Frequency response analysis

Mehdi Bagheri, Toan Phung

Research output: Chapter in Book/Report/Conference proceedingChapter

Abstract

Transformers can be treated as a time-invariant system which can be characterized by its response to the Dirac’s delta function. This impulse response is completely unique and should remain so over the system life. Therefore, it can be used as a kind of indicator to check if the internal compartments, elements or parameters have physically changed during service life. The system response is the convolution of the system impulse response with the excitation signal. This time-domain response has its equivalent response in the frequency domain. Thus, the frequency response of a time-invariant system should also remain unchanged if system parameters are unchanged. This concept can be utilized to evaluate the mechanical structure integrity as well as diagnosis of transformers and rotating machines. It is called frequency response analysis. This chapter is specifically focused on frequency response measurement and analysis of transformers.

Original languageEnglish
Title of host publicationPower Transformer Condition Monitoring and Diagnosis
PublisherInstitution of Engineering and Technology
Pages143-210
Number of pages68
ISBN (Electronic)9781785612541
DOIs
Publication statusPublished - Jan 1 2018

Keywords

  • Dirac delta function
  • Electric machines
  • Excitation signal
  • Frequency domain
  • Frequency response
  • Frequency response analysis transformers
  • Frequency response measurement
  • Frequency-domain analysis
  • Mathematical analysis
  • Mechanical structure integrity
  • Power transformers
  • Reliability
  • Rotating machines
  • Service life
  • System impulse response
  • System life
  • System parameters
  • System response
  • Time-domain response
  • Time-invariant system
  • Transformers and reactors
  • Transient response

ASJC Scopus subject areas

  • General Engineering

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