175 research outputs found
Rapid Approximation of Bilinear Forms Involving Matrix Functions Through Asymptotic Analysis of Gaussian Node Placement
Technological advancements have allowed computing power to generate high resolution model s. As a result, greater stiffness has been introduced into systems of ordinary differential equations (ODEs) that arise from spatial discreti zation of partial differential equations (PDEs). The components of the solutions to these systems are coupled and changing at widely varying rates, which present problems for time-stepping methods. Krylov Subspace Spectral methods, developed by Dr. James Lambers, bridge the gap between explicit and implicit methods for stiff problems by computing each Fouier coefficient from an individualized approximation of the solution operator. KSS methods demonstrate a high order of accuracy, but their efficiency needs to be improved. We will carry out an asymptotic study to determine how these approximations behave at high frequencies to develop a formula to reduce the computation of each node while still achieving a high level of accuracy. Our numerical results will reveal that our method does prove to increase the efficiency as well as the accuracy of KSS methods
User-Generated Patterns to Initiate Electronic System Reset
An electronic device generates a hard-reset signal after receiving a sequential input via various sensors or a power supply of the electronic device. The sensors include components that measure physical characteristics or attributes like pressure, acceleration, temperature, light, rotation, changes in a magnetic field, or electricity. The sensors or the power supply generally serve other purposes in the electronic device, and the sequential input prevents an accidental or inadvertent hard-reset signal
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