“…[31,37,40,67,69,[75][76][77][78][79][80][81][82][83][84][85][86][87][88][89][90][91][92][93][94]. Specifically, Table 2 compares the proposed design to [31,37,40,67,79,83] in terms of area, gain, HPBW and bandwidth.…”
Section: Comparison Of the Designed Antenna Vs The State-of-the-artmentioning
confidence: 99%
“…[75][76][77] to achieve a Terahertz frequency operating range. The CN antennas, operating in Terahertz frequency range, can provide much higher communication data rates than on-chip antennas, operating up to 100 GHz.…”
Section: Comparison Of the Designed Antenna Vs The State-of-the-artmentioning
Abstract:To allow fast communication-at several Gb/s-of multimedia content among processors and memories in a multi-processor system-on-chip, a new approach is emerging in literature: Wireless Network-on-Chip (WiNoC). With reference to this scenario, this paper presents the design of the key element of the WiNoC: the antenna. Specifically, a bow-tie antenna is proposed, which operates at mm-waves and can be implemented on-chip using the top metal layer of a conventional silicon CMOS (Complementary Metal Oxide Semiconductor) technology. The antenna performance is discussed in the paper and is compared to the state-of-the-art, including the zig-zag antenna topology that is typically used in literature as a reference for WiNoC. The proposed bow-tie antenna design for WiNoC stands out for its good trade-off among bandwidth, gain, size and beamwidth vs. the state-of-the-art.
“…[31,37,40,67,69,[75][76][77][78][79][80][81][82][83][84][85][86][87][88][89][90][91][92][93][94]. Specifically, Table 2 compares the proposed design to [31,37,40,67,79,83] in terms of area, gain, HPBW and bandwidth.…”
Section: Comparison Of the Designed Antenna Vs The State-of-the-artmentioning
confidence: 99%
“…[75][76][77] to achieve a Terahertz frequency operating range. The CN antennas, operating in Terahertz frequency range, can provide much higher communication data rates than on-chip antennas, operating up to 100 GHz.…”
Section: Comparison Of the Designed Antenna Vs The State-of-the-artmentioning
Abstract:To allow fast communication-at several Gb/s-of multimedia content among processors and memories in a multi-processor system-on-chip, a new approach is emerging in literature: Wireless Network-on-Chip (WiNoC). With reference to this scenario, this paper presents the design of the key element of the WiNoC: the antenna. Specifically, a bow-tie antenna is proposed, which operates at mm-waves and can be implemented on-chip using the top metal layer of a conventional silicon CMOS (Complementary Metal Oxide Semiconductor) technology. The antenna performance is discussed in the paper and is compared to the state-of-the-art, including the zig-zag antenna topology that is typically used in literature as a reference for WiNoC. The proposed bow-tie antenna design for WiNoC stands out for its good trade-off among bandwidth, gain, size and beamwidth vs. the state-of-the-art.
“…One possibility is to use nanoscale antennas based on CNTs operating in the THz/optical frequency range [51][52][53][54]. Bundles of CNTs are predicted to enhance performance of antenna modules by up to 40dB in radiation efficiency and provide excellent directional properties in far-field patterns [55]. Moreover these antennas can achieve a bandwidth of around 500 GHz, whereas the antennas operating in the mm-wave range achieve a bandwidth of 10's of GHz.…”
“…In previous works CNT antennas bundle is studied based on effective axial surface conductivity for low coupling distances [8,9]. In terahertz and infrared frequency range, the radiation characteristics of CNT dipole antenna arrays have been investigated by CST MICROWAVE STUDIO.…”
Abstract-Fundamental properties of carbon nanotube antenna are firstly investigated to predict the antenna bundle response. The carbon nanotube effects are mathematically introduced via a quantum mechanical conductivity. This paper presents a new formulation based on integral equations system to study the coupled carbon nanotube antennas. The proposed integral equations system is numerically solved by the moments method. Each dipole antenna is excited at its center by a gap voltage source. The aim of the developed method is to investigate the antennas interaction effects for any coupling distance. The obtained input impedances, the current distributions and the antenna radiation patterns are in agreement with those obtained by the effective conductivity method or by the array factor method, according to the coupling distances.
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