JP4791727B2 - Ultrasonic diagnostic equipment - Google Patents

Description

  The present invention relates to an ultrasonic diagnostic apparatus that performs ultrasonic imaging of a subject, and more particularly to an ultrasonic diagnostic apparatus that displays and edits icons of image data collected by ultrasonic imaging.

  An ultrasonic diagnostic apparatus transmits an ultrasonic wave generated from an ultrasonic probe into a subject, detects a reflected wave caused by a difference in acoustic impedance of a subject tissue, and obtains an image such as a tomographic image in a living body In recent years, it has been used in various medical fields. This ultrasonic diagnostic apparatus is widely used for diagnosis of a heart, a liver, and the like because real-time image data can be easily obtained by a simple operation by simply bringing an ultrasonic probe into contact with the body surface.

  By the way, in such an ultrasonic diagnostic apparatus, when real-time image data is displayed by performing ultrasonic imaging on a subject, the image data is stored in a cine memory having a predetermined memory capacity. (For example, refer to Patent Document 1). In the cine memory of this patent document 1, when the stored image data reaches the memory capacity, the new image data is overwritten in the memory area where the old image data is stored.

Then, when necessary image data is obtained, the ultrasonic imaging is stopped, and the image data stored in the cine memory is reproduced and displayed at that time, and the image data is stored in another storage memory. If the desired image data cannot be obtained, the same operation is performed again by ultrasonic imaging. After the ultrasonic imaging is completed, the image data stored in the storage memory for each subject is used for analysis for diagnosis, image comparison before and after treatment, and the like.
JP-A-5-49635

  However, in order to edit the required image data from the image data stored in the cine memory of Patent Document 1, it is necessary to reproduce and display from the head or tail of the image data storage area, which is troublesome. .

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an ultrasonic diagnosis in which necessary image data can be easily edited.

To achieve the above object, an ultrasonic diagnostic apparatus according to a first aspect of the present invention includes an ultrasonic probe that transmits / receives ultrasonic waves to / from a subject, and transmission of a drive signal that drives the ultrasonic probe. Transmission / reception means for receiving a reception signal based on ultrasonic reception from the ultrasonic probe, RAW data generation means for generating RAW data based on the reception signal obtained by the transmission / reception means, and the RAW RAW data storage means for storing the RAW data generated by the data generation means; RAW data collection means for collecting and storing desired RAW data from the RAW data generated by the RAW data generation means; image de for generating image data from the RAW data read out from the RAW data storage unit or the RAW data collector A data generating means, the RAW data a plurality of said icons having a display area corresponding to the size of the storage area RAW data is stored in the storage means, and the storage area corresponding to the specified display area of the icons Display means for displaying the image data generated from the RAW data , and the display area is a size of a RAW data area in which the RAW data collected by the RAW data collection means in the storage area is stored And the uncollected display area corresponding to the size of the uncollected data area in which the RAW data not collected by the RAW data collection means in the storage area is stored. It is characterized by.

    According to the present invention, a marker is set to a predetermined range on an icon identified and displayed corresponding to each storage area of image data collected during ultrasonic imaging, and image data is displayed or erased in that range. Thus, it is possible to easily edit useful image data.

  Examples of the present invention will be described.

  Hereinafter, embodiments of the ultrasonic diagnostic apparatus of the present invention will be described with reference to FIGS.

  FIG. 1 is a block diagram showing a configuration of an ultrasonic diagnostic apparatus according to an embodiment of the present invention. The ultrasonic diagnostic apparatus 10 includes an ultrasonic probe 1 that transmits / receives ultrasonic waves to / from a subject P, and a transmission / reception unit 2 that transmits ultrasonic drive signals and receives reflection signals to / from the ultrasonic probe 1. A RAW data generation unit 3 that processes the received signal obtained by the transmission / reception unit 2 to generate RAW data such as B mode RAW data for B mode, color Doppler RAW data for color Doppler, and the RAW data And a RAW data processing unit 4 for processing.

  The ultrasonic diagnostic apparatus 10 also processes a RAW data storage unit 5 that stores RAW data from the RAW data processing unit 4 and a RAW data from the RAW data processing unit 4 and the RAW data storage unit 5 to process a B-mode image. Data, image data generation unit 6 for generating image data such as color Doppler image data, display unit 7 for displaying image data generated in image data generation unit 6, selection of image data generation mode and various command signals An operation unit 8 that performs input and a system control unit 9 that controls the above-described units in an integrated manner are provided.

  The ultrasonic probe 1 is for transmitting and receiving ultrasonic waves by bringing its tip surface into contact with the body surface of the subject P. For example, a plurality of (N) piezoelectric transducers arranged in one dimension are arranged at the tip thereof. Have in part. This piezoelectric vibrator is an electroacoustic transducer, which converts an electric pulse (ultrasonic drive signal) into an ultrasonic pulse (transmitted ultrasonic wave) at the time of transmission, and an ultrasonic reflected wave (from the subject P at reception) ( It has a function of converting received ultrasonic waves into electrical signals (ultrasound received signals).

  The ultrasonic probe 1 is connected to the transmission / reception unit 2 via an N-channel cable connected to N piezoelectric vibrators. The ultrasonic probe 1 includes sector scanning support, linear scanning support, convex scanning support, and the like. The ultrasonic probe 1 is selected from these ultrasonic probes according to the diagnosis site. The case where it is used will be described.

  The transmission / reception unit 2 includes a transmission unit 21 that generates an ultrasonic drive signal for generating transmission ultrasonic waves from the ultrasonic probe 1 and a plurality of channels (N channels) of ultrasonic waves obtained from the piezoelectric vibrator of the ultrasonic probe 1. A receiving unit 22 that performs phasing addition on the received signal is provided.

  The transmission unit 21 includes a rate pulse generator 23, a transmission delay circuit 24, and a pulsar 25. Then, the rate pulse generator 23 of the transmission unit 21 supplies the transmission delay circuit 24 with a rate pulse that determines the repetition period (Tr) of the ultrasonic pulse radiated to the subject P.

  The transmission delay circuit 24 is composed of the same number (N channels) of independent delay circuits as the piezoelectric vibrators used for transmission in the ultrasonic probe 1, and is used for focusing ultrasonic waves to a predetermined depth during transmission. A focusing delay time and a deflection delay time for transmitting ultrasonic waves in a predetermined scanning direction (θ1 to θK) are given to the rate pulse, and the rate pulse is supplied to the pulser 25.

  The pulser 25 has the same number (N channels) of independent drive circuits as the piezoelectric vibrators used for transmission, drives the N piezoelectric vibrators built in the ultrasonic probe 1, and the subject P A drive pulse for emitting transmission ultrasonic waves is generated.

  The reception unit 22 includes an N-channel preamplifier 26, a reception delay circuit 27, and an adder 28. The preamplifier 26 amplifies a minute ultrasonic reception signal from the ultrasonic probe 1 to ensure sufficient S / N. The reception delay circuit 27 receives the ultrasonic beam in a predetermined scanning direction (θ1 to θK) and a focusing delay time for focusing the received ultrasonic wave from a predetermined depth to obtain a narrow received beam width. A deflection delay time for setting the directivity is given to the output of the preamplifier 26, and then sent to an adder 28. In this adder 28, N-channel received signals from the piezoelectric vibrator are added to be combined into one. It is done.

  The RAW data generation unit 3 performs a signal processing for generating B-mode RAW data on the phase-adjusted signal output from the reception unit 22, and performs color processing on the signal. And a color Doppler data generation unit 32 that performs signal processing for generating Doppler RAW data. Then, RAW data such as B-mode RAW data and color Doppler RAW data generated by the RAW data generation unit 3 is output to the RAW data processing unit 4.

  The B-mode data generation unit 31 includes a detector 31-1, a logarithmic converter 31-2, and an A / D converter 31-3. The signal input to the B-mode data generation unit 31 is subjected to envelope detection by the detector 31-1, and then logarithmically converted by the logarithmic converter 31-2. The output from the logarithmic converter 31-2 is A / D converted by the A / D converter 31-3 to generate B-mode RAW data.

  The color Doppler data generation unit 32 includes a Doppler shift detection unit 32-1 that detects a Doppler shift frequency, and a calculation unit 32-2 that processes a signal from the Doppler shift detection unit 32-1 and generates color Doppler RAW data. I have.

  The Doppler shift detector 32-1 includes an oscillator 33-1, a phase shifter 33-2, mixers 34a and 34b, low-pass filters (hereinafter referred to as LPF) 35a and 35b, and A / D converters 36a and 36b. And. The output signal from the receiving unit 22 is input to the first input terminals of the mixers 34a and 34b.

  In addition, the continuous wave output signal from the oscillator 33-1 is supplied to the second input terminal of the mixer 34b, and is also supplied to the phase shifter 33-2. The phase shifter 33-2 has a phase of 90 degrees. It is shifted and sent to the second input terminal of the mixer 34a. The continuous wave output signal from the oscillator 33-1 has a frequency substantially equal to the center frequency of the input signals to the first input terminals of the mixers 34a and 34b, and is synchronized with the rate pulse of the rate pulse generator 23. Signal.

  The outputs of the mixers 34a and 34b are supplied to the LPFs 35a and 35b, the sum component of the input signal frequency of the Doppler shift detector 33 and the output signal frequency of the oscillator 33-1 is removed, and only the difference component is detected. Is done.

  The A / D converters 36a and 36b sample the output signals of the LPFs 35a and 35b at a predetermined sampling period and convert them into digital signals.

  The arithmetic unit 32-2 includes MTI filters 37a and 37b, an autocorrelator 38, and an arithmetic circuit 39. Then, the MTI filters 37a and 37b of the arithmetic unit 32-2 extract only blood flow information from the signal from the Doppler shift detection unit 32-1, and the autocorrelator 38 extracts the Doppler signal. An autocorrelation process is performed, and based on the autocorrelation process result, an arithmetic circuit 39 calculates an average blood flow velocity value, a variance value, and the like to generate color Doppler data.

  The RAW data processing unit 4 collects and stores arbitrary RAW data of the RAW data output from the RAW data generation unit 3 and the RAW data storage unit 41 that sequentially stores the RAW data output from the RAW data generation unit 3. A RAW data collection unit 42. Then, the RAW data stored in the RAW data processing unit 4 until then is erased by registering information about a new subject P or turning off the power of the ultrasonic diagnostic apparatus 10.

  The RAW data storage unit 41 includes a storage circuit 41A that stores the RAW data output from the RAW data generation unit 3, and starts saving the RAW data from the RAW data generation unit 3 by the operation of starting the inspection by the operation unit 8. . Further, the RAW data storage unit 41 has a RAW data storage function for storing RAW data in the storage circuit 41A based on a storage condition of either A type or B type in advance by setting from the operation unit 8. Yes.

  With the A-type RAW data storage function, the storage of subsequent RAW data is stopped when the RAW data stored in the storage circuit 41A reaches a predetermined capacity. In this case, by performing a clear operation from the operation unit 8, the RAW data stored in the storage circuit 41A is deleted, and new RAW data output from the RAW data generation unit 3 after the deletion is stored in the storage circuit 41A. Is done.

  In the case of the B type RAW data storage function, when the RAW data stored in the storage circuit 41A reaches a predetermined capacity, the latest RAW data is overwritten in order from the memory area in which the old RAW data is stored. .

  FIG. 2 shows an example of the configuration of RAW data stored in the storage circuit 41A of the RAW data storage unit 41. The vertical axis represents the array of RAW data corresponding to the scanning directions θ1 to θK, and the horizontal axis represents It corresponds to the direction of sound wave transmission / reception. For example, in the K pieces of RAW data A-1 to AK constituting the B-mode image data for one frame, the RAW data A-1 generated by ultrasonic transmission / reception in the first scanning direction (θ1) Pixels a11 to a1L (each composed of 12 bits) are stored, and scanning information a10 related to the scanning direction (θ1) is stored at the head of these L pixels.

  Similarly, the RAW data A-2 to AK with respect to the second scanning direction (θ2) to the Kth scanning direction (θK) are also scanned information a20 to aK0 and RAW data pixels am1 to amL (m = m = m = m). 2 to K) are stored.

  In the RAW data storage unit 41, the RAW data B-1 to B of the B-mode image data for the next frame and subsequent frames is followed by the RAW data AK obtained for the Kth scanning direction (θK). -K is stored repeatedly.

  Returning to FIG. 1, the RAW data collection unit 42 includes a collection data storage circuit 43 that stores the RAW data generated and output by the RAW data generation unit 3. The collected data storage circuit 43 has a configuration similar to that of the storage circuit 41A shown in FIG. 2, and similarly stores RAW data.

  Then, the RAW data collection unit 42 sets the RAW data collection time T from the operation unit 8 in advance, and then performs the RAW data time collection operation, the RAW data for T time output from the RAW data generation unit 3. Is stored in the collected data storage circuit 43.

  Further, when the RAW data collection unit 42 sets the RAW data collection time T from the operation unit 8 in advance and then performs a freeze operation, the RAW data collection unit 42 stores the storage circuit 41A of the RAW data storage unit 41 between that time and T time before. The RAW data stored in the memory is read out and written into the collected data storage circuit 43.

  Further, the RAW data collection unit 42 collects the RAW data output from the RAW data generation unit 3 between the ON time point and the OFF time point by the operation of turning on and off the RAW data collection switch from the operation unit 8. Has the function of saving.

  Furthermore, the RAW data collection unit 42 displays the icon unit 90 (or 90b) corresponding to the RAW data stored in the collection data storage circuit 43 based on the above-described storage conditions of the A type (or B type). And the RAW data of the collected data storage circuit 43 is edited.

  The RAW data storage unit 5 is configured by a memory device such as a magnetic disk, and is provided for storing RAW data in the collected data storage circuit 43 when a new subject is registered or when the ultrasonic diagnostic apparatus 10 is turned off. Yes. The RAW data stored in the storage circuit 41A and the collected data storage circuit 43 of the RAW data processing unit 4 can be stored in an external storage device (not shown) other than the RAW data storage unit 5.

  The display unit 7 includes a conversion circuit and a monitor (not shown), and the image data generated by the image data generation unit 6 is converted into a video signal by D / A conversion and television format conversion in the internal conversion circuit, and is converted into a CRT or liquid crystal display. Displayed on a monitor such as a panel. Further, the icon unit 90 is displayed together with the image data on the display unit 7 by the operation of the operation unit 8.

  Although not shown, the operation unit 8 stops a transmission ultrasonic wave from the ultrasonic probe 1 on the operation panel and puts it in a standby state, a RAW data time collection switch for collecting RAW data, a RAW data collection switch, and a test start Switches, switches such as RAW data search switches, input devices such as keyboards, trackballs, and mice, and touch command screens, subject information such as patient ID and name, depth of field, scanning width, scanning line density, etc. Conditions, input of various command signals, selection of an image data generation mode, and the like are performed using the input device and the touch command screen.

  The system control unit 9 includes a CPU and a storage circuit (not shown), and stores various input information and selection information supplied from the operation unit 8 in the storage circuit. The CPU controls each unit such as the transmission / reception unit 2, the RAW data generation unit 3, the RAW data processing unit 4, the RAW data storage unit 5, the image data generation unit 6, and the display unit 7 based on such information. Control the entire system.

  Hereinafter, the operation of the ultrasonic diagnostic apparatus according to the embodiment will be described with reference to FIGS. 1 to 7. First, FIG. 3 is a flowchart showing a procedure for collecting RAW data.

  The operator of the ultrasonic diagnostic apparatus 10 sets the image conditions such as the depth of field, the scanning range, the scanning line density, the raw data storage conditions in the raw data storage unit 41, the raw data collection time, etc. Subject information such as the patient ID and name of the sample P is input, and an operation for starting the examination is performed (step S1).

  As a result, the ultrasonic diagnostic apparatus 10 starts ultrasonic imaging and stores the RAW data output from the RAW data generation unit 3 in the RAW data storage unit 41. Then, by applying the ultrasonic probe 1 to the imaging region of the subject P (step S2), the RAW data generation unit 3 generates image data of a B-mode image or a color Doppler image from the signal received by the transmission / reception unit 2. While being stored in the storage circuit 41A of the RAW data storage unit 41, the image of the subject P is displayed on the display unit 7 via the image data generation unit 6 in real time.

  Next, the operator collects RAW data necessary for diagnosis based on the image of the subject P displayed on the display unit 7 (step S3). First, at the time when the first image is displayed on the display unit 7, for example, when a RAW data collection time setting operation is performed from the operation unit 8, the RAW data collection unit 42 performs RAW data between that point and the set time. The first RAW data output from the data generation unit 3 is stored in the collected data storage circuit 43.

  Next, when a RAW data collection time setting operation is performed from the operation unit 8 at the time when the second desired image is displayed on the display unit 7, the RAW data collection unit 42 starts from that point until the set time. In the meantime, the second RAW data output from the RAW data generation unit 3 is stored in the collected data storage circuit 43.

  Similarly, the RAW data collection unit 42 sequentially stores the RAW data from the RAW data generation unit 3 in the collection data storage circuit 43 every time the RAW data collection operation is repeatedly performed from the operation unit 8. When the RAW data collection time setting operation is performed from the operation unit 8 at the time when the M-th image is displayed on the display unit 7, the RAW data collection unit 42 receives the RAW data between that time and after the set time. The Mth RAW data output from the data generation unit 3 is stored in the collected data storage circuit 43.

  When the ultrasonic imaging of the subject P is completed, the ultrasonic imaging is stopped by performing a freeze operation from the operation unit 8 (step S4), and both the RAW data collection unit 42 and the RAW data storage unit 41 are RAW data. The storage of the RAW data output from the generation unit 3 is stopped.

  Next, when a RAW data editing operation is performed from the operation unit 8, the icon unit 90 is displayed on the display unit 7, and the RAW data stored in the collected data storage circuit 43 is edited using the icon unit 90. (Step S5 in FIG. 3).

  Next, the RAW data useful for diagnosis stored in the collected data storage circuit 43 after the editing of the RAW data is stored in the RAW data storage unit 6 by the operation from the operation unit 8 (step S6 in FIG. 3). ).

  Then, after the examination of the subject P is completed, the RAW data stored in the RAW data storage unit 6 is read out and displayed on the display unit 7 through the image data generation unit 6, and is used for diagnosis using various information. be able to.

  FIG. 4 shows the relationship between the RAW data stored in the RAW data processing unit 4 and the icon unit 90 by the RAW data collection operation in step S5 of FIG. 3 when the RAW data storage condition is set to A type in advance. FIG.

  The storage circuit 41A in the RAW data storage unit 41 of the RAW data processing unit 4 has a storage area E1 in which RAW data is stored. The storage area E1 is divided into a storage area E2 in which RAW data generated by the RAW data generation unit 3 during ultrasound imaging is stored, and an unsaved area E3 in which RAW data is not stored.

  The storage area E2 of the storage circuit 41A stores all RAW data output from the RAW data generation unit 3 during ultrasonic imaging. When this is expressed in relation to the RAW data collection unit 42, the first to Mth RAW data areas (in which the same RAW data as the first to Mth RAW data collected in the RAW data collection unit 42 are stored) are stored. 41-1 to 41-M) and an uncollected data area 41C in which RAW data not collected by the RAW data collection unit 42 is stored.

  The collection data storage circuit 43 in the RAW data collection unit 42 of the RAW data processing unit 4 has a collection area E7, and the first to Mth RAW data areas (43-1 to 43-M) are included in the collection area E7. It is preserve | saved and it becomes the uncollected area | region E6 other than that.

  And according to the ultrasonic diagnostic apparatus of an Example, the icon 91 (refer also to FIG. 5 simultaneously) is displayed on the icon part 90 of the display part 7. FIG. The icon 91 includes a display area E4, an unsaved display area E5, an uncollected display area 91C, and first to M-th RAW data display areas (91-1 to 91-M) corresponding to the areas of the storage circuit 41A. It is divided and displayed.

  FIG. 5 is a diagram showing an example of a screen displayed on the display unit 7 by the RAW data editing operation in step S5 of FIG. 3 when the RAW data storage condition is set to A type in advance. On the screen 61 of the display unit 7, an icon unit 90 and an image 61-1 of the subject P corresponding to an instruction from the icon unit 90 are displayed.

  The icon unit 90 includes an icon 91 corresponding to the storage circuit 41A of the RAW data storage unit 41, a collection marker 92 that represents the range of the RAW data display area, a frame marker 93 that specifies an image to be displayed on the screen, and a storage circuit 41A. RAW data storage amount 94 for displaying the RAW data storage capacity.

  In addition, an uncollected display area 91C of the icon 91, first to M-th RAW data display areas (91-1 to 91-M) corresponding to the size of each area of the storage circuit 41A, and an unsaved display area E5 Each of the divided areas is displayed with a color identification such as blue, red, and white.

  The collection marker 92 includes a head marker 92-1 and a tail marker that are movably provided at the head and tail of each display area of the first to M-th RAW data display areas (91-1 to 91 -M) of the icon 91. 92-2 and displayed below the icon 91.

  When the collection marker 92 is moved to the head and tail of the desired RAW data display area by the collection marker moving operation from the operation unit 8 and then a loop reproduction operation is performed from the operation unit 8, the RAW data collection unit 42. Can repeatedly read out the RAW data corresponding to the RAW data display area from the collected data storage circuit 43 and repeatedly reproduce and display it as an image 61-1 on the screen 61 of the display unit 7 via the image data generation unit 6. .

  Further, when the collection marker 92 is moved to the RAW data display area of unnecessary RAW data by the collection marker moving operation from the operation unit 8 and then the RAW data deletion operation is performed from the operation unit 8, the RAW data collection unit 42. Can delete unnecessary RAW data corresponding to the RAW data display area from the collected data storage circuit 43. By the deletion, the RAW data collection unit 42 changes the RAW data display area corresponding to unnecessary RAW data to the uncollected display area 91C.

  The frame marker 93 is provided above the icon 91 so as to be movable between the leading marker 92-1 and the trailing marker 92-2. Then, when the frame marker 93 is moved to a desired RAW data display area by a frame marker moving operation from the operation unit 8 and a frame reproduction operation is performed from the operation unit 8, the RAW data collection unit 42 is moved to the moving position. Corresponding RAW data can be read out from the collected data storage circuit 43 frame by frame and displayed as an image 61-1 on the screen 61 of the display unit 7 via the image data generation unit 6.

  For example, in FIG. 5, the frame marker 93 is positioned at the head of the first RAW data display area 91-1, and the image 61-1 has the first RAW data area 43-1 read from the collected data storage circuit 43. The first RAW data is displayed.

  At this time, desired RAW data is not stored in the collected data storage circuit 43. For example, a desired RAW data is stored between the first RAW data area 41-1 and the second RAW data area 41-2 of the storage circuit 41A. When there is a possibility that data is included, the collection marker 92 is moved to the first RAW data display area 91-1 and the second RAW data display area 91-2 by a RAW data search operation from the operation unit 8. To the uncollected display area 91C.

  Next, when a RAW data collection operation is performed from the operation unit 8, the RAW data storage unit 41 reads out the RAW data stored in the uncollected area 41C of the storage circuit 41A corresponding to the collection marker 92 together with the area information, The data is output to the RAW data collection unit 42. Then, the RAW data collection unit 42 adds the RAW data to the collected data storage circuit 43 and writes it. When a reproduction operation is performed from the operation unit 8 after the additional storage of the RAW data, the RAW data collection unit 42 uses the icon unit 90 in which a new RAW display area is additionally displayed to display the additional RAW data on the screen 61. Can be displayed.

  In the RAW data storage amount 94, the size of the area of the first to M-th RAW data areas (43-1 to 43-M) stored in the collection area E7 of the collected data storage circuit 43 is displayed in%. At the same time, the total number of frames of RAW data stored in the first to M-th RAW data areas (43-1 to 43-M) is displayed.

  FIG. 6 shows the relationship between the RAW data stored in the RAW data processing unit 4 and the icon unit 90b by the RAW data collection operation in step S5 of FIG. 3 when the RAW data storage condition is set to B type in advance. FIG. Here, differences from the A type RAW data storage condition will be described.

  An icon 91b is displayed on the icon part 90b of the display part 7. The icon 91b is divided into a display area E4b corresponding to each area of the collected data storage circuit 43, first to Mth RAW data display areas (91-1 to 91-Mb), and an uncollected display area E5b. .

  FIG. 7 is a diagram showing an example of a screen displayed on the display unit 7 by the RAW data editing operation in step S5 of FIG. 3 when the RAW data storage condition is set to the B type in advance. On the screen 61b of the display unit 7, an icon unit 90b and an image 61-1b of the subject P specified by the icon unit 90b are displayed.

  The icon section 90b includes an icon 91b corresponding to the size of each area of the collected data storage circuit 43, a collection marker 92b indicating the range of the display area of the collected RAW data, and a frame marker 93b for designating an image to be displayed on the screen. And a RAW data storage amount 94b for displaying the RAW data storage capacity E7 of the collected data storage circuit 43.

  The collection marker 92b includes a head marker 92-1b and a tail marker that are movably provided at the head and tail of each display area of the first to M-th RAW data display areas (91-1b to 91-Mb) of the icon 91b. 92-2b and displayed below the icon 91b.

  Then, after the collection marker 92b is moved to the head and tail of the desired RAW data display area by the collection marker moving operation from the operation unit 8, when the loop reproduction operation is performed from the operation unit 8, the RAW data collection unit 42 The RAW data corresponding to the RAW data display area can be repeatedly read from the collected data storage circuit 43 and repeatedly reproduced and displayed on the screen 61 b of the display unit 7 via the image data generation unit 6.

  When the collection marker 92b is moved to the RAW data display area of unnecessary RAW data by the collection marker moving operation from the operation unit 8 and then the RAW data deletion operation is performed from the operation unit 8, the RAW data collection unit 42 is operated. Can delete unnecessary RAW data corresponding to the RAW data display area from the collected data storage circuit 43. By the deletion, the RAW data collection unit 42 changes the RAW data display area corresponding to unnecessary RAW data to the uncollected display area 91C.

  The frame marker 93b is provided on the upper side of the icon 91b so as to be movable between the head marker 92-1b and the tail marker 92-2b. When the frame marker 93b is moved to a desired RAW data display area by a frame marker moving operation from the operation unit 8 and a frame reproduction operation is performed from the operation unit 8, the RAW data collection unit 42 is moved to the moving position. Corresponding RAW data can be read out from the collected data storage circuit 43 frame by frame and displayed as an image 61-1b on the screen 61b of the display unit 7 via the image data generation unit 6.

  According to the embodiment of the present invention described above, a marker is set to a predetermined range on the icon identified and displayed corresponding to each storage area of the RAW data collected during the ultrasonic imaging, and repeated reproduction display of the range is performed. By performing reproduction display for each frame or erasing unnecessary RAW data, it is possible to easily edit useful RAW data. Then, using the useful RAW data, various analyzes can be performed and used for diagnosis.

  If the collected image data is insufficient by operating the icon, the necessary RAW data is added by reading the image data of the portion from the RAW data storage unit and writing it in the RAW data collection unit. By editing, useful RAW data can be easily edited. Then, using the useful RAW data, various analyzes can be performed and used for diagnosis.

1 is a block diagram showing a configuration of an ultrasonic diagnostic apparatus according to an embodiment of the present invention. The figure which shows an example of a structure of the raw data preserve | saved at the memory | storage circuit of the raw data processing part which concerns on the Example of this invention. The flowchart which shows the procedure of the raw data collection which concerns on the Example of this invention. The figure which shows the relationship between the RAW data and the icon of the RAW data processing part in A type RAW data preservation | save conditions concerning the Example of this invention. The figure which shows an example of the screen in the RAW data storage condition of A type which concerns on the Example of this invention. The figure which shows the relationship between the RAW data and the icon of the RAW data processing part in B type RAW data preservation | save conditions based on the Example of this invention. The figure which shows an example of the screen in the RAW data storage condition of B type which concerns on the Example of this invention.

Explanation of symbols

P Subject 2 Transmission / reception unit 3 RAW data generation unit 4 RAW data processing unit 5 RAW data storage unit 6 Image data generation unit 7 Display unit 8 Operation unit 9 System control unit 10 Ultrasound diagnostic device 21 Transmission unit 22 Reception unit 31 B mode Data generation unit 32 Color Doppler data generation unit 41 RAW data storage unit 41A Storage circuit 42 RAW data collection unit 43 Collection data storage circuit 90 Icon unit

Claims (3)

Ultrasonic probe for transmitting / receiving ultrasonic waves to / from a subject, transmission / reception means for transmitting a drive signal for driving the ultrasonic probe, and receiving a reception signal based on ultrasonic reception from the ultrasonic probe RAW data generating means for generating RAW data based on the received signal obtained by the transmitting / receiving means, RAW data storage means for storing the RAW data generated by the RAW data generating means, and the RAW data and RAW data collecting means collecting and storing desired RAW data from the RAW data generated by the generating means, the image data from the RAW data read out from the RAW data storage unit or the RAW data collector and image data generating means for generating a plurality of the RAW data of the RAW data storage means Icon having a display area corresponding to the size of the presence has been conserved regions, and a display means for displaying the image data generated from the RAW data of the storage area corresponding to the specified display area of the icons The display area includes a RAW data display area corresponding to a size of a RAW data area in which the RAW data collected in the RAW data collection means in the storage area is stored, and the RAW data collection in the storage area An ultrasonic diagnostic apparatus characterized in that the raw data not collected by the means is identified as an uncollected display area corresponding to the size of an uncollected data area in which the raw data is stored . The ultrasonic diagnostic apparatus according to claim 1, wherein the icon has an unsaved display area corresponding to a size of an unsaved area in which the RAW data of the RAW data storage unit is not saved . The icon is provided with a collection marker that can move to the head and tail of the RAW data display area or the uncollected display area, and when the collection marker is set in the uncollected display area, the RAW data storage means 3. The ultrasonic diagnostic apparatus according to claim 1, wherein the RAW data corresponding to the uncollected display area set from 1 is read out and stored in the RAW data collection unit. 4.

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