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Your search keyword '"DE GORTARI BRISENO, JULIAN"' showing total 4 results
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4 results on '"DE GORTARI BRISENO, JULIAN"'

1. TinyNS: Platform-Aware Neurosymbolic Auto Tiny Machine Learning.

Author

Saha, Swapnil, Sandha, Sandeep, Aggarwal, Mohit, Wang, Brian, Han, Liying, DE Gortari Briseno, Julian, and Srivastava, Mani

Subjects
AutoML, Bayesian, TinyML, neural architecture search, neurosymbolic, platform-aware
Abstract

Machine learning at the extreme edge has enabled a plethora of intelligent, time-critical, and remote applications. However, deploying interpretable artificial intelligence systems that can perform high-level symbolic reasoning and satisfy the underlying system rules and physics within the tight platform resource constraints is challenging. In this paper, we introduce TinyNS, the first platform-aware neurosymbolic architecture search framework for joint optimization of symbolic and neural operators. TinyNS provides recipes and parsers to automatically write microcontroller code for five types of neurosymbolic models, combining the context awareness and integrity of symbolic techniques with the robustness and performance of machine learning models. TinyNS uses a fast, gradient-free, black-box Bayesian optimizer over discontinuous, conditional, numeric, and categorical search spaces to find the best synergy of symbolic code and neural networks within the hardware resource budget. To guarantee deployability, TinyNS talks to the target hardware during the optimization process. We showcase the utility of TinyNS by deploying microcontroller-class neurosymbolic models through several case studies. In all use cases, TinyNS outperforms purely neural or purely symbolic approaches while guaranteeing execution on real hardware.

Published
2024

3. Using Inkjet Printers for Acoustic Data Exfiltration from Air-Gapped Networks

Author

de Gortari Briseno, Julian

Subjects
Computer engineering, Electrical engineering, acoustic, color perception, covert channel, inkjet printer, linux, security
Abstract

The ubiquity of printers in modern office spaces provides our motivation to design a covert channel based on the emanations of one particular class of these devices which uses inkjet technology. In this thesis, we demonstrate how a covert channel can be established by leveraging the acoustic emissions of inkjet printers to exfiltrate information from an air-gapped network. In essence, malware installed on a computer with access to a printer, but no access to the Internet, can inject certain imperceptible patterns into all documents being sent to the printer, so as to control the printing process in such a way that an acoustic signal is generated which can be captured with a nearby smartphone. Throughout this work, we demonstrate how people are unable to perceive these patterns under normal light conditions. Moreover, two distinct modulation schemes are proposed for our communication system and tests are carried out considering different types of document layouts, in distinct circumstances.

Published
2020

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