dc.description.abstract | With the increased proliferation of small embedded systems connected to the
internet and the internet-of-things, the security concerns becomes increasingly
important. Encryption, and the protection of encrypted circuits can be of great
importance. With this thesis the aim was to design an encryption chip that
was able to operate without leaking sensitive information even in the presence
of a malicious adversary, specifically to be able to withstand differential power
analysis attacks.
A masked 128-bit data-path AES encryption and decryption architecture is
proposed, supporting AES-128, 192 and 256 using cipher-block chaining mode
of operation. Synthesized to 65nm technology, the system achieves a keymode-
dependent throughput of 0.99-1.32 Gb/s operating at 400MHz with an average
power consumption of 167.9mW. Our masking approach should withstand second
order DPA-attacks at an area cost of 486% compared to the unmasked equivalent
circuit. | |