Workshop on Space Technologies & Synergies with Technological Poles Aveiro, Portugal, 28 th November 2011 Microwave & millimeter wave dielectric antennas Carlos A. Fernandes * Eduardo B. Lima Jorge R. Costa 2005, it - instituto de telecomunicações. Todos os direitos reservados.
Outline Motivation Examples of fabricated and tested prototypes ILASH - lens design software tool Conclusions 2
Motivation Traditional feeds for focal plane arrays: horns - Physical size of horns limits spot density; - Not appropriate for sub-mm wave systems and THz. 3
Motivation z Integrated lens antenna concept (the sensors are integrated at the lens base) Typical lens diameter: 10 λ 4
Motivation z θ x y Double-shell integrated lens antenna. The shape of the two surfaces can be optimized to enhance antenna performance. 5
Motivation z θ z x Analysis of the combined performance of doubleshell integrated lens antenna plus reflector. x y y 6
Example1 - Quasi-optical imaging reflector system Frequency = 500 GHz. 3dB 3dB overlapping beams. 0.36º 7
Example 1 - Quasi-optical imaging reflector system Scaled model for 62.5 GHz Off-set parabolic reflector; Feed separation 2λ; Feed Gaussian beamwidth: 13º; Azimuth scan: mechanical. x x x x x 8
Lens for quasi-optical system Fabricated lens antenna Used materials: MACOR/PLEXIGLAS (ε r = 5.6/2.53, tan δ = 0.012) Lens dimensions: F = 41.9 mm; T = 20.9 mm; Ray Tracing C. A. Fernandes; J. R. Costa; M. van der Vorst; Design of a Shaped Double-Shell Lens Feed for a Quasi-Optical Reflector System, Proc. IEEE APS/URSI Symposium, Washington, USA, Jun. 2007 9
Lens for quasi-optical system f = 62.5 GHz Amplitude Phase H-plane E-plane 10
Reflector + lens performance Scaled reflector: F = 1.6 m, D = 2 m Simulated results @ 62.5 GHz [db] 3dB level [db] 3dB level θ [deg] H-plane θ [deg] (x= 2.75, -1.5, 0, 1.5, 3.0 mm) E-plane θ [deg] 11
Example2 - Broadband Lens Antenna with Frequency Constant Gaussicity The objective is to maximize aperture efficiency of the reflector over frequency. Illuminate the reflector with a frequency constant beamwidth. Design a broadband feed to produce a frequency constant beamwidth. Frequency range : 30 to 90 GHz (100% bandwidth). 12
Fabricated dielectric lens Designation Variable Value Inner shell height F 41.8 mm Outer shell height S 20.9 mm Inner shell refraction index n 2 5.5 Lens material: MACOR ε r = 5.5 (1-j0.0118); Acrylic ε r = 2.53 (1-j0.0118). Outer shell refraction index n 1 2.53 Feed Gaussian width ϕ 0 64º Maximum feed aperture ϕ max 90º Far-field Gaussian width α 0 23º Maximum subtended angle α max 31º 13
Measured and simulated lens radiation pattern @ 62.5 GHz [db] 10 Magnitude Gaussian Simulated Measured (Co-Pol) Measured (Cross-Pol) -45-30 -15 0 θ[deg] 0-10 -20-30 -40 Gaussian Simulated Measured (Co-Pol) Measured (Cross-Pol) 0 15 30 45 θ[deg] Phase [Deg] 180 Phase 90 0 Simulated Measured (Co-Pol) -45-30 -15 0 θ[deg] E-plane -90-180 Simulated Measured (Co-Pol) 0 15 30 45 θ[deg] H-plane 14
Simulations within the 100% bandwidth [db] 0 Magnitude 30 GHz 50 GHz 70 GHz 90 GHz -45-30 -15 0 θ[deg] -10-20 -30-40 30 GHz 50 GHz 70 GHz 90 GHz 0 15 30 45 θ[deg] Phase [Deg] 180 Phase 30 GHz 50 GHz 70 GHz 90 GHz -45-30 -15 0 θ[deg] 90 0-90 -180 30 GHz 50 GHz 70 GHz 90 GHz 0 15 30 45 θ[deg] E-plane H-plane 15
Lens antenna + reflector Off-set parabolic reflector. D ψ Generating parabola α T F Virtual focus x' z' z 0 f 16
Lens antenna + reflector ILASH (Co-Pol) GRASP (Co-Pol) ILASH (Cross-Pol) GRASP (Cross-Pol) [db] 0-10 -20 ILASH (Co-Pol) GRASP (Co-Pol) 30 GHz -30-40 Reflector illuminated by the lens -1-0.5 0 θ[deg] ILASH (Co-Pol) GRASP (Co-Pol) ILASH (Cross-Pol) GRASP (Cross-Pol) 0 0.5 1 θ[deg] [db] 0 ILASH (Co-Pol) -10 GRASP (Co-Pol) -20-30 90 GHz -1-0.5 0 θ[deg] E-plane -40 0 0.5 1 θ[deg] H-plane 17
Lens antenna + reflector Simulations including the off-set parabolic reflector show almost frequency constant aperture efficiency within the 1:3 bandwidth. 70 Directivity [dbi] Aperture efficiency [%] 100 65 90 60 80 55 50 Directivity Aperture efficiency 30 50 70 90 f [GHz] θ[deg] 70 60 18
ILASH Overview ILASH tool is intended for design, analysis and optimization of shaped single- and double-shell integrated lens antennas (ILA); Lenses can be fed by arbitrary feeds: Internally defined; Defined in data file. ILASH combines two lens design modules: Closed-form analytical formulations for several types of shaped double-shell lenses; Genetic Algorithm (GA) optimization. 19
User Interface (Lens Synthesis) 20
User Interface (Evaluation Tools) 21
Optimization Module (Genetic Algorithms) Test lenses Performance evaluation Performance ranking Best lens so far Best performance so far 22
Manufacturing of dielectric lenses by milling or molding 23
Fabricated lens antenna prototypes 24
Lens antenna tests 0-5 -10 ILASH Measured Target E φ -15-20 -25-30 -50 0 50 θ 25
Conclusions Two different dielectric lens antenna configurations were described, intended to feed a quasi-optical imaging reflector system. Good scanning conditions are obtained when combined with an off-set parabolic reflector; A single lens antenna can replace multiple individual parabola feeds, not being limited by the available space between feeds in the parabola focal arch. 26