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Related Concept Videos

State Space Representation01:27

State Space Representation

324
The frequency-domain technique, commonly used in analyzing and designing feedback control systems, is effective for linear, time-invariant systems. However, it falls short when dealing with nonlinear, time-varying, and multiple-input multiple-output systems. The time-domain or state-space approach addresses these limitations by utilizing state variables to construct simultaneous, first-order differential equations, known as state equations, for an nth-order system.
Consider an RLC circuit, a...
324
Sampling Continuous Time Signal01:11

Sampling Continuous Time Signal

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In signal processing, a continuous-time signal can be sampled using an impulse-train sampling technique, followed by the zero-order hold method. Impulse-train sampling involves the use of a periodic impulse train, which consists of a series of delta functions spaced at regular intervals determined by the sampling period. When a continuous-time signal is multiplied by this impulse train, it generates impulses with amplitudes corresponding to the signal's values at the sampling points.
In the...
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Upsampling01:22

Upsampling

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Managing signal sampling rates is essential in digital signal processing to maintain signal integrity. A decimated signal, characterized by a reduced frequency range due to its lower sampling rate, can be upsampled by inserting zeros between each sample. This upsampling process expands the original spectrum and introduces repeated spectral replicas at intervals dictated by the new Nyquist frequency. To refine this zero-inserted sequence, it is passed through a lowpass filter with a cutoff...
351
Transfer Function to State Space01:23

Transfer Function to State Space

450
State-space representation is a powerful tool for simulating physical systems on digital computers, necessitating the conversion of the transfer function into state-space form. Consider an nth-order linear differential equation with constant coefficients, like those encountered in an RLC circuit. The state variables are selected as the output and its n−1 derivatives. Differentiating these variables and substituting them back into the original equation produces the state equations.
In an...
450
Downsampling01:20

Downsampling

296
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...
296
Second Order systems II01:18

Second Order systems II

204
In an underdamped second-order system, where the damping ratio ζ is between 0 and 1, a unit-step input results in a transfer function that, when transformed using the inverse Laplace method, reveals the output response. The output exhibits a damped sinusoidal oscillation, and the difference between the input and output is termed the error signal. This error signal also demonstrates damped oscillatory behavior. Eventually, as the system reaches a steady state, the error diminishes to zero.
204

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Quantum State Engineering of Light with Continuous-wave Optical Parametric Oscillators
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A Two-Filter Approach for State Estimation Utilizing Quantized Output Data.

Angel L Cedeño1,2, Ricardo Albornoz1,2, Rodrigo Carvajal3

  • 1Departamento Electrónica, Universidad Técnica Federico Santa María (UTFSM), Av. España 1680, Valparaíso 2390123, Chile.

Sensors (Basel, Switzerland)
|November 27, 2021
PubMed
Summary
This summary is machine-generated.

This study introduces Gaussian sum filtering and smoothing algorithms to improve state estimation from quantized, noisy measurements. The new methods enhance accuracy and reduce computational cost in real-world applications.

Keywords:
Gaussian sum filteringGaussian sum smoothingGauss–Legendre quadraturequantized datastate estimation

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Area of Science:

  • Control Systems Engineering
  • Signal Processing
  • Data Analysis

Background:

  • Filtering and smoothing algorithms are crucial for decision-making and parameter identification in diverse fields like economics and control systems.
  • Noisy measurements from cost-effective sensors or digitalization processes often lead to significant information loss, complicating accurate state estimation.
  • Developing robust algorithms is essential for reliable system analysis and control under practical measurement constraints.

Purpose of the Study:

  • To develop advanced Gaussian sum filtering and smoothing algorithms specifically designed for quantized and noisy measurements.
  • To address the challenge of information loss in real-world sensor data and communication channels.
  • To improve the accuracy and computational efficiency of state estimation techniques.

Main Methods:

  • Characterization of the probability mass function of quantized output using an integral equation.
  • Approximation of the integral equation via Gauss-Legendre quadrature to obtain a Gaussian mixture model.
  • Development of filtering and smoothing algorithms based on the derived Gaussian mixture model.

Main Results:

  • The proposed Gaussian sum filtering and smoothing algorithms effectively handle quantized and noisy measurements.
  • Numerical simulations demonstrate significant improvements in estimation accuracy compared to existing methods.
  • The developed algorithms offer a favorable balance between estimation accuracy and computational cost.

Conclusions:

  • Gaussian sum filtering and smoothing provide a robust framework for state estimation with quantized measurements.
  • The Gauss-Legendre quadrature approximation enables efficient processing of quantized data within a Gaussian mixture structure.
  • This approach offers practical benefits for applications requiring accurate state estimation under measurement limitations.