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Classification of Signals01:30

Classification of Signals

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In signal processing, signals are classified based on various characteristics: continuous-time versus discrete-time, periodic versus aperiodic, analog versus digital, and causal versus noncausal. Each category highlights distinct properties crucial for understanding and manipulating signals.
A continuous-time signal holds a value at every instant in time, representing information seamlessly. In contrast, a discrete-time signal holds values only at specific moments, often denoted as x(n), where...
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Signal and System01:26

Signal and System

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A signal x(t) is a set of data or a time function representing a variable of interest. Signals typically convey information about a phenomenon, such as atmospheric temperature, humidity, human voice, television images, a dog's bark, or birdsongs. More generally, a signal can be a function of more than one independent variable. For instance, images depend on horizontal and vertical positions and can be regarded as two-dimensional signals. However, this text will focus on one-dimensional...
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Cascaded Op Amps01:16

Cascaded Op Amps

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Operational amplifiers (op-amps) are versatile electronic components that can be interconnected in a cascade - one after another in a linear sequence. This cascading is possible due to their infinite input resistance and zero output resistance, allowing them to maintain their input-output relationships even when connected in series.
In a cascaded system, each op-amp is referred to as a stage. The output of one stage drives the input of the subsequent stage. As the input signal passes through...
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Region of Convergence of Laplace Tarnsform01:20

Region of Convergence of Laplace Tarnsform

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The Region of Convergence (ROC) is a fundamental concept in signal processing and system analysis, particularly associated with the Laplace transform. The ROC represents an area in the complex plane where the Laplace transform of a given signal converges, determining the transform's applicability and utility.
Consider a decaying exponential signal that begins at a specific time. When deriving its Laplace transform, the time-domain variable is replaced with a complex variable. This...
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Basic Operations on Signals01:22

Basic Operations on Signals

351
Basic signal operations include time reversal, time scaling, time shifting, and amplitude transformations. These operations are fundamental in signal processing and analysis.
Time Reversal mirrors a continuous-time signal about the vertical axis at t=0. This is achieved by substituting t with −t. For example, if a signal x(t) is considered, the time-reversed signal is x(−t). This operation can be graphically represented, showing the mirrored signal.
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¹H NMR Signal Integration: Overview00:58

¹H NMR Signal Integration: Overview

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The intensity of a signal, which can be represented by the area under the peak, depends on the number of protons contributing to that signal. The area under each peak is shown as a vertical line called an integral, with the integral value listed under it, as seen in the proton NMR spectrum of benzyl acetate. Each integral value is divided by the smallest integral value to obtain the ratio of the number of protons producing each signal. The ratio reveals the relative number of protons and not...
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Related Experiment Video

Updated: Jun 4, 2025

Tracking Infiltration Front Depth Using Time-lapse Multi-offset Gathers Collected with Array Antenna Ground Penetrating Radar
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Enhanced Radar Signal Classification Using AMP and Visibility Graph for Multi-Signal Environments.

Ji-Hyeon Kim1, Soon-Young Kwon1, Hyoung-Nam Kim1

  • 1Department of Electrical and Electronics Engineering, Pusan National University, Busan 46241, Republic of Korea.

Sensors (Basel, Switzerland)
|December 17, 2024
PubMed
Summary

This study introduces a new two-stage radar signal classification method using amplitude pattern analysis and visibility graphs. It effectively distinguishes overlapping signals, even in challenging low signal-to-noise ratio environments.

Keywords:
amplitude patternradar scan pattern classificationvisibility graph

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Area of Science:

  • Signal Processing
  • Electronic Warfare
  • Machine Learning

Background:

  • Classifying overlapping radar signals is difficult in complex environments.
  • Traditional methods like spectrogram analysis fail with similar scan patterns or low signal-to-noise ratios (SNR).

Purpose of the Study:

  • To develop a novel framework for accurate and efficient radar signal classification and deinterleaving.
  • To overcome limitations of traditional methods in complex electronic warfare scenarios.

Main Methods:

  • A two-stage classification framework combining amplitude pattern (AMP) analysis and visibility graphs.
  • AMP analysis for initial signal grouping and noise reduction.
  • Visibility graphs for refining classifications and separating similar amplitude signals.
  • Integration of deep learning models (GoogLeNet, ResNet) for enhanced performance.

Main Results:

  • The framework effectively classifies and deinterleaves overlapping radar signals.
  • Demonstrated robustness in low-SNR and multi-signal environments.
  • Successfully handled complex scans, including the Palmer series.

Conclusions:

  • The proposed method significantly improves radar signal differentiation over conventional techniques.
  • Offers enhanced performance for various scanning patterns in challenging multi-signal environments.