Static Random-Access Memory (SRAM)-based Field Programmable Gate Arrays (FPGAs) are increasingly being used in many application domains due to their higher logic density and reconfiguration capabilities. However, with state-of-the-art FPGAs being manufactured in the latest technology nodes, reliability is becoming an important issue, particularly for safety-critical avionics, automotive, aerospace, industrial robotics, medical, and financial systems. Therefore, fault tolerant system design methodologies have become essential in the aforementioned application domains. The Isolation Design Flow (IDF) is one such design methodology that has promising prospects due to its ability to isolate logic design modules at the physical level for fault containment purposes. This paper proposes a methodology to evaluate the effectiveness of the IDF. To do so, reverse engineering is used to enable fault injection on the IDF designs with minimal changes in the bit-stream. This reduces the time needed to inject a fault significantly thus accelerating the evaluation process. Then this methodology is applied to a case study of a single-chip cryptography application on a ZynQ SoC. Specifically, an Advanced Encryption Standard (AES) Duplication With Comparison (DWC) design is physically isolated with IDF and subsequently subjected to frame-level Fault Injection (FI) in the configuration memory.
Hybrid architectures integrating a processor with an SRAM-based FPGA fabric—for example, Xilinx ZynQ SoC—are increasingly being used as a single-chip solution in several market segments to replace multi-chip designs. These devices not only provide advantages in terms of logic density, cost and integration, but also provide run-time in-field reconfiguration capabilities. However, the current reconfiguration capabilities provided by vendor tools are limited to the module level. Therefore, incremental run-time configuration memory changes require a lengthy compilation time for off-line bitstream generation along with storage and reconfiguration time overheads with traditional vendor methodologies. In this paper, an internal configuration access port (ICAP) controller that provides a versatile fine-grain resource-level incremental reconfiguration of the programmable logic (PL) resources in ZynQ SoC is presented. The proposed controller implemented in PL, called VR-ZyCAP, can reconfigure look-up tables (LUTs) and Flip-Flops (FF). The run-time reconfiguration of FF is achieved through a reset after reconfiguration (RAR)-featured partial bitstream to avoid the unintended state corruption of other memory elements. Along with versatility, our proposed controller improves the reconfiguration time by 30 times for FFs compared to state-of-the-art works while achieving a nearly 400-fold increase in speed for LUTs when compared to vendor-supported software approaches. In addition, it achieves competitive resource utilization when compared to existing approaches.
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