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The broadband metamaterial termination for use in planar superconducting transmission lines has been successfully demonstrated in CLASS circuit structures as an effective termination. This metamaterial implementation is fully compatible with microfabrication techniques commonly used for microwave circuitry, and its response is insensitive to geometric tolerances, material properties, and interface details of conductive elements in device fabrication. In the context of far-infrared imaging, polarimetric, and superconducting integral field unit (IFU) spectrometer arrays for astrophysics, this strategy leads to higher performance, increased device yield, and greater overall circuit density. The metamaterial termination achieves a broadband absorption response with lower reflectance in a smaller physical footprint compared to existing adiabatic structures. This absorption response demonstrates significantly lower sensitivity to fabrication tolerances, material properties, and modeling assumptions than previous designs. These characteristics are critical for cryogenic applications, but the termination can also enhance the performance of room-temperature planar transmission line structures used in microwave engineering. The termination is realized as a lossy stepped impedance transition between Nb and PdAu, which reduces the total meander length, device footprint, and sensitivity to detailed implementation. This broadband metamaterial termination is applicable in superconducting technologies, including quantum communications, computing, and sensors. It has reached Technology Readiness Level (TRL) 7 (technology demonstrated in an operational environment) and is now available for patent licensing.