Junctions of waveguides with capacitance gap

Figure 4 Reflection coefficient for the vertical polarization. ᎏᎏ: experimental results, `````: numerical results Figure 5 Reflection coefficient for the horizontal polarization. ᎏᎏ: experimental results, `````: numerical results The good agreement between the numerical and experimental results val

## Abstract The domain‐product technique is applied to modeling of H‐ and E‐plane loaded waveguide junctions with a rectangular connecting cavity. A specific use of the edge condition accelerates the convergence of the solution. Very high efficiency of the technique is demonstrated by the example o

## Abstract Gap junctions are specialized transmembrane channels that allow rapid electrical signalling and direct intercellular communication for maintenance and coordination of normal cellular activities and homeostasis. Although gap junction channels in the nervous system mediate intercellular c

## Abstract By the use of a simple, rapid method for the isolation of gap junctions from small amounts of rat liver (2–3 g), we have followed the incorporation of the radiolabeled amino acid precursors ^3^H‐leucine and ^35^S‐methionine into the gap junction protein. In timed studies with ^35^S‐meth

## Abstract In this letter, the capacitance of a conductor‐backed coplanar waveguide (CPW) with an upper shielding is investigated.An electrostatic boundary‐value problem of the conductor‐backed CPW with an upper shielding is solved using the Fourier transform, mode matching technique, and superpos

## Abstract Gap junctions are intercellular channels that allow the passage of water, ions, and small molecules. They are involved in quick, short‐range messaging between cells and are found in skin, nervous tissue, heart, and muscle. An increasing number of hereditary skin disorders appear to be c