An intelligent, multi-transducer signal conditioning design for manufacturing applications

This paper describes a flexible, intelligent, high bandwidth, signal conditioning reference design and implementation, which is suitable for a wide range of force and displacement transducers in manufacturing applications. The flexibility inherent in the design has allowed more than 10 specialised transducer conditioning boards to be replaced by this single design, in a range of bespoke mechanical test equipment manufactured by the authors. The board is able to automatically reconfigure itself for a wide range of transducers and calibrate and balance the transducer. The range of transducers includes LVDT, AC/DC strain gauge and inductive bridges, and a range of standard industrial voltage current interface transducers. Further, with a minor lowcost addition to the transducer connector, the board is able to recognise the type of transducer, reconfigure itself and store the calibration data within the transducer, thereafter allowing a plugand-play operation as transducers are changed. The paper provides an example of the operation in typical manufacturing test application and illustrates the stability and noise performance of the design

A 36 µW 1.1 mm2 reconfigurable analog front-end for cardiovascular and respiratory signals recording

© 2018 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting /republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other worksThis paper presents a 1.2 V 36 µW reconfigurable analog front-end (R-AFE) as a general-purpose low-cost IC for multiple-mode biomedical signals acquisition. The R-AFE efficiently reuses a reconfigurable preamplifier, a current generator (CG), and a mixed signal processing unit, having an area of 1.1 mm2 per R-AFE while supporting five acquisition modes to record different forms of cardiovascular and respiratory signals. The R-AFE can interface with voltage-, current-, impedance-, and light-sensors and hence can measure electrocardiography (ECG), bio-impedance (BioZ), photoplethysmogram (PPG), galvanic skin response (GSR), and general-purpose analog signals. Thanks to the chopper preamplifier and the low-noise CG utilizing dynamic element matching, the R-AFE mitigates 1/f noise from both the preamplifier and the CG for improved measurement sensitivity. The IC achieves competitive performance compared to the state-of-the-art dedicated readout ICs of ECG, BioZ, GSR, and PPG, but with approximately 1.4×-5.3× smaller chip area per channel.Peer ReviewedPostprint (author's final draft

A versatile wearable based on reconfigurable hardware for biomedical measurements

In this work a versatile hardware platform based on reconfigurable devices is presented. This platform it intended for the acquisition of multiple biosignals, only requiring a reconfiguration to switch applications. This prototype has been combined with graphene-based, flexible electrodes to cover the application to different biosignals presented in this paper, which are electrocardiogram, electrooculogram and electromyogram. The features of this system provide to the user and to medical personnel a complete set of diagnosis tools, available both at home and hospitals, to be used as a triage tool and for remote patient monitoring. Additionally, an Android application has been developed for signal processing and data presentation to the user. The results obtained demonstrate the wide range of possibilities in portable/wearable applications of the combination of reconfigurable devices and flexible electronics, especially for the remote monitoring of patients using multiple biosignals of interest. The versatility of this device makes it a complete set of monitoring tools integrated in a reduced size device

Design of a Programmable Passive SoC for Biomedical Applications Using RFID ISO 15693/NFC5 Interface

Low power, low cost inductively powered passive biotelemetry system involving fully customized RFID/NFC interface base SoC has gained popularity in the last decades. However, most of the SoCs developed are application specific and lacks either on-chip computational or sensor readout capability. In this paper, we present design details of a programmable passive SoC in compliance with ISO 15693/NFC5 standard for biomedical applications. The integrated system consists of a 32-bit microcontroller, a sensor readout circuit, a 12-bit SAR type ADC, 16 kB RAM, 16 kB ROM and other digital peripherals. The design is implemented in a 0.18 μ m CMOS technology and used a die area of 1.52 mm × 3.24 mm. The simulated maximum power consumption of the analog block is 592 μ W. The number of external components required by the SoC is limited to an external memory device, sensors, antenna and some passive components. The external memory device contains the application specific firmware. Based on the application, the firmware can be modified accordingly. The SoC design is suitable for medical implants to measure physiological parameters like temperature, pressure or ECG. As an application example, the authors have proposed a bioimplant to measure arterial blood pressure for patients suffering from Peripheral Artery Disease (PAD)

A self-powered single-chip wireless sensor platform

Internet of things” require a large array of low-cost sensor nodes, wireless connectivity, low power operation and system intelligence. On the other hand, wireless biomedical implants demand additional specifications including small form factor, a choice of wireless operating frequencies within the window for minimum tissue loss and bio-compatibility This thesis describes a low power and low-cost internet of things system suitable for implant applications that is implemented in its entirety on a single standard CMOS chip with an area smaller than 0.5 mm2. The chip includes integrated sensors, ultra-low-power transceivers, and additional interface and digital control electronics while it does not require a battery or complex packaging schemes. It is powered through electromagnetic (EM) radiation using its on-chip miniature antenna that also assists with transmit and receive functions. The chip can operate at a short distance (a few centimeters) from an EM source that also serves as its wireless link. Design methodology, system simulation and optimization and early measurement results are presented

RF Power Transfer, Energy Harvesting, and Power Management Strategies

Energy harvesting is the way to capture green energy. This can be thought of as a recycling process where energy is converted from one form (here, non-electrical) to another (here, electrical). This is done on the large energy scale as well as low energy scale. The former can enable sustainable operation of facilities, while the latter can have a significant impact on the problems of energy constrained portable applications. Different energy sources can be complementary to one another and combining multiple-source is of great importance. In particular, RF energy harvesting is a natural choice for the portable applications. There are many advantages, such as cordless operation and light-weight. Moreover, the needed infra-structure can possibly be incorporated with wearable and portable devices. RF energy harvesting is an enabling key player for Internet of Things technology. The RF energy harvesting systems consist of external antennas, LC matching networks, RF rectifiers for ac to dc conversion, and sometimes power management. Moreover, combining different energy harvesting sources is essential for robustness and sustainability. Wireless power transfer has recently been applied for battery charging of portable devices. This charging process impacts the daily experience of every human who uses electronic applications. Instead of having many types of cumbersome cords and many different standards while the users are responsible to connect periodically to ac outlets, the new approach is to have the transmitters ready in the near region and can transfer power wirelessly to the devices whenever needed. Wireless power transfer consists of a dc to ac conversion transmitter, coupled inductors between transmitter and receiver, and an ac to dc conversion receiver. Alternative far field operation is still tested for health issues. So, the focus in this study is on near field. The goals of this study are to investigate the possibilities of RF energy harvesting from various sources in the far field, dc energy combining, wireless power transfer in the near field, the underlying power management strategies, and the integration on silicon. This integration is the ultimate goal for cheap solutions to enable the technology for broader use. All systems were designed, implemented and tested to demonstrate proof-of concept prototypes

Integrated Electronics to Control and Readout Electrochemical Biosensors for Implantable Applications

Biosensors can effectively be used to monitor multiple metabolites such as glucose, lactate, ATP and drugs in the human body. Continuous monitoring of these metabolites is essential for patients with chronic or critical conditions. Moreover, this can be used to tune the dosage of a drug for each individual patient, in order to achieve personalized therapy. Implantable medical devices (IMDs) based on biosensors are emerging as a valid alternative for blood tests in laboratories. They can provide continuous monitoring while reduce the test costs. The potentiostat plays a fundamental role in modern biosensors. A potentiostat is an electronic device that controls the electrochemical cell, using three electrodes, and runs the electrochemical measurement. In particular the IMDs require a low-power, fully-integrated, and autonomous potentiostats to control and readout the biosensors. This thesis describes two integrated circuits (ICs) to control and readout multi-target biosensors: LOPHIC and ARIC. They enable chronoamperometry and cyclic voltammetrymeasurements and consume sub-mW power. The design, implementation, characterisation, and validation with biosensors are presented for each IC. To support the calibration of the biosensors with environmental parameters, ARIC includes circuitry to measure the pHand temperature of the analyte through an Iridiumoxide pH sensor and an off-chip resistor-temperature detector (RTD). In particular, novel circuits to convert resistor value into digital are designed for RTD readout. ARIC is integrated into two IMDs aimed for health-care monitoring and personalized therapy. The control and readout of the embedded sensor arrays have been successfully achieved, thanks to ARIC, and validated for glucose and paracetamol measurements while it is remotely powered through an inductive link. To ensure the security and privacy of IMDs, a lightweight cryptographic system (LCS) is presented. This is the first ASIC implementation of a cryptosystem for IMDs, and is integrated into ARIC. The resulting system provides a unique and fundamental capability by immediately encrypting and signing the sensor data upon its creation within the body. Nano-structures such as Carbon nanotubes have been widely used to improve the sensitivity of the biosensors. However, in most of the cases, they introduce more noise into the measurements and produce a large background current. In this thesis the noise of the sensors incorporating CNTs is studied for the first time. The effect of CNTs as well as sensor geometry on the signal to noise ratio of the sensors is investigated experimentally. To remove the background current of the sensors, a differential readout scheme has been proposed. In particular, a novel differential readout IC is designed and implemented that measures inputcurrents within a wide dynamic range and produces a digital output that corresponds to the -informative- redox current of the biosensor

Metabolomic sensing system for personalised medicine using an integrated CMOS sensor array technology

Precision healthcare, also known as personalised medicine, is based on our understanding of the fundamental building blocks of biological systems, with the ultimate aim to clinically identify the best therapeutic strategy for each individual. Genomics and sequencing technologies have brought this to the foreground by enabling an individual’s entire genome to be mapped for less than a thousand dollar in just one day. Recently, metabolomics, the quantitative measurement of small molecules, has emerged as a field to understand an individual’s molecular profile in terms of both genetics and environmental factors. This is crucial because a genome could only indicate an individual’s susceptibility to a particular disease, whereas a metabolome provides an immediate measurement of body function, enabling a means of diagnosis. However, the current approach of measurements depends on large-scale and expensive equipment such as mass spectroscopy and NMR instrumentation, which does not offer a single analytical platform to detect the entire metabolome. This thesis describes the development of an integrated CMOS sensor array technology as a single platform to quantify different metabolites using specific enzymes. The key stages in the work were: to construct instrumentation systems to perform enzyme assays on the CMOS sensor array; to establish techniques to package the CMOS sensor array for an aqueous environment; to implement and develop a room temperature Ta2O5 sputtering process on CMOS sensor array for hydrogen ion detection; to collaborate with a chemist and investigate an inorganic layer on top of the CMOS ISFET sensor to show an improvement of sensitivity towards potassium ion; to test several different enzyme assays electrochemically and optically and show the functionalities of the sensors; to devise microfluidic channels for segregation of the sensor array into different compartments and perform enzyme immobilisation techniques on CMOS chips; and integrate the packaged chip with microfluidic channels and enzyme immobilisation using 2D inkjet printer into a complete system that has the potential to be used as a multi-enzyme platform for detection of different metabolites. Two CMOS sensor array chips (1) a 256×256-pixel ISFET array chip and (2) a 16×16-pixel Multi-Corder chip were fully understood. Therefore, a high-speed instrumentation system was constructed for the ISFET array chip with a maximum readout speed of 500 frames per second, with 2D and 3D imaging capability, as well as single pixel analysis. Follow by that, a miniaturised measurement platform was implemented for the Multi-Corder chip that has three different sensor arrays, which are ISFET, PD and SPAD. All the sensor arrays can be operated independently or together (ionic sensor and one of the optical sensors). Several post-processing steps were investigated to allow suitable fabrication process on small 4×4 mm2 CMOS chips. Post-processing of the CMOS chips was first established using room temperature sputtering process for Ta2O5 layer, achieving Ta:O ratio of 1:1.77 and a surface roughness of 0.42 nm. This Ta2O5 layer was then fabricated on top of CMOS ISFETs, which improves the ISFET pH sensitivity to 45 mV/pH, with an average drift of 6.5 ± 8.6 mV/hour from chip to chip and a working pH range of 2 to 12. Furthermore, a layer of POMs was drop casted on top of Ta2O5 ISFET to make ISFET sensitive to potassium ions. This was investigated in terms of potassium ions sensitivity, hydrogen ions sensitivity and sodium ions as interfering background ions. The POMs Ta2O5 ISFET was found to have a net potassium sensitivity of 75 mV/pK, with a linear range between pH 1.5 to 3. Moreover, the POMs ISFET has -5 mV/pH in pH sensitivity, showing that it is selectivity towards potassium ions and not hydrogen ions. However, sodium ions were found to produce a large interference towards the pK sensitivity of POMs ISFET and reduced the pK sensitivity of POMs ISFET. Hence, further work is still required to modify POMs layer for better selectivity and sensitivity. Besides that, microfluidic channels were fabricated on top of the CMOS chips that could provide segregation for multiple enzyme assays on a single chip. In addition, a PDMS and a manual dam and fill method were developed to encapsulate the CMOS chips for wet biochemistry measurements. The CMOS sensor array was found to have the ensemble averaging capability to reduce noise as a function of √N , where N is the number of sensors used for averaging. Several enzyme assays that include: hexokinase, lactate dehydrogenase, urease and lipase were tested on the ISFET sensor array. Moreover, using an optical sensor array, namely a PD on the Multi-Corder chip and using LED illumination, quantification of cholesterol levels in human blood serum was demonstrated. Enzyme kinetics calculations were performed for hexokinase and cholesterol oxidase assays and the results were comparable to that obtained from a bench top spectrophotometer. This shows the CMOS sensor array can be used as a low cost portable diagnostic device. Several enzyme immobilisation techniques were explored but were unsuccessful. Alginate enzyme gel immobilisation with a 2D inkjet printer was found to be the best candidate to bio-functionalise the CMOS sensor array. The packaged chip was integrated with microfluidic channels and alginate enzyme gel immobilisation into a complete system, in order to perform an enzyme assay with its control experiments simultaneously on a single chip. As a proof-of-concept, this complete system has the potential to be used as a multiple metabolite quantification platform

Neue Methodik zur Optimierung der Energieeffizienz des Künstlichen Akkommodationssystems

Das Künstliche Akkommodationssystem ist ein neuer Ansatz zur Wiederherstellung der Akkommodationsfähigkeit des menschlichen Auges. Das hochintegrierte, gekapselte Mikrosystem soll autonom die Funktion der natürlichen Linse übernehmen. Das Ziel der Arbeit besteht darin, eine neue Methodik zur Optimierung der Energieeffizienz des Künstlichen Akkommodationssystems zu entwickeln. Dazu werden Konzepte zur Optimierung der Spannungswandlung sowie Konzepte zur Reduktion der Leistungsaufnahme und zur Verlängerung der autonomen Betriebsdauer des Implantats vorgestellt