An aperture array has antennas that can be deployed in particular geometric patterns to detect radio\u00a0signals at a given range of frequencies. Using an array is beneficial for electrical engineering because\u00a0it can magnify a radio signal in the direction of that signal while suppressing noise and interference\u00a0through a process known as beamforming (see Fig. 1). Lower levels of noise and interference\u00a0leads to better detectability in radar applications, more reliable and robust communications, and\u00a0clearer pictures, for imaging. In addition, an antenna array can be used to detect the directionand distance of the signal\u2019s source. This is known as source localization. Localization is used\u00a0for applications in position, mapping and surveillance. Aperture arrays are a crucial component of\u00a0scientific instruments that measure the spatial distribution of radio sources.<\/p>\n
At the Advanced Signal\u00a0Processing Circuits (ASPC) Lab my students and I investigate aperture array signal processing\u00a0algorithms, circuits and electronics based on multi-dimensional (MD) systems and signal processing\u00a0for applications in microwave and millimeter-wave radio-frequency (RF) antenna array processing.<\/p>\n
Fig. 1. Mathematically computed far-field beam patterns from 3-D cone-filterbank NRPA superimposed from artist’s impression of a Square Kilometer Array (SKA) aperture array with station-level beamforming.<\/p>\n The main idea of our projects funded by the Office of Naval Research (ONR) is the directional\u00a0enhancement of propagating electromagnetic planar waves based on their directions of arrival.\u00a0A particularly relevant example for such electromagnetic \u201cbeamforming\u201d applications is in active electronically-scanned array receivers, which are part of advanced radar sensors used by the\u00a0Department of Defense (DoD). Our proposed MD theory allows new beamformers to be realized\u00a0using novel classes of array processing algorithms, circuits and systems using both analog and\u00a0digital implementation platforms, that may outperform traditional phased-array beamformers\u00a0that are extensively deployed in DoD applications, such as radar and wireless communications.<\/p>\n Imaging Applications for Radio Astronomy<\/strong><\/p>\n Our proposed beamforming techniques show improved steerability, directivity and bandwidth\u00a0compared to traditional phased-array based systems. Our work has led to theoretical developments\u00a0in the field of adaptive algorithms that outperform available beamformers using the properties of\u00a0MD algorithms. We have applied such MD beamforming developments for defense applications.\u00a0Our work will lead to improved beamformers in the presence of excessive interference, noise and\u00a0jamming. Furthermore, we investigate reconfigurable array signal processors, circuits, and systems\u00a0for use in array processor-based antenna apertures for wireless communications,\u00a0localization, and sensor systems. An example is the use of apertures for detection of airborne\u00a0threats having low radar visibility. The research includes the\u00a0investigation of both MD signal processing theory and circuit theory as well as explores practical\u00a0aspects pertaining to analog, digital and mixed-signal VLSI implementation at microwave and\u00a0millimeter wave frequencies.<\/p>\n![\"dense_aperture_array_overview_300dpi\"](\"http:\/\/blogs.uakron.edu\/dharma\/files\/2014\/11\/dense_aperture_array_overview_300dpi.jpg\")
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