Your search keyword '"MULTICORE processors"' showing total 2,412 results

1. Thermodynamic quantum Fokker–Planck equations and their application to thermostatic Stirling engine.

Author

Koyanagi, Shoki and Tanimura, Yoshitaka

Subjects

GRAPHICS processing units, STIRLING engines, MULTICORE processors, THERMODYNAMIC potentials, NONEQUILIBRIUM thermodynamics

Abstract

We developed a computer code for the thermodynamic quantum Fokker–Planck equations (T-QFPE), derived from a thermodynamic system–bath model. This model consists of an anharmonic subsystem coupled to multiple Ohmic baths at different temperatures, which are connected to or disconnected from the subsystem as a function of time. The code numerically integrates the T-QFPE and their classical expression to simulate isothermal, isentropic, thermostatic, and entropic processes in both quantum and classical cases. The accuracy of the results was verified by comparing the analytical solutions of the Brownian oscillator. In addition, we illustrated a breakdown of the Markovian Lindblad-master equation in the pure quantum regime. As a demonstration, we simulated a thermostatic Stirling engine employed to develop non-equilibrium thermodynamics [S. Koyanagi and Y. Tanimura, J. Chem. Phys. 161, 114113 (2024)] under quasi-static conditions. The quasi-static thermodynamic potentials, described as intensive and extensive variables, were depicted as work diagrams. In the classical case, the work done by the external field is independent of the system–bath coupling strength. In contrast, in the quantum case, the work decreases as the coupling strength increases due to quantum entanglement between the subsystem and bath. The codes were developed for multicore processors using Open Multi-Processing (OpenMP) and for graphics processing units using the Compute Unified Device Architecture. These codes are provided in the supplementary material. [ABSTRACT FROM AUTHOR]

Published

2024

2. HTPA: a hybrid traffic pattern aware arbitration strategy for network on chip systems.

Author

Matin, Mostafa, Mehranzadeh, Amin, Chekin, Mohsen, and Mosleh, Mohammad

Subjects

MULTICORE processors, TRAFFIC patterns, NETWORKS on a chip, ROUTING algorithms, COMMUNICATION infrastructure

Abstract

The Network-on-Chip (NoC) is a communication infrastructure designed to integrate various components of a System-on-Chip (SoC) and connect multi-core processors. In on-chip networks, routing is a process that determines how a data packet should move from the source node to the destination node. Essentially, a routing algorithm configures the internal connections of a switch to establish communication towards the destination node by examining the source, destination and the current node addresses. After routing, multiple input channels may simultaneously request access to an output channel based on the routing results. In such cases, an arbitration strategy needs to prioritize access to the output channel for the requesting input channels. This research presents an arbitration strategy called HTPA (Hybrid Traffic Pattern-Aware arbitration) that utilizes local and global information. HTPA also uses a hybrid arbitration scheme consisting of a simple arbitration and a complex switch arbitration. Additionally, it uses age-related techniques to increase the fairness of arbitration and prevent starvation. The proposed method considers certain priorities for accessing output channels based on the distance to the destination, the number of available paths from the current node to the destination, and the traffic intensity parameter. Evaluations were conducted under uniform, transient, hot spot, and MPEG4 traffic patterns and the proposed method demonstrated a reduction in average packet delay compared to RoundRobin, CAIS, and DTIS methods by 79.46%, 71.35%, and 19.91%, respectively, across various traffic patterns. [ABSTRACT FROM AUTHOR]

Published

2024

3. High-performance application mapping in network-on-chip-based multicore systems.

Author

Reza, Md Farhadur

Subjects

SIMULATED annealing, GENETIC algorithms, LINEAR programming, BUDGET, MULTICORE processors, RESOURCE allocation

Abstract

The allocation of resources and scheduling of tasks, specifically mapping, in multicore systems on-chip (MCSoC), poses significant challenges. Tasks have diverse resource requirements and interact with each other, while network-on-chip (NoC)-based MCSoC consists of heterogeneous cores and communication networks. The heterogeneity of resources in MCSoC, along with the varying computational and communication demands of applications, makes mapping a complex optimization problem. We have mathematically modeled the mapping problem in NoC-based MCSoC using mixed-integer linear programming (MILP) with the objective of minimizing the execution time of applications. This model incorporates computation and communication capacity, energy budget constraints of MCSoC, and execution time requirements of applications. We further propose heuristics, including simulated annealing (SA) and genetic algorithm (GA), considering the capacity and budget constraints of MCSoC systems to accelerate applications and provide quick mapping solutions. Simulation results demonstrate that the performance from SA and GA heuristics is very close (within 10%) to the optimal solutions from MILP across various applications for 2D-Mesh NoCs with 16–100 cores. The energy consumption of SA and GA heuristics is also very close to the optimal solutions from MILP, with a few exceptions on small-scale 16-core NoC. Additionally, SA outperforms GA in most cases for all applications. [ABSTRACT FROM AUTHOR]

Published

2024

4. 多核处理器共享 Cache 的划分算法.

Author

吕海玉, 罗广, 朱嘉炜, and 张凤登

Subjects

MULTICORE processors, PARALLEL algorithms, COMPUTER storage devices, CYCLING instruction, MATHEMATICAL models

Abstract

Copyright of Electronic Science & Technology is the property of Electronic Science & Technology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

5. Threads, Asynchrony, Parallelism, and Concurrency in C#.

Author

Kanjilal, Joydip

Subjects

MICROSOFT .NET Framework, CENTRAL processing units, MULTICORE processors, PRIME numbers, DOWNLOADING, PARALLEL programming

Abstract

The article from CODE Magazine discusses the concepts of threads, asynchrony, parallelism, and concurrency in C#. It covers topics such as resources in an operating system, CPU-bound and I/O-bound operations, processes, threads, tasks, multitasking, multiprocessing, multithreading, and parallel programming. The article also delves into best practices for asynchronous methods, parallel programming, and synchronization primitives for ensuring thread safety. Overall, it provides a comprehensive overview of key concepts related to multithreading and parallel processing in C#. [Extracted from the article]

Published

2024

6. Research and optimization of task scheduling algorithm based on heterogeneous multi-core processor.

Author

Liu, Junnan, Liu, Yifan, and Ding, Yongkang

Subjects

HIGH performance processors, HIGH performance computing, OPTIMIZATION algorithms, MULTICORE processors, HETEROGENEOUS distributed computing

Abstract

Heterogeneous multi-core processor has the ability to switch between different types of cores to perform tasks, which provides more space and possibility for realizing efficient operation of computer system and improving computer computing power. Current research focuses on heterogeneous multiprocessor systems with high performance or low power consumption to reduce system energy consumption. However, some studies have shown that excessive voltage reduction may lead to an increase in transient failure rates, reducing system reliability. This paper studies the energy optimal scheduling problem of HMSS with DVFS under the constraints of minimum time and reliability, and proposes an improved wild horse optimization algorithm (OIWHO), which improves the efficiency of heterogeneous task scheduling and shortens the task completion time. The algorithm uses the learning and chaos perturbation strategies based on opposition and crossover strategies to balance the search and utilization capabilities, and can further improve the performance of OIWHO. Compared with previous work, our proposed algorithm has more advantages than existing algorithms. Experimental results show that the average computing time of OIWHO algorithm is 12.58%, 11.42%, 7.53%, 4.20% and 3.21% faster than DRNN-BWO, PSO, GWO-GA, GACSH and OIWOAH, respectively. Especially when solving large-scale problems, our algorithm takes less time than other algorithms. [ABSTRACT FROM AUTHOR]

Published

2024

7. Parallel continuous skyline query over high-dimensional data stream windows.

Author

Khames, Walid, Hadjali, Allel, and Lagha, Mohand

Subjects

MULTICORE processors, MULTIDIMENSIONAL databases, EMERGENCY management, PARALLEL processing, DATA transmission systems, PARALLEL algorithms

Abstract

Real-time multi-criteria decision-making applications in fields like high-speed algorithmic trading, emergency response, and disaster management have driven the development of new types of preference queries. This is an example of a skyline search. Multi-criteria decision-making utilizes the skyline operator to extract highly significant tuples or useful data points from extensive sets of multi-dimensional databases. The user's settings determine the results, which include all tuples whose attribute vector remains undefeated by another tuple. The extracted tuples are commonly known as the skyline set. Lately, there has been a growing trend in research studies to perform skyline queries on data stream applications. These queries consist of extracting desired records from sliding windows and removing outdated records from incoming data sets that do not meet user requirements. The datasets in these applications are extremely large and exhibit a wide range of dimensions that vary over time. Consequently, the skyline query is considered a computationally demanding task, with the challenge of achieving a real-time response within an acceptable duration. We must transport and process enormous quantities of data. Traditional skyline algorithms have faced new challenges due to limitations in data transmission bandwidth and latency. The transfer of vast quantities of data would affect performance, power efficiency, and reliability. Consequently, it is imperative to make alterations to the computer paradigm. Parallel skyline queries have attracted the attention of both scholars and the business sector. The study of skyline queries has focused on sequential algorithms and parallel implementations for multicore processors, primarily due to their widespread use. While previous research has focused on sequential algorithms, there is a limitation to comprehensive studies that specifically address modern parallel processors. While numerous articles have been published regarding the parallelization of regular skyline queries, there is a limited amount of research dedicated specifically to the parallel processing of continuous skyline queries. This study introduces PRSS, a continuous skyline technique for multicore processors specifically designed for sliding window-based data streams. The efficacy of the proposed parallel implementation is demonstrated through tests conducted on both real-world and synthetic datasets, encompassing various point distributions, arrival rates, and window widths. The experimental results for a dataset characterized by a large number of dimensions and cardinality demonstrate significant acceleration. [ABSTRACT FROM AUTHOR]

Published

2024

8. Accelerated dimensionality reduction of single-cell RNA sequencing data with fastglmpca.

Author

Weine, Eric, Carbonetto, Peter, and Stephens, Matthew

Subjects

MULTICORE processors, RNA sequencing, PRINCIPAL components analysis, POISSON regression, SOURCE code

Abstract

Summary Motivated by theoretical and practical issues that arise when applying Principal component analysis (PCA) to count data, Townes et al. introduced "Poisson GLM-PCA", a variation of PCA adapted to count data, as a tool for dimensionality reduction of single-cell RNA sequencing (scRNA-seq) data. However, fitting GLM-PCA is computationally challenging. Here we study this problem, and show that a simple algorithm, which we call "Alternating Poisson Regression" (APR), produces better quality fits, and in less time, than existing algorithms. APR is also memory-efficient and lends itself to parallel implementation on multi-core processors, both of which are helpful for handling large scRNA-seq datasets. We illustrate the benefits of this approach in three publicly available scRNA-seq datasets. The new algorithms are implemented in an R package, fastglmpca. Availability and implementation The fastglmpca R package is released on CRAN for Windows, macOS and Linux, and the source code is available at github.com/stephenslab/fastglmpca under the open source GPL-3 license. Scripts to reproduce the results in this paper are also available in the GitHub repository and on Zenodo. [ABSTRACT FROM AUTHOR]

Published

2024

9. High-Level Programming of FPGA-Accelerated Systems with Parallel Patterns.

Author

Birath, Björn, Ernstsson, August, Tinnerholm, John, and Kessler, Christoph

Subjects

PARALLEL programming, MULTICORE processors, SOURCE code, PRICES, SKELETON

Abstract

As a result of frequency and power limitations, multi-core processors and accelerators are becoming more and more prevalent in today's systems. To fully utilize such systems, heterogeneous parallel programming is needed, but this introduces new complexities to the development. High-level frameworks such as SkePU have been introduced to help alleviate these complexities. SkePU is a skeleton programming framework based on a set of programming constructs implementing computational parallel patterns, while presenting a sequential interface to the programmer. Using the various skeleton backends, SkePU programs can execute, without source code modification, on multiple types of hardware such as CPUs, GPUs, and clusters. This paper presents the design and implementation of a new backend for SkePU, adding support for FPGAs. We also evaluate the effect of FPGA-specific optimizations in the new backend and compare it with the existing GPU backend, where the actual devices used are of similar vintage and price point. For simple examples, we find that the FPGA-backend's performance is similar to that of the existing backend for GPUs, while it falls behind in more complex tasks. Finally, some shortcomings in the backend are highlighted and discussed, along with potential solutions. [ABSTRACT FROM AUTHOR]

Published

2024

10. Energy efficiency and performance analysis of a legacy atomic scale materials modeling simulator (VASP).

Author

Nieves-Pírez, Isidoro, Muñoz, Alfonso, Almeida, Francisco, and Blanco, Vicente

Subjects

ENERGY consumption, MODELS & modelmaking, MOLECULAR size, MULTICORE processors, MOLECULAR structure, MATRICES (Mathematics)

Abstract

This work tackles the performance and energy consumption analysis of a legacy scientific application, the VASP (Vienna Ab-initio Simulation Package), an application commonly used by physicists and chemists for modeling materials at the atomic scale. Many of these scientific applications have been implemented in Fortran, where energy metrics instrumentation is not straightforward. We obtained performance figures (execution time and energy consumption) by instrumenting the source code using EML. This energy measurement library has been modified to introduce Fortran interfaces for these metrics. The analysis was carried out using different matrix algebra libraries, parallelization techniques, and hardware platforms, emphasizing on the MPI, OpenMP, and CUDA parallel implementations of the algorithms used in VASP. We employ various material specifications (atomic structures) and molecular sizes of a silicon-based crystal to create a set of benchmarks for these specifications, leading to some recommendations for final users regarding performance improvements. The proposed benchmarking technique assists the user in selecting the right combination of problem size, compilers, and parallelization options available in VASP. For a given system platform, the user will be able to determine not only the architecture to use (GPU or multicore processors), but also the appropriate library and parallelization according to the atomic structure and molecular size. [ABSTRACT FROM AUTHOR]

Published

2024

11. PARamrfinder: detecting allele-specific DNA methylation on multicore clusters.

Author

Fernández-Fraga, Alejandro, González-Domínguez, Jorge, and Martín, María J.

Subjects

DNA methylation, SINGLE nucleotide polymorphisms, GENOMIC imprinting, DYNAMIC balance (Mechanics), MULTICORE processors, SOURCE code, PARALLEL programming

Abstract

The discovery of Allele-Specific Methylation (ASM) is an important research field in biology as it regulates genomic imprinting, which has been identified as the cause of some genetic diseases. Nevertheless, the high computational cost of the bioinformatic tools developed for this purpose prevents their application to large-scale datasets. Hence, much faster tools are required to further progress in this research field. In this work we present PARamrfinder, a parallel tool that applies a statistical model to identify ASM in data from high-throughput short-read bisulfite sequencing. It is based on the state-of-the-art sequential tool amrfinder, which is able to detect ASM at regional level from Bisulfite Sequencing (BS-Seq) experiments in the absence of Single Nucleotide Polymorphism information. PARamrfinder provides the same Allelically Methylated Regions as amrfinder but at significantly reduced runtime thanks to exploiting the compute capabilities of common multicore CPU clusters and MPI RMA operations to attain an efficient dynamic workload balance. As an example, our tool is up to 567 times faster for real data experiments on a cluster with 8 nodes, each one containing two 16-core processors. The source code of PARamrfinder, as well as a reference manual, is available at https://github.com/UDC-GAC/PARamrfinder. [ABSTRACT FROM AUTHOR]

Published

2024

12. TREAFET: Temperature-Aware Real-Time Task Scheduling for FinFET based Multicores.

Author

Chakraborty, Shounak, Sharma, Yanshul, and Moulik, Sanjay

Subjects

TEMPERATURE inversions, COMPUTING platforms, THERMAL properties, TEMPERATURE effect, MULTICORE processors, SCHEDULING

Abstract

The recent shift in the VLSI industry from conventional MOSFET to FinFET for designing contemporary chip-multiprocessor (CMP) has noticeably improved hardware platforms' computing capabilities, but at the cost of several thermal issues. Unlike the conventional MOSFET, FinFET devices experience a significant increase in circuit speed at a higher temperature, called temperature effect inversion (TEI), but higher temperature can also curtail the circuit lifetime due to self-heating effects (SHEs). These fundamental thermal properties of FinFET introduced a new challenge for scheduling time-critical tasks on FinFET-based multicores that how to exploit TEI towards improving performance while combating SHEs. In this work, TREAFET, a temperature-aware real-time scheduler, attempts to exploit the TEI feature of FinFET-based multicores in a time-critical computing paradigm. At first, the overall progress of individual tasks is monitored, tasks are allocated to the cores, and finally, a schedule is prepared. By considering the thermal profiles of the individual tasks and the current thermal status of the cores, hot tasks are assigned to the cold cores and vice-versa. Finally, the performance and temperature are balanced on-the-fly by incorporating a prudential voltage scaling towards exploiting TEI while guaranteeing the deadline and thermal safety. Moreover, TREAFET stimulates the average runtime frequency by employing an opportunistic energy-adaptive voltage spiking mechanism, in which energy saving during memory stalls at the cores is traded off during the time slice having the spiked voltage. Simulation results claim TREAFET maintains a safe and stable thermal status (peak temperature below 80 °C) and improves frequency up to 17% over the assigned value, which ensures legitimate time-critical performance for a variety of workloads while surpassing a state-of-the-art technique. The stimulated frequency in TREAFET also finishes the tasks early, thus providing opportunities to save energy by power gating the cores, and achieves a 24% energy delay product (EDP) gain on average. [ABSTRACT FROM AUTHOR]

Published

2024

13. Logical Execution Time and Time-Division Multiple Access in Multicore Embedded Systems: A Case Study.

Author

Mosqueda-Arvizu, Carlos-Antonio, Romero-González, Julio-Alejandro, Córdova-Esparza, Diana-Margarita, Terven, Juan, Chaparro-Sánchez, Ricardo, and Rodríguez-Reséndiz, Juvenal

Subjects

MULTICORE processors, TELECOMMUNICATION systems, FIXED interest rates, AUTONOMOUS vehicles, SAFETY standards

Abstract

The automotive industry has recently adopted multicore processors and microcontrollers to meet the requirements of new features, such as autonomous driving, and comply with the latest safety standards. However, inter-core communication poses a challenge in ensuring real-time requirements such as time determinism and low latencies. Concurrent access to shared buffers makes predicting the flow of data difficult, leading to decreased algorithm performance. This study explores the integration of Logical Execution Time (LET) and Time-Division Multiple Access (TDMA) models in multicore embedded systems to address the challenges in inter-core communication by synchronizing read/write operations across different cores, significantly reducing latency variability and improving system predictability and consistency. Experimental results demonstrate that this integrated approach eliminates data loss and maintains fixed operation rates, achieving a consistent latency of 11 ms. The LET-TDMA method reduces latency variability to approximately 1 ms, maintaining a maximum delay of 1.002 ms and a minimum delay of 1.001 ms, compared to the variability in the LET-only method, which ranged from 3.2846 ms to 8.9257 ms for different configurations. [ABSTRACT FROM AUTHOR]

Published

2024

14. Parallel GEMM-based convolution for deep learning on multicore RISC-V processors.

Author

Ramírez, Cristian, Castelló, Adrián, Martínez, Héctor, and Quintana-Ortí, Enrique S.

Subjects

DEEP learning, MATHEMATICAL convolutions, CACHE memory, MULTICORE processors, COMPUTER workstation clusters

Abstract

We address the efficient implementation of the convolution operator on the GAP8 parallel ultra-low power platform (PULP), a heterogeneous multi-core processor equipped with a fabric controller (FC); a cluster of eight compute cores; and a four-level memory hierarchy with scratchpads instead of conventional, hardware-assisted cache memories. Our solution for this platform transforms the convolution into a general matrix–matrix multiplication (gemm) via the lowering approach, demonstrating that it is possible to attain reasonable performance on the GAP8 by carefully adapting techniques such as tiling and loop parallelism, which are mainstream in the multi-threaded, cache-aware realization of gemm. [ABSTRACT FROM AUTHOR]

Published

2024

15. Parallel programming in mobile devices with FancyJCL.

Author

Afonso, Sergio, Gómez-Cárdenes, Óscar, Expósito, Paula, Blanco, Vicente, and Almeida, Francisco

Subjects

MULTICORE processors, IMAGE processing, MARKET penetration, PARALLEL programming, PARALLEL algorithms, MOBILE computing, SMARTPHONES

Abstract

Mobile devices and handheld systems, such as the smartphones and tablets universally extended, are becoming increasingly powerful. Their basic hardware configuration is usually state-of-the-art heterogeneous architectures consisting of multi-core processors and some kind of accelerator such as GPUs or DSPs. Specific code adapted to the architecture is mandatory if high-performance computation is required and low-level libraries and parallelism are needed, which constitutes an important barrier for the usual developer in such devices. In this context, we propose the FancyJCL framework. It provides a high-level abstraction layer that hides implementation details and allows to develop parallel programs for mobile devices. The target platform for FancyJCL is mainly Android and Java developers due to their high market penetration. A very simple, seemingly sequential encoding results in parallel efficient OpenCL code. FancyJCL is itself based on the Fancier framework, which enables optimal memory management across memory spaces on unified memory systems. Benchmarks of FancyJCL code developed for a wide range of image processing algorithms show good performance with low development effort. [ABSTRACT FROM AUTHOR]

Published

2024

16. A Method to Order Point Clouds for Visualization on the Ray Tracing Pipeline.

Author

Timokhin, P. Y. and Mikhaylyuk, M. V.

Subjects

RAY tracing, POINT cloud, VIRTUAL reality, SOFTWARE as a service, MULTICORE processors, POINT set theory

Abstract

Currently, the digitization of environment objects (vegetation, terrain, architectural structures, etc.) in the form of point clouds is actively being developed. The integration of such digitized objects into virtual environment systems allows the quality of the modeled environment to be improved, but requires efficient methods and algorithms for real-time visualization of large point volumes. In this paper the solution of this task on modern multicore GPUs with support of hardware-accelerated ray tracing is researched. A modified method is proposed where the original unordered point cloud is split up into point groups whose visualization is effectively parallelized on ray tracing cores. The paper describes an algorithm for constructing such groups using swapping arrays of point indices, which works faster than alternative solutions based on linked lists, and also has lower memory overhead. The proposed method and algorithm were implemented in point cloud visualization software complex and approbated on a number of digitized environment objects. The results of the approbation confirmed the efficiency of proposed solutions as well as their applicability for virtual environment systems, video simulators, geoinformation systems, virtual laboratories, etc. [ABSTRACT FROM AUTHOR]

Published

2024

17. OptSmart: a space efficient Optimistic concurrent execution of Smart contracts.

Author

Anjana, Parwat Singh, Kumari, Sweta, Peri, Sathya, Rathor, Sachin, and Somani, Archit

Subjects

BLOCKCHAINS, MULTICORE processors, CONTRACTS, MINERS

Abstract

Popular blockchains such as Ethereum and several others execute complex transactions in the block through user-defined scripts known as smart contracts. Serial execution of smart contract transactions/atomic units (AUs) fails to harness the multiprocessing power offered by the prevalence of multi-core processors. By adding concurrency to the execution of AUs, we can achieve better efficiency and higher throughput. In this paper, we develop a concurrent miner that proposes a block by executing AUs concurrently using optimistic Software Transactional Memory systems (STMs). It efficiently captures independent AUs in the concurrent bin and dependent AUs in the block graph (BG). Later, we propose a concurrent validator that re-executes the same AUs concurrently and deterministically using the concurrent bin followed by the BG given by the miner to verify the block. We rigorously prove the correctness of concurrent execution of AUs. The performance benchmark shows that the average speedup for the optimized concurrent miner is 5.21 × , while the maximum is 14.96 × over the serial miner. The optimized validator obtains an average speedup of 8.61 × to a maximum of 14.65 × over the serial validator. The proposed miner outperforms 1.02 × to 1.18 × , while the proposed validator outperforms 1 × to 4.46 × over state-of-the-art concurrent miners and validators, respectively. Moreover, the proposed efficient BG saves an average of 2.29 × more block space when compared with the state-of-the-art. [ABSTRACT FROM AUTHOR]

Published

2024

18. Parallel Multi-core Implementation of the Optimized Speck Cipher.

Author

Fanfakh, Ahmed, Abduljalil, Nihad, and Al-Qurabat, Ali Kadhum M.

Subjects

CIPHERS, MULTICORE processors, BLOCK ciphers, CRYPTOGRAPHY, NATIONAL security

Abstract

Lightweight cryptographic algorithms like Speck, which are a family of block ciphers developed by the US National Security Agency (NSA), have become popular because of their efficient performance and small operational size. This paper introduces the execution on a parallel multi-core processor of the optimized version of the Speck cipher. However, this proposition fulfils the increased demand for developing quick and ultra-lightweight ciphers. In this work, this is addressed by optimizing the speck128/128 cipher by reducing its number of rounds to five. The optimization is accomplished by adding the dynamic substitution layer to increase the randomness of the cipher, which allows us to reduce the speck rounds. We conducted tests such as statistical, randomness, and cryptanalysis tests for linear and differential attacks on the optimized speck. The security results show that the optimized speck overcomes the original speck security level. The conducted experiments show that the new version of the speck runs faster than the original one in terms of execution time and throughput. The parallel execution over a multicore processor is applied, and its speedup ratio is equal to 2.64 when it's compared to the parallel execution of the original speck. Different message sizes and thread configurations are used in this work. The sequential execution of both speck ciphers is computed in terms of execution time and throughput, and the acceleration ratio of the optimized speck in this case is equal to 2.63. [ABSTRACT FROM AUTHOR]

Published

2024

19. Multicore underground power line health monitoring using optical fiber bragg grating.

Author

WAHAB, M. Hazwan, RAHMAN, Mohammad Syuhaimi A. B., IBRAHIM, Ahmad Asrul, AHMAD ABAS, A. H., and AHMAD, Norhidayah

Subjects

FIBER Bragg gratings, OPTICAL fibers, ELECTROMAGNETIC interference, PASSIVE optical networks, ELECTRIC lines, MULTICORE processors, HEALTH care networks

Abstract

Copyright of Przegląd Elektrotechniczny is the property of Przeglad Elektrotechniczny and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

20. Solving the heat transfer equations for permafrost models using multicore and graphics processors.

Author

Akimova, Elena N. and Misilov, Vladimir E.

Subjects

MULTICORE processors, HEAT equation, HEAT transfer, PARALLEL algorithms, PERMAFROST, ALGEBRAIC equations, GRAPHICS processing units

Abstract

The paper presents the efficient parallel algorithms for solving the heat equations for the permafrost models. By using the finite difference scheme, we transform the Stefan problem into the problem of solving multiple systems of linear algebraic equations. These systems have tridiagonal coefficient matrices and are solved by the sweep method. On the base of the parallel algorithms, we developed the codes for multicore CPU with OpenMP technology and for GPU with CUDA technology. The novel approach was proposed to achieve the efficient memory access patterns. Numerical experiments show that our new code is up to 2x faster than the previous one, and the GPU implementation achieves a tenfold speedup compared to the serial CPU code. [ABSTRACT FROM AUTHOR]

Published

2024

21. Kubernetes for the Deep Underground Neutrino Experiment Data Acquisition.

Author

Lasorak, Pierre, Alves, Tiago, Crone, Gordon, Gamberini, Enrico, Hancock, Jonathan, King, Bonnie, Riehecky, Patrick, Tapper, Alexander, and Thea, Alessandro

Subjects

NEUTRINOS, DATA acquisition systems, DETECTORS, SUPERNOVAE, MULTICORE processors

Abstract

The Deep Underground Neutrino Experiment (DUNE) is a next-generation long-baseline neutrino experiment based in the USA which is expected to start taking data in 2029. DUNE aims to precisely measure neutrino oscillation parameters by detecting neutrinos from the LBNF beamline (Fermilab) at the Far Detector, 1,300 kilometres away, in South Dakota at the Sanford Underground Research Facility. The Far Detector will consist of four cryogenic Liquid Argon Time Projection Chamber detectors of 17 kT, each producing more than 1 TB/sec of data. The main requirements for the data acquisition system are the ability to run continuously for extended periods of time, with a 99% up-time requirement, and the functionality to record both beam neutrinos and low energy neutrinos from the explosion of a neighbouring supernova, should one occur during the lifetime of the experiment. The key challenges are the high data rates that the detectors generate and the deep underground environment, which places constraints on power and space. To overcome these challenges, DUNE plans to use a highly optimised C++ software suite and a server farm of about 110 nodes continuously running about two hundred multicore processes located close to the detector, 1.5 kilometres underground. Thirty nodes will be at the surface and will run around two hundred processes simultaneously. DUNE is studying the use of the Kubernetes framework to manage containerised workloads and take advantage of its resource definitions and high up-time services to run the DAQ system. Progress in deploying these systems at the CERN neutrino platform on the prototype DUNE experiments is reported. [ABSTRACT FROM AUTHOR]

Published

2024

22. High performance packet classification algorithm for network security systems using modified grid-of-tries.

Author

Muthumanikandan, V., Sannasi, Ganapathy, Perumal, T. Sudarson Rama, and Sushmitha, J.

Subjects

CLASSIFICATION algorithms, COMPUTER network security, SECURITY systems, INTRUSION detection systems (Computer security), MULTICORE processors, TRAFFIC engineering

Abstract

In order to enhance the functionality of network applications including traffic engineering and intrusion detection, the packet classification problem has received extensive research during the past decade. Software-based packet classification algorithms are gaining significant attention due to their extremely high flexibility in satisfying various industrial requirements for security and network systems, which has coincided with the general improvement of hardware architectures and the rising popularity of multi-core multi-threaded processors over the past few years. These methods require extremely big tables internally to achieve fast classification, and the size of the tables could possibly grow along with the size of the rule set. They cannot be utilised with a big rule set as a result. To solve this issue, we present a novel software-based packet classification algorithm dubbed the grid-of-tries approach that combines the partition decision trees in a search table to support both high scalability and quick classification performance. Our proposed algorithm exhibits a very high categorization speed, regardless of the quantity of rules, with smaller tables and shorter table building time, while the majority of generic partitioning-based packet classification algorithms demonstrate acceptable scalability at the expense of reduced classification speed. In this study, we suggest the Grid-of-tries approach, a novel packet classification algorithm to bridge the theoretical and practical gap. In terms of classification speed, memory utilisation, and preprocessing time, our technique outperforms other well-known algorithms. The results of our tests demonstrate how the proposed method facilitates network systems to handle significant traffic in the most efficient way. [ABSTRACT FROM AUTHOR]

Published

2024

23. Parallel Algorithm on Multicore Processor and Graphics Processing Unit for the Optimization of Electric Vehicle Recharge Scheduling.

Author

Roberge, Vincent, Brooks, Katerina, and Tarbouchi, Mohammed

Subjects

PARTICLE swarm optimization, GRAPHICS processing units, PARALLEL algorithms, MULTICORE processors, ELECTRIC units, ELECTRIC vehicles, SMART parking systems, ELECTRIC vehicle charging stations

Abstract

Electric vehicles (EVs) are becoming more and more popular as they provide significant environmental benefits compared to fossil-fuel vehicles. However, they represent substantial loads on the power grid, and the scheduling of EV charging can be a challenge, especially in large parking lots. This paper presents a metaheuristic-based approach parallelized on multicore processors (CPU) and graphics processing units (GPU) to optimize the scheduling of EV charging in a single smart parking lot. The proposed method uses a particle swarm optimization algorithm that takes as input the arrival time, the departure time, and the power demand of the vehicles and produces an optimized charging schedule for all vehicles in the parking lot, which minimizes the overall charging cost while respecting the chargers' capacity and the parking lot feeder capacity. The algorithm exploits task-level parallelism for the multicore CPU implementation and data-level parallelism for the GPU implementation. The proposed algorithm is tested in simulation on parking lots containing 20 to 500 EVs. The parallel implementation on CPUs provides a speedup of 7.1x, while the implementation on a GPU provides a speedup of up to 247.6x. The parallel implementation on a GPU is able to optimize the charging schedule for a 20-EV parking lot in 0.87 s and a 500-EV lot in just under 30 s. These runtimes allow for real-time computation when a vehicle arrives at the parking lot or when the electricity cost profile changes. [ABSTRACT FROM AUTHOR]

Published

2024

24. Automatic performance tuning using the ATMathCoreLib tool: Two experimental studies related to dense symmetric eigensolvers.

Author

Kobayashi, Masato, Hirota, Yusuke, Kudo, Shuhei, Hoshi, Takeo, and Yamamoto, Yusaku

Subjects

MULTICORE processors, SYMMETRIC matrices, EIGENVALUES

Abstract

Summary: We consider automatic performance tuning of dense symmetric eigenvalue problems using ATMathCoreLib, which is a library to assist automatic tuning. We deal with two problems, namely, automatic code selection for the symmetric generalized eigenvalue problem in distributed‐memory parallel environments and automatic parameter tuning in tridiagonalization of dense symmetric matrices on multicore processors. As for the first problem, numerical experiments show that ATMathCoreLib can choose the fastest solver for a given computing environment and problem size quickly even if the fluctuation in the execution time is as high as 40%. As for the second problem, ATMathCoreLib was able to select nearly optimal combinations of the algorithm and its parameter reliably and efficiently for various computing environments and matrix sizes. The performance of auto‐tuning was further enhanced by incorporating a user‐provided execution‐time model into ATMathCoreLib. [ABSTRACT FROM AUTHOR]

Published

2024

25. CAMP: a hierarchical cache architecture for multi-core mixed criticality processors.

Author

Nair, Arun S., Patil, Geeta, Agarwal, Archit, Pai, Aboli V., Raveendran, Biju K., and Punnekkat, Sasikumar

Subjects

MULTICORE processors, CACHE memory, TIME management, CACTUS

Abstract

CAMP proposes a hierarchical cache subsystem for multi-core mixed criticality processors, focusing on ensuring worst-case execution time (WCET) predictability in automotive applications. It incorporates criticality-aware locked L1 and L2 caches, reconfigurable at mode change intervals, along with criticality-aware last level cache partitioning. Evaluation using CACOSIM, Moola Multicore simulator, and CACTI simulation tools confirms the suitability of CAMP for keeping high-criticality jobs within timing budgets. A practical case study involving an automotive wake-up controller using the sniper v7.2 architecture simulator further validates its usability in real-world mixed criticality applications. CAMP presents a promising cache architecture for optimized multi-core mixed criticality systems. [ABSTRACT FROM AUTHOR]

Published

2024

26. Architectural and Technological Approaches for Efficient Energy Management in Multicore Processors.

Author

Buduleci, Claudiu, Gellert, Arpad, Florea, Adrian, and Brad, Remus

Subjects

ENERGY management, ENERGY consumption, MULTICORE processors, MICROPROCESSORS

Abstract

Benchmarks play an essential role in the performance evaluation of novel research concepts. Their effectiveness diminishes if they fail to exploit the available hardware of the evaluated microprocessor or, more broadly, if they are not consistent in comparing various systems. An empirical analysis of the consecrated Splash-2 benchmarks suite vs. the latest version Splash-4 was performed. It was shown that on a 64-core configuration, half of the simulated benchmarks reach temperatures well beyond the critical threshold of 105 °C, emphasizing the necessity of a multi-objective evaluation from at least the following perspectives: energy consumption, performance, chip temperature, and integration area. During the analysis, it was observed that the cores spend a large amount of time in the idle state, around 45% on average in some configurations. This can be exploited by implementing a predictive dynamic voltage and frequency scaling (DVFS) technique called the Simple Core State Predictor (SCSP) to enhance the Intel Nehalem architecture and to simulate it using Sniper. The aim was to decrease the overall energy consumption by reducing power consumption at core level while maintaining the same performance. More than that, the SCSP technique, which operates with core-level abstract information, was applied in parallel with a Value Predictor (VP) or a Dynamic Instruction Reuse (DIR) technique, which rely on instruction-level information. Using the SCSP alone, a 9.95% reduction in power consumption and an energy reduction of 10.54% were achieved, maintaining the performance. By combining the SCSP with the VP technique, a performance increase of 8.87% was obtained while reducing power and energy consumption by 3.13% and 8.48%, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

27. A scheduling algorithm based on critical factors for heterogeneous multicore processors.

Author

Li, Chen, Lin, Ziniu, Tian, Lihua, and Zhang, Bin

Subjects

MULTICORE processors, ALGORITHMS, SCHEDULING, ENERGY consumption, HEATING, PREDICTION models

Abstract

Summary: As the development of chip manufacturing technology slows down, high‐performance processors often have high energy consumption and high heat generation. Therefore, heterogeneous multi‐core processors become more and more popular, and the heterogeneous multi‐core processors is adopted to execute programs. At present, the general program consists of multiple threads. To reach goals of accelerating program execution and reducing energy consumption and heat generation of system, a suitable thread scheduling algorithm for heterogeneous multi‐core processors is needed. In this article, a thread scheduling algorithm based on multiple critical scheduling factors is proposed. First, a prediction model of thread performance and energy consumption is used to predict the core sensitivity of threads. Then, critical threads are judged and accelerated by collecting the synchronization information between threads. Finally, the load balancing method based on the computing power of cores and the core sensitivity of threads is employed to perform system load balancing, which ensures the fairness of the scheduling. Several experiments are provided, and the results show that the proposed algorithm can obtain better performance of thread schedule. [ABSTRACT FROM AUTHOR]

Published

2024

28. Implementation and evaluation of two parallel computational models for the simulation of a long‐haul DWDM system limited by FWM.

Author

Sánchez‐Lara, Rafael, López‐Martínez, José L., Trejo‐Sánchez, Joel A., Offerhaus, Herman L., and Álvarez‐Chávez, José A.

Subjects

WAVELENGTH division multiplexing, SCIENTIFIC community, FOUR-wave mixing, OPTICAL amplifiers, MULTICORE processors, GRAPHICS processing units

Abstract

Four‐Wave Mixing (FWM) is one of the non‐linear phenomena affecting long‐reach communication systems and high bandwidth. Research communities use simulation tools for parameter optimization. Unfortunately, such a simulation is time‐consuming and requires more time as the number of channels increases. This paper proposes two fast implementations of Dense Wavelength Division Multiplexing (DWDM) system, limited by FWM and the intrinsic Amplified Spontaneous Emission (ASE) noise of optical amplifiers employed in each segment. Additionally, this work compares the efficiency and speed improvement of the proposed parallelization model versus an earlier sequential model. We present the computational complexity analysis of sequential and parallel models. The paper considers two different parallel implementations: a multicore processor using Open MultiProcessing (OpenMP) and Compute Unified Device Architecture (CUDA), which is based on the use of a Graphics Processing Unit (GPU). Results show that parallelism using CUDA improves by up to 70 times the simulation performance compared to the sequential model. Parallelism with CUDA is up to 15 times compared to OpenMP using 12 logical processors. It is possible to simulate an increased number of channels within our parallel execution, which was impractical in the sequential simulation. [ABSTRACT FROM AUTHOR]

Published

2024

29. Performance Analysis of Multicore Processor Using FOFO-Based Approximate Compatible ALU.

Author

Senthilmurugan, S. and Gunaseelan, K.

Subjects

CENTRAL processing units, MICROPROCESSORS, MULTICORE processors, APPROXIMATION error, ELECTRONIC equipment

Abstract

Modern electronic devices are supported by multicore processors and they have become an unavoidable part of recent technologies. The Arithmetic Logic Unit (ALU) is one of the indispensable parts of the Central Processing Unit (CPU) which performs most of the operations. Operations like multiplications, and exponentials consume more power than other normal operations. Power management is one of the major challenges in designing processors. To maximize speed and reduce power consumption, a new technique in Multiplier and ALU incorporated with a multicore processor has been proposed. The Proposed Approximate Compatible ALU (ACALU) is designed to perform specified operations that consume more power, using an advanced multiplication technique called the First One First Operand (FOFO) method. The selection process of eight bits is done by the FOFO method followed by error detection and error approximation is performed to get the accurate output. The ACALU performs these operations in the Approximate Computing Mode which utilizes only eight bits for the operations, thus reducing the power consumption. The results of several analyses between multipliers, ALUs, and microprocessors are provided. As we optimize the multiplier and ALU unit, the multicore processor is also enhanced. The proposed multicore processor is compared with the AMD processor and the latest INTEL processor and the comparison results show that the proposed technique is 95.2% and 97.8% more efficient than the existing processors. Thus, the power consumption is minimized and the performance speed is increased in the proposed multicore processor. [ABSTRACT FROM AUTHOR]

Published

2024

30. Analyzing Operation Efficiency of a City Transportation System by the U-Statistics Methods. II. Optimization of the Interactive Evaluation Methods.

Author

Polishchuk, O. D. and Yadzhak, M. S.

Subjects

URBAN transportation, U-statistics, EVALUATION methodology, MOTOR vehicle driving, MOTOR vehicles, MULTICORE processors

Abstract

The authors formalize the technique of interactive evaluation of the operation efficiency of the motor vehicle system of a large city based on U-statistics methods. To optimize this technique, the authors propose efficient algorithmic constructions for parallel execution of local, aggregated, and prognostic evaluation of the system's components using modern computers, namely, multi-core computers, clusters, hybrid architectures, and high-performance computing environments. The obtained scientific results allow for real-time evaluation of the operation efficiency of the city motor vehicle system. [ABSTRACT FROM AUTHOR]

Published

2024

31. Experiences with nested parallelism in task-parallel applications using malleable BLAS on multicore processors.

Author

Rodríguez-Sánchez, Rafael, Castelló, Adrián, Catalán, Sandra, Igual, Francisco D., and Quintana-Ortí, Enrique S.

Subjects

MULTICORE processors, LINEAR algebra

Abstract

Malleability is defined as the ability to vary the degree of parallelism at runtime, and is regarded as a means to improve core occupation on state-of-the-art multicore processors tshat contain tens of computational cores per socket. This property is especially interesting for applications consisting of irregular workloads and/or divergent executions paths. The integration of malleability in high-performance instances of the Basic Linear Algebra Subprograms (BLAS) is currently nonexistent, and, in consequence, applications relying on these computational kernels cannot benefit from this capability. In response to this scenario, in this paper we demonstrate that significant performance benefits can be gathered via the exploitation of malleability in a framework designed to implement portable and high-performance BLAS-like operations. For this purpose, we integrate malleability within the BLIS library, and provide an experimental evaluation of the result on three different practical use cases. [ABSTRACT FROM AUTHOR]

Published

2024

32. Bayesian Phylogenetic Analysis on Multi-Core Compute Architectures: Implementation and Evaluation of BEAGLE in RevBayes With MPI.

Author

Smith, Killian, Ayres, Daniel, Neumaier, René, Wörheide, Gert, and Höhna, Sebastian

Subjects

BAYESIAN analysis, MESSAGE passing (Computer science), TREE size, SEQUENCE alignment, BAYESIAN field theory, GRAPHICS processing units, MULTICORE processors

Abstract

Phylogenies are central to many research areas in biology and commonly estimated using likelihood-based methods. Unfortunately, any likelihood-based method, including Bayesian inference, can be restrictively slow for large datasets—with many taxa and/or many sites in the sequence alignment—or complex substitutions models. The primary limiting factor when using large datasets and/or complex models in probabilistic phylogenetic analyses is the likelihood calculation, which dominates the total computation time. To address this bottleneck, we incorporated the high-performance phylogenetic library BEAGLE into RevBayes , which enables multi-threading on multi-core CPUs and GPUs, as well as hardware specific vectorized instructions for faster likelihood calculations. Our new implementation of RevBayes+BEAGLE retains the flexibility and dynamic nature that users expect from vanilla RevBayes. In addition, we implemented native parallelization within RevBayes without an external library using the message passing interface (MPI); RevBayes+MPI. We evaluated our new implementation of RevBayes+BEAGLE using multi-threading on CPUs and 2 different powerful GPUs (NVidia Titan V and NVIDIA A100) against our native implementation of RevBayes+MPI. We found good improvements in speedup when multiple cores were used, with up to 20-fold speedup when using multiple CPU cores and over 90-fold speedup when using multiple GPU cores. The improvement depended on the data type used, DNA or amino acids, and the size of the alignment, but less on the size of the tree. We additionally investigated the cost of rescaling partial likelihoods to avoid numerical underflow and showed that unnecessarily frequent and inefficient rescaling can increase runtimes up to 4-fold. Finally, we presented and compared a new approach to store partial likelihoods on branches instead of nodes that can speed up computations up to 1.7 times but comes at twice the memory requirements. [ABSTRACT FROM AUTHOR]

Published

2024

33. An Algorithm for Solving the Problem of Phase Unwrapping in Remote Sensing Radars and Its Implementation on Multicore Processors.

Author

Martyshko, Petr S., Akimova, Elena N., Sosnovsky, Andrey V., and Kobernichenko, Victor G.

Subjects

REMOTE sensing by radar, REMOTE sensing, PROBLEM solving, MULTICORE processors, PARALLEL algorithms, SURFACE of the earth, ALGORITHMS

Abstract

The problem of the interferometric phase unwrapping in radar remote sensing of Earth systems is considered. Such interferograms are widely used in the problems of creating and updating maps of the relief of the Earth's surface in geodesy, cartography, environmental monitoring, geological, hydrological and glaciological studies, and for monitoring transport communications. Modern radar systems have ultra-high spatial resolution and a wide band, which leads to the need to unwrap large interferograms from several tens of millions of elements. The implementation of calculations by these methods requires a processing time of several days. In this paper, an effective method for equalizing the inverse vortex field for phase unwrapping is proposed, which allows solving a problem with quasi-linear computational complexity depending on the interferogram size and the number of singular points on it. To implement the method, a parallel algorithm for solving the problem on a multi-core processor using OpenMP technology was developed. Numerical experiments on radar data models were carried out to investigate the effectiveness of the algorithm depending on the size of the source data, the density of singular points and the number of processor cores. [ABSTRACT FROM AUTHOR]

Published

2024

34. Accelerating prediction of RNA secondary structure using parallelization on multicore architecture.

Author

Borkar, Pradnya, Shinde, Snehal, Raghuwanshi, Mukesh, and Raut, Roshani

Subjects

NUCLEOTIDE sequence, RNA, MESSENGER RNA, COVID-19 pandemic, DYNAMIC programming, MULTICORE processors

Abstract

Due to Covid pandemic, the investigation of bioinformatics, and more specifically the investigation of RNA, has become a major focus of the research. mRNA-based vaccines have been developed by a significant number of academician and scientists. When a virus infects a human body, it first causes disruption to the host's RNA structure, then it transforms the host's RNA into its own genetic structure. As a result, it is vital to research on the process of making predictions about the secondary structures of RNA. The process of predicting the secondary structure of long RNA sequences takes a significant amount of time. This study makes a contribution to the implementation of the algorithm that finds the predicted secondary structure. The methodology for RNA secondary prediction that was employed in this study is based on a dynamic programming model that uses shared memory multicore architecture. The Nearest Neighbor Thermodynamic Model (NNTM) is used as the foundation for the determination of the least amount of free energy. The Gutell database has been used for the RNA sequences of a number of different bacterial species. A comparison was made between the amount of time required to identify the secondary structure of RNA. The length of the RNA sequence is a factor that affects the performance of many existing methods, but the proposed GAfold technique handles sequences of any length. Once the secondary structure has been identified, it helped to detect the virus. It is discovered that the GAfold approach speeds up RNA Secondary structure's prediction. The proposed GAfold algorithm offers a speed increase factor of 2.5 ns on a four-core architecture, 3.09 ns on an eight-core design, and 5.5 ns on a twelve-core architecture. It has been shown that predicting suboptimal structures enhanced the accuracy of the free energy minimization algorithm, which in turn improved the accuracy of full RNA. [ABSTRACT FROM AUTHOR]

Published

2024

35. A Linearizability-based Hierarchy for Concurrent Specifications: Two linearizability-style correctness conditions that can be used to argue safety properties of progressively more concurrent behaviors of objects.

Author

CASTAÑEDA, ARMANDO, RAJSBAUM, SERGIO, and RAYNAL, MICHEL

Subjects

MULTICORE processors, COMPUTER architecture, SEQUENTIAL machine theory

Abstract

This article discusses the difficulties encountered with multicore processors which are used to increase the clock speed of microprocessors but can act in asynchronous and unpredictable ways. One approach to address this is linearizability which is the de facto correctness condition to reason about safety properties in concurrent programming but only deals with sequential specifications.

Published

2023

36. Intensification of research work using images processing by application of parallel filtering on multi-core architectures.

Author

Bosakova-Ardenska, Atanaska and Andreeva, Hristina

Subjects

PARALLEL processing, TIME complexity, MESSAGE passing (Computer science), IMAGE denoising, COMPUTATIONAL complexity, PARALLEL algorithms, MULTICORE processors

Abstract

As an essential operation filtering is a well-known technique for images smoothing and denoising on the level of primary images processing. Due to its computational complexity there are many approaches for decreasing its time complexity and the most often used one is the parallel processing. This paper presents a potential to improve effectiveness of images filtering by usage of computer system with multi-core architecture and message passing interface (MPI) library for communication among parallel processes. Two parallel algorithms for linear filtering are implemented and tested with two sets of experimental images. First algorithm is based on classic mean filter, but second algorithm uses partial sums in order to accelerate performance. It is observed that increasing number of parallel processes, decrease measured processing time when the number of parallel processes is not bigger than number of computational cores. Time performance of filtering process depends on size of used mask (kernel) also and increasing of mask size leads to significant increase of processing time. This effect is weaker presented when the algorithm for filtering uses partial sums. The experimental results based on processing on three different computer systems indicates that the best speed-up is achieved when the number of parallel processes is equal to number of computational cores and its value is about 4. [ABSTRACT FROM AUTHOR]

Published

2024

37. MacBook Air 15-inch (2024).

Author

LYNCH, GERALD

Subjects

MACBOOK (Computer), WIRELESS Internet, DIGITAL music, STREAMING video & television, MULTICORE processors, HUMAN fingerprints

Abstract

The article discusses the new MacBook Air 15-inch (2024) model, which features the Apple M3 chip and various upgrades. The design of the laptop remains unchanged from the previous model, but it offers improved performance and features facilitated by the new chip. The laptop is available in different configurations, with options for RAM and storage upgrades. It also comes in four color options. The article provides details about the laptop's design, display, keyboard, audio quality, ports, wireless connectivity, and battery life. It highlights the performance improvements of the M3 chip, particularly in terms of CPU and GPU power. The article concludes that the MacBook Air 15-inch (2024) is a solid upgrade and a powerful laptop option. [Extracted from the article]

Published

2024

38. NEW PRODUCTS.

Subjects

NEW product development, CHICKEN as food, WELL-being, MULTICORE processors, FLUID foods

Abstract

The article provides information about new pet food products that have been launched. Some of the products mentioned include Stella & Chewy's Dental Delights, Dogsters Pumpkin-Flavored Ice Cream, WagWell Freeze-Dried Treats, RAWZ Limited Rabbit Recipe for Cats, Veterinary Formula Smart Vitality Premium Supplements, and more. The article also mentions products for manufacturers such as the Gericke RotaSafe Retrofit Kit and the Bühler Chronos OMP-2090 B bagging station. [Extracted from the article]

Published

2024

39. Reconfigurable fork shaped plasmonic graphene based nano-patch antenna for wireless network-on-chip application in THz band.

Author

Sirisha Mrunalini, L. N. and Arun, M.

Subjects

ANTENNAS (Electronics), PLASMONICS, GRAPHENE, MULTICORE processors, TRANSMITTERS (Communication), COMPLEMENTARY metal oxide semiconductors, CHEMICAL potential

Abstract

Wireless Network-on-Chip (WNoC) incorporating on-chipantennas has emerged as a promising alternative to overcome the communication bottleneck due to high frequency operation, propagation delay, crosstalk delay, noise and need for repeaters inwired interconnects in chip-multiprocessors (CMPs). Recent advancements in nano materials, such as graphene have enabled the development of novel plasmonic graphene devices, which intrinsically operate in THz band. This ultra-low power andcompact graphene-based nano-antennas (GNA) establishes ultra-high bandwidth THz-on-chip wireless links for intra/inter-chip communication. In this article, we design and simulate a novel fork-shaped planarplasmonic nano-patch antenna using grapheneon SiO2/Si substrate that can be integrated into transceivers working at THz frequencies operating from 0.5 THz to 2.6 THz. By simulation at THz band, proposed antenna performance as a wireless inter/intra-chip link is investigated by numericallyobtaining itssignal transmission coefficient characteristics between the two on-chip antennas, acting as transmitter and receiver or vice-verse for short-range THz communication among wireless NoC based multi-core processors integrated on same substrate. Theresults are obtained by placing the antennas in broadside orientation, that can communicate with intra-chip transmission coefficients ranging from − 20 dB to − 60 dB while sustaining bandwidths upto 0.13–0.2 THz. Further, the effect of transmission and radiation performance of proposed antennas with increase in distance dlink is studied along with reconfigurable nature of graphene with varying chemical potentials from 0.1 eV − 0.5 eV. Proposed antenna has obtained maximum gain and radiation efficiency of 3.89 dB and 58% at 1.83 THz when chemical potential of 0.1 eV is applied. This concept can broadly be applied to future systems as it can be directly integrated into transceivers as graphene is compatible with CMOS processes.Fabrication process steps of proposed on-chip antenna and its feasibility as a real device in chip environment isalso discussed. [ABSTRACT FROM AUTHOR]

Published

2024

40. Explorations and Exploitation for Parity-based RAIDs with Ultra-fast SSDs.

Author

Wang, Shucheng, Cao, Qiang, Jiang, Hong, Lu, Ziyi, Yao, Jie, Chen, Yuxing, and Pan, Anqun

Subjects

HARD disks, DATA structures, SOLID state drives, MULTICORE processors, SOFTWARE architecture

Abstract

Following a conventional design principle that pays more fast-CPU-cycles for fewer slow-I/Os, popular software storage architecture Linux Multiple-Disk (MD) for parity-based RAID (e.g., RAID5 and RAID6) assigns one or more centralized worker threads to efficiently process all user requests based on multi-stage asynchronous control and global data structures, successfully exploiting characteristics of slow devices, e.g., Hard Disk Drives (HDDs). However, we observe that, with high-performance NVMe-based Solid State Drives (SSDs), even the recently added multi-worker processing mode in MD achieves only limited performance gain because of the severe lock contentions under intensive write workloads. In this paper, we propose a novel stripe-threaded RAID architecture, StRAID, assigning a dedicated worker thread for each stripe-write (one-for-one model) to sufficiently exploit high parallelism inherent among RAID stripes, multi-core processors, and SSDs. For the notoriously performance-punishing partial-stripe writes that induce extra read and write I/Os, StRAID presents a two-stage stripe write mechanism and a two-dimensional multi-log SSD buffer. All writes first are opportunistically batched in memory, and then are written into the primary RAID for aggregated full-stripe writes or conditionally redirected to the buffer for partial-stripe writes. These buffered data are strategically reclaimed to the primary RAID. We evaluate a StRAID prototype with a variety of benchmarks and real-world traces. StRAID is demonstrated to outperform MD by up to 5.8 times in write throughput. [ABSTRACT FROM AUTHOR]

Published

2024

41. Dynamic machine learning‐based heuristic energy optimization approach on multicore architecture.

Author

Sundaresan, Yokesh B. and Saleem Durai, M. A.

Subjects

DYNAMIC programming, HEURISTIC, MACHINE learning, TEST systems, MULTICORE processors, MACHINERY

Abstract

In the present era, energy is progressively turning into the major limitation in designing multicore chips. However, power and performance are the primary segments of energy, which are contrarily correlated in multicore architectures. This research primarily focused on optimizing energy level of multicore chips using parallel workloads by utilizing either power or execution advancement based on machine learning computation on dynamic programming. To do as such, the novel dynamic machine learning‐based heuristic energy optimization (DML‐HEO) algorithm has been designed and developed in this research on application‐specific controllers to optimize energy‐level on multicore architecture. Here DML‐HEO is implemented on the controller to maximize the execution inside a fixed power spending plan or to limit the expended capacity to accomplish a similar pattern execution. The controller is additionally scalable as it does not bring about critical overhead due to the increase in quantity of cores. The strategy has been assessed utilizing controllers on a full‐framework test system at lab‐scale analysis. The experimental results demonstrate that our proposed DML‐HEO system shows improving performance than the traditional system. [ABSTRACT FROM AUTHOR]

Published

2024

42. Rapid measurement of epidermal thickness in OCT images of skin.

Author

Lin, Chieh-Hsi, Lukas, Brandon E, Rajabi-Estarabadi, Ali, May, Julia Rome, Pang, Yanzhen, Puyana, Carolina, Tsoukas, Maria, and Avanaki, Kamran

Subjects

OPTICAL coherence tomography, SKIN imaging, THICKNESS measurement, SKIN, MULTICORE processors

Abstract

Epidermal thickness (ET) changes are associated with several skin diseases. To measure ET, segmentation of optical coherence tomography (OCT) images is essential; manual segmentation is very time-consuming and requires training and some understanding of how to interpret OCT images. Fast results are important in order to analyze ET over different regions of skin in rapid succession to complete a clinical examination and enable the physician to discuss results with the patient in real time. The well-known CNN-graph search (CNN-GS) methodology delivers highly accurate results, but at a high computational cost. Our objective was to build a computational core, based on CNN-GS, able to accurately segment OCT skin images in real time. We accomplished this by fine-tuning the hyperparameters, testing a range of speed-up algorithms including pruning and quantization, designing a novel pixel-skipping process, and implementing the final product with efficient use of core and threads on a multicore central processing unit (CPU). We name this product CNN-GS-skin. The method identifies two defined boundaries on OCT skin images in order to measure ET. We applied CNN-GS-skin to OCT skin images, taken from various body sites of 63 healthy individuals. Compared with CNN-GS, our described method reduced computation time by 130 × with minimal reduction in ET determination accuracy (from 96.38 to 94.67%). [ABSTRACT FROM AUTHOR]

Published

2024

43. Performance analysis: Securing SIP on multi-threaded/multi-core proxy server using public keys on Diffie–Hellman (DH) in single and multi-server queuing scenarios.

Author

Bhatti, David Samuel, Sidrat, Salbia, Saleem, Shahzad, Malik, Annas Wasim, Suh, BeomKyu, Kim, Ki-Il, and Lee, Kyu-Chul

Subjects

PROXY servers, INTERNET protocols, MULTIMEDIA messaging, MULTIMEDIA communications, COMPUTER systems, WIRELESS LANs, MULTICORE processors

Abstract

The rapid replacement of PSTN with VOIP networks indicates the definitive phase-out of the PBX/PABX with smartphone-based VOIP technology that uses WLAN connectivity for local communication; however, security remains a key issue, regardless of the communication coverage area. Session initiation protocol (SIP) is one of the most widely adopted VOIP connection establishment protocols but requires added security. On the Internet, different security protocols, such as HTTPS (SSL/TLS), IPSec, and S/MIME, are used to protect SIP communication. These protocols require sophisticated infrastructure and some pose a significant overhead that may deteriorate SIP performance. In this article, we propose the following: i) avoid using Internet bandwidth and complex Internet protocols for local communication within an organization, but harness WLAN connectivity, ii) use multi-threaded or multicore computer systems to handle concurrent calls instead of installing hardware-based SIP servers, and iii) run each thread in a separate core. Cryptography is a key tool for securely transmitting confidential data for long- and short-range communication, and the Diffie-Hellman (DH) protocol has consistently been a popular choice for secret key exchanges. Primarily, used for symmetric key sharing, it has been proven effective in generating public/private key pairs, sharing public keys securely over public channels, and subsequently deriving shared secret keys from private/public keys. This key exchange scheme was proposed to safeguard VOIP communication within WLANs, which rely on the SIP for messaging and multimedia communication. For ensuring an efficient implementation of SIP, the system was rigorously analyzed using the M/M/1 and M/M/c queuing models. We analyze the behavior of SIP servers with queuing models with and without end-to-end security and increase users' trust in SIP security by providing a transparent sense of end-to-end security as they create and manage their private and public keys instead of relying on the underlying SIP technology. This research implements instant messaging, voice conversation, and secret key generation over DH while implementing and observing the role of multi-threading in multiqueue systems that serve incoming calls. By increasing the number of threads from one to two, the SIP response time improved from 20.23809 to 0.08070 min at an arrival rate of 4250 calls/day and a service rate of three calls/min. Similarly, by adding one to seven threads, the queue length was reduced by four calls/min. Implementing secure media streaming and reliable AES-based signaling for session confidentiality and integrity introduces a minor 8-ms tradeoff in SIP service performance. However, the advantages of implementing added security outweigh this limitation. [ABSTRACT FROM AUTHOR]

Published

2024

44. Minimizing Fuel Consumption for Surveillance Unmanned Aerial Vehicles Using Parallel Particle Swarm Optimization.

Author

Roberge, Vincent, Labonté, Gilles, and Tarbouchi, Mohammed

Subjects

PARTICLE swarm optimization, AERIAL surveillance, DRONE aircraft, AUTOMOTIVE fuel consumption, MULTICORE processors, ENERGY consumption, EQUATIONS of motion

Abstract

This paper presents a method based on particle swarm optimization (PSO) for optimizing the power settings of unmanned aerial vehicle (UAVs) along a given trajectory in order to minimize fuel consumption and maximize autonomy during surveillance missions. UAVs are widely used in surveillance missions and their autonomy is a key characteristic that contributes to their success. Providing a way to reduce fuel consumption and increase autonomy provides a significant advantage during the mission. The method proposed in this paper included path smoothing techniques in 3D for fixed-wing UAVs based on circular arcs that overfly the waypoints, an essential feature in a surveillance mission. It used the equations of motions and the decomposition of Newton's equation to compute the fuel consumption based on a given power setting. The proposed method used PSO to compute optimized power settings while respecting the absolute physical constraints, such as the load factor, the lift coefficient, the maximum speed and the maximum amount of fuel onboard. Finally, the method was parallelized on a multicore processor to accelerate the computation and provide fast optimization of the power settings in case the trajectory was changed in flight by the operator. Our results showed that the proposed PSO was able to reduce fuel consumption by up to 25% in the trajectories tested and the parallel implementation provided a speedup of 21.67× compared to a sequential implementation on the CPU. [ABSTRACT FROM AUTHOR]

Published

2024

45. Fast slope algorithm with the use of vectorization and parallelization for multicore architectures.

Author

Bylina, Beata, Bylina, Jarosław, Chabudziński, Łukasz, Karpowicz, Karol, Klisowski, Michał, Oleszczuk, Piotr, Potiopa, Joanna, and Stpiczyński, Przemysław

Subjects

MULTICORE processors, ALGORITHMS, PARALLEL algorithms

Abstract

The slope calculation algorithm is one of the most widely used geospatial algorithms employing the 3x3 moving window technique (along with calculation of aspect, curvature and flow direction). This work presents an approach consisting of transforming a slope algorithm from a sequential form into a version that can exploit vector and parallel traits of multicore architectures with vector instructions. This approach allows us to take advantage of the potential of the modern multicore processors. The basic idea for optimizing the 3x3 moving window computation is to split the equation used to calculate the result into parts that operate on data that are known to exist in adjacent memory locations. The research was conducted on two multicore architectures without the change in the code — the older architecture was Sandy Bridge and the newer one was Haswell (with more cores). The efficiency of the developed slope algorithm was verified in practice with the use of DEM files of the same resolution but of different sizes. We showed through the numerical experiments that our approach gives better time performance than the original algorithm (and other tools) — and with no loss of accuracy. [ABSTRACT FROM AUTHOR]

Published

2024

46. Optimization of re-configurable multi-core processors and security based on field programmable gate arrays.

Author

Bachanna, Prashant, Sankar, Palla Hari, Tripathi, Mukesh Kumar, Shivendra, Kumar, Kadali Ravi, and Bhosle, Nilesh

Subjects

FIELD programmable gate arrays, FLOATING-point arithmetic, ADVANCED Encryption Standard, SOFTWARE development tools, QUALITY control, PUBLIC key cryptography, MULTICORE processors

Abstract

In system-on-a-chip based complex processors has the problem of multithreading and miss-functionality due to their complexity and high-speed operations. In order to minimize these problems, the proposed design has machine learningbased algorithms and cryptography systems for security has been incorporated. In the proposed work, the security level has been taken care of in three different stages such as data integrity, data authentication, and private and public keys encryption and decryption. In order to increase throughput with minimal latency, the proposed architecture with advanced high-performance protocol and advanced high-performance and advanced peripheral bus bridge is incorporated between the fabric dynamically re configurable multi-processor and peripherals along with security algorithms using secure hash algorithm (SHA-256) bits and advanced encryption standard (AES). In order to perform machine learningbased applications, the proposed system is incorporated double-precision floating point arithmetic operations. The overall proposed architecture is developed in verilog hybrid deep learning (HDL) and quality checking using the LINT tool. The entire design is interfaced with the Zynq processor and software development kit (SDK) tool to verify data transfer between hardware and software. The obtained results are compared with existing state-of-art results and found that 18% improvement in throughput, a 21% improvement in power consumption savings, and a 34% reduction in latency. [ABSTRACT FROM AUTHOR]

Published

2024

47. RLARA: A TSV-Aware Reinforcement Learning Assisted Fault-Tolerant Routing Algorithm for 3D Network-on-Chip.

Author

Jiao, Jiajia, Shen, Ruirui, Chen, Lujian, Liu, Jin, and Han, Dezhi

Subjects

REINFORCEMENT learning, ROUTING algorithms, MULTICORE processors, FAULT tolerance (Engineering), K-means clustering, GARNET

Abstract

A three-dimensional Network-on-Chip (3D NoC) equips modern multicore processors with good scalability, a small area, and high performance using vertical through-silicon vias (TSV). However, the failure rate of TSV, which is higher than that of horizontal links, causes unpredictable topology variations and requires adaptive routing algorithms to select the available paths dynamically. Most works have aimed at the congestion control for TSV partially 3D NoCs to bypass the TSV reliability issue, while others have focused on the fault tolerance in TSV fully connected 3D NoCs and ignored the performance degradation. In order to adequately improve reliability and performance in TSV fully connected 3D NoC architectures, we propose a TSV-aware Reinforcement Learning Assisted Routing Algorithm (RLARA) for fault-tolerant 3D NoCs. The proposed method can take advantage of both the high throughput of fully connected TSVs and the cost-effective fault tolerance of partially connected TSVs using periodically updated TSV-aware Q table of reinforcement learning. RLARA makes the distributed routing decision with the lowest TSV utilization to avoid the overheating of the TSVs and mitigate the reliability problem. Furthermore, the K-means clustering algorithm is further adopted to compress the routing table of RLARA by exploiting the routing information similarity. To alleviate the inherent deadlock issue of adaptive routing algorithms, the link Q-value from reinforcement learning is combined with the router status based in buffer utilization to predict the congestion and enable RLARA to perform best even under a high traffic load. The experimental results of the ablation study on simulator Garnet 2.0 verify the effectiveness of our proposed RLARA under different fault models, which can perform better than the latest 3D NoC routing algorithms, with up to a 9.04% lower average delay and 8.58% higher successful delivered rate. [ABSTRACT FROM AUTHOR]

Published

2023

48. Parallel path detection for fraudulent accounts in banks based on graph analysis.

Author

Zuxi Chen, ShiFan Zhang, XianLi Zeng, Meng Mei, Xiangyu Luo, and Lixiao Zheng

Subjects

ACCOUNTING fraud, BANK accounts, BANKING industry, MULTICORE processors, DIRECTED graphs, MONEY laundering, PARALLEL algorithms, GRAPH algorithms

Abstract

This article presents a novel parallel path detection algorithm for identifying suspicious fraudulent accounts in large-scale banking transaction graphs. The proposed algorithm is based on a three-step approach that involves constructing a directed graph, shrinking strongly connected components, and using a parallel depth-first search algorithm to mark potentially fraudulent accounts. The algorithm is designed to fully exploit CPU resources and handle large-scale graphs with exponential growth. The performance of the algorithm is evaluated on various datasets and compared with serial time baselines. The results demonstrate that our approach achieves high performance and scalability on multi-core processors, making it a promising solution for detecting suspicious accounts and preventing money laundering schemes in the banking industry. Overall, our work contributes to the ongoing efforts to combat financial fraud and promote financial stability in the banking sector. [ABSTRACT FROM AUTHOR]

Published

2023

49. Computational performance of musculoskeletal simulation in OpenSim Moco using parallel computing.

Author

Denton, Alex N. and Umberger, Brian R.

Subjects

PARALLEL programming, HUMAN mechanics, THREE-dimensional modeling, PROBLEM solving, INTEGRATED software, MULTICORE processors, PARALLEL algorithms

Abstract

Optimal control musculoskeletal simulation is a valuable approach for studying fundamental and clinical aspects of human movement. However, the high computational demand has long presented a substantial challenge, creating a need to improve simulation performance. The OpenSim Moco software package permits musculoskeletal simulation problems to be solved in parallel on multicore processors using the CasADi optimal control library, potentially reducing the computational demand. However, the computational performance of this framework has not been thoroughly examined. Thus, we aimed to investigate the computational speed‐up obtained via multicore parallel computing relative to solving problems serially (i.e., using a single core) in optimal control simulations of human movement in OpenSim Moco. Simulations were solved using up to 18 cores with a variety of temporal mesh interval densities and using two different initial guess strategies. We examined a range of musculoskeletal models and movements that included two‐ and three‐dimensional models, tracking and predictive simulations, and walking and reaching tasks. The maximum overall parallel speed‐up was problem specific and ranged from 1.7 to 7.7 times faster than serial, with most of the speed‐up achieved by about 6 processor cores. Parallel speed‐up was generally greater on finer temporal meshes, while the initial guess strategy had minimal impact on speed‐up. Considerable speed‐up can be achieved for some optimal control simulation problems in OpenSim Moco by leveraging the multicore processors often available in modern computers. However, since improvements are problem specific, achieving optimal computational performance will require some degree of exploration by the end user. [ABSTRACT FROM AUTHOR]

Published

2023

50. An analysis on multi-level cache eviction policies in multi-core processor using GEM5 simulator.

Author

Sahu, Narottam, Dash, Banchhanidhi, Pattnaik, Prasant Kumar, Sangam, Manas, Moningi, Venkateshh, Verma, Arushi, and Jha, Shubham

Subjects

MULTICORE processors, CACHE memory, EVICTION, COMPARATIVE studies

Abstract

Ideally, we could solve all memory performance problems, where we store everything in high performance caches. But the high cost associated forces us to keep only a limited amount of working set of data in these caches making replacementt of disposable blocks of data with the desired one is a fundamental property to caches. Ultimately, the performance of a cache is influenced heavily by the replacement policy it uses. In this paper, we conduct a comparative analysis about a few replacement policies in use today from traditional strategies to the ones that attempt to emulate optimal replacement and also simulated a few replacement strategy to test the performance of multi-level cache by configuring the cache memory subsystem in GEM5 simulator and build up using X86, ARM, And MIPS instruction set architecture and observed through the statistical output that LRU replacement technique outperforms over existing policy and found an improvement in simulation time, miss rate and some other measures by giving workload of highly intensive benchmark application from CPU 2006 and CPU 2017. [ABSTRACT FROM AUTHOR]

Published

2023