Comparative study of several operation modes of AES algorithm for encryption ECG biomedical signal

Hameed, Mustafa Emad; Ibrahim, Marc; Manap, Nurulfajar Abd; Attiah, Mothana L.

doi:10.11591/ijece.v9i6.pp4850-4859

Cited by 15 publications

(12 citation statements)

References 20 publications

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“…The encryption and decryption algorithms were developed using a pipelined approach, and the AES-128 cipher algorithm was implemented on the Xilinx ZCU102 FPGA board and is used for 5G communications [33]. The encryption and decryption algorithms are widely developed and implemented on FPGA boards, which are frequently used in communication and parallel computing areas [34]- [36].…”

Section: Serial Communication Using Uartmentioning

confidence: 99%

Implementation of the advanced encryption standard algorithm on an FPGA for image processing through the universal asynchronous receiver-transmitter protocol

Prasanna

Siddaiah

et al. 2022

IJECE

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<span lang="EN-US">Communication among end users can be based either on wired or wireless technology. Cryptography plays a vital role in ensuring data exchange is secure among end users. Data can be encrypted and decrypted using symmetric or asymmetric key cryptographic techniques to provide confidentiality. In wireless technology, images are exchanged through low-cost wireless peripheral devices, such as radio frequency identification device (RFID), nRF, and ZigBee, that can interface with field programmable gate array (FPGA) among the end users. One of the issues is that data exchange through wireless devices does not offer confidentiality, and subsequently, data can be lost. In this paper, we propose a design and implementation of AES-128 cipher algorithm on an FPGA board for image processing through the <a name="_Hlk107307233"></a>universal asynchronous receiver transmitter (UART) protocol. In this process, the advanced encryption standard (AES) algorithm is used to encrypt and decrypt the image, while the transmitter and receiver designs are implemented on two Xilinx BASYS-3 circuits connected with a ZigBee RF module. The encrypted image uses less memory, such as LUTs (141), and also consumes less chip power (0.0291 w), I/O (0.003), block RAM (0.001 w), data, and logic to provide much higher efficiency than wired communication technology. We also observe that images can be exchanged through the UART protocol with different baud rates in run time.</span>

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Section: Serial Communication Using Uartmentioning

confidence: 99%

Implementation of the advanced encryption standard algorithm on an FPGA for image processing through the universal asynchronous receiver-transmitter protocol

Prasanna

Siddaiah

et al. 2022

IJECE

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“…The advantages of this paper were better error correction, maximum storage efficiency, and increased data retrieval capacity. Hameed et al [17] recommended an AES-based encryption algorithm for ensuring the properties of authentication, confidentiality, and integrity of the ECG signal transmission system. Here, the encryption and decryption processes were carried out based on the Electronic Code Book (ECB).…”

Section: Literature Surveymentioning

confidence: 99%

VIHS with ROTR Technique for Enhanced Light-Weighted Cryptographic System

N¹,

B²

2022

IJACSA

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Developing a bypass parallel processing block is one of the emerging and exciting research areas in the system encrypt/decrypt application areas. A Partial Pseudo-Randombased Hashing VIHS is the most suitable methodology for designing the system to encrypt/solve a block in cryptography. For this purpose, various VIHS and register techniques have been developed to process the storage system data. But, it is limited by the problems of reduced efficiency, increased computational complexity, high area consumption, and cost consumption. Thus, this research intends to develop a novel dynamic system register with hashing with optimal Hash Signature design to process the system's encryption /decrypt data. The main intention of this paper is to analyze the transfer characteristics of the current based on the pseudo-differential pair for a proficient system detection. Then, a system window can be created and adjusted to obtain an optimized power flow with less data loss sensitivity. The major stages involved in the proposed block design are register, partition design, and VIHS design. The dynamic system register is designed at first for getting a fast decision and to enable a low input-referred offset value. Then, the partition is formed concerning the output of the register, and the VIHS is used to produce the high proportional logical work. During performance evaluation, various measures have been utilized to analyze the performance of the proposed dynamic system registerbased hashing with optimal Hash Signature design. In addition to that, the estimated results are compared with the proposed technique to prove its efficiency.

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“…Lastly, heart rate was calculated and arrhythmia detected. PHE technique is one of the block ciphers with lightweight properties for enhancing confidentiality, integrity and authentication in ECG signal transmission in comparison to Gentry (Li, et al, 2013) AES (Hameed, et al, 2019) algorithm and ECG steganography (Sivaranjani, 2017).…”

Section: Related Workmentioning

confidence: 99%

Secured Electrocardiograph (ECG) Signal Using Partially Homomorphic Encryption Technique–RSA Algorithm

Shaikh¹,

Adnan²,

Ahmad³

2020

JST

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ECG signal differs from individual to individual, making it hard to be emulated and copied. In recent times ECG is being used for identifying the person. Hence, there is a requirement for a system that involves digital signal processing and signal security so that the saved data are secured at one place and an authentic person can see and use the ECG signal for further diagnosis. The study presents a set of security solutions that can be deployed in a connected healthcare territory, which includes the partially homomorphic encryption (PHE) techniques used to secure the electrocardiogram (ECG) signals. This is to record confidentially and prevent the information from meddling, imitating and replicating. First, Pan and Tompkins’s algorithm was applied to perform the ECG signal processing. Then, partially homomorphic encryption (PHE) technique - Rivest-Shamir-Adleman (RSA) algorithm was used to encrypt the ECG signal by using the public key. The PHE constitutes a gathering of semantically secure encryption works that permits certain arithmetical tasks on the plaintext to be performed straightforwardly on the ciphertext. The study shows a faster and 90% accurate result before and after encryption that indicates the lightweight and accuracy of the RSA algorithm. Secure ECG signal provides innovation in multiple healthcare sectors such as medical research, patient care and hospital database.

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Comparative study of several operation modes of AES algorithm for encryption ECG biomedical signal

Cited by 15 publications

References 20 publications

Implementation of the advanced encryption standard algorithm on an FPGA for image processing through the universal asynchronous receiver-transmitter protocol

Implementation of the advanced encryption standard algorithm on an FPGA for image processing through the universal asynchronous receiver-transmitter protocol

VIHS with ROTR Technique for Enhanced Light-Weighted Cryptographic System

Secured Electrocardiograph (ECG) Signal Using Partially Homomorphic Encryption Technique–RSA Algorithm

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