Currently, cryptographic algorithms are widely applied to communications systems to guarantee data security. For instance, in an emerging automotive environment where connectivity is a core part of autonomous and connected cars, it is essential to guarantee secure communications both inside and outside the vehicle. The AES algorithm has been widely applied to protect communications in onboard networks and outside the vehicle. Hardware implementations use techniques such as iterative, parallel, unrolled, and pipeline architectures. Nevertheless, the use of AES does not guarantee secure communication, because previous works have proved that implementations of secret key cryptosystems, such as AES, in hardware are sensitive to differential fault analysis. Moreover, it has been demonstrated that even a single fault during encryption or decryption could cause a large number of errors in encrypted or decrypted data. Although techniques such as iterative and parallel architectures have been explored for fault detection to protect AES encryption and decryption, it is necessary to explore other techniques such as pipelining. Furthermore, balancing a high throughput, reducing low power consumption, and using fewer hardware resources in the pipeline design are great challenges, and they are more difficult when considering fault detection and correction. In this research, we propose a novel hybrid pipeline hardware architecture focusing on error and fault detection for the AES cryptographic algorithm. The architecture is hybrid because it combines hardware and time redundancy through a pipeline structure, analyzing and balancing the critical path and distributing the processing elements within each stage. The main contribution is to present a pipeline structure for ciphering five times on the same data blocks, implementing a voting module to verify when an error occurs or when output has correct cipher data, optimizing the process, and using a decision tree to reduce the complexity of all combinations required for evaluating. The architecture is analyzed and implemented on several FPGA technologies, and it reports a throughput of 0.479 Gbps and an efficiency of 0.336 Mbps/LUT when a Virtex-7 is used.
In recent years, there is a trend towards the development of reconfigurable circuits where devices using them offer flexibility and performance. Different technologies are explored, such as threshold logic gates (TLGs), which are one of the most promising future technologies, and researchers are examining and improving different characteristics such as density, performance and power dissipation. This research presents a 4-bit arithmetic logic unit (ALU), which was designed using TLGs through reconfigurable logic blocks with a universal circuit configured with three stages based on a floating-gate metal oxide semiconductor transistor with more than one control gate, which was named neu-complementary metal oxide semiconductor (ν-CMOS). The main contribution is that this device is configured as a ν-CMOS inverter and has the ability to program the threshold voltage of its transfer curve by applying an external voltage to the additional control gates. The number of input bits and the magnitude of the weighted input capacitances related to control gates of the ν-CMOS inverters is obtained and analyzed by using the graphical method (floating-gate potential diagram). Finally, the proposed 4-bit ALU shows similar results as those measured from the ALUs implemented in the field programmable gate array evaluation kit and the Motorola chip MC14581B.
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