Learn more about Post Quantum IP core
If your device processes valuable data, controls a critical function, or connects to a wider network, it’s a target. Attackers don’t just try to break software; they increasingly physically tamper with hardware; probing, fault injecting, or opening enclosures to bypass protections and extract secrets. The consequences range from IP theft and fraud to orchestrated downtime across fleets of connected devices.
SoC designers are increasingly challenged to integrate robust security measures into their designs. Modern connected devices, such as automotive Electronic Control Units (ECUs), Internet of Things (IoT) nodes, and industrial control systems, face increasing susceptibility to cyberattacks. This escalating threat landscape underscores the critical importance of mandatory security requirements.
Today’s world is already overly complicated to provide robust product security, with extremely motivated hackers creating novel threats exposing new vulnerabilities every day. But considering tomorrow’s world with the looming threat of quantum computing, expanding AI possibilities and rapidly evolving regional regulations and export control risk with severe financial penalties, this is a daunting challenge.
This Agile Analog blog post is focused on describing the dangers of Electromagnetic Fault Injection (EMFI) attacks and outlining the importance of EMFI sensors that are designed to provide protection.
The objective of this article is to present and analyze a concrete IPsec/IKEv2 deployment on an FPGA-based embedded Linux system. Using an Arty Z7 FPGA platform with PetaLinux and StrongSwan, the focus is on system-level integration rather than protocol theory: how the IPsec stack is built and deployed, how classical and post-quantum key exchange are integrated without modifying standardized protocols, and what architectural trade-offs arise when moving cryptographic operations into programmable logic.
