Omodara Gbotemi scite author profile

Omodara Gbotemi

3Publications

6Citation Statements Received

72Citation Statements Given

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University of Oulu

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Printed GNSS and Bluetooth Antennas Embedded on Flexible Low Loss Substrates for Wearable Applications

Gbotemi

Myllymäki

Jantunen

et al. 2020

PIER M

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This paper presents Global Navigation Satellite System (GNSS) F-type and Bluetooth (BT) L-shaped antennas printed on flexible low loss substrate materials for smartwatch applications. The proposed printed antennas were designed along with the wristband of a smartwatch device with the main purpose of improving their electrical performance by using a new low loss polymer material and locating the antenna on the wrist strap. The antenna performances were simulated using CST Microwave Studio, and the prototypes were measured in a Satimo StarLab anechoic chamber. Silver printing and injection molding technologies were successfully utilized for fabricating new SEBS materials (styrene-ethylenebutylene-styrene) in wearable devices. The SEBS materials improved the radiation efficiency of the antennas by 1.6 dB for the GNSS and 2.2 dB for the BT over the previously used TPU (thermoplastic polyurethane) materials. The overmolded printed and hybrid integrated discrete antennas produced added-value for electronics fabrication thanks to its flexible and seamless integration technique. In addition, it is a low-cost mass manufacturing method. The research opens new perspectives for product definitions with a flexible, low loss material that enables better antenna performance.

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Microwave Characterization of Printed Inductors With Ferrimagnetic BaFe₁₂O₁₉Composite Layers

et al. 2017

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Characterization of PMMA/BaTiO₃ Composite Layers Through Printed Capacitor Structures for Microwave Frequency Applications

Gbotemi

Myllymäki

Kallioinen

et al. 2018

IEEE Trans. Microwave Theory Techn.

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This paper presents the extraction of microwave properties of low-temperature cured inorganic composite materials based on barium titanate (BaTiO 3). These composite materials exhibit attractive features such that when the volume fraction of the filler contents varied, its electrical properties of high permittivity and moderately low loss tangent can be manipulated to suit different areas of applications. For the extraction of the permittivity and the loss tangent, three different ink particles were developed and printed on the top of interdigitalshaped microwave capacitor. The properties of the inks were extracted from measured results through computer simulations. The obtained results were verified with several types of interdigital capacitor structures of different fingers and linewidths. The effect of the thickness of the ink layer materials on the top of the capacitor structures was likewise investigated. The results show relative permittivity (ε r) values of 30, 25, and 27 for composite layers printed using inks with Pr. A shape at 67.4 wt% (percentage by weight), Pr. B shape at 66.3 wt%, and Pr. C shape at 67.1 wt% of BaTiO 3 , respectively, at 2 GHz. Corresponding loss tangents (tan δ) were 0.065, 0.040, and 0.025. The dielectric properties of the composite materials are influenced by the thickness variation of the ink layers on the capacitor structures. This novel capacitor composite materials would be a promising candidate for printed application in mobile telecommunication operations, especially in the frequency range of 0.5-3 GHz.

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Omodara Gbotemi

Printed GNSS and Bluetooth Antennas Embedded on Flexible Low Loss Substrates for Wearable Applications

Microwave Characterization of Printed Inductors With Ferrimagnetic BaFe₁₂O₁₉Composite Layers

Characterization of PMMA/BaTiO₃ Composite Layers Through Printed Capacitor Structures for Microwave Frequency Applications

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Omodara Gbotemi

Printed GNSS and Bluetooth Antennas Embedded on Flexible Low Loss Substrates for Wearable Applications

Microwave Characterization of Printed Inductors With Ferrimagnetic BaFe12O19Composite Layers

Characterization of PMMA/BaTiO3 Composite Layers Through Printed Capacitor Structures for Microwave Frequency Applications

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Product

Resources

About

Microwave Characterization of Printed Inductors With Ferrimagnetic BaFe₁₂O₁₉Composite Layers

Characterization of PMMA/BaTiO₃ Composite Layers Through Printed Capacitor Structures for Microwave Frequency Applications