2017 IEEE International Solid-State Circuits Conference (ISSCC) 2017
DOI: 10.1109/isscc.2017.7870415
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22.1 A self-tuning resonant inductive link transmit driver using quadrature-symmetric phase-switched fractional capacitance

Abstract: Inductive coupling for power transfer is increasingly popular in many applications such as RFID and wireless charging. While much recent work has focussed on receivers [1,2], less consideration has been given to the transmit function. High-Q antenna circuits are beneficial for several reasons. Activation of a link at a distance requires a large magnetic field from the transmitter, so for a given antenna current, lower driver voltages may be used, simplifying the driver and its power supplies, and improving ove… Show more

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Cited by 8 publications
(3 citation statements)
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“…To simplify the design of the binary-weighted capacitor array used in the resonant frequency control, a single phase switched fractional capacitor can be adopted for TX regulation by using the resonant frequency trimming technique as given in [45].…”
Section: Discussion and Development Trendsmentioning
confidence: 99%
“…To simplify the design of the binary-weighted capacitor array used in the resonant frequency control, a single phase switched fractional capacitor can be adopted for TX regulation by using the resonant frequency trimming technique as given in [45].…”
Section: Discussion and Development Trendsmentioning
confidence: 99%
“…Furthermore, a large number of capacitors, HV switches and control lines are required for precise tuning to resonance at high-Q to compensate for detuning effects and component tolerances. Adaptive real-time tuning of a driven resonant circuit can be achieved by synchronously switching a capacitor in and out of circuit within each cycle, where the duty cycle determines the average capacitance [2]. Resonance is maintained with external magnetic loading and across PVT variations by sensing the voltage across the switch each cycle at the closure instant, and determining the direction of error from resonance to close a control loop ( fig.…”
mentioning
confidence: 99%
“…This gives a min:max tuning range of 1:1.41, sufficient to permit both compensation of tolerance/environmental effects as well as the required frequency shifting for FSK/PSK data modulation. Capacitive dividers isolate the high voltages on the tuning capacitors from the tuning control input [2]. The timing reference is derived from a current integrator oscillator, creating VTR and VDR, the currents generated by a digital V-to-I function.…”
mentioning
confidence: 99%