Erratum: Corrections to “a broadband microstrip antenna: SGMEP antenna”

## Abstract A novel structure of broadband microstrip antennas, termed the SGMFP antenna, is proposed. It is consisted of a slot in the ground plane, a microstrip feedline supported on a substrate, a foam layer, and a patch. It can achieve broad bandwidth and high polarisation purity. By using a si

Experimental in¨estigations of the impedance characteristics of a capaciti¨ely fed square microstrip antenna are reported. The antenna structure consists of a radiating patch and a small self-complementary patch located between the radiating patch and the ground plane. The small self-complementary p

theoretical analysis.

An amplifier-type acti¨e microstrip antenna, as a transmitting antenna, consisting of a passi¨e broadband slotted triangular microstrip antenna and a coplanar amplifier circuitry for enhanced gain and bandwidth, is demonstrated. The acti¨e microstrip antenna studied ( here is printed on an inexpensi

of Targets Correctly Classified with Respect to the Number of Tests Considered for Different Signal-to-Noise Ratios Signal-to-Noise Ratio Targets Correctly Classified SrN s 50 dB 30r30 SrN s 40 dB 30r30 SrN s 30 dB 28r30 SrN s 20 dB 27r30 than 90%, while for a signal-to-noise ratio greater than 40

The proposed antenna is found to ha¨e a much broader impedance bandwidth as compared to the con¨entional U-slot antenna. An impedance bandwidth of about 33.8% is achie¨ed for the proposed E-plane antenna. Through the use of a washer on the proposed antenna, the probe inductor is compensated, and an