Abstract
This paper reports on the novel implementation of a tunable solenoid inductor using the fluid-based inductance varying technique. The concept utilized material permeability variation that directly modifies self-induced magnetic flow density inside the coil, which in turn creates a variation of the inductance value. The core is formed by a channel which allows the circulation of a liquid through it. The liquid proposed for this technique has ferromagnetic behavior, called ferrofluid, with a magnetic permeability higher than unity. To evaluate the proposed technique, two different types of solenoid inductor were designed, simulated and measured. The two structures are wire-wound and wire bond solenoid inductors. The structures are simulated in a 3D EM analysis tool followed by fabrication, test and measurement. The wire-bonded-based inductor showed a quality factor of 12.7 at 310 MHz, with 81% tuning ratio, by using ferrofluid EMG 901. The wire-wound-based inductor showed that the maximum tuning ratio is 90.6% with quality factor 31.3 at 300 MHz for ferro fluidic EMG 901. The maximum measured tuning ranges were equal to 83.5% and 56.2% for the wire-wound type and the wire-bonded one, respectively. The measurement results for the proposed technique showed a very high tuning range, as well as high quality factor and continuous tunability.
Highlights
With the evolution of wireless communications, especially market demand for a smaller communication device, there is a tremendous interest and need for integrated, less costly andAppl
The demand for the tunability feature of the inductor increased, especially in radio frequency (RF) application, to create standard reconfigurable wireless systems utilizing single miniaturized on-chip solution. This includes discrete and micro electro-mechanical system (MEMS) inductors that have a wide range of applications in RF transceiver block, such as voltage controlled oscillator (VCO) [1,2], low-noise amplifier (LNA) [3], wireless matching network [4,5,6,7], multi-band filters [8], multi-band RF circuits [9], RF power amplifier [10], and reconfigurable antenna [11,12,13,14,15,16]
The Printed Circuitry Board (PCB) used in this work is ROGERS4003, with 0.8-mm dielectric a common reference ground
Summary
With the evolution of wireless communications, especially market demand for a smaller communication device, there is a tremendous interest and need for integrated, less costly andAppl. The demand for the tunability feature of the inductor increased, especially in radio frequency (RF) application, to create standard reconfigurable wireless systems utilizing single miniaturized on-chip solution. This includes discrete and micro electro-mechanical system (MEMS) inductors that have a wide range of applications in RF transceiver block, such as voltage controlled oscillator (VCO) [1,2], low-noise amplifier (LNA) [3], wireless matching network [4,5,6,7], multi-band filters [8], multi-band RF circuits [9], RF power amplifier [10], and reconfigurable antenna [11,12,13,14,15,16]. Research to create such a component is still at early stages, since obtaining high inductance tuning range and high quality factor simultaneously is very challenging
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