Design and Validation of a Software Defined Radio Testbed for DVB-T Transmission

This paper describes the design and validation of a Software Defined Radio (SDR) testbed, which can be used for Digital Television transmission using the Digital Video Broadcasting - Terrestrial (DVB-T) standard. In order to generate a DVB-T-compliant signal with low computational complexity, we design an SDR architecture that uses the C/C++ language and exploits multithreading and vectorized instructions. Then, we transmit the generated DVB-T signal in real time, using a common PC equipped with multicore central processing units (CPUs) and a commercially available SDR modem board. The proposed SDR architecture has been validated using fixed TV sets, and portable receivers. Our results show that the proposed SDR architecture for DVB-T transmission is a low-cost low-complexity solution that, in the worst case, only requires less than 22% of CPU load and less than 170 MB of memory usage, on a 3.0 GHz Core i7 processor. In addition, using the same SDR modem board, we design an off-line software receiver that also performs time synchronization and carrier frequency offset estimation and compensation

Defining interfaces between hardware and software: Quality and performance

One of the most important interfaces in a computer system is the interface between hardware and software. This interface is the contract between the hardware designer and the programmer that defines the functional behaviour of the hardware. This thesis examines two critical aspects of defining the hardware-software interface: quality and performance. The first aspect is creating a high quality specification of the interface as conventionally defined in an instruction set architecture. The majority of this thesis is concerned with creating a specification that covers the full scope of the interface; that is applicable to all current implementations of the architecture; and that can be trusted to accurately describe the behaviour of implementations of the architecture. We describe the development of a formal specification of the two major types of Arm processors: A-class (for mobile devices such as phones and tablets) and M-class (for micro-controllers). These specifications are unparalleled in their scope, applicability and trustworthiness. This thesis identifies and illustrates what we consider the key ingredient in achieving this goal: creating a specification that is used by many different user groups. Supporting many different groups leads to improved quality as each group finds different problems in the specification; and, by providing value to each different group, it helps justify the considerable effort required to create a high quality specification of a major processor architecture. The work described in this thesis led to a step change in Arm's ability to use formal verification techniques to detect errors in their processors; enabled extensive testing of the specification against Arm's official architecture conformance suite; improved the quality of Arm's architecture conformance suite based on measuring the architectural coverage of the tests; supported earlier, faster development of architecture extensions by enabling animation of changes as they are being made; and enabled early detection of problems created from architecture extensions by performing formal validation of the specification against semi-structured natural language specifications. As far as we are aware, no other mainstream processor architecture has this capability. The formal specifications are included in Arm's publicly released architecture reference manuals and the A-class specification is also released in machine-readable form. The second aspect is creating a high performance interface by defining the hardware-software interface of a software-defined radio subsystem using a programming language. That is, an interface that allows software to exploit the potential performance of the underlying hardware. While the hardware-software interface is normally defined in terms of machine code, peripheral control registers and memory maps, we define it using a programming language instead. This higher level interface provides the opportunity for compilers to hide some of the low-level differences between different systems from the programmer: a potentially very efficient way of providing a stable, portable interface without having to add hardware to provide portability between different hardware platforms. We describe the design and implementation of a set of extensions to the C programming language to support programming high performance, energy efficient, software defined radio systems. The language extensions enable the programmer to exploit the pipeline parallelism typically present in digital signal processing applications and to make efficient use of the asymmetric multiprocessor systems designed to support such applications. The extensions consist primarily of annotations that can be checked for consistency and that support annotation inference in order to reduce the number of annotations required. Reducing the number of annotations does not just save programmer effort, it also improves portability by reducing the number of annotations that need to be changed when porting an application from one platform to another. This work formed part of a project that developed a high-performance, energy-efficient, software defined radio capable of implementing the physical layers of the 4G cellphone standard (LTE), 802.11a WiFi and Digital Video Broadcast (DVB) with a power and silicon area budget that was competitive with a conventional custom ASIC solution. The Arm architecture is the largest computer architecture by volume in the world. It behooves us to ensure that the interface it describes is appropriately defined

A Low-Overhead Script Language for Tiny Networked Embedded Systems

With sensor networks starting to get mainstream acceptance, programmability is of increasing importance. Customers and field engineers will need to reprogram existing deployments and software developers will need to test and debug software in network testbeds. Script languages, which are a popular mechanism for reprogramming in general-purpose computing, have not been considered for wireless sensor networks because of the perceived overhead of interpreting a script language on tiny sensor nodes. In this paper we show that a structured script language is both feasible and efficient for programming tiny sensor nodes. We present a structured script language, SCript, and develop an interpreter for the language. To reduce program distribution energy the SCript interpreter stores a tokenized representation of the scripts which is distributed through the wireless network. The ROM and RAM footprint of the interpreter is similar to that of existing virtual machines for sensor networks. We show that the interpretation overhead of our language is on par with that of existing virtual machines. Thus script languages, previously considered as too expensive for tiny sensor nodes, are a viable alternative to virtual machines

From FPGA to ASIC: A RISC-V processor experience

This work document a correct design flow using these tools in the Lagarto RISC- V Processor and the RTL design considerations that must be taken into account, to move from a design for FPGA to design for ASIC

State of the art baseband DSP platforms for Software Defined Radio: A survey

Software Defined Radio (SDR) is an innovative approach which is becoming a more and more promising technology for future mobile handsets. Several proposals in the field of embedded systems have been introduced by different universities and industries to support SDR applications. This article presents an overview of current platforms and analyzes the related architectural choices, the current issues in SDR, as well as potential future trends.Peer reviewe