acem-web/main/applications.md

---
layout: banner
title: Applications
permalink: /applications/

cardTitle: Topics
cardDesc: We tackle a broad set of problems relating to the electromagnetic phenomena, from antennas and propagation, to electromagnetic interference/compatiblity, to wireless communication.
---

{: .alignCenter }
# Engineering Applications

<!--ITEM-->

## Full-Wave Field Solvers for Signal Integrity (SI) and EM Interference (EMI) Analysis of Product-Level Integrated Circuits (ICs) and Electronics

Ever-increasing complexity in high-speed electronic devices and systems presents significant computational challenges in numerical analysis in terms of desired accuracy, efficiency, and scalable parallelism. We investigate high-resolution, high-performance full-wave field solvers for scalable electromagnetic simulations of product-level integrated circuits (ICs) and electronics.

[Read More](/applications/SIEMI/)

![IEMIMotivation](/assets/images/research/Intra-System-EMIEMC/IEMI-2.png)

<!--ITEM-->

## Stochastic Wave Model Statistically Replicating Reverberation Chambers

We present a novel physics-oriented statistical representation for complex multipath environments, and develop a hybrid deterministic and stochastic formulation incorporating component-specific features. The advancements lead to a stochastic wave model statistically replicating mode-stirred reverberation chambers, and establish an imperative design-under-chaos capability for electronic devices and systems. The research work is evaluated and validated through representative experiments.

[Read More](/applications/reverberation-chamber/)

![RCMotivation](/assets/images/research/RC/IC_COE_Cavity_Result2.png)


<!--ITEM-->

## Deterministic and Statistical Modeling of Wireless Channel

we present a full-wave field-based computational methodology for radio wave propagation in complex urban environments. Both transmitting/receiving antennas and propagation environments are modeled by first-principles calculations. System-level, large scene analysis is enabled by scalable, ultra-parallel algorithms on emerging high-performance computing platforms. The proposed computational framework is verified and validated with semi-analytical models and representative measurements. 

[Read More](/applications/statistical-channel/)

![Wireless](/assets/images/research/ABQFullWave.png)

<!--ITEM-->
Added website content 2 years ago			`---`
			`layout: banner`
			`title: Applications`
			`permalink: /applications/`

			`cardTitle: Topics`
			`cardDesc: We tackle a broad set of problems relating to the electromagnetic phenomena, from antennas and propagation, to electromagnetic interference/compatiblity, to wireless communication.`
			`---`

			`{: .alignCenter }`
			`# Engineering Applications`

			`<!--ITEM-->`

			`## Full-Wave Field Solvers for Signal Integrity (SI) and EM Interference (EMI) Analysis of Product-Level Integrated Circuits (ICs) and Electronics`

			`Ever-increasing complexity in high-speed electronic devices and systems presents significant computational challenges in numerical analysis in terms of desired accuracy, efficiency, and scalable parallelism. We investigate high-resolution, high-performance full-wave field solvers for scalable electromagnetic simulations of product-level integrated circuits (ICs) and electronics.`

			`[Read More](/applications/SIEMI/)`

			`![IEMIMotivation](/assets/images/research/Intra-System-EMIEMC/IEMI-2.png)`

			`<!--ITEM-->`

			`## Stochastic Wave Model Statistically Replicating Reverberation Chambers`

			`We present a novel physics-oriented statistical representation for complex multipath environments, and develop a hybrid deterministic and stochastic formulation incorporating component-specific features. The advancements lead to a stochastic wave model statistically replicating mode-stirred reverberation chambers, and establish an imperative design-under-chaos capability for electronic devices and systems. The research work is evaluated and validated through representative experiments.`

			`[Read More](/applications/reverberation-chamber/)`

			`![RCMotivation](/assets/images/research/RC/IC_COE_Cavity_Result2.png)`


			`<!--ITEM-->`

			`## Deterministic and Statistical Modeling of Wireless Channel`

			`we present a full-wave field-based computational methodology for radio wave propagation in complex urban environments. Both transmitting/receiving antennas and propagation environments are modeled by first-principles calculations. System-level, large scene analysis is enabled by scalable, ultra-parallel algorithms on emerging high-performance computing platforms. The proposed computational framework is verified and validated with semi-analytical models and representative measurements.`

			`[Read More](/applications/statistical-channel/)`

			`![Wireless](/assets/images/research/ABQFullWave.png)`

			`<!--ITEM-->`