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Related Concept Videos

Reducing Line Loss01:18

Reducing Line Loss

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In a three-phase circuit, line loss is an indicator of energy dissipated as heat due to the resistance of transmission lines. To address this, incorporating transformers into the system—a step-up transformer at the source and a step-down transformer at the load—is a strategic solution. Two three-phase transformers are introduced to improve this.
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Reconstruction of Signal using Interpolation01:10

Reconstruction of Signal using Interpolation

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Signal processing techniques are essential for accurately converting continuous signals to digital formats and vice versa. When a continuous signal is sampled with a period T, the resulting sampled signal exhibits replicas of the original spectrum in the frequency domain, spaced at intervals equal to the sampling frequency. To handle this sampled signal, a zero-order hold method can be applied, which creates a piecewise constant signal by retaining each sample's value until the next...
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Boundary Conditions: Lossless Lines01:21

Boundary Conditions: Lossless Lines

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Consider a single-phase, two-wire, lossless transmission line terminated by an impedance at the receiving end and a source with Thevenin voltage and impedance at the sending end. The line, with length, has a surge impedance and wave velocity determined by the line's inductance and capacitance.
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Downsampling01:20

Downsampling

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When considering a sampled sequence with zero values between sampling instants, one can replace it by taking every N-th value of the sequence. At these integer multiples of N, the original and sampled sequences coincide. This process, known as decimation, involves extracting every N-th sample from a sequence, thereby creating a more efficient sequence.
The Fourier transform of the decimated sequence reveals a combination of scaled and shifted versions of the original spectrum. This...
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Uniform Depth Channel Flow: Problem Solving01:18

Uniform Depth Channel Flow: Problem Solving

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To calculate the flow rate for a trapezoidal channel, first, identify the bottom width, side slope, and flow depth of the channel. The cross-sectional area (A) corresponding to the depth of flow (y), channel bottom width (B), and side slope (θ) is determined by:Next, calculate the wetted perimeter, which includes the bottom width and the sloped side lengths in contact with the water. Using the values of the cross-sectional area and the wetted perimeter, determine the hydraulic radius by...
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Deconvolution01:20

Deconvolution

217
Deconvolution, also known as inverse filtering, is the process of extracting the impulse response from known input and output signals. This technique is vital in scenarios where the system's characteristics are unknown, and they must be inferred from the observable signals.
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Lossless Reconstruction of Convolutional Neural Network for Channel-Based Network Pruning.

Donghyeon Lee1, Eunho Lee1, Youngbae Hwang1

  • 1Department of Control and Robot Engineering, Chungbuk National University, Cheongju 28644, Republic of Korea.

Sensors (Basel, Switzerland)
|February 28, 2023
PubMed
Summary
This summary is machine-generated.

This study introduces a novel reconstruction process for channel-based network pruning, enhancing performance on real devices. The method improves accuracy and significantly reduces latency for convolutional neural networks (CNNs).

Keywords:
convolutional neural networklossless reconstructionnetwork pruning

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Area of Science:

  • Computer Science
  • Artificial Intelligence
  • Machine Learning

Background:

  • Network pruning is crucial for reducing computational costs and parameters in convolutional neural networks (CNNs).
  • Existing pruning methods often neglect the reconstruction phase, limiting practical deployment on devices.
  • Efficient deployment of pruned CNNs requires careful consideration of network components post-pruning.

Purpose of the Study:

  • To propose a novel reconstruction process for channel-based network pruning.
  • To enable lossless reconstruction of pruned networks for practical device application.
  • To improve the performance and efficiency of pruned CNNs on downstream tasks.

Main Methods:

  • Developed a reconstruction process focusing on residual blocks, skip connections, and convolution layers.
  • Applied union operation and index alignment for reconstructing residual blocks and skip connections.
  • Incorporated batch normalization into the reconstruction of compressed convolution layers.

Main Results:

  • Achieved higher accuracy in image classification (1.93%), semantic segmentation (2.2 mIoU), and object detection (0.054 mAP) compared to small models.
  • Demonstrated significant latency reduction: 8.15× on Raspberry Pi and 5.29× on Jetson Nano.
  • Validated the method's effectiveness across various downstream tasks.

Conclusions:

  • The proposed reconstruction method effectively enhances pruned CNN performance for real-world applications.
  • This approach bridges the gap between network pruning research and practical device deployment.
  • The method offers a viable solution for deploying efficient and high-performing deep learning models on edge devices.