JP2011087729A - Ultrasonic diagnostic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technique of storing two or more kinds of data formed inside an ultrasonic diagnostic apparatus. <P>SOLUTION: A reception beam former 1 forms two or more pieces of beam data corresponding to a plurality of ultrasonic beams. A beam processor 20 performs reception processing to each of the two or more pieces of beam data and forms two or more pieces of line data. The two or more pieces of beam data and the two or more pieces of line data are transferred to an image processor 30 and stored in a beam memory 32 and a line memory 34. The image processor 30 forms image data from the two or more pieces of line data belonging to respective frames, and forms two or more pieces of image data corresponding to the plurality of frames. The two or more pieces of image data formed in the image processor 30 are stored in an image memory 36. Then, a management table indicating the correspondence relation of the beam data, the line data and the image data is stored in a data management part 40. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an ultrasonic diagnostic apparatus, and more particularly to a technique for storing data formed in the apparatus.

  A general ultrasonic diagnostic apparatus forms beam data based on signals obtained from a plurality of vibration elements, performs processing such as detection on the beam data, and forms line data. The image data is formed by processing the image data using a scan converter or the like. An image corresponding to the image data formed in this way is displayed on a monitor or the like.

  A technique for storing data formed in an ultrasonic diagnostic apparatus is also known. For example, Patent Document 1 proposes a technique for storing beam data (phased RF signal) in a memory and using it for signal processing after freezing.

  As described above, there are a plurality of types of data corresponding to different processing stages, such as beam data, line data, and image data, in a general ultrasonic diagnostic apparatus. However, in the conventional apparatus, only one type of data among a plurality of types of data is to be stored. For example, in the apparatus described in Patent Document 1, only beam data is a storage target.

JP 2001-299745 A

  In view of the above-described background art, the inventors of the present application have conducted research and development on data storage processing in an ultrasonic diagnostic apparatus that handles a plurality of types of data such as beam data, line data, and image data.

  The present invention has been made in the course of research and development, and an object thereof is to realize a technique for storing a plurality of types of data formed in an ultrasonic diagnostic apparatus.

  An ultrasonic diagnostic apparatus suitable for the above object includes a probe including a plurality of vibration elements that transmit and receive ultrasonic waves, a beam forming unit that forms beam data based on signals obtained from the plurality of vibration elements, and beam data A beam processing unit that performs line processing to form line data, an image processing unit that performs image processing on line data to form image data, and beam data, line data, and image data. And a data storage unit that stores at least two types of data associated with each other.

  In a preferred embodiment, the beam forming unit forms a plurality of beam data corresponding to a plurality of ultrasonic beams, and the beam processing unit performs a reception process on each of the plurality of beam data to generate a plurality of lines. Forming data, and the data storage unit stores a plurality of beam data and a plurality of line data in which each beam data and each line data obtained from the beam data are associated with each other. .

  In a preferred embodiment, the image processing unit forms a plurality of image data corresponding to a plurality of frames, and the data storage unit associates the image data of each frame with the beam data and line data belonging to the frame. A plurality of added beam data, a plurality of line data, and a plurality of image data are stored.

  In a preferred embodiment, the ultrasonic diagnostic apparatus includes a data management unit that manages a correspondence relationship between the image data of each frame stored in the data storage unit and the beam data and line data belonging to the frame. Features.

  In a preferred embodiment, the image processing unit performs video processing on a plurality of image data to form video data, and the data storage unit stores a plurality of beam data, a plurality of line data, and a plurality of image data. In addition, video data is stored.

  According to the present invention, it is possible to store a plurality of types of data formed in the ultrasonic diagnostic apparatus.

1 is a diagram illustrating an overall configuration of an ultrasonic diagnostic apparatus that is preferable in the practice of the present invention. It is a figure for demonstrating the management table memorize | stored in a data management part.

  Hereinafter, preferred embodiments of the present invention will be described.

  FIG. 1 is a diagram showing an overall configuration of an ultrasonic diagnostic apparatus suitable for implementing the present invention. The probe 10 is an ultrasonic probe that transmits and receives ultrasonic waves to a subject such as a living body. The probe 10 includes a plurality of vibration elements each of which transmits and receives an ultrasonic wave. The plurality of vibration elements are transmission-controlled by the transmission beam former 12 to form a transmission beam. In addition, the plurality of vibration elements receive the ultrasonic waves reflected from the subject, and signals obtained thereby are output to the reception beam former 14, and the reception beam former 14 forms beam data along the reception beam. .

  The beam data is, for example, RF signal data (RF data), but data (in-phase component data and quadrature component data) obtained by performing quadrature detection processing on the RF signal may be used as beam data. Beam data is formed for each received beam. That is, a plurality of beam data corresponding to a plurality of reception beams are formed one after another.

  The beam processor 20 performs reception processing on the beam data to form line data. A plurality of beam data successively formed in the reception beamformer 14 are sequentially stored in a beam buffer 22 connected to the beam processor 20. The beam processor 20 performs reception processing on each of the plurality of beam data stored in the beam buffer 22 to form a plurality of line data. A plurality of line data successively formed in the beam processor 20 are stored in the line buffer 24 one after another.

  The beam processor 20 appropriately executes, for example, various types of filter processing such as detection, quadrature detection, logarithmic compression processing, spatial filter processing, and frequency analysis processing as reception processing.

  The plurality of beam data and the plurality of line data temporarily stored in the beam buffer 22 and the line buffer 24 are transferred to the image processor 30 and stored in the beam memory 32 and the line memory 34 connected to the image processor 30. . The beam processor 20 and the image processor 30 are connected to each other by, for example, a high-speed bus such as a PCI Express bus, and a plurality of beam data and a plurality of line data are DMA-transferred from the beam processor 20 to the image processor 30, for example.

Assuming beam data up to a depth of 30 cm sampled at 32 bits and 40 MHz, the amount of data for each received beam is about 56 kbits as shown in the following equation. (0.030 [m] × 2/1530 [m / s]) × 32 [bit] × 40 × 10 ⁶ [Hz] <56kbit

  Assuming that the line data is composed of 1024 pixels of 8 bits for each reception beam, the line data is 8 kbits.

  Therefore, even if all the line data and beam data are transferred, the data amount is 64 kbits (= 8 Kbytes) for each received beam. If the number of line data constituting one frame is assumed to be 1024, the data amount per frame is 8 MByte.

  In the PCI Express bus, the transfer amount in the case of x1 is 250 MByte / second, and the transfer amount in the case of x4 is 1 GByte / second. Therefore, if the amount of data per frame is 8 MByte, data transfer of 256 frames / second is possible in the case of x4. That is, for example, by using the PCI Express bus, it is possible to transfer both a plurality of beam data and a plurality of line data from the beam processor 20 to the image processor 30 in real time.

  The plurality of beam data transferred from the beam processor 20 is stored in a beam memory 32 connected to the image processor 30, and the plurality of line data transferred from the beam processor 20 is a line connected to the image processor 30. Stored in the memory 34.

  The image processor 30 performs image processing on the line data to form image data. For each frame, the image processor 30 forms image data from a plurality of line data belonging to the frame, and sequentially forms a plurality of image data corresponding to the plurality of frames. A plurality of image data successively formed in the image processor 30 is stored in the image memory 36 one after another. An ultrasonic image such as a B-mode image or a Doppler image is formed based on the plurality of image data and displayed on the display unit 50.

  The image processor 30 may form video data that can be reproduced by, for example, a general-purpose computer. That is, the image processor 30 performs video processing such as compression processing on the plurality of image data stored in the image memory 36 to form video data. The formed video data is stored in the video memory 38. A moving image (ultrasonic image) corresponding to the video data may be displayed on the display unit 50.

  Moreover, the functional block comprised by the image processor 30, the various memories connected to it, and the data management part 40 is realizable with a general purpose computer, for example. For example, the beam memory 32, the line memory 34, the image memory 36, and the video memory 38 can be realized by a relatively inexpensive and large-capacity hard disk.

  As described above, the ultrasonic diagnostic apparatus of FIG. 1 includes the beam memory 32, the line memory 34, the image memory 36, and the video memory 38, and the video data, line data, and image data obtained in different processing stages. It is possible to store video data. In addition, data stored in these memories can be transferred to a computer (not shown) or the like via the communication unit 60.

  Furthermore, in the ultrasonic diagnostic apparatus of FIG. 1, a plurality of types of data obtained at different processing stages are stored in association with each other. That is, a management table showing the correspondence between beam data, line data, and image data is stored in the data management unit 40. Therefore, the association of multiple types of data will be described below. In addition, about the part (structure) already shown in FIG. 1, the code | symbol of FIG. 1 is utilized also in the following description.

  FIG. 2 is a diagram for explaining a management table stored in the data management unit 40. The beam memory 32, the line memory 34, the image memory 36, and the video memory 38 can store data relating to a plurality of images, for example, a plurality of images obtained from a plurality of different subjects. FIG. 2 shows a table for an image number I among a plurality of images.

  Each beam data is specified by a frame number and a beam number. For example, the beam data (f1, b1) is beam data related to the beam number b1 of the frame number f1, and the beam data (f1, b2) is beam data related to the beam number b2 of the frame number f1. The frame number and beam number of the beam data are given by, for example, the beam processor 20 and transmitted to the data management unit 40 via the image processor 30.

  Each line data is also specified by a frame number and a beam number. For example, the line data (f1, b1) is line data related to the beam number b1 of the frame number f1, and the line data (f1, b2) is line data related to the beam number b2 of the frame number f1. The frame number and beam number of the line data are given by, for example, the beam processor 20 and transmitted to the data management unit 40 via the image processor 30.

  Each beam data and each line data obtained from the beam data are associated with each other by a frame number and a beam number. For example, line data (f1, b1) obtained from beam data (f1, b1) is associated with the same frame number and the same beam number.

  Further, each image data is specified by a frame number, and the image data of each frame, beam data belonging to the frame, and line data are associated with each other by the frame number. For example, the image data (f1) is image data related to the frame with the frame number f1, and a plurality of beam data from the beam data (f1, b1) to the beam data (f1, bm) belong to the frame with the frame number f1. A plurality of line data from line data (f1, b1) to line data (f1, bm) belong to the frame of frame number f1.

  Further, in addition to the correspondence relationship between the beam data, the line data, and the image data, an address of a memory that stores these plural types of data may be managed. For example, address information in the beam memory 32 regarding the beam data (f1, b1), address information in the line memory 34 regarding the line data (f1, b1), address information in the image memory 36 regarding the image data (f1), etc. May be added to the table of FIG.

  Note that video data and image data stored in the video memory 38 may be associated with each other. However, since the video data is not necessarily the same frame rate as the image data, for example, the frame number of the image data is associated with the time of the video data corresponding to the frame number.

  Next, a preferred use example of the ultrasonic diagnostic apparatus of FIG. 1 will be described. For example, an ultrasonic image of a moving image related to the subject tissue of the subject is displayed on the display unit 50, and when an intended symptom appears, the examiner freezes the ultrasonic image. In this still state, for example, image data of a frame corresponding to the still timing stored in the image memory 36 is used. Note that transmission and reception of ultrasonic waves by the probe 10 may be stopped according to the freeze operation. Further, the beam processor 20 may be stopped in accordance with the freeze operation to realize the power saving mode.

  When the ultrasonic image is stopped, the examiner sets a moving image period including a target symptom in the vicinity of the stationary timing. For example, the period of the moving image is set by a known method such as time designation or heartbeat designation. When the moving image period is set, the image processor 30 reads out image data of a plurality of frames corresponding to the set period from the image memory 36, and forms a moving image ultrasonic image based on the read image data. In this way, an ultrasonic image corresponding to the period set by the examiner is displayed on the display unit 50. The ultrasonic image during that period may be repeatedly reproduced.

  Furthermore, ultrasonic image data for a period designated by the examiner may be transferred to a computer or the like via the communication unit 60. For example, a plurality of frames of image data corresponding to a set period are read from the image memory 36 and transferred from the communication unit 60 to an external computer. Since a plurality of types of data are associated with each other (see FIG. 2), in addition to the image data of a plurality of frames, beam data, line data, and video data corresponding to the image data of the plurality of frames are transmitted to the communication unit 60. May be transferred to an external computer. For example, data corresponding to the performance and function of the application provided in the transfer destination computer may be selected from the beam data, line data, image data, and video data and transferred to the computer.

  As mentioned above, although preferred embodiment of this invention was described, embodiment mentioned above is only a mere illustration in all the points, and does not limit the scope of the present invention. The present invention includes various modifications without departing from the essence thereof.

  20 beam processor, 30 image processor, 32 beam memory, 34 line memory, 36 image memory, 38 video memory, 40 data management unit.

Claims (5)

A probe having a plurality of vibration elements for transmitting and receiving ultrasonic waves;
A beam forming unit that forms beam data based on signals obtained from a plurality of vibration elements;
A beam processing unit that performs reception processing on beam data to form line data;
An image processing unit that performs image processing on line data to form image data;
A data storage unit that stores at least two types of data associated with each other among the three types of data of beam data, line data, and image data;
Having
An ultrasonic diagnostic apparatus. The ultrasonic diagnostic apparatus according to claim 1,
The beam forming unit forms a plurality of beam data corresponding to a plurality of ultrasonic beams,
The beam processing unit performs reception processing on each of a plurality of beam data to form a plurality of line data,
The data storage unit stores a plurality of beam data and a plurality of line data in which each beam data and each line data obtained from the beam data are associated with each other.
An ultrasonic diagnostic apparatus. The ultrasonic diagnostic apparatus according to claim 2,
The image processing unit forms a plurality of image data corresponding to a plurality of frames,
The data storage unit stores a plurality of beam data, a plurality of line data, and a plurality of image data in which image data of each frame and beam data and line data belonging to the frame are associated with each other.
An ultrasonic diagnostic apparatus. The ultrasonic diagnostic apparatus according to claim 3.
A data management unit for managing a correspondence relationship between the image data of each frame stored in the data storage unit and the beam data and line data belonging to the frame;
An ultrasonic diagnostic apparatus. The ultrasonic diagnostic apparatus according to claim 3.
The image processing unit performs video processing on a plurality of image data to form video data,
The data storage unit stores video data in addition to a plurality of beam data, a plurality of line data, and a plurality of image data.
An ultrasonic diagnostic apparatus.