Collecting signatures to model latency tolerance in high-level simulations of microthreaded cores

The current many-core architectures are generally evaluated by a detailed emulation with a cycle-accurate simulation of the execution time. However this detailed simulation of the architecture makes the evaluation of large programs very slow. Since the focus in many-core architecture is shifting from the performance of the individual core to the overall behavior of chip, high-level simulations are becoming neces- sary, which evaluate the same architecture at less detailed level and allow the designer to make quick and reasonably accurate design decisions. We have developed a high-level simulator for the design space exploration of the Microgrid, which is a many-core architecture comprised of many fine- grained multi-threaded cores. This simulator allows us to investigate mapping and scheduling strategies of families (i.e. groups of threads) in developing an operating environ- ment for the Microgrid. The previous method to evaluate the workload counted in basic blocks was inaccurate. The key problem is that with many concurrent threads the la- tency of certain instructions are hidden because of the multi- threaded nature of the core. This paper presents a technique to manage the execution time of different types of instruc- tions with thread concurrency. We believe to achieve high accuracy in evaluating programs in the high-level simulator

On Application of Wireless Sensor Networks for Healthcare Monitoring

With the recent advances in embedded systems and very low power ,wireless tech­ nologies, there has been a great interest in the development and application of a new class of distributed Wireless body area network for health monitoring. The first part of the thesis presents a remote patient monitoring system within the scope of Body Area Network standardization. In this regime, wireless sensor networks are used to continuously acquire the patient’s Electrocardiogram signs and transmit data to the base station via IEEE.802.15. The personal Server (PS) which is responsible to provide real-time displaying, storing, and analyzing the patient’s vital signs is developed in MATLAB. It also transfers ECG streams in real-time to a remote client such as a physician or medical center through internet. The PS has the potential to be integrated with home or hospital computer systems. A prototype of this system has been developed and implemented. Tlie developed system takes advantage of two important features for healthcare monitoring: (i) ECG data acqui­ sition using wearable sensors and (ii) real-time data remote through internet. The fact that our system is interacting with sensor network nodes using MATLAB makes it distinct from other previous works. The second part is devoted to the study of indoor body-area channel model for 2.4 GHz narrowband communications. To un­ derstand the narrowband radio propagation near the body, several measurements are carried out in two separate environments for different on body locations. On the basis of these measurements, we have characterized the fading statistics on body links and we have provided a physical interpretation of our results