KR101456923B1 - Method For Providing Ultrasonic Imaging by Using Aperture Compounding, Ultrasonic Diagnostic Apparatus Therefor - Google Patents

Abstract

An ultrasonic imaging method using aperture compounding and an ultrasonic diagnostic apparatus therefor are disclosed.
A probe for transmitting an ultrasonic signal to a target object and receiving an ultrasonic echo signal reflected from the target object; A beamformer for focusing the ultrasound echo signal to form a received signal and generating frame data corresponding to the received signal; And controlling the beamformer to apply at least one of an aperture value and a weight value to each of the frame data when generating the frame data, (Aperture Compounding); A signal processing unit (digital signal processing) for processing the generated frame data; And a scan converter for converting the digital signal processed frame data to display and outputting the converted frame data through a display unit having the converted frame data. to provide.
According to this embodiment, there is an effect that the quality of the image is further improved by taking a value having different characteristics for each frame data of each time difference included in the ultrasound image.

Description

TECHNICAL FIELD [0001] The present invention relates to an ultrasonic imaging method using an aperture compounding method, and an ultrasonic imaging method using the aperture combing method.

The present embodiment relates to an ultrasonic imaging method using aperture compounding and an ultrasonic diagnostic apparatus therefor. More specifically, when an ultrasound image is formed, a value having different characteristics is applied to each frame data frame of each time difference included in the ultrasound image, thereby to improve the quality of the image The present invention relates to an ultrasound imaging method using a puncher compounding and an ultrasonic diagnostic apparatus therefor.

The contents described in this section merely provide background information on the present embodiment and do not constitute the prior art.

The ultrasound system is widely used as a diagnostic system because it has non-invasive and non-destructive properties. Generally, an ultrasound system transmits an ultrasound beam composed of a group of ultrasound signals to a target object, receives an ultrasound beam reflected from the target object, and forms an ultrasound image of the target object.

That is, the ultrasound imaging apparatus electrically generates the ultrasound signal transmitted to the human body by electrically stimulating the conversion element and transmits the ultrasound signal to the human body. The ultrasound signals transmitted to the human body are reflected at the boundaries of discontinuous human tissues and the ultrasound echo signals transmitted from the boundary of the human tissue to the conversion elements are converted into electrical signals. And amplifies and processes the converted electrical signal to generate ultrasound image data for the tissue.

Recently, as the performance of an ultrasound imaging apparatus is improved, a live 3D ultrasound image showing a 3D image in real time as well as a 2D ultrasound image of an internal shape of a target object (for example, internal organs of a patient) is provided. 3D ultrasound images are useful for diagnosis by showing images that are difficult to be seen by 2D images. Accordingly, there is a need for a technique capable of forming a more precise image with improved distortion, noise, and the like in the process of forming an image in an ultrasound system.

In order to solve the above-described problems, in the present embodiment, when an ultrasound image is formed, a value having different characteristics is applied to each frame data of each time difference included in the ultrasound image, There is a main purpose of providing an ultrasound imaging method using an aperture compounding and an ultrasound diagnostic apparatus therefor.

According to an aspect of the present invention, there is provided a probe for receiving an ultrasonic echo signal reflected from a target object and transmitting the ultrasonic signal to the target object. A beamformer for focusing the ultrasound echo signal to form a received signal and generating frame data corresponding to the received signal; And controlling the beamformer to apply at least one of an aperture value and a weight value to each of the frame data when generating the frame data, (Aperture Compounding); A signal processing unit (digital signal processing) for processing the generated frame data; And a scan converter for converting the digital signal processed frame data to display and outputting the converted frame data through a display unit having the converted frame data. to provide.

According to another aspect of the present invention, there is provided a transceiving method comprising: a transmission / reception process of transmitting an ultrasonic signal from a probe to a target object and receiving an ultrasonic echo signal reflected from the target object; A frame generation step of focusing the ultrasound echo signal in a beam former to form a reception signal and generating frame data corresponding to the reception signal; Controlling the beamformer to apply at least one of the aperture value and each weight value to each of the frame data when generating the frame data at the aperture compounding unit; A signal processing step of digitally processing the frame data generated by the signal processing unit; And a scan converter converting the frame data processed by the scan converter to display the frame data and outputting the converted frame data through a display unit having the converted frame data. And provides a shooting method.

As described above, according to the present embodiment, there is an effect that the quality of the image is further improved by taking a value having different characteristics for each frame data of each time difference included in the ultrasound image. That is, according to the present embodiment, the aperture value and the weight value of the ultrasonic probe are set differently, thereby making it possible to more accurately represent the portion that can not be expressed in the conventional image and improve the quality of the image.

In addition, according to the present embodiment, it is possible to generate adaptive frame data to which adaptive aperture values, which are different aperture values, are applied to each frame data, and additionally, adaptive weight values The image corresponding to the intermediate value is formed in the process of forming each data frame to which the adaptive aperture and the adaptive weight are applied as one image so that the image which can not be expressed by the conventional ultrasonic diagnostic apparatus There is an effect that can be expressed more accurately.

1 is a block diagram schematically showing an ultrasonic diagnostic apparatus according to an embodiment of the present invention.
FIG. 2 is a flowchart for explaining an ultrasonic imaging method using aperture compounding according to the present embodiment,
3 is an illustration showing an effective transducer array change based on an aperture value according to the present embodiment,
FIG. 4 is a view illustrating application of a weight value selected according to the radiation angle according to the present embodiment,
5A and 5B are exemplary views of a predetermined plurality of aperture values according to the present embodiment.

Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings.

The aperture described in this embodiment is configured to transmit an ultrasonic signal to a target object from a probe 110 and to receive a corresponding ultrasonic echo signal from a transducer array 110 provided in the probe 110, (Transducer Array). For example, as the aperture value increases, the number of transducer arrays to be applied increases, so that the range of the transmitted ultrasonic waves can be widened. The smaller the aperture value, the smaller the applied transducer array, and the transmitted ultrasonic range can be narrowed.

The weight described in this embodiment is a value set by the user to determine the distribution, beam width, noise, etc. of the ultrasonic wave for forming an image according to the object, and the corresponding weight is multiplied by the specific weight of the set value Can be applied. These weights can be determined to be optimal values through simulation.

In addition, the image described in this embodiment includes a B-mode image or a C-mode image. That is, the B-mode image is a gray scale image, and the C-mode image is a color flow image mode. The BC-mode image is a mode for displaying the flow of the blood flow or the motion of the object using the Doppler effect. The BC-mode image is a mode for simultaneously providing a B-mode image and a C- Which is an image mode that provides anatomical information along with blood flow and motion information of a subject. That is, the B-mode is an image of a gray scale, which indicates a motion mode of a target object, and the C-mode is a color flow image, which is a motion mode of a blood flow or a motion of a target object. Meanwhile, the ultrasound diagnostic apparatus 100 according to the present invention may include a device capable of simultaneously providing a B-mode image and a C-mode image, which is a color flow image, For convenience of explanation, it is assumed that the present invention is a B-mode image, which is a video provided by the ultrasonic diagnostic apparatus 100.

1 is a block diagram schematically showing an ultrasonic diagnostic apparatus according to the present embodiment.

The ultrasonic diagnostic apparatus 100 according to the present embodiment includes a probe 110, an analog digital converter 112, a beamformer 120, an aperture compounding unit 130, a signal processing unit A scan converter 150, a display unit 160, and a user input unit 170. The display unit 160 includes a display unit 140, a scan converter 150, a display unit 160, The ultrasonic diagnostic apparatus 100 includes a probe 110, an analog digital converter 112, a beam former 120, an aperture compounding unit 130, a signal processing unit 140, a scan converter 150, The display unit 160 and the user input unit 170. However, the present invention is not limited to only the display unit 160 and the user input unit 170, but is merely an exemplary description of the technical idea of the present embodiment. The present invention is not limited to the above embodiments, and various modifications may be made to the components included in the ultrasonic diagnostic apparatus 100 without departing from the essential characteristics of the exemplary embodiments.

The probe 110 includes a transducer array (not shown). The probe 110 transmits an ultrasonic signal to a target object and receives an ultrasonic echo signal reflected from a target object using the transducer array. The transducer converts an electrical analog signal into an ultrasonic signal, transmits the ultrasonic signal to the object, converts the ultrasonic echo signal reflected from the object into an electrical analog signal, and is formed by coupling a plurality of transducer elements. The probe 110 according to the present embodiment changes the effective transducer array based on a selected aperture value among a plurality of predetermined aperture values. Here, the predetermined plurality of aperture values may include an optimum value (Max Lobe) for setting the ultrasonic echo signal to be received at the maximum value, an optimum value (Beam Width) for preventing the representation of the circular shape from being distorted, (Main Lope / Clutter Power).

The analog-to-digital converter 112 converts the electrical analog signal converted by the transducer provided in the probe 110 into an electrical digital signal. In FIG. 1, the analog digital converter 112 is shown as being located between the transducer and the beam former 120, but the present invention is not limited thereto. Those skilled in the art will appreciate that, The present invention can be applied to various modules within the ultrasonic diagnostic apparatus 100 by being modified in various ways without departing from the essential characteristics.

The beam former 120 focuses the ultrasonic echo signals received by the respective transducers provided in the probe 110 to generate frame data, which is raw data. The beam former 120 forms a receive focusing signal based on the electrical digital signal converted by the analog-to-digital converter 112. In addition, the beam former 120 may add a proper delay to each electrical digital signal in consideration of the time required to reach each transducer of the probe 110 from a target object, and then sum the signals to form a receive focusing signal. The beam former 120 according to the present embodiment focuses the ultrasonic echo signals received from the probe 110 to form a reception signal and generates frame data corresponding to the reception signal.

When generating the frame data, the aperture compounding unit 130 according to the present embodiment applies the at least one of the aperture value and the weight value for each frame data to the beam former 120 .

The aperture compounding unit 130 causes the beam former 120 to generate aperture values that are different from one another for each frame of data. For example, when the aperture compounding unit 130 applies an adaptive aperture value, And generates first adaptive frame data to which an adaptive aperture value is applied. When the aperture compounding unit 130 applies the adaptive aperture value, the signal processing unit 140 performs digital signal processing on each first adaptive frame data to generate the intermediate adaptive frame data, Value image is formed.

The aperture compounding unit 130 may cause the beamformer 120 to generate adaptive weight values corresponding to different weight values for each frame data, And generates the second adaptive frame data to which the weight value is applied. Here, the adaptive weight value has a predetermined weight value according to the object. The weight value is preferably an apodization weight, but is not limited thereto. When the aperture compounding unit 130 applies an adaptive weight value, the signal processing unit 140 performs digital signal processing on each second adaptive frame data to generate an intermediate value To be formed.

When the aperture compounding unit 130 applies both the adaptive aperture value and the adaptive weight value, the aperture compounding unit 130 causes the beam former 120 to transmit the frame data The first adaptive frame data to which the adaptive aperture value is applied and the third adaptive frame data to which the adaptive weight value is applied for each first adaptive frame data Respectively. Meanwhile, when the aperture compounding unit 130 applies both the adaptive aperture value and the adaptive weight value, the signal processing unit 140 digitally processes each of the third adaptive frame data to generate a third adaptive So that an image having an intermediate value obtained by combining the frame data is formed.

The aperture compounding unit 130 may be configured to cause the beamformer 120 to generate the first adaptive frame data, Adaptively applies any one of a predetermined plurality of aperture values based on the object selection information input by the user input unit 170 for each frame data. The aperture compounding unit 130 may cause the beamformer 120 to select the adaptive weight value from the first adaptive frame among the preset weight values, The third adaptive frame data is generated by applying the weight value selected based on the object selection information input by the user input unit 170 as an adaptive weight value for each data.

The aperture compounding unit 130 selects a weight value based on the angle by using the aperture 110. The aperture compounding unit 130 may be configured to select a weight value based on the angle, It is determined whether or not the radiation angle is applied to the ultrasound signal. If it is determined that the radiation angle is applied, the beamformer 120 sets the weight value selected according to the radiation angle as an adaptive weight value, And generates third adaptive frame data applied to each data.

The signal processing unit 140 performs digital signal processing on the frame data signal to generate ultrasound image data. The signal processing unit 140 according to the present embodiment processes the frame data generated by the beam former 120 in a digital signal processing. In this case, when the aperture compounding unit 130 applies the adaptive aperture value, the signal processing unit 140 performs digital signal processing on each first adaptive frame data to generate an intermediate value To be formed. In addition, when the aperture compounding unit 130 applies an adaptive weight value, the signal processing unit 140 performs digital signal processing on each second adaptive frame data to generate an intermediate value To be formed. In addition, when the aperture compounding unit 130 applies both the adaptive aperture value and the adaptive weight value, the signal processing unit 140 digitally processes each third adaptive frame data to generate a third adaptive So that an intermediate value image in which frame data is combined is formed

The scan converter 150 converts ultrasound image data into a data format used in a display unit 160 of a predetermined scan line display format. That is, the scan converter 150 converts the ultrasound image data signal into a data format displayed on the display unit 160.

The scan converter 150 according to the present embodiment converts the digital signal processed frame data through the signal processing unit 140 so as to display the converted frame data and outputs the transformed frame data through the display unit 160 having the converted frame data. In this case, when the signal processor 140 processes the first frame data to which the adaptive aperture value is applied, the scan converter 150 converts each of the first adaptive frame data subjected to the digital signal processing to the display unit 160 And the image data is converted into a data format to be used and output through the display unit 160 having the intermediate value image obtained by combining the first adaptive frame data. In addition, when the signal processor 140 processes the second frame data to which the adaptive weight value is applied, the scan converter 150 uses each of the second adaptive frame data subjected to the digital signal processing on the display unit 160 And outputs the image data through the display unit 160 having the intermediate value image obtained by combining the second adaptive frame data. In addition, when the signal processor 140 digitally processes the third frame data using both the adaptive aperture value and the adaptive weight value, the scan converter 150 converts each of the third adaptive frame data The display unit 160 converts the image data into a data format used by the display unit 160 and outputs the image data through the display unit 160 having the intermediate value image obtained by combining the third adaptive frame data.

The user input unit 170 receives an instruction by a user's operation or input. Here, the user command may be a setting command for controlling the ultrasonic diagnostic apparatus 100, or the like.

2 is a flowchart illustrating an ultrasonic imaging method using aperture compounding according to the present embodiment.

The probe 110 transmits an ultrasound signal to a target object and receives an ultrasound echo signal reflected from the target object (S210). The beam former 120 focuses the ultrasonic echo signal to form a reception signal and generates frame data corresponding to the reception signal (S220).

The aperture compounding unit 130 controls the beam former 120 to apply at least one of the aperture value and the weight value to each frame data when generating the frame data (S230 ). The aperture compounding unit 130 may apply only the adaptive aperture value in step S230. That is, the aperture compounding unit 130 may generate the first adaptive frame data to which the beamformer 120 applies the adaptive aperture value, which is a different aperture value for each frame data. When the aperture compounding unit 130 applies the adaptive aperture value, the signal processing unit 140 performs digital signal processing on each first adaptive frame data to generate the intermediate adaptive frame data, Value image can be formed.

Also, in step S230, the aperture compounding unit 130 may apply only the adaptive weight value. That is, the aperture compounding unit 130 may generate the second adaptive frame data to which the beamformer 120 applies the adaptive weight value, which is a different weight value for each frame data. Here, the adaptive weight value has a predetermined weight value according to the object. When the aperture compounding unit 130 applies an adaptive weight value, the signal processing unit 140 performs digital signal processing on each second adaptive frame data to generate an intermediate value Can be formed. In addition, in step S230, the aperture compounding unit 130 may apply both the adaptive aperture value and the adaptive weight value. That is, the aperture compounding unit 130 causes the beam former 120 to generate first adaptive frame data to which an adaptive aperture value, which is a different aperture value, is applied to each frame data, It is possible to generate the third adaptive frame data applying adaptive weight values, which are different weight values, for each adaptive frame data. Meanwhile, when the aperture compounding unit 130 applies both the adaptive aperture value and the adaptive weight value, the signal processing unit 140 digitally processes each of the third adaptive frame data to generate a third adaptive So that an image having an intermediate value obtained by combining the frame data can be formed.

The signal processing unit 140 digitally processes the frame data generated through the beam former 120 (S240). In step S240, when the aperture compounding unit 130 applies the adaptive aperture value, the signal processing unit 140 digitally processes each first adaptive frame data to combine the first adaptive frame data So that an intermediate value image can be formed. In step S240, when the aperture compounding unit 130 applies an adaptive weight value, the signal processing unit 140 performs digital signal processing on each second adaptive frame data to generate a second adaptive frame data So that an intermediate image can be formed. In step S240, when the aperture compounding unit 130 applies both the adaptive aperture value and the adaptive weight value, the signal processing unit 140 performs digital signal processing on each of the third adaptive frame data, 3 < / RTI > adaptive frame data may be formed.

The scan converter 150 converts the digital signal processed frame data to be displayed and outputs the transformed frame data through the display unit 160 having the converted frame data (S250). In step S250, when the signal processor 140 processes the first frame data to which the adaptive aperture value is applied, the scan converter 150 converts each of the first adaptive frame data subjected to the digital signal processing into the display unit 160 ), And output the image data through a display unit 160 having an intermediate value image obtained by combining the first adaptive frame data. In addition, in step S250, when the signal processor 140 processes the second frame data to which the adaptive weight value is applied, the scan converter 150 converts each of the second adaptive frame data subjected to digital signal processing to a display unit 160), and output the result through a display unit 160 having an intermediate value image obtained by combining the second adaptive frame data. In addition, in step S250, when the signal processor 140 digitally processes the third frame data to which both the adaptive aperture value and the adaptive weight value are applied, the scan converter 150 converts the digital signal processed respective third adaptation The first frame data is converted into a data format used in the display unit 160 and is output through the display unit 160 having the intermediate value image obtained by combining the third adaptive frame data.

Although it is described in FIG. 2 that steps S210 to S250 are sequentially executed, it is only described as an example of the technical idea of the present embodiment. If a person skilled in the art is familiar with the present invention, It is to be understood that various changes and modifications may be made to the invention without departing from the essential characteristics thereof, or alternatively, by executing one or more of the steps S210 through S250 in parallel, But is not limited thereto.

As described above, the ultrasonic imaging method using the aperture compounding according to this embodiment described in FIG. 2 can be implemented by a program and recorded on a computer-readable recording medium. A program for implementing the ultrasonic imaging method using the aperture compounding according to the present embodiment is recorded, and a computer-readable recording medium includes all kinds of recording devices for storing data that can be read by a computer system. Examples of such computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, etc., and also implemented in the form of a carrier wave (e.g., transmission over the Internet) . The computer readable recording medium may also be distributed over a networked computer system so that computer readable code is stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the present embodiment can be easily inferred by programmers in the technical field to which the present embodiment belongs.

3 is an exemplary view showing an effective transducer array change based on the aperture value according to the present embodiment.

As shown in FIG. 3, the probe 110 changes the effective transducer array based on a selected aperture value among a plurality of predetermined aperture values. Here, the aperture compounding unit 130 selects the adaptive aperture value. The aperture compounding unit 130 causes the beamformer 120 to generate the first adaptive frame data It is possible to adaptively apply any one of a plurality of predetermined aperture values for each frame data based on the object selection information input by the user input unit 170. [

3, when the focus of the object is assumed to be located at 2 cm, the probe 110 changes the effective transducer array to 10 based on the aperture value selected from a predetermined plurality of aperture values The beamformer 120 focuses the ultrasound echo signals received by the ten transducers to form a receive signal, and the ultrasound echo signal corresponding to the receive signal Frame 1 '.

3, the probe 110 changes an effective transducer array to twelve based on a selected aperture value among a plurality of predetermined aperture values, and transmits an ultrasonic signal to a target object. And the beam former 120 focuses the ultrasound echo signals received by the twelve transducers to form a received signal and generates a 'frame 2' corresponding to the received signal.

3, the probe 110 changes the effective transducer array to 18 based on a selected aperture value among a plurality of predetermined aperture values, and then transmits the ultrasonic signal to the target object. And the beam former 120 focuses the ultrasound echo signals received by the 18 transducers to form a receive signal and generates a 'frame 3' corresponding to the receive signal. Frame 1 ',' frame 2 ', and' frame 3 'are subjected to digital signal processing by the signal processing unit 140, and' frame 1 ',' frame 2 ' Image 1 is formed by combining 'Frame 1', 'Frame 2', and 'Frame 3' after being converted to display through the display unit 150.

FIG. 4 is a view illustrating an application of a weight value selected according to the radiation angle according to the present embodiment.

The aperture compounding unit 130 selects a weight value based on the angle by using the ultrasound waves transmitted through the probe 110 when the adaptive aperture value is applied to the aperture compounding unit 130. [ As a result of the check, if the emission angle is applied, the beam former 120 causes the weight value selected according to the emission angle to be used as an adaptive weight value for each first adaptive frame data And generates the applied third adaptive frame data.

For example, when the probe 110 transmits an ultrasonic signal to the object, if the transducer provided in the probe 110 is arranged in a straight line, the radiation angle is not applied, but the radiation angle of the transducer In the case of the probe 110 which is determined or the transducer is arranged in a fan shape, the radiation angle is applied to the ultrasonic signal.

4, the aperture compounding unit 130 confirms whether or not the radiation angle is applied to the ultrasonic signal transmitted through the probe 110 when the adaptive aperture value is applied, determined that, when the radiation angle of the angles of θ ₁ is applied at ₂ θ causes the beam former 120, the adaptive weight values of the selected weight value depending on the angle and applied to the "1st- frame ', an emission angle θ ₃ If the angle of? ₁ is applied to the beamformer 120, the weight value selected according to the angle is applied to the '2st-frame', and if the angle of emission is? _N and the angle of? ₁ is applied The beam former 120 applies the selected weight value according to the angle to the adaptive weight value 'n-frame'.

 The '1st-frame', the '2st-frame' and the 'n-frame' are digital signals processed by the signal processing unit 140, Frame 'is transformed for display through the scan converter 150, and then an intermediate image (Sum Image) formed by combining' 1st-frame ',' 2st-frame ', and' n-frame ' .

5A and 5B are exemplary views of a predetermined plurality of aperture values according to the present embodiment.

As shown in FIGS. 5A and 5B, a predetermined plurality of aperture values include an optimal value (Max Lobe) set for receiving the ultrasonic echo signal at a maximum value, an optimal value (Beam Width) set so that the representation of the circular shape is not distorted, And an optimum value (Main Lope / Clutter Power) set so that the noise portion is removed.

5A and 5B show an example of the simulation result when the focus of the object is assumed to be located at 2 cm. The optimal value Max Lobe set to receive the ultrasonic echo signal at the maximum value is '14' And the optimum value (Main Lope / Clutter Power) in which the noise portion is set to be removed is '17' open channels, and the optimum value (Beam Width) Channel.

That is, when the aperture compounding unit 130 generates the first adaptive frame data to which the beamformer 120 applies the adaptive aperture value, which is a different aperture value for each frame data, Generates a first frame data to which '14' is applied, generates second frame data to which '11' is applied as an adaptive aperture value, and generates third frame data to which '17' is applied as an adaptive aperture value And the signal processing unit 140 may form an image having an intermediate value obtained by combining the first frame data and the third frame data.

The foregoing description is merely illustrative of the technical idea of the present embodiment, and various modifications and changes may be made to those skilled in the art without departing from the essential characteristics of the embodiments. Therefore, the present embodiments are to be construed as illustrative rather than restrictive, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of the present embodiment should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

100: ultrasonic diagnostic apparatus 110: probe
112: analog-to-digital converter 120: beam former
130: aperture compounding part
140: signal processor 150: scan converter
160: Display

Claims (20)

A probe for transmitting an ultrasonic signal to a target object and receiving an ultrasonic echo signal reflected from the target object;
A beamformer for focusing the ultrasound echo signal to generate a received signal and generating a plurality of adaptive frame data at the same focusing position using the received signal;
A user input unit for receiving a command by a user's operation or input;
Wherein the first adaptive frame data is generated by applying any one of a predetermined plurality of aperture values based on the object selection information input by the user input unit, An aperture compounding unit for controlling the beamformer to generate third adaptive frame data using an adaptive weight value;
A signal processing unit for compounding the third adaptive frame data; And
A scan converter (Scan Converter) operable to output the third adaptive frame data through a display unit,
And an ultrasonic diagnostic apparatus. The method according to claim 1,
The signal processing unit,
Wherein an intermediate value image formed by compounding the first adaptive frame data by digital signal processing of each of the first adaptive frame data is formed. The method according to claim 1,
Wherein the aperture compounding unit comprises:
Controls the beamformer to generate second adaptive frame data to which adaptive weight values, which are different weight values, are applied to a plurality of frame data generated at the same reception focusing position,
Wherein the signal processor digitally processes each of the second adaptive frame data to form an intermediate value image formed by compounding the second adaptive frame data. The method according to claim 1,
The signal processing unit,
Wherein an intermediate value image formed by compounding the third adaptive frame data by digital signal processing of each of the third adaptive frame data is formed. delete The method according to claim 1,
Wherein the probe comprises:
And changes an effective transducer array based on a selected aperture value among a plurality of predetermined aperture values. The method according to claim 6,
Wherein the predetermined plurality of aperture values comprise:
And an aperture value to which at least one of a maximum reception value (Max Lobe), a distortion prevention value (Beam Width) and a noise elimination value (Main Lope / Clutter Power) for receiving the ultrasonic echo signal at the maximum value is applied Characterized by an ultrasonic diagnostic device. A probe for transmitting an ultrasonic signal to a target object and receiving an ultrasonic echo signal reflected from the target object;
A beam former for focusing the ultrasound echo signal to generate a received signal and generating a plurality of adaptive frame data at the same focusing position using the received signal;
Wherein the first adaptive frame data is generated by applying an adaptive aperture value that is a different aperture value to each of a plurality of frame data generated at the same reception focusing position, An aperture compounding unit for controlling the beamformer so as to generate third adaptive frame data to which an enemy weight value is applied;
A signal processing unit for compounding the third adaptive frame data; And
A second adaptive frame data generator for generating a third adaptive frame data,
Wherein the adaptive weight value has a predetermined weight value according to the object. 9. The method of claim 8,
Further comprising a user input unit for receiving a command by a user's operation or input,
Wherein the aperture compounding unit applies the selected weight value to the adaptive weight value based on the object selection information input by the user input unit for each of the first adaptive frame data among the predetermined weight values, And controls the beam former to generate frame data. A probe for transmitting an ultrasonic signal to a target object and receiving an ultrasonic echo signal reflected from the target object;
A beam former for focusing the ultrasound echo signal to generate a received signal and generating a plurality of adaptive frame data at the same focusing position using the received signal;
Wherein the first adaptive frame data is generated by applying an adaptive aperture value, which is a different aperture value, to each of a plurality of frame data generated at the same reception focusing position, and when the emission angle is applied to the ultrasound signal, An aperture compounding unit for controlling the beamformer so that third adaptive frame data is generated by applying an adaptive weight value selected for each of the first adaptive frame data;
A signal processing unit for compounding the third adaptive frame data; And
A second adaptive frame data generator for generating a third adaptive frame data,
And an ultrasonic diagnostic apparatus. An ultrasonic imaging method using an ultrasonic diagnostic apparatus,
A transmitting and receiving process of transmitting an ultrasonic signal to a target object and receiving an ultrasonic echo signal reflected from the target object;
Generating a received signal by focusing the ultrasonic echo signal, and generating a plurality of adaptive frame data at the same focusing position using the received signal;
Wherein the first adaptive frame data is generated by applying any one of a predetermined plurality of aperture values based on the object selection information input by the user input unit, An aperture compounding process for generating third adaptive frame data to which a weight value is applied;
A signal processing step of compounding the third adaptive frame data; And
And outputting the third adaptive frame data through a display unit having the third adaptive frame data.
And an ultrasonic imaging method using the aperture compounding. 12. The method of claim 11,
Wherein the signal processing includes digitally processing each of the first adaptive frame data to form an intermediate value image formed by compounding the first adaptive frame data. Ultrasound imaging method used. 12. The method of claim 11,
Wherein the aperture compounding process includes generating second adaptive frame data to which adaptive weight values, which are different weight values, are applied to a plurality of frame data generated at the same focusing position,
Wherein the signal processing includes digitally processing each of the second adaptive frame data to form an intermediate value image formed by compounding the second adaptive frame data. Ultrasound imaging method used. 12. The method of claim 11,
Wherein the signal processing includes digital signal processing of each of the third adaptive frame data to form an intermediate value image formed by compounding the third adaptive frame data. Ultrasound imaging method used. delete 12. The method of claim 11,
The transmitting /
And changing an effective transducer array based on a selected aperture value among a plurality of predetermined aperture values. 17. The method of claim 16,
Wherein the predetermined plurality of aperture values comprise:
And an aperture value to which at least one of a maximum reception value (Max Lobe), a distortion prevention value (Beam Width) and a noise elimination value (Main Lope / Clutter Power) for receiving the ultrasonic echo signal at the maximum value is applied A method of ultrasound imaging using an aperture compounding. An ultrasonic imaging method using an ultrasonic diagnostic apparatus,
A transmitting and receiving process of transmitting an ultrasonic signal to a target object and receiving an ultrasonic echo signal reflected from the target object;
Generating a received signal by focusing the ultrasonic echo signal, and generating a plurality of adaptive frame data at the same focusing position using the received signal;
Wherein the first adaptive frame data is generated by applying an adaptive aperture value that is a different aperture value to each of a plurality of frame data generated at the same reception focusing position, An aperture compounding process for generating third adaptive frame data to which an enemy weight value is applied;
A signal processing step of compounding the third adaptive frame data; And
And outputting the third adaptive frame data through a display unit having the third adaptive frame data.
Wherein the adaptive weight value has a predetermined weight value according to the object. ≪ RTI ID = 0.0 > 11. < / RTI > 19. The method of claim 18,
The aperture compounding process includes:
And generating the third adaptive frame data by applying a weight value selected based on the object selection information input by the user input unit to the first adaptive frame data among the predetermined weight values as the adaptive weight value And an ultrasonic imaging method using the aperture compounding. An ultrasonic imaging method using an ultrasonic diagnostic apparatus,
A transmitting and receiving process of transmitting an ultrasonic signal to a target object and receiving an ultrasonic echo signal reflected from the target object;
Generating a received signal by focusing the ultrasonic echo signal, and generating a plurality of adaptive frame data at the same focusing position using the received signal;
Wherein the first adaptive frame data is generated by applying an adaptive aperture value, which is a different aperture value, to each of a plurality of frame data generated at the same reception focusing position, and when the emission angle is applied to the ultrasound signal, And generating third adaptive frame data by applying an adaptive weight value selected for each of the first adaptive frame data to the first adaptive frame data;
A signal processing step of compounding the third adaptive frame data; And
And outputting the third adaptive frame data through a display unit having the third adaptive frame data.
And an ultrasonic imaging method using the aperture compounding.

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