Performance and reliability of SLS ELA polysilicon TFTs fabricated with novel crystallization techniques

SLS ELA polysilicon TFTs fabricated in films crystallized with several novel techniques, yielding different film microstructure and texture, were investigated. The parameter statistics indicate that the TFT performance depends on film quality and asperities, in conjunction with the grain boundary trap density. The drain current transients, upon TFT switch from OFF to ON state, showed gate oxide polarization, related to film asperities and also confirmed the presence of extended defects in the TFTs of small mobilities. DC hot carrier stress was applied, indicating a reliability dependence on polysilicon structure and differences in degradation mechanisms for the various TFT technologies.     

MRE hierarchical decomposition of general queueing network models

Summary The principle of Minimum Relative Entropy (MRE), given fully decomposable subset and aggregate mean queue length, utilisation and flow-balance constraints, is used in conjunction with asymptotic connections to infinite capacity queues, to derive new analytic approximations for the conditional and marginal state probabilities of single class general closed queueing network models (QNMs) in the context of a multilevel variable aggregation scheme. The concept of subparallelism is applied to preserve the flow conservation and a universal MRE hierarchical decomposition algorithm is proposed for the approximate analysis of arbitrary closed queueing networks with single server queues and general service-times. Heuristic criteria towards an optimal coupling of network's units at each level of aggregation are suggested. As an illustration, the MRE algorithm is implemented iteratively by using the Generalised Exponential (GE) distributional model to approximate the service and asymptotic flow processes in the network. This algorithm captures the exact solution of separable queueing networks, while for general queueing networks it compares favourably against exact solutions and known approximations.This work is sponsored by the Science and Engineering Research Council (SERC), UK, under grant GR/F29271     

Mathematical methods for the modular design of computer systems

An approach to modular design is proposed, involving the estimation of the information transfer between the modules of acomplex system.In apreviouspaper[l], a general decomposition criterion was derived, employing the entropy function as a measure of the amount of information contained within a system or subsystems. This paper concerns the formulation of an algorithm for the optimisation of the criterion which decomposes hierarchically a system into its most independent subsystems or modules. A simple illustrative example is given and further, the design methodology is applied to detect the modular structure of a computer teaching system.     

Performance modelling and cost-effective analysis of multiserviceintegrated networks

The performance prediction and quantitative analysis of multiservice integrated networks are extremely important in view of their ever expanding usage and the multiplicity of their component parts together with the complexity of their functioning. Queueing network models (QNMs) are widely recognised as powerful and realistic tools for representing these systems as complex networks of queues and servers and optimising their performance. This paper highlights the use of cost-effective methodologies as applied to performance modelling studies involving QNMs of asynchronous transfer mode (ATM) switch architectures with bursty and/or correlated traffic. These methodologies offer simple and practical means for performance evaluation and prediction and have their roots in the principle of maximum entropy (ME), queueing theoretic concepts and batch renewal processes for traffic characterisation. Comments on current theoretical advances and future research work are included     

Entropy maximised queueing networks with blocking and multiple job classes

The method of entropy maximisation (MEM) is applied in a state space partitioning mode for the approximation of the joint stationary queue length distribution of an M/M/1/N queue with finite capacity, N( > 1), multiple and distinct classes of jobs, R( > 1), under a complete buffer sharing scheme and mixed service disciplines drawn from the first-come-first-served (FCFS), last-come-first-served with (LCFS-PR) or without (LCFS-NPR) preemption and processor sharing (PS) rules. The marginal and aggregate maximum entropy (ME) queue length distributions and the associated blocking probabilities per class are also determined. These ME results in conjunction with the first moments of the effective flows are used, as building blocks, in order to establish a new product-form approximation for arbitrary exponential open queueing networks with multiple classes of jobs under repetitive-service (RS) blocking with random destination (RD). It is verified that the ME approximation reduces to the exact truncated solution of open multi-class reversible queueing networks. Numerical experiments demonstrate a good accuracy level of ME statistics in relation to simulation. Moreover, recent extentions of MEM for arbitrary GE-type queueing networks with RS-RD blocking and multiple classes of jobs are presented.     

Performance analysis of a dynamic handoff scheme in wireless networks with heterogeneous call arrival processes

The Guard Channel Scheme (GCS) and Handoff Queueing Scheme (HQS) are the popular and practical strategies to prioritize handoff calls in wireless cellular networks. A key issue of giving handoff calls the higher priority is how to achieve a tradeoff among the handoff call blocking probability, new call blocking probability and handoff delay. This paper extends GCS and HQS and presents an efficient handoff scheme that dynamically manages the channels reserved for handoff calls depending on the current status of the handoff queue. A three-dimensional Markov model is developed to analyze the performance of this scheme and investigate the desirable performance tradeoff. The Poisson process and Markov-Modulated-Poisson-Process (MMPP) are used to model the arrival processes of new and handoff calls, respectively. The accuracy of this model is evaluated through the extensive comparison of the analytical results to those obtained from discrete-event simulation experiments. Performance measures in terms of the mean number of calls in the system, aggregate response time, aggregate call blocking probability, handoff call blocking probability, new call blocking probability and handoff delay are evaluated. The analytical model is used to investigate the effects of the number of channels originally reserved for handoff calls, the number of dynamic channels, and the ratio of the rate of handover calls to the aggregate arrival rate on the system performance.     

Characteristics of W and Cu/W gate MOS diodes fabricated by a process utilizing LPCVD of W and Cu lift-off

MOS diodes having double layer Cu/W, W, or Al gates were fabricated using tungsten chemical vapor deposition, copper evaporation and lift-off and were characterized before and after thermal anneals. The breakdown field statistics were determined for all kinds of devices, while the high field conduction and charge trapping in the oxide were investigated. The W gate devices exhibited high performance and very low degradation even after annealing at 650 °C. In Cu/W gate diodes good barrier action of our LPCVD tungsten films against copper penetration after annealing at 510 °C was observed, while reduced breakdown integrity and degradation due to copper diffusion occurred after annealing at 650 °C.     

An experimental study of the thermally activated processes in polycrystalline silicon thin film transistors

The thermally activated mechanisms that determine the electrical properties of polycrystalline silicon thin film transistors have been investigated. The study employed devices fabricated on long grains and different thickness polycrystalline films, which were obtained by excimer laser annealing crystallization. The transfer and the transient characteristics have been recorded and analysed in the linear operation regime. The temperature dependence of basic parameters such as leakage current, subthreshold swing and drain current overshoot transient amplitude was found to stem from the same thermally activated carriers generation mechanism. The dependence of thermally activated mechanisms on the film thickness suggests that the device operation is strongly related to polycrystalline material properties.