Abstract: Miniature slow-wave transmission lines are described having an asymmetrical ground configuration. In some embodiments, the asymmetrical ground configuration facilitates a reduction in size. Non-uniform auxiliary conductors may be disposed above or below the co-planar waveguide to facilitate a reduction in the length of the miniature slow-wave transmission lines. Phase shifters may be implemented having a reduced size by including one or more miniature slow-wave transmission lines.

Abstract: An electrical circuit can be formed at least in part using lumped or discrete circuit elements to provide an artificial transmission line structure that can mimic the electrical properties of a corresponding actual transmission line structure. Such an artificial transmission line structure can generally consume less area than an actual transmission line structure lacking such lumped or discrete elements. Such an artificial transmission line structure can be formed using two or more “unit cells” such as by cascading such cells as shown and described herein. The present inventors have recognized, among other things, that a unit cell of an artificial transmission line structure can include a t-coil section comprising magnetically-coupled inductors. Such an artificial transmission line structure can be used for applications such as phase shifting or to provide a delay line having a substantially constant group delay, among other applications.

Abstract: An electrical circuit can be formed at least in part using lumped or discrete circuit elements to provide an artificial transmission line structure that can mimic the electrical properties of a corresponding actual transmission line structure. Such an artificial transmission line structure can generally consume less area than an actual transmission line structure lac0ure can be formed using two or more “unit cells” such as by cascading such cells as shown and described herein. The present inventors have recognized, among other things, that a unit cell of an artificial transmission line structure can include a t-coil section comprising magnetically-coupled inductors. Such an artificial transmission line structure can be used for applications such as phase shifting or to provide a delay line having a substantially constant group delay, among other applications.

Abstract: An electronic circuit can include a gain adjustment circuit (e.g., a gain “equalizer” circuit), such as to compensate for a variation in insertion loss over a specified range of frequencies. For example, such a gain adjustment circuit can provide an insertion loss characteristic having a specified slope. Such a slope can include a positive slope where insertion loss increases with respect to frequency, or a negative slope where insertion loss decreases with respect to frequency, as illustrative examples. A gain equalization technique can be used to compensate for variation in insertion loss versus frequency between different circuit paths, such as in relation to a switchable delay line having two or more selectable paths, such as for phase shifting applications. A gain adjustment circuit can be configured to provide relatively flat or constant time-domain delay versus frequency, such as inhibiting or reducing dispersion.

Abstract: Miniature slow-wave transmission lines are described having an asymmetrical ground configuration. In some embodiments, the asymmetrical ground configuration facilitates a reduction in size. Non-uniform auxiliary conductors may be disposed above or below the co-planar waveguide to facilitate a reduction in the length of the miniature slow-wave transmission lines. Phase shifters may be implemented having a reduced size by including one or more miniature slow-wave transmission lines.

Abstract: A power divider/combiner circuit with coupled inductors is provided. With coupled inductors, the new circuit topology exhibits broader bandwidth for insertion loss, port matching and isolation compared with traditional power divider/combiner circuit topologies. The coupled inductors can be implemented for single-stage low-pass networks, multi-stage low-pass networks, or multi-stage wide-band networks. For example, the power divider/combiner circuit includes a first coupled inductor circuit coupled to an input terminal that provides a first signal path to a first output terminal, and a second coupled inductor circuit coupled to the input terminal that provides a second signal path to a second output terminal. Each of the coupled inductor circuits include multiple inductors that are tightly and positively magnetically coupled to one another.

Abstract: A power divider/combiner circuit with coupled inductors is provided. With coupled inductors, the new circuit topology exhibits broader bandwidth for insertion loss, port matching and isolation compared with traditional power divider/combiner circuit topologies. The coupled inductors can be implemented for single-stage low-pass networks, multi-stage low-pass networks, or multi-stage wide-band networks. For example, the power divider/combiner circuit includes a first coupled inductor circuit coupled to an input terminal that provides a first signal path to a first output terminal, and a second coupled inductor circuit coupled to the input terminal that provides a second signal path to a second output terminal. Each of the coupled inductor circuits include multiple inductors that are tightly and positively magnetically coupled to one another.