Abstract
It is often more complicated to measure the phase response of a large system than the magnitude. In that case, one can attempt to use the Kramers-Kronig (KK) relations for magnitude and phase, which relates magnitude and phase analytically. The advantage is that then only the magnitude of the frequency response needs to be measured. We show that the KK relations for magnitude and phase may yield invalid results when the transfer function has zeros located in the right half of the complex s-plane, i.e. the system is non-minimum phase. In this paper we propose a method which enables to determine these zeros, by using specific excitation signals and measuring the resulting time responses of the system. The method is verified using blind tests among the authors. When the locations of the zeros in the right half of the complex s-plane are known, modified KK relations can be successfully applied to non-minimum phase systems. We demonstrate this by computing the phase response of the electric field, excited by a point dipole source inside a closed cavity with Perfect Electrically Conducting (PEC) walls. Also, the effects of simulated measurement noise are considered for this example.
Highlights
The frequency response of a system is an important property to define the relation between the input and output and is used for characterizing and designing systems
The electromagnetic field inside a Perfect Electrically Conducting (PEC) cavity is efficiently modelled using an eigenmode expansion when the EM fields can be sufficiently well approximated using a reasonable number of modes
If only the magnitude of the transfer function is known, the KK relations may be used to reconstruct the phase from the magnitude
Summary
The frequency response of a system is an important property to define the relation between the input and output and is used for characterizing and designing systems. The phase information is required to accurately reconstruct the time response of the electric field inside the ship when a (N)EMP threat is simulated. We propose a method which enables us to accurately estimate the locations of the zeros in the right half of the s-plane This is done using specific excitation signals and calculating the time responses of the system. After using our new zero-search method to precisely locate the zeros, we successfully reconstruct the phase from the measured magnitude of the frequency response using modified KK relations. It is concluded with a successful application of modified KK relations to the cavity model from Section 2.
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