The generation of strong and homogeneous magnetic fields is of great interest in many technical applications. In particular, it is very important for clinical magnetic resonance imaging (MRI). Many of the early magnet designs were based on the work of Garrett [1,2]. The central uniformity of symmetrical fields was analyzed by a spherical harmonic expansion. There is only a small body of literature available on the design of superconducting main magnets for these systems. In recent years, there has been an increasing interest in optimal design of clinical MRI magnets. Pissanetzky [3] has proposed an approach to field design based on a hybrid methodology incorporating ideas from finite elements, analytical techniques, and other numerical methods. Thompson [4] has illustrated a method based on a variational approach with constraints introduced by Lagrange multipliers. The analytical aspects of variational calculus were combined with numerical techniques to obtain optimal spatial coil distributions. Crozier [5] has introduced a stochastic optimization technique that was successfully used to design compact MRI magnets. Zhao [6, 7, 8] has used an inverse approach to formulating a continuous function space for solution and then used integration relationships to define a kernel matrix linear equation. The problem has then been solved as a nonlinear optimization.
In general, the design of a superconducting MRI magnet requires the consideration of various parameters. These include: central magnetic field strength, spatial homogeneity, peak field in the superconductors, size of stray field, stress in the superconductor coil, geometrical constraints, weight and cost. For clinical imaging, these constraints include:
The challenge in designing a high field compact magnet is the retention of high homogeneity conditions over the imaging volume while maintaining all the other requirements. As magnet performance is strongly dependent on the overall length and the inner diameter of the coil structure, the shorter the length and the larger the inner diameter of the magnet, the more difficult it is to maintain the homogeneity specification. For a clinical MRI superconductor magnet, the advantages of a shorter magnet with a stronger field are very clear, but it is also important that image quality should not be compromised by making the magnet shorter. The main advantages of making the magnet shorter and with a larger diameter include the potential to reduce the perception of claustrophobia for the patient and better access to the patient by attending physicians. However, as the magnet length becomes shorter and as its central field increases, the degree of difficulty in designing and producing such a magnet significantly increases.
The successful design and construction of a superconducting magnet is a three stage process. First, a theoretical design is produced which optimizes field homogeneity over the region of interest, minimizes the stress on the coils and the coil formers, and minimizes cost. This invention concerns this first step. In a second step, working drawings are developed and the magnet is wound with the whole assembly, coils, formers and cryostat at room temperature. The third step involves cooling the assembly to liquid helium temperatures. During this last step the component parts will contract to the extent that the calculated homogeneity predicted by the first step will not be achieved. Often errors in the order of many hundreds of ppm are induced by the winding process (at room temperature) and additional thermal and subsequent stresses are induced by cooling to 4K and charging the magnet to the required field.
The design of a superconducting magnetic resonance imaging (MRI) magnet is a very specific problem because of one essential feature: virtually every characteristic parameter of the field produced is determined by the geometry of the current-bearing superconductors. Various methods are used to overcome the mathematical and computational difficulty to obtain a homogeneous magnetic field over a SVOI, control of the maximum peak field inside the superconductors, limit leakage magnetic field and keep the stress in a wire bundle within a certain level. The main cost driver is the type and amount of the superconductor wire used.
U.S. Pat. No. 5,818,319 describes a magnet for a magnetic resonance system and a procedure for the designing that magnet. The method is appropriate for the design of superconducting magnets, shim magnets and gradient magnets for magnetic resonance. A simulated annealing procedure is used in the procedure error function having weighted spherical harmonics. The optimizing procedure results in a superconducting magnet having at least one coil with current flowing in an opposite direction to that of adjoining coils. The reverse current flow in combination with the relatively large number of coils, e.g. more than six, leads to the development of short, homogenous whole body magnets for magnetic resonance imaging. The patent discloses a homogenous volume of 40×103 cm3 and emphasizes design of a magnet having one single primary coil layer and one single shielding layer.
The U.S. Pat. No. 5,818,319 patent is prescriptive in the length of the magnet to be designed. For some applications the art described in the '319 patent may not lead to a design for the application being considered because the stress in coil bundles may be outside acceptable design limits.
In view of the above it is the purpose of the present invention to present a superconducting magnet design appropriate for use in MRI which permits an extremely compact magnet construction with sufficiently large investigational volumes of appropriate homogeneity to permit investigation of the human anatomy, while nevertheless maintaining a coil structure of sufficient strength to satisfy safety requirements as well as to prevent quenching of the magnet.
This purpose is achieved with a method for designing a high field, compact superconducting magnet for clinical MRI, the magnet producing a substantially homogeneous magnetic field within an investigational volume, the method comprising the steps of:
By splitting the coil into a plurality of coil layers, the inventive method achieves an increased number of degrees of freedom which, in turn, permits minimization of the overall length of the magnet while nevertheless avoiding excessive magnet field and stress values in the coils. A compact coil system can thereby be designed which satisfies a plurality of requirements with regard to investigational volume, magnet field strength, acceptable homogeneity, and magnet stray field limitation.
In a preferred embodiment of the method, the first coil layer produces a magnetic field in the investigational volume having an axial component oriented in a first direction, the second coil layer being disposed radially outside of the first coil layer to produce a magnetic field in the investigational volume having an axial component facing in a second direction opposite said first direction. In this preferred embodiment, a primary coil layer produces a magnet field in a first direction and an external coil layer produces a magnetic field in a direction opposite to that of the first layer. In so doing, a structure is generated having low fringe fields, since the dipole moments of the outer and inner layer can be adjusted to cancel in the external region.
In a preferred variation of this embodiment, step m) comprises the step of splitting said first coil layer to create the additional coil layer. The splitting of the inner coil layer producing the primary magnetic field increases the number of degrees of freedom in the portions of the overall magnet coil which have major contributions to the magnetic field. By splitting the coil, both the homogeneity requirements as well as the requirements with regard to maximum magnetic field in the coils and maximum stress can be more easily satisfied.
In another preferred embodiment of the invention, step i) comprises defining a hoop stress limitation. This particular measure has the advantage of focusing considerations of stress on the dominant hoop stress contribution.
In a preferred variation of this embodiment, a local optimization procedure is used to minimize hoop stress differences among coils in the magnet. This particular measure has the advantage of yielding a coil design having similar hoop stress conditions in all coils, thereby allowing for a common coil design which prevents quenching and maintains sufficient coil structural integrity.
In a further advantageous feature of the preferred method, a weighted sum of field homogeneity, stray field, peak field and stress is stochastically optimized. This particular measure allows for adjustment of the relative importance of certain design parameters as well as reduction of the number of parameters to a subset of parameters of particular importance to the magnet design.
An additional preferred method further comprises the step of radially splitting individual coils within a respective first, second or third coil layer. In this manner stress can be reduced within the individual coils without substantially changing their magnet field contributions.
In a particularly preferred embodiment of the method, all coils in all layers are simultaneously, mutually optimized. In this manner, complete consideration of all possible variations in all degrees of freedom is maintained without separate constraints with respect to the individual layers.
In a preferred variation of this embodiment, the coils are moved only within their respective layer. In this manner, corrections can be made to an overall coil design without departing from a certain optimization region of the overall parameter space.
In a preferred embodiment of the method, the coil space is fixed and coil layer thicknesses are varied. This measure constrains the optimization to a parameter subspace which simplifies conversion to a good design result.
The purpose of invention is also achieved by a high field, compact superconducting magnet for clinical MRI, the magnet producing a substantially homogeneous magnetic field within an investigational volume, the magnet comprising:
By splitting the coil space into at least three mutually parallel layers in which the inner most layers contribute to a common magnetic field direction and the outer most layer generates a magnet field oriented in an opposite direction to those of the inner layers, a magnet can be constructed having a high magnetic field which nevertheless has a low fringe field. The subdivision of the coils into axially spaced coil pairs renders the magnetic field axially symmetric with respect to a central region. The splitting of the those coils contributing to the main magnetic field direction into two separate layers provides for an increase in the degrees of freedom for shortening and optimizing the homogeneity of the magnet system and permits satisfaction of the stress and maximum magnetic field requirements to avoid quenching and maintain the structural integrity of the magnet system.
In a preferred embodiment of the magnet, each coil layer and all subcombinations of coil layers produce magnetic fields having field homogeneities within the investigational volume in excess of 1000 ppm, and only a full combination of all coil layers produces a field homogeneity in the investigational volume of less than or equal to 20 ppm. In this embodiment, the individual layers are not structured to provide contributions to the magnetic field of certain orders. On the contrary, all layers are important to the overall homogeneity of the system. Even the outermost layer not only provides a shielding function but also plays a central role with regard to achieving the homogeneity requirements within the investigational volume. In principle, each coil can contribute to any harmonic necessary to homogenize the fields produced by the other coils.
In this fashion, the optimization algorithm can search parameter space without restrictions to thereby permit full variation of the parameters available in the split coil design.
In a preferred embodiment of the invention, said first coil layer comprises at least one coil pair disposed adjacent to an axially outermost coil pair and producing a magnetic field in the investigational volume having an axial component oriented in said second direction. The field contributions from various orders in the expansion of the magnetic field tend to change sign as the magnet becomes shorter. Therefore, by introducing a coil having opposite magnetic field direction than that of adjacent coils, a cancellation of the inhomogeneities resulting from shorting the overall length of the coil is effected.
In a preferred embodiment of the invention, said first coil layer comprises 4 coil pairs, said second coil layer comprises two coil pairs, and said third coil layer comprises two coil pairs. This solution leads to a compact design satisfying the requirements with respect to homogeneity and field strength.
In a preferred variation of this latter embodiment, the investigational volume has a diameter of at least 45 cm and a length of at least 40 cm. In this design, the investigational volume is sufficiently large for whole body MRI.
In a preferred variation of this embodiment, said first coil layer produces a magnetic field in the investigational volume of approximately 2 T, said second coil layer of approximately 3 T, and said third coil layer of approximately −2 T. In this manner, a three Tesla magnet is produced in which the five Tesla positive field contribution is split between the two inner coil layers. The shielding layer of approximately −2 Tesla provides for proper cancellation of the stray field. A high field compact magnet with low stray field can be thereby constructed, which is suitable for MRI applications.
In a preferred variation of this embodiment, the magnet coils have an overall axial extent of less than or equal to 1.3 meters. This permits MRI investigations of claustrophobic patients and eases access to patients during examinations.
A second design of the magnet in accordance with the invention comprises an additional fourth coil layer radially disposed between said second and said third coil layers, said fourth coil layer producing a fourth magnetic field oriented in said first direction. This particular embodiment has the advantage of providing an additional splitting of the magnet layers, which thereby results in an extremely short, high field magnet.
In a preferred variation of this second design, said first coil layer comprises 4 coil pairs, with an axially outermost coil pair each being split into two radially aligned sub-coils, said second coil layer comprising two coil pairs with an axially outermost pair each being split into two radially aligned sub-coils, said third coil layer comprised two coil pairs, and said fourth coil pair having two coil pairs, with an axially outermost coil pair each being split into two radially aligned sub-coils. In this particular embodiment, the splitting of the outermost coils into two sub coils reduces hoop stress and peak magnetic field in the coils without substantially altering their magnet field contributions.
In a particular preferred variation of this second design, the investigational volume has a diameter of at least 46 cm and a length of at least 30 cm. An extremely compact MRI magnet is thereby generated which is nevertheless appropriate for whole body MRI.
In a particular preferred variation of the second design the magnet coils generate an overall magnetic field of 1.5 T and are constrained to an overall axial length of less than or equal to 90 cm. A high field magnet is thereby produced which is sufficiently short to allow investigations of claustrophobic patients under whole body imaging requirements while nevertheless permitting good access to the patient during the course of the examination.
In a third design for a 3 layer magnet in accordance with the invention, said first coil layer comprises 4 coil pairs, said second coil layer comprises 2 coil pairs, and said third coil layer comprises two coil pairs. This configuration permits an extremely short magnet to be constructed, which has sufficiently good field for investigation of parts of the human anatomy.
In a preferred variation of this third design, the investigational volume has a diameter of at least 16 cm and a length of at least 13 cm. The investigational volume is thereby sufficiently large to permit investigation of human limbs.
In a preferred variation of the third design, the coils produce a magnet field in the investigational volume of approximately 1.5 T and are constrained to an overall axial length of at most 40 cm. In this manner, a high field magnet can be generated which has an extremely short extent thereby allowing access to a patient during examination of limbs as well as permitting examination of the anatomic portions of the patient in such a manner that access to the investigational volume is permitted without substantial patient discomfort.
The invention is further described below with reference to the drawings. The individual embodiments of the drawing are not to be considered exhaustive enumeration of all possible inventive configurations rather having exemplary status for illustration of the invention. The features illustrated in the drawings can be important to the invention either alone or in arbitrary mutual combination.
The mathematical model for the optimization procedure in accordance with the invention can be considered as follows. Since the magnet is axially symmetric, the geometrical constraints can be defined by the magnet cross section dimension (see
let
Ω:(R1,R2)×(Z1,Z2)∈R2 (1)
be the coils feasible domain, and for the superconducting coil block i is defined by
Ci:(ri±Δri/2,zi±Δzi/2)∈Ω (2)
If a wire with cross section is w (width) h (height) is used in the coil Ci, then the turn balance condition has to be satisfied
Nlayeri=Δri/h,Nzi=Δzi/w, and Ntotali=Nlayeri·Nzi (3)
where Nlayeri is the number of layers, Nzi is the number of turn for each layer, and Ntotali is the total number of turns in the coil Ci. Nlayeri and Nzi are integers.
The specific volume of interest (SVOI) is defined by
VSVOI:az×ar. (4)
The magnetic field strength Bz in the VSOVI has to match the specified field strength B0, i.e.
Bz=B0, (5)
and the measure of field homogeneity is taken as peak to peak error as
The stray field, in general 5 gauss line, is defined as
L5G:∂(R5G×Z5G). (7)
The peak field constraint in the superconducting wire is a function of current density and is wire dependent
Bp=ƒ(wire-type,J). (8)
In general, the stress is dominated by hoop stress
σθ≦σC, (9)
where σC is critical stress level for the superconducting wire not to quench.
The magnetic field is governed by Maxwells' equations. For a current carrying circular wire loop, the Biot-Savart law based calculation can be used to represent the static magnetic field,
As the static magnetic field can be represented as a vector potential
B=∇×A, (11)
and the vector potential satisfies the vector Poisson equation
∇2A=−μ0J (12)
Therefore, the magnetic field is often represented by spherical harmonic functions as
For the stress calculation, the body force is produced from Lorentz's force
F=(Fr,0,Fz)=J×B (14)
Due to axial-symmetry, all stresses are independent of the θ coordinate. Shear stresses σθz and σrθ equal to zero, while stresses (σr, σθ, σz, σrz)are given by solving following equilibrium equations
together with the stress-strain relations:
and strain-displacement equations:
where r, θ and z are cylindrical coordinates with r representing the radial direction, θ the circumferential direction and z the axial direction; Fr and Fz are body forces in r and z directions respectively; σr, σθ, σz are normal stresses in r, θ and z directions while σrz, σθz and σrθ are shear stresses in rz, θz and rθ planes; εr, εθ, εz are normal strains in r, θ and z directions while γrz is the shear strain in the rz plane; ur and uz are displacements in r and z directions; and finally E and v are elastic modulus and Poisson ratio respectively.
A numerical solution technique, such as the finite element method, can be used to easily get results (σr, σθ, σz, σrz). In the MRI superconductor magnet case, the stress component σθ (hoop stress) is the dominant stress, which is a major factor to be considered in a superconductor magnet design.
A simple example is given below to demonstrate the methodology of the split coil concept approach with regard to managing stress.
The example compares two situations, one is a single coil, other is the single coil has been split into two coils. The dimension of the coils and the current densities are shown in
In order to compare the stress fairly, both situations (single coil and split coil) generate the same Bz field strength (2.0 Tesla) at the center, (see
It is interesting to see that the peak magnetic fields are similar between the single and split coils. However, the body force has been redistributed. The final hoop stress (σθ) results show that the single coil is 82.5 Mpa and the split coil is 77.5 Mpa. The peak stress is reduced by 7%.
From this it example, one sees that the way in which a coil is split and its current density redistributed can be very important for managing the stress. An optimization procedure is used such that the optimized function given by
min∥σi−σj∥,i≠j (18)
where σi and σj are the absolute value of the maximum stress in each sub-coil that result by splitting the single coil. The procedure thereby causes the peak stress values in each sub-coil to be similar, so that all sub-coils have similar strength. Although a single coil may not be able to manage the stress, a split coil approach provides a way to reduce the peak stress. The split coil approach therefore results in a multi layer magnet. Depending on the situation of the single coil, the coil can be split into or three or more layers.
For the design optimization, the optimized function can be given by
Φ=ωSVOI·MSVOI+ωshield·Mshield+ωpeak·Mpeak+ωstress·Mstress. (19)
Where MSVOI, Mshield, Mpeak, and Mstress are measures of the field homogeneity, stray field, peak field and stress lever in the superconducting coils, and ωSOVI, ωshield, ωpeak, ωstress are their weight coefficients respectively. The measures are often using first normal, second normal or infinity normal on metric space. The geometrical constraints can be considered as constraints of the optimization. In general, most optimization techniques can be adapted to solve such a problem.
This stochastic approach to magnet design can yield a variety of designs which are not necessarily obvious; the coil bundles can all begin at slightly differing radii from the magnet central z axis and the current in each coil bundle may be different in polarity from an adjacent coil bundle. Using such an approach, the common feature is a primary coil layer in which the coil bundles have essentially the same radius from the magnet central z axis and a second layer which acts to shield the field from the primary layer, limiting the field to a confined space outside the magnet. It must be appreciated that the desired field homogeneity is only achieved when the fields from each layer are summed.
As noted above, a conventional MRI magnet design usually has a primary coil layer, and a shielding coil layer (see
In order to solve these problems, and particularly to reduce stress, the large coil block (of
Based on this splitting coil concept, a multi layer magnet design method has been developed. The design procedures are as follows:
It is to be noted that all the coils in all the layers are optimizing together. The coils are only allowed to move within the layer they occupy. Although the coil space is fixed, the thickness of layers can be adjusted.
As will be illustrated below with reference to concrete embodiments, the optimized solutions often result in coils within a given layer having negative turns. In the following, a physical explanation is given for this phenomenon.
The magnetic field produced by a circular loop can be represented with spherical harmonics as [1]
For a pair of coils (see
n is an even number only, I is the current, and (r, θ) is a field point.
Table 1 gives normalized harmonic coefficients up to 12th order of a coil pair at the different Z positions. The coil radius is equal to 0.5, and field position at r=0.25.
From these data, one sees that as the coils are positioned closer to the center (Z=0), the higher order harmonics generally increase and their signs change. This property of the harmonic coefficients behavior gives a way to use the combination of the coils to achieve specific task. In a short magnet design, the negative turn pair of coils attempts to correct the large positive turn coils. In fact, the combination of all coils results in a homogeneous field in the volume of interest. It is clear that because of the sign of the spherical harmonic coefficients the higher order terms for the coil pair above are eliminated when another coil pair similar to the above is combined with it but having its current flowing in the opposite direction. This is why the negative turns are used in the magnet design. However, as a stochastic process is used to derive the positions and the turns density of each coil bundle there is no simple explanation other than the above. No analytical equations can be derived on how much of any coil bundle, polarity, radial position, should be in the magnet design.
Using the multi layers superconducting magnet design procedures outlined above, a 3 Tesla compact magnet was designed. The magnet dimensions were specified as 1.3 meters long, inner diameter of 1.0 meter, and outer diameter set at 2.2 meters, which gives a coil space
Ω:(0.05,1.10)×(−0.650,0.650).
The SVOI was specified as
VSVOI:40×45(cm).
For this example, all the coils use a single type of wire with the dimension of the wire set at
w =1.95(mm) and h=1.20(mm).
The magnetic field strength in the VSOVI is
B0=3(tesla).
The stray field, 5 gauss line, was bounded as
L5G:∂(4×6(m)).
The peak field is set at
Bp≦8(tesla)
The results are illustrated as following:
The design contains three layers of coil blocks. The coils' position data are given in Table 2, while the magnet pattern is shown in
The coil dimensions, number of wire turns and turns balancing information are given in Table 3.
This is a 12th order design with a three layer coil structure. Each layer generates its own field distribution. No single layer can produce the desired homogeneity field (see
Clearly the splitting of the layers based on the above criteria can be extended to more than two splits (to give three layers). The alignment of the layers with respect to each other is critical. If they are not aligned to fractions of a mm the procedure will fail.
Table 4 lists the coil pattern and Table 5 the coil dimensions, number of wire turns, as well as the turn balancing data for another embodiment in accordance with the invention: a 1.5 T ORTH superconducting magnet.
The magnet has an overall superconductor volume of 0.015614 m3, a 10 ppm peak homogeneity within a region of 13 by 16 cm in the Z and R directions. The peak field in the superconducting coils <5 T. The magnet is extremely short, having an overall length of 0.4 m.
Table 6 illustrates the coil pattern of a third embodiment of the invention illustrating the design for a four layer, compact 1.5 T superconducting magnet having an overall length of 0.9 m.