JP5980654B2 - Distributed wireless communication base station system, signal processing device, wireless device, and operation method of distributed wireless communication base station system - Google Patents

Description

  The present invention includes a distributed wireless communication base station system and a method for operating the distributed wireless communication base station system in which the functions of the wireless communication base station are divided into a signal processing unit and a wireless communication unit and physically separated from each other. The present invention relates to a signal processing device and a wireless device.

  In a cellular system, in order to improve the degree of freedom of cell configuration, a base station function is physically separated by dividing it into a signal processing unit (BBU: Base Band Unit) and an RF unit (RRU: Remote Radio Unit). It is considered to do. At this time, the radio signal is transmitted through the optical fiber between the BBU and the RRU by the RoF (Radio over Fiber) technique. RoF technology can be broadly divided into analog RoF technology and digital RoF technology, but in recent years, digital RoF technology with excellent transmission quality has been actively studied, and the use formulation under the standard organizations such as CPRI (Common Public Radio Interface) (See, for example, Non-Patent Document 1).

  One BBU can also accommodate a plurality of RRUs. As a result, the BBUs required for each RRU can be consolidated into one, and the operation / installation cost can be reduced. As an example of such a configuration, a configuration has been proposed in which BBU and RRU are connected by a PON (Passive Optical Network) as shown in FIG. In this method, the band between the OLT and the optical splitter is constant, but the band between the optical splitter and the ONU can be changed according to the required band of the ONU. As a PON signal multiplexing method, TDM, WDM, FDM, or the like can be adopted.

CPRI, “CPRI Specification V5.0”, Sep. , 2011, http: // www. cpri. info / spec. html 3GPP TS 36.104 V10.4.0, “Evolved Universal Terrestrial Radio Access (E-UTRA) semiconon Base Station (BS) radio transmission and reception”, p. 28 (Sep. 2011).

  The digital RoF transmission technology between BBU and RRU is a technology related to the present invention, and this type is hereinafter referred to as a related technology. Also, a digital signal (IQ data) for each I-axis and Q-axis of the radio signal created by BBU is converted into an optical signal and transmitted to the RRU, and the optical signal received by the RRU is converted into a radio signal and sent to the terminal. The link to transmit is called a downlink. On the other hand, a link that receives a radio modulated signal transmitted from a terminal by RRU, converts the received radio signal to an optical signal and transmits it to the BBU, converts the optical signal received by the BBU to IQ data, and demodulates the signal Is called uplink.

  FIG. 10 shows an apparatus configuration example of the RRU of related technology.

  Since the RRU is an uplink, an antenna 11 that transmits / receives a radio signal, a transmission / reception switching unit 12 that switches between transmission / reception, an amplifier 21 that amplifies the signal power of the received radio signal to a level that allows signal processing, A down-conversion unit 22 that down-converts the radio signal, an A / D conversion unit 23 that converts the down-converted analog signal into IQ data, and a baseband filter unit (upstream) 24 that performs a filtering process on the IQ data; , A frame conversion unit 25 that multiplexes IQ data and control signals, and an E / O conversion unit 26 that converts electrical signals into optical signals and transmits them.

  Since the RRU is a downlink, the O / E conversion unit 31 that converts the optical signal received from the BBU into an electric signal, the frame conversion unit 32 that extracts the control signal and IQ data from the received signal, and the IQ data are filtered. A baseband filter unit (downstream) 33 that performs processing, a D / A converter 34 that converts IQ data into an analog signal, an upconverter 35 that upconverts the analog signal, and amplifies the power to a predetermined transmission power An amplifier 36, a transmission / reception switching unit 12, and an antenna 11.

    FIG. 11 shows a device configuration example of the related art BBU.

  Since the BBU is an uplink, the O / E conversion unit 41 that converts an optical signal into an electrical signal, the frame conversion unit 42 that extracts a control signal and IQ data from the received signal, and a modulation / demodulation unit 43 that demodulates the IQ data Have

  Also, since the BBU is a downlink, a modem unit 43 that outputs IQ data of a radio modulation signal, a frame conversion unit 51 that multiplexes IQ data and a control signal, and an E / O that converts an electrical signal into an optical signal and transmits it. A conversion unit 52 is included.

  In a cellular system such as LTE (Long Term Evolution) and WiMAX (Worldwide Interoperability for Microwave Access), a terminal needs a communication channel (wireless band) unique to the terminal. This allocation of the radio band is performed by the base station. Taking the LTE system as an example, as shown in FIG. 12, the base station performs scheduling with a minimum period of 1 ms and allocates a radio band to each terminal. Radio band allocation is performed in resource block (RB) units, and 1 RB is 180 kHz and 0.5 ms. When the system bandwidth is 20 MHz, 110 RBs exist on the frequency axis. In addition, 7 symbols (1 symbol including a cyclic prefix, 71.4 μs) are inserted into 1 RB assuming a normal cyclic prefix.

In the related art, the sampling frequency f _s for converting a radio modulation signal into a digital signal is determined by the system bandwidth. Taking CPRI example, if _f s = 30.72 MHz in the LTE system bandwidth is 20 MHz, the system bandwidth is _f s = 15.36 MHz when the 10 MHz. As shown in FIG. 13, the sampling frequency f _s is constant and does not change with time.

However, not all radio bands are always used for signal transmission, and there are unused radio bands that are not used depending on the number of terminals under the RRU and the required transmission rate of the terminals. For this reason, even if the system bandwidth is 20 MHz, only 10 MHz or 5 MHz wireless bands may be used. In this case, a sampling frequency f _s that is higher than necessary for converting a radio signal into a digital signal is used, and the band of the PON system is excessively used.

  Therefore, in order to solve such a problem, the present invention provides operations of a distributed wireless communication base station system, a signal processing device, a wireless device, and a distributed wireless communication base station system that can effectively use a band between BBU and RRU. It aims to provide a method.

The present invention divides the radio signal into a plurality of frequency components, and the reducing capable of reducing the sampling frequency f _s for each frequency component.

Specifically, in the distributed radio communication base station system according to the present invention, the functions of the base station that transmits and receives radio signals to and from the radio terminal are a signal processing device (BBU: Base Band Unit) and a radio device (RRU: Remote Radio Unit). ) Distributed wireless communication base station system,
An optical fiber connecting the BBU and the RRU, and transmitting a transmission signal between the BBU and the RRU as an optical signal by RoF (Radio over Fiber);
Based on radio band information of the radio signal, the radio signal is divided into a plurality of frequency component divided signals, and the sampling frequency of the divided signal is changed from a predetermined value for each frequency component to obtain the transmission signal Frequency change function,
A sampling frequency restoration function for restoring a sampling frequency to a predetermined value for each frequency component when the transmission signal is received, and removing a folding signal generated at the time of restoration of the sampling frequency;
It is characterized by providing.

The operation method of the distributed radio communication base station system according to the present invention is an operation method of the distributed radio communication base station in which the function of the base station that transmits and receives radio signals to and from the radio terminal is divided into BBU and RRU. And
When the BBU and the RRU are connected by an optical fiber, and a transmission signal between the BBU and the RRU is RoF-transmitted as an optical signal,
Based on radio band information of the radio signal, the radio signal is divided into a plurality of frequency component divided signals, and the sampling frequency of the divided signal is changed from a predetermined value for each frequency component to obtain the transmission signal Frequency change procedure,
A sampling frequency restoration procedure for restoring a sampling frequency to a predetermined value for each frequency component when the transmission signal is received, and removing a folding signal generated when the sampling frequency is restored;
It is characterized by performing.

  Moreover, the signal processing apparatus and radio apparatus which concern on this invention are BBU and RRU with which the said distributed radio | wireless communication base station system is provided.

In order to determine the necessary band for each frequency component and reduce the sampling frequency f _s of the signal of the frequency component with a relatively small width of the used radio band and perform digital RoF transmission, it is transmitted between BBU and RRU. Bandwidth can be reduced. Therefore, the present invention can provide a distributed radio communication base station system, a signal processing device, a radio device, and a method for operating the distributed radio communication base station system that can effectively use a band between BBU and RRU.

  The sampling frequency changing function of the distributed radio communication base station system according to the present invention is changed to a sampling frequency at which the influence of the folded signal of one divided signal on the other divided signals is less than a preset allowable value. can do.

  The sampling frequency changing function of the distributed radio communication base station system according to the present invention can change the sampling frequency according to a band included in the frequency component.

  The sampling frequency changing function of the distributed radio communication base station system according to the present invention can set the sampling frequency of the frequency component to zero when there is an unused frequency component.

The optical fiber of the distributed wireless communication base station system according to the present invention is a PON (Passive Optical Network) system that connects one BBU and a plurality of RRUs,
OLT on the BBU side of the PON system, which converts the signal format handled by the BBU and the signal format that can be transmitted by the PON system, and controls transmission timing to avoid collision of optical signals in the PON system (Optical Line Terminal) function,
An ONU (Optical) that is on the RRU side of the PON system, converts the signal format handled by the RRU and the signal format that can be transmitted by the PON system, and transmits an upstream optical signal at a timing instructed by the OLT function. (Network Unit) function,
Is further provided.

  This distributed wireless communication base station system reduces the installation / operation cost of optical fiber transmission lines by connecting one BBU and multiple RRUs with a PON system, and statistical multiplexing by sharing optical fiber transmission lines. Bandwidth utilization efficiency can be improved by obtaining the effect.

  INDUSTRIAL APPLICABILITY The present invention can provide a distributed radio communication base station system, a signal processing device, a radio device, and a method for operating the distributed radio communication base station system that can effectively use a band between BBU and RRU.

It is a figure explaining the radio | wireless apparatus which concerns on this invention. It is a figure explaining the filter bank which the radio | wireless apparatus which concerns on this invention has. It is a figure explaining the filter bank which the radio | wireless apparatus which concerns on this invention has. It is a figure explaining the signal processing apparatus which concerns on this invention. It is a figure explaining the filter bank which the signal processor concerning the present invention has. It is a figure explaining the filter bank which the signal processor concerning the present invention has. It is a figure explaining the operation | movement method of the distributed radio | wireless communication base station system which concerns on this invention. It is a figure explaining the operation | movement method of the distributed radio | wireless communication base station system which concerns on this invention. It is a figure explaining the distributed radio | wireless communication base station system relevant to this invention. It is a figure explaining the radio | wireless apparatus relevant to this invention. It is a figure explaining the signal processing apparatus relevant to this invention. It is a figure explaining the radio | wireless band allocation method of a LTE system. It is a figure explaining operation | movement of the distributed radio | wireless communication base station system relevant to this invention. It is a figure explaining a return signal.

  Embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments described below are embodiments of the present invention, and the present invention is not limited to the following embodiments. In the present specification and drawings, the same reference numerals denote the same components.

The distributed wireless communication base station system of this embodiment is a distributed wireless communication base station system in which the functions of the base station that transmits and receives wireless signals to and from wireless terminals are divided into BBUs and RRUs.
An optical fiber that connects the BBU and the RRU, and performs RoF transmission of a transmission signal between the BBU and the RRU as an optical signal;
Based on radio band information of the radio signal, the radio signal is divided into a plurality of frequency component divided signals, and the sampling frequency of the divided signal is changed from a predetermined value for each frequency component to obtain the transmission signal Frequency change function,
A sampling frequency restoration function for restoring a sampling frequency to a predetermined value for each frequency component when the transmission signal is received, and removing a folding signal generated at the time of restoration of the sampling frequency;
Is provided.

9, when the BBU 110 and a plurality of RRUs 120 are connected by the PON system 130, the distributed radio communication base station system of the present embodiment connects one BBU 110 and a plurality of RRUs 120, and the BBU 110 PON system 130 that performs RoF transmission using an optical signal between the RRU 120 and the RRU 120;
An OLT (Optical) that is on the BBU side of the PON system 130 and converts the signal format handled by the BBU 110 and the signal format that can be transmitted by the PON system 130 to control transmission timing to avoid collision of optical signals in the PON system 130 Line Terminal) function 140;
An ONU (Optical Network) that is on the RRU side of the PON system 130, mutually converts the signal format handled by the RRU 120 and the signal format that can be transmitted by the PON system 130, and transmits an upstream optical signal at a timing instructed by the OLT function 140. Unit) function 150;
Is provided.

  For example, when a TDM-PON system such as GE-PON (IEEE802.3ah), 10G-EPON (IEEE802.3av), etc. is applied as the PON system 130, the OLT function 140 is output from the BBU 110 in the downlink. It includes a function of mapping IQ data to an Ethernet (registered trademark) frame and transmitting it at a predetermined timing, and a function of extracting IQ data from an Ethernet (registered trademark) frame received in the uplink. On the other hand, the ONU function 150 is a function for extracting IQ data from the Ethernet (registered trademark) frame received in the downlink, or mapping IQ data output from the RRU 120 in the uplink to the Ethernet (registered trademark) frame to obtain a predetermined value. Includes a function to transmit at timing.

  In FIG. 9, the distributed wireless communication base station system in which the BBU 110 has the OLT function 140 and the RRU 120 has the ONU function 150 has been described. However, the present embodiment is described using the existing BBU / RRU / OLT / ONU. You may implement. In this case, an adapter (not shown) is connected between the BBU 110 and the OLT (not shown) and between the RRU 120 and the ONU (not shown), and the OLT-ONU is connected by the PON system 130.

  The function of the adapter between the BBU and the OLT includes a function of converting a downstream optical signal output from the BBU 110 into a signal in a format that can be recognized by the input interface of the OLT, and a format in which the input interface of the BBU 110 can recognize an upstream signal output from the OLT. The function to convert to an optical signal.

  On the other hand, the ONU-RRU adapter functions include a function for converting a downstream signal output from the ONU into an optical signal in a format that can be recognized by the input interface of the RRU 120, and an upstream optical signal output from the RRU 120 by the ONU input interface. Includes the ability to convert the signal into a recognizable format.

  FIG. 1 is a diagram illustrating an example of the configuration of an RRU provided in the distributed radio communication base station system according to the present embodiment.

The RRU has an antenna 11 for transmitting / receiving radio signals, a transmission / reception switching unit 12 for switching between transmission / reception, and an amplifier 21 that amplifies the signal power of the received radio signals to a level that can be handled by signal processing for uplink. A down-conversion unit 22 that down-converts the radio signal, an A / D conversion unit 23 that converts the down-converted analog signal into IQ data of a digital signal, and a radio band from a control signal included in the transmission signal from the BBU A radio band allocation information (upstream) extraction unit 169b that extracts information, a filter bank unit (upstream, RRU) 169c that performs a filtering process on IQ data based on the radio band information and reduces sampling frequency f _s , IQ A frame converter 25 that multiplexes data and control signals, and converts electrical signals into optical signals and transmits them. E / O converter 26 is provided. The radio band allocation information (upstream) extraction unit 169 b and the filter bank unit (upstream, RRU) 169 c correspond to the sampling frequency change function 169.

  The RRU has an O / E conversion unit 31 that converts an optical signal received from a BBU into an electrical signal, a frame conversion unit 32 that extracts a control signal and IQ data from the received signal, and a radio band from the control signal for downlink. A wireless band allocation information (downlink) extraction unit 168b that extracts allocation information, recognizes the original sampling frequency based on the extracted wireless band allocation information, returns the sampling frequency reduced by BBU to the original value, and performs IQ data A filter bank unit (downstream, RRU) 168c that performs filtering on the D / A conversion unit 34 that converts IQ data into an analog signal, an up-conversion unit 35 that up-converts the analog signal, and the power of the radio signal Has an amplifier 36. The radio band allocation information (downlink) extraction unit 168 b and the filter bank unit (downlink, RRU) 168 c correspond to the sampling frequency restoration function 168.

Unlike the related art, the RRU calculates and changes the sampling frequency f _s and the filter coefficient based on the radio band allocation information received from the BBU.

FIG. 2 is a diagram for explaining the configuration of the filter bank unit (upstream, RRU) 169c. In the uplink, the filter bank unit (uplink, RRU) 169c divides it into a plurality of frequency components based on the radio band allocation information received by the radio band allocation information (uplink) extraction unit 169b. Specifically, a filter coefficient that extracts only the signal of the necessary frequency component is calculated by the filter coefficient determination unit 169c2, and the filter coefficient of each filter 169c1 is changed. _'Determines the sampling frequency determination unit 169C3, the sampling frequency of the IQ data at a sampling frequency converting unit 169c4 from f _s f _s' can reduce the sampling frequency f _s for each frequency component as described later output by changing the To do. The signals for each frequency component are multiplexed by the data multiplexing unit 169c5 and output. As the multiplexing method, time multiplexing or the like is used.

FIG. 3 is a diagram illustrating the configuration of the filter bank unit (downstream, RRU) 168c. In the downlink, the filter bank unit (downlink, RRU) 168c separates the input signal for each frequency component by the data separation unit 168c5. Then, based on the radio band allocation information received by the radio band allocation information (downlink) extracting unit 168b, the sampling frequency determining unit 168c3 calculates the reduced sampling frequency f _s ′ of each frequency component, and the sampling frequency restoring unit 168c4. in the output back to the original sampling frequency f _s. Further, the filter coefficient determination unit 169c2 grasps the frequency component of each signal based on the radio band allocation information received by the radio band allocation information (downlink) extraction unit 168b and changes the filter coefficient of each filter 168c1. The signal output from each sampling frequency restoration unit 168c4 includes a folded signal because data obtained by reducing the sampling frequency is restored to the original sampling frequency. Each filter 168c1 transmits only the desired signal and removes the folded signal.
The original sampling frequency f _s is known for BBU and RRU. If the sampling frequency determination method based on the radio band allocation information is unified for the BBU and RRU, the BBU and RRU that have received the same radio band allocation information should divide the radio signal, It can be known what the reduced sampling frequency f _s ′ is.

Next, a method for dividing a radio signal performed by the filter bank unit (upstream, RRU) 169c into a plurality of frequency components will be described.
i) Based on the minimum scheduling unit of the base station.
For example, in LTE of FIG. 12, the minimum scheduling unit is 180 kHz. That is, it is divided into 110 frequency components for each maximum RB. Further, the division unit may be an integral multiple of RB (360 KHz, 540 KHz, 720 KHz,...) According to the status of unused RBs and allocated RBs. Note that the filter bank unit (upstream, RRU) 169c can change the division form for each minimum period (0.5 ms) of radio band allocation.
ii) A value obtained by dividing an available frequency bandwidth by an integer.
When the available frequency bandwidth is f _ava , the frequency band is divided into f _ava / n (n = 1, 2,...) And _used as frequency components. For example, if f _ava = 18 MHz, the division unit may be n = 10 at every 1.8 MHz for a certain time, and the division unit may be every 180 KHz at n = 100 at other times.
iii) For each radio band assigned to the radio terminal.
A wireless band is continuously assigned to one wireless terminal. Therefore, the division unit can be set for each assigned radio band. In this case, it is not divided uniformly. Moreover, the radio band allocated for every time changes according to the communication status of the radio terminal.
iv) Every continuous radio band.
As one of the chunks frequency interval has continuously following signal f _th, it divides the signal frequency interval is separated more than f _th as another signal. Here, it is assumed that there are two radio signals, they are present apart frequency interval f _t. The filter has a pass band / transition band / stop band. When one signal is extracted by filtering processing, the power of the other signal component can be suppressed in the stop band if the transition band is _ft or less. If the transition band is f _t or more, the signal component extracted by the filtering process, the other signal component power will be included without being suppressed. Therefore, f _th is determined in consideration of the filter f _{t so} that the quality of the divided signal does not deteriorate.

A method for determining a sampling frequency f _s ′ that can be reduced by each frequency component performed by the filter bank unit (upstream, RRU) 169c will be described.
a) It determines so that signal quality may not deteriorate by radio | wireless communication between a base station and a radio | wireless terminal.
The filter bank unit (upstream, RRU) 169c changes the sampling frequency f _s ′ so that the influence of the return signal of one divided signal on other divided signals is equal to or lower than a preset allowable value. The wireless communication base station system has a standard such as total noise that is allowed in advance for wireless communication between a base station and a wireless terminal (see Non-Patent Document 2). When the sampling frequency is reduced by the filter bank unit (upstream, RRU) 169c, noise exceeds the standard at a certain sampling frequency. Therefore, the filter bank unit (upstream, RRU) 169c reduces the sampling frequency to such a level that the noise does not exceed the standard (may have a slight margin).
b) Determined according to the band included in the frequency component.
The filter bank unit (upstream, RRU) 169c changes the sampling frequency based on the band included in the frequency component obtained by dividing the radio band. For example, in the LTE of FIG. 10, when the frequency component width is 540 KHz (for RB × 3), if three allocated RBs are included in the frequency component, the sampling frequency is not reduced. If two or one allocation RB is included in the component, the sampling frequency is halved. The sampling frequency may be set to 1/4 or 1/8 depending on the width of the frequency component and the number of assigned RBs.
Note that the sampling frequency may be set to zero so that only unused RB frequency components are sampled.
c) Decide so that the folding signal and the desired signal do not overlap on the frequency axis.
FIG. 14 illustrates a case where the folding signal and the desired signal overlap. On the transmission side, a radio band is set for every four blocks on the frequency axis. In the related art, since there is no change in the sampling frequency, a signal on every four blocks is similarly received on the receiving side. On the other hand, when the sampling frequency is lowered, a return signal is generated when the sampling frequency is restored on the receiving side. At this time, the desired signal component and the aliasing signal overlap depending on the lowered sampling frequency, and the receiving side cannot receive the desired signal. Therefore, the sampling frequency determination unit 169c3 of this embodiment reduces the sampling frequency to the minimum frequency at which the aliasing signal and the desired signal do not overlap on the frequency axis.

  The sampling frequency conversion unit 169c4 is realized by thinning out bit sequence data output from the A / D conversion unit 23 as shown in FIG. The sampling frequency converter 169c4 can also be realized by down-sampling while applying a LPF (Low Pass Filter) using a decimation filter, or by averaging or adding a plurality of bits to convert them to 1 bit and down-sampling. . On the other hand, the sampling frequency restoration unit 168c4 is realized by complementing 0 to the input bit sequence data.

  FIG. 4 is a diagram for explaining an example of the device configuration of a BBU provided in the distributed radio communication base station system of the present embodiment.

  The BBU is an O / E converter 41 that converts an optical signal into an electric signal for uplink, a frame converter 42 that extracts a control signal and IQ data from a received signal, and original sampling based on radio band allocation information. A filter bank unit (upstream, BBU) 172c that recognizes the frequency and returns the sampling frequency reduced by RRU to the original value and performs filtering on IQ data, and a modem unit 43 that demodulates IQ data Have The filter bank unit (upstream, BBU) 172 c corresponds to the sampling frequency restoration function 172.

Based on the radio band information, the BBU is based on the radio band information because of the downlink, the modulation / demodulation unit 43 that outputs IQ data of the modulation signal, the control signal creation unit 50 that multiplexes radio band allocation information and other control information, and creates a control signal. Filtering the IQ data to reduce the sampling frequency f _s , a filter bank unit (downstream, BBU) 173c, a frame conversion unit 51 for multiplexing the IQ data and the control signal, and converting the electrical signal into an optical signal And an E / O converter 52 for transmission. The filter bank unit (downstream, BBU) 173 c corresponds to the sampling frequency changing function 173.

Unlike the related art, the BBU calculates and changes f _s and the filter coefficient based on the radio band allocation information, and transmits the radio band allocation information to the RRU as control information.

FIG. 5 is a diagram illustrating the configuration of the filter bank unit (downstream, BBU) 173c. In the downlink, the filter bank unit (downlink, BBU) 173c calculates, based on the radio band allocation information, a filter coefficient that extracts only the signal of the necessary frequency component by the filter coefficient determination unit 173c2, and the filter of each filter 173c1 Change the coefficient. Further, the _{f s} required for each frequency component determined by the sampling frequency determination unit 173C3, and outputs the sampling frequency of the IQ data at a sampling frequency conversion unit 173c4 changed from _{f s} to _{f s'.} The signals for each frequency component are multiplexed by the data multiplexing unit 173c5 and output.

FIG. 6 is a diagram for explaining the configuration of the filter bank unit (upstream, BBU) 172c. In the uplink, the filter bank unit (uplink, BBU) 172c separates the input signal for each frequency component by the data separation unit 172c5. Then, based on the radio band allocation information, the sampling frequency f _s ′ of each reduced frequency component is calculated by the sampling frequency determining unit 172c3, and returned to the original sampling frequency f _s by the sampling frequency restoring unit 172c4 and output. . Further, the filter coefficient determination unit 172c2 grasps the frequency component of each signal based on the radio band allocation information and changes the filter coefficient of each filter 172c1. The signal output from each sampling frequency restoration unit 172c4 includes a folded signal because data obtained by reducing the sampling frequency is restored to the original sampling frequency. Each filter 172c1 transmits only the true signal and removes the folded signal.

The method of dividing the radio signal performed by the filter bank unit (downstream, BBU) 173c into a plurality of frequency components is the same as the description of the filter bank unit (upstream, RRU) 169c. Further, the method for determining the sampling frequency f _s ′ required for each frequency component performed in the filter bank unit (downstream, BBU) 173c is the same as the description of the filter bank unit (upstream, RRU) 169c.

FIG. 7 is a diagram for explaining a downlink operation method in the distributed radio communication base station system of the present embodiment. The BBU first divides a radio signal into a plurality of frequency components through a filter bank unit (downstream, BBU) 173c. Each frequency component divides a signal into, for example, consecutively assigned radio bands. The sampling frequency conversion unit 173c4 sets the sampling frequency f _s to, for example, 1/4 sampling frequency f _s ′. When the sampling frequency restoration unit 168c4 of the RRU returns the sampling frequency from f _s ′ to the original f _s , a folding signal is generated. Therefore, the signal of each frequency component is subjected to filtering processing by the RRU filter 168c1, and only the desired signal component is extracted, added, and output to the D / A converter 34.

FIG. 8 is a diagram illustrating an uplink operation method in the distributed radio communication base station system according to the present embodiment. The RRU performs a filtering process on the received radio signal by a filter bank unit (upstream, RRU) 169c, and divides the signal for each desired frequency component. Then perform transmission at a sampling frequency converting unit 169c4 to BBU sampling frequency _{f s,} for example, as a quarter of the sampling frequency _{f s'.} When the sampling frequency restoration unit 172c4 of the BBU returns the sampling frequency from f _s ′ to the original f _s , a folding signal is generated. Accordingly, the signal of each frequency component is subjected to filtering processing by the BBU fill 172 c 1, and only the desired frequency component is extracted, added, and output to the modem unit 43.

  Note that a radio signal received by the RRH may include a radio signal from a radio terminal included in another cell. Such a radio signal is described as “unnecessary wave” in FIG. Unnecessary waves can be removed by the filter bank unit (upstream, RRU) 169c.

  Alternatively, the filter bank unit (upstream, RRU) 169c may be the subsequent stage of the frame conversion unit 25, and the filter bank unit (upstream, BBU) 172c may be the previous stage of the frame conversion unit 42. Similarly, the filter bank unit (downstream, BBU) 173c may be the subsequent stage of the frame conversion unit 51, and the filter bank unit (downstream, RRU) 168c may be the previous stage of the frame conversion unit 32.

  Furthermore, the filter bank (168c, 169c), the E / O conversion unit 26, and the O / E conversion unit 31 may be an adapter having one housing, and may be connected to the RRU frame conversion unit (25, 32). . Similarly, the filter bank (172c2, 173c2), the O / E conversion unit 41, and the E / O conversion unit 52 may be an adapter having one housing, and may be connected to the BBU frame conversion unit (42, 51). . The distributed wireless communication base station system of this embodiment can be realized without modifying existing BBUs or RRUs.

The following is a summary of the distributed wireless communication base station system of this embodiment.
<Issues>
In the related art, since the sampling frequency of RRU is always constant, there is a possibility that A / D conversion is performed at a sampling frequency higher than necessary with respect to the frequency bandwidth of the radio signal.
<Solution>
By dividing the radio signal into frequency components based on the radio band allocation information and reducing the sampling frequency of a signal with a relatively small radio band allocation, the band required for digital RoF transmission between BBU and RRU is reduced.
<Effect>
According to the present invention, since the sampling frequency can be reduced according to the allocation state of the radio band, the necessary band between BBU and RRU can be reduced.

  The structure of the present invention is not limited to FIG. 9 and can be applied when a BBU accommodates one or more RRUs.

11: Antenna 12: Transmission / reception switching unit 21: Amplifier 22: Down-conversion unit 23: A / D conversion unit 24: Baseband filter unit (upstream)
25: Frame conversion unit 26: E / O conversion unit 31: O / E conversion unit 32: Frame conversion unit 33: Baseband filter unit (downlink)
34: D / A trunk 35: Up-converter 36: Amplifier 41: O / E converter 42: Frame converter 43: Modulator / demodulator 50: Control signal generator 51: Frame converter 52: E / O converter 101 : Mobile terminal 110: BBU
120: RRU
130: PON system 140: OLT function 150: ONU function 168: Sampling period restoration function 168b: Radio band allocation information (downlink) extraction section 168c: Filter bank section (downlink, RRU)
168c1: Filter 168c2: Filter coefficient determination unit 168c3: Sampling frequency determination unit 168c4: Sampling frequency restoration unit 168c5: Data separation unit 169: Sampling frequency variable function 169b: Radio band allocation information (upstream) extraction unit 169c: Filter bank unit (upstream) , RRU)
169c1: Filter 169c2: Filter coefficient determination unit 169c3: Sampling frequency determination unit 169c4: Sampling frequency conversion unit 169c5: Data multiplexing unit 172: Sampling period restoration function 172c: Filter bank unit (upstream, BBU)
172c1: Filter 172c2: Filter coefficient determination unit 172c3: Sampling frequency determination unit 172c4: Sampling frequency restoration unit 172c5: Data separation unit 173: Sampling cycle variable function 173c: Filter bank unit (downstream, BBU)
173c1: Filter 173c2: Filter coefficient determination unit 173c3: Sampling frequency determination unit 173c4: Sampling frequency conversion unit 173c5: Data multiplexing unit 301: Distributed wireless communication base station system

Claims (8)

A distributed radio communication base station system in which the function of a base station for transmitting and receiving radio signals to and from a radio terminal is divided into a signal processing device (BBU: Base Band Unit) and a radio device (RRU: Remote Radio Unit),
An optical fiber connecting the BBU and the RRU, and transmitting a transmission signal between the BBU and the RRU as an optical signal by RoF (Radio over Fiber);
Based on the radio band information of the wireless signal, and the transmission signal is divided into divided signals of a plurality of frequency components, the divided signal sampling frequency changing function to change from a predetermined value the sampling frequency for each of the frequency components of,
A sampling frequency restoration function for restoring a sampling frequency to a predetermined value for each frequency component when the transmission signal is received, and removing a folding signal generated at the time of restoration of the sampling frequency;
A distributed wireless communication base station system comprising: The sampling frequency changing function is
2. The distributed radio communication base station system according to claim 1, wherein the sampling frequency is changed to a sampling frequency at which an influence of a folded signal of one of the divided signals on another divided signal is equal to or less than a preset allowable value. .   The distributed radio communication base station system according to claim 1 or 2, wherein the sampling frequency changing function changes a sampling frequency according to a band included in the frequency component. The sampling frequency changing function is
4. The distributed radio communication base station system according to claim 1, wherein when there is an unused frequency component, a sampling frequency of the frequency component is set to zero. 5. The optical fiber is a PON (Passive Optical Network) system that connects one BBU and a plurality of RRUs,
OLT on the BBU side of the PON system, which converts the signal format handled by the BBU and the signal format that can be transmitted by the PON system, and controls transmission timing to avoid collision of optical signals in the PON system (Optical Line Terminal) function,
An ONU (Optical) that is on the RRU side of the PON system, converts the signal format handled by the RRU and the signal format that can be transmitted by the PON system, and transmits an upstream optical signal at a timing instructed by the OLT function. (Network Unit) function,
The distributed wireless communication base station system according to claim 1, further comprising:   The signal processing apparatus with which the distributed radio | wireless communication base station system in any one of Claim 1 to 5 is provided.   A wireless device provided in the distributed wireless communication base station system according to claim 1. An operation method of a distributed radio communication base station in which a function of a base station that transmits and receives radio signals to and from a radio terminal is divided into BBU and RRU,
When the BBU and the RRU are connected by an optical fiber, and a transmission signal between the BBU and the RRU is RoF-transmitted as an optical signal,
Based on the radio band information of the wireless signal, and dividing the transmission signal into division signals of a plurality of frequency components, and the sampling frequency change procedure to change from a predetermined value the sampling frequency of the divided signal for each of the frequency components,
A sampling frequency restoration procedure for restoring a sampling frequency to a predetermined value for each frequency component when the transmission signal is received, and removing a folding signal generated when the sampling frequency is restored;
A method for operating a distributed radio communication base station system, characterized in that:

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