (= f1-f1). The lower band signal can be used.

The demodulator 442 may demodulate the plurality of narrowband signals C to correspond to a demodulation scheme having a predetermined demodulation level, that is, a modulation scheme having a predetermined modulation level used by a modulation unit in the DU. The second DSP 443 may combine the demodulated multiple narrowband signals B and convert them into the original wideband digital signal A.

As a result, the second RF processor 430 converts the wideband digital signal A into an analog signal and then converts the digital signal A into an RF signal as opposed to the first RF processor in the DU, thereby converting the converted RF signal into a transmission antenna 440. It can be transmitted to at least one mobile terminal through.

As described above, the present invention enables the construction of a relay system because a low-cost coaxial cable can be used as a high-speed transmission line between a DU and at least one RU in a repeater in place of an optical cable or a UTP cable suitable for transmitting a mobile communication signal. And maintenance costs can be reduced.

FIG. 6 is a second exemplary diagram showing a detailed configuration of the DU 122 in the digital repeater shown in FIG. 1.

As illustrated in FIG. 6, the DU 122 according to the present invention includes a receiving antenna 610, an RF processor 620, a first signal processor 630, a transmission line 640, and the like. The first signal processor 630 may include a divider 634 and a first DSP 631, a modulator 632, and a combiner 633 corresponding to each of the plurality of RUs.

In addition, the first signal processor 630 may further include a synthesizer 635 and a separator 636, a demodulator 637, a second DSP 638, and the like corresponding to each of the plurality of RUs. This is because the DU may not only provide the RF signal to the RU but also receive and process the RF signal.

The DU converts the RF signal received from the base station or another repeater into a digital signal of the base rental, and distributes the number of Ms (M≥2) of the RUs through the divider 634 to each signal processor, thereby providing them to each signal processor. This may be transmitted to each of a plurality of RUs using a modulation scheme having a predetermined modulation level and a channel bonding technique combining a plurality of low speed channels.

This is because, in installing the digital repeater in the shaded area, a plurality of RUs may be provided in one DU depending on the size or distribution state of the shaded area.

According to the present invention, a digital repeater of a mobile communication system and a relay method using the same may be modified and applied in various forms within the scope of the technical idea of the present invention, and the present invention is not limited to the above embodiments. In addition, the embodiments and drawings are merely for the purpose of describing the contents of the invention in detail, not intended to limit the scope of the technical idea of the invention, the present invention described above is common knowledge in the technical field to which the present invention belongs As those skilled in the art may have various substitutions, modifications, and changes without departing from the technical spirit of the present invention, it is not limited to the embodiments and the accompanying drawings, as well as the claims below. It should be judged by including the claims and the equivalents.

1 is an exemplary view showing the configuration of a schematic mobile communication system according to an embodiment of the present invention.

FIG. 2 is a first exemplary diagram showing a detailed configuration of the DU 122 in the digital repeater shown in FIG. 1.

3 is an exemplary diagram for describing a signal processing process of a DU according to an embodiment of the present invention.

4 is an exemplary view showing a detailed configuration of the RU 124 in the digital repeater shown in FIG.

5 is an exemplary diagram for describing a signal processing procedure of an RU according to an embodiment of the present invention.

FIG. 6 is a second exemplary diagram showing a detailed configuration of the DU 122 in the digital repeater shown in FIG. 1.

<Description of Symbols for Main Parts of Drawings>

110: base station

120: digital repeater

122: DU

124: RU

130: mobile terminal

210: receiving antenna

220: first RF processing unit

230: First signal processing unit

240, 410: transmission line

420: second signal processing unit

430: second RF processing unit

440: transmit antenna

Claims (13)

Upon receiving a radio frequency (RF) signal, converts the received RF signal into a baseband digital signal and separates the converted digital signal into N narrowband signals having a predetermined bandwidth. A DU (Donor Unit) for combining the separated N narrowband signals according to a channel bonding scheme and transmitting the same through a coaxial cable which is a transmission line; And At least one remote unit (RU) for converting the signal transmitted through the coaxial cable to the RF signal, The DU, A first RF processor converting the RF signal received from a base station or a repeater into the baseband digital signal; A first digital signal processing (DSP) for dividing the converted digital signal into N narrowband signals having the preset bandwidth; A modulator for modulating each of the separated N narrowband signals in a modulation scheme having a preset modulation level; And And a combiner for combining the modulated N narrowband signals according to the channel bonding technique and transmitting the modulated N narrowband signals to the RU through the coaxial cable. delete The method according to claim 1, The modulator, Modulate each of the separated N narrowband signals, Modulates a modulation scheme having a predetermined modulation level satisfying relation (N × S _channel ) ≥S _target , wherein the S _channel is a transmission rate according to a channel bandwidth and a modulation scheme, and the S _target is a target transmission rate, respectively. Digital repeater which means. The method according to claim 1, The coupling part, And multiplying the different center frequencies according to the channel bonding scheme to combine the modulated N narrowband signals with each other so as not to overlap each other on a frequency axis. The method of claim 1, wherein the DU, A divider for distributing the converted baseband digital signals by the M numbers to transmit to the M (M≥2) RUs Digital repeater comprising more. The method according to claim 1, The RU is, A separation unit for separating the signal received through the coaxial cable from the DU into N narrowband signals; A demodulator for demodulating each of the separated N narrowband signals in a demodulation scheme having a preset demodulation level; A second DSP for combining the demodulated N narrowband signals into a baseband digital signal; And And a second RF processor converting the converted baseband digital signal into the RF signal and transmitting the converted baseband digital signal to at least one mobile terminal. The method according to claim 6, The separation unit, And multiplying the signals received through the coaxial cable by different center frequencies applied according to the channel bonding technique in the DU to separate the N narrowband signals from which the different center frequencies have been canceled. Repeater. Upon receiving a radio frequency (RF) signal, converts the received RF signal into a baseband digital signal and separates the converted digital signal into N narrowband signals having a predetermined bandwidth. Combining the separated N narrowband signals according to a channel bonding technique and transmitting them through a coaxial cable which is a transmission line; And Converting the signal transmitted through the coaxial cable into the RF signal, Transmitting through the coaxial cable, Converting the RF signal received from a base station or repeater into the baseband digital signal; Dividing the converted digital signal into N narrowband signals having the preset bandwidth; Modulating each of the separated N narrowband signals in a modulation scheme having a preset modulation level; And Combining the modulated N narrowband signals according to the channel bonding technique and transmitting the modulated N narrowband signals through the coaxial cable. delete The method of claim 8, Converting to the baseband digital signal, And distributing the converted digital signals by M to transmit M digital signals to M RUs. The method of claim 8, Converting to the RF signal, Dividing the signal received through the coaxial cable into N narrowband signals using different center frequencies applied according to the channel bonding technique; Demodulating the separated N narrowband signals in a demodulation scheme having a preset demodulation level; Combining the demodulated N narrowband signals into a baseband digital signal; And And converting the converted baseband digital signal into the RF signal. The method of claim 8, Transmitting the converted RF signal to at least one mobile terminal Relay method using a digital repeater further comprising. delete

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