A spiral planar inductor: <scp>A</scp>n experimentally verified physically based model for frequency and time domains

Spiral inductors are required to realise high inductance in radio frequency (RF) circuits. Although their fabrication by using micro-electrical–mechanical systems, thin films, actuators, etc., has received considerable research attention, current approaches are both complex and expensive. In this study, we designed and fabricated a thermal spiral inductor by using a three-dimensional (3D) printed shape-memory polymer (SMP). The proposed inductor was inspired by kirigami geometry whereby a two-dimensional (2D) planar geometric shape could be transformed into a 3D spiral one to change the inductance by heating and manually transform. Mechanical and electromagnetic analyses of the spiral inductor design was conducted. Hence, in contrast with the current processes used to manufacture spiral inductors, ours can be realised via a single facile fabrication step.

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“…In addition, the Q-factor of the inductor can be expressed as where is the frequency, is the inductance and is the resistance 22 , 23 .…”

Section: Resultsmentioning

confidence: 99%

“…where α is the angle of a conical inductor and L cy is the inductance of a cylindrical inductor with has same radius size determined as In addition, the Q-factor of the inductor can be expressed as where f is the frequency, L is the inductance and R is the resistance 22,23 .…”

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confidence: 99%

Thermal spiral inductor using 3D printed shape memory kirigami

Kim

Phon

Jeong

et al. 2022

Sci Rep

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“…For high frequency applications, skin effects appear on coil surfaces which contributes to high frequency losses of the LC sensor. Such high frequency losses can be reduced by using litz wire to design inductive coil [80], [81]. The dielectric loss can be tackled by selecting low-loss dielectric material for the sensing element and the radiation loss can be tackled by shielding the sensor during high frequency operation.…”

Section: Discussionmentioning

confidence: 99%

Measurement Techniques and Challenges of Wireless LC Resonant Sensors: A Review

Masud,

Vazquez,

Rehman

et al. 2023

IEEE Access

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Wireless operation of the LC resonant sensor is based on magnetic coupling between two inductive coils, where the inductor of the sensor acts as a secondary coil for the magnetic coupling. An external reader coil is used as a primary coil to interrogate the sensor to detect the sensor's response. The wireless LC resonant sensor is applied in many applications where the cable connections for powering sensors and acquiring data are inconvenient. This review focuses on the fundamental operating principles of wireless LC resonant sensors, their measurement techniques, the challenges of accurately measuring the LC sensors, and their potential solutions. The main challenge in wireless measurement of the LC resonant sensor is to accurately measure the resonant frequency and the quality factor of the sensor which are solely dependent on the intrinsic parameters of the sensors. For practical wireless applications, it is crucial to interrogate LC resonant sensors regardless of their wireless measurement distances. To interrogate wireless LC resonant sensors, frequency and time domain measurements are commonly used. The coupling coefficient, which is greatly influenced by the geometrical dimensions and alignment of the two inductively coupled coils, has an adverse effect on distance independent readout in phase dip measurement in the frequency domain. Furthermore, the presence of parasitic capacitance that appears in parallel to the readout coil of the sensor has also an adverse effect on distance independent measurement in both frequency and time domain, resulting in an inaccurate measurement of the sensor's resonant frequency. A parasitic capacitance compensation technique can be employed to reduce or even eliminate the presence of parasitic capacitance in the readout coil, which significantly improves the measurement accuracy of the LC resonant sensor.

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“…The parasitic capacitance between the nearby turns can be computed from Equation (10) [ 49 , 50 ], where α and β are 0.9 and 0.1, respectively, and represent the parasitic contribution due to the air gap between the coil turns, and the gap between the metallic tracks and the substrate, as shown in Figure 3 c.

and

are the relative permittivity of air and substrate material respectively.

…”

Section: Methodsmentioning

confidence: 99%

Thin-Film Flexible Wireless Pressure Sensor for Continuous Pressure Monitoring in Medical Applications

Farooq

Iqbal

Vázquez

et al. 2020

Sensors

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Physiological pressure measurement is one of the most common applications of sensors in healthcare. Particularly, continuous pressure monitoring provides key information for early diagnosis, patient-specific treatment, and preventive healthcare. This paper presents a thin-film flexible wireless pressure sensor for continuous pressure measurement in a wide range of medical applications but mainly focused on interface pressure monitoring during compression therapy to treat venous insufficiency. The sensor is based on a pressure-dependent capacitor (C) and printed inductive coil (L) that form an inductor-capacitor (LC) resonant circuit. A matched reader coil provides an excellent coupling at the fundamental resonance frequency of the sensor. Considering varying requirements of venous ulceration, two versions of the sensor, with different sizes, were finalized after design parameter optimization and fabricated using a cost-effective and simple etching method. A test setup consisting of a glass pressure chamber and a vacuum pump was developed to test and characterize the response of the sensors. Both sensors were tested for a narrow range (0–100 mmHg) and a wide range (0–300 mmHg) to cover most of the physiological pressure measurement applications. Both sensors showed good linearity with high sensitivity in the lower pressure range <100 mmHg, providing a wireless monitoring platform for compression therapy in venous ulceration.

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A spiral planar inductor: An experimentally verified physically based model for frequency and time domains

Cited by 14 publications

References 24 publications

Thermal spiral inductor using 3D printed shape memory kirigami

Thermal spiral inductor using 3D printed shape memory kirigami

Measurement Techniques and Challenges of Wireless LC Resonant Sensors: A Review

Thin-Film Flexible Wireless Pressure Sensor for Continuous Pressure Monitoring in Medical Applications

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