Side-channel attacks and countermeasures in the design of secure IC's devices for cryptographic applications

Abstract--- A lot of devices which are daily used have to guarantee the retention of sensible data. Sensible data are ciphered by a secure key by which only the key holder can get the data. For this reason, to protect the cipher key against possible attacks becomes a main issue. The research activities in hardware cryptography are involved in finding new countermeasures against various attack scenarios and, in the same time, in studying new attack methodologies. During the PhD, three different logic families to counteract Power Analysis were presented and a novel class of attacks was studied. Moreover, two different activities related to Random Numbers Generators have been addressed

Investigation into the wafer-scale integration of fine-grain parallel processing computer systems

This thesis was submitted for the degree of Doctor of Philosophy and awarded by Brunel University.This thesis investigates the potential of wafer-scale integration (WSI) for the implementation of low-cost fine-grain parallel processing computer systems. As WSI is a relatively new subject, there was little work on which to base investigations. Indeed, most WSI architectures existed only as untried and sometimes vague proposals. Accordingly, the research strategy approached this problem by identifying a representative WSI structure and architecture on which to base investigations. An analysis of architectural proposals identified associative memory to be general purpose parallel processing component used in a wide range of WSI architectures. Furthermore, this analysis provided a set of WSI-level design requirements to evaluate the sustainability of different architectures as research vehicles. The WSI-ASP (WASP) device, which has a large associative memory as its main component is shown to meet these requirements and hence was chosen as the research vehicle. Consequently, this thesis addresses WSI potential through an in-depth investigation into the feasibility of implementing a large associative memory for the WASP device that meets the demanding technological constraints of WSI. Overall, the thesis concludes that WSI offers significant potential for the implementation of low-cost fine-grain parallel processing computer systems. However, due to the dual constraints of thermal management and the area required for the power distribution network, power density is a major design constraint in WSI. Indeed, it is shown that WSI power densities need to be an order of magnitude lower than VLSI power densities. The thesis demonstrates that for associative memories at least, VLSI designs are unsuited to implementation in WSI. Rather, it is shown that WSI circuits must be closely matched to the operational environment to assure suitable power densities. These circuits are significantly larger than their VLSI equivalents. Nonetheless, the thesis demonstrates that by concentrating on the most power intensive circuits, it is possible to achieve acceptable power densities with only a modest increase in area overheads.SER

FBsim and the Fully Buffered DIMM Memory System Architecture

As DRAM device data rates increase in chase of ever increasing memory request rates, parallel bus limitations and cost constraints require a sharp decrease in load on the multi-drop buses between the devices and the memory controller, thus limiting the memory system's scalability and failing to meet the capacity requirements of modern server and workstation applications. A new technology, the Fully Buffered DIMM architecture is currently being introduced to address these challenges. FB-DIMM uses narrower, faster, buffered point to point channels to meet memory capacity and throughput requirements at the price of latency. This study provides a detailed look at the proposed architecture and its adoption, introduces an FB-DIMM simulation model - the FBSim simulator - and uses it to explore the design space of this new technology - identifying and experimentally proving some of its strengths, weaknesses and limitations, and uncovering future paths of academic research into the field

NASA Space Engineering Research Center Symposium on VLSI Design

The NASA Space Engineering Research Center (SERC) is proud to offer, at its second symposium on VLSI design, presentations by an outstanding set of individuals from national laboratories and the electronics industry. These featured speakers share insights into next generation advances that will serve as a basis for future VLSI design. Questions of reliability in the space environment along with new directions in CAD and design are addressed by the featured speakers

A High Dynamic Range CMOS Image Sensor with Adaptive Integration Time Control

The scope of this thesis encompasses the development and testing of a CMOS based image sensor. The imaging process consists of the integration of the photocurrent generated by incident light in each pixel. The implementation of a concept for adaptive regulation of the local integration time allows imaging of high dynamic range scenes without loss of information due to over- or underexposure. Depending on the size of the integrated memory, the proposed concept allows the specification of a freely movable image region within which the integration time is regulated. At a chosen maximum integration time of 33ms the dynamic range of the sensor amounts to 134dB and covers a range of intensities from 1mW/m^2 to 5kW/m^2. The prototype consists of 170x170 pixels with a high dynamic region of 85x85 pixels. The additionally implemented ability to average neighboring pixels allows an expansion of the high dynamic range region over the entire extent of the sensor. An on-chip double sampling circuitry reduces the fixed pattern noise caused by unavoidable device-to-device mismatch

Reconfigurable G and C computer study for space station use. Volume 2 - Final technical report Final report, 29 Dec. 1969 - 31 Jan. 1971

Design and development of reconfigurable guidance and control computer for space station applications - Vol.

Energy Efficient Servers

Computer scienc

The 1991 3rd NASA Symposium on VLSI Design

Papers from the symposium are presented from the following sessions: (1) featured presentations 1; (2) very large scale integration (VLSI) circuit design; (3) VLSI architecture 1; (4) featured presentations 2; (5) neural networks; (6) VLSI architectures 2; (7) featured presentations 3; (8) verification 1; (9) analog design; (10) verification 2; (11) design innovations 1; (12) asynchronous design; and (13) design innovations 2