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Design of Noise Filters for Integrating Time Delay Processes

  • Ediga Chandramohan Goud and A. Seshagiri Rao EMAIL logo
Published/Copyright: November 14, 2019
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Chemical Product and Process Modeling
From the journal Chemical Product and Process Modeling Volume 15 Issue 2

Abstract

In this research, a second order noise filter is designed for reducing the noise effect on PID controlled Integrating plus time delay (IPTD), Integrating plus first order plus time delay (IFOPTD), Double integrating plus time delay (DIPTD) processes. The second order noise filter time constant is designed based on an iterative approach, which is a function of loop gain crossover frequency (ωgc) and a design parameter β. Based on the data obtained from an integrating process and the controller, the controller parameters are calculated using Optimal H2 -IMC based technique. The design parameter (β) is selected as a compromise among robustness, performance and reduction of measurement noise. Simulation studies are carried out on different IPTD, IFOPTD and DIPTD processes to illustrate the amount of reduction of noise effect on process output and controller output. The effect is also calculated based on Integral Absolute Error (IAE), Integral Square Error (ISE) and Total Variance (TV) criteria by considering perfect and perturbations in the process parameters.

Keywords: noise filter; PID controller; integrating process; time delay; Maximum sensitivity; Total variance

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Received: 2019-04-11
Revised: 2019-09-18
Accepted: 2019-10-23
Published Online: 2019-11-14

© 2019 Walter de Gruyter GmbH, Berlin/Boston

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https://doi.org/10.1515/cppm-2019-0056
Keywords for this article
noise filter; PID controller; integrating process; time delay; Maximum sensitivity; Total variance

Articles in the same Issue

  1. Editorial
  2. NOTE FROM GUEST EDITORS
  3. Research Articles
  4. Kinetic Modeling of Citrullus Lanatus (Watermelon) Peel Using Thermo Gravimetric Analysis
  5. Numerical Evaluation of Liquid Mixing in a Serpentine Square Convergent-divergent Passive Micromixer
  6. Design of Noise Filters for Integrating Time Delay Processes
  7. Fractional Order PID Controller Design for Multivariable Systems using TLBO
  8. Natural Convection Heat Transfer in a Shell and Helical Coil Heat Exchanger Using non-Newtonian Nanofluids
  9. Numerical Investigation of Heat Transfer and Fluid Flow Characteristics in Circular Wavy Microchannels with Sidewall Rib
  10. Design of Fractional Order PID Controller Using Genetic Algorithm Optimization Technique for Nonlinear System
  11. Design of VRFT Based Feedback-feedforward Controllers for Enhancing Disturbance Rejection on Non-minimum Phase Systems
  12. Simultaneous Scheduling and Heat Integration of Batch Plants Using Unit-Specific Event Based Modelling
  13. Multi Gene Genetic Program Modelling on L-Asparaginase Activity of Bacillus Stratosphericus
  14. Enhancement of Glass Production Rate in Joule Heated Ceramic Melter
  15. Thermographic Studies of Aerogel Composites
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