KR100696944B1 - Hybrid software-defined radio - Google Patents

Abstract

The present invention relates to a structure of a first wireless transceiver for receiving a radio signal from an antenna and performing RF down conversion to generate a digital received signal by hardware, and performing a transmission operation of up-converting a digital transmission signal and transmitting the same to an antenna. After receiving and storing a downloadable waveform from an external server, the digital received signal is processed using software emulation and the content to be transmitted is processed using software emulation. The present invention relates to a hybrid software defined radio (SDR) including ubiquitous technology (uT) software communication architecture (SCA) for generating the digital transmission signal.

According to the present invention, a software module which is reconfigurable by software and software modules for converting the reconfigurable hardware into a communication system for a specific specification or a specific purpose and supports ubiquitous technology provides a software module in a single transmission and reception hardware platform By changing only, various wireless standards can be provided in one system. In particular, while conventional SDR performs transmission / reception through dedicated hardware such as FPGA, it supports the implementation of hybrid concept through software emulation. It can accommodate restricted platform environment such as and can be applied to various hardware.

SDR, SCA, Ubiquitous, Waveform, Downloadable, Core Framework, Reconfigurable

Description

HYBRID SOFTWARE-DEFINED RADIO}

1 is a structural diagram of a wireless communication transceiver according to the prior art.

2 is a structural diagram of an SDR-based wireless transceiver according to the prior art.

3 is a structural diagram of an SCA according to the prior art.

4 is a structural diagram of a hybrid SDR according to the present invention;

5 is an SCA structure diagram of a server communicating with hybrid SDR in accordance with the present invention.

6 shows an example of an SDR waveform markup structure used for hybrid SDR according to the present invention;

<Description of the symbols for the main parts of the drawings>

110: deplexer 120: RF processing unit

123: down converter 125: frequency synthesizer

127: up converter 130: IF processing unit

140: baseband processor 150: bitstream processor

210: deplexer 215: amplifier

220: RF processor 225: ADC / DAC

230: IF processor 240: baseband processor

250: bitstream processing unit 310: application software

320: waveform 330: core framework

340: Operating system 400: first wireless transmission and reception structure

410: deplexer 415: amplifier

420: RF processing unit 425: ADC / DAC

500: second wireless transmit / receive structure 510: deplexer

515: amplifier 520: RF processing unit

525: ADC / DAC 530: IF processing unit

540: baseband processing unit 550: bitstream processing unit

600: uT SCA 610: Application Software

620: Waveform 630: uT Core Framework

640: download broker 650: reconfigurable waveform block

660: Operating System 710: Storage Manager

720: uT Core Framework 730: Directory Server

740: operating system

The present invention relates to a hybrid SDR, and more particularly, is composed of software reconfigurable hardware and software modules for converting the reconfigurable hardware into a specific standard or a communication communication system for a specific purpose and support ubiquitous technology. By changing only the software modules on a single transmit and receive hardware platform, various wireless standards can be provided as a single system. Especially, the conventional SDR can transmit and receive through dedicated hardware such as FPGA. By supporting the implementation of the hybrid concept can accommodate a restricted platform environment, such as a mobile small terminal, and relates to a hybrid SDR applicable to a variety of hardware.

In the current situation where the paradigm is changing from the existing service provider-centered service provision to the differentiated service provided by the service user's demand, there is a limit to the existing system that requires a system change according to various wireless system standards.

In this situation, Software-defined Radio (SDR) technology is a convergence concept of software and hardware technology that can implement a reconfigurable system structure of wireless communication, and upgrade software without changing hardware (platform). It is attracting attention as a technology that enables the implementation of a multi-mode, multi-band and multi-function wireless system by itself.

SDR consists of a core software framework and software download protocol technology for controlling and operating a software-defined radio-based multimode system. In particular, the underlying technical structure of SDR follows the structure proposed by the SDR forum. Existing SDR technology is defined in terms of signal processing, regulatory and ITU-R. Among them, the SDR, in terms of signal processing, performs the digitization of the received signal as close as possible to the antenna, reducing fixed hardware functions, extending partially programmable hardware parts, and utilizing the increased software programmability. It is defined as a wireless technology that increases.

In order to describe such an SDR, a conventional digital wireless communication system will be described. In most digital wireless communication systems, hardware includes an RF, an ADC, a DAC, and a digital signal processor.

1 is a structural diagram of a wireless communication transceiver according to the prior art.

The deplexer 110 transmits a radio signal received from the antenna to the RF processor 120 or a signal transmitted from the RF processor 120 to the antenna.

The RF processor 120 includes a down converter 123, a frequency synthesizer 125, and an up converter 127 to perform RF transmission or RF reception of a signal.

The IF processor 130 converts the output signal of the RF processor 120 into an IF signal or converts the output signal of the baseband processor 140 into an RF signal.

The baseband processor 140 converts an output signal of the IF processor 130 into a baseband signal or a digital signal of the bitstream processor 150 into a baseband signal.

The bitstream processor 150 processes a digital signal.

The signal from the deplexer 110 to the baseband processor 140 is in the form of an analog signal, and the baseband processor 140 converts the digital signal into a digital signal using a low speed ADC.

Unlike the conventional wireless communication transceiver, the SDR technology can increase the sampling processing band of the system to RF processing by bringing the position of the ADC (or DAC for transmission) to the IF or RF rather than the baseband. .

In addition, SDR is programmable with high-speed DSPs and CPUs, rather than the concept of traditional software-controlled digital radios that use traditional digital circuits and low-speed / high-speed digital signal processors (DSPs) and CPUs. It is embodied in the concept of a total programmable digital radio capable of IF or RF, channel access mode, channel modulation and more.

2 is a structural diagram of an SDR-based wireless transceiver according to the prior art.

As shown, according to the concept of the SDR, the structure of the SDR-based wireless transceiver which converts an IF analog signal into a digital signal through a high-speed ADC and processes it using a DSP or the like is shown.

In the configuration of FIG. 2, the ADC / DAC 225 is located between the RF processor 220 and the IF processor 230, and the IF processor 230, the baseband processor 240, and the bitstream processor 250 are digitally processed. Through such a configuration, it is possible to configure a system applicable to existing systems and new system standards. In addition, the amplifier 215 performs signal amplification before transmitting the signal from the RF processor 220 to the deplexer 210. Details of each component are omitted because they are similar to the radio transceiver structure according to the prior art.

3 is a structural diagram of a software communication architecture (SCA) according to the prior art.

SCA defines the basic structure of radio system module, API between each module and software download protocol from the software point of view. SDR Forum develops software structure based on SCA of JTRS (Joint Tactical Radio System) -JPO. .

As shown, the SCA may be divided into a hierarchical structure of the application software 310 and the operating environment 330 and 340.

Application software 310 is a program that performs SCA compliant system operations.

Waveform 320 contains information about data (analog or digital) reception, encryption, modulation, IF / RF conversion, etc., and is designed to be portable to other systems due to its portability. do. In addition, using the information stored in the waveform 320, the baseband processor 240 is reconfigured to perform modulation or demodulation in response to various demodulation standards such as FSK, PSK, AM, FM, and OFDM. The baseband processor 240 is implemented using, for example, an FPGA, and this configuration is mainly applied to fixed or large communication equipment such as a base station.

The Core Framework (CF, 330) is a basic set of open application-layer interfaces and services that provide application software developers with an abstract layer of software and hardware. These include, for example, Base Application Interfaces providing Ports, LifeCycle, etc., used in application software, and devices, LoadableDevices, and ExecutableDevices. It includes a framework control interface that provides system control, and a framework service interface that provides applications such as files and file systems.

Operating system 340 is a set of basic functions that control and coordinate the overall operation of the operation of the system based on an abstract layer for each hardware.

For more detailed description of this SCA can refer to the homepage of the US JTRS, for example, detailed description thereof will be omitted.

Through the SDR configuration supporting SCA, existing systems that depended heavily on hardware operation can be replaced with reconfigurable hardware, and error correction, service change according to a user, and real-time acceptance of a new service can be performed by downloading application software.

From the manufacturer's point of view, a single SDR platform can be built, and then wireless specifications and protocols can be provided to customers as application software downloads, enabling them to respond quickly to the rapidly changing communications market environment.

On the network operator's side, multiple wireless standards are supported by a single base station platform, making network deployment easier and system upgrades easy due to application software changes, resulting in increased system backward compatibility and coping with the development of various communication technologies.

On the user side, in the existing environment where only fixed services of a specific communication system were used, the service can be provided according to individual needs by selecting a service according to the user's needs, and real-time bug fixes and upgrades are possible.

In order to realize all the functions and services targeted by SDR, an ultra-high performance processor is required. In addition, the processor must operate at low power and have a very high density per unit area. In fact, when implementing an SDR using an FPGA, it is possible to accommodate the existing communication specifications on a single chip. It is also expected that the implementation of this SDR will be possible by developing a hybrid processor architecture that combines the advantages and disadvantages of FPGAs, DSPs, and ASICs. In fact, a lot of research is being conducted by DSP manufacturers.

In addition, it is expected that the speed of development of SDR will change depending on which direction the mobile communication service requiring multiple modes is developed in the future. Recently, ubiquitous technology (uT) computing, which is drawing attention, is expected to form the basis of the next generation network. Ubiquitous means that any kind of service can be supported in various network environments. For example, GSM, Enhanced Data Rates GSM Evolution (EDGE), Bluetooth, Home Network, WLAN, IrDA, Broadband Wireless Access (BWA), cellular The various communication standards must be satisfied. Therefore, one terminal and system should actively establish a communication network to meet these various communication standards.

As such, the structure of the conventional SDR has a problem in that expensive hardware, such as an FPGA or a DSP, must be present, and such a configuration has a problem in flexibility in consideration of the state of the art to date.

In particular, the technology of the SDR forum also focuses on base station-based reconfigurable wireless hardware, which is not useful for platforms such as mobile handheld equipment. In addition, the existing SCA architecture does not disclose the ability to manage the actual reconfigurable applications in such a mobile small equipment environment.

Therefore, there is a growing need for a structure that can be applied to mobile small equipment and can realize software-based reconfiguration and transformation at low cost according to a wireless environment.

An object of the present invention consists of software reconfigurable hardware and software modules for converting the reconfigurable hardware into a communication system for a specific specification or a specific purpose, and support ubiquitous technology to provide software for a single transmission and reception hardware platform. By changing only the module, various wireless standards can be provided in one system. In particular, while conventional SDR performs transmission / reception through dedicated hardware such as FPGA, it supports the implementation of hybrid concept through software emulation. The present invention provides a hybrid SDR that can accommodate a limited platform environment such as a terminal and can be applied to various hardware.

In order to achieve the above technical problem, the present invention is a hardware operation for receiving a radio signal from the antenna and down-converting the RF to generate a digital reception signal, and a transmission operation for RF up-converting the digital transmission signal and transmitting it to the antenna A structure of a first wireless transceiver to be performed and a downloadable waveform from an external server are received and stored. Based on this, the digital reception signal is processed and transmitted using software emulation. A hybrid software defined radio (SDR) is provided that includes ubiquitous technology (uT) software communication architecture (UCA) to process using software emulation to generate the digital transmission signal.

In the hybrid SDR according to the present invention, the uT SCA is configured to download a uT core framework to retrieve the downloadable waveform from the external server, and to download the downloadable waveform retrieved from the uT core framework. A reconfigurable waveform block that includes a download broker, basic channel modem code and modularization functionality, and performs software emulation to perform signal processing for various wireless communication standards using waveforms downloaded from the download broker. It is preferable to include.

In addition, in the hybrid SDR according to the present invention, it is preferable that the download broker performs verification of stability when downloading the downloadable waveform.

In addition, in the hybrid SDR according to the present invention, the external server, a storage manager (store manager) for storing and managing information about the downloadable waveform, and connected to the uT core framework and the information about the downloadable waveform It is desirable to support an SCA that includes a server uT core framework that provides security and a directory manager that provides information about the protocols, supportable information structures, or directories used for communication between the server and the SDR.

In the hybrid SDR according to the present invention, the uT SCA is preferably operated on a real-time operating system.

In the hybrid SDR according to the present invention, the external server uses the markup structure for information including a frequency name, a waveform name, and an application name. It is desirable to manage possible waveforms.

In addition, in the hybrid SDR according to the present invention, the hybrid SDR is applicable to a mobile communication device including a mobile phone or a PDA.

In addition, in the hybrid SDR according to the present invention, a reception operation for receiving a radio signal from an antenna, processing an RF downconversion and IF signal, demodulating the bitstream, and bitstream processing and modulating a signal to be transmitted and an IF signal It is preferable to further include a second radio transceiver structure for performing the transmission operation after the RF up-conversion and transmits to the antenna after processing.

The present invention also provides a function for searching a downloadable waveform from an external server, a function for downloading the searched downloadable waveform, basic channel modem code and modularization function, and the downloaded waveform for various wireless communication standards. A computer-readable recording medium having a program recorded thereon for realizing a function of reconfiguring the signal processing method by emulating in software to perform signal processing for the same.

A computer-readable recording medium having recorded thereon a program for realizing a function according to the present invention, preferably, further comprising a function of verifying stability when downloading the downloadable waveform.

Hereinafter, the hybrid SDR of the present invention will be described in more detail with reference to the drawings.

4 is a structural diagram of a hybrid SDR according to the present invention.

As shown, the hybrid SDR according to the present invention includes a first wireless transmit / receive structure 400 and a ubiquitous technology (uT) SCA 600. In addition, the hybrid SDR according to the present invention may further include a second wireless transmit / receive structure 500.

The first wireless transmission / reception structure 400 performs a reception operation of receiving a radio signal from an antenna by hardware and performing RF down conversion to generate a digital reception signal, and a transmission operation of RF up-converting a digital transmission signal and transmitting it to the antenna. .

The first wireless transmit / receive structure 400 may include, for example, a deplexer 410, an RF processor 420, an ADC / DAC 425, and an amplifier 415. As described above with reference to FIGS. 1 to 3, detailed descriptions thereof will be omitted.

The uT SCA 600 receives and stores downloadable waveforms from an external server, processes the digital received signal using software emulation, and processes the content to be transmitted using software emulation based on the digital transmission signal. Create

The uT SCA 600 is configured in the present invention so that the existing SCA structure is particularly suitable for small terminals used in mobile communication, etc., and serves to form a reconfigurable waveform block 650 by searching for downloadable waveforms and downloading them. do.

uT SCA 600 includes application software 610, waveforms 620a, 620b, uT core framework 630, download broker 640, reconfigurable waveform block, RWB. 650, and an operating system 660.

The details of the application software 610, the waveforms 620a and 620b, and the operating system are the same as those of the SCA according to the prior art, and thus detailed description thereof will be omitted.

The uT core framework 630 finds downloadable waveforms from the server and actively informs clients supporting hybrid SDR.

The download broker 640 downloads the downloadable waveform and in this case performs verification of stability, such as security issues. Verification is performed, for example, against stability against viruses or hacks.

RWB 650 is an existing core signaling structure that performs basic channel modem code and modularization functions. The RWB 650 may flexibly maintain the overall SDR structure by providing a function of software emulation through the RWB 650 to process tasks that the conventional SDR processes through the FPGA and the DSP.

Operating system 660 is a set of basic functions that control and adjust the overall operation of the system's operation based on an abstract layer for each hardware. The operating system 660 is a real-time operating system that is more suitable when considering an environment such as a mobile handheld device. Preference is given to using.

In addition, the hybrid SDR according to the present invention may be implemented in a form embedded in a small mobile communication terminal such as, for example, a mobile phone or a PDA. That is, the existing SDR can be applied to fixed or large communication equipment such as a base station because it uses a dedicated hardware such as an FPGA, but it is difficult to apply to a mobile small equipment. However, the hybrid SDR according to the present invention has an advantage in that it can be applied to more various devices by processing through software emulation in the processor based on the downloadable waveform instead of the FPGA.

In addition, the hybrid SDR according to the present invention may further include a second wireless transmit / receive structure 500. That is, the second wireless transceiver structure 500 receives a radio signal from an antenna, processes the RF downconversion and IF signals, demodulates the bitstreams, and processes the received stream and the signal to be transmitted. After processing, uplink RF and transmit it to the antenna.

As shown, the second wireless transmit / receive structure 500 may include, for example, a deplexer 510, an RF processor 520, an ADC / DAC 525, an amplifier 515, an IF processor 530, and a baseband processor. 540 and the bitstream processor 550.

In the hybrid SDR according to the present invention, the reason for including both the first wireless transmission / reception structure 400 and the second wireless transmission / reception structure 500 at the same time is for compatibility and efficiency of transmission and reception through SDR. . That is, it is necessary to include the second wireless transmission / reception structure 500 because it is more efficient to process the base station function in the conventional large-scale communication network by hardware rather than software emulation when performing frequent modulation, demodulation, and the like through the SDR function. Do.

5 is an SCA structural diagram of a server communicating with a hybrid SDR according to the present invention.

In order to support the hybrid SDR system according to the present invention, the server side includes a structure including a storage manager 710, a uT core framework 720, a directory server 730, and an operating system 740. Support.

The storage manager 710 stores and manages information about downloadable waveforms.

The uT core framework 720 manages a task of providing information on a downloadable waveform connected to the SDR system according to the present invention, that is, the client through the uT core framework 630 and the uT core framework bus.

Directory server 730 provides information about directories, protocols and supportable information structures used in client-server communication.

Operating system 740 is a set of basic functions that control and coordinate the overall operation of the operation of a server system.

6 is a diagram illustrating an example of an SDR waveform markup structure used for hybrid SDR according to the present invention.

The SDR waveform markup structure is presented in the present invention to manage the actual downloadable and reconfigurable applications for realizing dynamic and reconfigurable techniques in various hardware environments.

As shown, the SDR waveform markup structure includes markups for information on frequency names, waveform names, application names, etc., so that they can be actually serviced from the server side to the client. And it can be effectively used when managing all the appropriate application services.

Although the present invention has been described in detail, this is for illustrative purposes only, and the protection scope of the present invention is not limited thereto, and the protection scope of the present invention is defined through the description of the claims.

As described above, according to the present invention, the hardware is reconfigurable by software and software modules for converting the reconfigurable hardware into a communication system for a specific specification or a specific purpose, and supports ubiquitous technology to support a single transmission and reception hardware. By changing only the software modules on the platform, various wireless standards can be provided as one system.In particular, the conventional SDR supports the implementation of hybrid concepts through software emulation, compared to performing transmission / reception through dedicated hardware such as FPGAs. As a result, it can accommodate a restricted platform environment such as a mobile small terminal and can be applied to various hardware.

Claims (10)

A first radio transceiver structure for receiving a radio signal from an antenna and performing RF down conversion to generate a digital reception signal; and a first radio transceiver structure for performing an RF up conversion of a digital transmission signal and transmitting the same to an antenna; Receives and downloads a downloadable waveform from an external server, processes the digital received signal using software emulation, and processes the content to be transmitted using software emulation. Ubiquitous technology (uT) software communication architecture (SCA) for generating digital transmission signals Including, The external server, A hybrid SDR is a hybrid software defined SDR, which manages the downloadable waveform using a markup structure for information including frequency name, waveform name, and application name. radio). The method of claim 1, wherein the uT SCA, A uT core framework for retrieving the downloadable waveform from the external server; A download broker for downloading the downloadable waveform retrieved from the uT core framework; A reconfigurable waveform block that includes basic channel modem code and modularization functionality and performs software emulation to perform signal processing for a variety of wireless communications standards using waveforms downloaded from the download broker. Hybrid SDR comprising a. The method of claim 2, The download broker performs verification for stability when downloading the downloadable waveform. The server of claim 2, wherein the external server comprises: A storage manager for storing and managing information about the downloadable waveform, a server uT core framework connected to the uT core framework and providing information about downloadable waveforms, between the server and the SDR. A hybrid SDR that supports an SCA that includes a directory manager that provides information about the protocols or supported information structures or directories used to communicate. The method of claim 2, wherein the uT SCA, Hybrid SDR running on a real-time operating system. delete The method according to any one of claims 1 to 5, The hybrid SDR is applicable to a mobile communication device including a mobile phone or a PDA hybrid SDR. The method according to any one of claims 1 to 5, The hardware receives the radio signal from the antenna, processes the RF downconversion and IF signal processing, and demodulates the bitstream to process the bitstream. And a second wireless transceiver structure for performing a transmitting operation for transmitting. The ability to search for downloadable waveforms from an external server, Downloading the retrieved downloadable waveform; Basic channel modem code and modularity, Reconfiguring a signal processing scheme by emulating in software to perform signal processing on various wireless communication standards using the downloaded waveform; A function to verify the stability when downloading the downloadable waveform A computer-readable recording medium having recorded thereon a program for realizing this. delete

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