A new time-domain method based on the general transmission-line equations

Figure 4 f versus B for ascending and descending I order of B at 77 K. Inset shows ␦ f versus B o mation can therefore serve as a guideline for microwave engineers in predicting or even circumventing the influence of an external dc magnetic field on the performance of HTS microwave filters according

## Abstract General transmission‐line equations based on the theory of differential equations [1] were introduced in [2] and [3]. The equations' dispersion characteristic of a microstrip low‐pass filter is studied. The parameters __L, C, α____, and β of general transmission‐line equations are found

The eigenvalue problem of the time-independent Schrodinger equation is solved as usual by expanding the eigenfunctions in terms of a basis set. However, the wave-function Ž . expansion coefficients WECs , which are certain matrix elements of the wave operator, are determined by an iterative method.

## Abstract We assume that Ω^__t__^ is a domain in ℝ^3^, arbitrarily (but continuously) varying for 0⩽__t__⩽__T__. We impose no conditions on smoothness or shape of Ω^__t__^. We prove the global in time existence of a weak solution of the Navier–Stokes equation with Dirichlet's homogeneous or inhom