Method and apparatus for designing an RF coil assembly
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01V-003/00
H01P-007/00
출원번호
US-0748967
(2000-12-27)
발명자
/ 주소
Tropp, James S.
출원인 / 주소
GE Medical Systems Global Technology Company, LLC
대리인 / 주소
Horton, Carl B
인용정보
피인용 횟수 :
9인용 특허 :
12
초록▼
A method and system for designing a radio frequency (RF) coil assembly is disclosed herein. The designing scheme or tool includes determining a self inductance by solving analytically or numerically two-dimensional boundary value problems s. The scheme further includes determining at least one mutua
A method and system for designing a radio frequency (RF) coil assembly is disclosed herein. The designing scheme or tool includes determining a self inductance by solving analytically or numerically two-dimensional boundary value problems s. The scheme further includes determining at least one mutual inductance by solving analytically or numerically the two-dimensional boundary value problems. The ratio of the mutual inductance and the self inductance represents a magnetic coefficient of coupling of the RF coil assembly.
대표청구항▼
A method and system for designing a radio frequency (RF) coil assembly is disclosed herein. The designing scheme or tool includes determining a self inductance by solving analytically or numerically two-dimensional boundary value problems s. The scheme further includes determining at least one mutua
A method and system for designing a radio frequency (RF) coil assembly is disclosed herein. The designing scheme or tool includes determining a self inductance by solving analytically or numerically two-dimensional boundary value problems s. The scheme further includes determining at least one mutual inductance by solving analytically or numerically the two-dimensional boundary value problems. The ratio of the mutual inductance and the self inductance represents a magnetic coefficient of coupling of the RF coil assembly. ift oscillator, comprising: at least five stages coupled between an input and an output of the oscillator, wherein each stage includes: a CMOS amplifier; and a phase shift network coupled to the CMOS amplifier, wherein the phase shift network includes an NMOS transistor coupled to the amplifier, wherein the NMOS transistor provides a variable resistor value to the network; and wherein a phase shift in each stage contributes to a total phase shift, and wherein a small phase shift is realized in each stage at a high frequency such that the at least five stages result in a high oscillation frequency. 7. The CMOS phase shift oscillator of claim 6, wherein each one of the at least five stages has a phase shift of approximately 36 degrees. 8. The CMOS phase shift oscillator of claim 6, wherein an input capacitance, Cin, for each CMOS amplifier is much smaller than a capacitance, C, in each phase shift network. 9. The CMOS phase shift oscillator of claim 6, wherein a phase shift network resistance, R, in each phase shift network is much larger than a load resistance, RL, for each CMOS amplifier. 10. A phase shift network, comprising: a number of stages coupled in series between an input and an output of the network, the output coupled to the input via a feedback line, wherein each stage includes: an amplifier, wherein the amplifier includes: an NMOS transistor; and a diode connected PMOS transistor acting as a load resistor, wherein the diode connected PMOS transistor has a low impedance, RL; and an NMOS transistor in a phase shift network, the NMOS transistor serving as a voltage variable resistor coupled to the amplifier; and wherein the amplifier provides a gain and allows a small phase shift in each stage to eventually provide a signal which is 180 degrees out of phase with the input signal. 11. The phase shift network of claim 10, wherein a gain of the amplifier is slightly greater than one (1). 12. The phase shift network of claim 10, wherein the diode connected PMOS transistor acts as a low valued load resistance expressed as RL=1/gd, wherein gd is the conductance looking back into the drain. 13. The phase shift network of claim 11, wherein an overall gain for each stage, including the amplifier and the NMOS transistor serving as the voltage variable resistor, is approximately 0.9 gm(RL) such that where gm(RL) is slightly larger than one (1) an overall gain of each stage is greater than one (1) and a condition for oscillation is satisfied. 14. The phase shift network of claim 10, wherein the number of stages includes a number of stages such that an output of the number of stages has a phase shift of 180 degrees and a gain greater than one (1). 15. The phase shift network of claim 10, wherein a frequency of oscillation, fo, for the network can be expressed as fo=n/(2×pi×pi×R×C) Hz, wherein pi=3.14 radians, wherein R is a resistance value of the NMOS transistor serving as a voltage variable resistor in the phase shift network, and wherein C is a capacitance value of the phase shift network. 16. The phase shift network of claim 10, wherein a larger number of stages results in a higher frequency of oscillation, fo, and requires a lower gain per stage. 17. The phase shift network of claim 10, wherein an output impedance of the amplifier is Zo=1/gd. 18. The phase shift network of claim 10, wherein a gain requirement for the amplifier is low and a load resistance, RL, of the diode connected PMOS transistor is small providing a low output impedance. 19. The phase shift network of claim 18, wherein the low output impedance drives a subsequent phase shift network of a next stage without significant loading effects. 20. A phase shift oscillator, comprising: a number of stages coupled in series between an input and an output of the oscillator, the output coupled to the input via a feedback line, wherein each stage includes: an amplifier, wherein the amplifier includes: an NMOS transistor; and a diode co nnected PMOS transistor acting as a load resistor, wherein the diode connected PMOS transistor has a low impedance; and an NMOS transistor serving as a voltage variable resistor coupled to the amplifier; and wherein the amplifier provides a gain and allows a small phase shift in each stage to eventually provide an output signal at the output which is 180 degrees out of phase with an input signal received at the input, and wherein an oscillation frequency, fo, for the oscillator is defined as fo=n/(2×pi×pi×R×C) Hz, wherein pi=3.14 radians, wherein R is a resistance value of the NMOS transistor serving as a voltage variable resistor, and wherein C is a capacitance value provide by the NMOS transistor serving as a voltage variable resistor. 21. The phase shift oscillator of claim 20, wherein the NMOS transistor serving as a voltage variable resistor provides a gate bias to the NMOS transistor in the amplifier. 22. The phase shift oscillator of claim 21, wherein a source region of the NMOS transistor serving as a voltage variable resistor is connected to a gate bias supply potential (VGG). 23. The phase shift oscillator of claim 20, wherein the diode connected PMOS transistor acting as a low valued load resistance has a load resistance value which can be expressed as RL=1/gd, wherein gd is the conductance looking back into the drain. 24. The phase shift oscillator of claim 20, wherein an overall gain for each stage, including the amplifier and the NMOS transistor serving as a voltage variable resistor is approximately 0.9 gm(RL) such that where gm(RL) is slightly larger than one (1) an overall gain of each stage is greater than one (1) and a condition for oscillation is satisfied. 25. The phase shift oscillator of claim 20, wherein a gain of the amplifier is slightly greater than one (1). 26. The phase shift oscillator of claim 20, wherein a tuning of the oscillator or a varying of the frequency, fo, for the oscillator is accomplished by varying a resistor value, R, for the NMOS transistor serving as a voltage variable resistor. 27. The phase shift oscillator of claim 26, wherein varying the resistor value, R, for the NMOS transistor serving as a voltage variable resistor changes the oscillation frequency (fo) such that as long as an overall gain remains greater than one (1) as the resistance value (R) varies, the phase shift oscillator will still oscillate, but at a new frequency (f1). 28. The phase shift oscillator of claim 24, wherein a larger value of R and/or C results in a smaller phase shift per stage at any particular frequency. 29. The phase shift oscillator of claim 24, wherein a total phase shift for the oscillator is fixed by the number of stages, and wherein a larger value of R will lower the frequencies of oscillation per stage. 30. The phase shift oscillator of claim 24, wherein a total phase shift for the oscillator is fixed by the number of stages, and wherein a frequency of oscillation for the oscillator can be varied by varying R for all or only some of the number of stages. 31. A phase shift circuit, comprising: a number of stages coupled in series between an input and an output of the circuit, the output coupled to the input via a feedback line, wherein each stage includes: a CMOS amplifier; and an NMOS transistor serving as a voltage variable resistor, R, coupled to the CMOS amplifier; and wherein an oscillation frequency, fo, for the circuit increases with the number of stages, and wherein the oscillation frequency increases as an R-C time constant decreases, wherein C is an input capacitance provided by the NMOS transistor. 32. The phase shift circuit of claim 31, wherein the oscillation frequency for the circuit increases as the input capacitance (C) in the circuit decreases. 33. The phase shift circuit of claim 31, wherein an increase in the input capacitance (C) of the circuit reduces the oscillation frequency, and wherein the effect of a limited value for a resistance value (R) of th e NMOS transistor serving as a voltage variable resistor is to require an increased gain for the CMOS amplifier. 34. The phase shift circuit of claim 31, wherein the number of stages is an odd number of stages. 35. The phase shift circuit of claim 31, wherein an output signal at the output of the circuit includes a total phase shift for the circuit which is 180 degrees out of phase with an input signal received at the input to the circuit, and wherein each stage of the circuit does not produce an identical phase shift. 36. The phase shift circuit of claim 35, wherein the total phase shift is divided in unequal portions for each stage of the circuit. 37. A phase shift network, comprising: a number of stages coupled in series between an input and an output of the network, the output coupled to the input via a feedback line, wherein each stage includes: a CMOS amplifier; and an NMOS transistor, serving as a voltage variable resistor, coupled to the CMOS amplifier; wherein a first number of stages have a first degree value phase shift; and wherein a second number of stages have a second degree value phase shift. 38. The phase shift network of claim 37, wherein the first number of stages having a first degree value phase shift includes three stages having a 30 degree phase shift value, and wherein the second number of stages having a second degree value phase shift includes four stages having a 22.5 degree phase shift value such that the network allows two quadrature signals to be obtained or two signals at the same frequency but with a 90 degree phase relationship. 39. The phase shift network of claim 37, wherein a resistor value, R, for the NMOS transistor serving as a voltage variable resistor in any given stage can be varied such that as the resistance value, R, for the NMOS transistor serving as a voltage variable resistor in that stage becomes larger a phase shift for that stage is increased. 40. The phase shift network of claim 39, wherein a resistor value, R, for the NMOS transistor serving as a voltage variable resistor in any given stage can be varied such that as the resistance value, R, for the given NMOS transistor serving as a voltage variable resistor in that stage is made smaller a phase shift for that stage is decreased. 41. The phase shift network of claim 37, wherein increasing a resistance value, R1, for a given NMOS transistor serving as a voltage variable resistor in one stage and decreasing a resistance value, R2, for another given NMOS transistor serving as a voltage variable resistor in another stage maintains an overall phase shift and oscillation frequency for the network. 42. The phase shift network of claim 37, wherein the phase shift network produces a phase modulated signal for a communication system. 43. The phase shift network of claim 37, wherein the phase shift network produces a phase modulated signal for a digital integrated circuit. 44. The phase shift network of claim 37, wherein the phase shift network produces a phase modulated signal for a timing circuit. 45. The phase shift network of claim 37, wherein the phase shift network produces a phase modulated signal for a signal and clock recovery circuit. 46. The phase shift network of claim 37, wherein an oscillation frequency can be increased unlike conventional inverter ring oscillators by increasing the number of stages. 47. The phase shift network of claim 37, wherein each stage has a small gain and phase shift. 48. The phase shift network of claim 37, wherein a phase shift in each stage can be controlled by an externally applied voltage. 49. A phase shift network, comprising: a number of stages coupled in series between an input and an output of the network, the output coupled to the input via a feedback line, wherein each stage includes: an amplifier; and an NMOS transistor coupled to the amplifier, wherein the NMOS transistor provides a variable resistor value to the network; and wherein the amplifier provides a gain a nd allows a small phase shift in each stage to eventually provide a signal which is 180 degrees out of phase with the input signal. 50. The phase shift network of claim 49, wherein the amplifier includes an NMOS transistor and a diode connected PMOS transistor coupled thereto, wherein the diode connected PMOS transistor acts as a low valued load resistance expressed as RL=1/gd, wherein gd is the conductance looking back into the drain. 51. The phase shift network of claim 50, wherein the variable resistor value of the NMOS transistor in the phase shift network is much larger than the low valued load resistance of the amplifier. 52. The phase shift network of claim 50, wherein a gain of the amplifier is slightly greater than one (1). 53. The phase shift network of claim 50, wherein an overall gain for each stage, including the amplifier and the NMOS transistor, is approximately 0.9 gm(RL) such that where gm(RL) is slightly larger than one (1) an overall gain of each stage is greater than one (1) and a condition for oscillation is satisfied. 54. The phase shift network of claim 49, wherein the number of stages includes an odd number of stages such that a phase shift in successive stages generates an unstable feedback circuit. 55. The phase shift network of claim 49, wherein the number of stages includes an odd number of stages such that an output signal at the output of the number of stages has a phase shift of 180 degrees from an input signal received at the input and has a gain greater than one (1). 56. The phase shift network of claim 49, wherein a frequency of oscillation for the network can be expressed as fo=n/(2×pi×pi×R×C) Hz, wherein pi=3.14 radians, wherein R is a resistance value of the NMOS transistor serving as a voltage variable resistor, and wherein C is a capacitance value provide by the NMOS transistor serving as a voltage variable resistor. 57. The phase shift network of claim 49, wherein a larger number of stages results in a higher frequency of oscillation for the network and requires a lower gain per stage. 58. The phase shift network of claim 49, wherein an output impedance of the amplifier is Zo=1/gd. 59. The phase shift network of claim 49, wherein an input capacitance, Cin, of the amplifier is much smaller than a capacitance value provide by the NMOS transistor serving as a voltage variable resistor. 60. A method of forming a CMOS phase shift oscillator, comprising: forming a number of stages coupled in series between an input and an output of the oscillator, wherein the output is coupled to the input via a feedback line, and wherein forming each stage includes: forming a CMOS amplifier; and forming a phase shift network coupled to the CMOS amplifier, wherein forming the phase shift network includes forming an NMOS transistor coupled to the amplifier such that the NMOS transistor provides a variable resistor value to the network; and wherein forming the CMOS amplifier includes forming a CMOS amplifier which provides a gain and allows a small phase shift in each stage to provide an output signal at the output which is 180 degrees out of phase with an input signal received at the input of the oscillator. 61. The method of claim 60, wherein forming the oscillator includes forming any odd number of stages of the CMOS amplifier and phase shift networks connected in series. 62. The method of claim 60, wherein forming the CMOS phase shift oscillator includes forming a CMOS phase shift oscillator which provides an output signal at the output without the use of any L-C circuits. 63. The method of claim 60, wherein forming the CMOS phase shift oscillator includes forming a CMOS phase shift oscillator which provides an output signal at the output without the use of resonance. 64. The method of claim 60, wherein forming the CMOS phase shift oscillator includes forming a CMOS phase shift oscillator which provides an output signal at the output without utilizing a signal delay. 65. A method of forming a CMOS phase shift oscillator, comprising: forming at least five stages coupled in series between an input and an output of the oscillator, wherein the output is coupled to the input via a feedback line, and wherein forming each stage includes: forming a CMOS amplifier; and forming a phase shift network coupled to the CMOS amplifier, wherein forming the phase shift network includes forming an NMOS transistor coupled to the amplifier such that the NMOS transistor provides a variable resistor value to the network; and wherein forming each stage includes forming each stage such that a phase shift in each stage contributes to a total phase shift, and wherein a small phase shift is realized in each stage at a high frequency such that the at least five stages result in a high oscillation frequency. 66. The method of claim 65, wherein forming each one of the at least five stages includes forming each stage to have a phase shift of approximately 36 degrees. 67. The method of claim 65, wherein forming each CMOS amplifier includes forming each CMOS amplifier to have an input capacitance, Cin, which is much smaller than a capacitance, C, in each phase shift network. 68. The method of claim 65, wherein forming each phase shift network includes forming each phase shift network to have a resistance, R, which is much larger than a load resistance, RL, for each CMOS amplifier. 69. A method of forming a phase shift network, comprising: forming a number of stages coupled in series between an input and an output of the oscillator, wherein the output is coupled to the input via a feedback line, wherein forming each stage includes: forming an amplifier, wherein forming the amplifier includes: forming an NMOS transistor; and forming a diode connected PMOS transistor coupled at a drain region to the NMOS transistor and acting as a load resistor, wherein the diode connected PMOS transistor has a low impedance, RL; and forming a phase shift device coupled to the amplifier; and wherein forming the amplifier includes forming an amplifier which provides a gain and allows a small phase shift in each stage to eventually provide an output signal at the output which is 180 degrees out of phase with an input signal received at the input. 70. The method of claim 69, wherein forming the diode connected PMOS transistor includes forming a diode connected PMOS transistor which acts as a low valued load resistance expressed as RL=1/gd, wherein gd is the conductance looking back into the drain. 71. The method of claim 69, wherein forming the amplifier includes forming an amplifier in which a gain of the amplifier is slightly greater than one (1). 72. The method of claim 70, wherein forming the number of stages includes forming a number of stages in which an overall gain for each stage, including the amplifier and the phase shift device, is approximately 0.9 gm(RL) such that where grn(RL) is slightly larger than one (1) an overall gain of each stage is greater than one (1) and a condition for oscillation is satisfied. 73. The method of claim 69, wherein the forming the phase shift network includes forming a phase shift network in which a frequency of oscillation, fo, for the network can be expressed as fo=n/(2×pi×pi×R×C) Hz, wherein pi=3.14 radians, wherein R is a resistance value of the phase shift device, and wherein C is a capacitance value provide by the phase shift device. 74. The method of claim 69, wherein forming the phase shift network includes forming a phase shift network in which a larger number of stages results in a higher frequency of oscillation for the network and requires a lower gain per stage. 75. The method of claim 69, wherein forming the phase shift network includes forming a phase shift network in which an output impedance of the amplifier is Zo =1/gd. 76. The method of claim 69, wherein forming the phase shift network includes forming a phase shift network in which a gain requirement is low and a load resistance of the diode connected PMOS transistor is small providing a low output impedance. 77. The method of claim 76, wherein providing the low output impedance includes driving a subsequent phase shift network of a next stage without significant loading effects. 78. A method of operating a voltage controlled phase shift oscillator, wherein the oscillator includes a number of stages having an amplifier and a phase shift network coupled to the amplifier, wherein each amplifier includes an NMOS transistor and a diode connected PMOS transistor acting as a load resistor with a low impedance, comprising: controlling phase shift by an externally applied voltage; and wherein controlling phase shift by an externally applied voltage includes using an NMOS transistor in the phase shift network as a voltage variable resistor having a resistance which is larger than the load resistance of the diode connected PMOS transistor of the amplifier. 79. The method of claim 78, wherein using an NMOS transistor in the phase shift network as a voltage variable resistor includes using an NMOS transistor having a drain coupled to a gate of the NMOS transistor in the amplifier and having a source coupled to a gate bias supply potential, VGG, in order to provide a gate bias to the NMOS transistor in the amplifier. 80. A method of operating a voltage controlled phase shift oscillator, wherein the oscillator includes a number of stages each having an amplifier and a phase shift device coupled to the amplifier, wherein each amplifier includes an NMOS transistor and a diode connected PMOS transistor acting as a load resistor with a low impedance, comprising: increasing an oscillation frequency (fo) of the circuit by increasing the number of stages; and wherein increasing the oscillation frequency (fo) of the circuit by increasing the number of stages includes using an amplifier having an input capacitance, Cin, which is much smaller than a capacitance, C, in the phase shift device. 81. The method of claim 80, wherein the method further includes: controlling a phase shift in each stage by an externally applied voltage; and wherein controlling the phase shift in each stage by an externally applied voltage includes using an NMOS transistor as the phase shift device, the NMOS transistor acting as a voltage variable resistor having a resistance, R, which is larger than the load resistance, RL, of the diode connected PMOS transistor of the amplifier. 82. A method of operating a phase shift circuit, wherein the phase shift circuit includes a number of stages, each stage having an amplifier and a phase shift network coupled to the amplifier, wherein each amplifier includes an NMOS transistor and a diode connected PMOS transistor acting as a load resistor with a low impedance, comprising: controlling an oscillation frequency (fo) of the circuit by controlling a variable resistor value of an NMOS transistor in the phase shift network of any given stage; and controlling a phase shift in any given stage by an externally applied voltage. 83. The method of claim 82, wherein controlling the phase shift in any given stage by an externally applied voltage includes using an NMOS transistor in the phase shift network, the NMOS transistor acting as a voltage variable resistor having a resistance, R, which is larger than the load resistance, RL, of the diode connected PMOS transistor of the amplifier. 84. The method of claim 82, wherein the method further includes increasing an oscillation frequency (fo) of the circuit by increasing the number of stages. ctric material in the tunable dielectric device. A second capacitor, second charging circuit, and second switch can be used to provide voltage to the tunable dielectric device during charging or discharging of the first capacitor. The method for providing a control voltage for tunable dielectric devices performed by these circuits is also included.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (12)
Bridges James F. (St. Charles IL), Cavity resonator with improved magnetic field uniformity for high frequency operation and reduced dielectric heating in.
Tropp James S. (Berkeley CA), Method of correcting an asymmetry in an NMR radio frequency coil and an improved radio frequency coil having N-fold symm.
Corbeil, James; Ladebeck, Ralf; Stocker, Stefan, Method for electromagnetic shielding for a magnetic resonance system and correspondingly shielded device.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.