BEGIN:VCALENDAR VERSION:2.0 PRODID:-//132.216.98.100//NONSGML kigkonsult.se iCalcreator 2.20.4// BEGIN:VEVENT UID:20260521T063401EDT-8026uZGIFN@132.216.98.100 DTSTAMP:20260521T103401Z DESCRIPTION:Abstract\n\nElectrical noise sets a fundamental limit on the pe rformance of electronic systems\, particularly in high-sensitivity applica tions such as radio-frequency receivers. As circuit complexity continues t o grow\, there is a critical need for faster and more scalable noise analy sis methods in circuit simulators. Although time-domain transient noise an alysis offers broader applicability than frequency-domain and time-domain steady-state noise analysis\, it is typically more computationally expensi ve\, especially for large circuits. This challenge is intensified by flick er noise\, whose inclusion in a time-domain circuit formulation greatly in creases the effective size of the system. To address these efficiency prob lems\, this dissertation presents several transient noise analysis methods . Using parallel computing and innovative continuous-time and discrete-tim e modeling approaches\, these methods achieve significant improvements in computational efficiency compared to state-of-the-art methods.\n\nCovarian ce analysis is an effective technique for simulating transient noise in sm all subblocks of larger circuit designs due to its accuracy and reasonable simulation times. However\, its computational efficiency deteriorates as circuit size increases. To improve scalability and reduce simulation times \, this dissertation first presents a parallel covariance analysis method. It also introduces a new flicker noise time-domain circuit representation that mitigates the added system complexity associated with modeling flick er noise sources in covariance analysis. Furthermore\, an adjoint-based ap proach is offered to improve the computational efficiency of the parallel covariance analysis method. This dissertation then presents a charge-based covariance analysis method that models nonlinear capacitors using charge rather than voltage in a linearized time-domain noise-perturbed circuit fo rmulation. This approach achieves higher numerical accuracy than tradition al capacitance-based methods\, allowing larger simulation step sizes and c onsequently reducing simulation times. Finally\, a charge-based covariance analysis method derived using implicit numerical schemes for stochastic d ifferential equations is introduced. By modeling the discrete-time evoluti on of the covariance\, this method provides a more computationally efficie nt and scalable alternative to continuous-time formulations.\n DTSTART:20260526T130000Z DTEND:20260526T150000Z LOCATION:Room 603\, McConnell Engineering Building\, CA\, QC\, Montreal\, H 3A 0E9\, 3480 rue University SUMMARY:PhD defence of Alex Goulet – Covariance-Based Methods for Computati onally Efficient Transient Noise Analysis in Electronic Circuits URL:/ece/channels/event/phd-defence-alex-goulet-covari ance-based-methods-computationally-efficient-transient-noise-analysis-3728 84 END:VEVENT END:VCALENDAR