Title :
Flip-Chip-Assembled Air-Suspended Inductors
Author :
Bell, Patrick J. ; Hoivik, Nils D. ; Saravanan, R.A. ; Ehsan, Negar ; Bright, Victor M. ; Popovic, Zoya
Author_Institution :
Colorado Univ., Boulder, CO
Abstract :
This paper discusses high-performance planar suspended inductors for hybrid integration with microwave circuits. The inductors are fabricated using a silicon surface micromachining foundry process and assembled using flip-chip bonding. The silicon substrate is removed, leaving a metal inductor suspended 60 mum above the microwave substrate, thus reducing the parasitic capacitance and loss. Various rectangular, octagonal, and circular inductor geometries with one to five windings are designed with inductance values between 0.65 and 16 nH to demonstrate the flexibility of this technique. Measured self-resonant frequencies are between 5 and 34.8 GHz, with quality factors from 45 to 100. Equivalent circuits extracted from measurement for each inductor type show good agreement with measured impedance and full-wave simulations over frequency. The dc current handling limit is 200 mA
Keywords :
Q-factor; elemental semiconductors; equivalent circuits; flip-chip devices; foundries; inductors; micromachining; microwave circuits; semiconductor device measurement; silicon; 200 mA; 34.8 GHz; 5 GHz; Si; circular inductor; equivalent circuits; flip-chip bonding; flip-chip-assembled air-suspended inductors; full-wave simulations; hybrid circuit; hybrid integration; metal inductor; microwave circuits; microwave substrate; octagonal inductor; parasitic capacitance; planar suspended inductors; quality factor; radio frequency choke; rectangular inductor; self-resonant frequency; silicon surface micromachining foundry; Assembly; Bonding; Foundries; Frequency measurement; Impedance measurement; Inductors; Micromachining; Microwave circuits; Parasitic capacitance; Silicon; Bias-tee; hybrid circuit; micromachined; quality factor; radio frequency (RF) choke; self-resonant frequency;
Journal_Title :
Advanced Packaging, IEEE Transactions on
DOI :
10.1109/TADVP.2006.890227
