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1. A CMOS Smart Temperature and Humidity Sensor with Combined Readout

Author

Clemens Eder, Virgilio Valente, Nick Donaldson, and Andreas Demosthenous

Subjects
capacitive sensor, humidity measurement, microelectronic implants, oscillator, on-chip sensor, temperature sensor, Chemical technology, TP1-1185
Abstract

A fully-integrated complementary metal-oxide semiconductor (CMOS) sensor for combined temperature and humidity measurements is presented. The main purpose of the device is to monitor the hermeticity of micro-packages for implanted integrated circuits and to ensure their safe operation by monitoring the operating temperature and humidity on-chip. The smart sensor has two modes of operation, in which either the temperature or humidity is converted into a digital code representing a frequency ratio between two oscillators. This ratio is determined by the ratios of the timing capacitances and bias currents in both oscillators. The reference oscillator is biased by a current whose temperature dependency is complementary to the proportional to absolute temperature (PTAT) current. For the temperature measurement, this results in an exceptional normalized sensitivity of about 0.77%/°C at the accepted expense of reduced linearity. The humidity sensor is a capacitor, whose value varies linearly with relative humidity (RH) with a normalized sensitivity of 0.055%/% RH. For comparison, two versions of the humidity sensor with an area of either 0.2 mm2 or 1.2 mm2 were fabricated in a commercial 0.18 μm CMOS process. The on-chip readout electronics operate from a 5 V power supply and consume a current of approximately 85 µA.

Published
2014
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3. Frequency Splitting Analysis and Compensation Method for Inductive Wireless Powering of Implantable Biosensors

Author

Matthew Schormans, Virgilio Valente, and Andreas Demosthenous

Subjects
frequency splitting, frequency tuning, implantable biosensors, inductive link, inductive powering, medical implants, wireless power transfer, Chemical technology, TP1-1185
Abstract

Inductive powering for implanted medical devices, such as implantable biosensors, is a safe and effective technique that allows power to be delivered to implants wirelessly, avoiding the use of transcutaneous wires or implanted batteries. Wireless powering is very sensitive to a number of link parameters, including coil distance, alignment, shape, and load conditions. The optimum drive frequency of an inductive link varies depending on the coil spacing and load. This paper presents an optimum frequency tracking (OFT) method, in which an inductive power link is driven at a frequency that is maintained at an optimum value to ensure that the link is working at resonance, and the output voltage is maximised. The method is shown to provide significant improvements in maintained secondary voltage and system efficiency for a range of loads when the link is overcoupled. The OFT method does not require the use of variable capacitors or inductors. When tested at frequencies around a nominal frequency of 5 MHz, the OFT method provides up to a twofold efficiency improvement compared to a fixed frequency drive. The system can be readily interfaced with passive implants or implantable biosensors, and lends itself to interfacing with designs such as distributed implanted sensor networks, where each implant is operating at a different frequency.

Published
2016
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4. Wideband Fully-Programmable Dual-Mode CMOS Analogue Front-End for Electrical Impedance Spectroscopy

Author

Virgilio Valente and Andreas Demosthenous

Subjects
analogue readout, electrical impedance spectroscopy (EIS), integrated circuits, Chemical technology, TP1-1185
Abstract

This paper presents a multi-channel dual-mode CMOS analogue front-end (AFE) for electrochemical and bioimpedance analysis. Current-mode and voltage-mode readouts, integrated on the same chip, can provide an adaptable platform to correlate single-cell biosensor studies with large-scale tissue or organ analysis for real-time cancer detection, imaging and characterization. The chip, implemented in a 180-nm CMOS technology, combines two current-readout (CR) channels and four voltage-readout (VR) channels suitable for both bipolar and tetrapolar electrical impedance spectroscopy (EIS) analysis. Each VR channel occupies an area of 0.48 mm 2 , is capable of an operational bandwidth of 8 MHz and a linear gain in the range between −6 dB and 42 dB. The gain of the CR channel can be set to 10 kΩ, 50 kΩ or 100 kΩ and is capable of 80-dB dynamic range, with a very linear response for input currents between 10 nA and 100 μ A. Each CR channel occupies an area of 0.21 mm 2 . The chip consumes between 530 μ A and 690 μ A per channel and operates from a 1.8-V supply. The chip was used to measure the impedance of capacitive interdigitated electrodes in saline solution. Measurements show close matching with results obtained using a commercial impedance analyser. The chip will be part of a fully flexible and configurable fully-integrated dual-mode EIS system for impedance sensors and bioimpedance analysis.

Published
2016
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27. A Primary-side Maximum Efficiency Transfer Solution in Wireless Power Transfer Systems: Theory and Validation

Author

Gianluca Setti, Wouter A. Serdijn, Riccardo Rovatti, Virgilio Valente, Fabio Pareschi, Carmine Paolino, and Andrea Celentano

Abstract

In this paper, we investigate the primary-side control of a Wireless Power Transfer (WPT) link, i.e., the capability of delivering the optimal power level to the load without compromising system efficiency, by only sensing quantities available at the primary side. When adding a simple power regulator at the secondary side, we observe and analyze the existence of a Maximum Efficiency Transfer point, easily detectable at the primary side, and corresponding to the additional power regulator being barely on, with negligible dissipated power. More important, the approach does not require any advanced system modeling, nor the estimation of the system parameters. A theoretical model is developed and verified by measurements on a prototype built upon a 60 mW-class-E based WPT link working at 6.78 MHz.

Published
2023
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33. A CMOS Smart Temperature and Humidity Sensor with Combined Readout

Author

Andreas Demosthenous, Nick Donaldson, Virgilio Valente, and Clemens Eder

Subjects
Transducers, Temperature, capacitive sensor, Water, Humidity, Signal Processing, Computer-Assisted, humidity measurement, temperature sensor, Equipment Design, lcsh:Chemical technology, Article, on-chip sensor, Equipment Failure Analysis, Systems Integration, Semiconductors, Thermography, oscillator, Product Packaging, lcsh:TP1-1185, microelectronic implants
Abstract

A fully-integrated complementary metal-oxide semiconductor (CMOS) sensor for combined temperature and humidity measurements is presented. The main purpose of the device is to monitor the hermeticity of micro-packages for implanted integrated circuits and to ensure their safe operation by monitoring the operating temperature and humidity on-chip. The smart sensor has two modes of operation, in which either the temperature or humidity is converted into a digital code representing a frequency ratio between two oscillators. This ratio is determined by the ratios of the timing capacitances and bias currents in both oscillators. The reference oscillator is biased by a current whose temperature dependency is complementary to the proportional to absolute temperature (PTAT) current. For the temperature measurement, this results in an exceptional normalized sensitivity of about 0.77%/°C at the accepted expense of reduced linearity. The humidity sensor is a capacitor, whose value varies linearly with relative humidity (RH) with a normalized sensitivity of 0.055%/% RH. For comparison, two versions of the humidity sensor with an area of either 0.2 mm2 or 1.2 mm2 were fabricated in a commercial 0.18 μm CMOS process. The on-chip readout electronics operate from a 5 V power supply and consume a current of approximately 85 μA.

Published
2022
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34. Frequency Splitting Analysis and Compensation Method for Inductive Wireless Powering of Implantable Biosensors

Author

Matthew, Schormans, Virgilio, Valente, and Andreas, Demosthenous

Subjects
inductive link, wireless power transfer, Biosensing Techniques, Prostheses and Implants, frequency splitting, medical implants, lcsh:Chemical technology, implantable biosensors, Article, Electric Power Supplies, Hardware_INTEGRATEDCIRCUITS, Humans, Telemetry, lcsh:TP1-1185, inductive powering, Wireless Technology, Software, frequency tuning
Abstract

Inductive powering for implanted medical devices, such as implantable biosensors, is a safe and effective technique that allows power to be delivered to implants wirelessly, avoiding the use of transcutaneous wires or implanted batteries. Wireless powering is very sensitive to a number of link parameters, including coil distance, alignment, shape, and load conditions. The optimum drive frequency of an inductive link varies depending on the coil spacing and load. This paper presents an optimum frequency tracking (OFT) method, in which an inductive power link is driven at a frequency that is maintained at an optimum value to ensure that the link is working at resonance, and the output voltage is maximised. The method is shown to provide significant improvements in maintained secondary voltage and system efficiency for a range of loads when the link is overcoupled. The OFT method does not require the use of variable capacitors or inductors. When tested at frequencies around a nominal frequency of 5 MHz, the OFT method provides up to a twofold efficiency improvement compared to a fixed frequency drive. The system can be readily interfaced with passive implants or implantable biosensors, and lends itself to interfacing with designs such as distributed implanted sensor networks, where each implant is operating at a different frequency.

Published
2022
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40. Bidirectional Bioelectronic Interfaces: System Design and Circuit Implications

Author

Alessandro Urso, Wouter A. Serdijn, Vasiliki Giagka, Virgilio Valente, Ronaldo Martins da Ponte, Timothy G. Constandinou, Tiago Costa, Yan Liu, Timothy J. Denison, Publica, Wellcome Trust, and Engineering & Physical Science Research Council (EPSRC)

Subjects
Bioelectronics, Computer science, 020208 electrical & electronic engineering, 02 engineering and technology, Pharmacological treatment, Clinical study, 03 medical and health sciences, 0302 clinical medicine, Risk analysis (engineering), 0202 electrical engineering, electronic engineering, information engineering, Systems design, Electronics, Electrical and Electronic Engineering, Electronic hardware, 030217 neurology & neurosurgery
Abstract

The total economic cost of neurological disorders exceeds £100 billion per annum in the United Kingdom alone, yet pharmaceutical companies continue to cut investments due to failed clinical studies and risk [1]. These challenges motivate an alternative to solely pharmacological treatments. The emerging field of bioelectronics suggests a novel alternative to pharmaceutical intervention that uses electronic hardware to directly stimulate the nervous system with physiologically inspired electrical signals [2]. Given the processing capability of electronics and precise targeting of electrodes, the potential advantages of bioelectronics include specificity in the time, method, and location of treatment, with the ability to iteratively refine and update therapy algorithms in software [3]. A primary disadvantage of the current systems is invasiveness due to surgical implantation of the device.

Published
2020
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41. Short-Range Quality-Factor Modulation (SQuirM) for Low Power High Speed Inductive Data Transfer

Author

Virgilio Valente, Dai Jiang, Andreas Demosthenous, and Matthew Schormans

Subjects
business.industry, Computer science, Circuit design, 020208 electrical & electronic engineering, Transmitter, Electrical engineering, 02 engineering and technology, Energy consumption, Power budget, 03 medical and health sciences, 0302 clinical medicine, CMOS, Hardware and Architecture, Telemetry, Hardware_INTEGRATEDCIRCUITS, 0202 electrical engineering, electronic engineering, information engineering, Wireless, Electrical and Electronic Engineering, business, 030217 neurology & neurosurgery, Electronic circuit, Data transmission
Abstract

Wireless data telemetry for implantable medical devices (IMDs) has, in general, been limited to a few Mbps, and used for applications such as transmitting recordings from an implanted monitoring device, or uploading commands to an implanted stimulator. However, modern neural interfaces need to record high resolution potentials from hundreds of neurons; this requires much higher data rates. While fast wireless communication is possible using existing standards such as WiFi, power consumption demands are far too high for IMDs. Short range inductive link based telemetry, in particular impulse-based systems such as pulse-harmonic modulation (PHM), have demonstrated transfer speeds of up to 20 Mbps with a small power budget. However, these systems require complex and precise circuits, making them potentially susceptible to inter-symbol-interference. This work presents a new method named Short-range Quality-factor Modulation (SQuirM), which retains the low power consumption and high data rate of PHM, while improving the resilience of the system and simplifying the circuit design. Transmitter and receiver circuits were fabricated using 0.35 ${\mu }m$ CMOS. The circuits were capable of reliably transceiving data at speeds of up to 50.4 Mbps, with a BER of $ , and a transmitter energy consumption of 8.11 pJ/b.

Published
2019
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42. A Comparison between Class-E DC-DC Design Methodologies for Wireless Power Transfer

Author

Fabio Pareschi, Riccardo Rovatti, Gianluca Setti, Andrea Celentano, Virgilio Valente, Wouter A. Serdijn, and A. Celentano, F. Pareschi, F.,Valente, R. Rovatti, W.A. Seridjn, G. Setti

Subjects
Coupling, Computer science, Couplings, Costs, Transmitters, Design methodology, Wireless power transfer, DC-DC power converters, Receivers, Transmitter, Receivers, Costs, Transmitters, law.invention, Reduction (complexity), law, Robustness (computer science), Design methodology, DC-DC power converters, Couplings, Electronic engineering, Wireless power transfer, Transformer, Design methods, Energy (signal processing), Class-E converters
Abstract

We consider the design of Wireless Power Transfer (WPT) systems based on inductive links and focus on recent works where the whole WPT system (i.e. both energy transmitter and energy receiver) is designed as an isolated resonant class-E DC-DC converter characterized by a loosely-coupled transformer. The aim of this work is to compare the classic WPT design approach with a novel one, which allows achieving the same performance with a significant reduction in the number of reactive components of the circuit, with beneficial effects in terms of system complexity, size, and cost. We will also show that such a reduction in the number of reactive components leads to improved performance robustness to variations in the inductive link coupling factor.

Published
2021

43. 1.2V Energy-Efficient Wireless CMOS Potentiostat for Amperometric Measurements

Author

Nazanin Neshatvar, Matthew Schormans, Andreas Demosthenous, Evdokia Pilavaki, and Virgilio Valente

Subjects
CMOS sensor, business.industry, Computer science, Amplifier, 020208 electrical & electronic engineering, 010401 analytical chemistry, Electrical engineering, 02 engineering and technology, Chip, 01 natural sciences, Potentiostat, 0104 chemical sciences, law.invention, Capacitor, CMOS, law, 0202 electrical engineering, electronic engineering, information engineering, Wireless, Electrical and Electronic Engineering, business, Wireless sensor network, Efficient energy use
Abstract

Wireless biosensors are playing a pivotal role in health monitoring, disease detection and management. The development of wireless biosensor nodes and networks strongly relies on the design of novel low-power, low-cost and flexible CMOS sensor readouts. This brief presents a CMOS potentiostat that integrates a control amplifier, a dual-slope ADC and a wireless unit on the same chip. It implements a novel time-based readout scheme, whereby the counter of the dual-slope ADC is moved to the receiver and the sensor current is encoded in the timing between two wireless pulses transmitted via pulse-harmonic modulation across an inductive link. Measured results show that the potentiostat chip can resolve a minimum input current of 10pA at a sampling frequency of 125 Hz and a power consumption of $12~\mu \text{W}$ .

Published
2020
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44. An Implantable Stimulator With Safety Sensors in Standard CMOS Process for Active Books

Author

Zhulin Zong, Dai Jiang, Virgilio Valente, Xiao Liu, Nick Donaldson, and Andreas Demosthenous

Subjects
Materials science, business.industry, 020208 electrical & electronic engineering, Electrical engineering, Pulse duration, 02 engineering and technology, Integrated circuit, 021001 nanoscience & nanotechnology, Temperature measurement, law.invention, Capacitor, CMOS, law, Microsystem, Electrode, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, 0210 nano-technology, business, Instrumentation, Voltage
Abstract

This paper presents a second-generation integrated circuit for the Active Books neural stimulation microsystem. It provides multi-channel stimulation with versatile control of stimulation profiles and reduced crosstalk from other stimulation channels. The new design features enhanced safety by monitoring the temperature and humidity inside the micropackage, and the peak electrode voltage at any stimulating electrode. The humidity sensor uses an interdigitated capacitor covered by a passivation layer and a polyimide covering. To boost sensitivity in the operating range of interest, the temperature sensor uses a temperature-insensitive current that is subtracted from a proportional-to-absolute-temperature current. A 3-b analog-to-digital converter is used to record the peak electrode voltage. All sensor data is sent to an implanted central hub using bidirectional connection with error checking. Both the stimulation electronics and sensors are integrated on a 6.2 mm $\times $ 4 mm silicon die using XFAB’s 0.6- $\mu \text{m}$ CMOS high-voltage process. No post-processing steps are involved. The stimulator uses a five-wire cable to provide the power supply and bidirectional data signals. The chip operates from a 7.5–18 V power supply and can generate stimulation currents of 1 mA, 4 mA or 8 mA with a pulse duration of 2 $\mu \text{s}$ –1.07 ms. The humidity sensor output varies linearly with relative humidity (RH) with a normalized sensitivity of 0.04%/%RH over the range of 20–90%RH. The temperature sensor has a nonlinearity of 0.4% over the range of 20–90 °C and a resolution of 0.12 °C. The stimulator is the first of its kind to include integrated temperature and humidity sensors.

Published
2016
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45. Co-integration of flip-tip patch clamp and microelectrode arrays for in-vitro recording of electrical acvity of heart cells

Author

Asli Yelkenci, Ronaldo Ponte, and Virgilio Valente

Abstract

The patch clamp has been widely considered the gold standard to measure intracellular ionic activity of single cells [1]. However, patch clamping is a laborious method and suffers from low throughput. To mitigate the disadvantages of patch clamping, planar patch clamp (PPC) chips with higher throughput have been recently introduced [2-3]. Yet those microfluidic chips do not allow to concurrently monitor the extracellular and the intracellular activity of the cells. Understanding of the complex cellular network activity and electrochemical processes, requires correlation between local field potentials (LFPs) of a population of cells and action potentials (APs) of single cells. This abstract presents a novel CMOS compatible microfluidic system that integrates flip-tip planar patch clamps (FTPPCs) and microelectrode arrays (MEAs) on the same wafer, for invitro extra- and intra-cellular recordings of electrical activity of cardiac cells. The device is fabricated using conventional wafer front- and back-side photolithography. The fabrication process leverages anisotropic wet etching selectivity of potassium hydroxide (KOH) and deep reactive ion etching (DRIE) to pattern FTPPCs. Before DRIE process, plasma-enhanced chemical vapor deposition (PECVD) of silicon dioxide (SiO2) is applied as passivation layer. After DRIE process, a metallization step is performed by sputtering titanium nitride (TiN) on patterned structures. As the final step, SiO2 is removed and backside DRIE is used to open apertures approximately with 2 µm diameter. The FTPPCs are intended to have a tip in 20 µm depth after KOH etching, and a spacing of 200 µm to ensure that mechanical stability of the device after DRIE. The planar MEAs are then patterned on the front side with 50 µm diameter and a pitch of 200 µm. A PDMS culture chamber is attached the front-side of the wafer, while a PDMS microfluidic channel is constructed on the back-side. By applying suction through the microfluidic channels, the cells are trapped in the FTPPC apertures. Potentiostatic measurements are used to record the ionic activity of the cells intracellularly, while low-noise instrumentation amplifiers are used in combination with the MEAs, to concurrently measure LPFs. Co-integration of PPC and MEAs on the same wafer can provide valuable insight in the correlation between sing

Published
2019

46. A High-Power CMOS Class-D Amplifier for Inductive-Link Medical Transmitters

Author

Virgilio Valente, Clemens Eder, Nick Donaldson, and Andreas Demosthenous

Subjects
Engineering, business.industry, Amplifier, Transmitter, Transistor, Electrical engineering, Integrated circuit, Phase detector, law.invention, Phase-locked loop, CMOS, law, Class-D amplifier, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Electrical and Electronic Engineering, business
Abstract

Powering of medical implants by inductive coupling is an effective technique, which avoids the use of bulky implanted batteries or transcutaneous wires. On the external unit side, class-D and class-E power amplifiers (PAs) are conventionally used, thanks to their high efficiency at high frequencies. The initial specifications driving this study require the use of multiple independent stimulators, which imposes serious constraints on the area and functionality of the external unit. An integrated circuit class-D PA has been designed to provide both small area and enhanced functionality, the latter achieved by the addition of an on-chip (PLL) a dead-time generator and a phase detector. The PA was designed in a 0.18- $\mu$ m CMOS high-voltage process technology and occupies an area of 9.86 mm $^2$ . It works at frequencies up to 14 MHz and 30-V supply and efficiencies higher than 80 $\%$ are obtained at 14 MHz. The PA is intended for a closed-loop transmitter system that optimizes power delivery to medical implants.

Published
2015
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47. An Energy-Efficient 1.2V 4-Channel Wireless CMOS Potentiostat for Amperometric Biosensors

Author

Matthew Schormans, Virgilio Valente, and Andreas Demosthenous

Subjects
business.industry, Computer science, 020208 electrical & electronic engineering, 010401 analytical chemistry, 02 engineering and technology, 01 natural sciences, Potentiostat, 0104 chemical sciences, law.invention, Capacitor, CMOS, law, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Wireless, business, Efficient energy use, Communication channel
Abstract

Point-of-care (PoC) diagnostics rely on the design of low-power and miniaturized readout units that can offer rapid and accurate test results, replacing the need for specialized equipment. CMOS technology can be exploited in order to design complex systems while achieving high energy efficiency for suitable operation in a mobile settings. This paper presents the design of a novel energy-efficient 4-channel wireless potentiostat chip, based on a dual-slope ADC architecture, that features a low-complexity wireless unit and a calibration approach that does not require additional circuitry. The chip was designed in a 0.35μm CMOS process. The simulated results suggest that each potentiostat channel can achieve an estimated energy efficiency of 2.5 pJ/bit from a 1.2 V supply.

Published
2018
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48. Compact pixel architecture for CMOS lateral flow immunoassay readout systems

Author

Andreas Demosthenous, Evdokia Pilavaki, Wouter A. Serdijn, and Virgilio Valente

Subjects
Transimpedance amplifier, Engineering, Correlated double sampling, business.industry, Capacitive sensing, Amplifier, 020208 electrical & electronic engineering, 02 engineering and technology, Noise (electronics), Photodiode, law.invention, CMOS, law, Hardware_INTEGRATEDCIRCUITS, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, 020201 artificial intelligence & image processing, business, Hardware_LOGICDESIGN, Active noise control
Abstract

A novel pixel architecture for CMOS image sensors is presented. It uses only one amplifier for both integration of the photocurrent and in-pixel noise cancelation, thus minimizing power consumption. The circuit is specifically designed to be used in readout systems for lateral flow immunoassays. In addition a switching technique is introduced enabling the use of column correlated double sampling technique in capacitive transimpedance amplifier pixel architectures without the use of any memory cells. As a result the reset noise which is crucial in these architectures can be suppressed. The circuit has been designed in a 0.35-μm CMOS technology and simulations are presented to show its performance.

Published
2017
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49. Correction to 'Practical Inductive Link Design for Biomedical Wireless Power Transfer: A Tutorial' [Oct 18 1112-1130]

Author

Andreas Demosthenous, Matthew Schormans, and Virgilio Valente

Subjects
business.industry, Computer science, Biomedical Engineering, Link design, Finite element method, Software, Q factor, Electronic engineering, Microelectronics, Wireless, Wireless power transfer, Electrical and Electronic Engineering, business, Electronic circuit
Abstract

Presents corrections to the paper, “Practical inductive link design for biomedical wireless power transfer: A tutorial,” (Schormans, M., et al), IEEE Trans. Biomed. Circuits Syst., vol. 12, no. 5, pp. 1112–1130, Oct. 2018.

Published
2019
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50. Frequency Splitting Analysis and Compensation Method for Inductive Wireless Powering of Implantable Biosensors

Author

Demosthenous, Matthew Schormans, Virgilio Valente, and Andreas

Subjects
frequency splitting, frequency tuning, implantable biosensors, inductive link, inductive powering, medical implants, wireless power transfer, Hardware_INTEGRATEDCIRCUITS
Abstract

Inductive powering for implanted medical devices, such as implantable biosensors, is a safe and effective technique that allows power to be delivered to implants wirelessly, avoiding the use of transcutaneous wires or implanted batteries. Wireless powering is very sensitive to a number of link parameters, including coil distance, alignment, shape, and load conditions. The optimum drive frequency of an inductive link varies depending on the coil spacing and load. This paper presents an optimum frequency tracking (OFT) method, in which an inductive power link is driven at a frequency that is maintained at an optimum value to ensure that the link is working at resonance, and the output voltage is maximised. The method is shown to provide significant improvements in maintained secondary voltage and system efficiency for a range of loads when the link is overcoupled. The OFT method does not require the use of variable capacitors or inductors. When tested at frequencies around a nominal frequency of 5 MHz, the OFT method provides up to a twofold efficiency improvement compared to a fixed frequency drive. The system can be readily interfaced with passive implants or implantable biosensors, and lends itself to interfacing with designs such as distributed implanted sensor networks, where each implant is operating at a different frequency.

Published
2016
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