PRISEC: Comparison of Symmetric Key Algorithms for IoT Devices

With the growing number of heterogeneous resource-constrained devices connected to the Internet, it becomes increasingly challenging to secure the privacy and protection of data. Strong but efficient cryptography solutions must be employed to deal with this problem, along with methods to standardize secure communications between these devices. The PRISEC module of the UbiPri middleware has this goal. In this work, we present the performance of the AES (Advanced Encryption Standard), RC6 (Rivest Cipher 6), Twofish, SPECK128, LEA, and ChaCha20-Poly1305 algorithms in Internet of Things (IoT) devices, measuring their execution times, throughput, and power consumption, with the main goal of determining which symmetric key ciphers are best to be applied in PRISEC. We verify that ChaCha20-Poly1305 is a very good option for resource constrained devices, along with the lightweight block ciphers SPECK128 and LEA.info:eu-repo/semantics/publishedVersio

A Survey of Lightweight Cryptosystems for Smart Home Devices

A Smart Home uses interconnected network technology to monitor the environment, control the various physical appliances, and communicate with each other in a close environment. A typical smart home is made up of a security system, intercommunication system, lighting system, and ventilation system.  Data security schemes for smart homes are ineffective due to inefficiency cryptosystems, high energy consumption, and low exchange security. Traditional cryptosystems are less-applicable because of their large block size, large key size, and complex rounds. This paper conducts a review of smart homes, and adopts Ultra-Sooner Lightweight Cryptography to secure home door. It provides extensive background of cryptography, forms of cryptography as associated issues and strengths, current trends, smart home door system design, and future works suggestions. Specifically, there are prospects of utilizing XORed lightweight cryptosystem for developing encryption and decryption algorithms in smart home devices. The Substitution Permutation Network, and Feistel Network cryptographic primitives were most advanced forms of cipher operations with security guarantees. Therefore, better security, memory and energy efficiency can be obtained with lightweight ciphers in smart home devices when compared to existing solutions. In the subsequent studies, a blockchain-based lightweight cryptography can be the next springboard in attaining the most advanced security for smart home systems and their appliances.     &nbsp

Implementation of MD5 Framework for Privacy-Preserving Support for Mobile Healthcare

The improvement of science and technology has made life so easy and fast that smartphones and other touch-screen minicomputers have become the most trusted personal storage and communication devices for individuals. Comparable to the rich enhancement in wireless body sensor networks, it is valuable to the development of medical treatment to be exceptionally adaptable and become very flexible by means of smartphones through 2G and 3G system bearers. This has made treatment simple even to the common individual in the general public with less payable cash. In this paper, we introduce privacy-preserving support for mobile healthcare using message digest where we have used an MD5 algorithm instead of AES, which can certainly achieve an efficient way and minimizes the memory consumed and the large amount of PHI data of the medical user (patient) is reduced to a fixed amount of size compared to AES which in parallel increases the speed of the data to be sent to TA without any delay which in-turn. This study implements a secure and privacy-preserving opportunistic computing framework (SPOC) for mobile-health care emergency. Utilizing smartphones and SPOC, assets like computing power and energy can be gathered to reliably to take care of intensive personal health information (PHI) of the medicinal client when he/she is in critical situation with minimal privacy disclosure. With these, the healthcare authorities can treat the patients (restorative clients) remotely, where the patients live at home or at different spots they run. This sort of a treatment can be done under mHealth (Mobile-Healthcare). In malice of the fact that in them-medicinal services administration, there are numerous security and information protection issues to be succeed. The main aim of this paper is to bring medical health to patients in remote locations by providing the basic triage of an emergency to increase the patient’s body acceptance until they can reach a proper medical facility, in addition to providing emergency care in minimal payable cash

Message Encryption in Robot Operating System: Collateral Effects of Hardening Mobile Robots

[EN] In human–robot interaction situations, robot sensors collect huge amounts of data from the environment in order to characterize the situation. Some of the gathered data ought to be treated as private, such as medical data (i.e., medication guidelines), personal, and safety information (i.e., images of children, home habits, alarm codes, etc.). However, most robotic software development frameworks are not designed for securely managing this information. This paper analyzes the scenario of hardening one of the most widely used robotic middlewares, Robot Operating System (ROS). The study investigates a robot’s performance when ciphering the messages interchanged between ROS nodes under the publish/subscribe paradigm. In particular, this research focuses on the nodes that manage cameras and LIDAR sensors, which are two of the most extended sensing solutions in mobile robotics, and analyzes the collateral effects on the robot’s achievement under different computing capabilities and encryption algorithms (3DES, AES, and Blowfish) to robot performance. The findings present empirical evidence that simple encryption algorithms are lightweight enough to provide cyber-security even in lowpowered robots when carefully designed and implemented. Nevertheless, these techniques come with a number of serious drawbacks regarding robot autonomy and performance if they are applied randomly. To avoid these issues, we define a taxonomy that links the type of ROS message, computational units, and the encryption methods. As a result, we present a model to select the optimal options for hardening a mobile robot using ROS.SIInstituto Nacional de Ciberseguridad (Adenda21)Junta de Castilla y León (LE028P17