Asynchronous Processing for Latent Fingerprint Identification on Heterogeneous CPU-GPU Systems

Sanchez-Fernandez, A.; Romero, Luis F.; Peralta, Daniel; Medina‐Pérez, Miguel Angel; Saeys, Yvan; Herrera, Francisco; Tabik, Siham

doi:10.1109/access.2020.3005476

Cited by 10 publications

(3 citation statements)

References 45 publications

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“…In designing CPU and GPU acceleration strategies, tasks are assigned based on the computational characteristics of the CPU and GPU [38][39][40]. The CPU is suitable for a series of control-type tasks, particularly those requiring low latency and high performance, such as data transfer and image display processes.…”

Section: Central Processing Unit (Cpu) and Gpu Processingmentioning

confidence: 99%

“…The CPU and GPU performances can be optimized by disabling the power-saving functions of the CPU, adjusting the GPU clock to the maximum frequency, and closing all superfluous programs. Due to the independent CPU and GPU memories on computers, there are many migrations between them; the CPU and GPU of the Jetson Nano Developer Kit share physically unified memory, eliminating the tedious transfer process [35][36][37][38][39][40].…”

Section: Central Processing Unit (Cpu) and Gpu Processingmentioning

confidence: 99%

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Fast and accurate phase processing in off-axis digital holography combining adaptive spatial filtering and an embedded GPU platform

Bai,

Li,

Sun

et al. 2024

Meas. Sci. Technol.

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Parallel-phase processing enables rapid phase extraction from off-axis digital holograms. To achieve fast and accurate results, the phase reconstruction processes were parallelized using improved filter algorithms and optimized programming strategies. First, an adaptive filtering method based on the Chan-Vese (CV) model which better suits parallelism was designed to extract the +1 term spectrum. We selected suitable computer unified device architecture (CUDA) libraries according to the characteristics of the key phase reconstruction steps. Acceleration technologies, such as virtual memory and shared memory, were used to improve the computational efficiency. Furthermore, we combined an improved 4f optical imaging system with an embedded graphic processing unit (GPU) platform to design a low-cost phase reconstruction system for off-axis digital holography. To verify the feasibility of our method, the reconstructed quality of the CV filtering method was estimated, and the run times of phase retrieval on the central processing unit (CPU) and embedded GPU were compared for off-axis holograms with different pixel sizes. Additionally, the dynamic fluctuation phase maps of water droplet evaporation were retrieved to demonstrate the real-time capability of the method.

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Section: Central Processing Unit (Cpu) and Gpu Processingmentioning

confidence: 99%

Section: Central Processing Unit (Cpu) and Gpu Processingmentioning

confidence: 99%

Fast and accurate phase processing in off-axis digital holography combining adaptive spatial filtering and an embedded GPU platform

Bai,

Li,

Sun

et al. 2024

Meas. Sci. Technol.

View full text Add to dashboard Cite

show abstract

“…The technological advances in high-performance computing have enabled the development of fast and highly accurate biometric systems. Most frequently, this performance is achieved using power-hungry processors and graphics processing units (GPUs) [ 42 , 43 ]. While this cost in power and space may not be important in big data applications that require high precision, it is normally not acceptable in mobile or portable biometric systems [ 11 ], which require compact, power-efficient electronics.…”

Section: Related Workmentioning

confidence: 99%

Face Recognition on a Smart Image Sensor Using Local Gradients

Valenzuela

Soto

Zarkesh-Ha

et al. 2021

Sensors

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In this paper, we present the architecture of a smart imaging sensor (SIS) for face recognition, based on a custom-design smart pixel capable of computing local spatial gradients in the analog domain, and a digital coprocessor that performs image classification. The SIS uses spatial gradients to compute a lightweight version of local binary patterns (LBP), which we term ringed LBP (RLBP). Our face recognition method, which is based on Ahonen’s algorithm, operates in three stages: (1) it extracts local image features using RLBP, (2) it computes a feature vector using RLBP histograms, (3) it projects the vector onto a subspace that maximizes class separation and classifies the image using a nearest neighbor criterion. We designed the smart pixel using the TSMC 0.35 μm mixed-signal CMOS process, and evaluated its performance using postlayout parasitic extraction. We also designed and implemented the digital coprocessor on a Xilinx XC7Z020 field-programmable gate array. The smart pixel achieves a fill factor of 34% on the 0.35 μm process and 76% on a 0.18 μm process with 32 μm × 32 μm pixels. The pixel array operates at up to 556 frames per second. The digital coprocessor achieves 96.5% classification accuracy on a database of infrared face images, can classify a 150×80-pixel image in 94 μs, and consumes 71 mW of power.

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ConDense: Multiple Additional Dense Layers with Fine-Grained Fully-Connected Layer Optimisation for Fingerprint Recognition

Lang

Haar

2022

Pattern Recognition and Artificial Intelligence

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Asynchronous Processing for Latent Fingerprint Identification on Heterogeneous CPU-GPU Systems

Cited by 10 publications

References 45 publications

Fast and accurate phase processing in off-axis digital holography combining adaptive spatial filtering and an embedded GPU platform

Fast and accurate phase processing in off-axis digital holography combining adaptive spatial filtering and an embedded GPU platform

Face Recognition on a Smart Image Sensor Using Local Gradients

ConDense: Multiple Additional Dense Layers with Fine-Grained Fully-Connected Layer Optimisation for Fingerprint Recognition

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