Publications

Borchardt, John J.; Lapointe, Tyler C.

Abstract not provided.

Borchardt, John J.; Lapointe, Tyler C.

Abstract not provided.

2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting, IEEECONF 2020 - Proceedings

Borchardt, John J.; Lapointe, Tyler C.

The impedance bandwidth of a microstrip patch antenna may be increased by additional resonances in the antenna structure. This work uses Characteristic Mode Analysis to show that a classic stacked patch design from the literature operates in this manner and that Coupled Mode Theory governs its operation.

Borchardt, John J.; Lapointe, Tyler C.

Abstract not provided.

Lapointe, Tyler C.

Abstract not provided.

Borchardt, John J.; Lapointe, Tyler C.

Abstract not provided.

IEEE Access

Borchardt, John J.; Lapointe, Tyler C.

Patch antennas incorporating a U-shaped slot are well-known to have relatively large (about 30%) impedance bandwidths. This work uses characteristic mode analysis (CMA) to explain the impedance behavior of a classic U-slot patch geometry in terms of coupled mode theory and shows the relevant modes are in-phase and anti-phase coupled modes whose resonant frequencies are governed by coupled mode theory. Additional analysis shows that one uncoupled resonator is the conventional TM01 patch mode and the other is a lumped LC resonator involving the slot and the probe. An equivalent circuit model for the antenna is given wherein element values are extracted from CMA data and which explicitly demonstrates coupling between these two resonators. The circuit model approximately reproduces the impedance locus of the driven simulation. A design methodology based on coupled mode theory and guided by CMA is presented that allows wideband U-slot patch geometries to be designed quickly and efficiently. The methodology is illustrated through example.