A significantly miniaturised meandered loop on‐chip antenna (MeLOCA) for communication at 9.45 GHz has been proposed. First, a meandered loop antenna size is reduced and its gain is enhanced by introducing a partially shield layer (PSL). Then, the antenna size is further reduced with a shorted conical pin connecting the antenna and PSL. The PSL provides capacitive loading and shifts resonating frequency of the reference antenna from 23 to 11.07 GHz. Also, it reduces substrate loss by obstructing EM wave propagation towards the lossy Silicon substrate and offers gain enhancement. Moreover, shorting to PSL offers an enhanced electrical length and shifts resonating frequency at 9.45 GHz. Thus, combination of PSL and shorting pin leads to realise the optimally designed MeLOCA size of 2.1 × 2 mm2 with reduction up to λ0/15.11. Simulated maximum gain and efficiency of −29 dB and 21.07%, respectively, make the antenna a suitable candidate for short range communication. Also, maximum of 16 and 20 dB and minimum of 3 and 5.6 dB isolations between co‐polarisation and cross‐polarisation components are achieved, respectively, in E and H planes. A prototype has been fabricated using 0.18 μm CMOS technology and good agreement between simulated and measured return loss characteristics is observed.
This paper presents the design and analysis of a miniaturized, coplanar waveguide-fed ultra-wideband monopole on-chip antenna with band-notch characteristics. By incorporating a “U”-shaped slot in the feedline, a band-notch is realized in the frequency range of 7.9–8.4 GHz to avoid interference from the X-band uplink satellite communication system. The proposed antenna achieved good voltage standing wave ratio (VSWR) characteristics with VSWR value <2 for the frequency range of 2.5–20.1 GHz excluding the band-notched frequencies. The fractional bandwidth and bandwidth ratio are obtained as 156% and 8.04:1, respectively. Dominant factors that affect the center frequency and bandwidth of the notched band are thoroughly investigated. This paper addresses both frequency as well as time domain behavior of the proposed structure. Standard 675 µm thick, high resistive silicon substrate (ρ≥8 kΩ-cm, εr = 11.8, and tan δ = 0.01) is used to design the proposed compact antenna structure with a layout area of 8.5 × 11.5 mm2. Fabrication process steps along with simulated and measured data are presented here. A close analogy between simulated and measured data is observed.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.