Designs of broadband unilateral finline sis mixers employing 15 µm silicon-on-insulator substrate at THz frequencies
<p style="text-align:justify;"> We present the design of two niobium singleended Superconductor-Insulator-Superconductor (SIS) mixers optimized to work in the frequency range of 600–700 GHz. A key feature of this new mixer design is the utilization of a unilateral finline taper. Thi...
Main Authors: | , , , |
---|---|
Format: | Conference item |
Published: |
National Radio Astronomy Observatory
2010
|
_version_ | 1797056701089710080 |
---|---|
author | Tan, B Yassin, G Grimes, P Jacobs, K |
author_facet | Tan, B Yassin, G Grimes, P Jacobs, K |
author_sort | Tan, B |
collection | OXFORD |
description | <p style="text-align:justify;"> We present the design of two niobium singleended Superconductor-Insulator-Superconductor (SIS) mixers optimized to work in the frequency range of 600–700 GHz. A key feature of this new mixer design is the utilization of a unilateral finline taper. This transition is significantly easier to design and simulate than the previously employed antipodal finline, and more importantly it simplifies the chip fabrication considerably since the fins do not overlap at any stage. RF power propagating in the finline is coupled to the microstrip either directly from the slotline to microstrip, or more efficiently via a coplanar waveguide (CPW). Another novel feature of our design is the fabrication of the mixer chip on a very thin silicon substrate which will be achieved using Silicon-On-Insulator (SOI) technology. This will allow easy matching of the incoming signal from the feed horn to the loaded waveguide and allows the lightweight mixer chip to be held in the E-plane of the waveguide using gold beam leads, eliminating the need for a deep groove in the waveguide wall. These new features yield a significantly shorter chip and allow wider RF bandwidth since the excitation of higher order modes in the groove has been avoided. The mixer block is extremely simple, composing a smooth-walled horn and a waveguide section without any complicated mechanical features. In this paper, we present the details of the mixer chip, including various transition sections, tuning circuits and mixer block designs, supported by electromagnetic simulations. We describe the design procedure in detail and predict the full mixer performance using the SuperMix software package. </p> |
first_indexed | 2024-03-06T19:26:20Z |
format | Conference item |
id | oxford-uuid:1bd6974a-7036-4ddd-89c5-b8c640774eeb |
institution | University of Oxford |
last_indexed | 2024-03-06T19:26:20Z |
publishDate | 2010 |
publisher | National Radio Astronomy Observatory |
record_format | dspace |
spelling | oxford-uuid:1bd6974a-7036-4ddd-89c5-b8c640774eeb2022-03-26T11:02:38ZDesigns of broadband unilateral finline sis mixers employing 15 µm silicon-on-insulator substrate at THz frequenciesConference itemhttp://purl.org/coar/resource_type/c_5794uuid:1bd6974a-7036-4ddd-89c5-b8c640774eebSymplectic Elements at OxfordNational Radio Astronomy Observatory2010Tan, BYassin, GGrimes, PJacobs, K <p style="text-align:justify;"> We present the design of two niobium singleended Superconductor-Insulator-Superconductor (SIS) mixers optimized to work in the frequency range of 600–700 GHz. A key feature of this new mixer design is the utilization of a unilateral finline taper. This transition is significantly easier to design and simulate than the previously employed antipodal finline, and more importantly it simplifies the chip fabrication considerably since the fins do not overlap at any stage. RF power propagating in the finline is coupled to the microstrip either directly from the slotline to microstrip, or more efficiently via a coplanar waveguide (CPW). Another novel feature of our design is the fabrication of the mixer chip on a very thin silicon substrate which will be achieved using Silicon-On-Insulator (SOI) technology. This will allow easy matching of the incoming signal from the feed horn to the loaded waveguide and allows the lightweight mixer chip to be held in the E-plane of the waveguide using gold beam leads, eliminating the need for a deep groove in the waveguide wall. These new features yield a significantly shorter chip and allow wider RF bandwidth since the excitation of higher order modes in the groove has been avoided. The mixer block is extremely simple, composing a smooth-walled horn and a waveguide section without any complicated mechanical features. In this paper, we present the details of the mixer chip, including various transition sections, tuning circuits and mixer block designs, supported by electromagnetic simulations. We describe the design procedure in detail and predict the full mixer performance using the SuperMix software package. </p> |
spellingShingle | Tan, B Yassin, G Grimes, P Jacobs, K Designs of broadband unilateral finline sis mixers employing 15 µm silicon-on-insulator substrate at THz frequencies |
title | Designs of broadband unilateral finline sis mixers employing 15 µm silicon-on-insulator substrate at THz frequencies |
title_full | Designs of broadband unilateral finline sis mixers employing 15 µm silicon-on-insulator substrate at THz frequencies |
title_fullStr | Designs of broadband unilateral finline sis mixers employing 15 µm silicon-on-insulator substrate at THz frequencies |
title_full_unstemmed | Designs of broadband unilateral finline sis mixers employing 15 µm silicon-on-insulator substrate at THz frequencies |
title_short | Designs of broadband unilateral finline sis mixers employing 15 µm silicon-on-insulator substrate at THz frequencies |
title_sort | designs of broadband unilateral finline sis mixers employing 15 µm silicon on insulator substrate at thz frequencies |
work_keys_str_mv | AT tanb designsofbroadbandunilateralfinlinesismixersemploying15μmsilicononinsulatorsubstrateatthzfrequencies AT yassing designsofbroadbandunilateralfinlinesismixersemploying15μmsilicononinsulatorsubstrateatthzfrequencies AT grimesp designsofbroadbandunilateralfinlinesismixersemploying15μmsilicononinsulatorsubstrateatthzfrequencies AT jacobsk designsofbroadbandunilateralfinlinesismixersemploying15μmsilicononinsulatorsubstrateatthzfrequencies |