Resonant ultrasonic wireless power transmission for bio-implants

Lee, Sung Q; Youm, Woosub; Hwang, Gunn; Moon, Kiwon; Öztürk, Yusuf

doi:10.1117/12.2046600

Cited by 12 publications

(13 citation statements)

References 20 publications

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“…Wireless power transmission is an attractive alternative to batteries in low-power biomedical implants and has received increasing research interest in recent years [33,34]. Radio frequency (RF), ultrasound [15,35], infrared light and low-frequency magnetic field are considered as viable wireless power transfer options. Wireless power charging technologies, such as magnetic resonance and induction coupling, have limited applications because of their short transfer distance compared to device size and the magnetic field intensity limitation for the safety of body exposure.…”

Section: Wireless Power Transfer and Power Budgetmentioning

confidence: 99%

“…As an alternative, the biocompatible wireless power transfer using ultrasonic resonance developed in a collaborating study offers a smaller circuit size and no heat dissipation. In this study, we used the wireless power transfer technique fully described in [15] to deliver power to the implantable BBMI system as demonstrated in Figure 3. Also illustrated in Figure 3, ultrasonic wireless power transmission is composed of converting electrical energy to ultrasonic energy and vice versa.…”

Section: Wireless Power Transfer and Power Budgetmentioning

confidence: 99%

“…Since the wireless BBMI system we proposed would be placed as a skull implant, the scalp is the only object that lies between the ultrasonic transmitter and the receiver. The detailed implementation of the ultrasonic power transmitter and the receiver is presented in our previous work [15]. The key parameters of the novel ultrasonic power transfer module are listed in Table 1.…”

Section: Wireless Power Transfer and Power Budgetmentioning

confidence: 99%

“…Based on the brain activity report, the system can induce stimulation to the brain and record neural activity as a response to the stimulus. The system utilizes the ultrasonic power transfer technique developed in a collaborative study [15] for wirelessly charging an on board battery. The hardware and component-based software platform we developed were validated through in vivo tests and adapted by other research groups.…”

Section: Introductionmentioning

confidence: 99%

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A Wireless 32-Channel Implantable Bidirectional Brain Machine Interface

Routhu

Moon

et al. 2016

Sensors

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All neural information systems (NIS) rely on sensing neural activity to supply commands and control signals for computers, machines and a variety of prosthetic devices. Invasive systems achieve a high signal-to-noise ratio (SNR) by eliminating the volume conduction problems caused by tissue and bone. An implantable brain machine interface (BMI) using intracortical electrodes provides excellent detection of a broad range of frequency oscillatory activities through the placement of a sensor in direct contact with cortex. This paper introduces a compact-sized implantable wireless 32-channel bidirectional brain machine interface (BBMI) to be used with freely-moving primates. The system is designed to monitor brain sensorimotor rhythms and present current stimuli with a configurable duration, frequency and amplitude in real time to the brain based on the brain activity report. The battery is charged via a novel ultrasonic wireless power delivery module developed for efficient delivery of power into a deeply-implanted system. The system was successfully tested through bench tests and in vivo tests on a behaving primate to record the local field potential (LFP) oscillation and stimulate the target area at the same time.

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Section: Wireless Power Transfer and Power Budgetmentioning

confidence: 99%

Section: Wireless Power Transfer and Power Budgetmentioning

confidence: 99%

Section: Wireless Power Transfer and Power Budgetmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Wireless 32-Channel Implantable Bidirectional Brain Machine Interface

Routhu

Moon

et al. 2016

Sensors

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“…Acoustic waves, especially ultrasonic waves, have widely been used in fields such as underwater acoustic communications [ 23 , 24 ], industrial detection and health monitoring of structures [ 25 ]. Wireless ultrasonic power transfer has been used to power biomedical implants through human tissues [ 26 , 27 , 28 , 29 ], so this should be a favorable solution for power delivery and data transmission through metal walls by means of ultrasound. However, this field is less well developed than areas such as underwater acoustic communications.…”

Section: Ultrasonic Through-metal-wall Power Delivery and Data Tramentioning

confidence: 99%

Through-Metal-Wall Power Delivery and Data Transmission for Enclosed Sensors: A Review

Yang

Zhao

et al. 2015

Sensors

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The aim of this review was to assess the current viable technologies for wireless power delivery and data transmission through metal barriers. Using such technologies sensors enclosed in hermetical metal containers can be powered and communicate through exterior power sources without penetration of the metal wall for wire feed-throughs. In this review, we first discuss the significant and essential requirements for through-metal-wall power delivery and data transmission and then we: (1) describe three electromagnetic coupling based techniques reported in the literature, which include inductive coupling, capacitive coupling, and magnetic resonance coupling; (2) present a detailed review of wireless ultrasonic through-metal-wall power delivery and/or data transmission methods; (3) compare various ultrasonic through-metal-wall systems in modeling, transducer configuration and communication mode with sensors; (4) summarize the characteristics of electromagnetic-based and ultrasound-based systems, evaluate the challenges and development trends. We conclude that electromagnetic coupling methods are suitable for through thin non-ferromagnetic metal wall power delivery and data transmission at a relatively low data rate; piezoelectric transducer-based ultrasonic systems are particularly advantageous in achieving high power transfer efficiency and high data rates; the combination of more than one single technique may provide a more practical and reliable solution for long term operation.

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Modeling and analysis of ultrasonic power transfer system with tightly coupled solid medium

Leung

2016

Wirel Pow Transfer

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Ultrasonic Power Transfer (UPT) has been developed as an alternative solution for achieving wireless power transfer. This paper proposes a new model describing UPT systems with tightly coupled piezoelectric transducers firmly bound to solid media. The model is derived from the short-circuit admittance of the system measured from the primary transducer. The mechanical characteristics of the system are modeled with parallel LCR branches, which reveal the fundamental relationships between the power transfer characteristics of the tightly coupled UPT system and system parameters. The loading conditions for achieving the maximum power transfer are identified, and the operating frequencies corresponding to the peak power transfer points for variable loads are determined. A practical UPT system is built with two 28 kHz Langevin-type piezoelectric transducers connected to a 5 mm-thick aluminum plate, and the practical results have verified the accuracy of the proposed model.

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Resonant ultrasonic wireless power transmission for bio-implants

Cited by 12 publications

References 20 publications

A Wireless 32-Channel Implantable Bidirectional Brain Machine Interface

A Wireless 32-Channel Implantable Bidirectional Brain Machine Interface

Through-Metal-Wall Power Delivery and Data Transmission for Enclosed Sensors: A Review

Modeling and analysis of ultrasonic power transfer system with tightly coupled solid medium

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