Journal article
Accurate and Efficient Analysis of Printed Reflectarrays With Arbitrary Elements Using Higher-Order Hierarchical Legendre Basis Functions
It is demonstrated that nonsingular higher-order hierarchical Legendre basis functions are capable of accounting for the singularities of the electric currents at the edges of the reflectarray elements, thus yielding good convergence properties and very accurate results. In addition, the number of Floquet harmonics needed in the spectral domain method of moments is reduced by using higher-order hierarchical Legendre basis functions as compared to singular basis functions.
At the same time, higher-order hierarchical Legendre basis functions can be applied to any arbitrarily shaped array elements, thus providing the flexibility required in the analysis of printed reflectarrays. A comparison to DTU-ESA Facility measurements of a reference offset reflectarray shows that higher-order hierarchical Legendre basis functions produce results of the same accuracy as those obtained using singular basis functions.
| Language: | English |
|---|---|
| Publisher: | IEEE |
| Year: | 2012 |
| Pages: | 814-817 |
| ISSN: | 15485757 and 15361225 |
| Types: | Journal article |
| DOI: | 10.1109/LAWP.2012.2208174 |
| ORCIDs: | Kim, Oleksiy S. and Breinbjerg, Olav |
Accurate antenna analysis Basis functions Floquet harmonics Method of moments (MoM), Reflectarray
Antenna measurements Antennas Arrays Convergence Harmonic analysis Legendre polynomials Niobium Shape arbitrarily shaped array element basis functions convergence property electric current singularities higher-order hierarchical Legendre basis function method of moments method of moments (MoM) microstrip antenna arrays printed reflectarray reference offset reflectarray reflectarray reflectarray antennas reflectarray element singular basis function spectral domain method-of-moment
