Regulador de tensión LDO de muy bajo consumo para sistemas de recolección de energía en el propio chip

Universidad de Sevilla. Máster Universitario en Microelectrónica: Diseño y Aplicaciones de Sistemas Micro/Nanométrico

Ultralow power voltage reference circuit for implantable devices in standard CMOS technology

This is the peer reviewed version of the following article: Óscar Pereira-Rial, Paula López, Juan M. Carrillo, Victor M. Brea and Diego Cabello (2019) Ultralow power voltage reference circuit for implantable devices in standard CMOS technology. International journal of circuit theory and applications, 47 (7), 991-1005, which has been published in final form at https://doi.org/10.1002/cta.2643. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Use of Self-Archived VersionsAn ultralow power CMOS voltage reference for body implantable devices is presented in this paper. The circuit core consists of only regular threshold voltage PMOS transistors, thus leading to a very reduced output voltage dispersion, defined as σ/μ, and extremely low power consumption. A mathematical model of the generated reference voltage was obtained by solving circuit equations, and its numerical solution has been validated by extensive electrical simulations using a commercial circuit simulator. The proposed solution incorporates a passive RC low‐pass filter, to enhance power supply rejection (PSR) over a wide frequency range, and a speed‐up section, to accelerate the switching‐on of the circuit. The prototype was implemented in 0.18 μm standard CMOS technology and is able to operate with supply voltages ranging from 0.7 to 1.8 V providing a measured output voltage value of 584.2 mV at the target temperature of 36° C. The measured σ/μ dispersion of the reference voltage generated is 0.65% without the need of trimming. At the minimum supply of 0.7 V, the experimental power consumption is 64.5 pW, while the measured PSR is kept below –60 dB from DC up to the MHz frequency rangeThis work has been partially funded by the Spanish government projects TEC2015‐66878‐C3‐3‐R (MINECO/FEDER) and RTI2018‐097088‐B‐C32 (FEDER), by the Xunta de Galicia under project ED431C2017/69, by the Consellería de Cultura, Educación e Ordenación Universitaria (accreditation 2016‐2019, ED431G/08 and reference competitive group 2017‐2020, ED431C 2017/69), by the Junta de Extremadura R&D Plan, and the European Fund for Regional Development (EFRD) under Grant IB18079S

On-Chip Solar Energy Harvester and PMU With Cold Start-Up and Regulated Output Voltage for Biomedical Applications

This paper presents experimental results from a system that comprises a fully autonomous energy harvester with a solar cell of 1 mm 2 as energy transducer and a Power Management Unit (PMU) on the same silicon substrate, and an output voltage regulator. Both chips are implemented in standard 0.18 μm CMOS technology with total layout areas of 1.575 mm 2 and 0.0126 mm 2 , respectively. The system also contains an off-the-shelf 3.2 mm × 2.5 mm × 0.9 mm supercapacitor working as an off-chip battery or energy reservoir between the PMU and the voltage regulator. Experimental results show that the fast energy recovery of the on-chip solar cell and PMU permits the system to replenish the supercapacitor with enough charge as to sustain Bluetooth Low Energy (BLE) communications even with input light powers of 510 nW. The whole system is able to self-start-up without external mechanisms at 340 nW. This work is the first step towards a self-supplied sensor node with processing and communication capabilities. The small form factor and ultra-low power consumption of the system components is in compliance with biomedical applications requirementsThis work was supported in part by the Spanish Government (Ministerio de Ciencia, Innovación y Universidades) under Project RTI2018-097088-B-C32 and Project RTI2018-095994-B-I00 (MICINN/FEDER), in part by the Xunta de Galicia, in part by the Consellería de Cultura, Educación e Ordenación Universitaria (accreditation 2016-2019, ED431G/08 and reference competitive group 2017-2020, ED431C 2017/69) and European Regional Development Fund (ERDF), and in part by the Junta de Extremadura and the ERDF, under Grant IB 18079S

Ultra-low power CMOS circuit design for energy harvesting applications

Harvesting energy from the environment has become a very suitable option for supplying devices where finite battery life is a major drawback. In miniaturized energy harvesting powered devices, the amount of energy is very limited, making essential the use of circuitry with the lowest possible consumption. The work carried out in this thesis has been focused on designing essential analog electronic blocks maintaining the power consumption as low as possible. To achieve this in CMOS technology, the subthreshold region of the transistor must be exploited. Under this premise, two voltage references and two voltage regulators are presented. Furthermore, an improved DC DC converter operating with subthreshold input voltages while maintaining good power efficiency is proposed too

Biodiversidad en la cuenca del Orinoco. Bases científicas para la identificación de áreas prioritarias para la conservación y uso sostenible de la biodiversidad

Es un placer para el Instituto de Investigación de Recursos Biológicos Alexander von Humboldt presentar a la comunidad científica, conservacionista y autoridades ambientales de Colombia y Venezuela la obra Biodiversidad de la cuenca del Orinoco: bases científicas para la identificación de áreas prioritarias para la conservación y el uso sostenible de la biodiversidad. Este libro es fruto de un esfuerzo de una década de trabajo y recoge numerosos proyectos de carácter institucional que han venido desarrollándose en la Orinoquia, incluyendo el Plan de acción en biodiversidad para la cuenca del Orinoco (2005-2015), además de los resultados de reuniones técnicas de carácter binacional