lc circuit Search Results


lc tuning circuit  (Magritek Ltd)
90
Magritek Ltd lc tuning circuit
Expanded schematic of the <t>homebuilt</t> 9.81 GHz TE102 resonant microwave cavity. The screw holes and shim coils are not shown for clarity. Panel (A) shows the configuration for a fixed resonant frequency, suitable if the magnetic field can be varied. Panel (B) shows the changes required for a variable resonance frequency cavity, if hyperpolarization in a fixed magnetic field is desired. The variable-frequency short is placed inside the waveguide extension, which then replaces the fixed-frequency short present in (A). The rest of the pieces are unchanged. Panel (C) gives the dimensions for the cylindrical portion of the variable-frequency short. The ¼-32 threads on the cylindrical portion and the threaded hole in the attached plate allow for rotation of the cylindrical portion against the plate to adjust the position of the short inside the waveguide extension, thereby changing the length and frequency of the cavity.
Lc Tuning Circuit, supplied by Magritek Ltd, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/lc tuning circuit/product/Magritek Ltd
Average 90 stars, based on 1 article reviews
lc tuning circuit - by Bioz Stars, 2026-04
90/100 stars
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lc resonant circuits  (Keysight Technologies)
90
Keysight Technologies lc resonant circuits
Expanded schematic of the <t>homebuilt</t> 9.81 GHz TE102 resonant microwave cavity. The screw holes and shim coils are not shown for clarity. Panel (A) shows the configuration for a fixed resonant frequency, suitable if the magnetic field can be varied. Panel (B) shows the changes required for a variable resonance frequency cavity, if hyperpolarization in a fixed magnetic field is desired. The variable-frequency short is placed inside the waveguide extension, which then replaces the fixed-frequency short present in (A). The rest of the pieces are unchanged. Panel (C) gives the dimensions for the cylindrical portion of the variable-frequency short. The ¼-32 threads on the cylindrical portion and the threaded hole in the attached plate allow for rotation of the cylindrical portion against the plate to adjust the position of the short inside the waveguide extension, thereby changing the length and frequency of the cavity.
Lc Resonant Circuits, supplied by Keysight Technologies, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/lc resonant circuits/product/Keysight Technologies
Average 90 stars, based on 1 article reviews
lc resonant circuits - by Bioz Stars, 2026-04
90/100 stars
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integrated superconducting lc circuit  (National Institute of Standards and Technology)
90
National Institute of Standards and Technology integrated superconducting lc circuit
Expanded schematic of the <t>homebuilt</t> 9.81 GHz TE102 resonant microwave cavity. The screw holes and shim coils are not shown for clarity. Panel (A) shows the configuration for a fixed resonant frequency, suitable if the magnetic field can be varied. Panel (B) shows the changes required for a variable resonance frequency cavity, if hyperpolarization in a fixed magnetic field is desired. The variable-frequency short is placed inside the waveguide extension, which then replaces the fixed-frequency short present in (A). The rest of the pieces are unchanged. Panel (C) gives the dimensions for the cylindrical portion of the variable-frequency short. The ¼-32 threads on the cylindrical portion and the threaded hole in the attached plate allow for rotation of the cylindrical portion against the plate to adjust the position of the short inside the waveguide extension, thereby changing the length and frequency of the cavity.
Integrated Superconducting Lc Circuit, supplied by National Institute of Standards and Technology, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/integrated superconducting lc circuit/product/National Institute of Standards and Technology
Average 90 stars, based on 1 article reviews
integrated superconducting lc circuit - by Bioz Stars, 2026-04
90/100 stars
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lc tank circuit  (Coilcraft Inc)
90
Coilcraft Inc lc tank circuit
Expanded schematic of the <t>homebuilt</t> 9.81 GHz TE102 resonant microwave cavity. The screw holes and shim coils are not shown for clarity. Panel (A) shows the configuration for a fixed resonant frequency, suitable if the magnetic field can be varied. Panel (B) shows the changes required for a variable resonance frequency cavity, if hyperpolarization in a fixed magnetic field is desired. The variable-frequency short is placed inside the waveguide extension, which then replaces the fixed-frequency short present in (A). The rest of the pieces are unchanged. Panel (C) gives the dimensions for the cylindrical portion of the variable-frequency short. The ¼-32 threads on the cylindrical portion and the threaded hole in the attached plate allow for rotation of the cylindrical portion against the plate to adjust the position of the short inside the waveguide extension, thereby changing the length and frequency of the cavity.
Lc Tank Circuit, supplied by Coilcraft Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/lc tank circuit/product/Coilcraft Inc
Average 90 stars, based on 1 article reviews
lc tank circuit - by Bioz Stars, 2026-04
90/100 stars
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passive inductor-capacitor (lc) resonator circuits  (CardioMEMS Inc)
90
CardioMEMS Inc passive inductor-capacitor (lc) resonator circuits
Expanded schematic of the <t>homebuilt</t> 9.81 GHz TE102 resonant microwave cavity. The screw holes and shim coils are not shown for clarity. Panel (A) shows the configuration for a fixed resonant frequency, suitable if the magnetic field can be varied. Panel (B) shows the changes required for a variable resonance frequency cavity, if hyperpolarization in a fixed magnetic field is desired. The variable-frequency short is placed inside the waveguide extension, which then replaces the fixed-frequency short present in (A). The rest of the pieces are unchanged. Panel (C) gives the dimensions for the cylindrical portion of the variable-frequency short. The ¼-32 threads on the cylindrical portion and the threaded hole in the attached plate allow for rotation of the cylindrical portion against the plate to adjust the position of the short inside the waveguide extension, thereby changing the length and frequency of the cavity.
Passive Inductor Capacitor (Lc) Resonator Circuits, supplied by CardioMEMS Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/passive inductor-capacitor (lc) resonator circuits/product/CardioMEMS Inc
Average 90 stars, based on 1 article reviews
passive inductor-capacitor (lc) resonator circuits - by Bioz Stars, 2026-04
90/100 stars
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Image Search Results


Expanded schematic of the homebuilt 9.81 GHz TE102 resonant microwave cavity. The screw holes and shim coils are not shown for clarity. Panel (A) shows the configuration for a fixed resonant frequency, suitable if the magnetic field can be varied. Panel (B) shows the changes required for a variable resonance frequency cavity, if hyperpolarization in a fixed magnetic field is desired. The variable-frequency short is placed inside the waveguide extension, which then replaces the fixed-frequency short present in (A). The rest of the pieces are unchanged. Panel (C) gives the dimensions for the cylindrical portion of the variable-frequency short. The ¼-32 threads on the cylindrical portion and the threaded hole in the attached plate allow for rotation of the cylindrical portion against the plate to adjust the position of the short inside the waveguide extension, thereby changing the length and frequency of the cavity.

Journal: Journal of magnetic resonance (San Diego, Calif. : 1997)

Article Title: Continuous flow Overhauser dynamic nuclear polarization of water in the fringe field of a clinical magnetic resonance imaging system for authentic image contrast

doi: 10.1016/j.jmr.2010.05.008

Figure Lengend Snippet: Expanded schematic of the homebuilt 9.81 GHz TE102 resonant microwave cavity. The screw holes and shim coils are not shown for clarity. Panel (A) shows the configuration for a fixed resonant frequency, suitable if the magnetic field can be varied. Panel (B) shows the changes required for a variable resonance frequency cavity, if hyperpolarization in a fixed magnetic field is desired. The variable-frequency short is placed inside the waveguide extension, which then replaces the fixed-frequency short present in (A). The rest of the pieces are unchanged. Panel (C) gives the dimensions for the cylindrical portion of the variable-frequency short. The ¼-32 threads on the cylindrical portion and the threaded hole in the attached plate allow for rotation of the cylindrical portion against the plate to adjust the position of the short inside the waveguide extension, thereby changing the length and frequency of the cavity.

Article Snippet: The RF coil was connected to a homebuilt LC tuning circuit then a Kea NMR spectrometer (Magritek Ltd., New Zealand) and external RF amplifier (BT00250-Beta, Tomco Technologies, Australia), as shown in .

Techniques: