Monitor amb control strategies to reduce the impact of process variations in digital circuits

As CMOS technology scales down, Process, Voltage, Temperature and Ageing (PVTA) variations have an increasing impact on the performance and power consumption of electronic devices. These issues may hold back the continuous improvement of these devices in the near future. There are several ways to face the variability problem: to increase the operating margins of maximum clock frequency, the implementation of lithographic friendly layout styles, and the last one and the focus of this thesis, to adapt the circuit to its actual manufacturing and environment conditions by tuning some of the adjustable parameters once the circuit has been manufactured. The main challenge of this thesis is to develop a low-area variability compensation mechanism to automatically mitigate PVTA variations in run-time, i.e. while integrated circuit is running. This implies the development of a sensor to obtain the most accurate picture of variability, and the implementation of a control block to knob some of the electrical parameters of the circuit.A mesura que la tecnologia CMOS escala, les variacions de Procés, Voltatge, Temperatura i Envelliment (PVTA) tenen un impacte creixent en el rendiment i el consum de potència dels dispositius electrònics. Aquesta problemàtica podria arribar a frenar la millora contínua d'aquests dispositius en un futur proper. Hi ha diverses maneres d'afrontar el problema de la variabilitat: relaxar el marge de la freqüència màxima d'operació, implementar dissenys físics de xips més fàcils de litografiar, i per últim i com a tema principal d'aquesta tesi, adaptar el xip a les condicions de fabricació i d'entorn mitjançant la modificació d'algun dels seus paràmetres ajustables una vegada el circuit ja ha estat fabricat. El principal repte d'aquesta tesi és desenvolupar un mecanisme de compensació de variabilitat per tal de mitigar les variacions PVTA de manera automàtica en temps d'execució, és a dir, mentre el xip està funcionant. Això implica el desenvolupament d'un sensor capaç de mesurar la variabilitat de la manera més acurada possible, i la implementació d'un bloc de control que permeti l'ajust d'alguns dels paràmetres elèctrics dels circuits

Hardware / Software Architectural and Technological Exploration for Energy-Efficient and Reliable Biomedical Devices

Nowadays, the ubiquity of smart appliances in our everyday lives is increasingly strengthening the links between humans and machines. Beyond making our lives easier and more convenient, smart devices are now playing an important role in personalized healthcare delivery. This technological breakthrough is particularly relevant in a world where population aging and unhealthy habits have made non-communicable diseases the first leading cause of death worldwide according to international public health organizations. In this context, smart health monitoring systems termed Wireless Body Sensor Nodes (WBSNs), represent a paradigm shift in the healthcare landscape by greatly lowering the cost of long-term monitoring of chronic diseases, as well as improving patients' lifestyles. WBSNs are able to autonomously acquire biological signals and embed on-node Digital Signal Processing (DSP) capabilities to deliver clinically-accurate health diagnoses in real-time, even outside of a hospital environment. Energy efficiency and reliability are fundamental requirements for WBSNs, since they must operate for extended periods of time, while relying on compact batteries. These constraints, in turn, impose carefully designed hardware and software architectures for hosting the execution of complex biomedical applications. In this thesis, I develop and explore novel solutions at the architectural and technological level of the integrated circuit design domain, to enhance the energy efficiency and reliability of current WBSNs. Firstly, following a top-down approach driven by the characteristics of biomedical algorithms, I perform an architectural exploration of a heterogeneous and reconfigurable computing platform devoted to bio-signal analysis. By interfacing a shared Coarse-Grained Reconfigurable Array (CGRA) accelerator, this domain-specific platform can achieve higher performance and energy savings, beyond the capabilities offered by a baseline multi-processor system. More precisely, I propose three CGRA architectures, each contributing differently to the maximization of the application parallelization. The proposed Single, Multi and Interleaved-Datapath CGRA designs allow the developed platform to achieve substantial energy savings of up to 37%, when executing complex biomedical applications, with respect to a multi-core-only platform. Secondly, I investigate how the modeling of technology reliability issues in logic and memory components can be exploited to adequately adjust the frequency and supply voltage of a circuit, with the aim of optimizing its computing performance and energy efficiency. To this end, I propose a novel framework for workload-dependent Bias Temperature Instability (BTI) impact analysis on biomedical application results quality. Remarkably, the framework is able to determine the range of safe circuit operating frequencies without introducing worst-case guard bands. Experiments highlight the possibility to safely raise the frequency up to 101% above the maximum obtained with the classical static timing analysis. Finally, through the study of several well-known biomedical algorithms, I propose an approach allowing energy savings by dynamically and unequally protecting an under-powered data memory in a new way compared to regular error protection schemes. This solution relies on the Dynamic eRror compEnsation And Masking (DREAM) technique that reduces by approximately 21% the energy consumed by traditional error correction codes

Development, Optimisation and Characterisation of a Radiation Hard Mixed-Signal Readout Chip for LHCb

The Beetle chip is a radiation hard, 128 channel pipelined readout chip for silicon strip detectors. The front-end consists of a charge-sensitive preamplifier followed by a CR-RC pulse shaper. The analogue pipeline memory is implemented as a switched capacitor array with a maximum latency of 4us. The 128 analogue channels are multiplexed and transmitted off chip in 900ns via four current output drivers. Beside the pipelined readout path, the Beetle provides a fast discrimination of the front-end pulse. Within this doctoral thesis parts of the radiation hard Beetle readout chip for the LHCb experiment have been developed. The overall chip performances like noise, power consumption, input charge rates have been optimised as well as the elimination of failures so that the Beetle fulfils the requirements of the experiment. Furthermore the characterisation of the chip was a major part of this thesis. Beside the detailed measurement of the chip performance, several irradiation tests and an Single Event Upset (SEU) test were performed. A long-time measurement with a silicon strip detector was also part of this work as well as the development and test of a first mass production test setup. The Beetle chip showed no functional failure and only slight degradation in the analogue performance under irradiation of up to 130Mrad total dose. The Beetle chip fulfils all requirements of the vertex detector (VELO), the trigger tracker (TT) and the inner tracker (IT) and is ready for the start of LHCb end of 2007