The present invention relates to an ultrasonic imaging device, and more particularly, it relates to a medical ultrasonic imaging device having a probe including a two-dimensional (2D) matrix array of transducer elements and having a configuration in which multiple output signals of transducer elements are bundled together to each channel so that the number of channels is less than that of transducer elements.
In recent years, an ultrasonic imaging device endowed with a three-dimensional imaging function is rapidly shifting to a phase of commercialization and clinical application. Such an ultrasonic imaging device endowed with the three-dimensional imaging function employs a probe which incorporates a large number of transducer elements, for example, around a few thousands of elements. Therefore, it is necessary to bundle output signals in units of multiple transducer elements, and to reduce the number of signals, down to the number from 100 to 200, which corresponds to the number of I/O channels of the imaging device main unit.
Patent document 1 discloses a configuration that a phasing circuit is divided into two stages; storing in a probe, a sub-focusing circuit in which multiple transducer elements are bound into one sub-channel, and storing in the device main unit, a main-focusing circuit in which multiple sub-channels are bound into one channel. With the configuration, the sub-channel shape and the channel shape are dynamically controlled, and a width of the transducer elements, which are bound into the same channel, is made to be the same as the distribution width of one transducer element, irrespective of a deflective direction, whereby deterioration of beams can be suppressed.
Patent document 2 discloses a configuration that the two-dimensional array transducer elements 20 are divided into multiple concentric ring areas about a perpendicular line dropped from a wave transmission or wave receiving focal point, and a group of transducer elements within a concentric ring area are connected to one signal line (see FIG. 2 of the patent document 2). The group of transducer elements within the ring area has an approximately the same distance from the focal point, and receiving signals of each transducer element are approximately in phase. Signals in phase do not cancel one another out even though they are added together. Therefore, according to the configuration as disclosed in the patent document 2, a group of transducer elements in the ring area is connected to one signal line, and the signals in the group of transducer elements are bound together. Thereafter, an identical delay amount is given to the bound signals, and they are added to signals of a signal line to which a group of transducer elements in other ring area is connected, whereby phasing is performed. Accordingly, the number of signal lines (the number of channels) can be reduced to the number of the ring areas, and since it is sufficient for a delay circuit to be installed for each of the signal lines, the number of the delay circuits can be reduced as well.
[Patent document 1]
Japanese unexamined patent application publication No. 2005-34633
[Patent document 2]
Japanese unexamined patent application publication
However, according to the two-stage phasing circuit as disclosed in the patent document 1, the number of channels is not sufficiently reduced at the time of outputting from the sub-focusing circuit, and there still exist around a few hundreds of channels between the sub-focusing circuit and the main-focusing circuit. In implementation, a portion between the sub-focusing circuit and the main-focusing circuit corresponds to a cable which connects the probe and the device main unit. In order to prevent a loss of operability of the device with the cable which binds a few hundreds of channels, it is necessary to develop a dedicated cable which is much smaller in diameter than a general-purpose cable. However, since it costs high to develop such dedicated cable, there is a problem that it may bring up the price of the device.
In the technique to divide the ring area as disclosed in the patent document 2, if a width of one ring area (a difference between a diameter of inner periphery and a diameter of outer periphery) is large, a phase difference in signals becomes not ignorable, between the transducer elements in proximity to the inner periphery and the transducer elements in proximity to the outer periphery. Then, when a group of the transducer elements is bound together into one signal line, the signals may cancel one another out, thereby reducing the precision in phasing. Since the number of the settable ring areas is the same as the number of signal lines, the ring area cannot be narrowed to a width equal to or less than a predetermined value.
An object of the present invention is to provide an ultrasonic imaging device which establishes annular areas each having a narrowed width, without increasing the number of channels, thereby enabling enhancement of a focused sound pressure.
In order to achieve the above object, the ultrasonic imaging device according to a first aspect of the present embodiment includes multiple transducer elements arranged in two-dimensional surface, a probe having the multiple transducer elements for transmitting an ultrasonic wave to a predetermined focal point and receiving a reflected wave therefrom, multiple signal lines the number of which is less than the number of the transducer elements, a selection part for connecting the multiple transducer elements with any of the signal line being selected out of the multiple signal lines, a controller for controlling an operation of the selection part, and a beamformer for delaying signals outputted from the multiple signal lines by a predetermined amount with respect to each of the signal lines, and summing the signals, wherein, the controller establishes annular areas the number of which is larger than the number of signal lines, along with line intersections between wave surfaces of the reflected wave and the two-dimensional surface. The controller selects out of the multiple annular areas being established, multiple annular areas with focal depths differing by an integral multiple of an ultrasonic wavelength, and controls the selection part to connect the transducer elements positioned within the selected multiple annular areas with an identical signal line.
With the configuration above, it is possible to establish the annular areas the number of which is larger than the number of signal lines, thereby narrowing the width of the annular area. Accordingly, since the signals of the transducer elements within the same annular area are distributed within a narrow duration, the phase shift amount becomes small, and thereby reducing the possibility that signals cancel one another out, when addition is performed by the connection with the same signal line. Furthermore, multiple annular areas are selected, whose focal depths differ by an integral multiple of the ultrasonic wavelength, and the signals received from the selected multiple annular areas arrive at multiple time points being shifted by the time length corresponding to the wavelength, and these signals do not cancel one another out. Accordingly, it is possible to prevent the signals from cancelling one another out, without increasing the number of signal lines (the number of channels), thereby improving the focused sound pressure.
It is possible to configure such that the controller assumes multiple concentric spheres, each being different by a predetermined value in radius centering the focal point, and establishes areas sectioned by the line intersections between the multiple concentric spheres and the two-dimensional surface, as the annular areas. By way of example, if it is assumed that the number of signal lines is M, a predetermined integer between or equal to 1 and M is N1, and the ultrasonic wavelength is λ, the radius of the multiple concentric spheres varies by λ/N1, so as to establish the annular areas. Accordingly, the delay amounts of the multiple signal lines become values varying by a certain quantity, enabling an accurate delaying.
It is preferable for the controller to select the annular areas not adjacent to each other. It is further possible to configure such that the controller establishes a nonuse annular area between adjacent annular areas, and the selection part does not connect the transducer elements positioned in the nonuse annular area with any signal lines.
If a focal position is changed, it is preferable that the controller modifies the position of the annular areas and the selection thereof. Therefore, the controller is capable of performing an arithmetical operation in advance to establish and select the annular areas, with respect to each position that can be set as the focal point, and storing a result of the operation in a storage. Upon receipt of the reflected wave, the controller reads the operation result stored in the storage, according to the focal position at that point of time, and controls the selection part. With this configuration, it is not necessary to perform the arithmetical operation every time when the focal position is changed, and therefore, it is possible to respond quickly to the change of the focal position.
In order to achieve the object as described above, the ultrasonic imaging device according to a second aspect of the present invention is provided with multiple transducer elements which are arranged in two-dimensional array in the first direction and in the second direction, a probe having the multiple transducer elements for transmitting an ultrasonic wave of wavelength λ to a predetermined focal point and receiving a reflected wave, M signal lines the number of which is less than the number of the transducer elements, a selection part for connecting the multiple transducer elements with any of signal line selected out of the multiple signal lines, a controller for controlling an operation of the selection part, and a beamformer for delaying the signals outputted from the multiple signal lines by a predetermined amount with respect to each of the signal lines, and summing the signals, wherein when it is assumed that a maximum value of a distance between the focal point and the multiple transducer elements is Rmax, a minimum value of the distance between the focal point and the multiple transducer elements is Rmin, a distance between the focal point and the transducer elements at i-th position and j-th position respectively in the first direction and the second direction is Rij, a predetermined actual number between or equal to Rmin and Rmax is R0, a predetermined integer between or equal to 1 and M is N1, an arbitrary integer between or equal to 0 and N1−1 is n1 (n1=0, 1, . . . N1−1), a predetermined integer between or equal to 0 and (Rmax−R0)/λ is N2, and an arbitrary integer between or equal to 0 and N2−1 is n2 (n2=0, 1, . . . N2−1), the controller establishes the annular area for each combination of n1 and n2, the annular area being made up of multiple transducer elements having Rij which satisfies the formula 1 as the following:
R
0
+n
2
·λ+n
1·(λ/N1)<Rij≦R0+n2·λ+(n1+1)·(λ/N1) (formula 1)
The controller selects predetermined multiple annular areas out of the multiple annular areas being established, and controls the selection part to connect the transducer elements constituting the multiple annular areas being selected with an identical signal line.
Accordingly, it is possible to set N1×N2 annular areas the number of which is larger than the number of the signal lines, thereby narrowing the width of the annular areas. Therefore, even when the signals of the transducer elements within the same annular area are added, it is possible to reduce the occurrence that the signals cancel one another out. Since each of the multiple annular areas varies by λ/N1 in the distance from the focal point, the delay amounts of the multiple signal lines become values varying by a certain quantity, enabling an accurate delaying. Accordingly, it is possible to prevent that the signals cancel one another out, without increasing the number of signal lines (the number of channels), thereby improving the focused sound pressure.
It is possible to configure such that the controller selects multiple annular areas with focal depths differing by an integral multiple of an ultrasonic wavelength. By way of example, when the annular areas established by the combination of n1 and n2 are represented as (n1, n2) in the formula 1, the controller selects N2 annular areas represented by (m, 0), (m, 1), (m, 2) . . . (m, N2−1) for the m-th signal line, and connects the transducer elements in these annular areas with the signal line. Accordingly, receiving signals in the selected multiple annular areas are shifted in arrival time corresponding to the distance λ, and the signals do not cancel one another out. Therefore, it is possible to enhance the focused sound pressure.
In the ultrasonic imaging device according to the present invention, annular areas which are narrow in width can be established, the number of which is larger than the number of the signal lines, and therefore, it is possible to obtain received pulses which are distributed within a narrow duration. In addition, when multiple annular areas are selected to be connected with one signal line, the annular areas targeted for selection have distances from the focal point being different by the ultrasonic wavelength, and the arrival time points of the pulses respectively in these annular areas are shifted by the time length corresponding to the ultrasonic wavelength on the time axis, thereby preventing the occurrence that pulses cancel one another out. Accordingly, even when a deflection angle is large, the focused sound pressure can be amplified without bringing about canceling of sound pressure in a delay addition process, and in any place other than the front side of the probe, it is possible to obtain an image having a quality nearly the same as that of the front face of the probe.
As discussed above, the present invention does not need to increase the number of signal lines, and therefore, a general-purpose cable can be implemented between the probe and the device main unit. In addition, the focused sound pressure can be improved by around 100% to 300%. Even when the deflection angle is large, a sufficient focused sound pressure can be ensured, and therefore it is possible to implement an ultrasonic imaging device with a low cost, which is capable of obtaining an image having a quality nearly the same as the image quality in front of the probe, even in the place other than the front side of the probe.
In addition, the width of the annular area can be narrowed to the width of the transducer element to the extreme. In the case above, if a delay time is given to the signal line, adjacent transducer elements can be provided with delay times different respectively, thereby enabling a highly qualified three-dimensional imaging.
Hereinafter, preferred embodiments of the present invention will be explained in detail with reference to the accompanying drawings.
Firstly, a configuration of the ultrasonic imaging device according to the first embodiment will be explained with reference to
As shown in
Specifically, the probe 1 and the selection part 2 are configured as shown in
Accordingly, since multiple transducer elements positioned in the predetermined number of annular areas are connected to an identical one signal line, at the time of wave receiving, multiple signals outputted from these multiple transducer elements are made to flow through one signal line, whereby the signals are added together to be bound into one signal. Therefore, at the time of wave receiving, N signals from N transducer elements 1a1 to 1aN can be reduced to M, and outputted to the device main unit 3.
As shown in
At the time of wave receiving, each of the received signals bound into M by the selection part 2 are amplified by the amplifier 6, and the signals are subjected to the delay process in the receive beam former 7 for delaying the signals by a predetermined delay time with respect to each of the M signal lines. Thereafter, an addition process is performed for binding the signals of M signal lines into one, thereby subjecting the signals to phasing addition, and further converted into digital signals to make received data. Therefore, the receive beam former 7 is provided with delay circuits respectively for M signal lines.
The received data outputted from the receive beam former 7 is subjected to a signal processing to constitute an image in the signal processor 8, and the result is accumulated in the three-dimensional memory 9. Then, the image is displayed on the display part 10.
At the time of wave transmission, in response to a directive from the controller 11, the transmit beam former 5 rotates the phase of the signals of predetermined frequency by a certain amount and passes the delayed signals to the transmit-receive separation switch 4, in order to transmit a certain ultrasonic wave to the transducer elements 1a1 to 1aN at the predetermined focal position. The transmit-receive separation switch 4 passes the signals to each of the transducer elements 1a1 to 1aN via the selection part 2. The selection part 2 is able to perform switching at the time of wave transmission as well, in the similar manner as the wave receiving time. Alternatively, as far as the wave transmission is possible to the predetermined focal position, other method may be employed to perform switching.
After carrying out an operation for setting the annular areas, the controller 11 establishes the annular areas as a result of the operation, and controls the selection part 2 to connect the transducer elements positioned in the selected annular areas, with a predetermined signal line. In addition, the controller 11 controls each part of the device main unit 3, so that a transmission beam direction, a receive beam direction, a delay time, displaying, and the like are controlled.
Here, with reference to
In other words, when it is assumed that the wavelength of the ultrasonic wave received by the probe 1 is λ, a maximum value of the distance between the focal point 410 and the multiple transducer elements 1a1 to 1aN is Rmax 43, a minimum value of the distance between the focal point 410 and the multiple transducer elements 1a1 to 1aN is Rmin 44, a distance between each of the transducer elements and the focal point is Rij, each transducer element being placed at the i-th position and the j-th position respectively in the first direction 11 and the second direction 12 of the probe 1, a distance between one end of the area on the probe 1 where the annular areas are to be established according to the formula 1 and the focal point is R0 45 (an actual number between or equal to Rmin and Rmax), the number of output signals from the selection part is M, a predetermined integer between or equal to 1 and M is N1, an arbitrary integer between or equal to 0 and N1−1 is n1 (n1=0, 1, . . . N1−1), a predetermined integer between or equal to 0 and (Rmax−R0)/λ for defining the other end of the area to which the annular areas are to be established according to the following formula 1 is N2, and an arbitrary integer between or equal to 0 and N2−1 is n2 (n2=0, 1, . . . N2−1), the annular areas 422 to 42p are made up of a group of transducer elements of Rij satisfying the following formula 1, with respect to each of the combinations n1 (n1=0, 1, . . . N1−1) and n2 (n2=0, 1 . . . N2−1). It is to be noted that N1 indicates the number of signal lines (1≦N1≦M) to be connected with the transducer elements of the annular areas established by the formula 1, indicating a priority setting for a resolving power in the sound axis direction and a focused sound pressure.
R
0
+n
2
·λ+n
1·(λ/N1)<Rij≦R0+n2·λ+(n1+1)·(λ/N1) (formula 1)
With reference to
In addition, in the formula 1, the terms of n1·(λ/N1) and (n1+1)·(λ/N1) are included respectively in the left hand side and the right hand side. With these terms, each the values (n1=0, 1, . . . N1−1) is set to n1, for each of the values of n2 (n2=0, 1, . . . N2−1), and accordingly, as shown in
The transducer elements positioned inner and/or outer than the annular areas 422 to 42p established by the formula 1 are associated with arbitrary number n3 of the annular areas 421 and the like, being reserved separately. In the case of
With reference to
Next, an explanation will be made regarding the annular areas and a selection of signal line which is connected to these annular areas. The selection part 2 selects multiple annular areas not adjacent to each other, out of N1×N2 annular areas being established according to the formula 2, and connects the selected annular areas with one signal line, thereby reducing the number of channels. In other words, when integers between or equal to 0 and N1−1, which represent the numerical numbers of N1 signal lines, are assumed as m (m=0, 1, . . . N1−1) and the annular areas are represented by (n1, n2), annular areas having n1 being equal to m (n1=m) and n2 being each value of n2=0, 1, . . . N2−1, are all selected as the annular areas (m, n2) (N2 pieces) for the m-th signal line. Then, the transducer elements in those areas are connected to the m-th signal line. Accordingly, the annular areas connected to the signal line m are represented by the formula 2. This is the channel number reducing pattern.
(m, n2) n2=0, 1, . . . N2−1 (formula 2)
By way of example, in the case as shown in FIG. 6(b), the selection part 2 connects the transducer elements in the annular areas (0, 0), (0, 1), and (0, 2) to the m=0th signal line, connects the transducer elements in the annular areas (1, 0), (1, 1), and (1, 2) to the m=1st signal line, and connects the transducer elements in the annular areas (2, 0), (2, 1) and (2, 2) to the m=2nd signal line.
It is to be noted that the annular areas 421 and the like positioned inner and/or outer than the annular areas 422 to 42p established according to the formula 1, are connected to a signal line m′ that is different from the aforementioned N1 signal lines. Alternatively, it is further possible to configure such that the annular areas 421 and the like are not connected to any of the signal lines.
Here, with reference to a flow diagram shown in
Firstly, in the annular area establishing step 51, an operation is carried out to establish correspondences between N transducer elements and the annular areas 421 to 42p. By way of example, this operation is carried out by calculating a matrix A which represents the correspondences between N transducer elements and the annular areas. In the annular area selection step 52, an operation is carried out to establish correspondences between N2 annular areas with one signal line. By way of example, this operation is carried out by calculating a matrix B which represents the correspondences between the annular areas and the signal line. Further in step 53, the correspondences between the N transducer elements and the signal lines are calculated by using the results of the steps 51 and 52. By way of example, if the correspondences between the transducer elements and the annular areas are assumed as A, and the correspondences between the annular areas and the signal is assumed as B, a product of A·B represents a channel number reducing pattern, and therefore, this is calculated by the channel number reducing pattern calculation step 53. In the setting file generation step 54, the channel number reducing pattern is written and stored in the setting file 1142. In those steps 51 to 54, the operations are carried out with respect to each settable focal position and each of the parameters (R0, N1, N2, and n3) settable by the user as described below, and the results are stored in the setting file 1142.
When imaging is performed, the CPU 112 reads from the setting file 1142, a channel number reducing pattern which is associated with the parameters set by the user and the focal point position at that time, and passes the selected pattern to the selection part 2. The selection part performs switching operation according to the pattern being received, thereby achieving the reduction of number of the channels.
With reference to
Correspondences are established respectively between the combinations (n1, n2) of n1 (n1=0, 1, . . . N1−1) and n2 (n2=0, 1, . . . N2−1), and the transducer elements satisfying the formula 1 into which each of the values from steps 511 to 513 are substituted, and thereby setting N1×N2 annular areas (n1, n2) (step 515)
R
0
+n
2
·λ+n
1·(λ/N1)<Rij≦R0+n2·λ+(n1+1)·(λ/N1) (formula 1)
Finally, the annular areas 421 and the like, the number of which is an arbitrary number n3, are reserved for establishing correspondences with the transducer elements ij which are not associated with any of the annular areas (n1, n2) defined by the formula 1, and correspondences are established between these transducer elements ij and n3 annular areas (step 516). As for the correspondences, it is further possible to prepare multiple types thereof allowing the user to make a selection.
Next, with reference to
(m, n2) n2=0, 1, . . . N2−1 (formula 2)
The same procedure is executed for each of the values of m (m=0, 1, 2 . . . N1−1).
The annular areas the number of which is n3 being set in the aforementioned step 516 are different from the annular areas (n1, n2), and therefore, correspondences are established between these annular areas and the signal line m′ which is different from N1 signal lines used in step 521 (step 523). Also for this correspondence, it is further possible to prepare multiple types of correspondences, so as to allow the user to make a selection.
Each of the operations in the steps described above is performed for each of the settable focusing position and for each of the parameters (R0, N1, N2, and n3) settable by the user as described below, and a result of the operations is stored in the setting file 1142.
As discussed above, in the present embodiment, the annular areas the number of which is larger than the number of signal lines are established, and N2 annular areas (m, n2) are connected to the m-th signal line. N2 annular areas (m, n2) are positioned respectively at the distances from the focal point 410 being shifted by λ, and therefore, ultrasonic signals arriving from the focal point 410 (point sound source 411) to the transducer elements in these annular areas, are also shifted in time length which corresponds to the distance λ (2 π as a phase). Accordingly, even though an addition is performed by simultaneously connecting the wave receiving signals from N2 annular areas with the signal line, N2 peaks are formed on different positions (on the time axis), and there is no overlapping between waveforms. Therefore, there is no occurrence that the signals coming from different annular areas cancel one another out.
In addition, the width of the annular areas 422 and 42p (a difference between the inner diameter and the outer diameter) becomes narrower, compared to the case where the annular areas are established in such a manner that the number of the areas is equal to the number of the signal lines. In other words, each of the annular areas 51a and the like, corresponding to λ as a distance from the focal point 410, is divided into N1, and the width is narrowed to the duration corresponding to λ/N1 as a distance from the focal point 410. A phase lag amount between the signals arriving the transducer element in the innermost periphery side and arriving the transducer element in the outermost periphery side, within one of the annular areas 422 to 42p is just the phase lag amount (2 π/N1) corresponding to the distance λ/N1 from the focal point 410. Therefore, even though the addition is performed by connecting simultaneously the wave receiving signals of multiple transducer elements within one annular area with the signal lines, it is possible to reduce a phenomenon that the signals of the transducer elements within one annular area cancel one another out.
Therefore, a signal waveform outputted from one signal line has N2 peaks with peak positions shifted by the time corresponding to the wavelength λ (approximately 2 π as a phase), and each one of the peak width (discretization pitch) is narrowed to the duration corresponding to the distance λ/N1. This kind of signal waveform extends in the time axis direction, but each of the peaks has a narrow width and being steep.
A phase difference between the signals of M signal lines is 2 π/N1 (i.e., corresponding to the distance λ/N1) for each. The receive beam former 7 performs addition by delaying by 2π/N1, the phase of signals from the M signal lines, achieving an accurate phasing, thereby enabling a reduction of occurrence that the signals cancel one another out at the time of addition by the beam former 7. Accordingly, it is possible to obtain from the beam former 7, output signals having N2 peaks each being narrow in peak width and each being steep. The signal processor 8 performs an image reconstruction by using the output signals. Then, the resolving power in the sound axis is lowered because the output signals are made up of N2 peaks which are shifted in clock time, but since each of the peaks is steep, piece by piece, it is possible to improve several-fold the focused sound pressure.
Hereinafter, by using a specific example, an explanation will be made regarding an operation and effect of the present embodiment. Here, in a example with the channel number reducing pattern of the present embodiment and a comparative example, simulations were performed regarding a temporal waveform of the focused sound pressure and a point image function on a hemisphere face. Then, an explanation will be made numerically, as to an improved effect in the focused sound pressure and image quality enhancement, according to the configuration of the present invention.
As a configuration of the probe 1, the size of each transducer elements 1a1 to 1aN was set to be 0.3 mm square, the number of transducer elements N was 64 in the major direction 12, and 48 in the minor direction 11, and the number of channels (the number of signal lines M) was set to be 12.
The channel number reducing pattern of the present embodiment was based on the annular area established by the formula 1, assuming that N1=12 and N2=3. According to steps 511 to 616 shown in
In the comparative example, as shown in
As is clear from
In addition, the annular areas N2=3, being connected with one signal line, are shifted by λ as a distance from the focal point 410, and therefore, output signals arrive with a time lag corresponding to λ/C (C represents acoustic velocity). Therefore, even though the addition is performed by simultaneously connecting the wave receiving signals from N2=3 annular areas with the signal line, the peaks of N2=3 are formed at different positions (on the time axis), and the waveforms do not overlap one another. Therefore, there is no phenomenon that signals from different annular areas cancel one another out, enabling an accurate delay time control.
Actually, a pulse was received from the focal point, and a signal waveform was calculated according to an arithmetic operation. As conditions for generating the pulse, an amplitude for each transducer element was assumed as constant (=1), and a phase difference as to each element was assumed to be equivalent to the phase difference generated by one-point focusing on each of the focal points (50 mm, 0 mm, and 30 mm). An amplitude waveform in the temporal direction was obtained, assuming that a center frequency was 2.5 MHz, a pulse length was 4 waves, and an envelope curve was raised cosine.
a) and
When the maximum sound pressure of the present embodiment was assumed as a reference value,
As discussed above, it is found that according to the present embodiment, an effect of image quality improvement has been achieved, in the points that a virtual image is suppressed and the resolving power is enhanced, and the noise level is still the same as a conventional level.
As described above, the ultrasonic imaging device according to the first embodiment establishes annular areas the number of which is larger than the number of signal lines M, the annular areas using as borders, line intersections between the two-dimensional surface of the probe 1 and multiple concentric spheres having the focal point as a center. Then, the ultrasonic imaging device selects out of the established annular areas, annular areas whose distance from the focal point are shifted by the ultrasonic wavelength λ, and connects the transducer elements of the selected annular areas to one signal line. Accordingly, it is possible to establish the annular areas the number of which is larger than the number of signal lines, narrowing the width of the annular area, and reduces the possibility that the signals from the transducer elements of an identical annular area cancel one another out. In the embodiment as described above, according to formula 1, the annular areas are established in such a manner that the distance from the focal point 410 varies by a constant value (λ/N1), but the present invention is not limited to this configuration method. It is further possible that the annular areas are established in such a manner that the distance from the focal point 410 varies by a value which is not constant. In addition, it is further possible that the annular areas may be established in such a manner that the width of each of the annular areas is made constant on the two-dimensional surface of the probe 1. Further in such cases above, the annular areas are established under the condition that the number of annular areas exceeds the number of signal lines, the annular areas are selected which are positioned, each at a distance from the focal point being shifted by λ, and these selected annular areas are connected to one signal line, whereby it is possible to reduce the number of channels while the signals in the annular areas do not cancel one another out, and a certain effect can be obtained.
The ultrasonic diagnostic device according to the first embodiment is capable of improving the focused sound pressure by 100% to 300%, and therefore, it is suitable for an imaging method which gives a higher priority to the sound pressure, rather than the resolving power in the sound axis direction, for instance, Doppler imaging.
Next, an ultrasonic imaging device according to a second embodiment of the present invention will be explained. In the ultrasonic imaging device according to the second embodiment, in a similar manner as the first embodiment, annular areas are established, the number of which is larger than the number of signal lines. However, unlike the first embodiment, as shown in
As a method for setting the nonuse areas 161 to 171 as shown in
As another method for setting the nonuse areas 161 to 171, for instance, it is possible to employ a method in which N1 is set to be double the value of the first embodiment in the formula 1 according to the first embodiment, thereby setting annular areas the number of which is doubled, and in the formula 2, only the areas having n1 that is odd-numbered or even-numbered are selected. With the method above, either the areas having n1 that is odd-numbered or the areas having n1 that is even-numbered can be set as the nonuse annular areas 161 to 171.
In the second embodiment, the maximum distance of the transducer elements to be connected to the same signal line can be narrowed more, relative to the first embodiment, and therefore, a high resolving power can be obtained in the sound axis direction. Simultaneously, the width of the annular area is equal to or less than half-wavelength when converted into ultrasonic wavelength, and the signals outputted from the transducer elements within the same annular area do not cancel one another out by the addition via the signal lines, and the pulses being canceled out are removed, when delay addition is performed, thereby reserving a certain focused sound pressure. In the second embodiment, it is possible to improve the focused sound pressure at the most within the range not damaging the resolving power in the sound axis direction. Therefore, this method is suitable for the imaging in the case where the resolving power in the sound axis direction is given a priority to the focused sound pressure, such as an RF imaging and imaging of fine structure.
Next, an explanation will be made regarding an ultrasonic imaging device according to a third embodiment of the present invention. The ultrasonic imaging device according to the third embodiment establishes areas the number of which is larger than the number of signal lines, in a similar manner as the first embodiment. However, unlike the first embodiment, a shape of the areas is not limited to the annular shape. In addition, a mean value or a central value of the distances between the transducer elements belonging to the area and the focal point is calculated, and this is assumed as a distance between the focal point and the areas. Since the other configuration is the same as the first embodiment, a tedious explanation will not be made.
In the third embodiment, the shape of the area is not limited to the annular, the present invention can be applied to an area that is not annular in shape which is configured on the basis of electric consistency, for example, impedance matching, or it can be applied to a sparse array area configured on the basis of grating suppression by introducing randomness. Therefore, it is possible to achieve both effects; electric consistency or grating suppression by introducing randomness, and attainment of a focused sound pressure.
a) and
a) illustrates a part of the annular areas being established according to the first embodiment, and
b) illustrates the annular areas the number of which is the same as the number of channels, as a comparative example;
a) is a graph showing a signal waveform after delaying and summing operations by the receive beam former 7 according to the first embodiment, and
b) is a graph showing a signal waveform after delaying and summing the signals from the annular areas as shown in
a) is a graph showing a temporal waveform of the focused sound pressure of the signals obtained by the receive beam former 7, and
b) is a graph showing a temporal waveform of the focused sound pressure of the signals obtained by the comparative example;
a) shows a contour plot of the point spread function obtained from the temporal waveform of the focused sound pressure of the received signals according to the first embodiment, and
b) shows a contour plot of the point spread function obtained from the temporal waveform of the focused sound pressure of the received signals according to the comparative example; and
1: PROBE, 2: SELECTION PART, 3: DEVICE MAIN UNIT, 4: TRANSMIT-RECEIVE SEPARATION SWITCH, 5: TRANSMIT BEAM FORMER, 6: AMPLIFIER, 7: RECEIVE BEAM FORMER, 8: SIGNAL PROCESSOR, 9: THREE-DIMENSIONAL MEMORY, 10: DISPLAY PART, 11: CONTROLLER, 51 TO 54: WAVE SURFACES, 410: FOCAL POINT, 411: VIRTUAL POINT SOUND SOURCE, 412: WAVE SURFACE, 420: LINE INTERSECTION BETWEEN ULTRASONIC WAVE SURFACES AND PROBE SURFACE, 421 TO 42p: ANNULAR AREAS, 430: WIDTH OF ANNULAR AREA
Number | Date | Country | Kind |
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2007-006635 | Jan 2007 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2008/050392 | 1/16/2008 | WO | 00 | 7/14/2009 |