JP2011134095A - Software radio device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio device which has an interface which can make a plurality of pieces of software operate without considering differences between OSs, and has a platform operated at a low load. <P>SOLUTION: This radio device has an operating system, a plurality of software components, and middleware interposed between the operating system and the plurality of software components, and executes one or more of the plurality of software components to perform radio communication processing as a whole. Furthermore, the radio device has a first starting means which is included in the middleware and starts one or more of the plurality of software components on the basis of a predetermined condition when the radio device is started, and a second starting means which is included in the middleware and starts a software component specified from the outside of the plurality of software components. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a software defined radio apparatus.

  For example, Cited Document 1 provides a domain management interface that manages the operating status of a software program that operates in a domain composed of a plurality of modules.

JP 2007-148844 A

  The present invention has been made from the background described above, and includes an interface capable of operating a plurality of software without considering the difference in OS, and improved wireless to include a platform that operates at a low load. An object is to provide an apparatus.

To achieve the above object, a wireless device (1) according to the present invention includes an operating system (208), a plurality of software components (200, 202), and between the operating system and the plurality of software components. Middleware (30) provided, and a wireless device that executes one or more of the plurality of software components and performs wireless communication processing as a whole, and is included in the middleware, and the wireless device is activated A first activation means (308) for activating one or more of the plurality of software components based on a predetermined condition, and included in the middleware, Starts a software component specified externally And a second activation means (310).
In addition, the code | symbol attached | subjected here intends helping an understanding of this invention, and does not intend limiting the technical scope of this invention.

  According to the wireless device of the present invention, it is possible to realize a platform that includes an interface capable of operating a plurality of software without considering the difference in OS and that operates with a low load.

(A) is a figure which illustrates the structure of the software defined radio apparatus according to the present invention, and (B) is a diagram illustrating the configuration of the platform layer of the software defined radio apparatus shown in (A). It is a figure which illustrates the structure of the service interface which performs software in the platform layer shown in FIG.1 (B). (A) is a diagram illustrating a class diagram of the AutoFactory interface illustrated in FIG. 2, and (B) is a diagram illustrating a method name or attribute name defined in the AutoFactory interface and an explanation thereof. . (A) is a diagram illustrating a class diagram of the MicroManager interface shown in FIG. 2, and (B) is a diagram illustrating a method name or attribute name defined in the MicroManager interface and an explanation thereof. . It is a sequence diagram which illustrates the starting process of the software defined radio shown in FIG. FIG. 2 is a sequence diagram illustrating software exchange processing in the software defined radio illustrated in FIG.

[Background of the present invention]
In order to help understanding of the present invention, first, the background that led to the present invention will be described.
For example, the wireless device includes a plurality of arithmetic processing devices provided with a software execution environment and a plurality of software corresponding to CORBA (Common Object Request Broker Architecture), and a plurality of software components according to the contents of the wireless communication processing. Necessary software is arranged in an appropriate software execution environment on the arithmetic processing unit and executed.
In addition, in the above-described wireless apparatus, a platform that uses a standardized technology called SCA (Software Communication Architecture) is constructed in order to dynamically manage operations such as addition and deletion of a plurality of hardware devices.

For example, a platform using SCA dynamically manages hardware devices to be registered or deleted, or selects software necessary for wireless communication processing from a plurality of software based on hardware device registration information. , Equipped with middleware to dynamically arrange.
While the above-described middleware can dynamically manage a plurality of hardware devices and a plurality of software components, a high-performance processor may be required to operate the middleware.
Therefore, in terms of the performance of a processor such as a mobile phone in which no hardware device is added, the load for operating the platform including the middleware described above may increase.

Further, since the plurality of software components described above operate only on the same OS (Operating System), the same software cannot be operated on different OSs.
Therefore, it is necessary to install software that performs the same operation for each type of OS, which may be inefficient.
The wireless device according to the present invention is made from such a background, and the platform of the wireless device according to the present invention includes an interface capable of operating a plurality of software without considering the difference in OS, It is devised to operate at a lower load than the platform using SCA.

[Wireless device 1]
FIG. 1A is a diagram illustrating a configuration of a wireless device 1 according to the present invention.
As shown in FIG. 1A, a wireless device 1 includes an RF unit 102, an antenna 100 connected to the RF unit 102, and a modem unit 12 connected via a bus 110 such as CompactPCI (Peripheral Component Interconnect). The codec unit 14 and the control unit 16 are configured.
As shown in FIG. 1A, the modem unit 12 includes a CPU 104 and a memory 106, and the codec unit 14 and the control unit 16 are connected to the CPU 104, the memory 106, and a LAN interface (IF) 108 for network connection. including.
In these components, a DSP (Digital Signal Processor) may be used together with the CPU 104 or instead of the CPU 104.
The wireless device 1 controls the modem unit 12 and the codec unit 14 by the control unit 16 to perform necessary processing, and transmits / receives a signal of a predetermined wireless method via the RF unit 102 and the antenna 100. Wireless communication processing is performed.
In the following drawings, substantially the same components are denoted by the same reference numerals.

[Platform layer 20]
FIG. 1B is a diagram illustrating a configuration of the platform layer 20 of the wireless device 1 (FIG. 1A).
As shown in FIG. 1B, the platform layer 20 included in the wireless device 1 includes a DSP software 200, a GPP (General Purpose Processor) software 202, an input / output library 204, a DSP hardware 206, a middleware 30, and an OS 208. And a platform composed of GPP hardware 210.
Hereinafter, the DSP software 200 and the GPP software 202 may be simply referred to as “software” without being distinguished from each other.

Hereinafter, the platform layer 20 platform in the present embodiment will be described as a specific example when it is implemented according to the following policies (1) to (5).
(1) Realized on one GPP board.
(2) A DSP or FPGA (Field Programmable Gate Array) can be mounted on the GPP board.
(3) The software is executed in a predetermined execution environment. That is, dynamic software allocation to a plurality of execution environments is not performed.
(4) The software execution environment of the platform can be used regardless of whether software that communicates with the DSP or FPGA is resident.
(5) No security proxy is provided.

The DSP software 200 is a software component for DSP that realizes wireless communication processing.
The GPP software 202 is a software component for GPP that realizes wireless communication processing.
The input / output library 204 is an interface that mediates between the DSP software 200 and the DSP hardware 206, and a method defined in this interface is called to realize input / output of data to both.
The input / output library 204 communicates with the middleware 30 via the communication bus and performs various processes.

The communication bus is, for example, an ORB (Object Request Broker) that is a software bus in the bus 110 (FIG. 1A).
The middleware 30 operates on the OS 208, and includes a plurality of interfaces (described later with reference to FIG. 2) that mediate between the GPP software 202 and the OS 208.
The GPP software 202 calls the methods defined in the plurality of interfaces, and executes them by specifically using the resources of the GPP hardware 210 on the OS 208 without considering the difference of the OS 208. It is processed as follows.
The middleware 30 communicates with the input / output library 204 via the communication bus to perform various processes.

[Service Interface 3]
FIG. 2 is a diagram illustrating a configuration of the service interface 3 that executes software without considering the difference of the OS 208 in the platform layer 20 (FIG. 1B).
As shown in FIG. 2, the service interface 3 includes a DSP input / output library 204 mounted on one GPP board and a CPU middleware 30.
The middleware 30 includes a plurality of CORBA-compatible interfaces such as an HCI (Host Controller Interface) 300, Naming Service 302, Log 304, GPP_Device 306, AutoFactory 308, MicroManager 310, and DownLoader 312.

The HCI 300 is an interface that performs processing for activating necessary software when the wireless device 1 (FIG. 1B) is activated.
For example, the HCI 300 requests and acquires the IP address of the software to be activated by the Naming Service 302, and sets the acquired IP address to the DownLoader 312.
Further, the HCI 300 performs processing for starting software corresponding to a predetermined hardware device.
The Naming Service 302 is an interface that registers various interface names and interface IP addresses, and outputs the registered addresses to the request source in response to a request.

GPP_Device 306 is a logical device interface that enables access to hardware devices that do not support CORBA, such as DSPs, serial devices, and audio devices.
The AutoFactory 308 is an interface that is set so that the software executed last time is automatically activated when the wireless device 1 (FIG. 1A) is activated next time (described later with reference to FIG. 3).
The MicroManager 310 is an interface that instructs activation and termination of software and manages a software list (described later with reference to FIG. 4).
The DownLoader 312 is an interface for downloading software corresponding to the IP address based on the IP address set from the HCI 300.

[AutoFactory 308]
3A is a diagram illustrating a class diagram of the AutoFactory interface 308 included in the service interface 3 (FIG. 2), and FIG. 3B illustrates a method name or attribute name defined in the AutoFactory interface 308, It is a figure which illustrates these explanations.
As shown in FIG. 3A, the AutoFactory interface 308 inherits the ApplicationFactory interface.
The Application Factory interface is middleware provided in the platform using the SCA. For example, the necessary software is selected according to the contents of the wireless communication processing, and the selected software is arranged in one of a plurality of execution environments. Or start.

The AutoFactory interface 308 does not perform dynamic software allocation to a plurality of execution environments in accordance with the policy (3) described above, and is executed last time when the wireless device 1 (FIG. 1A) is started next time. Set the software to start automatically.
As shown in FIG. 3B, the AutoFactory interface 308 defines, for example, an attribute AutoOn_OFF indicating whether the setting of automatic software activation is on or off.
In addition, when the attribute AutoOn_OFF indicates ON, an Auto_create_at_start method for setting to automatically start the software executed last time at the next startup is defined.

[MicroManager 310]
4A is a diagram illustrating a class diagram of the MicroManager interface 310 included in the service interface 3 (FIG. 2), and FIG. 4B illustrates a method name or attribute name defined in the MicroManager 310, and It is a figure which illustrates these description.
As shown in FIG. 4A, the MicroManager interface 310 has an aggregation relationship with the DomainManager interface.
The DominManager interface is middleware provided in the platform using the SCA. For example, the DominManager interface manages various interfaces such as GPP_Device 306 (FIG. 2), and performs processing and management for the software according to the method call of the managed interface.

The MicroManager interface 310 performs processing for instructing activation and termination of software, and software list management among various types of processing defined in the DomainManager interface.
As shown in FIG. 4B, the MicroManager interface 310 defines, for example, a launchApplication method for starting specified software and a cleanApplication method for ending specified software.

[First Operation Example of Wireless Device 1]
FIG. 5 is a sequence diagram illustrating the activation process of the wireless device 1 (FIG. 1A).
Hereinafter, with reference to FIG. 5, the activation process of the wireless device 1 will be described as a first operation example.
As shown in FIG. 5, in step 400 (S400), the HCI 300 activates and initializes a common interface that is used in common in the wireless device 1, regardless of the content of the wireless communication processing.

In step 402 (S402), the HCI 300 (FIG. 2) registers the common interface name and IP address activated and initialized in S400 with the Naming Service 302.
In step 404 (S404), the three interfaces MicroManager 310, Log 304, and GPP_Device 306 perform activation processing, and register the interface name and the IP address with Naming Service 302.
In step 406 (S406), the DownLoader 312 performs activation processing, and registers the interface name and the IP address with the Naming Service 302.

In step 408 (S408), the HCI 300 requests and obtains the IP addresses of the MicroManager 310, the Log 304, and the GPP_Device 306 from the Naming Service 302.
In step 410 (S410), the HCI 300 sets the IP address of each interface acquired in S408 to the DownLoader 312.
In step 412 (S412), the DownLoader 312 downloads software corresponding to the IP address based on the IP address set from the HCI 300 in S410.
In step 414 (S414), the HCI 300 performs activation completion processing.

[Second Operation Example of Wireless Device 1]
FIG. 6 is a sequence diagram illustrating a software exchange process in the wireless device 1 (FIG. 1A).
The software replacement process is to allow the GPP_Device 306 (FIG. 2) to access another hardware device or the latest hardware device.
Hereinafter, with reference to FIG. 6, software replacement processing in the wireless device 1 will be described as a second operation example.

In step 500 (S500), the HCI 300 (FIG. 2) calls the launchApplication method of the MicroManager 310, designates software corresponding to a predetermined hardware device, and instructs activation processing of the designated software.
In step 502 (S502), the MicroManager 310 calls the create method of the AutoFactory 308 to perform the software activation process specified in S500.
In step 504 (S504), the AutoFactory 308 analyzes the profile.

In step 506 (S506), the AutoFactory 308 calls the GPP_Device 306 method to instruct the DSP register software write area allocation processing.
In step 508 (S508), the AutoFactory 308 calls a method of GPP_Device 306 to instruct software write processing.
In step 510 (S510), the GPP_Device 306 performs the software writing process instructed in S508 to the DSP register area allocated in S506.

In step 512 (S512), the AutoFactory 308 calls a method of GPP_Device 306 to instruct DSP reset processing.
In step 514 (S514), the GPP_Device 306 receives the instruction from the AutoFactory 308 in S512 and performs DSP reset processing.
In step 516 (S516), the HCI 300 notifies the completion of the software exchange process.

[Features of the wireless device 1]
Hereinafter, features of the wireless device 1 (FIG. 1A) will be described.
As described above, the platform of the wireless device 1 includes middleware including an interface for automatically starting software and an interface for instructing start processing of designated software.
With such an interface, it is not necessary to dynamically select and arrange appropriate software from a plurality of software, unlike the interface of a platform using SCA, so that the platform can be operated with a low load. .
In addition, the platform of the wireless device 1 includes middleware configured with such an interface between the OS and the software, so that a plurality of software can be operated without considering the difference between the OSs.
Therefore, according to the wireless apparatus 1 according to the present invention, a platform having an interface capable of operating a plurality of software without considering the difference in OS and operating at a lower load than a platform using SCA is realized. can do.

  DESCRIPTION OF SYMBOLS 1 ... Wireless apparatus, 12 ... Modem part, 14 ... Codec part, 16 ... Control part, 100 ... Antenna, 102 ... RF part, 104 ... CPU, 106 ... Memory 108: LAN-IF 110 110 Bus 20 Platform layer 200 DSP software 202 GPP software 204 I / O library 206 DSP hardware, 208 ... OS, 210 ... GPP hardware, 3 ... service interface, 30 ... middleware, 300 ... HCI, 302 ... NamigService, 304 ... Log, 306 ... GPP_Device, 308 ... AutoFactory, 310 ... MicroManager, 312 · DownLoader

Claims (1)

An operating system, a plurality of software components, and middleware provided between the operating system and the plurality of software components, and executing one or more of the plurality of software components to perform wireless communication as a whole A wireless device for processing,
A first activation unit included in the middleware, and activates one or more of the plurality of software components based on a predetermined condition when the wireless device is activated;
And a second activation unit that is included in the middleware and activates a software component designated from outside among the plurality of software components.

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