Thin-Film Absorbing Elements of Adapter-Attenuators for HICs.

One of the urgent tasks in the design of hybrid integrated circuits (HICs) is the construction of adapter-attenuators of film absorbing elements that provide a wide range of attenuations with the given values of input and output resistances. Known versions of adapter-attenuators based on homogeneous and piecewise-homogeneous resistive films provide a resistance transformation ratio of not more than 3 and 10–12, respectively. The paper proposes promising topologies of adapter-attenuators for HICs with an almost optimal profile of the input and output contacts. It is shown that these topologies make it possible not only to obtain a wide range of transformation ratios (more than 100) but also to reduce the maximum values of the potential gradient and power density by a factor of 10 to 30. When calculating the rectangular topology, the apparatus of the theory of functions of a complex variable is used. The optimized topology of adapter-attenuators for HICs is modeled by the finite element method implemented in the Elcut software package. The calculated ratios and graphs that show the relationship between attenuation, the transformation ratio, gain in the potential gradient, and power density depending on the ratio of the dimensions of the film element and the specific resistances of the resistive films used are presented. The features of fitting adapter-attenuators are considered. The results obtained are important for the operation of the film element of adapter-attenuators for well logging in the pulsed mode. [ABSTRACT FROM AUTHOR]