IMSE-CNM

Implementing innovative concepts in silicon

Research Areas

Analog Signal Processing
Analog Signal Processing

Digital Signal Processing & VLSI Systems
Digital Signal Processing & VLSI Systems

Brain-Inspired Neural Networks and Artificial Intelligence
Brain-Inspired Neural Networks and Artificial Intelligence

Sensory & Photonic Vision Systems
Sensory & Photonic Vision Systems

Nanoelectronics and Emerging Technologies
Nanoelectronics and Emerging Technologies

Biomedical and Bioinspired Circuits and Systems
Biomedical and Bioinspired Circuits and Systems

Integrated Circuits for Space Applications
Integrated Circuits for Space Applications

Hardware Security
Hardware Security

News

Angel Rodriguez Fama Award
The US professor and IMSE researcher Ángel Rodríguez Vázquez receives the Fama award

On March 19, 2024, the Universidad de Sevilla held the ceremony to present the Fama Awards for research career.
March 22, 2024

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PERTE Chip Chairs Call
The call for PERTE Chip Chairs has been provisionally resolved

The Universidad de Sevilla obtains a PERTE Chip Chair (€4.2M), with the third best score out of 17 proposals, with a project led by IMSE professors and whose team includes 39 researchers from our center.
March 6, 2024

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Eros Camacho Doctoral Thesis
Announcement Public Defense of Doctoral Thesis

The public defense event of the Doctoral Thesis of Eros Camacho Ruiz within the framework of the doctoral program in Physical Sciences and Technologies of the Universidad de Sevilla will be held on March 13, 2024 at 11:00 a.m. at the Instituto de Microelectrónica de Sevilla.

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FAMA Award
The US recognizes five of its researchers with the FAMA Awards

Prof. Ángel Rodríguez Vázquez has been awarded the FAMA Award for Research and Transfer Career in the Area of Engineering and Architecture.
March 5, 2024

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Oscillatory neural networks
Post on the La Cuadratura del Círculo blog

Oscillatory neural networks represent an exciting step forward in our journey toward understanding and emulating the complexity of the human brain, and their impact promises to be profound and lasting.
Juan Núñez Martínez
February 1, 2024

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GoIT Panel IMSE
GoIT Project activity

A panel around open-source hardware to build Root-of-Trust components will be held next Dec 14 at IMSE "Salón de Grados", as part of our activities in the GoIT project.
December 7, 2023

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PREVIOUS EVENTS & NEWS

New Director of the IMSE-CNM

IMSE researcher Teresa Serrano Gotarredona has been appointed as the new Director of the Instituto de Microelectrónica de Sevilla.

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Education at IMSE

- Doctoral Studies
- Master Studies
- Degree Studies
- Final Degree Projects
- Internships

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Recent publications

A CMOS-compatible oscillation-based VO2 Ising machine solver
O. Maher, M. Jiménez, C. Delacour, N. Harnack, J. Núñez, M.J. Avedillo, B. Linares-Barranco, A. Todri-Sanial, G. Indiveri and S. Karg
Journal Paper · Nature Communications vol. 15, article 3334, 2024
NATURE    ISSN: 2041-1723
abstract      doi      

Phase-encoded oscillating neural networks offer compelling advantages over metal-oxide-semiconductor-based technology for tackling complex optimization problems, with promising potential for ultralow power consumption and exceptionally rapid computational performance. In this work, we investigate the ability of these networks to solve optimization problems belonging to the nondeterministic polynomial time complexity class using nanoscale vanadium-dioxide-based oscillators integrated onto a Silicon platform. Specifically, we demonstrate how the dynamic behavior of coupled vanadium dioxide devices can effectively solve combinatorial optimization problems, including Graph Coloring, Max-cut, and Max-3SAT problems. The electrical mappings of these problems are derived from the equivalent Ising Hamiltonian formulation to design circuits with up to nine crossbar vanadium dioxide oscillators. Using sub-harmonic injection locking techniques, we binarize the solution space provided by the oscillators and demonstrate that graphs with high connection density (μ > 0.4) converge more easily towards the optimal solution due to the small spectral radius of the problema’s equivalent adjacency matrix. Our findings indicate that these systems achieve stability within 25 oscillation cycles and exhibit power efficiency and potential for scaling that surpasses available commercial options and other technologies under study. These results pave the way for accelerated parallel computing enabled by large-scale networks of interconnected oscillators.

Cryptographic Security Through a Hardware Root of Trust
L.F. Rojas-Muñoz, S. Sánchez-Solano, M.C. Martínez-Rodríguez, E. Camacho-Ruiz, P. Navarro-Torrero, A. Karmakar, C. Fernández-García, E. Tena-Sánchez, F.E. Potestad-Ordóñez, A. Casado-Galán, P. Ortega-Castro, A.J. Acosta-Jiménez, C.J. Jiménez-Fernández and P. Brox
Conference · Applied Reconfigurable Computing. Architectures, Tools, and Applications (ARC), 2024
abstract      doi      

This work presents a novel approach to a Hardware Root-of-Trust that leverages System-on-Chip technology for the implementation of hardware cryptographic functions. Taking advantage of the processing power of a System-on-Chip, the solution established promotes hardware-based security solutions over software-only solutions. The proposed Root-of-Trust, developed around a Xilinx Zynq-7000 SoC device, integrates components based on cryptographic algorithms and physical phenomena. This innovative Root-of-Trust is tailored to support a spectrum of security tasks within cryptographic systems, including device-specific identifiers and keys, encryption and decryption, hashing, and signature generation and verification. The study adopts a unified design methodology, capitalizing on collaborative efforts to efficiently develop hardware primitives that significantly contribute to enhancing security in computing environments. Aligned with the advantages of reconfigurable hardware, this Hardware Root-of-Trust addresses the critical need for robust hardware-level security and introduces a set of countermeasures to fortify the design against potential threats.

A Small-Area 2nd-Order Adder-Less Continuous-Time ΔΣ Modulator With Pulse Shaping FIR DAC for Magnetic Sensing
M. Srivastava, A. Ferro, A. Sidun, P. Cantillon-Murphy, Daniel O’Hare, K. O’Donoghue and J.M. de la Rosa
Journal Paper · IEEE Open Journal of Circuits and Systems (Volume 5), 2024
IEEE    ISSN: 2644-1225
abstract      doi      

This work presents a small-area 2nd-order continuous-time ΔΣ Modulator (CTΔΣM) with a single low dropout regulator (LDO) serving as both the power supply for the CTΔΣM and reference voltage buffer. The CTΔΣM is used for digitising very low amplitude signals in applications such as magnetic tracking for image-guided and robotic surgery. A cascade of integrators in a feed-forward architecture implemented with an adder-less architecture has been proposed to minimise the silicon area. In addition, a novel continuous-time pulse-shaped digital-to-analog converter (CT-PS DAC) is proposed for excess loop delay (ELD) compensation to simplify the current drive requirements of the reference voltage buffer. This enables a single low-dropout (LDO) voltage regulator to generate both power supply and Vref for the DAC. The circuit has been designed in 65-nm CMOS technology, achieving a peak 82-dB SNDR and 91-dB DR within a signal bandwidth of 20 kHz and the CTΔΣM consumes 300 μW of power when clocked at 10.24 MHz. The CTΔΣM achieves a state-of-the-art area of 0.07 mm.

A Control-Bounded Quadrature Leapfrog ADC
H. Malmberg, F. Feyling and J.M. de la Rosa
Journal Paper · IEEE Transactions on Circuits and Systems I: Regular Papers, 2024
IEEE    ISSN: 1549-8328
abstract      doi      

In this paper, the design flexibility of the control-bounded analog-to-digital converter principle is demonstrated. A band-pass analog-to-digital converter is considered as an application and case study. We show how a low-pass control-bounded analog-to-digital converter can be translated into a band-pass version where the guaranteed stability, converter bandwidth, and signal-to-noise ratio are preserved while the center frequency for conversion can be positioned freely. The proposed converter is validated with behavioral simulations on several filter orders, center frequencies, and oversampling ratios. Additionally, we consider an op-amp circuit realization where the effects of first-order op-amp non-idealities are shown. Finally, robustness against component variations is demonstrated by Monte Carlo simulations.

ALL PUBLICATIONS

IMSE corporate video

What we do

Our main area of specialization is the design of CMOS analog and mixed-signal integrated circuits and their use in different application contexts such as wireless communications, data conversion, smart imagers & vision sensors, biomedical devices, cybersecurity, neuromorphic computing and space technologies.

The IMSE-CNM staff consists of approximately one hundred people, including scientists and support personnel. IMSE-CNM employees are involved in advancing scientific knowledge, designing high level scientific-technical solutions and in technology transfer.

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IMSE-related sites

Master in Microelectronics. Design and Applications of Micro/Nanometrics Systems

Physical Sciences and Technologies Doctoral Programme

Informatics Engineering Doctoral Programme

SIMSIDES: A Time-Domain Behavioral Simulator for Sigma-Delta Modulators in MATLAB/SIMULINK

SHORES: Software & Hardware Open Repository for Embedded Systems

Fuzzy Logic Design Tools

IMSE in the media
IMSE in the media

The World of Chips
The World of Chips

Catalog of Scientific-Technical Services
Catalog of Scientific-Technical Services

Career at IMSE
Career at IMSE