JP2010130162A - Wireless base station and control method of wireless unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem wherein the risk of convergence increases in a wireless controller in communication with wireless units as the number of wireless units increases when a plurality of wireless units are connected with one wireless controller, and the circuitry of the wireless unit is complicated because it takes time to perform communication when mounting a CPU on the wireless unit and carrying out communications with the CPU of a wireless controller by software. <P>SOLUTION: In the wireless base station (200) where the wireless controller (210) and a plurality of wireless units (250) are connected by a link using a predetermined interface (CPRI), the wireless controller (210) transmits control information for the wireless units (250) and associated address information through a specific bender region in a frame. The wireless unit (250) reads out the control information and address information from the specific bender region in a received frame, and writes them directly in a storage region corresponding to the address information. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a radio base station and a radio apparatus control method.

  In a radio base station, a common public radio interface (CPRI) is used as a standard interface between a radio control apparatus (REC) and a radio apparatus (RE). By using CPRI, connectivity between devices provided by different vendors can be ensured. Further, by transmitting the CPRI traffic through the fiber link, the radio control device and the radio device can be distributed.

  FIG. 1 is a block diagram showing a conventional base station apparatus 100. In base station apparatus 100 shown in FIG. 1, radio control apparatus (REC) 110 and a plurality of radio apparatuses (RE # 0 to RE # n) 150 communicate control data and user data using CPRI. Yes. This communication is performed between the software running on the CPU 111 of the radio network controller (REC) 110 and the software running on the CPU 151 of the radio equipment (RE # 0 to RE # n) 150. This is performed using a protocol such as LAPB (Link Access Procedure, Balanced) via the RE communication control units 112 and 152. The radio control device (REC) 110 communicates with each radio device (RE # 0 to RE # n) 150 individually.

A paging-structured memory mapped I / O scheme has been proposed for accessing the memory and the like by the CPU.
JP-A-61-208152 JP-A-9-223100 Japanese Patent Laid-Open No. 2003-67350

  However, when a plurality of wireless devices are connected to one wireless control device, there is a high possibility that communication with the wireless device in the wireless control device will be congested as the number increases. Further, when the CPU is mounted on the wireless device and communicates with the CPU of the wireless control device by software, there is a problem that it takes time to communicate and the circuit configuration of the wireless device becomes complicated.

  According to an embodiment, a radio base station in which a radio control device and a plurality of radio devices are connected by a link using a predetermined interface, the radio control device includes control information for the radio device and accompanying address information. The wireless device reads out the control information and address information from the vendor specific area of the received frame and directly into the storage area corresponding to the address information. Write to.

  According to another embodiment, a control method in which a wireless control device controls a plurality of wireless devices connected by a link using a predetermined interface, wherein the wireless control device includes control information for the wireless device and an accompanying address. Transmitting information via a vendor-specific area in a frame, and the wireless device reads the control information and address information from the vendor-specific area of the received frame and corresponds to the address information Writing directly to the storage area.

  Communication congestion between the wireless control device and the wireless device can be avoided. In addition, since it is not necessary to install a CPU in the wireless device and perform communication by the handshake method, the communication speed is increased and the circuit configuration of the wireless device can be simplified.

  Embodiments of the present invention will be described in detail with reference to the drawings. Throughout the drawings, the same or corresponding components are denoted by the same or corresponding reference numerals.

  FIG. 2 is a block diagram illustrating a base station apparatus 200 according to an embodiment. In the base station apparatus 200 shown in FIG. 2, a radio control apparatus (REC) 210 and a plurality of radio apparatuses (RE # 0 to RE # n) 250 are connected by a common public radio interface (CPRI). Yes.

  The radio network controller (REC) 210 includes a CPU and memory 211, a REC control information transmission / reception unit 212, a plurality of CPRI transmission interfaces 213D, a plurality of CPRI reception interfaces 213U, a control data processing unit 214, a user data processing unit 215, and other devices 216. Have These are connected to each other via a CPU bus 220 or the like as shown in FIG. A set of CPRI transmission interface 213D and CPRI reception interface 213U corresponds to each wireless device (RE # 0 to RE # n) 250.

  The control data processing unit 214 and the user data processing unit 215 respectively process control data and user data transmitted / received to / from a radio network control device (RNC, not shown). The other device 216 includes, for example, a memory storing a control program of the CPU 211, an ATM communication device, and the like.

  The wireless devices (RE # 0 to RE # n) 250 each include an RE control information transmission / reception unit 252, a CPRI reception interface 253D, a CPRI transmission interface 253U, other devices 256, and an amplifier interface 257. These are connected to each other via a bus 260 and the like as shown in FIG.

  Amplifying device (AMP) 270 and antenna (ANT) 280 are connected to amplifier interface 257 of each wireless device (RE # 0 to RE # n) 250.

  The other device 256 is, for example, a device such as an FPGA or a PLD including a circuit for monitoring and controlling the transmission signal output from the amplification device (AMP) 270, and stores or monitors control data therefor. It includes a register for storing transmission signal parameters and the like.

  Here, the radio base station 200 according to the present embodiment uses a radio network controller (REC) 210 and a plurality of radio devices (RE # 0 to RE # n) 250 using a common public radio interface (CPRI). Connected via CPRI link. Radio control apparatus 210 transmits control information for radio apparatus 250 and accompanying address information via a vendor-specific area (Vendor Specific) in the CPRI frame. The wireless device 250 reads the control information and the address information from the vendor-specific area of the received CPRI frame, and directly (that is, software operating on the CPU) in the storage area (register) corresponding to the address information. (Without control by).

  Accordingly, in the radio base station 200 according to the present embodiment, the CPU 211 of the radio network controller 210 accesses the register of the device 256 of the radio device 250 as if the device 256 is connected to the CPU bus 220 of the CPU 211. Thus, write data can be written and read data can be read.

  FIG. 3A is a memory configuration diagram showing a register area of the wireless device developed in the memory space in the wireless control device. The memory space of the REC control information transmission / reception unit is arranged in the memory space of the radio network controller. The radio network controller (REC) 210 includes a REC control information transmission / reception unit 212 that is directly connected to the CPU bus 220. The 4-gigabyte memory space 310 (00000000h to FFFFFFFFh) of the radio network controller (REC) 210 includes a 16-megabyte memory space (xx000000h to xxFFFFFFh) 320 allocated to the REC control information transmission / reception unit 212. The register area 321 of the wireless device (RE) is developed here. The register of the wireless device is mapped as it is in the register area 321. Further, when a large number of wireless devices (RE) are connected, if the register areas corresponding to the number are expanded as they are in the memory space 310 of the wireless control device (REC) 210, the memory space on the REC side may be exhausted. is there. Therefore, a separate paging register 322 is provided, and each paging register 322 is used to identify each wireless device (RE). Thereby, even if there are a large number of radio devices (RE), only one register area 321 of the radio device (RE) is required to be secured in the memory space 310 of the radio control device (REC). Of the memory space 320 of the REC control information transmission / reception unit, a part not used as the register area 321 and the paging register 322 of the radio apparatus (RE) is a free area 323.

  As described above, the wireless control device 210 includes the control unit (CPU 211) and the control information transmission / reception unit (REC control information transmission / reception unit 212). The control unit (CPU 211) has a memory map as illustrated in FIG. 3A. Control information and address information are supplied to the control information transmission / reception unit (REC control information transmission / reception unit 212) by the I / O method.

  FIG. 3B is a diagram showing a bit configuration of the paging register 322 in FIG. 3A. In the paging register 322, 0 to 15 bits are a paging value 351 that is an identification value of the radio apparatus (RE), and 16 to 31 bits are empty (don't care) 352.

  The relationship between the paging value 351 of the paging register 322 and each wireless device (RE) is shown in FIG. 4A. For example, when the paging value 351 is 0000h, the wireless device RE # 0 is selected. When the paging value 351 is 0001h, the radio device RE # 1 is selected. When the paging value 351 is 0002h, the radio device RE # 2 is selected. Similarly, when the paging value 351 is n, the radio device RE # n is selected.

  As described above, the radio network controller 210 has a paging area (address xxFFFFF0h) in the memory space of the memory mapped I / O method, and the radio apparatus (RE # 0) corresponding to the value (for example, 0000h) of this paging area. CPRI frames can be sent to

  Further, as illustrated in FIG. 4B, when the paging value 351 is FFFFh, the broadcast is performed in which all the radio devices RE # 0 to RE # n are designated.

  In this way, the radio network controller 210 transmits the CPRI frame to all connected radio devices (RE # 0 to RE # n) according to a predetermined value (value FFFFh) of the paging area (address xxFFFFF0h). can do.

  Control data for the wireless device (RE) 250 written in the memory space 320 of the REC control information transmitting / receiving unit 212 by the CPU 211 is transmitted via a vendor specific area (Vendor Specific) in the CPRI frame as shown in FIG. It is transmitted to the radio equipment (RE) 250. FIG. 5 is a diagram illustrating transmission / reception of the CPRI frame between the radio control apparatus 210 and the radio apparatus 250. The radio equipment controller (REC) 210 and the radio equipment (RE) 250 transmit and receive user data using the CPRI frame 510. Control data for the wireless device 250 transmitted from the wireless control device 210 to the wireless device 250 is stored in a vendor-specific area (Vendor Specific) in the control word 511 of the CPRI frame 510, and is transmitted from the wireless control device 210 to the wireless device 250. Sent to (downlink).

  Further, as will be described later, data that the wireless device 250 returns to the wireless control device 210 in accordance with the control data is in the control word 511 of the CPRI frame 510 transmitted from the wireless device 250 to the wireless control device 210. It is stored in a vendor specific area (Vendor Specific) and transmitted.

  FIG. 6A is a diagram illustrating a configuration of a vendor specific area of a downlink CPRI frame. The vendor specific area is in subchannels 16-20 of the CPRI frame. Among these, the write instruction signal is stored in the first 1 bit of the first 8 bits (Xs = 0) of the subchannel 16. Further, the read instruction signal is stored in the first 1 bit of the next 8 bits (Xs = 1) of the subchannel 16. The write instruction signal and read instruction signal will be described in detail later. Further, the offset address (see FIG. 3A) in the register area of the wireless device is stored in 24 bits (Xs = 1 to 3) of the subchannel 17. Further, control data (write data) is stored in 32 bits (Xs = 0 to 3) of the subchannel 18. Other areas in the vendor specific area are unused.

  FIG. 6B is a diagram illustrating a configuration of a vendor specific area of an uplink CPRI frame. The read completion signal is stored in the first 1 bit of the first 8 bits (Xs = 0) of the subchannel 16. Further, 32 bits (Xs = 0 to 3) of the subchannel 18 store data (read data) returned from the wireless device 250 to the wireless control device 210 according to the control data.

  The configuration of the vendor specific area illustrated in FIGS. 6A and 6B is merely an example, and other configurations may be adopted in other embodiments.

  Next, with reference to FIGS. 7 to 10, data transmission / reception between the wireless control device and the wireless device via the vendor-specific area of the CPRI frame will be described in more detail.

  FIG. 7 is a sequence diagram showing a write operation from the radio network controller (REC) 210 to the radio system (RE) 250. Hereinafter, it is assumed that the radio network controller (REC) 210 performs a write operation on RE # 0 among the plurality of radio devices (RE) 250. Needless to say, the same applies to a case where a write operation is performed on another wireless device.

  Software operating on the CPU 211 of the wireless control device 210 sets a value corresponding to the wireless device (RE # 0) 250 in a paging register (see 322 in FIG. 3A) provided in the REC control information transmission / reception unit 212. (Step S10). As a result, the wireless device (RE # 0) 250 can be selected. Further, control data to be written to the wireless device (RE # 0) 250 is written in the register area of the wireless device provided in the REC control information transmitting / receiving unit 212 (see 321 in FIG. 3A) (step S12). As a result, the control data is written directly into the register of the wireless device (RE # 0) 250 (that is, without the intervention of the CPU) as described below.

  The REC control information transmission / reception unit 212 of the radio network controller 210 is connected to the CPRI transmission interface 213D corresponding to each of the radio apparatuses. The REC control information transmitting / receiving unit 212 decodes the wireless device (RE) identification value of the paging register (see 322 in FIG. 3A), and corresponding CPRI transmission interface (CPRI TX INF) 213D (in this case, the wireless device RE #) CPRI transmission interface 213D) corresponding to 0 is selected, and the offset address of the register area of the wireless device, write data (write data), and a write instruction signal are sent to the CPRI transmission interface 213D. It maps to the vendor specific area of the CPRI downlink frame to be transmitted (step S14).

  Further, the REC control information transmitting / receiving unit 212 outputs a completion signal (ACK) to, for example, the CPU bus in order to notify the CPU 211 that the writing operation (write access) to the register of the wireless device RE # 0 is completed ( Step S15).

  The CPRI transmission interface 213D that has received the enable signal stores and transmits the received offset address, write data, and write instruction signal in the vendor-specific area of the CPRI downlink frame (step S16).

  In the wireless device (RE # 0) 250, the CPRI reception interface 253D extracts (drops) the offset address, the write data, and the write instruction signal from the vendor-specific area of the CPRI frame transmitted from the wireless control device (REC) 210. The RE control information transmitting / receiving unit 252 is sent (step S18).

  The RE control information transmission / reception unit 252 writes the write data in the area corresponding to the offset address of the register of the device 256 in response to the write instruction signal included in the data received from the radio network controller 210 (step S20). .

  As described above, the radio base station 200 according to the present embodiment uses the radio control apparatus (REC) 210 and the plurality of radio apparatuses (RE # 0 to RE # n) 250 using the common public radio interface (CPRI). Connected by the CPRI link. Radio control apparatus 210 transmits control information (write data) for radio apparatus 250 and associated address information (offset address of the write data) via a vendor-specific area (Vendor Specific) in the CPRI frame ( Step S16). The wireless device 250 reads the control information and the address information from the vendor-specific area of the received CPRI frame, and directly (that is, software operating on the CPU) in the storage area (register) corresponding to the address information. Can be written (step S20).

  The write operation to the wireless device has been described. Next, a read operation from the wireless device will be described.

  FIG. 8 is a sequence diagram showing a read operation from the radio network controller (REC) 210 to the radio system (RE) 250. Hereinafter, it is assumed that the radio network controller (REC) 210 performs a read operation on RE # 0 among the plurality of radio devices (RE) 250. Needless to say, the same applies to the case where a read operation is performed on another wireless device.

  Software operating on the CPU 211 of the wireless control device 210 sets a value corresponding to the wireless device (RE # 0) 250 in a paging register (see 322 in FIG. 3A) provided in the REC control information transmission / reception unit 212. (Step S30). As a result, the wireless device (RE # 0) 250 can be selected. Further, the offset address of the register area to be read out by the wireless device (RE # 0) and the read instruction signal are sent to the REC control information transmitting / receiving unit 212 (step S32). As a result, the area corresponding to the offset address in the register area of the wireless device (RE # 0) 250 can be read directly, that is, without the intervention of the CPU.

  The REC control information transmitting / receiving unit 212 of the wireless control device 210 decodes the wireless device (RE) identification value of the paging register (see 322 in FIG. 3A), and corresponding CPRI transmission interface (CPRI TX INF) 213D (in this case) The CPRI transmission interface 213D) corresponding to the wireless device RE # 0 is selected, the offset address of the register area of the wireless device and the read instruction signal are transmitted to the CPRI transmission interface 213D, and the CPRI transmission interface 213D transmits the CPRI. Mapping to the vendor-specific area of the downstream frame (step S34).

  In the case of a read operation, the REC control information transmitting / receiving unit 212 does not output a completion signal (ACK) to the CPU bus until the read operation (read access) from the register of the wireless device RE # 0 is completed.

  The CPRI transmission interface 213D that has received the enable signal stores and transmits the received offset address and read instruction signal in the vendor-specific area of the CPRI downlink frame (step S36).

  In the wireless device (RE # 0) 250, the CPRI reception interface 253D extracts (drops) the offset address and the read instruction signal from the vendor-specific area of the CPRI frame transmitted from the wireless control device (REC) 210, and RE control information. The data is sent to the transmission / reception unit 252 (step S38).

  The RE control information transmission / reception unit 252 reads the area corresponding to the offset address of the register of the device 256 in accordance with the read instruction signal included in the data received from the radio network controller 210 (read access) (step S40). ).

  In response to the read access from the RE control information transmission / reception unit 252, the device 256 reads the register (step S42) and returns data to the RE control information transmission / reception unit 252. Thus, the read access by the RE control information transmitting / receiving unit 252 is completed (step S44).

  The RE control information transmission / reception unit 252 sends the data received from the device 256 to the CPRI transmission interface 253U together with the read completion signal (see FIG. 6B), and the vendor-specific area in the control word of the CPRI upstream frame transmitted by the CPRI transmission interface 253U. (Step S46).

  The CPRI transmission interface 253U sends the read data received from the RE control information transmission / reception unit 252 and the read completion signal to the vendor-specific area of the CPRI uplink frame that transmits the frame to the CPRI reception interface 213U of the radio network controller (REC) 210. Store and transmit (step S48).

  The CPRI reception interface 213U of the radio network controller (REC) 210 extracts (drops) the read data and the read completion signal from the vendor specific area of the received CPRI uplink frame, and sends them to the REC control information transmission / reception unit 212 (step S50). ).

  The REC control information transmission / reception unit 212 notifies the CPU 211 that the register reading operation (read access) of the wireless device RE # 0 has been completed. For example, the received REC data and the read completion signal are sent to the CPU bus. Output (step S52).

  As described above, the radio network controller 210 transmits the address information (offset address) of the storage area of the radio apparatus 250 (the register of the device 256) to the radio apparatus 250 via the vendor specific area in the first CPRI frame ( Step S36 in FIG. Also, the wireless device 250 returns data in the storage area (register of the device 256) corresponding to the address information (offset address) to the wireless control device 210 via the vendor-specific area in the second CPRI frame (FIG. 8 step S48).

  In addition, the wireless control device 210 includes a control unit (CPU 211) and a control information transmission / reception unit (REC control information transmission / reception unit 212). As described with reference to FIG. Address information is supplied to the control information transmitting / receiving unit by the / O method (step S32 in FIG. 8), and data returned from the wireless device 250 can be received (step S52 in FIG. 8).

  The read operation from the wireless device has been described. A plurality of radio apparatuses (RE) 250 are connected to one radio control apparatus (REC) 210, but in many cases, a plurality of radio apparatuses are controlled in the same manner by software of the radio control apparatus. Therefore, as described with reference to FIG. 4B, it is preferable that the same control information can be broadcast to all wireless devices.

  FIG. 9 is a sequence diagram showing a write operation by broadcast. The broadcast write operation shown in FIG. 9 is different from the unicast write operation shown in FIG. 7 in steps S10A and S14A (corresponding to steps S10 and S14 in FIG. 7 respectively).

  In step S10A, the software operating on the CPU 211 of the radio network controller 210 sets a value corresponding to the broadcast in the paging register (see 322 in FIG. 3A) provided in the REC control information transmitting / receiving unit 212 (FIG. 4B). reference).

  In step S14A, the REC control information transmission / reception unit 212 of the wireless control device 210 transmits the offset address, the write data (write data), and the write instruction signal of the register area of the wireless device to all CPRI transmission interfaces 213D. Further, the REC control information transmitting / receiving unit 212 decodes the radio device (RE) identification value of the paging register (see 322 in FIG. 3A), and if it is a value corresponding to broadcast, all CPRI transmission interfaces ( CPRI TX INF) 213D is selected and an enable signal (a signal corresponding to a chip enable signal of the semiconductor device) is sent. With this enable signal, all the CPRI transmission interfaces 213D receive the offset address, the write data, and the write instruction signal.

  The other steps are the same as those shown in FIG.

Now, the read operation from the wireless device has been described with reference to FIG. 8, but in the configuration of FIG.
This means that the wireless device is on standby until read data and a read completion signal are returned. However, if the read data and the read completion signal are not returned from the wireless device for some reason such as a failure of the wireless device, the software of the wireless control device continues to wait. Therefore, it is preferable to incorporate a mechanism for forcibly terminating this standby state.

  FIG. 10 is a sequence diagram illustrating forced termination when a read access abnormality occurs.

  In FIG. 10, the REC control information transmitting / receiving unit 212 sends an offset address and a read instruction signal to the CPRI transmission interface 213D (step S34), and starts a timer (step S35).

  Here, as described with reference to FIG. 8, the offset address and the read instruction signal are transmitted to the radio apparatus (RE # 0), and the data (read data) of the area corresponding to the offset address is read from the device 256. However (step S42), it is assumed that the read data is not returned to the RE control information transmitting / receiving unit 252 for some reason (step S44B).

  If the read data and the read completion signal are not received from the CPRI reception interface 213U even if the timer started in step S35 expires, the REC control information transmission / reception unit 212 notifies the CPU 211 of the radio device (RE # 0) 250. It is notified that the read operation (read access) to the register has been forcibly terminated (step S52B).

  The other steps are the same as those shown in FIG.

  Since the wireless device (RE) is generally located at a remote location with respect to the wireless control device (REC), it is a device that is required to be reduced in size, saved in power, and reduced in cost. According to the present embodiment, the CPU and the associated memory that are conventionally mounted in the radio apparatus (RE) can be reduced, and the circuit can be simplified. As a result, the radio apparatus (RE) can be reduced in size, power consumption, and cost. In addition, since the radio network controller (REC) can access the radio system (RE) directly, that is, without going through the CPU of the radio system (RE), congestion of communication between the radio network controller and the radio device. Can be avoided and the control of the radio equipment (RE) can be speeded up.

  Next, signals transmitted and received between the components in the base station apparatus shown in FIG. 2 will be described with reference to FIGS.

  FIG. 11 is a diagram illustrating signals between components in the base station apparatus of FIG. In the wireless control device 210, the CPU 211 controls each component of the wireless control device 210 as a control unit of the wireless control device 210 and is connected to the wireless control device 210 via a CPRI link using a common public radio interface. The plurality of wireless devices (for example, the wireless device (RE # 0) 250 in FIG. 11) are controlled. A plurality of wireless devices can be controlled by a memory mapped I / O method.

  The CPU 211 of the wireless controller (REC) 210 writes an address signal, a chip select (CS) signal, and a write enable (WE) signal to the CPU bus 220 in order to write control data to the device 256 of the wireless device (RE # 0). And write data. Further, the CPU 211 receives a ready (RDY) signal indicating that the writing operation is completed from the REC control information transmitting / receiving unit 212 via the CPU bus 220.

  In addition, the CPU 211 of the radio network controller (REC) 210 reads an address signal, a chip select (CS) signal, and an output enable (OE) to the CPU bus 220 in order to read data from the device 256 of the radio system (RE # 0). ) Output the signal. Further, the CPU 211 receives data (read data) read from the device 256 from the REC control information transmission / reception unit 212 via the CPU bus 220.

  The REC control information transmission / reception unit 212 is connected to a plurality of CPRI transmission interfaces 213D. As described with reference to FIG. 7 (step S14) and FIG. 8 (step S34), the REC control information transmission / reception unit 212 sends an offset address and write data to the selected CPRI transmission interface 213D in the case of a write operation. , And a write instruction signal (W bit), and in the case of a read operation, an offset address and a read instruction signal (R bit) are transmitted.

  The REC control information transmission / reception unit 212 is connected to a plurality of CPRI reception interfaces 213U. As described with reference to FIG. 8 (step S50), the REC control information transmission / reception unit 212 receives read data and a read data completion signal (C bit) from the selected CPRI reception interface 213U in the case of a read operation. To do.

  The CPRI transmission interface 213D and the CPRI reception interface 213U are respectively connected to the CPRI reception interface 253D and the CPRI transmission interface 253U of the corresponding wireless device (RE0 to n) 250.

  In the case of a write operation, the CPRI transmission interface 213D stores the offset address, the write data, and the write instruction signal received from the REC control information transmission / reception unit 212 in the vendor specific area (Vendor Specific) of the control word of the CPRI downlink frame, The data is transmitted to the CPRI reception interface 253D of the corresponding wireless device (RE) 250.

  On the other hand, in the case of a read operation, the CPRI reception interface 213U reads the read data and the read data completion signal stored in the vendor specific area of the control word of the CPRI uplink frame received from the CPRI transmission interface 253U of the corresponding radio apparatus (RE) 250. (C bit) is extracted and transmitted to the REC control information transmitting / receiving unit 212.

  On the other hand, in the wireless device (RE # 0) 250, the CPRI reception interface 253D starts from the CPRI downlink frame received from the wireless control device (REC) 210 in the case of a write operation, the offset address, the write data, and the write instruction signal (W Bit) is extracted and transmitted to the RE control information transmitting / receiving unit 252. In the case of a read operation, an offset address and a read instruction signal (R bit) are extracted and transmitted to the RE control information transmission / reception unit 252.

  Further, in the case of a read operation, the CPRI transmission interface 253U receives the read data and the read data completion signal (C bit) from the RE control information transmission / reception unit 252 and stores them in the number-specific area of the control word of the CPRI upstream frame. It transmits to the radio control apparatus 210.

  In the case of a write operation, the RE control information transmission / reception unit 252 receives an offset address, write data, and a write instruction signal (W bit) from the CPRI reception interface 253D, and writes the write data to the register area specified by the offset address of the device 256. Therefore, an address signal, a chip select (CS) signal, a write enable (WE) signal, and data are output to the bus 260.

  In the case of a read operation, the RE control information transmitting / receiving unit 252 receives an offset address and a read instruction signal (R bit) from the CPRI reception interface 253D, and reads the read data from the register area specified by the offset address of the device 256. The address signal, the chip select (CS) signal, and the output enable (OE) signal are output to the bus 260, and the data (read data) output from the device 256 is received.

  FIG. 12 is a block diagram showing the REC control information transmission / reception unit 212 of the radio network controller.

  In the case of a write operation, the CPU bus interface 1201 receives an address signal, a chip select (CS) signal, a write enable (WE) signal, and data (write data) from the CPU bus 220, and sends an address signal to the transmission control unit 1202T. A write enable (WE) signal and write data are sent.

  The transmission control unit 1202T receives these signals, forms a CPRI frame including an offset address, write data, and a write instruction signal, and sends the CPRI frame to the transmission port selection unit 1203T.

  On the other hand, the paging register 1211 stores the paging value (radio device (RE) identification value) supplied from the CPU 211 in advance.

  The transmission / reception port determination unit 1212 reads a paging value from the paging register 1211 and sends a port selection signal for selecting a transmission port corresponding to the selected radio apparatus (RE) 250 to the transmission port selection unit 1203T.

  Based on the port selection signal from the transmission / reception port determination unit 1212, the transmission port selection unit sends an offset address, write data, and a write instruction signal to the CPRI transmission interface 213 D to which the selected wireless device (RE) 250 is connected. Send a CPRI frame containing

  In a read operation, the CPU bus interface 1201 receives an address signal, a chip select (CS) signal, and an output enable (OE) signal from the CPU bus 220, and sends an address signal and an output enable to the transmission control unit 1202T. (OE) Send a signal.

  The transmission control unit 1202T receives these signals, forms a CPRI frame including an offset address and a read instruction signal, and sends the CPRI frame to the transmission port selection unit 1203T.

  On the other hand, the paging register 1211 stores the paging value (radio device (RE) identification value) supplied from the CPU 211 in advance.

  The transmission / reception port determination unit 1212 reads a paging value from the paging register 1211 and sends a port selection signal for selecting a transmission port corresponding to the selected radio apparatus (RE) 250 to the transmission port selection unit 1203T.

  Based on the port selection signal from the transmission / reception port determination unit 1212, the transmission port selection unit adds a CPRI including an offset address and a read instruction signal to the CPRI transmission interface 213 D to which the selected radio apparatus (RE) 250 is connected. Send a frame.

  On the other hand, similarly to the transmission port selection unit 1203T, the reception port selection unit 1203R receives a read data and a read data completion signal from the CPRI reception interface 213U selected by the port selection signal from the transmission / reception port determination unit 1212. The frame is received and sent to the reception control unit 1202R.

  Since the read data completion signal is included in the CPRI upstream frame, the reception control unit 1202R extracts the read data from the CPRI upstream frame and sends it to the CPU bus interface 1201.

  The CPU bus interface 1201 sends the read data and the ready (RDY) signal to the CPU bus 220 in order to notify the CPU 211 of the wireless control device 210 that the reading of data (read data) from the device 256 of the wireless device 250 is completed. Output to.

  FIG. 13 is a block diagram illustrating the RE control information transmission / reception unit 252 of the wireless device.

  In the case of the write operation, the transmission control unit 1301R receives the offset address, the write data, and the write instruction signal from the CPRI reception interface 253D, converts them, and sends the offset address, the write enable (WE) signal to the bus interface 1302. , Send write data.

  The bus interface 1302 receives the offset address, the write enable (WE) signal, and the write data from the transmission control unit 1301R, and outputs the address, the chip enable signal, the write enable signal, and the write data to the bus 260. Write data is written to the address area of the device 256.

  On the other hand, in the case of a read operation, the reception control unit 1301R receives the offset address and the read instruction signal from the CPRI reception interface 253D, converts them, and sends the offset address and output enable (OE) to the bus interface 1302. Send a signal.

  The bus interface 1302 receives an offset address and an output enable (OE) signal from the reception control unit 1301R, and outputs an address, a chip enable signal, and an output enable signal to the bus 260, whereby the address of the device 256 is output. Read data (read data) from the area.

  The bus interface 1302 sends the read data that has been read to the transmission control unit 1301T.

  The transmission control unit sends the read data to the CPRI transmission interface 253U together with a read data completion signal indicating that reading from the device 256 is completed.

  Next, the timing of each signal described with reference to FIGS. 11 to 13 will be described.

  FIG. 14 is a timing chart showing the write operation. In the write operation, in the radio controller (REC) 210, the offset address, the write data, and the write instruction signal from the control information transmission / reception unit 212 are placed in the vendor specific area of the CPRI downlink frame n + 1 in the CPRI transmission interface 213D, Sent to a device (RE) 250.

  In the radio apparatus (RE) 250, the offset address, the write data, and the write instruction signal are extracted from the CPRI downlink frame n + 1 by the CPRI reception interface 253D.

  As a result, the offset address, the write data, and the write instruction signal on the radio controller (REC) 210 side are reproduced by the radio device (RE) 250 as they are. Therefore, the CPU 211 of the radio network controller (REC) 210 can write control information directly to the device 256 of the radio system (RE) 250, that is, without providing the CPU in the radio system (RE 250).

  FIG. 15 is a timing chart showing a read operation. In the read operation, in the radio control apparatus (REC) 210, the offset address and the read instruction signal from the control information transmission / reception unit 212 are placed in the vendor specific area of the CPRI downlink frame n + 1 in the CPRI transmission interface 213D, and the radio apparatus (RE ) 250.

  In the radio apparatus (RE) 250, the CPRI reception interface 253D extracts the offset address and the read instruction signal from the CPRI downlink frame n + 1.

  As a result, the offset address and the read instruction signal on the radio network controller (REC) 210 side are reproduced by the radio device (RE) 250 as they are. Therefore, the CPU 211 of the radio network controller (REC) 210 can read data from the device 256 of the radio system (RE) 250 directly, that is, without providing a CPU in the radio system (RE 250).

  The read data that has been read is put together with the read data completion signal in the vendor-specific area of the CPRI upstream frame n by the CPRI transmission interface 253U and sent to the radio network controller (REC) 210.

  In the radio network controller (REC) 210, the CPRI receiving interface 213U extracts the read data and the read data completion signal from the CPRI upstream frame. Therefore, the CPU 211 of the radio network controller (REC) 210 can read data from the device 256 of the radio system (RE) 250 directly, that is, without providing a CPU in the radio system (RE 250).

  Although the embodiment of the present invention has been described in detail above, the present invention is not limited to the specific embodiment, and various modifications and changes are made within the scope of the gist of the present invention described in the claims. It can be changed.

Regarding the above embodiment, the following additional notes are disclosed.
(Appendix 1)
In a radio base station in which a radio control device and a plurality of radio devices are connected by a link using a predetermined interface,
The wireless control device transmits control information for the wireless device and accompanying address information via a vendor specific area in a frame,
The radio base station is a radio base station that reads the control information and address information from the vendor-specific area of the received frame and directly writes the read control information and address information in a storage area corresponding to the address information.
(Appendix 2)
The radio base station according to claim 1, wherein the predetermined interface is a common public radio interface.
(Appendix 3)
The wireless control device includes a control unit and a control information transmission / reception unit,
The radio base station according to appendix 1 or 2, wherein the control unit supplies the control information and the address information to the control information transmission / reception unit by a memory mapped I / O method.
(Appendix 4)
The radio base station according to appendix 3, wherein the radio network controller has a paging area in the memory space of the memory mapped I / O method, and transmits the frame to a radio apparatus corresponding to the value of the paging area.
(Appendix 5)
The radio base station according to appendix 4, wherein the radio control apparatus transmits the frame to all connected radio apparatuses in accordance with a predetermined value of the paging area.
(Appendix 6)
The wireless control device transmits address information of the storage area of the wireless device to the wireless device via a vendor specific area in a first frame,
The radio base station according to appendix 1, wherein the radio apparatus returns data in a storage area corresponding to the address information to the radio control apparatus via a vendor specific area in a second frame.
(Appendix 7)
The wireless control device includes a control unit and a control information transmission / reception unit,
7. The radio base station according to appendix 6, wherein the control unit supplies the address information to the control information transmitting / receiving unit using a memory mapped I / O method and receives the data returned from the radio device.
(Appendix 8)
A wireless control device connected to a plurality of wireless devices by a link using a predetermined interface,
A radio control apparatus comprising: a control information transmission / reception unit that transmits control information for the radio apparatus and accompanying address information via a vendor specific area in a frame.
(Appendix 9)
A wireless device connected to the wireless control device by a link using a predetermined interface,
A storage area for storing control data;
The control information transmitted through the vendor specific area in the frame and the accompanying address information are read from the vendor specific area of the received frame and directly stored in the storage area corresponding to the address information. A wireless device having a control information transmission / reception unit to be written in
(Appendix 10)
A wireless control device is a control method for controlling a plurality of wireless devices connected by a link using a predetermined interface,
The wireless control device transmits control information for the wireless device and accompanying address information via a vendor specific area in a frame;
A method in which the wireless device reads the control information and address information from the vendor-specific area of the received frame and directly writes it in a storage area corresponding to the address information.

It is a block diagram which shows the conventional base station apparatus. It is a block diagram which shows the base station apparatus by one Embodiment. It is a memory block diagram which shows the register | resistor area | region of the radio | wireless apparatus expand | deployed by the memory space in the radio | wireless control apparatus. It is a figure which shows the bit structure of the register for paging of FIG. 3A. It is a figure for demonstrating the register for paging at the time of a unicast. It is a figure for demonstrating the register for paging at the time of broadcast. It is a figure which shows transmission / reception of the CPRI frame between a radio | wireless control apparatus and a radio | wireless apparatus. It is a figure which shows the structure of the vendor specific area | region of a downlink CPRI frame. It is a figure which shows the structure of the vendor specific area | region of an uplink CPRI frame. It is a sequence diagram which shows the write-in operation from a radio | wireless control apparatus to a radio | wireless apparatus. It is a sequence diagram which shows the read-out operation from a radio | wireless control apparatus to a radio | wireless apparatus. It is a sequence diagram which shows the write-in operation | movement by broadcast. It is a sequence diagram which shows the forced termination at the time of read access abnormality. It is a figure which shows the signal between each component in the base station apparatus of FIG. It is a block diagram which shows the REC control information transmission / reception part of a radio | wireless control apparatus. It is a block diagram which shows RE control information transmission / reception part of a radio | wireless apparatus. It is a timing chart showing a write operation. It is a timing diagram which shows read-out operation.

Explanation of symbols

200 Radio base station 210 Radio control unit (REC)
211 CPU
212 REC control information transmission / reception unit 213D CPRI transmission interface 213U CPRI reception interface 214 Control data processing unit 215 User data processing unit 216 Other device 220 CPU bus 250 Wireless device (RE)
252 RE control information transmission / reception unit 253D CPRI reception interface 253U CPRI transmission interface 256 Other device 257 AMP interface 260 Bus 270 AMP
280 Antenna 1201 CPU bus interface 1202T Transmission control unit 1202R Reception control unit 1203T Transmission port selection 1203R Reception port selection 1211 Paging register 1212 Transmission / reception port determination unit 1301R Reception control unit 1301T Transmission control unit 1302 Bus interface

Claims (5)

In a radio base station in which a radio control device and a plurality of radio devices are connected by a link using a predetermined interface,
The wireless control device transmits control information for the wireless device and accompanying address information via a vendor specific area in a frame,
The radio apparatus is a radio base station that reads the control information and address information from the vendor-specific area of the received frame and writes the read control information and address information in a storage area corresponding to the address information.   The radio control apparatus according to claim 1, wherein the predetermined interface is a common public radio interface. The wireless control device includes a control unit and a control information transmission / reception unit,
The radio base station according to claim 1, wherein the control unit supplies the control information and the address information to the control information transmission / reception unit using a memory mapped I / O method.   The radio base station according to claim 3, wherein the radio network controller has a paging area in the memory space of the memory mapped I / O scheme, and transmits the frame to a radio apparatus corresponding to the value of the paging area. . A wireless control device is a control method for controlling a plurality of wireless devices connected by a link using a predetermined interface,
The wireless control device transmits control information for the wireless device and accompanying address information via a vendor specific area in a frame;
A method in which the wireless device reads the control information and address information from the vendor-specific area of the received frame and directly writes it in a storage area corresponding to the address information.

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