Lock-in Thermography for the Localization of Security Hard Blocks on SoC Devices

Michael Kögel; Sebastian Brand; Christian Große; Frank Altmann; Bodo Selmke; Kilian Zinnecker; Robert Hesselbarth; Nisha Jacob Kabakci

doi:10.1007/s11668-024-02005-6

Lock-in Thermography for the Localization of Security Hard Blocks on SoC Devices

Michael Kögel, Sebastian Brand, Christian Große, Frank Altmann, Bodo Selmke, Kilian Zinnecker, Robert Hesselbarth, Nisha Jacob Kabakci

Research output: Contribution to journal › Article › peer-review

Abstract

Localizing security-relevant hard blocks on modern System-on-Chips for physical attacks, such as side-channel analysis and fault attacks, has become increasingly time-consuming due to ever-increasing chip-area and -complexity. While this development increases the effort and reverse engineering cost, it is not sufficient to withstand resolute attackers. This paper explores the application of camera-based lock-in thermography, a nondestructive testing method, for identifying and localizing security hard blocks on integrated circuits. We use a synchronous signal to periodically activate security-related functions in the firmware, which causes periodic temperature changes in the activated die areas that we detect and localize via an infrared camera. Using this method, we demonstrate the precise detection and localization of security-related hard blocks at the die level on a modern SoC.

Original language	English
Pages (from-to)	2154-2162
Number of pages	9
Journal	Journal of Failure Analysis and Prevention
Volume	24
Issue number	5
DOIs	https://doi.org/10.1007/s11668-024-02005-6
State	Published - Oct 2024
Externally published	Yes

Keywords

Lock-in thermography
Nondestructive testing (NDT)
Reverse engineering
Thermal analysis

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10.1007/s11668-024-02005-6

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title = "Lock-in Thermography for the Localization of Security Hard Blocks on SoC Devices",

abstract = "Localizing security-relevant hard blocks on modern System-on-Chips for physical attacks, such as side-channel analysis and fault attacks, has become increasingly time-consuming due to ever-increasing chip-area and -complexity. While this development increases the effort and reverse engineering cost, it is not sufficient to withstand resolute attackers. This paper explores the application of camera-based lock-in thermography, a nondestructive testing method, for identifying and localizing security hard blocks on integrated circuits. We use a synchronous signal to periodically activate security-related functions in the firmware, which causes periodic temperature changes in the activated die areas that we detect and localize via an infrared camera. Using this method, we demonstrate the precise detection and localization of security-related hard blocks at the die level on a modern SoC.",

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AU - Kögel, Michael

AU - Brand, Sebastian

AU - Große, Christian

AU - Altmann, Frank

AU - Selmke, Bodo

AU - Zinnecker, Kilian

AU - Hesselbarth, Robert

AU - Jacob Kabakci, Nisha

N1 - Publisher Copyright: © The Author(s) 2024.

PY - 2024/10

Y1 - 2024/10

N2 - Localizing security-relevant hard blocks on modern System-on-Chips for physical attacks, such as side-channel analysis and fault attacks, has become increasingly time-consuming due to ever-increasing chip-area and -complexity. While this development increases the effort and reverse engineering cost, it is not sufficient to withstand resolute attackers. This paper explores the application of camera-based lock-in thermography, a nondestructive testing method, for identifying and localizing security hard blocks on integrated circuits. We use a synchronous signal to periodically activate security-related functions in the firmware, which causes periodic temperature changes in the activated die areas that we detect and localize via an infrared camera. Using this method, we demonstrate the precise detection and localization of security-related hard blocks at the die level on a modern SoC.

AB - Localizing security-relevant hard blocks on modern System-on-Chips for physical attacks, such as side-channel analysis and fault attacks, has become increasingly time-consuming due to ever-increasing chip-area and -complexity. While this development increases the effort and reverse engineering cost, it is not sufficient to withstand resolute attackers. This paper explores the application of camera-based lock-in thermography, a nondestructive testing method, for identifying and localizing security hard blocks on integrated circuits. We use a synchronous signal to periodically activate security-related functions in the firmware, which causes periodic temperature changes in the activated die areas that we detect and localize via an infrared camera. Using this method, we demonstrate the precise detection and localization of security-related hard blocks at the die level on a modern SoC.

KW - Lock-in thermography

KW - Nondestructive testing (NDT)

KW - Reverse engineering

KW - Thermal analysis

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IS - 5

ER -

Lock-in Thermography for the Localization of Security Hard Blocks on SoC Devices

Abstract

Keywords

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