An FPGA-based analysis of trade-offs in the presence of ill-conditioning and different precision levels in computations

Algredo‐Badillo, Ignacio; Mones, José Julio Conde; Hernández-Gracidas, Carlos Arturo; Morín-Castillo, M. M.; Óliveros, J.; Feregrino-Uribe, Claudia

doi:10.1371/journal.pone.0234293

Cited by 3 publications

(2 citation statements)

References 19 publications

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“…At this point, it is important to consider that inadequate handling of precision might worsen results as the solution found for data with errors might be too far from the one for data without errors, besides increasing other costs in hardware resources and critical paths. In [6], the authors made a wake-up call, using 2 × 2 matrices to show how ill-conditioning and precision can affect system design (resources, cost, etc. ), and they illustrated the effect generated in the calculation of the inverse of an ill-conditioned matrix when its elements were approximated by truncation.…”

Section: Of 24mentioning

confidence: 99%

FPGA-Based Hardware Implementation of a Stable Inverse Source Problem Algorithm in a Non-homogeneous Circular Region

Oliveros,

Sánchez,

Gracidas

et al. 2023

Preprint

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This work implements a stable algorithm in Field-Programmable Gate Arrays (FPGAs) for which two architectures (unrolling the loop) were developed and analyzed. The algorithm recovers sources located at the boundary separating two homogeneous media that make up a two-dimensional non-homogeneous region from measurements on the boundary of such region. The problem of recovering these sources is an ill-posed inverse problem as small errors in the measurement can produce important changes in the source location. Inverse source problems have many applications in different areas, such as engineering and medicine, making the proposed implementation important. The first architecture (mode one) allows considering different operating speeds, which is an advantage depending on whether we work with fast or slow signals. The second one (mode two) reduces resource consumption by exploiting the characteristics of the source identification algorithm, which is an advantage for multichannel problems such as inverse electrocardiography or electroencephalography. The architectures were tested on four FPGAs of the 7 Series of Xilinx: Spartan-7 xc7s100fgga484, Virtex-7 xc7v585tffg1157, Kintex-7 xc7k70tfbg484, and Artix-7 xc7a35tcpg236. The two FPGA implementations of the algorithm were validated using synthetic examples implemented in MATLAB. The results presented here can be extended to concentric spheres and complex geometries.

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Section: Of 24mentioning

confidence: 99%

FPGA-Based Hardware Implementation of a Stable Inverse Source Problem Algorithm in a Non-homogeneous Circular Region

Oliveros,

Sánchez,

Gracidas

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

“…At this point, it is important to consider that handling precision inadequately might worsen the results, as the solution found for data with errors might be too far from the one for data without errors in addition to increasing other costs via hardware resources and critical paths. In [6], the authors pointed out that using 2 × 2 matrices to show how ill-conditioning and precision can affect system design (resources, cost, etc. ), and they illustrated the effect generated in the calculation of the inverse of an ill-conditioned matrix when its elements were approximated by truncation.…”

Section: Introductionmentioning

confidence: 99%

FPGA-Based Hardware Implementation of a Stable Inverse Source Problem Algorithm in a Non-Homogeneous Circular Region

Oliveros-Oliveros,

Conde-Sánchez,

Hernández-Gracidas

et al. 2024

Applied Sciences

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Objective: This work presents an implementation of a stable algorithm that recovers sources located at the boundary separating two homogeneous media in field-programmable gate arrays. Two loop unrolling architectures were developed and analyzed for this purpose. This inverse source problem is ill-posed due to numerical instability, i.e., small errors in the measurement can produce significant changes in the source location. Methodology: To handle the numerical instability when recovering these sources, the Tikhonov regularization method in combination with the Fourier series truncation method are applied in the stable algorithm. This stable algorithm is implemented in two different architectures developed in this work: The first architecture (Mode 1) allows for different operating speeds, which is an advantage depending on whether we work with fast or slow signals. The second one (Mode 2) reduces resource consumption by exploiting the characteristics of the source identification algorithm, which is an advantage for multichannel problems such as inverse electrocardiography or electroencephalography. Results: The architectures were tested on four devices of the 7 Series of Xilinx: Spartan-7 xc7s100fgga484, Virtex-7 xc7v585tffg1157, Kintex-7 xc7k70tfbg484, and Artix-7 xc7a35tcpg236. The two hardware implementations of the stable algorithm were validated using synthetic examples implemented in MATLAB, which shows the advantages of each architecture. Contributions: We developed two efficient architectures based on a loop unrolling design for source identification problems. These are effective strategies to divide and assign tasks to the configurable hardware, and they appear as an appropriate technique for implementing the algorithm. The first one is simple and allows for different operating speeds. The second one uses a control system based on multiplexors that reduce resource consumption and complexity of the design and can be used for multichannel problems. From the numerical test, we found the regularization parameters. The synthetic examples developed here can be considered for similar problems and can be extended to concentric spheres.

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Acceleration of Nuclear Reactor Simulation and Uncertainty Quantification Using Low-Precision Arithmetic

2023

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In recent years, interest in approximate computing has been increasing significantly in many disciplines in the context of saving energy and computation cost by trading off on the quality of numerical simulation. The hardware acceleration based on the low-precision floating-point arithmetic is anticipated by the upcoming generation of microprocessors and code compilers and has already proven to be beneficial for weather and climate modelling and neural network training. The present work illustrates the application of low-precision arithmetic for the nuclear reactor core uncertainty analysis. We studied the performance of an elementary transient reactor core model for the arbitrary precision of the floating-point multiplication in a direct linear system solver. Using this model, we calculated the reactor core transients initiated by the control rod ejection taking into account the uncertainty of the model input parameters. Then, we evaluated the round-off errors of the model outputs for different precision levels. The comparison of the round-off errors and the model uncertainty showed the model could be run using a 15-bit floating-point number precision with an acceptable degradation of the result’s accuracy. This precision corresponds to a gain of about 6× in the bit complexity of the linear system solution algorithm, which can be actualized in terms of reduced energy costs on low-precision hardware.

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An FPGA-based analysis of trade-offs in the presence of ill-conditioning and different precision levels in computations

Cited by 3 publications

References 19 publications

FPGA-Based Hardware Implementation of a Stable Inverse Source Problem Algorithm in a Non-homogeneous Circular Region

FPGA-Based Hardware Implementation of a Stable Inverse Source Problem Algorithm in a Non-homogeneous Circular Region

FPGA-Based Hardware Implementation of a Stable Inverse Source Problem Algorithm in a Non-Homogeneous Circular Region

Acceleration of Nuclear Reactor Simulation and Uncertainty Quantification Using Low-Precision Arithmetic

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