US2009079432A1PendingUtilityA1
Transceive surface coil array for magnetic resonance imaging and spectroscopy
Est. expiryMar 19, 2024(expired)· nominal 20-yr term from priority
G01R 33/3415G01R 33/34046G01R 33/365
36
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Claims
Abstract
A surface coil array comprises a surface coil support and an arrangement of non-overlapping magnetically decoupled surface coils mounted on the support. The surface coils encompass a volume into which a target to be imaged is placed. Magnetic decoupling circuits act between adjacent surface coils. Impedance matching circuitry couples the surface coils to conventional transmit and receive components.
Claims
exact text as granted — not AI-modified1 . A transceive surface coil array comprising:
a plurality of spaced surface coils arranged about a volume, each surface coil transmitting input transmit signals and receiving incoming receive signals; and magnetic decoupling circuits acting between and magnetically decoupling said surface coils, said magnetic decoupling circuits being electrically connected in parallel with said surface coils.
2 . A transceive surface coil array according to claim 1 wherein magnetic decoupling circuits act between adjacent surface coils.
3 . A transceive surface coil array according to claim 2 wherein said magnetic decoupling circuits are purely capacitive.
4 . A transceive surface coil array according to claim 3 wherein the capacitive reactance of each magnetic decoupling circuit is equal to the mutual inductive reactance between adjacent surface coils.
5 . A transceive surface coil array according to claim 4 wherein each magnetic decoupling circuit comprises a single capacitor.
6 . A transceive surface coil array according to claim 4 wherein said surface coils are generally equally spaced about said volume.
7 . A transceive surface coil array according to claim 5 further comprising a dielectric support on which said surface coils are mounted.
8 . A transceive surface coil array according to claim 7 further comprising dielectric loss reducing elements distributed about said surface coils.
9 . A transceive surface coil array according to claim 8 wherein said dielectric loss reducing elements are low-loss lumped capacitors.
10 . A transceive surface coil array according to claim 4 further comprising baluns coupled to said surface coils.
11 . A transceive surface coil array according to claim 10 wherein said baluns are impedance matched to feed network circuitry coupled thereto.
12 . A transceive surface coil array according to claim 11 wherein said baluns are impedance matched to 50Ω component-based feed network circuitry.
13 . A transceive surface coil array according to claim 10 further comprising a feed network coupled to said baluns and communicating with said surface coils.
14 . A transceive surface coil array according to claim 13 wherein said baluns are balanced and impedance matched to said feed network.
15 . A transceive surface coil array according to claim 14 wherein said feed network comprises transmit and receive components.
16 . A transceive surface coil array according to claim 15 wherein said transmit and receive components comprise 50Ω preamplifiers and low cost radio frequency (RF) power amplifiers.
17 . A transceive surface coil array according to claim 16 wherein said feed network further comprises a 50Ω coaxial cable connecting said baluns to said feed network.
18 . A transceive surface coil array according to claim 13 wherein said baluns are configured to provide transmit signals generated by said feed network to said surface coils for transmit operation and to provide receive signals received by said surface coils to said feed network for receive operation.
19 . A transceive surface coil array according to claim 18 wherein said feed network comprises transmit and receive components.
20 . A transceive surface coil array according to claim 19 wherein said transmit and receive components comprise 50Ω preamplifiers and low cost RF power amplifiers.
21 . A transceive surface coil array according to claim 13 wherein said baluns are configured to condition said surface coil array to a receive-only mode, in said receive-only mode, said baluns isolating said surface coils from said feed network when said feed network generates transmit signals.
22 . A transceive surface coil array according to claim 21 wherein said feed network comprises transmit and receive components.
23 . A transceive surface coil array according to claim 22 wherein said transmit and receive components comprise 50Ω preamplifiers and low cost power amplifiers.
24 . A transceive surface coil array according to claim 4 wherein a magnetic decoupling circuit acts between each adjacent pair of surface coils.
25 . A transceive surface coil array according to claim 4 wherein said surface coils are arranged in sets, magnetic decoupling circuits acting between adjacent pairs of surface coils in each set.
26 . A transceive surface coil array according to claim 11 wherein said feed network circuitry includes a separate low power transmitter for each surface coil.
27 . A transceive surface coil array according to claim 18 wherein said feed network includes a separate low power transmitter for each surface coil.
28 . A transceive surface coil array according to claim 11 wherein receive signals received by said surface coils bypass said feed network circuitry.
29 . A transceive surface coil array comprising:
a surface coil support; a plurality of generally evenly spaced surface coils mounted on said support and surrounding a volume into which a target to be imaged is placed, each surface coil transmitting input transmit signals and receiving incoming receive signals; and capacitive decoupling circuitry acting between and magnetically decoupling said surface coils to inhibit magnetic coil-to-coil coupling, said capacitive decoupling circuitry being electrically connected in parallel with said surface coils.
30 . A transceive surface coil array according to claim 29 further comprising a feed network and impedance matching circuitry acting between said feed network and each of said surface coils.
31 . A transceive surface coil array according to claim 30 wherein said feed network comprises transmit and receive components.
32 . A transceive surface coil array according to claim 31 wherein said transmit and receive components comprise 50Ω preamplifiers and low cost RF power amplifiers.
33 . A transceive surface coil array according to claim 31 wherein said impedance matching circuitry is configured to provide transmit signals generated by said feed network to said surface coils for transmit operation and to provide receive signals received by said surface coils to said feed network for receive operation.
34 . A transceive surface coil array according to claim 33 wherein said transmit and receive components comprise 50Ω preamplifiers and low cost RF power amplifiers.
35 . A transceive surface coil array according to claim 30 wherein said impedance matching circuitry comprising a λ/4 lattice balun associated with each surface coil.
36 . An RF resonator comprising:
a surface coil array including an arrangement of non-overlapping magnetically decoupled surface coils encompassing a volume and a capacitive circuit between each pair of surface coils, each capacitive circuit being electrically connected in parallel with the associated pair of surface coils, each surface coil transmitting input transmit signals and receiving incoming receive signals; and a feed network coupled to said surface coil array, said feed network receiving signals received by said surface coils during imaging of a target within said volume.
37 . An RF resonator according to claim 36 wherein said feed network comprises 50Ω transmit and receive components.
38 . An RF resonator according to claim 37 wherein said surface coil array comprising impedance matching circuitry acting between each surface coil and said feed network.
39 . An RF resonator according to claim 38 wherein said feed network provides transmit signals to said surface coils via said impedance matching circuitry.
40 . A transceive surface coil array comprising:
a surface coil support; an arrangement of non-overlapping magnetically decoupled surface coils mounted on said support and encompassing a volume into which a target to be imaged is placed, each surface coil transmitting input transmit signals and receiving incoming receive signals; and a capacitive circuit between adjacent surface coils, each capacitive circuit being electrically connected in parallel with the associated adjacent surface coils.
41 . A transceive surface coil array according to claim 40 wherein each of said surface coils is generally identical.
42 . A transceive surface coil array according to claim 41 wherein said surface coils are of varying shape and/or size.
43 . A transceive surface coil array according to claim 42 wherein said surface coils are grouped into sets, the surface coils in each set being magnetically decoupled independent of other sets.
44 . A transceive surface coil array according to claim 43 wherein said surface coils receive transmit signals from at least one radio frequency transmitter.
45 . A transceive surface coil array according to claim 44 wherein said surface coils receive transmit signals from a single transmitter.
46 . A transceive surface coil array according to claim 45 wherein each surface coil receives transmit signals from an associated transmitter.Cited by (0)
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