Abstract
In this paper, we present a new reset tree-based scheme to protect cryptographic hardware against optical fault injection attacks. As one of the most powerful invasive attacks on cryptographic hardware, optical fault attacks cause semiconductors to misbehave by injecting high-energy light into a decapped integrated circuit. The contaminated result from the affected chip is then used to reveal secret information, such as a key, from the cryptographic hardware. Since the advent of such attacks, various countermeasures have been proposed. Although most of these countermeasures are strong, there is still the possibility of attack. In this paper, we present a novel optical fault detection scheme that utilizes the buffers on a circuit's reset signal tree as a fault detection sensor. To evaluate our proposal, we model radiation-induced currents into circuit components and perform a SPICE simulation. The proposed scheme is expected to be used as a supplemental security tool.
Highlights
Fault injection is one of the most threatening types of attack, revealing information in a cryptographic integrated circuit (IC) by causing chip malfunction
We present a novel reset tree-based optical fault detection (RTOFD) technique to strengthen cryptographic hardware against such attacks
We propose an optical fault detection scheme that utilizes the buffers on the reset net tree
Summary
Fault injection is one of the most threatening types of attack, revealing information in a cryptographic integrated circuit (IC) by causing chip malfunction. Voltage and clock glitches [1,2,3,4] are used as a fault source on the chip. Strong light beams, such as lasers or flashlights, are used to cause abnormal behavior in the silicon device [5,6,7,8]. Among the attacks listed above, optical fault injection removes the package that protects the IC before firing a light beam, such as laser, ultra violet(UV), or infrared(IR) light, which causes a malfunction
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