CMOS level shifters from 0 to 18 V output

A design methodology for level shifters voltage translators, where the output voltage ranges from 0 to 18 V, and the input voltage ranges from 2 to 5.5 V in a 0.6 lm CMOS-HV technology, is presented. This family of circuits have a special interest in the case of implantable medical devices where is common to handle previously unknown voltages either positive or negative, above or below the control logic supply VDD. Two application examples are presented: a composite switch to control negative stimuli voltage pulses, and a multi-channel programmable charge-pump voltage multiplier, aimed at charging the output capacitors of an IMD.Agencia Nacional de Investigación e Innovació

Wireless power transfer for combined sensing and stimulation in implantable biomedical devices

Actuellement, il existe une forte demande de Headstage et de microsystèmes intégrés implantables pour étudier l’activité cérébrale de souris de laboratoire en mouvement libre. De tels dispositifs peuvent s’interfacer avec le système nerveux central dans les paradigmes électriques et optiques pour stimuler et surveiller les circuits neuronaux, ce qui est essentiel pour découvrir de nouveaux médicaments et thérapies contre des troubles neurologiques comme l’épilepsie, la dépression et la maladie de Parkinson. Puisque les systèmes implantables ne peuvent pas utiliser une batterie ayant une grande capacité en tant que source d’énergie primaire dans des expériences à long terme, la consommation d’énergie du dispositif implantable est l’un des principaux défis de ces conceptions. La première partie de cette recherche comprend notre proposition de la solution pour diminuer la consommation d’énergie des microcircuits implantables. Nous proposons un nouveau circuit de décalage de niveau qui convertit les niveaux de signaux sub-seuils en niveaux ultra-bas à haute vitesse en utilisant une très faible puissance et une petite zone de silicium, ce qui le rend idéal pour les applications de faible puissance. Le circuit proposé introduit une nouvelle topologie de décaleur de niveau de tension utilisant un condensateur de décalage de niveau pour augmenter la plage de tensions de conversion, tout en réduisant considérablement le retard de conversion. Le circuit proposé atteint un délai de propagation plus court et une zone de silicium plus petite pour une fréquence de fonctionnement et une consommation d’énergie donnée par rapport à d’autres solutions de circuit. Les résultats de mesure sont présentés pour le circuit proposé fabriqué dans un processus CMOS TSMC de 0,18- mm. Le circuit présenté peut convertir une large gamme de tensions d’entrée de 330 mV à 1,8 V et fonctionner sur une plage de fréquence de 100 Hz à 100 MHz. Il a un délai de propagation de 29 ns et une consommation d’énergie de 61,5 nW pour les signaux d’entrée de 0,4 V, à une fréquence de 500 kHz, surpassant les conceptions précédentes. La deuxième partie de cette recherche comprend nos systèmes de transfert d’énergie sans fil proposé pour les applications optogénétiques. L’optogénétique est la combinaison de la méthode génétique et optique d’excitation, d’enregistrement et de contrôle des neurones biologiques. Ce système combine plusieurs technologies telles que les MEMS et la microélectronique pour collecter et transmettre les signaux neuronaux et activer un stimulateur optique via une liaison sans fil. Puisque les stimulateurs optiques consomment plus de puissance que les stimulateurs électriques, l’interface utilise la transmission de puissance par induction en utilisant des moyens innovants au lieu de la batterie avec la petite capacité comme source d’énergie.Notre première contribution dans la deuxième partie fournit un système de cage domestique intelligent basé sur des barrettes multi-bobines superposées à travers un récepteur multicellulaire implantable mince de taille 1×1 cm2, implanté sous le cuir chevelu d’une souris de laboratoire, et unité de gestion de l’alimentation intégrée. Ce système inductif est conçu pour fournir jusqu’à 35,5 mW de puissance délivrée à un émetteur-récepteur full duplex de faible puissance entièrement intégré pour prendre en charge des implants neuronaux à haute densité et bidirectionnels. L’émetteur (TX) utilise une bande ultra-large à impulsions radio basée sur des approches de combinaison, et le récepteur (RX) utilise une topologie à bande étroite à incrémentation de 2,4 GHz. L’émetteur-récepteur proposé fournit un débit de données de liaison montante TX à 500 Mbits/s double et un débit de données de liaison descendante RX à 100 Mbits/s, et est entièrement intégré dans un processus CMOS TSMC de 0,18-mm d’une taille totale de 0,8 mm2 . La puissance peut être délivrée à partir d’un signal de porteuse de 13,56-MHz avec une efficacité globale de transfert de puissance supérieure à 5% sur une distance de séparation allant de 3 cm à 5 cm. Notre deuxième contribution dans les systèmes de collecte d’énergie porte sur la conception et la mise en oeuvre d’une cage domestique de transmission de puissance sans fil (WPT) pour une plate-forme de neurosciences entièrement sans fil afin de permettre des expériences optogénétiques ininterrompues avec des rongeurs de laboratoire vivants. La cage domestique WPT utilise un nouveau réseau hybride de transmetteurs de puissance (TX) et des résonateurs multi-bobines segmentés pour atteindre une efficacité de transmission de puissance élevée (PTE) et délivrer une puissance élevée sur des distances aussi élevées que 20 cm. Le récepteur de puissance à bobines multiples (RX) utilise une bobine RX d’un diamètre de 1 cm et une bobine de résonateur d’un diamètre de 1,5 cm. L’efficacité moyenne du transfert de puissance WPT est de 29, 4%, à une distance nominale de 7 cm, pour une fréquence porteuse de 13,56 MHz. Il a des PTE maximum et minimum de 50% et 12% le long de l’axe Z et peut délivrer une puissance constante de 74 mW pour alimenter le headstage neuronal miniature. En outre, un dispositif implantable intégré dans un processus CMOS TSMC de 0,18-mm a été conçu et introduit qui comprend 64 canaux d’enregistrement, 16 canaux de stimulation optique, capteur de température, émetteur-récepteur et unité de gestion de l’alimentation (PMU). Ce circuit est alimenté à l’intérieur de la cage du WPT à l’aide d’une bobine réceptrice d’un diamètre de 1,5 cm pour montrer les performances du circuit PMU. Deux tensions régulées de 1,8 V et 1 V fournissent 79 mW de puissance pour tout le système sur une puce. Notre dernière contribution est un système WPT insensible aux désalignements angulaires pour alimenter un headstage pour des applications optogénétiques qui a été précédemment proposé par le Laboratoire de Microsystèmes Biomédicaux (BioML-UL) à ULAVAL. Ce système est la version étendue de notre deuxième contribution aux systèmes de collecte d’énergie.Dans la version mise à jour, un récepteur de puissance multi-bobines utilise une bobine RX d’un diamètre de 1,0 cm et une nouvelle bobine de résonateur fendu d’un diamètre de 1,5 cm, qui résiste aux défauts d’alignement angulaires. Dans cette version qui utilise une cage d’animal plus petite que la dernière version, 4 résonateurs sont utilisés côté TX. De plus, grâce à la forme et à la position de la bobine de répéteur L3 du côté du récepteur, la liaison résonnante hybride présentée peut correctement alimenter la tête sans interruption causée par le désalignement angulaire dans toute la cage de la maison. Chaque 3 tours du répéteur RX a été enveloppé avec un diamètre de 1,5 cm, sous différents angles par rapport à la bobine réceptrice. Les résultats de mesure montrent un PTE maximum et minimum de 53 % et 15 %. La méthode proposée peut fournir une puissance constante de 82 mW pour alimenter le petit headstage neural pour les applications optogénétiques. De plus, dans cette version, la performance du système est démontrée dans une expérience in-vivo avec une souris ChR2 en mouvement libre qui est la première expérience optogénétique sans fil et sans batterie rapportée avec enregistrement électrophysiologique simultané et stimulation optogénétique. L’activité électrophysiologique a été enregistrée après une stimulation optogénétique dans le Cortex Cingulaire Antérieur (CAC) de la souris.Our first contribution in the second part provides a smart home-cage system based on overlapped multi-coil arrays through a thin implantable multi-coil receiver of 1×1 cm2 of size, implantable bellow the scalp of a laboratory mouse, and integrated power management circuits. This inductive system is designed to deliver up to 35.5 mW of power delivered to a fully-integrated, low-power full-duplex transceiver to support high-density and bidirectional neural implants. The transmitter (TX) uses impulse radio ultra-wideband based on an edge combining approach, and the receiver (RX) uses a 2.4- GHz on-off keying narrow band topology. The proposed transceiver provides dual-band 500-Mbps TX uplink data rate and 100-Mbps RX downlink data rate, and it is fully integrated into 0.18-mm TSMC CMOS process within a total size of 0.8 mm2. The power can be delivered from a 13.56-MHz carrier signal with an overall power transfer efficiency above 5% across a separation distance ranging from 3 cm to 5 cm. Our second contribution in power-harvesting systems deals with designing and implementation of a WPT home-cage for a fully wireless neuroscience platform for enabling uninterrupted optogenetic experiments with live laboratory rodents. The WPT home-cage uses a new hybrid parallel power transmitter (TX) coil array and segmented multi-coil resonators to achieve high power transmission efficiency (PTE) and deliver high power across distances as high as 20 cm. The multi-coil power receiver (RX) uses an RX coil with a diameter of 1 cm and a resonator coil with a diameter of 1.5 cm. The WPT home-cage average power transfer efficiency is 29.4%, at a nominal distance of 7 cm, for a power carrier frequency of 13.56-MHz. It has maximum and minimum PTE of 50% and 12% along the Z axis and can deliver a constant power of 74 mW to supply the miniature neural headstage. Also, an implantable device integrated into a 0.18-mm TSMC CMOS process has been designed and introduced which includes 64 recording channels, 16 optical stimulation channels, temperature sensor, transceiver, and power management unit (PMU). This circuit powered up inside the WPT home-cage using receiver coil with a diameter of 1.5 cm to show the performance of the PMU circuit. Two regulated voltages of 1.8 V and 1 V provide 79 mW of power for all the system on a chip. Our last contribution is an angular misalignment insensitive WPT system to power up a headstage which has been previously proposed by the Biomedical Microsystems Laboratory (BioML-UL) at ULAVAL for optogenetic applications. This system is the extended version of our second contribution in power-harvesting systems. In the updated version a multi-coil power receiver uses an RX coil with a diameter of 1.0 cm and a new split resonator coil with a diameter of 1.5 cm, which is robust against angular misalignment. In this version which is using a smaller animal home-cage than the last version, 4 resonators are used on the TX side. Also, thanks to the shape and position of the repeater coil of L3 on the receiver side, the presented hybrid resonant link can properly power up the headstage without interruption caused by the angular misalignment all over the home-cage. Each 3 turns of the RX repeater has been wrapped up with a diameter of 1.5 cm, in different angles compared to the receiver coil. Measurement results show a maximum and minimum PTE of 53 % and 15 %. The proposed method can deliver a constant power of 82 mW to supply the small neural headstage for the optogenetic applications. Additionally, in this version, the performance of the system is demonstrated within an in-vivo experiment with a freely moving ChR2 mouse which is the first fully wireless and batteryless optogenetic experiment reported with simultaneous electrophysiological recording and optogenetic stimulation. Electrophysiological activity was recorded after delivering optogenetic stimulation in the Anterior Cingulate Cortex (ACC) of the mouse.Currently, there is a high demand for Headstage and implantable integrated microsystems to study the brain activity of freely moving laboratory mice. Such devices can interface with the central nervous system in both electrical and optical paradigms for stimulating and monitoring neural circuits, which is critical to discover new drugs and therapies against neurological disorders like epilepsy, depression, and Parkinson’s disease. Since the implantable systems cannot use a battery with a large capacity as a primary source of energy in long-term experiments, the power consumption of the implantable device is one of the leading challenges of these designs. The first part of this research includes our proposed solution for decreasing the power consumption of the implantable microcircuits. We propose a novel level shifter circuit which converting subthreshold signal levels to super-threshold signal levels at high-speed using ultra low power and a small silicon area, making it well-suited for low-power applications such as wireless sensor networks and implantable medical devices. The proposed circuit introduces a new voltage level shifter topology employing a level-shifting capacitor to increase the range of conversion voltages, while significantly reducing the conversion delay. The proposed circuit achieves a shorter propagation delay and a smaller silicon area for a given operating frequency and power consumption compared to other circuit solutions. Measurement results are presented for the proposed circuit fabricated in a 0.18-mm TSMC CMOS process. The presented circuit can convert a wide range of the input voltages from 330 mV to 1.8 V, and operate over a frequency range of 100-Hz to 100-MHz. It has a propagation delay of 29 ns, and power consumption of 61.5 nW for input signals 0.4 V, at a frequency of 500-kHz, outperforming previous designs. The second part of this research includes our proposed wireless power transfer systems for optogenetic applications. Optogenetics is the combination of the genetic and optical method of excitation, recording, and control of the biological neurons. This system combines multiple technologies such as MEMS and microelectronics to collect and transmit the neuronal signals and to activate an optical stimulator through a wireless link. Since optical stimulators consume more power than electrical stimulators, the interface employs induction power transmission using innovative means instead of the battery with the small capacity as a power source

Modulation Techniques for Biomedical Implanted Devices and Their Challenges

Implanted medical devices are very important electronic devices because of their usefulness in monitoring and diagnosis, safety and comfort for patients. Since 1950s, remarkable efforts have been undertaken for the development of bio-medical implanted and wireless telemetry bio-devices. Issues such as design of suitable modulation methods, use of power and monitoring devices, transfer energy from external to internal parts with high efficiency and high data rates and low power consumption all play an important role in the development of implantable devices. This paper provides a comprehensive survey on various modulation and demodulation techniques such as amplitude shift keying (ASK), frequency shift keying (FSK) and phase shift keying (PSK) of the existing wireless implanted devices. The details of specifications, including carrier frequency, CMOS size, data rate, power consumption and supply, chip area and application of the various modulation schemes of the implanted devices are investigated and summarized in the tables along with the corresponding key references. Current challenges and problems of the typical modulation applications of these technologies are illustrated with a brief suggestions and discussion for the progress of implanted device research in the future. It is observed that the prime requisites for the good quality of the implanted devices and their reliability are the energy transformation, data rate, CMOS size, power consumption and operation frequency. This review will hopefully lead to increasing efforts towards the development of low powered, high efficient, high data rate and reliable implanted devices

High-efficiency high voltage hybrid charge pump design with an improved chip area

A hybrid charge pump was developed in a 0.13- $\mu \text{m}$ Bipolar-CMOS-DMOS (BCD) process which utilised high drain-source voltage MOS devices and low-voltage integrated metal-insulator-metal (MIM) capacitors. The design consisted of a zero-reversion loss cross-coupled stage and a new self-biased serial-parallel charge pump design. The latter has been shown to have an area reduction of 60% in comparison to a Schottky diode-based Dickson charge pump operating at the same frequency. Post-layout simulations were carried out which demonstrated a peak efficiency of 38% at the output voltage of 18.5 V; the maximum specified output voltage of 27 V was also achieved. A standalone serial-parallel charge pump was shown to have a better transient response and a flatter efficiency curve; these are preferable for time-sensitive applications with a requirement of a broader range of output currents. These findings have significant implications for reducing the total area of implantable high-voltage devices without sacrificing charge pump efficiency or maximum output voltage

A HIGHLY-SCALABLE DC-COUPLED DIRECT-ADC NEURAL RECORDING CHANNEL ARCHITECTURE WITH INPUT-ADAPTIVE RESOLUTION

This thesis presents the design, development, and characterization of a novel neural recording channel architecture with (a) quantization resolution that is adaptive to the input signal's level of activity, (b) fully-dynamic power consumption that is linearly proportional to the recording resolution, and (c) immunity to DC offset and drifts at the input. Our results demonstrate the proposed design's capability in conducting neural recording with near lossless input-adaptive data compression, leading to a significant reduction in the energy required for both recording and data transmission, hence allowing for a potential high scaling of the number of recording channels integrated on a single implanted microchip without the need to increase the power budget. The proposed channel with the implemented compression technique is implemented in a standard 130nm CMOS technology with overall power consumption of 7.6uW and active area of 92×92µm for the implemented digital-backend

A HIGHLY-SCALABLE DC-COUPLED DIRECT-ADC NEURAL RECORDING CHANNEL ARCHITECTURE WITH INPUT-ADAPTIVE RESOLUTION

This thesis presents the design, development, and characterization of a novel neural recording channel architecture with (a) quantization resolution that is adaptive to the input signal's level of activity, (b) fully-dynamic power consumption that is linearly proportional to the recording resolution, and (c) immunity to DC offset and drifts at the input. Our results demonstrate the proposed design's capability in conducting neural recording with near lossless input-adaptive data compression, leading to a significant reduction in the energy required for both recording and data transmission, hence allowing for a potential high scaling of the number of recording channels integrated on a single implanted microchip without the need to increase the power budget. The proposed channel with the implemented compression technique is implemented in a standard 130nm CMOS technology with overall power consumption of 7.6uW and active area of 9292m for the implemented digital-backend

Wireless power and data transmission to high-performance implantable medical devices

Novel techniques for high-performance wireless power transmission and data interfacing with implantable medical devices (IMDs) were proposed. Several system- and circuit-level techniques were developed towards the design of a novel wireless data and power transmission link for a multi-channel inductively-powered wireless implantable neural-recording and stimulation system. Such wireless data and power transmission techniques have promising prospects for use in IMDs such as biosensors and neural recording/stimulation devices, neural interfacing experiments in enriched environments, radio-frequency identification (RFID), smartcards, near-field communication (NFC), wireless sensors, and charging mobile devices and electric vehicles. The contributions in wireless power transfer are the development of an RFID-based closed-loop power transmission system, a high-performance 3-coil link with optimal design procedure, circuit-based theoretical foundation for magnetic-resonance-based power transmission using multiple coils, a figure-of-merit for designing high-performance inductive links, a low-power and adaptive power management and data transceiver ASIC to be used as a general-purpose power module for wireless electrophysiology experiments, and a Q-modulated inductive link for automatic load matching. In wireless data transfer, the contributions are the development of a new modulation technique called pulse-delay modulation for low-power and wideband near-field data communication and a pulse-width-modulation impulse-radio ultra-wideband transceiver for low-power and wideband far-field data transmission.Ph.D

Biomimetic Based Applications

The interaction between cells, tissues and biomaterial surfaces are the highlights of the book "Biomimetic Based Applications". In this regard the effect of nanostructures and nanotopographies and their effect on the development of a new generation of biomaterials including advanced multifunctional scaffolds for tissue engineering are discussed. The 2 volumes contain articles that cover a wide spectrum of subject matter such as different aspects of the development of scaffolds and coatings with enhanced performance and bioactivity, including investigations of material surface-cell interactions