Analysis and Development of A Trusted Low Dropout Regulator (LDO) Model For Intellectual Property (IP) Reuse Aiming at System Verification

Liu, Wei

29 September 2014

No description available.

Electrical Engineering

Improving Bug Visibility using System-Level Assertions and Transactions

Barber, Kristin M.

21 October 2013

No description available.

Computer Engineering

Transaction-Level Modeling TLM

Verification

Debug

System-on-Chip SoC

High performance on-chip array antenna based on metasurface feeding structure for terahertz integrated circuits

Alibakhshikenari, M., Virdee, B.S., See, C.H., Abd-Alhameed, Raed, Limiti, E.

06 1900

Yes / In this letter a novel on-chip array antenna is investigated which is based on CMOS 20μm Silicon technology for operation over 0.6-0.65 THz. The proposed array structure is constructed on three layers composed of Silicon-Ground-Silicon layers. Two antennas are implemented on the top layer, where each antenna is constituted from three sub-antennas. The sub-antennas are constructed from interconnected dual-rings. Also, the sub-antennas are interconnected to each other. This approach enhances the aperture of the array. Surface waves and substrate losses in the structure are suppressed with metallic via-holes implemented between the radiation elements. To excite the structure, a novel feeding mechanism is used comprising open-circuited microstrip lines that couple electromagnetic energy from the bottom layer to the antennas on the top-layer through metasurface slot-lines in the middle ground-plane layer. The results show the proposed on-chip antenna array has an average radiation gain, efficiency, and isolation of 7.62 dBi, 32.67%, and -30 dB, respectively. / H2020-MSCA-ITN-2016 SECRET-722424 and the financial support from the UK Engineering and Physical Sciences Research Council (EPSRC) under grant EP/E0/22936/1

Array antenna

Metasurface

Terahertz IC

Antenna arrays

System-on-chip

Silicon

Dipole antennas

Antenna feeds

Slot antennas

Metamodeling Driven IP Reuse for System-on-chip Integration and Microprocessor Design

Mathaikutty, Deepak Abraham

02 December 2007

This dissertation addresses two important problems in reusing intellectual properties (IPs) in the form of reusable design or verification components. The first problem is associated with fast and effective integration of reusable design components into a System-on-chip (SoC), so faster design turn-around time can be achieved, leading to faster time-to-market. The second problem has the same goals of faster product design cycle, but emphasizes on verification model reuse, rather than design component reuse. It specifically addresses reuse of reusable verification IPs to enable a "write once, use many times" verification strategy. This dissertation is accordingly divided into part I and part II which are related but describe the two problems and our solutions to them. These two related but distinctive problems faced by system design companies have been tackled through a unique approach which hither-to-fore only have been used in the software engineering domain. This approach is called metamodeling, which allows creating customized meta-language to describe the syntax and semantics for a modeling domain. It provides a way to create, transform and analyze domain specific languages, which are themselves described by metamodels, and the transformation and processing of models in such languages are also described by metamodels. This makes machine based interpretation and translation from these models an easier and formal task. In part I, we consider the problem of rapid system-level model integration of existing reusable components such that (i) the required architecture of the SoC can be expressed formally, (ii) automatic selection of components from an IP library to match the need of the system being integrated can be done, (iii) integrability of the components is provable, or checkable automatically, and (iv) structural and behavioral type systems for each component can be utilized through inferencing and matching techniques to ensure their compatibility. Our solutions include a component composition language, algorithms for component selection, type matching and inferencing algorithms, temporal property based behavioral typing, and finally a software system on top of an existing metamodeling environment. In part II, we use the same metamodeling environment to create a framework for modeling generative verification IPs. Our main contributions relate to INTEL's microprocessor verification environment, and our solution spans various abstraction levels (System, architectural, and microarchitecture) to perform verification. We provide a unified language that can be used to model verification IPs at all abstraction levels, and verification collaterals such as testbenches, simulators, and coverage monitors can be generated from these models, thereby enhancing reuse in verification. / Ph. D.

ESTEREL

SystemC

System On Chip

Microprocessor

Metamodeling

Model-driven Design and Validation

Type inference

Reflection

Metamodel

Coverage metric

Enhancing Input/Output Correctness, Protection, Performance, and Scalability for Process Control Platforms

Burrow, Ryan David

07 June 2019

Most modern control systems use digital controllers to ensure safe operation. We modify the traditional digital control system architecture to integrate a new component known as a trusted input/output processor (TIOP). TIOP interface to the inputs (sensors) and outputs (actuators) of the system through existing communication protocols. The TIOP also interface to the application processor (AP) through a simple message passing protocol. This removes any direct input/output (I/O) interaction from taking place in the AP. By isolating this interaction from the AP, system resilience against malware is increased by enabling the ability to insert run-time monitors to ensure correct operation within provided safe limits. These run-time monitors can be located in either the TIOP(s) or in independent hardware. Furthermore, monitors have the ability to override commands from the AP should those commands seek to violate the safety requirements of the system. By isolating I/O interaction, formal methods can be applied to verify TIOP functionality, ensuring correct adherence to the rules of operation. Additionally, removing sequential I/O interaction in the AP allows multiple I/O operations to run concurrently. This reduces I/O latency which is desirable in many control systems with large numbers of sensors and actuators. Finally, by utilizing a hierarchical arrangement of TIOP, scalable growth is efficiently supported. We demonstrate this on a Xilinx Zynq-7000 programmable system-on-chip device. / Master of Science / Complex modern systems, from unmanned aircraft system to industrial plants are almost always controlled digitally. These digital control systems (DCSes) need to be verified for correctness since failures can have disastrous consequences. However, proving that a DCS will always act correctly can be infeasible if the system is too complex. In addition, with the growth of inter-connectivity of systems through the internet, malicious actors have more access than ever to attempt to cause these systems to deviate from their proper operation. This thesis seeks to solve these problems by introducing a new architecture for DCSes that uses isolated components that can be verified for correctness. In addition, safety monitors are implemented as a part of the architecture to prevent unsafe operation.

digital control system

programmable system-on-chip

model checking

input/output processor

malware resilience

Using High-level Synthesis to Predict and Preempt Attacks on Industrial Control Systems

Franklin, Zane Ryan

21 April 2014

As the rate and severity of malicious software attacks have escalated, industrial control systems (ICSes) have emerged as a particularly vulnerable target. ICSes govern the automation of the physical processes in industries such as power, water, oil and manufacturing. In contrast to the personal computing space, where attackers attempt to capture information or computing resources, the attacks directed at ICSes aim to degrade or destroy the physical processes or plants maintained by the ICS. Exploits with potentially catastrophic results are sold on brokerages to any interested party. Previous efforts in ICS security implicitly and mistakenly trust internal software. This thesis presents an architecture for trust enhancement of critical embedded processes (TECEP). TECEP assumes that all software can be or has already been compromised. Trust is instead placed in hardware that is invisible to any malicious software. Software processes critical for stable operation are duplicated in hardware, along with a supervisory process to monitor the behavior of the plant. Furthermore, a copy of the software and a model of the plant are implemented in hardware in order to estimate the system's future behavior. In the event of an attack, the hardware can successfully identify the plant's abnormal behavior in either the present or the future and supersede the software's directives, allowing the plant to continue functioning correctly. This approach to ICS security can be retrofitted to existing ICSes, has minimal impact on the ICS design process, and modestly increases hardware requirements in a programmable system-on-chip. / Master of Science

Industrial control systems

security

reconfigurable platform

high-level synthesis

system-on-chip

Efficiency of Logic Minimization Techniques for Cryptographic Hardware Implementation

Raghuraman, Shashank

15 July 2019

With significant research effort being directed towards designing lightweight cryptographic primitives, logical metrics such as gate count are extensively used in estimating their hardware quality. Specialized logic minimization tools have been built to make use of gate count as the primary optimization cost function. The first part of this thesis aims to investigate the effectiveness of such logical metrics in predicting hardware efficiency of corresponding circuits. Mapping a logical representation onto hardware depends on the standard cell technology used, and is driven by trade-offs between area, performance, and power. This work evaluates aforementioned parameters for circuits optimized for gate count, and compares them with a set of benchmark designs. Extensive analysis is performed over a wide range of frequencies at multiple levels of abstraction and system integration, to understand the different regions in the solution space where such logic minimization techniques are effective. A prototype System-on-Chip (SoC) is designed to benchmark the performance of these circuits on actual hardware. This SoC is built with an aim to include multiple other cryptographic blocks for analysis of their hardware efficiency. The second part of this thesis analyzes the overhead involved in integrating selected authenticated encryption ciphers onto an SoC, and explores different design alternatives for the same. Overall, this thesis is intended to serve as a comprehensive guideline on hardware factors that can be overlooked, but must be considered during logical-to-physical mapping and during the integration of standalone cryptographic blocks onto a complete system. / Master of Science / The proliferation of embedded smart devices for the Internet-of-Things necessitates a constant search for smaller and power-efficient hardware. The need to ensure security of such devices has been driving extensive research on lightweight cryptography, which focuses on minimizing the logic footprint of cryptographic hardware primitives. Different designs are optimized, evaluated, and compared based on the number of gates required to express them at a logical level of abstraction. The expectation is that circuits requiring fewer gates to represent their logic will be smaller and more efficient on hardware. However, converting a logical representation into a hardware circuit, known as “synthesis”, is not trivial. The logic is mapped to a “library” of hardware cells, and one of many possible solutions for a function is selected - a process driven by trade-offs between area, speed, and power consumption on hardware. Our work studies the impact of synthesis on logical circuits with minimized gate count. We evaluate the hardware quality of such circuits by comparing them with that of benchmark designs over a range of speeds. We wish to answer questions such as “At what speeds do logical metrics rightly predict area- and power-efficiency?”, and “What impact does this have after integrating cryptographic primitives onto a complete system?”. As part of this effort, we build a System-on-Chip in order to observe the efficiency of these circuits on actual hardware. This chip also includes recently developed ciphers for authenticated encryption. The second part of this thesis explores different ways of integrating these ciphers onto a system, to understand their effect on the ciphers’ compactness and performance. Our overarching aim is to provide a suitable reference on how synthesis and system integration affect the hardware quality of cryptographic blocks, for future research in this area.

Logic synthesis

Cryptographic hardware

Circuit minimization

Leon-3

System-on-Chip

Authenticated encryption hardware

Balancing Performance, Area, and Power in an On-Chip Network

Gold, Brian

06 August 2003

Several trends can be observed in modern microprocessor design. Architectures have become increasingly complex while design time continues to dwindle. As feature sizes shrink, wire resistance and delay increase, limiting architects from scaling designs centered around a single thread of execution. Where previous decades have focused on exploiting instruction-level parallelism, emerging applications such as streaming media and on-line transaction processing have shown greater thread-level parallelism. Finally, the increasing gap between processor and off-chip memory speeds has constrained performance of memory-intensive applications. The Single-Chip Message Passing (SCMP) parallel computer sits at the confluence of these trends. SCMP is a tiled architecture consisting of numerous thread-parallel processor and memory nodes connected through a structured interconnection network. Using an interconnection network removes global, ad-hoc wiring that limits scalability and introduces design complexity. However, routing data through general purpose interconnection networks can come at the cost of dedicated bandwidth, longer latency, increased area, and higher power consumption. Understanding the impact architectural decisions have on cost and performance will aid in the eventual adoption of general purpose interconnects. This thesis covers the design and analysis of the on-chip network and its integration with the SCMP system. The result of these efforts is a framework for analyzing on-chip interconnection networks that considers network performance, circuit area, and power consumption. / Master of Science

area

virtual channels

SCMP

power

network

router

crossbar switch

single chip computer

message passing

system on chip

On-Chip Memory Architecture Exploration Of Embedded System On Chip

Kumar, T S Rajesh

09 1900

Today’s feature-rich multimedia products require embedded system solution with complex System-on-Chip (SoC) to meet market expectations of high performance at low cost and lower energy consumption. SoCs are complex designs with multiple embedded processors, memory subsystems, and application specific peripherals. The memory architecture of embedded SoCs strongly influences the area, power and performance of the entire system. Further, the memory subsystem constitutes a major part (typically up to 70%) of the silicon area for the current day SoC. The on-chip memory organization of embedded processors varies widely from one SoC to another, depending on the application and market segment for which the SoC is deployed. There is a wide variety of choices available for the embedded designers, starting from simple on-chip SPRAM based architecture to more complex cache-SPRAM based hybrid architecture. The performance of a memory architecture also depends on how the data variables of the application are placed in the memory. There are multiple data layouts for each memory architecture that are efficient from a power and performance viewpoint. Further, the designer would be interested in multiple optimal design points to address various market segments. Hence a memory architecture exploration for an embedded system involves evaluating a large design space in the order of 100,000 of design points and each design points having several tens of thousands of data layouts. Due to its large impact on system performance parameters, the memory architecture is often hand-crafted by experienced designers exploring a very small subset of this design space. The vast memory design space prohibits any possibility for a manual analysis. In this work, we propose an automated framework for on-chip memory architecture exploration. Our proposed framework integrates memory architecture exploration and data layout to search the design space efficiently. While the memory exploration selects specific memory architectures, the data layout efficiently maps the given application on to the memory architecture under consideration and thus helps in evaluating the memory architecture. The proposed memory exploration framework works at both logical and physical memory architecture level. Our work addresses on-chip memory architecture for DSP processors that is organized as multiple memory banks, with each back can be a single/dual port banks and with non-uniform bank sizes. Further, our work also address memory architecture exploration for on-chip memory architectures that is SPRAM and cache based. Our proposed method is based on multi-objective Genetic Algorithm based and outputs several hundred Pareto-optimal design solutions that are interesting from a area, power and performance viewpoints within a few hours of running on a standard desktop configuration.

Very Large Scale Integration

Genetic Algorithm

Embedded System-On-Chip

Memory Subsystem Optimization

Embedded Systems - Data Layout

On-Chip Memory Architecture

System-on-Chip (SoC)

Embedded Systems

Embedded SoC

Logical Memory Exploration

Physical Memory Exploration

Data Layout Exploration

Computer Engineering

Compilation d'applications flot de données paramétriques pour MPSoC dédiés à la radio logicielle / Compilation of Parametric Dataflow Applications for Software-Defined-Radio-Dedicated MPSoCs

Dardaillon, Mickaël

19 November 2014

Le développement de la radio logicielle fait suite à l’évolution rapide du domaine des télécommunications. Les besoins en performance et en dynamicité ont donné naissance à des MPSoC dédiés à la radio logicielle. La spécialisation de ces MPSoC rend cependant leur pro- grammation et leur vérification complexes. Des travaux proposent d’atténuer cette complexité par l’utilisation de paradigmes tels que le modèle de calcul flot de données. Parallèlement, le besoin de modèles flexibles et vérifiables a mené au développement de nouveaux modèles flot de données paramétriques. Dans cette thèse, j’étudie la compilation d’applications utilisant un modèle de calcul flot de données paramétrique et ciblant des plateformes de radio logicielle. Après un état de l’art du matériel et logiciel du domaine, je propose un raffinement de l’ordonnancement flot de données, et présente son application à la vérification des tailles mémoires. Ensuite, j’introduis un nouveau format de haut niveau pour définir le graphe et les acteurs flot de données, ainsi que le flot de compilation associé. J’applique ces concepts à la génération de code optimisé pour la plateforme de radio logicielle Magali. La compilation de parties du protocole LTE permet d’évaluer les performances du flot de compilation proposé. / The emergence of software-defined radio follows the rapidly evolving telecommunication domain. The requirements in both performance and dynamicity has engendered software- defined-radio-dedicated MPSoCs. Specialization of these MPSoCs make them difficult to program and verify. Dataflow models of computation have been suggested as a way to mi- tigate this complexity. Moreover, the need for flexible yet verifiable models has led to the development of new parametric dataflow models. In this thesis, I study the compilation of parametric dataflow applications targeting software-defined-radio platforms. After a hardware and software state of the art in this field, I propose a new refinement of dataflow scheduling, and outline its application to buffer size’s verification. Then, I introduce a new high-level format to define dataflow actors and graph, with the associated compilation flow. I apply these concepts to optimised code generation for the Magali software-defined-radio platform. Compilation of parts of the LTE protocol are used to evaluate the performances of the proposed compilation flow.

Télécommunications

Radio logicielle

Flot de données

Système embarqué

Multiprocessor System-On-Chip - MPSoC

Compilation de données

Protocole LTE

Telecommunications

Software radio

Data Flow

Embedded System

Multiprocessor System-On-Chip - MPSoC

Data compilation

LTE Protocol

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