JP6515931B2 - Radio base station apparatus, base station cell processing resource allocation method and program - Google Patents

Description

  The present invention relates to a radio base station apparatus, a base station cell processing resource allocation method, and a base station cell processing resource allocation program. In particular, in order to reduce the power consumption of a wireless base station device, a wireless base station device, base station cell, which consolidates baseband signal processing units (BB units) for a plurality of base stations and efficiently shares processing resources Method of processing resource allocation and non-transitory computer readable medium storing base station cell processing resource allocation program

  Data traffic of mobile communication is explosively increasing due to the rapid spread of smartphones and tablet terminals in recent years. In order to cope with the future traffic explosion, 3.5 GHz band as a frequency band for 4G (4th Generation) such as LTE (Long Term Evolution)-Advanced etc at the 2007 World Radio Conference (WRC-07) It is expected that international agreement will be obtained by securing and these new frequency bands will be allocated for 4G. Also, as a measure to increase the traffic capacity of the entire system, heterogeneous network configuration where multiple small cell base stations are installed in the area of conventional macro cell base stations, high density installation of small cell base stations, etc. are considered. ing.

  The traffic of each wireless base station fluctuates with time depending on the installation location. For example, in the office area, traffic peaks in the daytime, which is working hours, but in the residential area, traffic peaks in the evening to night after returning home. However, in any area, traffic also decreases at midnight. Here, in the case of the existing wireless communication system, processing resources for wireless communication that are matched to the peaks of the respective areas are implemented for each base station, and even in the situation where traffic decreases, all the The processing resources for wireless communication of the base station operate independently of one another, consuming power in vain.

  Therefore, in order to cope with the traffic explosion, the processing resources of the wireless communication processing unit such as baseband signal processing for a plurality of base stations will be provided in one wireless base station towards the time of high density installation of the small cell base stations in the future. An architecture called C-RAN (Cloud Radio Access Network) or BB-Pooling (Baseband Pooling) is proposed.

  The concept of the C-RAN architecture enables cost reduction and power consumption reduction of wireless base station devices by efficiently sharing resources among a plurality of base stations with processing resources of an integrated wireless communication processing unit. Technology. That is, in the C-RAN architecture, the radio communication processing of a plurality of base stations is centralized in one radio base station apparatus separately disposed as a parent station, and ideally, traffic for all base station areas It is possible to reduce the size of the device and reduce the cost by implementing processing resources adjusted to the peak in an averaged form. In addition, resource sharing makes it possible to dramatically reduce the number of processing resources operated at low traffic, and also enables to reduce power consumption.

  Here, in order to realize the C-RAN architecture efficiently, the number of baseband cards and the number of baseband cards that operate and share computing units (processing resources) consolidated according to fluctuations in communication traffic of each base station. Overall architecture configuration technology and processing resource allocation technology that reduce the number of devices as much as possible are important issues. In addition, as another problem, it is also important to construct a highly scalable device architecture in which the radio base station device can be gradually enhanced with respect to gradually increasing traffic.

  With regard to the overall architecture and processing resource allocation technology for the conventional radio base station apparatus, for example, Japanese Patent Application Laid-Open No. 2011-101104 "Radio base station apparatus and radio base station apparatus control method" of Patent document 1; 2012-257110 "Distributed antenna system, distributed antenna allocation method, base station apparatus", Japanese Patent Laid-Open No. 2005-117579 "patent document 3" "radio transmitter, radio receiver, mobile communication system and radio resource control method", As disclosed in "BBU-RRH Switching Schemes for Centralized RAN" of KDDI R & D Labs, Non-Patent Document 1, and "BBU-RRH Switching Method in Centralized RAN" of KDDI R & D Labs, Non-Patent Document 2, etc. Prior art has been proposed.

  For example, in the prior art disclosed in Patent Document 1 and the like, a technique is proposed in the radio base station apparatus to control the number of active baseband cards. That is, the radio base station apparatus has a plurality of baseband cards, and includes measurement units for each resource usage, and a control unit that performs resource accommodation of each baseband card based on the resource usage. ing. Also, the accommodation is performed in consideration of a card capable of accommodating both the existing service and the HS (High Speed) service, and a card that can accommodate only the existing service but can not accommodate the HS service.

  However, in the case of the prior art such as Patent Document 1, the connection between all baseband cards and all base station cell radio units is all combinations (“number of baseband cards × number of base station radio cells”). It is premised that it can be freely switched by the proportional combination number), and there is a problem that the circuit configuration of the connection switching unit becomes large and complicated. Also, when trying to extend the baseband card or the base station cell radio unit of the wireless base station device, even if extension is performed to add any one, it is possible to connect to all of the opposite side. Is required, and it is necessary to replace the already implemented connection switching unit with the connection switching unit according to the number of new baseband cards and the number of base station cell radio units, and the problem of low expandability There is also.

  Next, in the prior art disclosed in Non-Patent Document 1 etc., BBU (Base Band Unit: Baseband Signal Processing Card, ie, signal processing card for baseband signal) and RRH (Remote Radio Head: Remote Radio Head: As switching methods between radio resources, two types of switching methods have been proposed: quasi-static switching methods that follow long-term traffic changes, and dynamic switching methods that follow short-term traffic changes. There is.

  However, for the connection between the BBU and the RRH, it is a premise of the two types of switching methods that it is possible to connect in all combinations using switches. Therefore, it is necessary to provide a switch proportional to "the number of BBUs × the number of RRHs" as in the prior art of the patent document 1 etc., and the configuration of the switches becomes complicated. Along with this, when the BBU is also enhanced, it is necessary to entirely replace / expand the existing switch with a switch taking into account the number of new BBUs and the number of RRHs, and there is a problem that the extensibility is low. That is, although the extensibility of the BBU and the RRH itself is considered, the extensibility of the switch, that is, the connection switching unit is not considered.

  If a switch that does not realize connection by all combinations is used, a desired effect can not be obtained by the switching method proposed in Non-Patent Document 1 or the like. That is, since it is not possible to connect all BBUs and RRHs, there arises a problem that a case occurs in which desired processing resource sharing can not be realized.

  In the prior art disclosed in Patent Document 2 and Patent Document 3 etc., the connection state between a plurality of baseband units (BBUs) and a plurality of radio resources (RRHs), and between BBU processing resources and user data. There has been proposed a technique for switching the connection between the two using a switch or a buffer. Also in this case, it is assumed that the switches described in Patent Document 2 and the interconnections between the buffers described in Patent Document 3 can realize connection of all combinations, and they are expanded. There is a problem that it is necessary to change the entire switch and the entire buffer interconnection network.

JP, 2011-101104, A (page 5-8) JP, 2012-257110, A (page 14-16) JP-A-2005-117579 (pages 16-20)

"BBU-RRH Switching Schemes for Centralized RAN", KDDI Lab, 2012 CHINACOM, pp. 762 to 766 "BBU-RRH switching method in Centralized RAN", KDDI R & D Lab., Shingaku Technical Report RCS 2012-250 (2013-1)

  The problems in the present invention will be described below. Generally, processing resources are achieved by aggregating baseband signal processing for a plurality of base station cells (RRU: Remote Radio Unit remote radio unit) with one or more baseband signal processing units (BBU: Base Band Unit baseband unit). Connection to perform connection switching between BBUs and RRUs in order to share processing resources efficiently so that the number of operating BBUs becomes as small as possible in order to reduce power consumption. A switching unit is used.

  The problem in the present invention is that, as in the prior art described above, when a connection switching unit capable of connecting between all BBUs and all RRUs is implemented, it is like a general switch or buffer-to-buffer interconnection network. In the case of such a connection switching unit, the circuit scale of the connection switching unit is proportional to "the number of BBUs × the number of RRUs" or the like, so that the circuit configuration of the connection switching unit becomes enormous.

  Also, when the RRU or BBU is increased in module units as traffic increases, the connection switching unit can not be linearly expanded for the same reason. That is, it is necessary to replace / change the whole connection switching unit nonlinearly depending on the number of existing BBUs and the number of RRUs, and there is a problem that the extensibility is low.

  On the other hand, if a connection switching unit is used to limit the combination of connections between BBU and RRU, then, in the processing resource allocation method proposed in the prior art, BBU and RRU As a result of combinations that can not be connected among them, there arises a problem that sharing of desired processing resources can not be realized.

(Object of the present invention)
The present invention has been made in view of the above circumstances, and is a connection switching that performs connection switching between a plurality of base station cells (RRU) and one or more baseband signal processing units (BBUs) consolidated. When expanding the RRU or BBU, the control unit can expand linearly similarly to the RRU or BBU, and further, even when using the connection switching control unit that can expand linearly, the BBU and RRU A radio base station apparatus capable of achieving the effect of reducing power consumption by processing resource sharing equivalent to the case of using a connection switching control unit realizing all connection combinations between The purpose is to provide a base station cell processing resource allocation program.

  In order to solve the above-mentioned problems, the radio base station apparatus, base station cell processing resource allocation method and base station cell processing resource allocation program according to the present invention mainly adopt the following characteristic configurations.

  (1) A radio base station apparatus according to the present invention is a radio base station apparatus for aggregating radio communication processing for a plurality of base station cells, and a baseband processing pool for integrating and accommodating one or more baseband signal processing modules. And a processing resource assignment control unit for assigning processing resources of each base station cell to each of the baseband signal processing modules, and a connection for switching connection between the baseband signal processing module and the base station cell. A switching control unit, and the connection switching control unit includes one or more connection switching modules, and each of the connection switching modules is one or more adjacent to each other predetermined for each of the base station cells To connect to any one of the baseband signal processing modules of A baseband signal processing module input / output interface connected to a band signal processing module, and a base station cell input / output interface connected to the base station cell, and between one or more adjacent connection switching modules And an interconnect input / output interface for interconnecting the two.

  (2) The base station cell processing resource allocation method according to the present invention is a base station cell processing resource allocation method in a radio base station apparatus that aggregates radio communication processing for a plurality of base station cells, and is aggregated into a baseband processing pool. , And each base station cell can be connected to one or more baseband signals processing modules that can be connected to each other, each base station cell being adjacent to one or more predetermined ones. Prior to the operation of performing processing resource allocation control of each base station cell with respect to each of the baseband signal processing modules by limiting to any one of the baseband signal processing modules to be Base band signal processing module trying to set operation to OFF state Characterized by preset Le candidate.

  (3) The base station cell processing resource allocation program according to the present invention is characterized in that the base station cell processing resource allocation method according to (2) is implemented as a program that can be executed by a computer. .

  According to the radio base station apparatus, the base station cell processing resource allocation method and the base station cell processing resource allocation program of the present invention, the following effects can be obtained.

  The first effect is that, in a wireless base station device that consolidates wireless communication processing for a plurality of base station cells (RRUs), the circuit scale of the connection switching control unit is reduced to reduce the device size and power consumption. Can be realized.

  The reason is that, in the radio base station apparatus according to the present invention, as the connection switching control unit, a connection switching module in which the connection between the base station cell (RRU) and the baseband signal processing module (baseband signal processing card: BBU) is limited. Are connected in series, so that the circuit compared to a conventional connection switching unit that realizes all ideal connection combinations between a base station cell (RRU) and a baseband signal processing module (BBU). This is because the scale can be significantly reduced.

  The second effect is that, in a wireless base station apparatus that consolidates wireless communication processing for a plurality of base station cells (RRUs), when attempting to expand the apparatus to cope with traffic increase etc. Not only RRU) and baseband signal processing module (Baseband signal processing card: BBU) but also connection switching module of connection switching control unit can be linearly expanded as much as necessary, and extensibility Improve.

  The reason is that, in the radio base station apparatus of the present invention, the connection switching control unit restricts the connection between the base station cell (RRU) and the baseband signal processing module (BBU), and mutually connects with the adjacent connection switching module. Since a plurality of connection switching modules provided with connection interfaces are arranged side by side and connected, the connection switching module is also extended, for example, like the base station cell (RRU) or the baseband signal processing module (BBU). The reason is that linear expansion may be performed according to the number.

  The third effect is an ideal connection switching even in the case of using a connection switching control unit with connection restriction in a wireless base station apparatus that aggregates wireless communication processing for a plurality of base station cells (RRUs) It is possible to realize substantially the same processing resource sharing as in the case of using a part, and to obtain almost the same power consumption reduction effect.

  The reason is that in the base station cell processing resource allocation method of the present invention, the baseband signal processing module (BBU) to be turned off (to set the off state) is determined in advance, and the off target is to be turned off. Priority in order from, for example, the baseband signal processing modules (BBUs) distant from the baseband signal processing modules (BBUs) targeted for operation OFF while taking into consideration the information of the baseband signal processing modules (BBUs) Thus, the processing resource allocation control for the baseband signal processing module (BBU) in the operation ON state is performed.

It is a block block diagram which shows the example of whole structure of the wireless base station apparatus in the 1st Embodiment of this invention. It is a schematic diagram which shows the structural example of the connection switching module in the 1st Embodiment of this invention. It is a connection block diagram which shows the connection structural example of the connection switching module in the 1st Embodiment of this invention. It is a control flowchart for demonstrating an example of the whole processing procedure regarding the processing resource allocation control in the 1st Embodiment of this invention. It is an explanatory view for explaining an example of a mechanism which determines order of a baseband signal processing card (BBU) which wants to carry out operation OFF next in processing resource assignment control in a 1st embodiment of the present invention. 7 shows an example of processing for moving a base station cell (RRU) processing of a baseband signal processing card (BBU) to another baseband signal processing card (BBU) in processing resource allocation control according to the first embodiment of the present invention It is a control flowchart. It is a control flowchart which shows an example of a process which allocates the base station cell (RRU) process of undecided allocation with respect to a baseband signal processing card (BBU) in the processing resource allocation control in the 1st Embodiment of this invention. It is a block block diagram which shows the example of a whole structure of the wireless base station apparatus in the 2nd Embodiment of this invention. It is a schematic diagram which shows the structural example of the connection switching module in the 2nd Embodiment of this invention. An explanatory view for explaining an example of a connection configuration of a connection switching module according to a second embodiment of the present invention and an example of a mechanism for determining the order of baseband signal processing cards (BBUs) desired to be turned off next. is there. It is a block block diagram which shows the example of a whole structure of the wireless base station apparatus in the 3rd Embodiment of this invention. For explaining the problem in the case of using an ideal connection switching unit such as a crossbar type that realizes all connection combinations between a conventional base station cell (RRU) and a baseband signal processing card (BBU) FIG. It is a schematic diagram for demonstrating the processing resource sharing effect of the base station cell processing resource allocation method in embodiment of this invention, and the conventional base station cell processing resource allocation method.

  BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of a radio base station apparatus, a base station cell processing resource allocation method and a base station cell processing resource allocation program according to the present invention will be described below with reference to the attached drawings. In the following description, although the radio base station apparatus and base station cell processing resource allocation method according to the present invention will be described, such a base station cell processing resource allocation method can be executed by a computer as a base station cell processing resource allocation program. It goes without saying that it may be implemented or the base station cell processing resource allocation program may be recorded on a computer readable recording medium. Further, reference numerals in the drawings attached to the following drawings are for convenience added to the respective elements as an example for aiding understanding, and it is needless to say that the present invention is not intended to be limited to the illustrated embodiment. Yes.

(Features of the present invention)
Before describing the embodiments of the present invention, the features of the present invention will first be outlined. The present invention relates to one or more baseband signal processing modules (BBU: Base Band Unit base) in which baseband signal processing (wireless communication processing) for a plurality of base station cells (RRU: Remote Radio Unit) is integrated. In the radio base station apparatus that performs processing resource sharing by using a band signal processing card, as a connection switching unit disposed to perform connection switching between the RRU and the BBU, when expanding the RRU or BBU, Like RRU and BBU, it can be realized with a relatively simple circuit configuration that can be extended linearly, and even if a connection switcher that can extend linearly is used, BBU and RRU Using a conventional connection switching unit that realizes all combinations of connections so that combinations that can not be connected between the two do not occur. The main feature is that low power consumption can be achieved by sharing processing resources as much as possible.

  More specifically, the present invention comprises the following arrangement. That is, in a radio base station apparatus performing baseband signal processing modules (BBUs) in which baseband signal processing (radio communication processing) for a plurality of base station cells (RRUs) is integrated, connection between RRUs and BBUs A connection switching control unit for switching is provided, the connection switching control unit having a configuration in which one or a plurality of connection switching modules that can be limitedly connected to three or more adjacent BBUs are arranged and connected to one another. Is the main feature.

  At the same time, in consideration of the limited connection state as described above, prior to the operation of allocating RRU processing resources to the BBU, it is desirable to turn the operation off (that is, try to set the operation to the off state). The candidate is determined in advance, and thereafter, the processing resource allocation control is preferentially performed in order from the BBU distant from the determined candidate of the BBU in order.

  Then, when the processing resource usage rate of a BBU to which processing allocation has been preferentially performed exceeds a predetermined upper limit value, priority is given in order to RRU processing relating to RRUs located at a position away from the BBU. If the processing resource usage rate of the BBU falls below a predetermined lower limit, the RRU for the RRU whose connection distance from the BBU is close is reversed. It is also a main feature that processing assignment control for the BBU is given priority in order from processing to processing.

  According to the present invention, the following effects can be obtained. The radio base station apparatus according to the present invention extends RRU or BBU by arranging connection switching modules connectable as limited to three or more adjacent BBUs as connection switching control units. Similar to RRU and BBU, the connection switching module can be simply expanded linearly, and a wireless base station apparatus that can be expanded linearly including the connection switching control unit can be realized. .

  Then, while limiting combinations of connections between BBUs and RRUs, in consideration of such constraints, a BBU to be turned off is determined in advance, and a BBU distant from the determined BBUs is Ideal connection switching without limitation of connection by performing processing assignment control in order of priority, and also setting RRU processing assignment control for the target BBU as the processing assignment control method considering the connection distance from the target BBU It is possible to realize processing resource sharing, that is, power consumption reduction substantially equivalent to the case of using a part.

(Embodiment of the present invention)
Next, an embodiment of the present invention will be described in detail with reference to the drawings of FIGS. First, in the first embodiment, baseband signal processing (wireless communication processing) for a plurality of base station cells (RRU: Remote Radio Unit) is performed as an example of the wireless base station apparatus according to the present invention. Or in a plurality of baseband signal processing modules (BBU: Base Band Unit baseband signal processing card) to perform connection switching between RRU and BBU in a radio base station apparatus that shares processing resources The basic configuration and features of the connection switching control unit disposed in the radio base station apparatus, and the operation and features of the base station cell processing resource allocation method will be described in detail. Also, in the second embodiment, a configuration example of a wireless base station apparatus provided with a connection switching module connectable to adjacent five (plurality) baseband signal processing modules (BBUs) as a connection switching control unit. Explain in detail. Furthermore, in the third embodiment, a configuration example of a wireless base station apparatus in which a baseband signal processing module, a base station cell, and a connection switching module are clustered in a predetermined unit will be described in detail.

(Example of Configuration of First Embodiment)
FIG. 1 is a block diagram showing an example of the entire configuration of a radio base station apparatus according to the first embodiment of the present invention, and as a radio base station apparatus, radio signal processing is integrated to share processing resources thereof The example of a whole structure of a base station apparatus is shown.

  A base band processing pool in which radio base station apparatus 100 shown in FIG. 1 integrates and carries out each radio communication process of n (n: natural number) base station cells (RRU: Remote Radio Unit remote radio unit) 11 to 1 n (BBU-pool) 20, and in the baseband processing pool (BBU-pool) 20, k (k: natural number, k ≦ n) baseband signal processing cards (BBU: Base Band Unit baseband signal processing module) ) 21-2k. Each of k (one or more) baseband signal processing cards (BBUs) 21 to 2 k in the baseband processing pool (BBU-pool) 20 is between n base station cells (RRUs) 11 to 1 n. For example, Layer-1 processing (baseband signal processing) of a wireless scheme such as LTE-Advanced is performed while sharing processing resources.

  Each of the k (one or more) baseband signal processing cards (BBUs) 21 to 2 k on the side of the RF (Radio Frequency) unit is connected to the optical fiber or wireless back via the connection switching control unit 30. It is connected to each base station cell (RRU) 11 to 1 n by a hole (front hole) or the like. Here, there is no problem even if the radio scheme processed in the baseband processing pool (BBU-pool) 20 is a radio scheme other than LTE-Advanced, and the layers to be processed are also Layers other than Layer-1. There is no particular problem even with the second grade processing.

  The connection switching control unit 30 includes k connection switching modules 31 to 3 k corresponding to k (one to a plurality of) baseband signal processing cards (BBUs) 21 to 2 k, and k The connection switching modules 31 to 3k are arranged in order, and the adjacent ones are connected to each other. Here, each connection switching module 31 to 3k is a connection between one or more base station cells (RRU) 11 to 1n and one or more baseband signal processing cards (BBU) 21 to 2k, respectively. It is possible to perform the interconnection between adjacent connection switching modules. For example, the i-th (1 ≦ i ≦ k) connection switching module 3i among the k connection switching modules 31 to 3k is the adjacent (i−1) th connection switching module 3 (i-1). And the (i + 1) th connection switching module 3 (i + 1) can be mutually connected.

  Therefore, any base station cell (RRU) connected to the i-th connection switching module 3i among the n base station cells (RRU) 11 to 1 n, for example, the j (1 ≦ j ≦ n) base station The station cell (RRU) 1j is located between the plurality of BBUs adjacent to both sides of the i-th BBU 2i corresponding to the connection switching module 3i to which the RRU 1j is connected, that is, the (i-1) th BBU 2 ( It is possible to switch connections between i-1) and the (i + 1) th BBU 2 (i + 1).

  Further, the radio base station apparatus 100 further includes a processing resource allocation control unit 51 for processing resource allocation control for k baseband signal processing cards (BBUs) 21 to 2 k in the baseband processing pool (BBU-pool) 20, A traffic prediction unit 52, a connection information storage unit 53, and the like are also provided.

  The traffic prediction unit 52 is a part that predicts traffic in the next predetermined period using the past traffic history, database, and the like for processing resource allocation control. Based on the traffic predicted by the traffic prediction unit 52, the processing resource assignment control unit 51 determines the k base signal processing cards (BBUs) 21 to 2 k of n base station cells (RRUs) 11 to 1 n. It is a part which performs processing resource allocation control to. In addition, in the connection information storage unit 53, as the connection information between the base station cells (RRUs) 11 to 1n to which the limited connection is performed and the baseband signal processing cards (BBUs) 21 to 2k, which RRU corresponds to which BBU Connection information indicating whether it is possible to connect to the network, and the processing resource allocation control unit 51 performs processing resource allocation control with reference to connection information of the connection information storage unit 53 as necessary. .

(Description of the operation of the first embodiment)
Next, an example of the operation of the wireless communication return station apparatus 100 shown in FIG. 1 as the first embodiment of the present invention will be described in detail with reference to FIG. 2 to FIG. In each of the k baseband signal processing cards (BBUs) 21 to 2 k in the baseband processing pool (BBU-pool) 20 of the radio base station apparatus 100 shown in FIG. For example, wireless communication processing such as Layer-1 processing (baseband signal processing) such as LTE-Advanced is performed intensively for the base station cells (RRU) 11 to 1 n.

  By sharing processing resources by k baseband signal processing cards (BBUs) 21 to 2 k, processing of each base station cell (RRU) for 11 to 1 n of base station cells (RRU) is performed on k baseband signals Each base station cell (RRU) 11 to 1 n and each baseband signal processing card (BBU) are used to make it variable which baseband signal processing card (BBU) is to be implemented among the processing cards (BBU) 21 to 2 k. The connection switching between 21 and 2 k is performed by the connection switching control unit 30. Each transmission / reception signal switched by the connection switching control unit 30 is connected to the base station cells (RRU) 11 to 1 n in a state of being connected to each other via an optical fiber, a wireless backhaul (front hall) or the like. The signal is transmitted to and received from the band signal processing card (BBU) 21 to 2k.

  Here, the connection switching control unit 30 has a configuration in which the adjacent connection switching modules 31 to 3k are connected to each other so that adjacent connection switching modules can be connected to each other. FIG. 2 is a schematic view showing a configuration example of the connection switching modules 31 to 3k according to the first embodiment of the present invention, and an i-th (1 ≦ i as an example configuration of each of the connection switching modules 31 to 3k. Taking the connection switching module 3i of ≦ k) as an example, a configuration example is shown in which one adjacent connection switching module and one connection switching module can be interconnected.

In the example shown in FIG. 2, an input / output interface for baseband signal processing module (BBU) connecting between one BBU # i and one connection switching module 3i, (at least) RRU # j ₁ , RRU Base band signal processing module (BBU) base station cell (RRU) input / output for connecting between _three RRUs #j ₂ and RRU # j ₃ (1 ≦ j ₁ , j ₂ , j ₃ ≦ k) An example is shown in the case of including an interface and an interconnection input / output interface for interconnecting between the connection switching module 3 (i-1) and the connection switching module 3 (i + 1) adjacent to both sides. For example, (at least) arbitrary 3 RRUs, for example, the j _{1st B} 1 # 1 connected to the connection switching module 3 i, even if the traffic is how large th RRU # _{j 1,} the _{j 2} th RRU # _{j 2,} the wireless communication processes on three RRU of the _{j 3} th _{RRU # j 3 (1 ≦ j} 1, j 2, j 3 ≦ k) The example of composition which assumed the case where it can carry out is shown.

In the configuration example shown in FIG. 2, the connection switching three _RRU which are connected to the module _{3i # j 1, RRU # j} 2, RRU # first 1RRU input interface 1 1 line from _{j 3,} on both sides of the adjacent connection Adjacent connection switching modules 3 (i-1) from both switching modules 3 (i-1) and 3 (i + 1) from two systems RRU # j ₁ , RRU # j ₂ , RRU # j ₃ And 3 (i + 1); and a selection circuit for selecting and arbitrating each input from each of the first RRU input interface 1 and the second RRU input interface 2 (see FIG. 2). Not shown) and the like.

  Although depending on the maximum throughput of each baseband signal processing card (BBU) 21 to 2 k, in the embodiment shown in FIG. 2, up to nine base station cells (RRU) can be used in one BBU, for example, BBU # i. It is possible to connect and process. In FIG. 2, only the flow of signals from the RRU side to the BBU side is illustrated, and the flow of signals in the reverse direction from the BBU side to the RRU side is omitted. However, it should be noted that, in fact, reverse signal flow from the BBU side to the RRU side is also almost the same.

As described above, by connecting a plurality of connection switching modules side by side and connecting them to each other and interconnecting them with one adjacent connection switching module, it is possible to connect any connection switching module, for example, connection switching module #i 3i. A base station cell (RRU), for example, RRU # j ₁ is at least adjacent to a plurality of connection switching modules, eg, BBUs corresponding to the connection switching module #i 3i to which the RRU # j ₁ is connected, eg, BBU # i. It is possible to switch connections between (for example, three in the example of FIG. 2) BBUs, for example, three BBUs of BBU # (i-1), BBU # i, and BBU # (i + 1).

  FIG. 3 is a connection configuration diagram showing a connection configuration example of the connection switching modules 31 to 3k in the first embodiment of the present invention, and for each of the k connection switching modules 31 to 3k shown in FIG. The example of the connection structure between RRU-BBU at the time of using the connection switching module illustrated to these is shown. In the embodiment of FIG. 3, the number k of connection switching modules 31 to 3 k and baseband signal processing cards (BBUs) 21 to 2 k is 4 (k = 4), and the number n of base station cells (RRUs) 11 to 1 n Shows the case of 12 (n = 12).

  Each BBU # 1 to BBU # 4 is basically (assuming a large traffic), each connection switching module # 1 to connection switching module # 4 corresponding to each BBU # 1 to BBU # 4. A case is shown where processing is performed for three RRUs connected to each. That is, BBU # 1 is for three RRUs of RRU # 1 to RRU # 3, BBU # 2 is for three RRUs # 4 to RRU # 6, and BBU # 3 is for RRU # 7 to RRU. The three RRUs of # 9 and the BBU # 4 perform processing of three RRUs of RRU # 10 to RRU # 12, respectively.

  The RRUs # 1 to RRU # 12 are adjacent to each other among the BBUs # 1 to #BBU # 4 of the baseband processing pool (BBU-pool) 20, which are mutually adjacent BBUs predetermined for each RRU # 1 to RRU # 12. It is possible to limit the connection to any one of the above. That is, each RRU # 1 to RRU # 12 is centered on each of BBU # 1 to BBU # 4 connected corresponding to each of connection switching module # 1 to connection switching module # 4 to which each RRU is connected. It is possible to selectively connect to any one of a total of three BBUs, including at least two adjacent BBUs on both sides. For example, in the case of RRU # 4 in FIG. 3, although connected to the connection switching module # 2, BBU # 1 and BBU # 3 adjacent on both sides centering on the corresponding BBU # 2 It is possible to select and connect any of three BBUs (BBU # 1, BBU # 2, BBU # 3).

  Then, for example, when traffic is small, an arbitrary BBU, for example, BBU # 2 among the four BBU # 1 to BBU # 4 centers on the connection switching module # 2 to which the BBU # 2 is correspondingly connected. Up to nine connected to three connection switching modules (connection switching module # 1, connection switching module # 2, connection switching module # 3), including adjacent connection switching module # 1 and connection switching module # 3. The RRU can be connected and processed.

  That is, for example, in the case of BBU # 2, three RRUs # 4 to RRU # 6 connected to the BBU # 2 and the connection switching module # 1 and the connection switching module # 3 on both sides, respectively. It is possible to connect and process up to nine RRUs # 1 to # 9, which are the total of three RRUs # 1 to RRU # 3 and three RRUs # 7 to RRU # 9 connected to is there.

  Next, as shown in FIG. 1, in order to implement processing resource sharing in each BBU, the radio base station apparatus 100 uses k pieces of k based on the traffic prediction result by the traffic prediction unit 52 (traffic prediction function). The processing resource allocation control unit 51 performs processing resource allocation of n base station cells (RRUs) 11 to 1 n to each baseband signal processing card (BBU) 21 to 2 k.

  The traffic prediction unit 52 is configured to store a traffic database (average value of daily traffic for each time interval) in which daily traffic data is stored, and traffic history for the day (every Traffic prediction for the next predetermined time interval is performed for every n base station cells (RRU) 11 to 1 n using the actual value of traffic on the current day for every interval.

  Also, the processing resource allocation control unit 51 determines n base station cells (RRUs) for each of k base band signal processing cards (BBUs) 21 to 2 k based on the traffic predicted by the traffic prediction unit 52. Control of processing resource allocation of 11 to 1 n is performed. The purpose of the processing resource allocation control is to increase the number of BBUs that can be turned off as much as possible by operating only as few BBUs as possible by processing resource sharing in order to realize low power consumption.

  Next, an example of a control method of base station cell processing resource allocation implemented in the processing resource allocation control unit 51 to realize low power consumption will be described with reference to the control flowcharts of FIGS. 4, 6 and 7 and FIG. 5. It demonstrates using explanatory drawing of. FIG. 4 is a control flowchart for explaining an example of the entire processing procedure related to processing resource allocation control in the first embodiment of the present invention.

  In the processing resource allocation control in the first embodiment of the present invention, as shown in the control flowchart of FIG. 4, first, the traffic prediction result by the traffic prediction unit 52 and the k baseband signals at the current point The processing resource allocation control unit 51 next wants to turn off the operation from the operation states of the processing cards (BBUs) 21 to 2 k (that is, try to set the operation to the off state) of the baseband signal processing card (BBU) The order is determined in advance (step S1). When the order of baseband signal processing cards (BBUs) to be turned off is determined, next, the order of baseband signal processing cards (BBUs) that perform processing resource allocation control is also determined in advance (step S2). For example, as the order of baseband signal processing cards (BBUs) that perform processing resource allocation control, priority is given to baseband signal processing cards (BBUs) separated from baseband signal processing cards (BBUs) that you want to turn off next. Set to

  Here, the reason for performing the processes of steps S1 and S2 is that, in the first embodiment of the present invention, the base station cell (RRU) -base band signal is used to improve the expandability of the radio base station apparatus 100. Since connection switching control unit 30 is used to limit a part of connections between processing cards (BBUs), processing resources may be allocated to BBUs that can not be connected from a specific RRU. It is necessary to prevent in advance.

  FIG. 5 shows the baseband signal processing cards (BBUs) 21 to 2k which are desired to be turned off in the processing resource allocation control in the first embodiment of the present invention (that is, to set the operation to the off state). FIG. 10 is an explanatory diagram for describing an example of a mechanism for determining the order, but the detailed process of step S1 of the control flowchart of FIG. 4 (a method of determining a baseband signal processing card (BBU) desired to be turned off next) Not only the mechanism but also a detailed mechanism of the process of step S2 (a method of determining a baseband signal processing card (BBU) that performs processing resource allocation control) is described as an example. In the explanatory diagram of FIG. 5, the number of baseband signal processing cards (BBUs) of the baseband processing pool (BBU-pool) 20 is eight in number of BBU # 1 to BBU # 8, and the corresponding connection switching control unit The number of 30 connection switching modules is also eight, that is, connection switching module # 1 to connection switching module # 8. On the other hand, the number of base station cells (RRUs) of the base station cell radio unit (RRU) 10 is RRU # 1 to RRU # 1. The case where it is set as 24 of RRU # 24 is illustrated.

  In the process of step S1 (the method of determining the baseband signal processing card (BBU) desired to be turned off next), the processing resource assignment control unit 51 basically performs the process according to the traffic volume predicted by the traffic prediction unit 52. Set a baseband signal processing card (BBU) to be turned off (that is, set to turn off the operation) at intervals of a power of 2.

That is, for example, as shown in FIG. 5A, when traffic is large, BBUs that are desired to be turned OFF are set at intervals of 8 (= 2 ³ ) (in the example of FIG. 5, For example, one BBU of BBU # 4 is set among eight BBUs). Further, as shown in FIG. 5B, when the traffic is medium, BBUs to be turned OFF are set at intervals of four (= 2 ² ) (in the case of the example of FIG. 5, Among the eight BBUs, for example, two BBUs of BBU # 4 and BBU # 8 are set). Further, as shown in FIG. 5C, when traffic is small, BBUs to be turned off are set at intervals of 2 (= 2 ¹ ) (8 in the example of FIG. 5). Among the BBUs, for example, four BBUs of BBU # 2, BBU # 4, BBU # 6, and BBU # 8 are set).

  Furthermore, as the operating status of each baseband signal processing card (BBU) at the time of traffic prediction, the BBU operating status (for example, BBU # 4 or other of the 8 BBUs described in “traffic large” in FIG. If any one of the BBUs can realize the operation OFF state, then, for example, BBU # 4 among the eight BBUs described in “in traffic” in FIG. 5B. , And processing resource allocation control aiming at state in which any other two BBUs are turned off at intervals of two or four BBUs # 8. That is, for example, as shown in FIG. 5 (A), when one BBU of BBU # 4 is in the operation OFF state, as shown in “Low” of FIG. 5 (B), Aim to add BBU # 8 to OFF.

  In addition, if the BBU operating state of “during traffic” in FIG. 5B has already been realized as the operating state of the baseband signal processing card (BBU) at the time of traffic prediction, then FIG. BBU operation state (for example, BBU # 2, BBU # 4, BBU # 6, BBU # 8 out of eight BBUs) described in “low traffic” in any of the other four BBUs at intervals of four or two Perform processing resource allocation control with the aim of That is, for example, as shown in FIG. 5 (B), when two BBUs of BBU # 4 and # 8 are in the operation OFF state, as shown in “Low” of FIG. 5 (C), We aim to add BBU # 2 and # 6 to the operation OFF after that.

  Next, a mechanism of the process of step S2 (a method of determining a baseband signal processing card (BBU) which performs processing resource allocation control) will be described with reference to FIG. The processing resource allocation control unit 51 selects a BBU as far away as possible from the BBUs (including the BBUs that are already in the operation OFF state) that they want to turn OFF as the selection order of the baseband signal processing card (BBU) that performs processing resource allocation control. Perform processing resource allocation control in order of priority. Here, when there are a plurality of BBUs for which operation is to be turned off (that is, the operation is to be turned off) and a plurality of BBUs that are already in the operation OFF state, processing resources are sequentially processed from the BBU located in the middle of the corresponding BBU. Perform assignment control.

  For example, it is predicted that the traffic is large in the traffic prediction unit 52, and as described in “traffic large” in FIG. 5A, for example, BBU # 4 out of eight BBUs is determined as the BBU to be turned off next. If the BBU # 4 has already been set to the operation OFF state, as shown by “High 1” in FIG. 5A, the BBU that is most distant from the BBU # 4 in question. Perform processing resource allocation control preferentially in order from # 8. Also, the traffic is predicted to be moderate, and as described in “in traffic” in FIG. 5B, for example, BBU # 4 and BBU # 8 out of the eight BBUs should be turned off as the next BBU. If it is determined, or if BBU # 4 and BBU # 8 have already been set to the operation OFF state, the relevant BBU # 4 and BBU # are displayed as shown in "High 1" of FIG. 5 (B). The processing resource allocation control is preferentially performed in order from BBUs # 2 and # 6 which are BBUs located farthest from 8 in distance, that is, BBUs located between BBUs # 4 and # 8.

  As described in “During traffic” in FIG. 5B, when there are a plurality of BBUs that are desired to be turned off and BBUs that are already in the turned off state, the BBUs separated by a similar distance from the plurality of relevant BBUs. When there are a plurality of BBUs, processing resource allocation control may be preferentially performed in order from any BBU among a plurality of BBUs separated by the same degree. Further, in the case of “traffic large” in FIG. 5A, BBU # 1 and BBU # 7 have a distance from BBU # 4 as a BBU that preferentially performs processing resource allocation control next to BBU # 8. If they are the same, either BBU # 1 or BBU # 7 may be selected as the next priority of BBU # 8.

  Next, returning to the description of the control flowchart of FIG. 4, each step after step S3 will be described. As shown in the control flowchart of FIG. 4, according to the control order of processing resource allocation control of the BBUs determined in step S2, according to the control of the processing resource allocation control as described below Repeat the process. First, with respect to the target BBUs selected in order, the processing resource usage rate is calculated from the traffic prediction values of all RRUs currently allocated, and threshold determination with threshold A, which is a predetermined upper limit, is performed (step S3) . If the processing resource usage rate of the target BBU exceeds the threshold A, which is the upper limit value (Yes in step S3), there is a concern that the processing resources will be insufficient, and the allocation control described in detail in FIG. Process A (proc. A) is executed (step S5) to determine whether any RRU process already assigned to the target BBU can be moved to another BBU, If it is determined that the process can be performed in the above, the process of moving the RRU process to another BBU determined to be processable is executed.

  In addition, when the processing resource usage rate of the target BBU does not exceed the threshold A which is the upper limit (No in step S3), next, threshold determination with the threshold B which is a predetermined lower limit is performed ( Step S4). If the processing resource usage rate of the target BBU is lower than the threshold value B, which is the lower limit (Yes in step S4), there still remains a processing capacity margin that allows other RRU processing to be performed on the target BBU. In order to mean that it means that it is an RRU process that is assigned to BBUs other than the target BBU by executing assignment control process B (proc. B) whose details will be described later with reference to FIG. 7 (step S6) It is determined whether it is possible to process in the target BBU about the RRU process for which the current allocation has not been decided, and if it is determined that the processing is possible, the process of allocating the corresponding RRU process to the target BBU Run.

  Then, in the control flowchart of FIG. 4, the threshold determination process related to the processing resource usage rate of the BBU shown in step S3 to step S6, the process of allocation control process A (proc. A) and the process of allocation control process B (proc. B) The process is repeatedly performed on all the BBUs in order in the order of BBUs determined in step S2, and when the processing resource allocation is determined for all the BBUs, one process resource allocation control is completed.

  Next, details of the process of the assignment control process A (proc. A) described above will be described using the control flowchart of FIG. FIG. 6 is a process of moving a base station cell (RRU) process of a baseband signal processing card (BBU) to another baseband signal processing card (BBU) in the processing resource allocation control according to the first embodiment of the present invention 4 is a control flowchart showing an example of the RRU process assigned to the target BBU when the processing resource usage rate of the target BBU exceeds a threshold A which is a predetermined upper limit value. Among them, one example of the processing content of assignment control processing A (proc. A) for moving any RRU processing to another BBU is shown.

  In the control flowchart shown in FIG. 6, first, the restricted connection function of the connection switching control unit 30 prevents the RRU processing resource allocation control for the RRU to a BBU that can not be connected from any RRU. Among the allocated RRUs, the priority order of the RRUs to be candidates for moving the RRU process is determined (step A1). Here, based on the connection information between RRU and BBU stored in the connection information storage unit 53 shown in FIG. The connection distance of is set in order of priority from the RRU which is far away. Then, according to the priority order determined in step A1, the following RRU process allocation control is repeated until the processing resource usage rate of the target BBU falls below the threshold A, which is the upper limit value.

  First, with regard to the RRU selected according to the priority order, it is determined whether the RRU can be allocated to the BBU already operating around the RRU as the connectable BBU (step A2). When it is possible to allocate the RRU process to the operating BBU around the RRU, that is, even if the RRU process is newly allocated to the operating BBU, the resource usage rate of the operating BBU does not exceed the threshold A which is the upper limit In the case (Yes in step A2), the RRU process is moved to the active BBU around the RRU (step A6).

  On the other hand, if the RRU processing allocation can not be assigned to the operating BBU in the vicinity of the RRU (No in step A2), then the RRU is operated as a connectable BBU at that time in the vicinity of the RRU. It is determined whether or not the RRU process allocation can be made to the BBU for which it has become (step A3). If the RRU process can be allocated to the BBU in the operation OFF state around the RRU (Yes in step A3), the RRU process is moved to the BBU in the operation OFF state around the RRU (that is, the BBU is Set the operation ON) (step A7).

  On the other hand, when the process allocation can not be performed on any of the active and inactive BBUs around the RRU (No in step A3), the connectable BBUs for which the process allocation has not been determined yet Even if the processing resource usage rate exceeds the threshold A, which is the upper limit value, the BRU located closest to the RRU moves the RRU processing (step A4). Here, the process of step A4 is a process for preventing allocation of processing resources to BBUs that can not be connected from any RRU.

  After performing the move process of steps A4, A6, and A7, the process resource usage status of the target BBU as a result of moving the RRU process that was the move candidate to any BBU to which the RRU process can be allocated. Changes, so that the threshold determination processing of comparing the processing resource usage rate of the target BBU with the threshold A, which is a predetermined upper limit value, is performed again (step A5). If the processing resource usage rate of the target BBU still exceeds the threshold A, which is the upper limit value (No in step A5), according to the priority order determined in step A1, according to the other RRU in the next priority order, The processes of steps A2 to A4, A6, and A7 are repeated.

  On the other hand, when the processing resource usage rate of the target BBU is less than or equal to the threshold A (Yes in step A5), the processing resource allocation of the RRU processing is determined for the target BBU (step A8). Complete processing resource allocation control of.

  Next, details of the process of the assignment control process B (proc. B) described above will be described using the control flowchart of FIG. FIG. 7 is a control flowchart showing an example of processing of allocating undecided base station cell (RRU) processing to the baseband signal processing card (BBU) in processing resource allocation control in the first embodiment of the present invention As shown in FIG. 4, if the processing resource usage rate of the target BBU is below the threshold B, which is a predetermined lower limit, any processing allocation for the BBU, including the target BBU, has not yet been determined. It is determined whether or not it is possible to assign any RRU process to the target BBU, and if the assignment is possible, an example of the processing content of the assignment control process B (proc. B) of assigning the RRU process to the target BBU It shows.

  In the control flowchart shown in FIG. 7, first, as in the case of FIG. 6, processing resource allocation control of RRU processing for the RRU to a BBU which can not be connected from any RRU by the limited connection function of the connection switching control unit 30. Among the RRU processes for which the process allocation to the BBU has not yet been determined, including the target BBU, the priority order of the RRU to which the RRU process is to be allocated is determined (step B1). Here, the priority order of RRUs for which RRU processing is a candidate for allocation is determined, for example, from the target BBU based on the connection information between RRU and BBU stored in the connection information storage unit 53 shown in FIG. Set the connection distance in order of priority from the nearest RRU. Then, according to the priority order determined in step B1, the following RRU process allocation control is repeated until the processing resource usage rate of the target BBU exceeds the threshold value B which is the lower limit value.

  First, with regard to the RRUs selected in accordance with the priority order, it is determined whether or not the RRU process allocation can be performed on the target BBU to which the RRU can be connected (step B2). If it is possible to allocate the RRU process to the target BBU, that is, if the resource utilization rate of the target BBU does not exceed the upper limit threshold A even if the RRU process is newly allocated to the target BBU (step Yes in B2) move the RRU process to the target BBU, and allocate the RRU process to the target BBU (step B3).

  Here, even if the RRU process is moved and assigned to the target BBU, if the resource usage rate of the target BBU has not yet reached the threshold B, which is the lower limit, or more (No in step B4), or When the resource usage rate of the target BBU exceeds the upper limit threshold A in step B2 and the RRU processing allocation to the target BBU is not possible (No in step B2), the priority determined in step B1 Thus, the processes in steps B2 to B4 are repeated for the other RRUs that are in the next priority order.

  On the other hand, when the RRU process is moved to the target BBU, the resource usage rate of the target BBU becomes equal to or higher than the threshold B which is the lower limit (No in step B4), or processing resource allocation control for all candidate RRUs. If the RRU processing resource allocation for the target BBU is determined (step B5), the processing resource allocation control for the target BBU is completed.

  As described above in detail, in the first embodiment of the present invention, the connection switching control unit 30 performing connection switching control between RRU and BBU has an interconnection interface between adjacent connection switching modules. One or more connection switching modules 31 to 3k are arranged, and the connection relationship from the RRU is not all baseband signal processing cards (BBUs) 21 to 2k in the baseband processing pool (BBU-pool) 20, By limiting only to the adjacent BBUs, it is possible to prevent an increase in the circuit scale of the connection switching control unit 30.

  That is, in the case of an ideal connection switching control unit that realizes all connection combinations between RRU and BBU, the connection switching control unit needs to have a scale proportional to the multiplication of the number of “RRU number × BBU number”. It becomes. On the other hand, in the first embodiment of the present invention, the scale of the connection switching control unit 30 is limited to a scale proportional to “the number of connected RRUs (9 in the example shown in FIG. 2) × the number of BBUs”. And the connection switching control unit can be reduced to a circuit scale approximately linear to the number of BBUs. Therefore, in the first embodiment of the present invention, when it is intended to enhance RRU or BBU as traffic increases, the connection switching module can also be expanded substantially linearly in accordance with the number of BBUs. The advantage is obtained that high extensibility can be ensured.

  In addition, even in the configuration in which the connection relationship between RRU and BBU is limited as described above in order to improve expandability, it is desirable to set the operation OFF in the first embodiment of the present invention (ie, operation) Base station cell processing resource for performing processing resource allocation control in order of priority from the BBU located at a distance away from the BBU targeted for operation OFF. The assignment method is adopted. Furthermore, in the first embodiment of the present invention, when the processing resource usage rate of the target BBU exceeds the threshold A of the upper limit predetermined in advance, the RRUs located at positions away from the target BBU at the connection distance start from the RRU. The transfer control of RRU processing to another BBU is given priority, and if the processing resource usage rate of the target BBU falls below a predetermined lower limit threshold B, the connection distance is closer to the target BBU. A base station cell processing resource allocation method is adopted in which RRU processing transfer control is preferentially performed in order from a certain RRU.

  Thus, even in the configuration in which the connection relationship between RRU and BBU is limited, almost the same as using the ideal connection switching control unit capable of connecting RRU and BBU in all connection combinations. The advantage of being able to realize processing resource sharing (as well as low power consumption) is obtained. The reason is that, as a base station cell processing resource allocation method in the first embodiment of the present invention, a scheme is adopted in which RRU processing resources are allocated in order from an RRU whose connection distance is as close as possible to any BBU. This is because a mechanism is realized that can prevent in advance a situation where RRU processing relating to any RRU is assigned to BBUs that do not have a connection relationship.

(Configuration Example of Second Embodiment)
Next, a configuration example of a radio base station apparatus according to the second embodiment of the present invention will be described with reference to FIG. FIG. 8 is a block diagram showing an example of the entire configuration of a radio base station apparatus in the second embodiment of the present invention, and as a radio base station apparatus, as in FIG. 1 of the first embodiment, An example of the overall configuration of a radio base station apparatus that consolidates radio signal processing and shares its processing resources is shown. However, in the radio base station apparatus 101 shown in FIG. 8 of the second embodiment, unlike the configuration of the connection switching control unit 30 in the case of FIG. 1 of the first embodiment, each connection switching module 41 4k is configured to be mutually connectable in a ring shape including between the last connection switching module 4k and the first connection switching module 41, and further, each base station cell (RRU) is provided with five adjacent baseband signals It is configured to be connectable to the processing card (BBU).

  Similar to the case of FIG. 1 of the first embodiment, the radio base station apparatus 101 shown in FIG. 8 includes n (n: natural number) base station cells (RRU: Remote Radio Unit remote radio units) 11 to 1 n. A baseband processing pool (BBU-pool) 20 is provided to collectively implement each wireless communication process, and k (k: natural number, k ≦ n) baseband bands are provided in the baseband processing pool (BBU-pool) 20. A signal processing card (BBU: Base Band Unit baseband signal processing module) 21 to 2k is provided. Each of k (one or more) baseband signal processing cards (BBUs) 21 to 2 k in the baseband processing pool (BBU-pool) 20 is between n base station cells (RRUs) 11 to 1 n. For example, Layer-1 processing (baseband signal processing) of a wireless scheme such as LTE-Advanced is performed while sharing processing resources.

  Further, as in the case of FIG. 1 of the first embodiment, the RF (Radio Frequency) portion side of each of k (one or more) baseband signal processing cards (BBUs) 21 to 2 k is The connection switching control unit 40 is connected to each of the base station cells (RRU) 11 to 1 n by an optical fiber, a wireless backhaul (front hall), or the like. Here, there is no problem even if the radio scheme processed in the baseband processing pool (BBU-pool) 20 is a radio scheme other than LTE-Advanced, and the layers to be processed are also Layers other than Layer-1. There is no particular problem even with the second grade processing.

  Also, as in the case of FIG. 1 of the first embodiment, the radio base station apparatus 101 applies to k baseband signal processing cards (BBUs) 21 to 2k in the baseband processing pool (BBU-pool) 20. A processing resource allocation control unit 51, a traffic prediction unit 52, a connection information storage unit 53 and the like are also provided for processing resource allocation control.

  The connection switching control unit 40 is configured by arranging (concatenating) k connection switching modules 41 to 4k, similarly to the connection switching control unit 30 in the case of FIG. 1 of the first embodiment. The connection switching modules 41 to 4k respectively make connections between one or more base station cells (RRUs) 11 to 1n and one or more baseband signal processing cards (BBUs) 21 to 2k The configuration is possible, and the interconnection between adjacent connection switching modules is possible.

  However, unlike the connection switching control unit 30 in the case of FIG. 1 of the first embodiment, the connection switching control unit 40 can interconnect even between the last connection switching module 4 k and the first connection switching module 41. It is characterized in that it adopts a ring type connection configuration. For example, of the k connection switching modules 41 to 4k, the ith (1 ≦ i ≦ k) connection switching module 4i is adjacent to the (i−1) th connection switching module 4 (i-1). And the (i + 1) th connection switching module 4 (i + 1) can be mutually connected, but in the case of the connection switching module 41 at the head of i = 1 or the last connection switching module 4k of i = k. In this case, as the connection switching modules adjacent to each other in the ring shape, it is possible to mutually connect with the last connection switching module 4k and the first connection switching module 41, respectively.

  In the first embodiment, each of the k connection switching modules 31 to 3k can be interconnected with one connection switching module adjacent on both sides. In the second embodiment, the number of interconnections is expanded so that interconnections can be made between two adjacent connection switching modules on both sides.

  Therefore, in the second embodiment, an arbitrary base station cell (RRU) connected to the i-th connection switching module 4i among the n base station cells (RRU) 11 to 1n, for example, the jth j The (1 ≦ j ≦ n) th base station cell (RRU) 1j is a pair of two BBUs adjacent on both sides of the i-th BBU 2i corresponding to the connection switching module 4i to which the RRU 1j is connected. Between the (i-2) th BBU 2 (i-2), the (i-1) th BBU 2 (i-1), the (i + 1) th BBU 2 (i + 1) and the (i + 2) th BBU 2 It is possible to switch the connection between (i + 2).

  Even in the case of the configuration that can be mutually coupled with one connection switching module on each side as shown in the first embodiment, the case of the second embodiment and Similarly, it should be noted that it is possible to connect (concatenate) in a ring shape between the last connection switching module 4k and the first connection switching module 41.

(Description of the operation of the second embodiment)
Next, an example of the operation of the wireless communication return station apparatus 101 shown in FIG. 8 as a second embodiment of the present invention will be described in detail using FIG. 9 and FIG. In each of the k baseband signal processing cards (BBUs) 21 to 2 k in the baseband processing pool (BBU-pool) 20 of the radio base station apparatus 101 shown in FIG. In the same manner as in the above embodiment, wireless communication processing such as Layer-1 processing (baseband signal processing) such as LTE-Advanced etc. is performed collectively for n base station cells (RRU) 11 to 1 n, for example. .

  By sharing processing resources by k baseband signal processing cards (BBUs) 21 to 2 k, processing of each base station cell (RRU) for 11 to 1 n of base station cells (RRU) is performed on k baseband signals Each base station cell (RRU) 11 to 1 n and each baseband signal processing card (BBU) are used to make it variable which baseband signal processing card (BBU) is to be implemented among the processing cards (BBU) 21 to 2 k. The connection switching between 21 and 2 k is performed by the connection switching control unit 40. Each transmission / reception signal switched by the connection switching control unit 40 is connected to a base station cell (RRU) 11 to 1 n in a state of being connected to each other via an optical fiber, a wireless backhaul (front hall), etc. The signal processing card (BBU) 21-2k is transmitted and received.

  Here, as a feature of the connection switching control unit 40 in the second embodiment, as described above, it is possible to mutually connect two adjacent connection switching modules. The connection switching modules 41 to 4k adjacent to each other are connected to each other. Furthermore, the last connection switching module 4k and the top connection switching module 41 can be interconnected in a ring configuration. FIG. 9 is a schematic diagram showing a configuration example of the connection switching modules 41 to 4k in the second embodiment of the present invention, and an i-th (1 ≦ i as an example configuration of each of the connection switching modules 41 to 4k. Taking the connection switching module 4i of ≦ k) as an example, a configuration example is shown in which interconnection is possible with two adjacent connection switching modules.

In the example shown in FIG. 9, as in the case of FIG. 2 of the first embodiment, a baseband signal processing module (BBU) connecting one connection switching module 4i to one BBU #i. Base station cell connecting between three RRUs (for at least) RRU # j ₁ , RRU # j ₂ and RRU # j ₃ (1 ≦ j ₁ , j ₂ , j ₃ ≦ k) (RRU) I / O interface, interconnects for interconnecting with two connection switching modules 4 (i-2), 4 (i-1), 4 (i + 1), 4 (i + 2) respectively adjacent to both sides An example is shown in the case of including an input / output interface. That is, (at least) arbitrary three RRUs, for example, the j _{1st one} , even if the traffic is large by only one of the i-th BBU # i connected to the connection switching module 4i. th RRU # _{j 1,} the _{j 2} th RRU # _{j 2,} to process three RRU of the _{j 3} th _{RRU # j 3 (1 ≦ j} 1, j 2, j 3 ≦ k) The example of composition which assumed the case where it can be shown is shown.

In the case of the configuration example shown in FIG. 9, the first RRU input interface 1 from the _three RRU # j ₁ , RRU # j ₂ and RRU # j ₃ connected to the connection switching module 4i is one system, two on each side. Of the second RRU input interface 2 from the adjacent connection switching modules 4 (i-2), 4 (i-1), 4 (i + 1) and 4 (i + 2) of the four RRU # j ₁ , RRU # j ₂ , RRU The first RRU output interface 3 is directed to four lines from #j ₃ to two adjacent connection switching modules 4 (i-2), 4 (i-1), 4 (i + 1) and 4 (i + 2) on two sides on two sides, It comprises a selection circuit (not shown in FIG. 9) etc. for selecting and arbitrating each input from each of the first RRU input interface 1 and the second RRU input interface 2.

  Although depending on the maximum throughput of each baseband signal processing card (BBU) 21 to 2 k, in the embodiment shown in FIG. 9, one BBU, for example, BBU # i, can be up to 15 base station cells (RRU) at maximum. It is possible to connect and process. In FIG. 9, only the flow of signals from the RRU side to the BBU side is illustrated, and the flow of signals in the reverse direction from the BBU side to the RRU side is omitted. However, it should be noted that, in fact, reverse signal flow from the BBU side to the RRU side is also almost the same.

As such, by connecting a plurality of connection switching modules side by side and interconnecting them with each other and connecting two adjacent connection switching modules to each other, any connection switching module such as any connection switching module #i 4i can be connected. A base station cell (RRU), for example, RRU # j ₁ has at least a plurality of adjacent connection switching modules, eg, BBUs corresponding to the connection switching module #i 4i to which the RRU # j ₁ is connected, eg, BBU # i. Between a plurality of BBUs (including four BBUs in the example of FIG. 9), for example, between BBU # (i-2), BBU # (i-1), BBU # i, BBU # (i + 1), BBU # (i + 2) It is possible to switch connections between the five BBUs of

  FIG. 10 shows a connection configuration example of the connection switching modules 41 to 4k according to the second embodiment of the present invention, and a baseband signal processing card to which the operation is to be turned off next (that is, the operation is going to be turned off). It is explanatory drawing for demonstrating an example of the structure which determines the order of (BBU). In the embodiment of FIG. 10, the number k of connection switching modules 41 to 4k of the connection switching control unit 40 is eight (k = 8) of the connection switching module # 1 to the connection switching module # 8, and The number k of baseband signal processing cards (BBUs) 21 to 2k of the baseband processing pool (BBU-pool) 20 to be connected is also eight (B = 8) of BBU # 1 to BBU # 8, while the base station The number n of cells (RRUs) 11 to 1 n is set to 24 (n = 24) of RRU # 1 to RRU # 24, and each of the eight connection switching modules 41 to 48 is connected as illustrated in FIG. The case where the switching module is used is shown.

  Each BBU # 1 to BBU # 8 is basically (assuming a large traffic), each connection switching module # 1 to connection switching module # 8 corresponding to each BBU # 1 to BBU # 8. A case is shown where processing is performed for three RRUs connected to each. That is, BBU # 1 is for three RRUs of RRU # 1 to RRU # 3, BBU # 2 is for three RRUs of RRU # 4 to RRU # 6, ..., BBU # 7 is for RRU # 19 The three RRUs of RRU # 21 and the BBU # 8 perform the processing of three RRUs of RRU # 22 to RRU # 24, respectively.

  The RRUs # 1 to RRU # 24 are adjacent BBUs predetermined for each RRU # 1 to RRU # 24 among the BBUs # 1 to #BBU # 8 of the baseband processing pool (BBU-pool) 20. It is possible to limit the connection to any one of the above. That is, each of RRU # 1 to RRU # 24 is centered on each of BBU # 1 to BBU # 8 connected corresponding to each of connection switching module # 1 to connection switching module # 8 to which each RRU is connected. It is possible to selectively connect to any of five BBUs in total including at least four BBUs adjacent on both sides. For example, in the case of RRU # 4 in FIG. 10, although connected to the connection switching module # 2, two adjacent BBU # s in a ring shape centering on the corresponding connected BBU # 2. Select and connect any of five BBUs (BBU # 8, BBU # 1, BBU # 2, BBU # 3, BBU # 4), including 8, BBU # 1, BBU # 3, and BBU # 4. It is possible.

  Then, for example, when traffic is small, an arbitrary BBU, for example, BBU # 2 among eight BBU # 1 to BBU # 8 centers on the connection switching module # 2 to which the BBU # 2 is correspondingly connected. Connection switching module # 8, connection switching module # 1, connection switching module # 3, and connection switching module # 4 adjacent to each other in a ring shape, and five connection switching modules (connection switching module # 8, connection switching module # 1, a maximum of 15 RRUs connected to the connection switching module # 2, the connection switching module # 3, and the connection switching module # 4) can be connected and processed.

  That is, for example, in the case of BBU # 2, three RRUs # 4 to RRU # 6 connected to the BBU # 2 and the connection switching module # 1 and the connection switching module # 3 on both sides, respectively. The connection switching module # 8 and the connection switching module # which are adjacent to each other in a ring shape by three of RRU # 1 to RRU # 3 and three of RRU # 7 to RRU # 9 connected to A maximum of 15 RRUs # 1 to # 12, RRUs # 22 to ## which are a total of three RRUs # 22 to RRU # 24 and three RRUs # 10 to RRU # 12 connected to each of four 24 can be connected and processed.

  Next, as shown in FIG. 8, the radio base station apparatus 101 is configured to perform the processing resource sharing in each BBU, similarly to the radio base station apparatus 100 according to the first embodiment. Processing resource allocation for performing processing resource allocation of n base station cells (RRU) 11 to 1 n to k baseband signal processing cards (BBUs) 21 to 2 k based on the traffic prediction result by the traffic prediction function) A control unit 51 is provided.

  The traffic prediction unit 52 is configured to store a traffic database (average value of daily traffic for each time interval) in which daily traffic data is stored, and traffic history for the day (every Traffic prediction for the next predetermined time interval is performed for every n base station cells (RRU) 11 to 1 n using the actual value of traffic on the current day for every interval.

  Also, the processing resource allocation control unit 51 determines n base station cells (RRUs) for each of k base band signal processing cards (BBUs) 21 to 2 k based on the traffic predicted by the traffic prediction unit 52. Control of processing resource allocation of 11 to 1 n is performed. The purpose of the processing resource allocation control is, as described in the first embodiment, to operate only a few BBUs as small as possible by processing resource sharing to realize low power consumption, and to turn the operation OFF. The goal is to increase the number of BBUs that can be done.

  Next, in the second embodiment, an example of control of processing resource allocation performed in the processing resource allocation control unit 51 to realize low power consumption will be further described using an explanatory view of FIG. Do. The flow of the entire processing procedure of processing resource allocation control in the second embodiment is basically the same as that of the first embodiment, and the control flowchart of FIG. 4 of the first embodiment is used. It is the same as the procedure shown. However, as a specific control operation in the second embodiment, as described above, the configuration of the connection switching module 41 to 4k is a configuration that allows interconnection to two adjacent connection switching modules on both sides. Also, since ring connection between the last connection switching module 4k and the first connection switching module 41 is also possible, it is possible to share processing resources of more RRU processing in any one BBU. Has become a control.

  Therefore, for example, in step S1 of the processing resource allocation control flowchart shown in FIG. 4 as the first embodiment, when the order of BBUs to be turned off is determined, in the second embodiment, It is possible to set many operation OFF target BBUs.

  As described above, the explanatory diagram of FIG. 10 also shows the mechanism for determining the BBU to be turned off next in the second embodiment. In the second embodiment, the configuration is such that RRUs connected to up to five adjacent connection switching modules can be selectively connected to any one BBU. Therefore, in the explanatory diagram of FIG. 10, other than the case of the BBU operating state described as “high traffic”, “in traffic”, and “low traffic” in the case of FIG. 5 showing the operation of the first embodiment. In addition, the case of BBU operation status described as “traffic minimal” can also be realized.

  Also in the second embodiment, in the process of step S1 of FIG. 4 (the method of determining the BBU to be turned off next), the method of determining the BBU to be turned off is the first embodiment. As in the case of the embodiment, the processing resource allocation control unit 51 of FIG. 8 basically wants to turn off operation at intervals of a power of 2 according to the traffic volume predicted by the traffic prediction unit 52 ( That is, the base band signal processing card (BBU) is selected and set to operate in an off state.

That is, for example, as shown in FIG. 10A, when traffic is large, BBU that wants to turn off operation at intervals of 8 (= 2 ³ ) (that is, it tries to set operation to the off state) BBU Is set (in the case of the example of FIG. 10, for example, one of BBU # 4 is set out of eight BBUs). Further, as shown in FIG. 10B, when the traffic is medium, BBUs to be turned off are set at intervals of 4 (= 2 ² ) (in the case of the example of FIG. 10, Among the eight BBUs, for example, two BBU # 4 and BBU # 8 are set). Further, as shown in FIG. 10C, when traffic is small, BBUs to be turned off are set at intervals of 2 (= 2 ¹ ) (8 in the example of FIG. 10). Among the BBUs, for example, four of BBU # 2, BBU # 4, BBU # 6 and BBU # 8 are set).

Further, as the second case specific to the embodiment of, as shown in FIG. 10 (D), when the traffic of the minima, BBU becomes operational ON is four (= 2 ²⁾ Interval In the case of the example shown in FIG. 10, for example, BBU # 2, BBU # 3, BBU # 4, BBU # 6, BBU # 7, and BBU # of the eight BBUs are set. Set 6 of 8 as BBU you want to turn OFF. The reason why such setting becomes possible in the second embodiment is that in the first embodiment, each RRU # 1 to RRU # 24 can be connected to only three adjacent BBUs. Although this could not be done, in the second embodiment, it is possible to connect up to five adjacent BBUs, so all three adjacent BBUs can be turned off. It is.

  Furthermore, as the operating status of each baseband signal processing card (BBU) at the time of traffic prediction, the BBU operating status (for example, BBU # 4 or other of the 8 BBUs described in “traffic large” in FIG. If any one of the BBUs can realize the operation OFF state, the BBU operating state (for example, BBU # 4 out of the eight BBUs) described in “during traffic” in FIG. , And processing resource allocation control aiming at state in which any other two BBUs are turned off at intervals of two or four BBUs # 8. That is, for example, as shown in FIG. 10 (A), when one BBU of BBU # 4 is in the operation OFF state, as shown in “Low” of FIG. 10 (B), Aim to additionally turn off BBU # 8.

  Also, if the BBU operating state of "during traffic" in FIG. 10B has already been realized as the operating state of the baseband signal processing card (BBU) at the time of traffic prediction, then, as shown in FIG. BBU operation state (for example, BBU # 2, BBU # 4, BBU # 6, BBU # 8 out of eight BBUs) described in “low traffic” in any of the other four BBUs at intervals of four or two Perform processing resource allocation control with the aim of That is, for example, as shown in FIG. 10 (B), when two BBUs of BBU # 4 and # 8 are in the operation OFF state, as shown in “Low” of FIG. 10 (C), Next, we aim to add BBU # 2 and BBU # 6 to OFF.

  Also, if the BBU operating state of “low traffic” in FIG. 10C has already been realized as the operating state of the baseband signal processing card (BBU) at the time of traffic prediction, then, as shown in FIG. Processing resources aiming at the BBU operating state (state in which any other 6 BBUs are turned off so that 4 out of 8 BBUs are at intervals of 4) as described in “Minimum Traffic” in). Perform assignment control. That is, for example, as shown in FIG. 10C, when four BBUs of BBU # 2, BBU # 4, BBU # 6, and BBU # 8 are in the operation OFF state, as shown in FIG. As shown in “Low”, it aims to turn off BBU # 3 and BBU # 7 additionally.

  The structure of the process of step S2 of FIG. 4 (the method of determining the baseband signal processing card (BBU) that performs processing resource allocation control) in the second embodiment is the same as in the first embodiment. It is similar. The processing resource allocation control unit 51 selects a BBU as far away as possible from the BBUs (including the BBUs that are already in the operation OFF state) that they want to turn OFF as the selection order of the baseband signal processing card (BBU) that performs processing resource allocation control. Perform processing resource allocation control in order of priority. Here, when there are a plurality of BBUs for which operation is to be turned off (that is, the operation is to be turned off) and a plurality of BBUs that are already in the operation OFF state, processing resources are sequentially processed from the BBU located in the middle of the corresponding BBU. Perform assignment control.

  For example, it is predicted that the traffic is large in the traffic prediction unit 52, and, for example, BBU # 4 out of eight BBUs is determined as the BBU to be turned off next, as described in "traffic large" in FIG. If the BBU # 4 has already been set to the operation OFF state, as shown by “High 1” in FIG. 10A, the BBU that is most distant from the BBU # 4 in question. Perform processing resource allocation control preferentially in order from # 8. Also, the traffic is predicted to be moderate, and as described in “in traffic” in FIG. 10B, for example, BBU # 4 and BBU # 8 out of the eight BBUs should be turned off as the next BBU. If it is determined, or if BBU # 4 and BBU # 8 have already been set to the operation OFF state, the relevant BBU # 4 and BBU # are displayed as shown by "High 1" in FIG. 10 (B). The processing resource allocation control is preferentially performed in order from BBUs # 2 and # 6 which are BBUs located farthest from 8 in distance, that is, BBUs located between BBUs # 4 and # 8.

  As described in “During traffic” in FIG. 10B, when there are a plurality of BBUs that you want to turn off and a plurality of BBUs that are already off, there are BBUs that are equally distant from the multiple BBUs. When there are a plurality of BBUs, processing resource allocation control may be preferentially performed in order from any BBU among a plurality of BBUs separated by the same degree. Further, in the case of “traffic large” in FIG. 10A, BBU # 1 and BBU # 7 have a distance from BBU # 4 as a BBU that performs processing resource allocation control preferentially after BBU # 8. If they are the same, either BBU # 1 or BBU # 7 may be selected as the next priority of BBU # 8.

(Example of Configuration of Third Embodiment)
Next, a configuration example of a radio base station apparatus according to the third embodiment of the present invention will be described with reference to FIG. FIG. 11 is a block diagram showing an example of the entire configuration of a radio base station apparatus according to the third embodiment of the present invention, and as a radio base station apparatus, as in FIG. 1 of the first embodiment An example of the overall configuration of a radio base station apparatus that consolidates radio signal processing and shares its processing resources is shown. However, in the radio base station apparatus 102 shown in FIG. 11 of the third embodiment, unlike the configuration of the connection switching control unit 30 in the case of FIG. 1 of the first embodiment, k base band The signal processing cards (BBUs) 21 to 2k and n base station cells (RRUs) 11 to 1n are grouped in a predetermined unit arbitrarily determined, and the connection switching control unit 70 also sets one according to the clustering. An example of configuration in the case of performing processing resource control with partial clustering is shown.

  As in the case of FIG. 1 of the first embodiment, the radio base station apparatus 102 shown in FIG. 11 includes n (n: natural number) base station cells (RRU: Remote Radio Unit remote radio units) 11 to 1 n. A baseband processing pool (BBU-pool) 90 is provided which collectively implements each wireless communication process, and k (k: natural number, k ≦ n) baseband bands are provided in the baseband processing pool (BBU-pool) 90. A signal processing card (BBU: Base Band Unit baseband signal processing module) 21 to 2k is provided. Each of k (one or more) baseband signal processing cards (BBUs) 21 to 2 k in the baseband processing pool (BBU-pool) 90 is located between n base station cells (RRUs) 11 to 1 n. For example, Layer-1 processing (baseband signal processing) of a wireless scheme such as LTE-Advanced is performed while sharing processing resources.

  Further, as in the case of FIG. 1 of the first embodiment, the RF (Radio Frequency) portion side of each of k (one or more) baseband signal processing cards (BBUs) 21 to 2 k is The connection switching control unit 70 is connected to each of the base station cells (RRU) 11 to 1 n by an optical fiber, a wireless backhaul (front hall), or the like. Here, there is no problem even if the radio scheme processed in the baseband processing pool (BBU-pool) 90 is a radio scheme other than LTE-Advanced, and the layers to be processed are also Layers other than Layer-1. There is no particular problem even with the second grade processing.

  However, as a configuration specific to the third embodiment, each of the baseband signal processing cards (BBUs) 21 to 2k in the baseband processing pool (BBU-pool) 90 is in a predetermined unit arbitrarily determined in advance. It is clustered, and includes, for example, a first signal processing card cluster (first BBU cluster) 91, a second signal processing card cluster (second BBU cluster) 92, and the like. Further, for example, the baseband signal processing cards (BBUs) 21 to 23 are included in the first signal processing card cluster (first BBU cluster) 91, and the baseband signal processing cards (BBUs) 24 to 2 k are second signal processing card clusters (Second BBU cluster) 92 is included.

  Similarly, the base station cells (RRUs) 11 to 1 n are also in a form of being clustered in arbitrary predetermined units, for example, the first base station cell cluster (first RRU cluster) 10A, the second base station cell A cluster (second RRU cluster) 10B and the like are provided. Then, for example, base station cells (RRU) 11 to 15 are included in the first base station cell cluster (first RRU cluster) 10A, and base station cells (RRU) 16 to 1 n are the second base station cell cluster (second RRU cluster) ) Included in 10B.

  Further, among the connection switching control unit 70, a part of the connection switching control unit 70 is clustered corresponding to each BBU cluster such as the first signal processing card cluster (first BBU cluster) 91, the second signal processing card cluster (second BBU cluster) 92, etc. It is done. For example, in FIG. 11, a connection switching module cluster 71 incorporating three connection switching modules # 1 41 to # 3 43 is provided corresponding to the first signal processing card cluster (first BBU cluster) 91. The remaining connection switching modules in the connection switching control unit 70 are provided corresponding to each baseband signal processing card (BBU) as in the first and second embodiments, for example, in FIG. Are provided with connection switching modules 44 to 4 k corresponding to the baseband signal processing cards (BBUs) 24 to 2 k, respectively. Then, as in the second embodiment, ring connection can be made between the adjacent connection switching modules (or the same configuration as the first embodiment can be made) As well).

  Also, as in the case of FIG. 1 of the first embodiment and FIG. 8 of the second embodiment, the radio base station apparatus 102 performs k basebands in the baseband processing pool (BBU-pool) 90. A processing resource allocation control unit 51, a traffic prediction unit 52, a connection information storage unit 53, and the like are also provided for processing resource allocation control for the signal processing cards (BBUs) 21 to 2k. Furthermore, as a configuration specific to the third embodiment, in order to enable ON / OFF control of each base station cell (RRU) 11 to 1 n in the upper layer, each base station cell (RRU) 11 to A base station cell ON / OFF information storage unit 54 for storing 1n ON / OFF information is additionally provided.

(Description of the operation of the third embodiment)
Next, an example of the operation of the radio base station apparatus 102 shown in FIG. 11 as a third embodiment of the present invention will be described in detail. In each of the k baseband signal processing cards (BBUs) 21 to 2 k in the baseband processing pool (BBU-pool) 90 of the radio base station apparatus 102 shown in FIG. In the same manner as in the above embodiment, wireless communication processing such as Layer-1 processing (baseband signal processing) such as LTE-Advanced etc. is performed collectively for n base station cells (RRU) 11 to 1 n, for example. .

  By sharing processing resources by k baseband signal processing cards (BBUs) 21 to 2 k, processing of each base station cell (RRU) for 11 to 1 n of base station cells (RRU) is performed on k baseband signals Each base station cell (RRU) 11 to 1 n and each baseband signal processing card (BBU) are used to make it variable which baseband signal processing card (BBU) is to be implemented among the processing cards (BBU) 21 to 2 k. The connection switching between 21 and 2 k is performed by the connection switching control unit 70. Each transmission / reception signal switched by the connection switching control unit 70 is a baseband signal with a base station cell (RRU) 11 to 1 n in a connected state via an optical fiber, a wireless backhaul (front hall) or the like. It is transmitted and received between the processing cards (BBUs) 21 to 2k.

  Here, as a feature of the radio base station apparatus 102 in the third embodiment, as described above, each of the baseband signal processing cards (BBUs) 21 to 2 k in the baseband processing pool (BBU-pool) 90 is Clustering is performed in a predetermined unit arbitrarily determined in advance, and similarly, the base station cells (RRUs) 11 to 1 n are also clustered in an arbitrarily determined unit.

  Therefore, the connection switching control unit 70 is also made to correspond to each signal processing card cluster (BBU cluster) such as the first signal processing card cluster (first BBU cluster) 91, the second signal processing card cluster (second BBU cluster) 92, etc. For example, the connection switching module cluster 71 may be configured to correspond to the first signal processing card cluster (first BBU cluster) 91, or to each single baseband signal processing card (BBU) 24 to 2 k. The connection switching modules 44 to 4k may be configured. The connection switching module cluster 71 for each signal processing card cluster (BBU cluster) is simply limited to the connection of the single connection switching modules 41 to 43 for each single baseband signal processing card (BBU). It is also possible to use a configuration that allows connection, or, for example, all connection combinations between BBU and RRU related to baseband signal processing cards (BBUs) 21 to 23 in the first signal processing card cluster (first BBU cluster) 91. It may be configured to be feasible.

  Also in the third embodiment, each connection switching module in the connection switching module cluster 71 of the connection switching control unit 70 and each single connection switching module 44 to 4 k are the same as those in FIG. Alternatively, as in the configuration shown in FIG. 2) of the first embodiment, at least two interconnecting two sides (or two adjacent ones) (or second RRU input interface 2 and first RRU output interface 3) And one connection switching module connected to each other. Therefore, in any of the base station cells (RRU) 11 to 1n, in any base station cell (RRU), a baseband signal processing card (BBU) corresponding to the connection switching module to which the base station cell (RRU) is connected. It is possible to connect to a total of five (or three) or more baseband signal processing cards (BBUs) including at least four (or two or more) signal processing cards adjacent to each other.

  Next, as shown in FIG. 11, the radio base station apparatus 102, like the radio base station apparatus 100 according to the first embodiment, uses the traffic prediction unit 52 (in order to implement processing resource sharing in each BBU). Processing resource allocation for performing processing resource allocation of n base station cells (RRU) 11 to 1 n to k baseband signal processing cards (BBUs) 21 to 2 k based on the traffic prediction result by the traffic prediction function) A control unit 51 is provided.

  The traffic prediction unit 52 is configured to store a traffic database (average value of daily traffic for each time interval) in which daily traffic data is stored, and traffic history for the day (every Traffic prediction for the next predetermined time interval is performed for every n base station cells (RRU) 11 to 1 n using the actual value of traffic on the current day for every interval.

  Also, the processing resource allocation control unit 51 determines n base station cells (RRUs) for each of k base band signal processing cards (BBUs) 21 to 2 k based on the traffic predicted by the traffic prediction unit 52. Control of processing resource allocation of 11 to 1 n is performed. The purpose of the processing resource allocation control is, as described in the first embodiment, to operate only a few BBUs as small as possible by processing resource sharing to realize low power consumption, and to turn the operation OFF. The goal is to increase the number of BBUs that can be done.

  Next, in the third embodiment, an example of control of processing resource allocation implemented in the processing resource allocation control unit 51 in order to realize low power consumption will be further described. Also in the third embodiment, the flow of the overall processing procedure of the processing resource allocation control is basically the same as that of the first embodiment, and the control of FIG. 4 of the first embodiment is performed. It is the same as the procedure shown in the flowchart. However, as described above, it is assumed that ON / OFF control of each base station cell (RRU) 11 to 1 n is performed in the upper layer as a specific control operation in the third embodiment, from the upper layer The notified base station cell (RRU) ON / OFF information is stored in the base station cell ON / OFF information storage unit 54, and is referred to when control of processing resource allocation is performed.

  That is, in addition to the traffic result notified from the traffic prediction unit 52 and the RRU-BBU connection information stored in the connection information storage unit 53, the processing resource assignment control unit 51 is further notified from the upper layer. The processing resource allocation control is performed also using the base station cell (RRU) ON / OFF information stored in the base station cell ON / OFF information storage unit 54.

  Also when the traffic prediction unit 52 performs traffic prediction, traffic prediction is performed also with reference to the base station cell (RRU) ON / OFF information stored in the base station cell ON / OFF information storage unit 54. . The traffic prediction result predicted by the traffic prediction unit 52 is notified to the processing resource assignment control unit 51, and is reflected in the processing of step S1 of the control flowchart of FIG. 4 that performs processing resource assignment control.

  As a result of referring to the base station cell (RRU) ON / OFF information stored in the base station cell ON / OFF information storage unit 54, the processing resource allocation control unit 51 may, for example, select an active base station cell (RRU) 11 When it is detected that any of 1 to 1 n is OFF, the RRU processing resource allocation is performed from the baseband signal processing card (BBU) to which the RRU processing resource for the base station cell (RRU) has been allocated. After deleting in advance, the processing resource allocation control shown in the control flowchart of FIG. 4 of the first embodiment is performed. As a result, the result of the determination of the order of baseband signal processing cards (BBUs) targeted for operation OFF according to the traffic prediction result shown in step S1 of FIG. 4 and each target baseband signal processing shown in steps S3 and S4 of FIG. It will affect the calculation result of the processing resource usage rate of the card (BBU).

  On the other hand, as a result of referring to the base station cell (RRU) ON / OFF information stored in the base station cell ON / OFF information storage unit 54, the processing resource assignment control unit 51, for example, When it is detected that any one of the cells (RRUs) 11 to 1 n is in the operation on state, the base station cell (RRU) can be connected, and baseband signal processing in the operation on state is performed. When the card (BBU) is present, among the baseband signal processing cards (BBUs) in the active ON state, the baseband signal processing card (BBU) in which the connection distance of the base station cell (RRU) is nearest. Temporarily after the temporary processing resource allocation relating to the base station cell (RRU) is performed, and then the control flowchart of FIG. 4 of the first embodiment is It performs the processing resource allocation control.

  Note that by allocating temporary processing resources related to the base station cell (RRU), the processing resource usage rate of the baseband signal processing card (BBU) exceeds the threshold value A of the predetermined upper limit. Even if the base station cell (RRU) is connectable and there is no baseband signal processing card (BBU) in the active state, the same applies. After temporary processing resource allocation to the baseband signal processing card (BBU) to which the base station cell (RRU) can be connected and the connection distance of the base station cell (RRU) is the shortest, The processing resource allocation control shown in FIG. 4 is performed. The reason is that by temporarily assigning processing resources to the baseband signal processing card (BBU) in which the connection distance of the base station cell (RRU) is closest, a base band signal having no connection relationship with the base station cell (RRU) This is because it is possible to prevent in advance the case where the processing card (BBU) needs to allocate the processing resource.

(Description of the effects of the first, second and third embodiments)
As described above in detail, the following effects can be expected in each embodiment of the present invention.

  The first effect is to reduce the circuit scale of the connection switching control unit 30, 40, 70 in the wireless base station devices 100 to 102 that aggregate wireless communication processing for a plurality of base station cells (RRU) 11 to 1 n. Thus, the device can be downsized and the power consumption can be reduced.

  The reason is that, in the radio base station apparatuses 100 to 102 in each embodiment of the present invention, as connection switching control units 30, 40, and 70, between a base station cell (RRU) and a baseband signal processing card (BBU) A plurality of connection switching modules 31 to 3k and 41 to 4k in which connections are limited are arranged side by side, or are partially clustered as in the connection switching module cluster 71 of the third embodiment. The circuit scale can be significantly reduced as compared with the conventional connection switching unit that realizes all ideal connection combinations between base station cell (RRU) and baseband signal processing card (BBU). is there.

  That is, in the case of realizing all ideal connection combinations, the circuit scale is proportional to the multiplication of the respective numbers, such as “number of RRUs × number of BBUs”, while in the embodiments of the present invention. In the case of the connection switching control unit 30, 40, 70, the circuit scale can be suppressed to be linearly proportional to only the number of BBUs, such as "(limited RRU number) x BBU number". Here, the “limited number of RRUs” is nine in the case of the first embodiment, fifteen in the case of the example of the second embodiment, etc. is there.

  And with regard to the effect of reducing the circuit size and reducing the equipment size and power consumption, traffic will increase in the future, and more base station cells (RRUs) and baseband signal processing cards (BBUs) will be consolidated. It goes without saying that this is particularly remarkable in comparison with the conventional connection switching control unit in which the circuit scale increases exponentially in an attempt to realize all ideal connection combinations.

  Basically, the connection switching modules 31 to 3k and 41 to 4k are basically provided for each baseband signal processing card (BBU) as in the first and second embodiments. As in the connection switching module cluster 71 of the third embodiment, the above-described effects are not affected at all even if the signal processing card cluster (BBU cluster) is configured to correspond to each unit. That is, although based on the device architecture capable of expanding all connection switching modules in a uniform configuration, in some cases, each of them shown in the first, second and third embodiments. There is no problem even in the device architecture in which the configurations of the connection switching modules 31 to 3k and 41 to 4k and the connection switching module cluster 71 are mixed.

  The second effect is that the radio base station apparatuses 100 to 102 that aggregate radio communication processing for a plurality of base station cells (RRU) 11 to 1 n are to expand the apparatuses to cope with traffic increase and the like. Not only the base station cells (RRUs) 11 to 1 n of the base station cell radio unit 10, but also the baseband signal processing cards (BBUs) 21 to 2 k of the baseband processing pools (BBU-pool) 20 and 90, as well as connection switching The connection switching modules 31 to 3k and 41 to 4k of the control units 30, 40, and 70 can be expanded linearly as much as necessary, and the expandability is improved.

  The reason is that, in the radio base station apparatuses 100 to 102 according to the embodiment of the present invention, as the connection switching control units 30, 40, 70, connection between a base station cell (RRU) and a baseband signal processing card (BBU) As in the first and second embodiments, a plurality of connection switching modules 31 to 3 k and 41 to 4 k having interconnection interfaces with adjacent connection switching modules are arranged side by side, or the third As in the connection switching module cluster 71 according to the second embodiment, the connection switching modules 31 to 3 k and 41 to 4 k are also connected in a hierarchical manner or the like. Similar to 1n and baseband signal processing cards (BBUs) 21 to 2k, for example, linear expansion may be performed according to the “number of BBUs” to be expanded. A.

  Next, regarding the second effect, problems in the prior art will be described using an explanatory view of FIG. FIG. 12 shows a problem in the case of using an ideal connection switching unit such as a crossbar type which realizes all connection combinations between a conventional base station cell (RRU) and a baseband signal processing card (BBU). It is an explanatory view for explaining. Here, in the case of the connection switching unit of the ideal configuration, all connections of “number of RRUs × number of BBUs” are required, and therefore, even when one RRU or one BBU is expanded, the number of existing RRUs And extensions dependent on the number of BBUs are required.

  For example, as shown in FIG. 12A, the number M of base station cells (RRUs) is four of RRU # 1 to RRU # 4, and the number N of baseband signal processing cards (BBUs) is BBU # 1 to BBUs. When using an ideal crossbar (interconnection network) type connection switching unit A that realizes all connection combinations among three BBU # 3, add one RRU # 5 and one BBU # 4 In order to realize all connection combinations of “M (= 5) × N (= 4)” as shown in FIG. It will be changed to B, and it will be necessary to change the whole connection switching part, and there is a problem that extensibility becomes low.

  Alternatively, as shown in FIG. 12C, connection switching is realized to realize all the connection combinations between the existing base station cell (RRU) and the baseband signal processing card (BBU) by collectively implementing all the connection combinations. In some cases, it is also possible to separately add a dedicated connection switching unit C for connecting only the added RRU # 5-BBU # 4 while leaving the unit A as it is. However, in the case of FIG. 12C, there arises a problem that processing resources can not be shared between the BBU # 4 to be added and the existing BBUs # 1 to # 3.

  On the other hand, in each embodiment of the present invention, the connection switching module shown in FIG. 2 and FIG. 9 is required according to the addition of the base station cell (RRU) and the baseband signal processing card (BBU). There is an advantage that it is possible to expand the processing resource sharing with the existing equipment in a form that can be shared by only adding the connection switching modules to the connection switching control units 30, 40 and 70 by the number to be set.

  The third effect is that the connection switching control units 30, 40, and 70 with connection restriction are used in the wireless base station devices 100 to 102 that aggregate wireless communication processing for a plurality of base station cells (RRUs) 11 to 1 n. Even in this case, it is possible to realize processing resource sharing substantially equivalent to the case of using the ideal connection switching unit, and to obtain substantially the same power consumption reduction effect.

  The reason is that in the base station cell processing resource allocation method in each embodiment of the present invention, the baseband signal processing card (BBU) to be turned off (that is, to set the operation to the off state) is determined in advance. Then, the process resource allocation control is preferentially performed in order from the baseband signal processing card (BBU) distant from the baseband signal processing card (BBU) targeted for operation OFF. Furthermore, when the processing resource usage rate of the allocation target baseband signal processing card (BBU) exceeds the threshold A of the predetermined upper limit, a base that is distant from the allocation target baseband signal processing card (BBU) Allocation transfer control is preferentially performed in order from the band signal processing card (BBU), and when the processing resource usage rate falls below a predetermined lower limit threshold B, the allocation target baseband signal processing card (BBU) Processing resource allocation control in which allocation transfer control is preferentially performed in order from the baseband signal processing card (BBU) located in the vicinity of.

  Thus, processing resource sharing substantially equivalent to that in the case of using an ideal connection switching control unit that enables connection between a base station cell (RRU) and a baseband signal processing card (BBU) in all connection combinations is possible. Power consumption can be reduced.

  Specifically, as a base station cell processing resource allocation method, a method is adopted in which processing is allocated in order from a base station cell (RRU) whose connection distance is as close as possible to an arbitrary baseband signal processing card (BBU). Because it uses a method that can prevent in advance the process of any base station cell (RRU) from being assigned to a baseband signal processing card (BBU) having no connection relationship. is there.

  In addition, as another reason, the baseband signal processing card (BBU) away from the baseband signal processing card (BBU) is considered in advance while conscious of the baseband signal processing card (BBU) to be turned off in advance. By assigning RRU processing resources in order, it is possible to assign as many RRU processing as possible to the remaining baseband signal processing cards (BBUs) for which setting of the operation ON state is scheduled, and the baseband that you want to turn OFF operation This is because it is possible to increase the probability that the signal processing card (BBU) can actually be set to the operation OFF state.

  FIG. 13 is a schematic diagram for explaining the processing resource sharing effect of the base station cell processing resource allocation method according to the embodiment of the present invention and the conventional base station cell processing resource allocation method, which are adjacent to each other It shows about the processing resource sharing effect at the time of using the connection switching part by which the connection limitation was carried out to one each one both sides. FIG. 13 (A) shows the case where the conventional base station cell processing resource allocation method described in Non-Patent Document 1 is applied, and FIG. 13 (B) shows the case of the first embodiment of the present invention. It shows the case where the base station cell processing resource allocation method is applied. Also, in the example shown in FIG. 13, as illustrated in the breakdown of the power consumption of the baseband signal processing card (BBU), as illustrated, the power consumption that is always required in the case of operation ON (load-independent part ) Is 30%, and it is assumed that the power consumption (load dependent portion) proportional to the utilization rate (processing resource utilization rate) is 70%. In addition, it is assumed that RRU processing traffic in BBU # 1 to BBU # 4 has changed from 90%, 100%, 100%, and 30% states to 90%, 30%, 100%, and 30% states, respectively. Do.

  In the case of the conventional processing assignment method as described in Non-Patent Document 1, since the baseband signal processing card (BBU) processing order and the base station cell (RRU) processing order are not particularly considered, FIG. As shown in), although RRU processing corresponding to 10% of the 30% operation rate of BBU # 2 can be moved to BBU # 1, the remaining operation rate of BBU # 2 is 20% and BBU # 4 is Base station cells (RRUs) corresponding to each RRU process are at a distant position not included in one adjacent side even if it is tried to share RRU processes with 30% operation rate as resources. It is not possible to connect to the card (BBU), and the processing related to the base station cell (RRU) can not be moved.

  Therefore, processing resource sharing can not be performed sufficiently, and all four baseband signal processing cards (BBUs) become active. As a result, as shown in FIG. 13A, the power consumption becomes 74% as a result of all the baseband signal processing cards (BBUs) being in the operation ON state.

  On the other hand, in the processing resource allocation method according to the embodiment of the present invention, as shown in FIG. 13B, since the baseband signal processing card (BBU) processing order and the base station cell (RRU) processing order are considered. Move the RRU process that corresponds to 33% of the 100% operation rate of BBU # 3 to BBU # 2, and further, move all the processes that correspond to the 30% operation rate of BBU # 2 of BBU # 4 to BBU # It can be moved to 3 to set BBU # 4 to the operation OFF state.

  Therefore, as shown in FIG. 13 (B), among the all baseband signal processing cards (BBUs), the operation ON state becomes three BBU # 1 to BBU # 3, resulting in a power consumption of 66%, The same low power consumption effect as in the case of using the ideal connection switching unit can be obtained.

  The configuration of the preferred embodiment of the present invention has been described above. However, it should be noted that such an embodiment is merely an example of the present invention and does not limit the present invention. It will be readily understood by those skilled in the art that various modifications and variations can be made according to a particular application without departing from the scope of the present invention.

  Although the present invention has been described as a hardware configuration in the above embodiment, the present invention is not limited to this. The present invention can also realize arbitrary processing by causing a central processing unit (CPU) to execute a computer program. Also, the programs described above can be stored using various types of non-transitory computer readable media and supplied to a computer. Non-transitory computer readable media include tangible storage media of various types. Examples of non-transitory computer readable media are magnetic recording media (eg flexible disk, magnetic tape, hard disk drive), magneto-optical recording media (eg magneto-optical disk), CD-ROM (Read Only Memory) CD-R, CD -R / W, semiconductor memory (for example, mask ROM, PROM (Programmable ROM), EPROM (Erasable PROM), flash ROM, RAM (Random Access Memory)) is included. Also, the programs may be supplied to the computer by various types of transitory computer readable media. Examples of temporary computer readable media include electrical signals, light signals, and electromagnetic waves. The temporary computer readable medium can provide the program to the computer via a wired communication path such as electric wire and optical fiber, or a wireless communication path.

  This application claims priority based on Japanese Patent Application No. 2014-174067 filed on August 28, 2014, the entire disclosure of which is incorporated herein.

1 1st RRU input interface 2 2nd RRU input interface 3 1st RRU output interface 10 base station cell radio unit (RRU)
10A 1st base station cell cluster (1st RRU cluster)
10B Second base station cell cluster (second RRU cluster)
11 to 1 n base station cell (RRU)
20 Base band processing pool (BBU-pool)
21-2k Baseband Signal Processing Card (BBU)
30 connection switching control unit 31 to 3k connection switching module 40 connection switching control unit 41 to 4k connection switching module 51 processing resource allocation control unit 52 traffic prediction unit (traffic prediction function)
53 connection information storage unit 54 base station cell (RRU) ON / OFF information storage unit 70 connection switching control unit 71 connection switching module cluster 81 upper layer processing unit 90 baseband processing pool (BBU-pool)
91 1st Signal Processing Card Cluster (1st BBU Cluster)
92 Second Signal Processing Card Cluster (Second BBU Cluster)
100 radio base station apparatus 101 radio base station apparatus 102 radio base station apparatuses A1 to A8 processing step B1 to B5 of processing resource allocation control processing step S1 to S6 of processing resource allocation control processing step of processing resource allocation control

Claims (8)

Kind Code: A1 In a wireless base station apparatus for aggregating wireless communication processing for a plurality of base station cells, a baseband processing pool for aggregating and accommodating one or more baseband signal processing modules, and each baseband signal processing module A processing resource allocation control unit that performs processing resource allocation of each of the base station cells; and a connection switching control unit that performs connection switching between the baseband signal processing module and the base station cell; switching control unit is provided with a one or a plurality of connection switching modules, each of said connection switching module, to any one or more of the baseband signal processing module that adjacent a predetermined for each said base station cell Connect with the baseband signal processing module for limited connection An interconnect input for interconnecting between an I / O interface for baseband signal processing module and an I / O interface for base station cell connected to the base station cell, and for interconnecting one or more adjacent connection switching modules Connected together by providing an output interface ,
The processing resource allocation control unit
Prior to the operation of performing processing resource allocation control of each base station cell to each of the baseband signal processing modules, of the baseband signal processing modules, baseband signal processing for setting the operation to an off state Set up module candidates in advance,
When allocating processing resources of each base station cell to each of the baseband signal processing modules, the base station cell is located at a distance from the candidate of the baseband signal processing modules whose operation is to be set to an off state. Perform processing resource allocation control in order of priority from the baseband signal processing module,
A wireless base station apparatus characterized in that. The processing resource allocation control unit, when the processing resource usage rate of the baseband signal processing module in the operating state exceeds a predetermined upper limit value, a base at a connection distance away from the baseband signal processing module preferentially in order from the process relating to a station the cell the base band signal processing module from the other of the baseband signal processing according to claim 1 Symbol placement of the radio base station apparatus and performs a processing resource switching control to move to the module. The processing resource allocation control unit determines that the connection distance from the baseband signal processing module is close when the processing resource usage rate of the baseband signal processing module in the active state falls below a predetermined lower limit. The radio base station apparatus according to claim 1 or 2 , characterized in that processing resource switching control to be assigned to the baseband signal processing module is prioritized in order from processing relating to a cell. As the interconnection input / output interface included in each of the connection switching modules, one system of input / output interface interconnected with one connection switching module on each side adjacent to each of the connection switching modules, or 4. The wireless communication system according to any one of claims 1 to 3 , further comprising any one of two systems of input / output interfaces interconnected with two connection switching modules adjacent to each other and with two connection switching modules. Base station device. The radio base station apparatus according to any one of claims 1 to 4 , wherein each of the connection switching modules is connected in a ring shape by the interconnection input / output interface. The processing resource allocation control unit controls on / off control information of the base station cell notified from the upper layer prior to an operation of allocating processing resources of each base station cell to each of the baseband signal processing modules. When a base station cell whose operation has been changed from the off state to the on state is detected, the base band signal in which the connection distance from the base station cell is close and the operation is in the on state. The radio base station apparatus according to any one of claims 1 to 5 , wherein temporary processing resource allocation control for the base station cell is performed by giving priority to the processing modules in order. A wireless base station apparatus for aggregating wireless communication processing for a plurality of base station cells, wherein each of the base station cells is connected with respect to each baseband signal processing module accommodated and accommodated in a baseband processing pool. The possible baseband signal processing modules are limited to any one or more adjacent baseband signal processing modules predetermined for each of the base station cells, and for each of the baseband signal processing modules Prior to the operation of performing processing resource allocation control of each of the base station cells, among the baseband signal processing modules, candidates for baseband signal processing modules for which operation is to be set to an off state are set in advance, and the processing is performed When assigning resources, try to set operation to the off state Serial baseband signal processing performing priority to processing resource allocation control in order from the baseband signal processing module in the candidate modules on the distance to a remote location, the base station cell processing resource allocation method, characterized in that. A base station cell processing resource allocation program, which implements the base station cell processing resource allocation method according to claim 7 as a program that can be executed by a computer.

Images