VLSI Core Architecture For GF(P) Elliptic Curve Crypto Processor

A novel GF(p) crypto processor core architecture is presented in this paper. The core is used to implement GF(p) Elliptic Curve Cryptosystem (ECC). The architecture is such that a single core can be used to implement ECC or alternatively a two core solution can be adopted. As a result, the core architecture allows the exploitation of the parallelism that exists in elliptic curve point addition and doubling. The core architecture results in several advantages over conventional implementations with regard to speed and power consumption

VLSI Core Architecture For GF(P) Elliptic Curve Crypto Processor

A novel GF(p) crypto processor core architecture is presented in this paper. The core is used to implement GF(p) Elliptic Curve Cryptosystem (ECC). The architecture is such that a single core can be used to implement ECC or alternatively a two core solution can be adopted. As a result, the core architecture allows the exploitation of the parallelism that exists in elliptic curve point addition and doubling. The core architecture results in several advantages over conventional implementations with regard to speed and power consumption

Crypto-test-lab for security validation of ECC co-processor test infrastructure

© 20xx IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting /republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other worksElliptic Curve Cryptography (ECC) is a technology for public-key cryptography that is becoming increasingly popular because it provides greater speed and implementation compactness than other public-key technologies. Calculations, however, may not be executed by software, since it would be so time consuming, thus an ECC co-processor is commonly included to accelerate the speed. Test infrastructure in crypto co-processors is often avoided because it poses serious security holes against adversaries. However, ECC co-processors include complex modules for which only functional test methodologies are unsuitable, because they would take an unacceptably long time during the production test. Therefore, some internal test infrastructure is always included to permit the application of structural test techniques. Designing a secure test infrastructure is quite a complex task that relies on the designer's experience and on trial & error iterations over a series of different types of attacks. Most of the severe attacks cannot be simulated because of the demanding computational effort and the lack of proper attack models. Therefore, prototypes are prepared using FPGAs. In this paper, a Crypto-Test-Lab is presented that includes an ECC co-processor with flexible test infrastructure. Its purpose is to facilitate the design and validation of secure strategies for testing in this type of co-processor.Postprint (author's final draft

Energy Efficient Hardware Design for Securing the Internet-of-Things

The Internet of Things (IoT) is a rapidly growing field that holds potential to transform our everyday lives by placing tiny devices and sensors everywhere. The ubiquity and scale of IoT devices require them to be extremely energy efficient. Given the physical exposure to malicious agents, security is a critical challenge within the constrained resources. This dissertation presents energy-efficient hardware designs for IoT security. First, this dissertation presents a lightweight Advanced Encryption Standard (AES) accelerator design. By analyzing the algorithm, a novel method to manipulate two internal steps to eliminate storage registers and replace flip-flops with latches to save area is discovered. The proposed AES accelerator achieves state-of-art area and energy efficiency. Second, the inflexibility and high Non-Recurring Engineering (NRE) costs of Application-Specific-Integrated-Circuits (ASICs) motivate a more flexible solution. This dissertation presents a reconfigurable cryptographic processor, called Recryptor, which achieves performance and energy improvements for a wide range of security algorithms across public key/secret key cryptography and hash functions. The proposed design employs circuit techniques in-memory and near-memory computing and is more resilient to power analysis attack. In addition, a simulator for in-memory computation is proposed. It is of high cost to design and evaluate new-architecture like in-memory computing in Register-transfer level (RTL). A C-based simulator is designed to enable fast design space exploration and large workload simulations. Elliptic curve arithmetic and Galois counter mode are evaluated in this work. Lastly, an error resilient register circuit, called iRazor, is designed to tolerate unpredictable variations in manufacturing process operating temperature and voltage of VLSI systems. When integrated into an ARM processor, this adaptive approach outperforms competing industrial techniques such as frequency binning and canary circuits in performance and energy.PHDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttps://deepblue.lib.umich.edu/bitstream/2027.42/147546/1/zhyiqun_1.pd

A survey of hardware implementations of elliptic curve cryptographic systems

Elliptic Curve Cryptography (ECC) has gained much recognition over the last decades and has established itself among the well known public-key cryptography schemes, not least due its smaller key size and relatively lower computational effort compared to RSA. The wide employment of Elliptic Curve Cryptography in many different application areas has been leading to a variety of implementation types and domains ranging from pure software approaches over hardware implemenations to hardware/software co-designs. The following review provides an overview of state of the art hardware implemenations of ECC, specifically in regard to their targeted design goals. In this context the suitability of the hardware/software approach in regard to the security challenges opposed by the low-end embedded devices of the Internet of Things is briefly examined. The paper also outlines ECC’s vulnerability against quantum attacks and references one possible solution to that problem

A Flexible Crypto-system Based upon the REDEFINE Polymorphic ASIC Architecture

The highest levels of security can be achieved through the use of more than one type of cryptographic algorithm for each security function. In this paper, the REDEFINE polymorphic architecture is presented as an architecture framework that can optimally support a varied set of crypto algorithms without losing high performance. The presented solution is capable of accelerating the advanced encryption standard (AES) and elliptic curve cryptography (ECC) cryptographic protocols, while still supporting different flavors of these algorithms as well as different underlying finite field sizes. The compelling feature of this cryptosystem is the ability to provide acceleration support for new field sizes as well as new (possibly proprietary) cryptographic algorithms decided upon after the cryptosystem is deployed.Defence Science Journal, 2012, 62(1), pp.25-31, DOI:http://dx.doi.org/10.14429/dsj.62.143