JP2005039557A - Software radio equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a software radio equipment which is flexible for change of a radio system, in order to solve the problem that change of a radio system of a conventional software requires labor and time, for example, a user need to select the software in accordance with specifications of the radio system, in some cases. <P>SOLUTION: The software radio equipment which performs communication by using a plurality of radio systems is provided with; a plurality of communication modules having delivery means for delivering data; a software group information storage part wherein software discrimination information being discrimination information of a plurality of softwares required of the plurality of communication modules in order to realize communication in the radio systems and connection information of softwares indicating delivery means of the plurality of communication modules by the plurality of softwares are stored correspondingly to radio system discrimination information; a connection information selection part which selects a plurality of software discrimination information and connection information stored in the software group storage part, correspondingly to a selected radio system; a connection setting part which sets delivery means of communication modules on the basis of connection information selected by the connection information selection part; and an inter-software communication part which uses delivery means set by the connection setting part to perform communication between a plurality of communication modules. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a software defined radio. In particular, the present invention relates to a software defined radio that performs communication by selectively using a plurality of radio systems.

A conventional software defined radio has a plurality of pieces of software for each function, and a desired wireless method is realized by changing a wireless method by selecting necessary software from the plurality of softwares. In such a software defined radio, data communication between software is performed using a distributed object technology such as CORBA (Common Object Request Broker Architecture) (see, for example, Non-Patent Document 1).
Internet <URL: http: //www.sdrforum.org/MTGS/mtg_22_feb01/t_0071_v0_00sra_2_overview_01_23_01.ppt>

  However, when changing the radio system of a conventional software defined radio, it may take time to change the radio system, for example, the user needs to select software according to the specifications of the radio system.

  Accordingly, an object of the present invention is to provide a software defined radio that can solve the above-described problems. This object is achieved by a combination of features described in the independent claims. The dependent claims define further advantageous specific examples of the present invention.

  That is, according to the embodiment of the present invention, a software defined radio that performs communication by selectively using a plurality of radio systems, and a plurality of communication modules each having a plurality of delivery means capable of delivering data; Software identification information, which is identification information of a plurality of software necessary for a plurality of communication modules to realize communication by the wireless method, in association with the wireless method identification information which is identification information of the wireless method, and a plurality of software A software group information storage unit for storing software connection information indicating delivery means of a plurality of communication modules by the computer, and a plurality of software identification information and connection information stored in the software group storage unit in association with the wireless method selected by the user The connection information selection unit for selecting the connection information and the connection information selected by the connection information selection unit. A connection setting unit for setting a delivery unit for the plurality of communication modules selected by the connection information selection unit, and an inter-software communication unit for performing communication between the plurality of communication modules using the delivery unit set by the connection setting unit; Is provided.

  A software information storage unit that stores, for each software, a port for software to transfer data to other software and port configuration information that is information indicating a configuration of a port for software to receive data from other software. The software group information storage unit stores the connection destination port identification information, which is the port identification information of the connection destination port, and the connection source port identification information, which is the port identification information of the connection source port, as connection information in association with each other. The information selection unit extracts port configuration information of software identified by the software identification information stored in the software group information storage unit as connection information, and the connection setting unit refers to the port configuration information extracted by the connection information selection unit In order to perform communication from the connection source port to the connection destination port, It may be constant.

  The software information storage unit stores the name of the connection destination port identified by the connection destination port identification information in association with the connection destination port identification information, and associates the connection source port identification information with the connection source port identification information. The name of the connection source port identified by the information is stored, and the connection information selection unit, based on the name of the connection destination port stored in the software information storage unit, from the software having the connection destination port to the object reference of the connection destination port Based on the name of the connection source port stored in the software information storage unit, the object reference of the connection source port having the connection source port is extracted, and the connection setting unit extracts the connection destination extracted by the connection information selection unit Access the connection destination port using the object reference of the port, and refer to the object reference of the connection source port. The connection information selection unit accesses the connection source port using the connection source port object reference extracted by the connection information selection unit, and sets the connection destination port object reference. Communication from the connection source port to the connection destination port may be performed between software as objects.

  The above summary of the invention does not enumerate all the necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.

  As is apparent from the above description, the present invention can provide a software defined radio that can flexibly change the radio system.

  Hereinafter, the present invention will be described through embodiments of the invention. However, the following embodiments do not limit the invention according to the scope of claims, and all combinations of features described in the embodiments are included. It is not necessarily essential for the solution of the invention.

  FIG. 1 shows an example of the configuration of a software defined radio 800 according to the present embodiment. In this embodiment, the software defined radio 800 prepares a file storing software connection relations and setting information in advance, and selects the software connection relations and setting information according to the wireless method to be changed. It is an object to provide a software defined radio that can change the radio system with the. The software defined radio 800 includes a plurality of AM / FM / SSB modulation / demodulation units 10, a baseband modulation / demodulation unit 20, an external I / F unit 30, a control unit 40, and a hardware bus 570. The AM / FM / SSB modulation / demodulation unit 10, the baseband modulation / demodulation unit 20, the external I / F unit 30, and the control unit 40 are connected to each other via a hardware bus 570 such as CompactPCI, PCI, VME, and the like. In this example, the AM / FM / SSB modulation / demodulation unit 10, the baseband modulation / demodulation unit 20, the external I / F unit 30, and the control unit 40 are examples of the communication module according to the present invention. With such a module configuration, the processing load is distributed.

  The AM / FM / SSB modulation / demodulation unit 10, the baseband modulation / demodulation unit 20, the external I / F unit 30, and the control unit 40 each have an OS (operating system) 550, a CPU (not shown), and a device driver 560. The OS 550 communicates with the hardware bus 570 via the device driver 560. The OS 550 is an embedded OS, for example, Linux (registered trademark). The AM / FM / SSB modulation / demodulation unit 10 is operated by the AM / FM / SSB modulation / demodulation software 100, the baseband modulation / demodulation unit 20 is operated by the 16QAM modulation / demodulation software 200, and the control unit 40 is operated by at least the application factory software 400. . The external I / F unit 30 is operated by the LAN input / output software 300 and the A / D / D / A software 350. In this example, the AM / FM / SSB modulation / demodulation software 100, the 16QAM modulation / demodulation software 200, the LAN input / output software 300, the A / D / D / A software 350, and the application factory software 400 are preliminarily set as software radio 800. This is an executable format file created outside the OS and placed on each OS 550. In addition to the AM / FM / SSB modulation / demodulation software 100, the 16QAM modulation / demodulation software 200, the LAN input / output software 300, the A / D / D / A software 350, and the application factory software 400, each OS 550 includes each hardware. Multiple software is installed for operation.

  The AM / FM / SSB modulation / demodulation software 100, the 16QAM modulation / demodulation software 200, the LAN input / output software 300, the A / D / D / A software 350, and the application factory software 400 communicate with each other via an ORB (Object Request Broker) 500. Do. The ORB 500 is middleware that performs data communication such as a data processing request between software distributed in the software defined radio 800. For example, the ORB 500 is an ORB of CORBA (Common Object Request Broker Architecture).

  In CORBA, a skeleton is an interface that waits to be called by other software, and a stub transmits / receives data to / from other software that has called the skeleton. The stub performs data conversion such as conversion to a type that can be processed by the software when data of a type different from the type declared in the software is received from the ORB 500, for example.

  In this example, each of AM / FM / SSB modulation / demodulation software 100, 16QAM modulation / demodulation software 200, LAN input / output software 300, A / D / D / A software 350, and application factory software 400 is called by other software. Have skeletons A, B, C, and D, respectively.

  The AM / FM / SSB modulation / demodulation software 100 includes stubs B, C, and D. According to each of the stubs B, C, and D, 16QAM modulation / demodulation software 200, LAN input / output software 300, and A / D / D / Each interface of the A software 350 is called. The AM / FM / SSB modulation / demodulation software 100 performs AM demodulation, FM demodulation, or SSB demodulation on an intermediate frequency signal (analog) received from an RF unit (not shown) included in the software defined radio 800, and the 16QAM modulation / demodulation software 200 or The data is transmitted to the LAN input / output software 300. The AM / FM / SSB modulation / demodulation software 100 receives data from the 16QAM modulation / demodulation software 200 or the LAN input / output software 300, and outputs an intermediate frequency obtained by AM modulation, FM modulation, or SSB modulation to the RF unit. .

  The 16QAM modulation / demodulation software 200 has stubs A and C, and the stubs A and C call the interfaces of the AM / FM / SSB modulation / demodulation software 100 and the LAN input / output software 300, respectively. The 16QAM modulation / demodulation software 200 performs quadrature demodulation (for example, 16QAM demodulation) of the baseband signal (digital) received from the AM / FM / SSB modulation / demodulation software 100 as necessary, and transmits it to the LAN input / output software 300. Further, the 16QAM modulation / demodulation software 200 modulates, for example, 16QAM the data received from the LAN input / output software 300 and transmits the data to the AM / FM / SSB modulation / demodulation software 100.

  The LAN input / output software 300 has a stub B, and the stub B calls an interface of the 16QAM modulation / demodulation software 200. The LAN input / output software 300 is connected to a LAN provided outside the software defined radio 800, for example. The LAN input / output software 300 converts the data received from the 16QAM modulation / demodulation software 200 into a protocol used in the LAN by adding a packet header or the like, and outputs the protocol to the LAN. The LAN input / output software 300 transmits data input from the LAN to the 16QAM modulation / demodulation software 200.

  The A / D / D / A software 350 includes stubs A and B, and the stubs A and B call the interfaces of the AM / FM / SSB modulation / demodulation software 100 and the 16QAM modulation / demodulation software 200, respectively. The A / D / D / A software 350 is connected to a microphone and a speaker included in the software defined radio 800. The A / D / D / A software 350 D / A (digital / analog) converts the data transmitted from the AM / FM / SSB modulation / demodulation software 100 or the like, and transmits it to the speaker. Further, the A / D / D / A software 350 performs A / D (analog / digital) conversion on the sound input from the microphone and transmits the converted sound to the AM / FM / SSB modulation / demodulation software 100 or the like.

  The application factory software 400 includes stubs A, B, C, and D. By each of the stubs A, B, C, and D, AM / FM / SSB modulation / demodulation software 100, 16QAM modulation / demodulation software 200, LAN input / output software 300, and the A / D / D / A software 350 interface is called. The application factory software 400 instructs the AM / FM / SSB modulation / demodulation software 100 and 16QAM modulation / demodulation software 200 to start / stop modulation / demodulation. Further, the application factory software 400 controls the input / output state of the LAN input / output software 300, for example, from the state of receiving data to the state of waiting for transmission data.

  The OS 550 of the control unit 40 includes an XML parser 700 and a domain profile 600. The domain profile 600 is described in XML (extensible Markup Language). The XML parser 700 parses the XML document, searches for tag names, attribute names, etc., acquires values, and the like. The application factory software 400 is an example of a connection setting unit according to the present invention, the ORB 500 is an example of an inter-software communication unit according to the present invention, and the XML parser 700 is a connection information extracting unit according to the present invention. It is an example.

  The domain profile 600 includes a plurality of software assembly descriptor (SAD) files 610, a plurality of software package descriptor (SPD) files 620, a plurality of software component files (SCD (software component files) 6 including a plurality of software components 6), and a plurality of software files 30). . The SAD file 610 is an example of a software group information storage unit according to the present invention, and the SCD file 630 is an example of a software information storage unit according to the present invention.

  The SAD file 610 is provided for each radio system, and is associated with radio system identification information including the name of the radio system and the AM / FM / SSB modulation / demodulation unit 10 and the baseband modulation / demodulation unit in order to realize communication by the radio system. Software identification information such as path names of a plurality of software necessary for the unit 20, the external I / F unit 30, and the control unit 40 are collectively stored. For example, the SAD file 610 includes an SPD file 620 and an SCD file associated with the AM / FM / SSB modulation / demodulation software 100, the 16QAM modulation / demodulation software 200, the LAN input / output software 300, and the A / D / D / A software 350, respectively. The software identification information of each of 630 and PD file 640 is stored. The SAD file 610 includes a plurality of software programs provided in the same OS 550 as the AM / FM / SSB modulation / demodulation software 100, 16QAM modulation / demodulation software 200, LAN input / output software 300, and A / D / D / A software 350. Software identification information may be stored.

  The SPD file 620 is provided for each software such as the A / D / D / A software 350, and stores software implementation information which is information indicating the operating environment and specifications of the software. The SPD file 620 stores, for example, the type of OS on which the software operates, the location (path) of the execution code, the language in which the software was developed, and the like as software implementation information.

  The SCD file 630 includes port configuration information, which is provided for each software, for the software to transfer data to other software, and port configuration information that is information indicating the configuration of the port for the software to receive data from other software. To store. The PD file 640 stores property information, which is information necessary for the software to operate the device, for each software.

  When changing the wireless method of the software defined radio 800, the XML parser 700 selects a plurality of software identification information and connection information stored in the SAD file 610 in association with the wireless method selected by the user. The application factory software 400 sets delivery means for a plurality of communication modules selected by the XML parser 700 based on the connection information selected by the XML parser 700. The ORB 500 performs communication among the AM / FM / SSB modulation / demodulation unit 10, the baseband modulation / demodulation unit 20, the external I / F unit 30, and the control unit 40 using the delivery means set by the application factory software 400.

  Also, the application factory software 400 selects a plurality of software provided on the OS 550 based on the software identification information (software name) selected by the XML parser, and the software For example, the connection relationship in each of AM / FM / SSB modulation / demodulation software 100, 16QAM modulation / demodulation software 200, LAN input / output software 300, and A / D / D / A software 350 is changed. Further, the application factory software 400 may select a plurality of software based on the software identification information, and change the setting of the selected software based on the domain profile. As a result, the software defined radio 800 can appropriately change the wireless method using the software identification information and the connection information, and can perform communication using the delivery means changed according to the wireless method.

  FIG. 2 is an explanatory diagram illustrating an interface included in the application factory software 400. The interface is a name of a program including at least one operation that instructs a predetermined operation such as data conversion, processing, and transmission / reception. The application factory software 400 has an interface ApplicationFactory and an interface Application. The interface ApplicationFactory has operations (Object create (name: in string, init Configuration: in Properties)) for giving instructions to the respective software to change the radio system according to the radio system identification information (radio system name). Further, the interface application has an operation (void ReleaseObject ()) for instructing to stop using the software defined radio by the selected radio method. As a result, the application factory software 400 gives an instruction to the wireless system change and cancellation to the interface of each software.

  FIG. 3 is an explanatory diagram for explaining an interface of each software. Each of the AM / FM / SSB modulation / demodulation software 100, 16QAM modulation / demodulation software 200, LAN input / output software 300, and A / D / D / A software 350 includes an interface port, an interface lifecycle, an interface testable object, an interface portsupplier, an interface property set, and It has an interface Resource.

  The interface LifeCycle has an operation for performing software initialization (void initialize) and an operation for disconnecting the connection with other software and terminating the operation of the software (void releaseObject). The interface PortSupplier is based on the connection destination port identification information such as the name of the connection destination port in the port configuration information included in the SCD file 630 and the connection source identification information such as the name of the connection source port. Has an operation (Object getPort (name: in string)) that gives an object reference of the port of the.

  The interface Port is based on a software object reference (connection), and connects to the connection destination software and its own software under connectionID (void connectPort (connection: in Object, connectionId: in string)) and connection. An interface (void disconnect Port (connectionId: in string)) for disconnecting the connected software. Further, the interface PropertySet is configured to set the property value extracted by the XML parser 700 in the software based on the software identification information (void configuration (config Properties: in Properties)) and the property value set in the software to the software. And an operation void query (config Properties: inout Properties)) that is output based on the identification information. Here, the Properties type is a kind of an array of structures composed of a String type id and an any type value.

  The interface Resource has an operation for starting the processing of the software (void start ()) and an operation for stopping the processing of the software (void stop ()). The interface TestableObject has an operation (void runTest (testid: inunsigned long, testValues: inout Properties)) that tests the software based on test information for selecting a test of the operation of the software and outputs the result of the test. .

  Each of the AM / FM / SSB modulation / demodulation software 100, 16QAM modulation / demodulation software 200, LAN input / output software 300, and A / D / D / A software 350 includes the six interfaces described with reference to FIG. Thus, it is possible to appropriately receive an instruction to change the wireless method transmitted by the application factory software 400.

  FIG. 4 is an explanatory diagram for compiling an IDL file that describes an interface included in the application factory software 400. FIG. 5 is an explanatory diagram in the case of compiling each IDL file describing the interface of each software.

  The IDL file is a file in which information related to the interface is described in the IDL language. The IDL file 50 describes interface information included in the application factory software 400. The IDL files 60, 70, 80, and 90 include interfaces provided by the AM / FM / SSB modulation / demodulation software 100, the 16QAM modulation / demodulation software 200, the LAN input / output software 300, and the A / D / D / A software 350, respectively. Each piece of information is described. Each of the IDL files 60, 70, 80, and 90 is a file having the same contents as long as each software has only the essential interface described with reference to FIG. Interfaces can be added. For example, the A / D / D / A software 350 may be provided with a Data interface having a dataIn operation, and digital data may be converted into audio by the dataIn operation.

  In this example, the IDL file 50 is compiled using an IDL compiler provided outside the software defined radio 800, for example, provided in a computer for a development environment. Thus, the IDL file 50 generates a skeleton file 52, a stub file 54, and a helper class file 56. Similarly, the IDL file 60, IDL file 70, IDL file 80, and IDL file 90 are skeleton files 62, 72, 82, 92, stub files 64, 74, 84, 94, helper class files 66, 76, 86. , 96 are generated. Here, each generated file has, for example, a C ++ language format. The helper class file generated here converts the object reference received by the software into a format that can be processed by the software, for example, by narrowing.

  FIG. 6 shows an example of an operation for creating an executable file of the application factory software 400. FIG. 7 shows an example of an operation for creating an executable file of each software. The source file 58 is a file in which information other than information related to the interface of the application factory software 400 is described. In this example, the source file 58 is described in, for example, the C ++ language.

  The source file 58 is compiled by a C ++ compiler provided outside the software defined radio 800, for example, provided in a development environment computer. In this case, the source file 58 has a stub file corresponding to an interface to be called by the application factory software 400, a skeleton file and a helper class file generated from the IDL file 50 by compilation, and a CORBA function declared in advance. CORBA. Compiled with h (header) file. That is, in this example, the source file 58 includes the helper class file 56, the skeleton file 52, the CORBA. h file 57 and stub files 64, 74, 84 and 94 are compiled. As a result, the source file 58 generates application factory software 400 that is an executable file having stubs A, B, C, and D and a skeleton E. In addition, CORBA. The h file is provided by, for example, a CORBA software vendor.

  Similarly, the source file 98 in which information other than the interface of the A / D / D / A conversion software software 350 is described is a stub file 64 corresponding to the communication partner software of the A / D / D / A software 350 and 74, each of the skeleton file 92 and helper file 96 of the A / D / D / A software 350 generated by the IDL compiler, and CORBA. h The file 97 is compiled together with the file 97. As a result, the source file 98 generates A / D / D / A software 350 which is an executable file having stubs A and B and a skeleton D. Similarly, execution format files of the AM / FM / SSB modulation / demodulation software 100, the 16QAM modulation / demodulation software 200, and the LAN input / output software 300 are generated.

  FIG. 8 is a flowchart showing an example of the operation of the application factory software 400 when the user changes the wireless method. FIG. 9 shows a part of the SAD file 610 described in XML. FIG. 10 shows an example of the SPD file 620 described in XML. FIG. 11 shows an example of the SCD file 630 described in XML. FIG. 12 shows an example of a PD file 640 described in XML.

  When changing the wireless method, for example, the user selects wireless method identification information (wireless method name) using a user interface capable of selecting the wireless method, and transmits the wireless method identification information to the application factory software 400 ( S100).

  The application factory software 400 calls the operation Object create (see FIG. 2) of the interface ApplicationFactory using the received wireless method identification information (equivalent to the corresponding SAD file 610) as an argument “name”. At that time, the XML parser 700 is requested to extract necessary data (S105), and the XML parser 700 refers to each of the domain profiles 600 (S110).

  Details of S110 to S115 will be described below. The SAD file 610 is provided for each wireless method, and holds the name (name) 201 of the SAD file as wireless method identification information. The XML parser 700 selects a SAD file to be referenced based on the name 201 of the SAD file.

  Further, the SAD file 610 stores all software configurations necessary for the wireless system in the software identification information 203. The SAD file 610 stores a path name and an identifier (component file id) 206 of each software as the software identification information 203. On the other hand, the SAD file 610 stores detailed information 202 about software configuring the radio. The XML parser 700 searches the identifier (componentfileref) 208 stored in the detailed information 202 for the one having the same value as the identifier 206 and selects software corresponding to the identifier 206. Thereby, the XML parser 700 extracts information about each software. For example, the XML parser 700 extracts a name 210 registered in the CORBA naming registration service for each software. Of the identifiers including the identifier 206, values such as id, refid, and repid are set to be unique all over the world in each space. For example, a UUID (Universal Unique Identifier) provided by the OS is set.

  Also, the XML parser 700 refers to the SPD file 620 existing in the path obtained from the software identification information 203, for example, the software producer information 250 indicating information related to the producer of the software, and the file name of the SCD file having an interface. And SCD interface information 252 indicating the path name, and mounting information 254 indicating the software mounting information are extracted. The XML parser 700 uses the implementation information 254, the PD interface information 256 indicating the log file name and path name of the PD file, the file name and file type of the software to be executed (type is Executable or Kernel Module, Code information 258 indicating any of the shared libraries), compiler information 260 indicating the compiler used, development language information 262 indicating information about the language used for development, and an OS that can be used. Corresponding OS information 264, corresponding processor information 266 indicating the processors that can be used, dependency on other software, dependency information 268 indicating the name and identification information of the SPD file of the dependent component, etc. Extract as needed . Also, the XML parser 700 refers to the SCD file 630 existing in the path obtained from the SCD interface information 252 and is CORBA version information 290 indicating the corresponding CORBA version, and an identifier used by CORBA to manage software. The repository identifier 292 and interface support information 296 indicating the interface name and identification information that the SCD file has uniquely are extracted. Further, the XML parser 700 refers to the PD file 640 existing in the path obtained from the PD interface information 256, and extracts the structure information 302 indicating the structure information and the test information 306 necessary for the test performed by the interface TestableObject. To do.

  Further, the SAD file 610 stores, as connection information 204, connection destination port identification information 216 that is port identification information of the connection destination port and connection source port identification information 218 that is port identification information of the connection source port in association with each other. . The SAD file 610 stores an identifier (connection interface id) 220 in association with the connection of each port.

  On the other hand, the SCD file 630 stores connection destination port names (usename) 282 and 284 in the port configuration information 294, and stores connection source port names (providesname) 286 and 288. Thereby, the XML parser 700 associates the name (usename) 282 or 284 of the connection destination port with the connection destination port identification information 216 (useidentifier) (from <uses /> having the same value as the useridentifier). The connection source port name (providesname) 286 or 288 associated with the connection source port identification information (provideidentifier) 218 is extracted.

  As described above, in S110 to S115, the XML parser 700 extracts data previously described in the domain profile. The XML parser 700 transmits these data to the application factory software 400 (S120).

  Next, the application factory software 400 generates an instance of the interface application (see FIG. 2) (corresponding to a new operator in the source code) (S125). As a result, the interface application becomes an execution state. Then, the application factory software 400 performs an operation (void initialize ()) of another software interface Lifecycle via the ORB 500 (see FIG. 1), and initializes each software (S130). Note that in order for the software to execute an operation, an object reference (corresponding to an address pointer) of the software is required. However, if only the necessary software name (name 200, etc.) can be extracted in S150, the CORBA Use the naming service to get an object reference.

  When the initialization is completed, the application factory software 400 performs an operation (Object getPort (name: in string)) of the interface PortSupplier for each software (object reference) (S135). At this time, the operation getPort returns the object reference of the connection destination port from the software having the connection destination port if the connection destination port name 282 is given to the argument (name), and if the connection destination port name 284 is given to the argument, Returns the object reference of the connection source port having the connection source port. Thereby, the application factory software 400 obtains the object reference of the connection destination port of the corresponding software and the object reference of the connection source port (S140).

  Then, the application factory software 400 instructs the connection source software (object reference) to operate the interface Port (void connectPort (connection: in Object, connectionId: in string)). As a result, the software instructed for the operation “connectPort” is connected to the connection destination software under the argument “connectioniconID” using the object reference (argument “connection”) of the connection destination software (S145). In this way, the application factory software 400 can communicate with each other by setting the delivery means so that communication from the connection source port to the connection destination port is performed. In addition, the ORB 500 mediates communication from the connection source port to the connection destination port between software that is a plurality of distributed objects.

  Here, the application factory software 400 performs an operation (void configuration (configProperties: in Properties)) of the interface PropertySet (S150). As a result, the application factory software 400 sets the names and values of the parameters extracted from the PD 640 or the like by the XML parser 700 in S110 to S115 into the properties type and passes them as arguments to set the respective software.

  Then, the application factory software 400 performs an operation (void start ()) of the interface Resource (S155). As a result, the application factory software 400 causes each software to start software radio processing. Note that the object reference of the interface application set in the execution state in step S125 is returned to the caller (user) of the application factory so that the selected wireless method can be released (S160).

  In the software defined radio 800 configured as described above, the application factory software 400 uses the domain profile 600 to acquire software connection destination and connection source port information necessary for changing the wireless system. Can do. Further, the application factory software 400 can appropriately connect the software using the acquired port information. In this case, the user can easily change the radio system by giving only the name of the radio system to the application factory software 400. In the above description, extraction of data and the like from the domain profile 600 is performed collectively from S105 to S120. However, the present invention is not limited to this, and can be extracted whenever necessary.

  FIG. 13 is a flowchart showing an example of the operation of the application factory software 400 when the user cancels the wireless method. When the user changes the data modulation / demodulation method in the currently used software radio, or when the input / output of data in the respective software is stopped, the user sends a release command or a stop command to the application factory software 400. . That is, the user calls an operation (void releaseObject ()) of the interface application (S180). Then, the application factory software 400 performs an operation (void stop) of the interface Resource of each software (S185). As a result, the application factory software 400 instructs to stop the processing of the respective software. Then, the application factory software 400 performs an operation (void releaseObject ()) of the interface Lifecycle of each software, and instructs each software to shift to the end sequence.

  As described above, according to the software defined radio 800 according to the present embodiment, by using the domain profile 600, it is possible to acquire the software connection destination and connection source port information necessary for changing the wireless method. . Moreover, software can be appropriately connected using the acquired port information. Also, the user can easily change the wireless method by designating the name of the wireless method, and can provide a software defined radio that flexibly changes the wireless method.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

It is a figure which shows an example of a structure of the software defined radio 800 which concerns on this embodiment. It is explanatory drawing explaining the interface which the application factory software 400 has. It is explanatory drawing explaining the interface which each software has. It is explanatory drawing at the time of compiling the IDL file which described the information regarding the application factory software 400. FIG. It is explanatory drawing at the time of compiling each IDL file which described the information regarding each software. 5 is a diagram illustrating an example of an operation for creating an executable file of the application factory software 400. FIG. It is a figure which shows an example of the operation | movement which creates the file of the execution format of each software. It is a flowchart which shows an example of operation | movement of the application factory software 400 when a user changes a radio system. It is a figure which shows a part of SAD file 610 described by XML. It is a figure which shows an example of the SPD file 620 described by XML. It is a figure which shows an example of the SCD file 630 described by XML. It is a figure which shows an example of PD file 640 described by XML. It is a flowchart which shows an example of operation | movement of the application factory software 400 when a user cancels | releases a radio system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... AM / FM / SSB modulation / demodulation part, 20 ... Baseband modulation / demodulation part, 30 ... External I / F part, 40 ... Control part, 50, 60, 70, 80, 90 ... IDL file, 54, 64, 74, 84, 94 ... stub file, 52, 62, 72, 82, 92, ... skeleton file, 56, 66, 76, 86, 96 ... helper class file, 58, 98 ... source file, 100 ... AM / FM / SSB modulation / demodulation software, 200 ... 16QAM modulation / demodulation software, 201, 210 ... name, 202 ... detailed information, 203 ... software identification Information, 204 ... Connection information, 206, 208, 220 ... Identifier, 216 ... Destination port identification information, 218 ... Connection source port identification information, 50 ... Software maker information, 252 ... SCD interface information, 254 ... Mounting information, 256 ... PD interface information, 258 ... Code information, 260 ... Compiler information, 262 ... Development language information, 264 ... Corresponding OS information, 266 ... Corresponding processor information, 268 ... Dependency information, 282, 284 ... Name of connection destination port, 286, 288 ... Connection source port Name, 290 ... CORBA version information, 292 ... Repository identifier, 294 ... Port configuration information, 296 ... Interface support information, 300 ... LAN input / output software, 302 ... Structure information, 306 ... Test information, 350 ... A / D / D / A software, 400 ... Application file Tori software, 500 ... ORB, 550 ... OS, 560 ... Device driver, 570 ... Hardware bus, 600 ... Domain profile, 610 ... SAD file, 620 ... SPD file 630 ... SCD file 640 ... PD file 700 ... XML parser 800 ... Software radio

Claims (3)

A software defined radio that communicates selectively using a plurality of wireless systems,
A plurality of communication modules each having a plurality of delivery means capable of delivering data;
Software identification information that is identification information of a plurality of software that is necessary for each of the plurality of communication modules in association with the wireless method identification information that is identification information of the wireless method, and A software group information storage unit for storing connection information of the software indicating the delivery means of the plurality of communication modules by a plurality of software;
A connection information selection unit that selects the plurality of software identification information and the connection information stored in the software group storage unit in association with the wireless method selected by the user;
A connection setting unit configured to set the delivery unit of the plurality of communication modules selected by the connection information selection unit based on the connection information selected by the connection information selection unit;
A software defined radio including an inter-software communication unit that performs communication between the plurality of communication modules using the delivery unit set by the connection setting unit. Software information for storing, for each software, port configuration information, which is information indicating a port for the software to transfer data to the other software, and a port for the software to receive data from the other software A storage unit;
The software group information storage unit stores, as the connection information, connection destination port identification information that is the port identification information of the connection destination port and connection source port identification information that is the port identification information of the connection source port in association with each other. And
The connection information selection unit extracts the port configuration information of the software identified by the software identification information stored in the software group information storage unit as the connection information,
The connection setting unit refers to the port configuration information extracted by the connection information selection unit, and sets the delivery unit so that communication from the connection source port to the connection destination port is performed. Software radio. The software information storage unit stores the name of the connection destination port identified by the connection destination port identification information in association with the connection destination port identification information, and associates the software information storage unit with the connection source port identification information. Stores the name of the connection source port identified by the connection source port identification information,
The connection information selection unit extracts an object reference of the connection destination port from the software having the connection destination port based on the name of the connection destination port stored in the software information storage unit, and the software information storage unit Based on the name of the connection source port stored by the server, the object reference of the connection source port having the connection source port is extracted,
The connection setting unit accesses the connection destination port using the object reference of the connection destination port extracted by the connection information selection unit, sets the object reference of the connection source port, and the connection information selection unit extracts Access the connection source port using the object reference of the connection source port, set the object reference of the connection destination port,
3. The software defined radio according to claim 2, wherein the inter-software communication unit performs communication from the connection source port to the connection destination port between the software as a plurality of distributed objects.

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