 |
Claims  |
|
|
What is claimed is:
1. A method of determining an NMR distribution in a region of a body
situated in a steady, uniform magnetic field, said method comprising the
steps of:
(a) generating an r.f. electromagnetic pulse during a preparation period in
order to cause a precessional motion of the magnetization of the nuclei in
the body so as to generate a resonance signal,
(b) then during a subsequent measurement period, generating a steady
gradient magnetic field, a first alternating, periodic gradient magnetic
field with a gradient direction extending in a first direction and a
second alternating, periodic gradient magnetic field with a gradient
direction extending perpendicularly to said first direction, said
measurement period being divided into a number of sampling intervals,
(c) during said measurement period taking a sample of said resonance signal
during each of said sampling intervals so as to obtain a plurality of
signal samples, and
(d) then repeating, each time after a waiting period, steps (a), (b) and
(c), said preparation period having a different duration during each
repetition so as to obtain a group of signal samples from which, after
Fourier transformation thereof, an image of a nuclear magnetization is
determined.
2. A method as claimed in claim 1 wherein said first and second alternating
gradient magnetic fields have the same period and are phase-shifted with
respect to one another.
3. A method as claimed in claim 2, wherein said first and second
alternating gradient magnetic fields are 90.degree. out of phase.
4. A method as claimed in claim 1, 2 or 3, characterized wherein per period
of an alternating gradient magnetic field a signal sample is taken at
least four times.
5. A method as claimed in claim 1, 2 or 3, wherein the starting instant of
one of said first and second alternating gradient magnetic fields
coincides with the end of the preparation period, the instant at which a
first signal sample is taken always commencing the same time interval
after the r.f. electromagnetic pulse.
6. A method as claimed in claim 1, 2 or 3, wherein during the successive
measurement periods the amplitudes of the alternating gradient magentic
fields are the same.
7. A method as claimed in claim 1, wherein eight signal samples are taken
per period of an alternating gradient magnetic field.
8. A method as claimed in claim 1, 2 or 3, wherein the periods of said
alternating gradient magnetic fields generated during successive
measurement periods are different and the ratio of the maximum field
intensity of the total alternating gradient magnetic field resulting from
summation of the individual alternating gradient fields and the period is
always smaller than or equal to a predetermined, fixed value.
9. A device for determining an NMR distribution in a region of a body, said
device comprising:
(a) means for generating a steady, uniform magnetic field,
(b) means for generating r.f. electromagnetic radiation so as to produce
processional motion of the magnetization of nuclei in the body disposed in
said uniform field and thereby generate a resonance signal,
(c) means for generating a steady, gradient magnetic field,
(d) means for generating at least two alternating, periodic gradient
magnetic fields whose gradient directions are mutually perpendicular,
(e) sampling means for taking signal samples of said resonance signal in
the presence of said alternating gradient magnetic fields,
(f) control means for controlling at least the means specified in
paragraphs (b) to (e) so as to generate and sample a plurality of said
resonance signals during successive measurement cycles,
(g) processing means controlled by said control means for processing said
signal samples taken during said measurement cycles so as to obtain an NMR
distribution therefrom.
10. A device as claimed in claim 9, wherein the periods of the alternating
gradient magnetic fields are the same and 90.degree. out of phase.
11. A device as claimed in claim 9 or 10, wherein the period of the
alternating gradient magnetic fields is adjustable.
12. A device as claimed in claim 11, wherein the intensity of the
alternating gradient magnetic fields is adjustable.
13. A method of determining an NMR distribution in a region of a body
situated in a steady, uniform magnetic field, said method comprising the
steps of:
(a) generating, during a preparation period, an r.f. electromagnetic pulse
in order to cause a precessional motion of the magnetization of nuclei in
the body so as to generate a resonance signal,
(b) generating, during said preparation period, at least one preparation
gradient magnetic field,
(c) then during a subsequent measurement period, generating a first
alternating, periodic gradient magnetic field with a gradient direction
extending in a first direction and a second alternating, periodic gradient
magnetic field with a gradient direction which extends perpendicularly to
said first direction, said measurement period being divided into a number
of sampling intervals,
(d) during said measurement period, taking a sample of said resonance
signal during each of said sampling intervals so as to obtain a plurality
of signal samples, and
(e) then repeating, each time after a waiting period, steps (a), (b), (c),
and (d), the integral over the preparation period of said at least one
preparation gradient magnetic field having a different value during each
repetition in order to obtain a group of said signal samples from which,
after Fourier transformation thereof, an image of a nuclear magnetization
is determined.
14. A method as claimed in claim 13, wherein said first and second
alternating gradient magnetic fields have the same period and are
phase-shifted with respect to one another.
15. A method as claimed in claim 14, wherein said first and second
alternating gradient magnetic fields are 90.degree. out of phase.
16. A method as claimed in claim 13, 14 or 15, wherein, per period of an
alternating gradient magnetic field, a signal sample is taken at least
four times.
17. A method as claimed in claim 13, 14 or 15, wherein one of said first
and second alternating gradient magnetic fields starts at an instant which
coincides with the end of the preparation period, the instant at which a
first signal sample is taken always commencing the same time interval
after the r.f. electromagnetic pulse.
18. A method as claimed in claim 13, 14 or 15, wherein the amplitudes of
the respective alternating gradient magnetic fields are the same during
successive measurement periods.
19. A method as claimed in claim 13, 14 or 15, wherein during the
preparation period at least two of said preparation gradient magnetic
fields are generated, the integral over the period of at least one
preparation gradient magnetic field having a different value in two
successive measurement periods.
20. A method as claimed in claim 19, wherein the gradient direction of one
of said two preparation gradient magnetic fields is the same as the
gradient directions of a respective one of the two alternating gradient
magnetic fields and the gradient direction of the other preparation
gradient magnetic field is the same as the gradient direction of the other
alternating gradient magnetic field.
21. A method as claimed in claim 13, wherein eight signal samples are taken
per period of an alternating gradient magnetic field.
22. A method as claimed in claim 13, 14 or 15, wherein the periods of said
alternating gradient magnetic fields generated during successive
measurement periods are different and the ratio of the maximum field
intensity of the total alternating gradient magnetic field resulting from
summation of the individual alternating gradient fields and the period is
always smaller than or equal to a predetermined, fixed value.
23. A method as claimed in claim 13, 14 or 15, wherein a steady gradient
magnetic field is generated during said measurement period. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
BACKGROUND OF THE INVENTION
The invention relates to a method of determining an NMR distribution in a
region of a body which is situated in a steady, uniform magnetic field,
including the steps of:
(a) generating an r.f. electromagnetic pulse in order to cause a
precessional motion of the magnetization of the nuclei in the body, thus
generating a resonance signal,
(b) then generating, after a preparation period, a steady gradient magnetic
field and an alternating, periodic gradient magnetic field during a
measurement period of several measurement periods, said measurement period
(periods) being divided into a number of sampling intervals for taking a
number of signal samples of the resonance signal,
(c) then repeating, each time after a waiting period, the steps (a) and (b)
a number of times, the duration of the preparation period and/or the
integral over the preparation period of at least one gradient magnetic
field applied during the preparation period each time having a different
value in order to obtain a group of signal samples from which, after
signal transformation thereof, an image of a nuclear magnetization is
determined.
The invention also relates to a device for determining an NMR distribution
in a region of a body, comprising:
(a) means for generating a steady, uniform magnetic field,
(b) means for generating r.f. electromagnetic radiation,
(c) means for generating a steady gradient magnetic field,
(d) means for generating an alternating, periodic gradient magnetic field,
(e) sampling means for taking signal samples of a resonance signal
generated by the means specified in the paragraphs (a) and (b) in the
presence of a steady gradient magnetic field and of an alternating
gradient magnetic field generated by the means specified in paragraphs (c)
and (d),
(f) processing means for processing of the signal samples in order to
obtain an NMR distribution, and
(g) control means for controlling at least the means specified in the
paragraphs (b) to (f) for generating, conditioning, and sampling a number
of resonance signals and for processing the signal samples.
Such a method and device are known from Netherlands patent application NL-A
No. 82.03519 corresponding to U.S. Pat. No. 4,527,124. According to the
known method, a periodic alternating gradient magnetic field is generated
during the measurement period, the period of said gradient field being
equal to the sampling interval, at least one additional signal sample
being taken in each sampling interval.
As explained in said Netherlands patent application NL-A No. 82.03519, the
use of the alternating gradient magnetic field and the taking of the
additional signal samples ensure that at least two rows of a
(two-dimensional) image frequency matrix will have been filled after the
sampling of a resonance signal (FID or spin echo signal). Thus, the
duration of a measurement cycle is reduced to one half (one third, one
quarter) when one (two, three) additional signal samples are taken,
respectively. Because the duration of a resonance signal amounts to only
some tens of milliseconds, the taking of 128 or 256 signal samples (in a
row in the image frequency matrix) will require a sampling interval in the
order of magnitude of 100 .mu.s, which means that the frequency of the
additional gradient magnetic field must amount to 10 kHz. This
comparatively high frequency of the alternating gradient magnetic field
limits the maximum number of rows of the image frequency matrix which can
be filled by the sampling of a single resonance signal. The maximum
distance .DELTA.k between two rows filled by the sampling of a resonance
signal amounts to:
##EQU1##
in which 1/2t.sub.m is the first half period of the periodic, alternating
gradient magnetic field, .gamma. is the gyromagnetic ratio, and G(.tau.)
is the alternating gradient magnetic field. The maximum distance .DELTA.k
determines the maximum number of rows in the image frequency matrix filled
after the sampling of a resonance signal and is proportional to the
amplitude of the applied alternating gradient magnetic field. The
amplitude of the alternating gradient magnetic field cannot be increased
at random, because the rate of change dG/dt of the alternating gradient
magnetic field must remain within health safety limits imposed. This rate
of change dG/dt is proportional to the product of the amplitude and the
frequency of the alternating gradient magnetic field. Because the
frequency (10 kHz) is comparatively high, a maximum permissible amplitude
will be quickly reached. If the period of time required for collecting all
signal samples were to be reduced to one quarter, the amplitude of the
alternating field would have to be increased by a factor 4.
SUMMARY OF THE INVENTION
It is the object of the invention to provide a method and a device in
which, utilizing comparatively weaker alternating gradient magnetic
fields, the time required to form an image having a resolution which at
least equals that obtained with the prior art method and device is
substantially reduced when three-dimensional images of NMR-distributions
are made.
To achieve this, the method in accordance with the invention is
characterized in that during the measurement period, a second periodic
alternating gradient magnetic field is applied whose gradient direction
extends perpendicularly to the gradient direction of the first-mentioned
alternating gradient magnetic field. According to the method of the
invention, during a single FID-signal, the signal samples are measured not
only along an image frequency line or in a flat image frequency plane, but
in a 3-D part of the image frequency space which can now be covered due to
the additional degree of freedom offered by the second alternating
gradient magnetic field.
A preferred version of the method in accordance with the invention is
characterized in that the two periodic alternating gradient magnetic
fields have the same period and are phase-shifted 90.degree. with respect
to one another. In the preferred version of the method in accordance with
the invention, the image frequency space (or image frequency time domain
in the case of location-dependent spectroscopy) is covered via a helical
path. Thus, per period four signal samples can be taken which are situated
at the corners of a square circumscribed by the projected helix.
Consequently, the overall measurement period will be reduced by a factor
of four; however, two alternating gradient fields will then be required
which effectively produce a gradient field which is a factor .sqroot.2
stronger than a single gradient field in accordance with the present state
of the art (with the same frequency) which reduces the overall measurement
period only to one half.
A further inventive method of determining an NMR distribution in a region
of a body which is situated in a steady, uniform magnetic field, including
the steps of:
(a) generating an r.f. electromagnetic pulse in order to cause a
precessional motion of the magnetization of the nuclei in the body, thus
generating a resonance signal,
(b) then generating, after a preparation period, an alternating, periodic
gradient magnetic field during a measurement period or several measurement
periods, said measurement period (periods) being divided into a number of
sampling intervals for taking a number of signal samples of the resonance
signal,
(c) then repeating, each time after a waiting period, the steps (a) and (b)
a number of times, the integral over the preparation period of at least
one gradient magnetic field applied during the preparation period having a
different value during each repetition in order to obtain a group of
signal samples from which, after signal transformation thereof, an image
of a nuclear magnetization is determined, characterized in that during the
measurement period, a second periodic alternating gradient field is
applied whose gradient direction extends perpendicularly to the gradient
direction of the first-mentioned alternating gradient magnetic field.
A device in accordance with the invention is characterized in that it
comprises means for generating two alternating gradient magnetic fields
whose gradient directions are mutually perpendicular.
A preferred embodiment of a device in accordance with the invention is
characterized in that the periods of the alternating gradient fields are
the same and 90.degree. out of phase.
BRIEF DESCRIPTION OF THE DRAWING
Embodiments in accordance with the invention will be described in detail
hereinafter with reference to the drawing, wherein:
FIG. 1 diagrammatically shows a coil system of a device for performing a
method in accordance with the invention,
FIG. 2 shows a block diagram of a device for performing the method in
accordance with the invention,
FIGS. 3a and 3b show simple embodiments and methods in accordance with the
invention,
FIGS. 4a and 4b show a preferred version of a method in accordance with the
invention,
FIGS. 5a and 5b illustrate the method shown in the FIGS. 4a and 4b, and
FIG. 6 shows a part of a device for performing the method in accordance
with the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1 shows a coil system 10 which forms part of a device 15 (FIG. 2) used
for determining an NMR distribution in a region of a body 20. The region
has a thickness of, for example .DELTA.z and is situated in the x-y-plane
of the x-y-z-coordinate system shown in FIG. 1. The y-axis of the system
extends upwards perpendicularly to the plane of drawing. The coil system
10 generates a steady, uniform magnetic field Bo having a field direction
parallel to the z-axis, three gradient magnetic fields G.sub.x, G.sub.y,
G.sub.z having a field direction parallel to the z-axis and a gradient
direction parallel to the x, y and z-axis, respectively, and an r.f.
magnetic field. To achieve this, the coil system 10 comprises a set of
main coils 1 for generating the steady, uniform magnetic field Bo. The
main coils 1 may be arranged, for example on the surface of a sphere 2
whose centre is situated at the origin O of the cartesian coordinate
system x, y, z shown, the axes of the main coils 1 being coincident with
the z-axis.
The coil system 10 also comprises four coils 3a, 3b for generating the
gradient field G.sub.z. To achieve this, a first set 3a is excited by
current in the opposite sense with respect to the current direction in the
second set 3b; this is denoted by .circle.. and .circle.x in the
Figure. Therein, .circle.. means a current entering the section of the
coil 3 and .circle.x means a current leaving the section of the coil.
The coil system 10 furthermore comprises four rectangular coils 5 (only two
of which are shown) or four other coils such as, for example "Golay
coils", for generating the gradient magnetic field G.sub.y. In order to
generate the gradient magnetic field G.sub.x, use is amde of four coils 7
which have the same shape as the coils 5 and which have been rotated
through an angle of 90.degree. about the z-axis with respect to the coils
5. FIG. 1 also shows a coil 11 for generating and detecting an r.f.
electromagnetic field.
FIG. 2 shows a device 15 for performing a method in accordance with the
invention. The device 15 comprises coils 1, 3, 5, 7 and 11 which have
already been described with reference to FIG. 1, current generators 17,
19, 21 and 23 for energizing the coils 1, 3, 5 and 7, respectively, and an
r.f. signal generator 25 for energizing the coil 11. The device 15 also
comprises an r.f. signal detector 27, a demodulator 28, a sampling circuit
29, processing means such as an analog-to-digital converter 31, a memory
33 and an arithmetic circuit 35 for performing a Fourier transformation, a
control unit 37 for controlling the sampling instants, and also a display
device 43 and central control means 45 whose functions and relationships
will be described in detail hereinafter.
The described device 15 performs a method of determining the NMR
distribution in a region of a body 20 as will be described herreinafter.
The method involves the frequent repetition of a measurement cycle which
itself can be divided into several steps. During a measurement cycle, a
part of the nuclear spins present in the body is resonantly excited. For
resonant excitation of the nuclear spins, the current generator 17 is
switched on by the central control unit 45, so that the coil 1 is
energized and remains energized for a desired number of measurement
cycles. Thus, a steady and uniform magnetic field Bo is generated.
Furthermore, the r.f. generator 25 is switched on for a short period of
time, so that the coil 11 generates an r.f. electromagnetic field. The
nuclear spins in the body 20 can be excited by the applied magnetic fields
and the excited nuclear magnetization takes up a given angle, for example
90.degree. (90.degree. r.f. pulse) with respect to the direction of the
uniform magnetic field Bo. The location where and which nuclear spins will
be excited depends inter alia on the intensity of the field Bo, on any
gradient magnetic field which may be applied, and on the angular frequency
.omega..sub.o of the r.f. electromagnetic field, because the equation
.omega..sub.o =.gamma.. Bo (1) must be satisfied, in which .gamma. is the
gyromagnetic ratio (for free protons, for example H.sub.2 O protons,
.gamma./2.multidot..pi.=42.576 MHz/T). After an excitation period, the
r.f. generator 25 is switched off by the central control means 45. The
resonant excitation is always performed at the beginning of each
measurement cycle. For some versions r.f. pulses are generated also during
the measurement cycle. These r.f. pulses are then, for example a series
composed of 180.degree. r.f. pulses which are periodically generated. The
latter is referred to as "spin echo". Spin echo is inter alia described in
the article by I. L. Pykett "NMR in Medicine", published in Scientific
American, May 1982.
During a next step signal samples are collected. For this purpose use can
be made of the gradient fields which are generated by the generators 19,
21 and 23, respectively, under the control of the central control means
45. The detection of the resonance signal (referred to as FID signal) is
performed by switching on the r.f. detector 27, the demodulator 28, the
sampling circuit 29, the analog-to-digital converter 31 and the control
unit 37. This FID signal appears as a result of the precessional motion of
the nuclear magnetizations about the field direction of the magnetic field
Bo due to the r.f. excitation pulse. This nuclear magnetization induces an
induction voltage in the detection coil whose amplitude is a measure of
the nuclear magnetization.
The analog sampled FID signals originating from the sampling circuit 29 are
digitized (converter 31) and stored in a memory 33. After a final signal
sample has been taken during a measurement period M.sub.T, the central
control means 45 deactivate the generators 19, 21 and 23, the sampling
circuit 29, the control unit 37 and the analog-to-digital converter 31.
The sampled FID signal is and remains stored in the memory 33.
Subsequently, a next measurement cycle is performed during which an FID
signal is generated, sampled and stored in the memory 33. When a
sufficient number of FID signals has been measured (the number of FID
signals to be measured depends, for example on the desired resolution), an
NMR-image can be determined via a 2-D or 3-D Fourier transformation (this
depends on the use of the gradient magnetic fields under whose effect the
FID signals are generated and sampled). FIG. 3a shows an example of a
measurement cycle in accordance with the invention which will be
illustrated with reference to the device 15 shown in FIG. 2. Using the
r.f. coil 11, a 90.degree. pulse P.sub.1 is generated after the
switching-on of the main coils 1 generate a steady, uniform magnetic field
Bo. The resonance signal F1 which results is allowed to decay when using
the spin echo technique and after a period of time t.sub.v1, a 180.degree.
pulse P.sub.2 is generated by the r.f. coil 11. During a part of the
period t.sub.v1, gradient fields G.sub.x and G.sub.y (denoted by curves
G.sub.1 and G.sub.3) are generated for reasons to be described
hereinafter. After a period of time t.sub.v2 which is equal to t.sub.v1,
an echo resonance signal F2 produced by the 180.degree. pulse P.sub.2 will
reach a peak value. The use of the so-called spin echo technique
(180.degree. pulse P.sub.2) prevents the occurrence of phase errors in the
resonance signals produced by nuclear spins; such phase errors are caused
by inhomogeneities in the steady magnetic field Bo. The echo resonance
signal is sampled each time after a sampling interval t.sub.m (not shown
in the Figure) in the presence of alternating gradient fields G.sub.x and
G.sub.y which are denoted by curves G.sub.2 and G.sub.4, respectively.
It is known that the phase angle of a magnetization at a point z in a
gradient magnetic field G.sub.z is determined by
##EQU2##
Thus, an image frequency k.sub.z can be defined as:
##EQU3##
Thus, after each sampling period t.sub.m a respective signal sample is
determined which is associated with a different image frequency k.sub.z.
The successive image frequencies exhibit an image frequency difference
##EQU4##
It will be apparent that when an alternating gradient field G.sub.x is
applied, signal samples are obtained which are associated with image
frequencies k.sub.x which will be situated between two extreme values
k.sub.xi and
##EQU5##
The quickly alternating G.sub.y gradient field G.sub.2 is now superposed
on a slowly alternating G.sub.y gradient field G.sub.4. If this G.sub.y
gradient field G.sub.4 were present and also a constant G.sub.x gradient
field (not shown), the successive signal samples to be taken would be
associated with the image frequencies (k.sub.y, k.sub.z), k.sub.y then
varying between two extreme values as denoted by the line l in FIG. 3b.
When the alternating G.sub.y gradient magnetic field as well as the
alternating G.sub.x gradient field and a constant G.sub.z gradient field
are applied, the path S on which the signal samples to be taken during the
measurement period M.sub.T are situated will form as if it were a
band-shaped plane L which passes through the line l and which has a width
which is determined by the two extreme values
##EQU6##
of k.sub.x. Because sampling takes place with three degrees of freedom
during an FID signal in accordance with the present method {(k.sub.x,
k.sub.y, k.sub.z) or, for example k.sub.x, k.sub.y, t) for spectroscopy},
more signal samples can be derived per FID signal, so that the overall
measurement period for the filling of a 3-D (or 4-D) matrix with signal
samples is drastically reduced. By application of G.sub.x and/or G.sub.y
preparation gradient magnetic fields G.sub.1 and/or G.sub.3 during the
preparation period t.sub.v1, the band-shaped plane L can be shifted in the
(k.sub.x, k.sub.y, k.sub.z) or (k.sub.x, k.sub.y, t) space in the k.sub.x
and/or the k.sub.y -direction, so that a regular filling of said image
frequency domain or image frequency-time domain is obtained. In order to
counteract the effect of T.sub.2 relaxation times and field
inhomogeneities which cause ghost images and blurring, it is advantageous
to take a signal sample associated with, for example the frequency plane
k.sub. z always at the same relative instant after the excitation pulse
P.sub.1 (or echo pulse P.sub.2). In the present example this can be
achieved by choosing for each different presetting of the G.sub.y gradient
field G.sub.3 (actually the time integral thereover) an adapted instant
.tau..sub.D for the switching-on of the alternating G.sub.x and G.sub.y
gradient fields G.sub.2 and G.sub.4, the G.sub.2 gradient magnetic field
and the measurement period M.sub.T not being shifted in the "time domain".
FIGS. 4a and 4b illustrate the principle of a preferred version of a method
in accordance with the invention. According to this method, the applied
G.sub.y gradient magnetic field G.sub.y4 deviates from the G.sub.y
gradient field G.sub.4 shown in FIG. 3a. The gradient field G.sub.y4 has
the same period t.sub.y, t.sub.x as the gradient field G.sub.x4. The
gradient fields G.sub.x4 and G.sub.y4 exhibit a phase difference of
preferably 90.degree.. It can be deduced that in the case of two
alternating gradient fields thus applied, the image frequencies at which
signal samples are taken are situated on an ellipse (a circle when the
amplitudes G.sub.x4 and G.sub.y4 are equal) in the k.sub.x --k.sub.y image
frequency plane. When a constant gradient field G.sub.z is switched on
simultaneously with the alternating gradient fields G.sub.x4 and G.sub.y4
(only during the measurement period M.sub.T), the signal samples taken
will be associated with image frequency triplets (k.sub.x, k.sub. y,
k.sub.z) which are situated on a helix l' which is wound about the
elliptical cylinder C (circular cylinder if G.sub.x4 =G.sub.y4) with a
constant pitch. By shifting the phases of the G.sub.x and the G.sub.y
gradient fields G.sub.x4 and G.sub.y4 with respect to the starting instant
t.sub.s of the measurement period M.sub.T, the helix can be rotated about
the cylinders (in order to achieve a more uniform coverage of the cylinder
surface, if necessary). The cylinder C itself can be shifted in the
k.sub.x and/or k.sub.y -direction by varying the preparation gradient
fields G.sub.vx and/or G.sub.vy (the shaded surfaces) as regards amplitude
and/or time, so that a uniform filling of the (k.sub.x, k.sub.y, k.sub.z)
space or (K.sub.x, k.sub.y, t) space can be realized (the starting instant
t.sub.s is then fixed in time with respect to the pulse P.sub.1 (or
P.sub.2) before the start of each measurement period).
FIG. 5a is a projection perpendicularly to the k.sub.x --k.sub.y plane of
all measurement points obtained along three helices. As appears from FIG.
5a, when four signal samples are taken per turn of the helix, a uniform
filling on cartesian coordinates k.sub.x, k.sub.y is possible. When the
amplitude of the gradient fields G.sub.x4 and G.sub.y4 is increased whilst
their frequency is decreased, an equal number of signal samples can be
taken with less energy and a lower dG/dt in the same period of time,
whilst a "cartesian" filling in the k.sub.x and k.sub.y direction is
still feasible. Instead of four signal samples, eight signal samples are
now taken per turn of the helix l' (see FIG. 4b) (however, the sampling is
no longer equidistant in time), said samples being situated at the corners
of octagons which are denoted by 0, .quadrature., x, .DELTA. and . in FIG.
5b. By allowing the "cylinders" to overlap, a cartesian filling of the
k.sub.x --k.sub.y plane is achieved (see, for example .quadrature., 0, x).
A phase correction is required only in the k.sub.z -direction, said
correction being different for seven signal samples successively situated
on a helix (assuming that one of the eight is "correctly" situated on the
k.sub.z grid); this is also applicable to three of the four signal samples
measured according to FIG. 5a. The phase correction to be used is already
known from U.S. Pat. No. 4,527,124. Furthermore, it is necessary to fill
the holes MS1 and MS2 occurring at the edge of the k.sub.x --k.sub.y space
to be filled with missing signal samples. Because each time two adjacent
signal samples are concerned (k.sub.x =constant), said holes MS1 and MS2
can be successively filled by means of the method described in U.S. Pat.
No. 4,527,124 (G.sub.z =constant, G.sub.y is modulated).
The methods described with reference to the FIGS. 4a, b and 5a, b are also
very suitable for NMR spectroscopy; to this end, for example it is not
necessary to apply a gradient field during the measurement period M.sub.T
; it is merely necessary to realize a presetting k.sub.z with a gradient
field G.sub.z during the preparation period (for example during t.sub.v1
or after P.sub.2 and before t.sub.s).
For the selection/adjustment of a given pulse sequence, time intervals and
associated gradient magnetic fields for a measurement cycle, use is made
of programmed computer means. In an embodiment of the device 15 (FIG. 2)
the central control means 45 comprise a programmed computer (VAX 11/730)
which comprises an input/output station 52 for control data and an
interface 53 (see FIG. 6). Outputs 55 of the interface 53 are connected,
via the bus 50 (see FIG. 2), to the current generators 19, 21, 23 and 25
to be controlled as well as to the control inputs of the receiver 27, the
demodulator 28 and the sampling circuit 29.
* * * * *
|
|
|
|
|
|
|
Description |
|
