Wide Array and Directive Monopole Antenna

 Various investigations have been reported on metamaterials with near-zero permittivity and/or index of refraction (n) because of their useful applications such as: highly directive beams, compact resonators, zero phase delay lines, wave front transformers, transparent coating, and subwavelength tunneling.

 The 2-D Metallic wire arrays are probably the simplest structures to realize an neff< 1 effective medium and can be analyzed using a simple plasma theory with reduced electron density. A simple design methodology for directive monopole antennas, which can be applied at any microwave frequencies, is introduced by embedding a monopole within a metallic wire array with neff < 1. Due to the symmetry in the wire-array / monopole system, there are four identical main beams. If a single main beam is desired, metal reflectors can be applied at the three boundaries of the wire arrays.

Directive monopole antenna model

Theory:

• n1 sin(θ1) = n2 sin(θ2)
  

• n2 <1 = n1 -> θ1 < θ2

Millimeter-Wave On-Chip Antenna

 There is much interest in developing systems at high operating frequencies. For example, the wireless personal area network is moving to the 60 GHz ISM band for wide proportional bandwidth and free spectrum cost. Other applications include the 77-GHz vehicular radar and the military satellite communication system (MILSTAR) at 20 / 44 GHz. To meet the different requirements of these systems, various types of antennas have to be designed. Among them, the on-chip antennas become attractive due to its ease for integration and low-cost. To further improve the performance of the on-chip antenna, it is desired to shrink the size of the antenna. In this way, both the loss introduced by the antenna and the cost of the whole system can be reduced.

 Inspired by the concept of metamaterials, we design a uni-planar, easy for integration and compact antenna for high-frequency applications (higher than 40 GHz). The measurement results are consistent with the simulations, showing good performance of the antenna.