Planar antennas on silicon for millimeterwave emitters

Heppenheimer, K. P.; Vietzorreck, L.; Russer, P.

doi:10.1109/EUMA.2001.338958

heppenheimer_planar_2001

Dokumenttyp:: Konferenzbeitrag
Autor(en):: Heppenheimer, K. P.; Vietzorreck, L.; Russer, P.
Titel:: Planar antennas on silicon for millimeterwave emitters
Abstract:: In this paper we investigate and design a planar patch antenna using the transmission line matrix method (TLM). The planar antenna is part of a monolithic integrated millimeter-wave emitter, working in the 60 GHz range on a high resistivity Si substrate. The active part is realized by an negative impedance amplifier, an IMPATT diode here; the patch antenna is used as resonator as well as radiating element. The resonator design criteria are the desired frequency, an impedance match with the IMPATT diode impedance and the radiation characteristic and efficiency. For technological reasons, a 525 μm substrate was chosen, which naturally deteriorates both the antenna radiation features and the impedance behaviour. The impedance requirements are a very low real part of the antenna input impedance (⩽ 3 Ω), smaller than the negative impedance of the IMPATT diode in order to enable exponentially increasing oscillations. The imaginary part of the antenna must show a steep gradient above the resonant frequency up to values ⩾ 30, 40 Ω. In order to find a design to fulfil those critical requirements, a full wave analysis is demanded. The TLM method has proven to be a very powerful and flexible numerical method for analysis of various planar and 3D topologies, especially useful for the investigation of broadband structures, but has not yet been used extensively for the analysis of radiating structures. The paper shows how TLM can be used for antenna modeling, necessary steps for the design of the patch antenna are demonstrated and results are validated by comparison with spectral domain methods
Stichworte:: millimetre wave antennas, transmission line matrix methods, impedance matching, planar antennas, resonant frequency, Si, silicon, microstrip resonators, TLM method, antenna radiation patterns, microstrip antennas, network topology, patch antenna, 60 GHz, radiation efficiency, oscillations, transmission line matrix method, full wave analysis, planar antenna, antenna input impedance, IMPATT diode, IMPATT diodes, monolithic integrated millimeter-wave emitter, negative impedance amplifier, planar patch antenna, high resistivity Si substrate, 3 ohm, 30 ohm, 3D topology, 40 ohm, 525 micron, antenna radiation features, broadband structures, flexible numerical method, IMPATT diode impedance, impedance behaviour, impedance match, millimeter wave emitters, negative impedance, patch antenna radiating element, patch antenna resonator, planar topology, radiating structures, radiation characteristic, resonator design criteria, spectral domain methods, TLM antenna modeling «
millimetre wave antennas, transmission line matrix methods, impedance matching, planar antennas, resonant frequency, Si, silicon, microstrip resonators, TLM method, antenna radiation patterns, microstrip antennas, network topology, patch antenna, 60 GHz, radiation efficiency, oscillations, transmission line matrix method, full wave analysis, planar antenna, antenna input impedance, IMPATT diode, IMPATT diodes, monolithic integrated millimeter-wave emitter, negative impedance amplifier, planar pa... »
Kongress- / Buchtitel:: 2001 Topical Meeting on Silicon Monolithic Integrated Circuits in RF Systems Digest
Jahr:: 2001
Seiten:: 205--209
Volltext / DOI:: doi:10.1109/EUMA.2001.338958
BibTeX

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mediaTUM Gesamtbestand Einrichtungen Hochschulpräsidium TUM Senior Excellence Faculty

mediaTUM Gesamtbestand Einrichtungen Schools TUM School of Computation, Information and Technology Departments Electrical Engineering Computational Photonics (Prof. Jirauschek)Peter Russer