JP4647899B2 - Ultrasonic diagnostic equipment - Google Patents

Description

  The present invention irradiates a subject such as a living body with ultrasonic waves, receives an echo of the ultrasonic waves, performs a three-dimensional scan, and uses image data of a three-dimensional region obtained by the three-dimensional scan, The present invention relates to an ultrasonic diagnostic apparatus that displays a desired tomographic image of a subject on a screen.

  Conventionally, a subject such as a living body is irradiated with ultrasonic waves, and echoes of the ultrasonic waves are spatially received to perform a three-dimensional scan on the subject, and a plurality of two-dimensional images obtained by the three-dimensional scan are obtained. 2. Description of the Related Art An ultrasonic diagnostic apparatus that creates three-dimensional image data of a subject using image data and displays a desired tomographic image of the subject on the screen based on the three-dimensional image data has been developed. The operator operates this ultrasonic diagnostic apparatus to display a desired tomographic image of the subject on the screen, and searches or observes a region of interest in the subject such as a diseased part such as a tumor or a characteristic part in a body cavity. Based on the above, medical treatment such as ultrasonic diagnosis is performed on the patient. With regard to such a technique, when a plurality of two-dimensional image data obtained by performing three-dimensional scanning on a subject is three-dimensionally arranged, a virtual cut surface is set on the plurality of arranged two-dimensional image data In addition, there is a technique that interpolates between a plurality of the two-dimensional image data and displays a tomographic image of the subject on the cut surface on the screen (see Patent Document 1).

JP-A-7-155328

  However, when the ultrasonic diagnostic apparatus described in Patent Document 1 described above interpolates between a plurality of two-dimensional image data obtained by performing three-dimensional scanning, the plurality of two-dimensional image data are parallel to each other. Since it is assumed that they are arranged, the tomographic image of the subject is displayed on the screen almost linearly regardless of the scanning path of this three-dimensional scanning. Therefore, the tomographic image of the subject displayed on the screen by the ultrasonic diagnostic apparatus is often distorted compared to the actual shape of the subject, and the operator uses this ultrasonic diagnostic apparatus. In many cases, it is difficult to obtain a tomographic image of the subject that approximates the actual shape of the subject, and to grasp the shape or size of the region of interest in the subject such as a diseased part such as a tumor. There was a problem.

  The present invention has been made in view of the above, and displays a tomographic image of the subject that approximates the actual shape of the subject on the screen, as well as the region of interest in the subject such as a diseased part such as a tumor. An object of the present invention is to provide an ultrasonic diagnostic apparatus that can easily grasp the shape or size.

In order to solve the above-described problems and achieve the object, an ultrasonic diagnostic apparatus according to claim 1 performs transmission / reception of ultrasonic waves by an ultrasonic transducer disposed at a distal end of a probe and applies to an object in a body cavity. A tomographic image acquisition means for acquiring a plurality of two-dimensional ultrasonic tomographic images; a detecting means for detecting information indicating a reference position of each two-dimensional ultrasonic tomographic image and an orientation of a tomographic plane; Image generating means for generating a belt-like longitudinal section image having a curved surface along the moving path of the ultrasonic transducer based on the orientation and each two-dimensional ultrasonic tomographic image, and the image generating means The straight lines that cut through the two-dimensional ultrasonic tomographic images are set to be the same on the relative coordinate system fixed on the two-dimensional ultrasonic tomographic images , and the pixels on the straight lines are in space. Arranged on a fixed absolute coordinate system, and Characterized in that between the lines to generate an image having a curved surface that occurs when it is interpolated as the band-shaped longitudinal section images.

According to a second aspect of the present invention, in the above invention, the ultrasonic diagnostic apparatus further comprises position specifying means for specifying the position of the straight line indicating the longitudinal section position on the two-dimensional ultrasonic tomographic image.

Further, in the ultrasonic diagnostic apparatus according to claim 3, in the above invention, the position designating unit is configured to display the straight line indicating a longitudinal cross-sectional position before acquiring the two-dimensional ultrasonic tomographic image or after acquiring the two-dimensional ultrasonic tomographic image. The position is designated on the two-dimensional ultrasonic tomographic image .

According to a fourth aspect of the present invention, in the above invention, the ultrasonic diagnostic apparatus further comprises a three-dimensional longitudinal section image generating means for generating a three-dimensional longitudinal section image including the belt-shaped longitudinal section image on one surface.

In the ultrasonic diagnostic apparatus according to claim 5 , in the above invention, the reference position is a position of the ultrasonic transducer, and the orientation of the tomographic plane is the two-dimensional superposition with the reference position as a base point. It is a plane formed by a vector in a predetermined direction on a tomographic plane of an acoustic tomogram and an outer product of the vector in the predetermined direction and a normal vector with the reference position as a base point.

In the ultrasonic diagnostic apparatus according to claim 6 , in the above invention, the relative coordinate is a coordinate having the reference position as an origin and the vector in the predetermined direction, the outer product, and the normal vector as three orthogonal axes. It is characterized by being.

According to a seventh aspect of the present invention, in the above invention, the ultrasonic diagnostic apparatus further comprises display means for displaying at least one of the two-dimensional ultrasonic tomographic image, the belt-like vertical cross-sectional image, and the three-dimensional vertical cross-sectional image. It is characterized by that.

An ultrasonic diagnostic apparatus according to an eighth aspect of the present invention is the ultrasonic diagnostic apparatus according to the above invention, wherein the rotation instruction means instructs rotation of at least one of the belt-like vertical cross-sectional image and the three-dimensional vertical cross-sectional image displayed on the display means. And display processing means for performing display processing of the belt-like vertical cross-sectional image and the three-dimensional vertical cross-sectional image corresponding to the rotation instruction of the rotation instruction means.

In the ultrasonic diagnostic apparatus according to claim 9 , in the above invention, the display unit simultaneously displays at least two of the two-dimensional ultrasonic tomographic image, the belt-like vertical cross-sectional image, and the three-dimensional vertical cross-sectional image. It is characterized by doing.

The ultrasonic diagnostic apparatus according to claim 10 is the above invention, wherein the detection means detects a magnetic field generated from a magnetic field generation source provided in the vicinity of the tip of the probe, thereby detecting each two-dimensional ultrasonic tomographic image. Information indicating the reference position and the orientation of the tomographic plane is detected.

Further, in the ultrasonic diagnostic apparatus according to claim 11 , in the above invention, the tomographic image acquisition unit is configured to scan a plurality of two-dimensional ultrasonic waves along a moving path of the ultrasonic transducer by scanning by hand pulling out the probe. A tomographic image is sequentially obtained, and the image generating means uses the plurality of two-dimensional ultrasonic tomographic images sequentially input from the tomographic image acquiring means, and is successively extended in accordance with a guide for pulling out the probe. A surface image is generated.

The ultrasonic diagnostic apparatus according to claim 12 is the above invention, wherein the display unit displays the two-dimensional ultrasonic tomographic image and the three-dimensional longitudinal cross-sectional image, and the image generation unit includes the three-dimensional image. A straight line indicating the position of the two-dimensional ultrasonic tomographic image on the longitudinal sectional image is displayed on the three-dimensional longitudinal sectional image, and a cut line corresponding to the position of the surface on which the strip-shaped longitudinal sectional image is formed is displayed. When displayed on a two-dimensional ultrasonic tomographic image and then the cut line is rotated, the belt-like longitudinal cross-sectional image and the three-dimensional longitudinal cross-sectional image having the belt-like longitudinal cross-sectional image are displayed according to the rotation of the cut line. Updated, and when the two-dimensional ultrasonic tomographic image is switched to another two-dimensional ultrasonic tomographic image, a straight line indicating the position of the two-dimensional ultrasonic tomographic image is displayed on the three-dimensional longitudinal sectional image. Of two-dimensional ultrasonic tomogram And updates a straight line corresponding to the.

  According to the present invention, the tomographic image acquisition means acquires and detects a plurality of two-dimensional ultrasonic tomographic images of the subject in the body cavity by transmitting and receiving ultrasonic waves by the ultrasonic transducer disposed at the tip of the probe. The means detects information indicating the reference position of each two-dimensional ultrasonic tomographic image and the orientation of the tomographic plane, and the image generating means has the reference position, the orientation of the tomographic plane, and each two-dimensional ultrasonic tomographic image. In addition, since a belt-like longitudinal cross-sectional image having a curved surface along the path of the ultrasonic transducer is generated, even when the probe performs a three-dimensional scan while bending along the shape in the body cavity, Or, even when the probe is three-dimensionally scanned while being twisted depending on the insertion or guidance of the operator, a tomographic image having almost the same shape as the actual subject in the body cavity can be easily acquired. , Characteristic site in body cavity or tumor, etc. An effect that a tomographic image that accurately shape of the desired region of interest, such as a disease site can be realized an ultrasonic diagnostic apparatus to easily display output.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of an ultrasonic diagnostic apparatus according to the present invention will be described in detail with reference to the accompanying drawings. In addition, this invention is not limited by this embodiment.

(Embodiment 1)
FIG. 1 is a block diagram illustrating a schematic configuration of an ultrasonic diagnostic apparatus according to the first embodiment of the present invention. In FIG. 1, the ultrasonic diagnostic apparatus 1 includes a probe 2 having an insertion section 3 to be inserted into a body cavity and an operation section 4 for operating the insertion section 3, an ultrasonic observation apparatus 5, and a receiving antenna 6b. , A position data calculation device 7, an input device 8, a monitor 9, and an image processing device 10. An ultrasonic transducer 3 a is rotatably incorporated at the distal end of the insertion unit 3, and an operation unit 4 is disposed at the rear end of the insertion unit 3. A transmission coil 6a is detachably disposed in the vicinity of the ultrasonic transducer 3a. The operation unit 4 includes a motor 4a, and the motor 4a is connected to the ultrasonic transducer 3a via a shaft 3b. The ultrasonic observation apparatus 5 is electrically connected to the ultrasonic transducer 3a and the motor 4a via a power switch (not shown) provided in the operation unit 4 and a cable. The position data calculation device 7 is electrically connected to the transmission coil 6a and the reception antenna 6b via a cable or the like. The image processing device 10 is electrically connected to the ultrasonic observation device 5, the position data calculation device 7, the input device 8, and the monitor 9 via a cable or the like.

  As described above, the probe 2 is configured by using the insertion portion 3 having the ultrasonic transducer 3a disposed at the tip and the operation portion 4 having the motor 4a incorporated therein, and radially scans the inside of the body cavity (radial scan). To function. In addition, the probe 2 may be provided with an optical system such as an endoscope. In this case, the probe 2 sends data related to the optical image in the body cavity by this optical system to the image processing apparatus 10 for image processing. The apparatus 10 causes the monitor 9 to display an optical image corresponding to the received data on the screen based on the received data regarding the optical image. The insertion portion 3 is realized using a flexible member, and has an elongated cylindrical shape suitable for insertion into a body cavity. The ultrasonic vibrator 3a is realized by using a piezoelectric ceramic such as barium titanate or lead zirconate titanate, and has a function of converting an applied pulse voltage into ultrasonic waves by an inverse piezoelectric effect, A function of converting a reflected wave (echo) into an electrical echo signal by a piezoelectric effect. The shaft 3b is a flexible shaft and functions as a flexible drive shaft that transmits rotational driving by the motor 4a to the ultrasonic transducer 3a.

  The operation unit 4 has a function of bending the distal end of the insertion unit 3 including a portion where the ultrasonic transducer 3a and the transmission coil 6a are arranged according to the operation of the operator. Further, when the operator turns on the power switch of the operation unit 4, the operation unit 4 electrically connects the ultrasonic transducer 3 a and the motor 4 a to the ultrasonic observation device 5, and the ultrasonic observation device 5. Applies a pulse voltage (pulse voltage) of, for example, about 100 [V] to the ultrasonic transducer 3 and a DC drive voltage of, for example, about 12 [V] to the motor 4a. In this case, the ultrasonic transducer 3a outputs an ultrasonic wave using the pulse voltage applied from the ultrasonic observation apparatus 5, receives an echo of the ultrasonic wave, and outputs an echo signal corresponding to the received echo. It is sent to the ultrasonic observation apparatus 5. At the same time, the motor 4a performs rotational driving using the driving voltage applied from the ultrasonic observation device 5, and transmits the rotational driving to the ultrasonic transducer 3a via the shaft 3b. Thus, the motor 4a rotates the ultrasonic transducer 3a with the shaft 3b as a drive shaft.

  Here, when the operator turns on the power switch of the operation unit 4 with the insertion unit 3 inserted into the body cavity, the ultrasonic transducer 3a is driven to rotate about the shaft 3b as a drive axis, and the body cavity The output of ultrasonic waves to the inside and reception of echoes of the ultrasonic waves are repeated. In this case, the ultrasonic transducer 3a performs a radial scan with respect to a plane perpendicular to the insertion axis direction of the insertion portion 3, whereby the probe 2 achieves one radial scan. Thereafter, the ultrasonic transducer 3a repeats this radial scan until the power switch of the operation unit 4 is turned off, and sequentially sends echo signals obtained for each radial scan to the ultrasonic observation apparatus 5. Further, when the probe 2 performing the radial scan is guided by the operator, the ultrasonic transducer 3a performs the radial scan three-dimensionally and scans the body cavity three-dimensionally (three-dimensional scan). To do.

  The ultrasonic observation apparatus 5 is configured using a detection circuit (not shown), an amplification circuit (not shown), an A / D conversion circuit (not shown), a coordinate conversion circuit (not shown), and the like. For echo signals sequentially received from the ultrasonic transducer 3a, known processes such as envelope detection processing, logarithmic amplification processing, A / D conversion processing, and coordinate conversion processing from a polar coordinate system to an orthogonal coordinate system are performed. One two-dimensional image data is sequentially generated for each echo signal received sequentially. Thereafter, the ultrasonic observation apparatus 5 sequentially sends the created two-dimensional image data to the image processing apparatus 10. In addition, when the operator turns on the power switch of the operation unit 4, the ultrasonic observation device 5 applies a pulse voltage of about 100 [V] to the ultrasonic transducer 3 as described above, and the motor A drive voltage of about 12 [V] is applied to 4a.

  The transmission coil 6a is realized by using a first coil in the insertion axis direction of the insertion portion 3 in the body cavity and a second coil in a direction perpendicular to the insertion axis direction, and as described above, the ultrasonic transducer 3a. Near the ultrasonic transducer 3a, for example, at a position about 0.5 to 1 [cm] away from the ultrasonic transducer 3a, and is detachably disposed, and is electrically connected to the position data calculation device 7 via a cable (not shown). Connected. In this case, the transmission coil 6a is fixed so that the distance and direction with respect to the ultrasonic transducer 3a are substantially constant, whereby the positions and directions of the first coil and the second coil are determined by the ultrasonic transducer. 3a is set almost constant. The transmission coil 6a generates a magnetic field in the space around the transmission coil 6a when the position data calculation device 7 supplies current to the first coil and the second coil. In addition, when arrange | positioning in the vicinity of the ultrasonic transducer | vibrator 3a, although the transmission coil 6a may be arrange | positioned so that attachment or detachment is possible, it is desirable to insert in the insertion part 3 so that attachment or detachment is possible. .

  The reception antenna 6b is realized by using a plurality of coils, senses the magnetic field generated by the transmission coil 6a, converts the magnetic field into a current, and then generates an electrical signal (magnetic field signal) corresponding to the current. The data is sent to the position data calculation device 7.

When the operator turns on a power switch (not shown) provided in the position data calculation device 7, the position data calculation device 7 supplies a current to the transmission coil 6 a through a cable or the like, and receives the reception antenna. The magnetic field signal transmitted by 6b is received. Further, the position data calculation device 7 obtains the position vector r of the transmission coil 6a, the unit length axial vector V _a , and the unit length plane parallel vector V _b based on the magnetic field signals sequentially received from the reception antenna 6b. The calculated position vector r, axial vector V _a , and plane parallel vector V _b are sequentially sent to the image processing apparatus 10 as position data regarding the transmission coil 6a.

Here, in the position data calculating device 7, a predetermined position, for example, the center position of the receiving antenna 6b is set as the origin O, a spatial coordinate system xyz composed of the x axis, the y axis, and the z axis is set in advance, and the position vector r is , A vector for determining the position of the transmission coil 6a on the spatial coordinate system xyz. Note that the position vector r can be approximated as a vector for determining the center position of the rotational drive of the ultrasonic transducer 3a due to the transmission coil 6a being disposed in the vicinity of the ultrasonic transducer 3a. On the other hand, the axial vector V _a is calculated on the basis of the magnetic field signal corresponding to the magnetic field output from the first coil of the transmission coil 6a, and is a vector on the spatial coordinate system xyz, It is a unit length direction vector indicating the direction of the insertion axis. Thus, axial vector V _a indicates a direction perpendicular to the plane of the body cavity ultrasonic transducer 3a performs radial scan. The plane parallel vector V _b is calculated on the basis of the magnetic field signal corresponding to the magnetic field output from the second coil of the transmission coil 6a, and is a vector on the spatial coordinate system xyz, which is perpendicular to the insertion axis direction. It is a unit length direction vector indicating a predetermined direction. Therefore, the plane parallel vector _Vb indicates a predetermined direction parallel to the plane in the body cavity where the ultrasonic transducer 3a performs radial scanning. The predetermined direction indicated by the plane parallel vector V _b is always set to a constant direction with respect to the vertical direction indicated by the axial direction vector V _a . This is because the positions and directions of the first coil and the second coil are set to be substantially constant with respect to the ultrasonic transducer 3a as described above.

  The input device 8 is realized by using a keyboard, a touch panel, a trackball, a mouse, a joystick, or the like, or a combination thereof, and a point (designated point) designated on the two-dimensional image data created by the ultrasonic observation device 5. ), The specified point information regarding the coordinate information, angle information specifying the rotation angle of various tomographic images displayed on the screen, instruction information regarding the screen display processing for the monitor 9, and the like are input to the image processing apparatus 10. For example, when a keyboard or a touch panel is used, a numerical value corresponding to designated point information or angle information is input or selected in the input acceptance state of each information, or the coordinate position displayed on the screen of the monitor 9 or the touch panel is set. By directly inputting, specified point information or angle information is input. On the other hand, when a trackball, a mouse, or a joystick is used, in the input acceptance state of each information, a numerical value corresponding to the designated point information is selected or a coordinate position displayed on the screen on the monitor 9 is directly input. The designated point information is input, and a numerical value corresponding to the angle information is selected, or the cursor displayed on the monitor 9 is moved in a predetermined direction while holding down the mouse button (hereinafter referred to as a drag operation). By inputting, angle information is input. For example, if the operator performs this drag operation and the cursor moves in the upward direction on the screen, angle information for rotating the tomographic image in the forward direction is input, and if the cursor moves in the downward direction on the screen, the tomographic image is displayed. Angle information that rotates in the negative direction is input. Alternatively, angle information that rotates the tomogram in the positive direction when the cursor moves to the right of the screen is input, and angle information that rotates the tomogram in the negative direction when the cursor moves to the left of the screen is input. Is done.

  The image processing apparatus 10 is realized by using a known computer including various storage media such as RAM, ROM, or hard disk and a CPU, and includes an image data storage unit 11, a display circuit 12, and a control unit 13. The image data storage unit 11 is realized by using various storage devices capable of writing and reading data, such as various IC memories such as RAM, EEPROM, or flash memory, a hard disk drive, or a magneto-optical disk drive. The image data storage unit 11 stores various image data sent from the control unit 13 under the control of the control unit 13. Further, when the control unit 13 creates various tomographic image data, the image data storage unit 11 stores the various tomographic image data under the control of the control unit 13.

  The control unit 13 is realized by using a ROM that stores various data such as a processing program, a RAM that stores each calculation parameter, a CPU that executes the processing program stored in the ROM, and the like. It has the data calculating part 13b and the cut surface calculating part 13c. The storage unit 13a is configured using the ROM and RAM, and stores position data sequentially received from the position data calculation device 7 by the control unit 13 in addition to the processing program and calculation parameters. The control unit 13 is preset with the spatial coordinate system xyz described above, and the storage unit 13a stores data relating to the spatial coordinate system xyz as reference setting data.

  When the ultrasonic transducer 3a sequentially sends n echo signals obtained by n times (n = 1, 2, 3,...) Radial scan to the ultrasonic observation device 5, the control unit 13 The ultrasonic observation device 5 grasps each timing at which n two-dimensional image data is created based on n echo signals, and grasps the position data sequentially received from the position data calculation device 7 for each timing. To do. Thereafter, the control unit 13 sequentially receives n pieces of two-dimensional image data from the ultrasound observation apparatus 5 and receives the two-dimensional image data created at this timing and the two-dimensional image data at each timing. Association with position data is performed. Thereby, the control unit 13 reliably associates the position data corresponding to the position where the radial scan has been performed with the two-dimensional image data created based on the echo signal by this radial scan.

  FIG. 2 shows the n-th two-dimensional image data that is associated with the position data by the control unit 13 when the control unit 13 sequentially receives n two-dimensional image data from the ultrasound observation apparatus 5. FIG. In the following, the operator inserts the insertion portion 3 into the duodenum of the subject, and then performs a radial scan by the ultrasonic transducer 3a and gradually guides the insertion portion 3 in the insertion axis direction. Although a case where a three-dimensional scan is performed on the subject will be described, this does not limit the present invention.

As shown in FIG. 2, the n-th two-dimensional image data D _n includes a duodenum image En that is a transverse section of the duodenum and a pancreatic duct image Fn that is a transverse section of the pancreatic duct. Control unit 13, as described above, to associate the two-dimensional image data D _n and position data received at the timing was created two-dimensional image data D _n. In this case, the control unit 13 sets the axial vector V _an, as the normal vector of the plane corresponding to the two-dimensional image data D _n, a parallel to this plane, a predetermined direction relative to the axial direction vector V _an, For example, the plane parallel vector V _bn is set as a direction vector indicating the 12 o'clock direction on this plane. The control unit 13 sets the position vector r _n as a position vector indicating the image center C _n of the two-dimensional image data D _n. Thereby, the control unit 13, to the two-dimensional image data D _n, the image center C _n the origin, and an axis parallel to the plane parallel to the vector V axis parallel to the outer product vector _bn (V _bn × V _an) The Cartesian coordinate system can be set. The outer product vector (V _bn × V _an ) is obtained by the outer product of the plane parallel vector V _bn and the axial vector V _an .

The control unit 13 also applies the (n−1) two-dimensional image data D ₁ , D ₂ ,..., D _n-1 sequentially received from the ultrasound observation apparatus 5 to the above-described two-dimensional image data D _n . The position data is associated in the same manner as described above. As a result, the n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n include the axial direction vectors V _a1 , V _a2 , ..., V _an and the plane parallel vectors V _b1 , V _b2,. and _bn, the position vector r _1, r _2, ..., and the r _n are respectively set.

FIG. 3 is a diagram illustrating an operation in which the control unit 13 arranges n pieces of two-dimensional image data associated with position data in the spatial coordinate system xyz. As shown in FIG. 3, when the control unit 13 associates n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n with position data, the spatial coordinates read from the storage unit 13a. Based on the system xyz and position data associated with each two-dimensional image data, the n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n are arranged in a spatial coordinate system xyz. Here, the axial direction vector V _a1, V _a2 constituting the position data, ..., V _an,, plane-parallel vectors _{V b1, V b2, ...,} V bn, and the position vector _{r 1, r 2, ...,} r n Determines each position and each direction of the two-dimensional image data D ₁ , D ₂ ,..., D _n arranged in the spatial coordinate system xyz, so that the control unit 13 makes the ultrasonic transducer 3a three-dimensionally. The n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n can be arranged in the spatial coordinate system xyz so as to be substantially the same as the actual positional relationship in which the radial scan is performed. Thereafter, the control unit 13 stores the n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _{n for} which the arrangement relation in the spatial coordinate system xyz is set in the image data storage unit 11.

  In FIG. 4, after the control unit 13 acquires n pieces of two-dimensional image data and position data, a cutting plane including each designated point is set and a tomographic image (designated tomographic image) of the cutting plane is monitored. 9 is a flowchart for explaining each processing step until a screen is displayed on the screen. In FIG. 4, the ultrasonic observation apparatus 5 creates two-dimensional image data based on the above-described echo signal, and the position data calculation apparatus 7 calculates position data regarding the position where the echo signal is obtained. In this case, the control unit 13 acquires the two-dimensional image data transmitted from the ultrasonic observation device 5 and the position data transmitted from the position data calculation device 7, and as described above, the acquired two-dimensional image data. Is associated with position data (step S101).

Next, the control unit 13 arranges the two-dimensional image data associated with the position data on the spatial coordinate system xyz, and associates the two-dimensional image data with the two-dimensional image data. An orthogonal coordinate system is set based on the axial direction vector and the plane parallel vector (step S102). In this case, as shown in FIG. 2, the control unit 13 sets the image center C _n as the origin and sets the plane parallel vector V _bn to the two-dimensional image data D _n (n = 1, 2, 3,...). Orthogonal coordinate systems A _n B _n are set by a parallel axis (B _n axis) and _an axis (A _n axis) parallel to the outer product vector (V _bn × V _an ).

After that, the control unit 13 stores the two-dimensional image data in which the orthogonal coordinate system is set in the image data storage unit 11 in a state of being arranged on the spatial coordinate system xyz, and also through the display circuit 12, the two-dimensional image. The data is sent to the monitor 9, and a two-dimensional ultrasonic tomographic image corresponding to the two-dimensional image data is displayed on the monitor 9 (step S103). Note that the control unit 13 does not receive the power-off information corresponding to the power-off state of the probe 2 when the probe 2 is performing a radial scan, that is, when the power switch of the operation unit 4 is in the on-state (Step S13). S104, No). In this case, the control part 13 repeats the process process after step S101 mentioned above. That is, when the probe 2 performs n radial scans until the probe 2 is turned off, the control unit 13 repeats the above-described processing steps after step S101 n times. , D _n are obtained, and the above-described orthogonal coordinate system is associated with each of these two-dimensional image data. Further, FIG. 3 shows the correspondence between the two-dimensional image data D ₁ , D ₂ ,. As shown, the obtained n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n are stored in the image data storage unit 11 in a state of being arranged on the spatial coordinate system xyz.

  Next, when the operator turns off the power switch of the operation unit 4 after performing n radial scans, the control unit 13 receives the power-off information of the probe 2 (Yes in step S104). Thereafter, the operator uses the input device 8 to switch the two-dimensional ultrasonic tomographic image displayed on the screen to another two-dimensional ultrasonic tomographic image without performing the above-described input operation of the designated point information ( When the switching instruction information is input, the control unit 13 receives the switching instruction corresponding to the switching instruction information without receiving the designated point information (No at Step S105) (Yes at Step S106). In this case, the control unit 13 reads out the two-dimensional image data stored in the image data storage unit 11 on the basis of the switching instruction based on the switching instruction information received and receives the two-dimensional image data via the display circuit 12. Send to monitor 9. The display circuit 12 performs various processes such as D / A conversion on the two-dimensional image data, and the monitor 9 performs a two-dimensional ultrasonic tomogram corresponding to the two-dimensional ultrasonic tomographic image corresponding to the two-dimensional image data. The screen display is switched to an image (step S107). Then, the control part 13 repeats the process after step S105 mentioned above. If neither the designated point information nor the switching instruction information is input to the control unit 13, the control unit 13 does not accept the designated point information (No in step S105), and issues a switching instruction corresponding to the switching instruction information. Not accepted (No at step S106). In this case, the control part 13 repeats the process after step S105 mentioned above.

  On the other hand, when the operator uses the input device 8 to input the specified point information of two specified points to be specified at each desired position on the desired two-dimensional ultrasonic tomographic image, the control unit 13 receives the input. The designated point information is received (step S105, Yes), and two designated points corresponding to the designated point information for which the input was accepted are set on the orthogonal coordinate system of the two-dimensional image data corresponding to the two-dimensional ultrasonic tomographic image. To do. The two designated points are set on the orthogonal coordinate system of one of the n two-dimensional image data. Based on the coordinate information of the two designated points, the control unit 13 sets two designated points and straight lines passing through the two designated points on each orthogonal coordinate system of the n pieces of two-dimensional image data. At the same time, this straight line is set as the vertical cross-sectional position of the n pieces of two-dimensional image data arranged in the spatial coordinate system xyz. That is, the curved surface passing through the straight line corresponds to a cut surface that forms a longitudinal section of n pieces of two-dimensional image data arranged in the spatial coordinate system xyz. Thereafter, the control unit 13 obtains all the pixels on each obtained straight line and the luminance of each pixel for each two-dimensional image data, and obtains 1 column j rows (j = 1, 2, 3,...). One-column image data is created, and a position vector (pixel position vector) in the spatial coordinate system xyz is set for the pixels in each row of the obtained one-column image data. Accordingly, the control unit 13 sets one-column image data in which the pixel position of each row corresponds to the coordinates of the spatial coordinate system xyz for n pieces of two-dimensional image data (step S108).

  When the control unit 13 sets one-row image data for each two-dimensional image data, the image data calculation unit 13b uses n two-dimensional image data in which the one-row image data is set, and each adjacent one-row image data. The data is linearly interpolated to generate the above-described tomographic image (designated tomographic image) data of the cut surface (step S109). The details of the process (designated tomographic image creation process) in which the image data processing unit 13b creates designated tomographic image data will be described later.

  When the image data calculation unit 13b creates designated tomographic image data, the control unit 13 sends the designated tomographic image data to the monitor 9 via the display circuit 12, and designates the designated tomographic image data corresponding to the designated tomographic image data. Is displayed on the monitor 9 (step S110). FIG. 5 is a diagram illustrating a designated tomographic image displayed on the screen of the monitor 9. As described above, the image data calculation unit 13b creates designated tomographic image data of a cut surface defined as a curved surface including a straight line on n pieces of two-dimensional image data. Therefore, designation corresponding to the designated tomographic image data is performed. As shown in FIG. 5, the tomographic image H is a belt-like longitudinal section having a curved surface or a twist according to the actual movement path or movement direction of the probe 2 that has moved through the body cavity when three-dimensional scanning is performed. Become an image. That is, the designated tomographic image H is less distorted in shape than the subject in the body cavity in which the probe 2 has performed three-dimensional scanning, and can present a tomographic image having the same shape as the actual subject. . For example, when the operator designates the above-described designated points in the duodenum image and pancreatic duct image captured in the two-dimensional ultrasonic tomographic image, the designated tomographic image H is a duodenal tomographic image E having substantially the same shape as the actual duodenum. And a tomographic image F of the pancreatic duct having substantially the same shape as the actual pancreatic duct can be reliably exhibited.

The three-dimensional designated tomographic image H of the curved surface displayed on the screen rotates in a predetermined direction according to an angle corresponding to the angle information when the operator inputs angle information using the input device 8. The operator can easily observe all the tomographic images captured in the designated tomographic image H including the hidden portion even if the designated tomographic image H is twisted or the like. In addition, when the operator inputs instruction information for image enlargement or image reduction using the input device 8, the control unit 13 sets the size according to the input amount by the input device 8 based on the instruction by the instruction information. The designated tomographic image H is enlarged or reduced. Further, when the operator inputs instruction information related to image display using the input device 8, the control unit 13, as shown in FIG. 5, designates the tomographic image H and the two-dimensional image data based on the instruction by the instruction information. The two-dimensional ultrasonic tomographic image G ₁ corresponding to D ₁ may be displayed and output within the same screen.

  In addition, if the operator causes the ultrasonic transducer 3a to perform a radial scan following the step S110 described above and guides the probe 2, the three-dimensional scanning by the ultrasonic transducer 3a is resumed, and the control unit 13 Generates the above-mentioned designated tomographic image data based on the designated point already set in step S201 described above and the two-dimensional image data sequentially obtained by this three-dimensional scanning, A corresponding designated tomographic image is displayed on the monitor 9. In this case, the control unit 13 additionally displays the designated tomographic image created in accordance with the guidance of the probe 2 by the operator with respect to the designated tomographic image H already displayed on the screen of the monitor 9, thereby controlling the tomographic image. The unit 13 sequentially extends the designated tomographic image H in accordance with the guidance operation of the probe 2 by the operator in the three-dimensional scanning.

  Next, each processing step until the control unit 13 achieves a process (one-column image data setting process) for setting one-row image data in n pieces of two-dimensional image data in step S108 described above will be described in detail. explain. FIG. 6 is a flowchart for explaining in detail processing steps until the control unit 13 achieves the one-row image data setting process. FIG. 7 is a diagram illustrating a process in which the control unit 13 sets two designated points and a straight line passing through the two designated points for each two-dimensional image data.

6 and 7, when the operator uses the input device 8 to input designated point information of two designated points designated at each desired position on a desired two-dimensional ultrasonic tomographic image, the control unit 13 Sets the designated points P _m and Q _m corresponding to the designated point information on the orthogonal coordinate system A _m B _{m of} the two-dimensional image data D _m corresponding to the two-dimensional ultrasonic tomographic image. For example, the control unit 13, as shown in FIG. 7, and sets the specified point P _m into coordinates on the orthogonal coordinate system _{A m B m (a 2,} b 2), the coordinates on the orthogonal coordinate system A _m B _m The designated point Q _m is set at (a ₁ , b ₁ ). However, the integer m is an integer satisfying 1 ≦ m ≦ (n−1), and the orthogonal coordinate system A _m B _m has the image center C _m as the origin and the plane parallel vector V _bm as described above. This is an orthogonal coordinate system including a parallel B _m axis and an A _m axis parallel to the outer product vector (V _bm × V _am ).

When the designated points P _m and Q _m are set on the orthogonal coordinate system A _m B _m of the two-dimensional image data D _m as described above, the control unit 13 is adjacent to the two-dimensional image data D _m. Designated points P _{m + 1} and Q _{m + 1} are set on the orthogonal coordinate system A _{m + 1} B _{m + 1 of the} dimensional image data D _{m + 1} . In this case, as shown in FIG. 6, the control unit 13 sets the designated point P _{m + 1} at the coordinates (a ₂ , b ₂ ) on the orthogonal coordinate system A _{m + 1} B _{m + 1} , and the orthogonal coordinate system A designated point Q _{m + 1} is set at coordinates (a ₁ , b ₁ ) on A _{m + 1} B _{m + 1} . Based on such a designated point setting method, the control unit 13 designates n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n as coordinates (a ₂ , b ₂ ) of each orthogonal coordinate system. The points P ₁ , P ₂ ,..., P _n are set, and the designated points Q ₁ , Q ₂ ,..., Q _n are set to the coordinates (a ₁ , b ₁ ) of each orthogonal coordinate system. The control unit 13 achieves a process for setting two designated points for each two-dimensional image data (designated point setting process) (step S201).

Next, the cut surface calculating section 13c, n-number of 2-dimensional image data D _1, D _2, ..., specified points respectively set to _{D n P 1, P 2,} ..., and the coordinate information of the P _n, Using the coordinate information of the designated points Q ₁ , Q ₂ ,..., Q _n , two designated points P _n , Q _n (n = 1, 2, 3,...) Set for each two-dimensional image data are obtained. A straight line L _n (n = 1, 2, 3,...) Passing through is calculated and output (step S202). In this case, on the orthogonal coordinate system A _m B _m of the two-dimensional image data D _m, designated point P _m, the straight line L _m is set to pass through the Q _m, orthogonal coordinate system of the two-dimensional image data D _{m + 1} on a m _{+ 1} B m _{+ 1} linearly L _{m + 1} passing through a designated point _{P m + 1, Q m +} 1 is set. n two-dimensional image data D _1, D _2, ..., the D _n, the straight line L _1, L _2, ..., if L _n is set respectively, cutting plane calculating unit 13c, the straight line L _1, L _2. A plane or curved surface including L _,. In this case, the control unit 13 sets straight lines L ₁ , L ₂ ,..., L _n as the vertical cross-sectional positions of the n pieces of two-dimensional image data arranged in the spatial coordinate system xyz, and the cutting plane calculation unit 13c The calculated curved surface is set as a designated cut surface on which this longitudinal section is formed (step S203).

When the control unit 13 sets straight lines L ₁ , L ₂ ,..., L _n for n pieces of two-dimensional image data, the image data calculation unit 13b sets the straight lines L ₁ , L _{2 ,.} with one row j row of the pixel groups respectively set, to seek the luminance of each pixel of the pixel group, n pieces of the two-dimensional image data D _1, D _2, ..., one row of the first column j rows in D _n pixel data d _1, d _2, ..., to create each d _n (step S204). In this case, one column pixel data d _1, d _2, ..., d _n linearly L _1, L _2, ..., since respectively correspond to L _n, the image data calculation unit 13b, first column pixel data d _1, d _2, ..., a position of each pixel of d _n can be obtained as the pixel position vector in the spatial coordinate system xyz.

For example, two-dimensional image data D _m orthogonal coordinate system A _m designation point P _m, which is set to B _m on the coordinates (a _2, b ₂₎ of the image center C _m and the orthogonal coordinate system A _m B _m space Since it exists on the coordinate system xyz, the position vector OP _m of the designated point P _m in the spatial coordinate system xyz is expressed as follows using the coordinates (a ₂ , b ₂ ) and the position vector r _m of the image center C _m. It is obtained by equation (1).
OP _m = r _m + a ₂ (V _bm × V _am ) + b ₂ V _bm (1)
Similarly, the position vector OQ _m orthogonal coordinate system A _m B _m on the coordinates (a _1, b ₁₎ which is set to the specified point Q _m of the two-dimensional image data D _m, the coordinates (a _1, b ₁₎ and using the position vector r _m of the image center C _m, obtained by the following equation (2).
OQ _m = r _m + a ₁ (V _bm × V _am ) + b ₁ V _bm (2)
Interpolation In this case, each point on the straight line L _m is used and the distance between the distance between the designated point P _m and the specified point Q _m, and equation (1) and (2), linearly in a straight line L _m Or, it is output by extrapolation. That is, the image data calculation unit 13b, by using the distance between the distance and the pixel position of the designated point P _m and the pixel position and the specified point Q _m, equations (1) and a (2), first column pixel data the position of each pixel of the d _m may be determined as a position vector in the spatial coordinate system xyz. Image data calculation unit 13b, first column pixel data d _1, d _2, ..., for d _n, when subjected to the same processing as this, one column pixel data d _1, d _2, ..., each of d _n A pixel position vector of the pixel can be set (step S205).

Next, the designated tomographic image creation process performed by the image data calculation unit 13b in step S109 described above will be described in detail. 8, the image data calculation unit 13b is, n pieces of the two-dimensional image data _{D 1, D 2, ...,} D n 1 row image data are respectively set to d _1, d _2, ..., adjacent each of the d _n It is a figure explaining the process which interpolates between 1 row image data. As shown in FIG. 8, one column image data d _1, d _2, ..., d _n is the two-dimensional image data D _1, D _2, ..., based on the respective axial direction vector and each surface parallel to the vector of D _n , Arranged in the spatial coordinate system xyz. In this case, the designated point _{P 1, P 2, ...,} P n is the two-dimensional image data D _1, D _2, ..., have the same coordinate components for each orthogonal coordinate system on the D _n, the specified point Q _1, Q _2, ..., Q _n is the two-dimensional image data D _1, D _2, ..., we have the same coordinate components for each orthogonal coordinate system on D _n. In FIG. 8, for convenience of explanation in the paper, one column image data d _1, d _2, ..., there d _n is in the same plane, and are drawn parallel to each other, in practice the same is It does not necessarily exist on a plane and does not necessarily be parallel to each other.

Here, the image data calculation unit 13b, a row image data d _1, d _2, ..., when interpolating between each adjacent first column image data d _n, designated point _{P 1, P 2, ...,} P n and The designated points Q ₁ , Q ₂ ,..., Q _n are used as base points, and linear interpolation is performed between adjacent pixels having the same pixel position determined by the number of rows from each base point. For example, as shown in FIG. 8, the image data calculation unit 13b is arranged between adjacent pixels at the same pixel position as the designated points P ₁ , P ₂ ,..., P _n and the designated points Q ₁ , Q _{2 ,.} g between each adjacent pixels in the same pixel position is linearly interpolated, also, f line designated point P _m as a base point (f = 1,2, ..., j ) located in, and the base point specified point Q _m and A pixel located in a row (g = 1, 2,..., J) and a designated point P _{m + 1} as a base point, located in a row f (f = 1, 2,..., J) and a designated point Q _m Linear interpolation is performed on pixels located in g rows (g = 1, 2,..., J) with ₊₁ as a base point. Image data calculation unit 13b, a row image data d _1, d _2, ..., for all pixels that are set on the d _n, by performing the same processing as this, one column image data d _1, d _2, ..., it is possible to interpolate all between each adjacent first column image data d _n, thereby, the image data calculation unit 13b, the straight line L _1, L _2, ..., specified tomographic image data of the cut surface containing L _n Can be created. Note that when the image data calculation unit 13b performs linear interpolation between adjacent pixels of the adjacent one-column image data d _m and d _{m + 1} , the one-column image data d _m between the adjacent pixels having the same pixel position described above. , D _{m + 1} is interpolated with the luminance of each pixel to determine the luminance between the adjacent pixels.

  In the first embodiment, a transmission coil is disposed in the vicinity of the ultrasonic transducer incorporated at the tip of the probe, and the position data calculation device uses the magnetic field output from the transmission coil to generate the ultrasonic wave. The position data of the radial scan by the vibrator has been calculated, but the present invention is not limited to this, and the movement acceleration of the ultrasonic vibrator when the operator pulls the probe is detected and Positional data of radial scan by this ultrasonic transducer may be calculated by performing integration processing of movement acceleration or the like.

  In the first embodiment, a transmission coil that generates a magnetic field is disposed in the vicinity of the ultrasonic transducer in the probe, and the position of the transmission coil is detected when the magnetic field generated by the transmission coil is detected by the reception antenna. However, the present invention is not limited to this, and a transmission coil is provided in place of the position of the reception antenna, and each of the insertion direction of the ultrasonic transducer and the direction perpendicular to the insertion direction is provided. A receiving coil provided with directivity may be arranged in the vicinity of the ultrasonic transducer in the probe, and the position of the receiving coil may be detected.

  As described above, in the first embodiment, a plurality of two-dimensional image data obtained by three-dimensional scanning is associated with position data regarding the position and direction in which the three-dimensional scanning has been performed. A plurality of two-dimensional image data associated with the data are arranged in predetermined spatial coordinates, and then a probe surface in three-dimensional scanning is used as a cut surface on which a longitudinal image of the plurality of two-dimensional image data is formed. When a curved surface corresponding to the moving path or moving direction is set and the tomographic image of the subject is displayed on the cut surface, the probe performs a three-dimensional scan while bending along the shape of the body cavity. Even in this case, even when the 3D scanning is performed while the probe is twisted depending on the operation such as insertion or guidance by the operator, this position data A tomographic image of the subject can be created on the cut surface obtained by accurately tracing the moving path or moving direction of the probe in the three-dimensional scanning based on the plurality of two-dimensional image data associated with the data. An ultrasonic diagnostic apparatus that easily displays and outputs a tomographic image having substantially the same shape as the specimen can be realized. When this ultrasonic diagnostic apparatus is used, the operator can manually insert or guide the probe in the body cavity during the radial scan without inserting or pulling out the probe into the body cavity. A tomogram having substantially the same shape as that of the specimen can be easily obtained, and thereby, intracorporeal ultrasound diagnosis using this tomogram can be performed efficiently.

  In the first embodiment, since a tomographic image having substantially the same shape as that of an actual subject can be easily created, the distance, area, and the like of a desired region of interest such as a characteristic site in a body cavity or a disease site such as a tumor, Alternatively, the volume or the like can be accurately grasped. Further, when the instruction information for rotating the image is input, the tomographic image on the screen display is rotated in a predetermined direction using the rotation angle corresponding to the input amount of the instruction information. The direction can be changed to a desired direction, and the direction of a tomographic image suitable for observation of a region of interest or ultrasonic diagnosis in a body cavity can be easily set. In addition, when instruction information for dramatically or reducing the image is input, the tomographic image on the screen display is enlarged or reduced by a size corresponding to the input amount of the instruction information. It is possible to easily set a tomographic image display suitable for intracorporeal ultrasound diagnosis.

(Embodiment 2)
Next, a second embodiment of the present invention will be described in detail. In the first embodiment described above, the designated tomographic image of the cut plane set based on this designated point information is displayed on the screen after the input of designated point information is performed. In the second embodiment, a default cut plane is set based on preset default point data, a default tomogram created on the default cut plane is displayed on the screen, and input of designated point information is accepted. Thereafter, the default tomographic image is updated to a designated tomographic image.

  FIG. 9 is a block diagram illustrating a schematic configuration of an ultrasonic diagnostic apparatus according to the second embodiment of the present invention. The ultrasonic diagnostic apparatus 21 includes an image processing apparatus 22 instead of the image processing apparatus 10. The image processing apparatus 22 includes a control unit 23 including an update processing unit 23 a instead of the control unit 13. . In addition, default point data 13a-1 is stored in the storage unit 13a in advance. Like the control unit 13, the control unit 23 is realized by using a ROM that stores various data such as processing programs, a RAM that stores each calculation parameter, and a CPU that executes the processing program stored in the ROM. Is done. Other configurations are the same as those of the first embodiment, and the same reference numerals are given to the same components.

  In FIG. 10, the control unit 23 acquires n pieces of two-dimensional image data and position data, and then displays a default tomographic image on the screen based on preset default point data. 5 is a flowchart for explaining each processing step until a designated tomographic image of a cutting plane set based on the above is displayed on the screen of the monitor 9. In FIG. 10, the ultrasonic observation apparatus 5 creates two-dimensional image data based on the above-described echo signal, and the position data calculation apparatus 7 calculates position data regarding the position where the echo signal is obtained. In this case, the control unit 23 associates the two-dimensional image data received from the ultrasound observation apparatus 5 with the position data received from the position data calculation apparatus 7 as in step S101 described above (step S301).

  When the two-dimensional image data and the position data are associated with each other, the control unit 23 arranges the two-dimensional image data associated with the position data on the spatial coordinate system xyz, and the above-described step S102. Similarly, an orthogonal coordinate system is set for the two-dimensional image data (step S302). Thereafter, the control unit 23 stores the two-dimensional image data in which the orthogonal coordinate system is set in the image data storage unit 11 in a state of being arranged on the spatial coordinate system xyz, and similarly to the above-described step S103, the two-dimensional image data is stored. A two-dimensional ultrasonic tomographic image corresponding to the image data is displayed on the monitor 9 (step S303).

  Next, the control unit 23 sets two default points and a default straight line passing through the two default points on the orthogonal coordinate system of the two-dimensional image data based on preset default point data. The default cut plane including the default straight line is set using the two-dimensional image data in which the default straight line is set. Thereafter, the control unit 23 creates one-row image data on the default straight line, creates tomographic image data (default tomographic image data) of a default cut surface based on the one-row image data, and also creates the default tomographic data. A default tomographic image corresponding to the image data is displayed on the monitor 9 (step S304).

Note that the control unit 23 does not receive the power-off information corresponding to the power-off state of the probe 2 when the probe 2 is performing a radial scan, that is, when the power switch of the operation unit 4 is in the on-state (Step S23). S305, No). In this case, the control part 23 repeats the process process after step S301 mentioned above. That is, when the control unit 23 performs the radial scan n times before the probe 2 is turned off, the control unit 23 repeats the above-described processing steps after step S301 n times. , D _n are obtained, and the above-described orthogonal coordinate system is associated with each of these two-dimensional image data. Further, FIG. 3 shows the correspondence between the two-dimensional image data D ₁ , D ₂ ,. As shown, the obtained n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n are stored in the image data storage unit 11 in a state of being arranged on the spatial coordinate system xyz. In addition, the control unit 23 sets a default straight line and a default cut surface for n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n and sets one-row image data on each default straight line. ., D _n of the two-dimensional image data D ₁ , D ₂ ,..., D _n are displayed on the monitor 9 on the screen using the n pieces of the one-row image data.

  Next, when the operator turns off the power switch of the operation unit 4 after performing n radial scans, the control unit 23 receives the power-off information of the probe 2 (Yes in step S305). After that, when the operator inputs the switching instruction information of the two-dimensional ultrasonic tomographic image displayed on the screen without performing the input operation of the specified point information for changing the default point described above using the input device 8, The control unit 23 accepts a switching instruction corresponding to the switching instruction information without accepting designated point information (No at Step S306) (Yes at Step S307). In this case, similarly to step S107 described above, the control unit 23 converts the two-dimensional ultrasonic tomographic image displayed on the monitor 9 into another two-dimensional ultrasonic tomographic image based on the switching instruction based on the received switching instruction information. After that, the control unit 23 repeats the processing steps after step S306.

  If neither the designated point information nor the switching instruction information is input to the control unit 23, the control unit 23 does not accept the designated point information (No in step S306) and issues a switching instruction corresponding to the switching instruction information. Not accepted (step S307, No). In this case, the control part 13 repeats the process process after step S306 mentioned above.

  On the other hand, when the operator uses the input device 8 to input the specified point information related to the specified point for changing at least one of the default points described above, the control unit 23 receives the input specified point information (step S306). , Yes). Next, the control unit 23 designates a default point that has been designated to be changed by inputting the designated point information, among the default points already set in the orthogonal coordinate system of the two-dimensional image data, and the designated point corresponding to the designated point information. In addition, the default straight line and the default cut plane for the default point for which the change is specified are also updated. Further, the control unit 23 updates the one-row image data set in step S304, creates designated tomographic image data using the updated one-row image data, and default tomographic image data created in step S304. Is updated to the designated tomographic image data (step S309).

  Thereafter, the control unit 23 causes the monitor 9 to display the designated tomographic image corresponding to the designated tomographic image data created in step S309 on the screen, similarly to step S110 described above (step S310). The operator observes the designated tomographic image displayed on the monitor 9 and confirms whether or not a desired region of interest is displayed on the monitor 9. When the desired region of interest is not displayed on the screen of the monitor 9, the operator uses the input device 8 to input designated point information for changing a designated point that has already been set. In this case, the control unit 23 receives the designated point information (step S311, Yes), and then the control unit 23 repeats the processing steps after step S309 described above using the designated point information. On the other hand, when the operator observes the designated tomographic image displayed on the screen of the monitor 9 and confirms that the desired region of interest is displayed on the screen of the monitor 9, the operator designates changing the designated point that has already been set. Do not input point information. In this case, the control unit 23 does not accept the designated point information (No at Step S311) and does not update the information on the designated point that has already been set. Therefore, the monitor 9 displays the state where the designated tomographic image is displayed on the screen. maintain. As a result, the operator can observe a desired region of interest displayed on the screen of the monitor 9 and can achieve ultrasonic diagnosis on the subject.

  In addition, if the operator causes the ultrasonic transducer 3a to perform a radial scan following the above-described step S310 and guides the probe 2, the three-dimensional scanning by the ultrasonic transducer 3a is resumed, and the control unit 23 Generates the above-mentioned designated tomographic image data based on the designated point already set in step S501 and the two-dimensional image data sequentially obtained by this three-dimensional scanning, A corresponding designated tomographic image is displayed on the monitor 9. In this case, the control unit 23 additionally displays the designated tomographic image created in accordance with the guidance of the probe 2 by the operator with respect to the designated tomographic image H already displayed on the screen of the monitor 9, thereby controlling the tomographic image. The unit 13 sequentially extends the designated tomographic image H in accordance with the guidance operation of the probe 2 by the operator in the three-dimensional scanning.

Next, the processing steps until the control unit 23 displays the default tomogram on the monitor 9 in step S304 will be described in detail. FIG. 11 is a flowchart for explaining processing steps from when the control unit 23 sets a default straight line based on preset default point data to when a default tomographic image is displayed on the monitor 9. FIG. 12 is a diagram illustrating a process in which the control unit 23 sets two default points and a default straight line passing through the default points in the orthogonal coordinate system on the two-dimensional image data based on the default point data. is there. 11 and 12, when the orthogonal coordinate system A _m B _m is set to the two-dimensional image data D _m associated with the position data, as in step S102 described above, the control unit 23 stores the storage unit The default point data 13a-1 stored in advance in 13a is read, and the default points R _m and S _m corresponding to the default point data 13a-1 are set. For example, the control unit 23, as shown in FIG. 12, to set the default point R _m to the coordinates of the orthogonal coordinate system _{A m B m (a 3,} b 3), an orthogonal coordinate system A _m B _m of coordinates (a Set the default point S _m in ₄ and b ₄ ).

When the default points R _m and S _m are set on the orthogonal coordinate system A _m B _m of the two-dimensional image data D _m as described above, the control unit 23 performs the two-dimensional operation similarly to step S201 described above. on an orthogonal coordinate system a _{m + 1} B _{m + 1} of the two-dimensional image data D _{m + 1} adjacent to the image data D _m, to set the default point _{R m + 1, S m +} 1. In this case, as shown in FIG. 12, the control unit 23 sets the designated point R _{m + 1} at the coordinates (a ₃ , b ₃ ) on the orthogonal coordinate system A _{m + 1} B _{m + 1} , and the orthogonal coordinate system A designated point S _{m + 1} is set at coordinates (a ₄ , b ₄ ) on A _{m + 1} B _{m + 1} . Based on the method of setting such a default point, the control unit 23, n-number of 2-dimensional image data D _1, D _2, ..., the D _n, default the rectangular coordinate system of the coordinates (a _3, b ₃₎ Points R ₁ , R ₂ ,..., R _n are set, and default points S ₁ , S ₂ ,..., _Sn are set to the coordinates (a ₄ , b ₄ ) of each orthogonal coordinate system. The control unit 23 sets two default points for each two-dimensional image data, and, similarly to step S202 described above, default straight lines T ₁ , T ₂ , ..., T _n are set (step S401).

n two-dimensional image data D _1, D _2, ..., the D _n, the default straight line T _1, T _2, ..., if T _n is set respectively, cutting plane calculating unit 13c, the default straight line T ₁ , T ₂ ,..., T _n are calculated and output. In this case, the control unit 23 sets default straight lines T ₁ , T ₂ ,..., T _n as vertical cross-sectional positions of n pieces of two-dimensional image data arranged in the spatial coordinate system xyz, and a cutting plane calculation unit 13c. The curved surface calculated and output by is set as a default cut surface on which the longitudinal section is formed (step S402).

When the control unit 23 sets the default straight lines T ₁ , T ₂ ,..., T _n for n pieces of two-dimensional image data, the image data calculation unit 13b performs the default straight line T as in step S204 described above. ₁ , T ₂ ,..., T _n are set with a pixel group of 1 column and j rows, respectively, and the luminance of each pixel of the pixel group is obtained to obtain n pieces of two-dimensional image data D ₁ , D ₂ ,. D 1 column pixel data d ₁ of the first column j row to _n, d _2, ..., to create each d _n (step S403). Thereafter, the image data calculation unit 13b, created one column pixel data d _1, d _2, ..., for d _n, as in step S205 described above, one column pixel data _{d 1, d 2, ...,} d n sets a pixel position vector of each pixel of the (step S404), 1-column pixel data d _1, d _2, ..., each pixel of the d _n to correspond to the coordinates of the spatial coordinate system xyz.

Space coordinate system one column pixel data d ₁ corresponding to the coordinates of _{xyz, d 2, ..., d} n is the default linear T _1, T _2, ..., when it is set respectively on T _n, the image data calculation unit 13b Is similar to step S109 described above, and linearly interpolates between each adjacent one-line image data to create default tomographic image data on the default cut plane set in step S402 described above (step S405), and thereafter The control unit 23 sends the default tomographic image data to the monitor 9 via the display circuit 12, and displays the default tomographic image corresponding to the default tomographic image data on the monitor 9 (step S406).

FIG. 13 is a diagram illustrating a default tomographic image displayed on the screen of the monitor 9. Since the image data calculation unit 13b creates default tomographic image data of a default cut surface defined as a curved surface including a default straight line on each orthogonal coordinate system of n pieces of two-dimensional image data, similarly to step S109 described above. The default tomographic image H ₀ corresponding to the default tomographic image data corresponds to the actual moving path or moving direction of the probe 2 that has moved in the body cavity when three-dimensional scanning is performed as shown in FIG. It becomes a strip-like longitudinal cross-sectional image having a curved surface. That is, this default tomographic image H ₀ is less in shape distortion and the like than the subject in the body cavity in which the probe 2 has performed three-dimensional scanning, as in the case of the specified tomographic image H described above, and the actual tomographic image. A tomographic image having almost the same shape as the specimen can be presented. For example, when the operator performs a three-dimensional scan using the probe 2 inserted into the duodenum, the default tomogram H ₀ displays a duodenal tomogram E having substantially the same shape as the actual duodenum. Makes it possible to accurately grasp the moving path or moving direction of the probe 2 that is executing the three-dimensional scanning when the three-dimensional scanning is performed while observing the default tomographic image H ₀ , thereby enabling the three-dimensional scanning with peace of mind. Work on.

Further, the operator operates the input device 8 to move the cursor k to the pancreatic duct image F ₁ on the screen using, for example, a mouse, and then presses a mouse button. By this operation, the designated point Q ₁ is set on the pancreatic duct image F ₁ . The operation for setting the designated point is performed in the same manner as in the case of the mouse using the keyboard, the touch panel, the trackball, or the joystick that realizes the input device 8, and thereby the designated point is placed at a desired position on the screen. Is set.

When the operator inputs instruction information related to image display using the input device 8, the control unit 23, based on an instruction based on the instruction information, as shown in FIG. 13, a default tomographic image H ₀ and a two-dimensional image. The two-dimensional ultrasonic tomographic image G ₁ corresponding to the data D ₁ or the latest two-dimensional ultrasonic tomographic image may be displayed and output on the same screen.

Next, when the designated point information for updating at least one of the two preset default points is input in step S309, the control unit 23 sets the designated point corresponding to the designated point information. The processing steps from when the default tomogram is updated to the designated tomogram will be described in detail. FIG. 14 shows details of processing steps from when the control unit 23 sets a designated point for updating the default point based on the inputted designated point information to when the default tomographic image is updated to the designated tomographic image. It is a flowchart to explain. FIG. 15 is a diagram illustrating processing in which the control unit 23 updates the default straight line using designated point information for updating the default point. In the following, n pieces of the two-dimensional image data D _1, D _2, ..., the default point S ₁ which is previously set to D _n, S _2, ..., designated point _{S n Q 1, Q 2,} ..., The case of updating to Q _n will be described, but this does not limit the present invention.

14 and 15, when designated point information for updating desired two-dimensional image data, for example, a default point S _m of the two-dimensional image data D _m to a designated point on the pancreatic duct image F _m is input. 23, as shown in FIG. 12 and FIG. 15, the designated point Q _m corresponding to this designated point information is set to the coordinates (a ₁ , b ₁ ) corresponding to the pancreatic duct image F _m (step S501). , update processing unit 23a deletes the default point S _m. In this case, the control unit 23, similarly to step S201 described above, the two-dimensional image data D _1, D _2, ..., for each orthogonal coordinate system D _n, the coordinates (a _1, b ₁₎ designated point for Q ₁ , Q _2, ..., sets the Q _n, the update processing portion 23a, the default points S _1, S ₂ of the coordinates _{(a 4, b 4),} ..., erases S _n, thereby, the update processing unit 23a, the default point S _1, S _2, ..., designated point Q _1, Q ₂ and S _n, ..., to update each of the Q _n.

When the update processing unit 23a updates the default points S ₁ , S ₂ ,..., _Sn to the designated points Q ₁ , Q ₂ ,..., Q _n , the cut surface calculation unit 13c uses the default points R ₁ , R _2, ..., specified point and R _n Q _1, Q _2, ..., linear L _1, L ₂ passing through each of the Q _n, ..., as well as calculates and outputs the L _n, the update processing unit 23a, the default point R _{1, R 2, ..., R} n and a default point S _1, S _2, ..., linear T _1, T ₂ passing respectively and S _n, ..., erases T _n, thereby, updating processor 23a as shown in FIG. 15, the straight line T _1, T _2, ..., linear L _1, L ₂ and T _n, ..., updates to L _n (step S502).

Next, the cutting plane calculation unit 13c calculates and outputs the specified cutting plane including the straight lines L ₁ , L ₂ ,..., L _n newly set in step S502, and the update processing unit 23a outputs the straight lines T ₁ , T _2, ..., to erase the known default cutting plane containing T _n, thereby, the update processing unit 23a linearly T _1, T _2, ..., lines L ₁ a known default cutting plane containing T _n, Update to a designated cutting plane including L ₂ ,..., L _n (step S503).

When the update processing unit 23a updates the default cutting plane or the designated cutting plane, the image data calculation unit 13b performs the latest specified cutting plane straight lines L ₁ and L in the same manner as the processing steps from step S204 to step S205 described above. ₂ ,..., L _n , the latest one-row image data d ₁ , d ₂ ,..., D _n corresponding to the spatial coordinate system xyz are created, and the update processing unit 23 a designates the default cut plane or the pre-update Clear a column image data of the cut surface, thereby, the update processing unit 23a, the two-dimensional image data D _1, D _2, ..., to achieve the update processing of a row image data created respectively on D _n (Step S504).

2-dimensional image data D _1, D _2, ..., 1-column image data d _1, d ₂ on D _n, ..., when d _n is updated to the latest one column image data, the image data calculation unit 13b is, as in step S109 described above, the latest one column image data d _1, d _2, ..., to create the specified tomographic image data by using the d _n (step S505), the update processing portion 23a, the default tomographic image data Or, the designated tomographic image data before update is deleted. After that, the update processing unit 23a stores the latest designated tomographic image data in the image data storage unit 11 (step S506), thereby performing tomographic image update processing for updating the default tomographic image or the designated tomographic image to the latest data. Achieve.

FIG. 16 is a diagram illustrating a state in which the designated tomographic image updated by the tomographic image updating process is displayed on the screen. The control unit 23 updates a straight line that determines a cut surface of the one two-dimensional image data so as to pass a desired region of interest on the one two-dimensional image data, for example, a pancreatic duct image, and Corresponding to the coordinates, each straight line on the n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n is updated, and as shown in FIG. 15, pancreatic duct images F ₁ , F ₂ ,. _Since the cut plane is determined using a straight line passing over _n , the designated tomographic image which is a tomographic image of the cut plane can easily capture the pancreatic duct tomographic image F as shown in FIG.

In the second embodiment, when the straight line that determines the cut plane of the one two-dimensional image data is updated using the designated point information designated for one two-dimensional image data, the straight line is updated. Each of the straight lines on the n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n has been updated in correspondence with the coordinates, but n pieces of the two-dimensional image data D ₁ , D ₂ ,. , D _n may be updated for each two-dimensional image data without corresponding coordinates to each other. FIG. 17 shows a modification of the second embodiment in which the control unit 23 passes the designated point and the designated point for each two-dimensional image data using the designated point information inputted for each two-dimensional image data. It is a flowchart explaining the processing process after updating a straight line until a new designated tomographic image is stored. FIG. 18 is a diagram illustrating a process in which the control unit 23 updates a designated point and a straight line passing through the designated point for each two-dimensional image data. FIG. 19 is a diagram illustrating a state in which a straight line on two-dimensional image data is updated for each two-dimensional image data.

In FIG. 17, FIG. 18, and FIG. 19, designated point information for updating desired two-dimensional image data, for example, the default point S _m of the two-dimensional image data D _m to a designated point on the pancreatic duct image F _m is input. In this case, the control unit 23 sets the designated point U _m corresponding to the designated point information to the coordinates (a ₅ , b ₅ ) corresponding to the pancreatic duct image F _m (step S601), and the update processing unit 23a The default point S _m is deleted. Next, the cut surface calculating section 13c is configured to calculates and outputs a line L _m which passes through the default point R _m and designated point U _m, the update processing unit 23a passes through the default point and R _m and a default point S _m Clear the straight line T _m to thereby update processing unit 23a updates the linear T _m in the straight line L _m (step S602).

Control unit 23, when performing the steps from step S601 to step S602, one of the two-dimensional image data, for example, to achieve the specified point of the two-dimensional image data D _m and the update processing for the line. Therefore, the operator uses the input device 8 to input switching instruction information for switching the screen display to another two-dimensional ultrasonic tomographic image. In this case, the control unit 23 receives the switching instruction information and accepts a switching instruction based on the switching instruction information (step S603, Yes). Based on the received switching instruction, the control unit 23 switches the two-dimensional ultrasonic tomographic image displayed on the monitor 9 in the same manner as in step S107 described above (step S604). When the operator observes the two-dimensional ultrasonic tomographic image whose display has been switched and changes the default point or designated point set in the two-dimensional ultrasonic tomographic image, the operator uses the input device 8 to relate to this change. Enter the specified point information. In this case, the control unit 23 receives input of the designated point information (step S606, Yes), and then repeats the processing steps after step S601 described above.

Here, when the designated point information for updating the default point S _{m + 1} of the two-dimensional image data D _{m + 1} to the designated point on the pancreatic duct image F _{m + 1} is input, the control unit 23 specifies the designated point information. the designated point Q _{m + 1} corresponding with setting the coordinates (a _1, b ₁₎ which corresponds on pancreatic image F _{m + 1,} the update processing unit 23a deletes the default point S _m. Next, the cut surface calculation unit 13c calculates and outputs a straight line L _{m + 1} passing through the default point R _{m + 1} and the specified point Q _{m + 1,} and the update processing unit 23a outputs the default point R _{m + 1.} And the straight line T _{m + 1} passing through the default point S _{m + 1} is deleted, and the update processing unit 23a updates the straight line T _{m + 1} to the straight line L _{m + 1} . That is, the control unit 23, specifies the process of step S601~ step S605 when repeated n times, n pieces of the two-dimensional image data D _1, D _2, ..., with respect to D _n, each 2-dimensional image data A point and a straight line passing through the designated point can be updated. In this case, as shown in FIG. 19, the control unit 23 can update the straight line passing through the designated point for each two-dimensional image data to a desired position. Thereby, the control unit 23 can surely pass a straight line through the region of interest such as the pancreatic duct on the two-dimensional image data.

  On the other hand, if the control unit 23 has not received the instruction to switch the two-dimensional ultrasonic tomographic image (No at Step S603), the control unit 23 enters the input standby state for the designated point information without performing the process at Step S604. When the operator completes the update of the straight line passing through the designated point and the outside designated point for n pieces of 2D image data, the operator uses the updated designated point information or the like without inputting the designated point information. Is instructed to start the cut surface update process. In this case, the control unit 23 receives the instruction signal for updating the cut surface without accepting the designated point information (step S605, No) (step S606, Yes). In this case, the control unit 23 updates the cutting planes of the n pieces of two-dimensional image data as in step S503 described above (step S607). When the instruction signal for the cut surface update process is not input, the control unit 23 does not receive this instruction signal (No at Step S606), and then repeats the processing steps after Step S603 described above.

When the control unit 23 updates the cut planes of the n pieces of two-dimensional image data, the image data calculation unit 13b corresponds to the spatial coordinate system xyz on each straight line of the latest designated cut plane as in step S504 described above. The update processing unit 23a deletes the one-row image data of the default cut surface or the designated cut surface before the update, and the update processing unit 23a thereby creates a two-dimensional image. Update processing of the one-row image data respectively created on the data D ₁ , D ₂ ,..., D _n is achieved (step S608).

When the one-row image data on the two-dimensional image data D ₁ , D ₂ ,..., D _n is updated to the latest one-row image data, the image data calculation unit 13b performs the latest operation in the same manner as in step S109 described above. The designated tomographic image data is created using the one-row image data (step S609), and the update processing unit 23a deletes the default tomographic image data or the designated tomographic image data before the update. Thereafter, the update processing unit 23a stores the latest designated tomographic image data in the image data storage unit 11 (step S610), thereby performing tomographic image update processing for updating the default tomographic image or the designated tomographic image to the latest data. Achieve.

  In the second embodiment, the case where one default point is updated to a new designated point is exemplified. However, the present invention is not limited to this and is set to two-dimensional image data. Two default points may be changed, or an already set designated point may be changed to a new designated point.

  In the second embodiment, the case where the default point data related to the default point is stored in advance in the storage unit is illustrated. However, the present invention is not limited to this, and before performing three-dimensional scanning. The operator may input default point data.

  As described above, in the second embodiment, two-dimensional image data sequentially obtained by performing three-dimensional scanning is cut at a designated longitudinal section position, and adjacent ones set at the longitudinal section position. Since the linear interpolation is performed between the column image data, and the tomographic image created by the linear interpolation is displayed on the screen simultaneously with the three-dimensional scanning, the position or movement path of the ultrasonic transducer during the three-dimensional scanning is performed. Etc., which makes it easy to determine whether or not the desired region of interest is within the scanning range of the three-dimensional scanning, and provides a sense of security in the operation of the three-dimensional scanning, as well as the ultrasound inside the body cavity. An ultrasonic diagnostic apparatus with improved diagnostic workability can be realized.

  In the second embodiment, when a straight line for determining the longitudinal cross-sectional position of the one two-dimensional image data is updated so as to pass through a desired region of interest located on the one two-dimensional image data, Corresponding to the change in the coordinates of the straight line, each straight line on a plurality of other two-dimensional image data is automatically updated, so that the longitudinal cross-sectional position of the tomographic image can be easily set in a desired region of interest. It is possible to realize an ultrasonic diagnostic apparatus that facilitates an operation of searching for a tomographic image of the region of interest.

  Further, in the modification of the second embodiment, since the straight line for determining the longitudinal cross-sectional position of the two-dimensional image data is configured to be updated for each two-dimensional image data, a desired region of interest is determined for each two-dimensional image data. Even in the case of disorderly positioning, this straight line can be reliably placed in a desired region of interest on the two-dimensional image data, so that a tomographic image that accurately captures the desired region of interest can be easily displayed on the screen. An ultrasonic diagnostic apparatus can be realized.

(Embodiment 3)
Next, a third embodiment of the present invention will be described in detail. In the first embodiment described above, the tomographic image of the cut plane set based on the designated point information regarding the two designated points is displayed on the screen as a two-dimensional tomographic image. In the third embodiment, however. A three-dimensional tomographic image, which is a three-dimensional tomographic image, is displayed on the screen using each two-dimensional ultrasonic tomographic image and designated tomographic image obtained first and last by three-dimensional scanning.

  FIG. 20 is a block diagram illustrating a schematic configuration of an ultrasonic diagnostic apparatus according to the third embodiment of the present invention. The ultrasonic diagnostic apparatus 31 includes an image processing apparatus 32 instead of the image processing apparatus 10. The image processing apparatus 32 is provided with a control unit 33 including a surface image processing unit 33 a instead of the control unit 13. It is done. Like the control unit 13, the control unit 33 is realized by using a ROM that stores various data such as processing programs, a RAM that stores each calculation parameter, and a CPU that executes the processing program stored in the ROM. Is done. Other configurations are the same as those of the first embodiment, and the same reference numerals are given to the same components.

  In FIG. 21, the control unit 33 obtains n pieces of two-dimensional image data and position data, and then sets a cutting plane including each specified point and creates a specified tomographic image of the cutting plane. It is a flowchart explaining each process process until the monitor 9 displays on the screen the three-dimensional tomogram which displayed this designated tomogram three-dimensionally. In FIG. 21, the ultrasonic observation apparatus 5 creates two-dimensional image data based on the echo signal described above, and the position data calculation apparatus 7 calculates position data regarding the position where the echo signal is obtained. In this case, the control unit 33 acquires the two-dimensional image data transmitted from the ultrasound observation apparatus 5 and the position data transmitted from the position data calculation apparatus 7, and the acquired 2 as in the above-described step S101. The correspondence between the dimensional image data and the position data is performed (step S701).

  Next, similarly to step S102 described above, the control unit 33 arranges the two-dimensional image data associated with the position data on the spatial coordinate system xyz and applies the two-dimensional image data to the two-dimensional image data. An orthogonal coordinate system is set based on the axial direction vector and the plane parallel vector associated with the two-dimensional image data (step S702). After that, the control unit 33 stores the two-dimensional image data in which the orthogonal coordinate system is set in the image data storage unit 11 in a state of being arranged on the spatial coordinate system xyz, and via the display circuit 12, the two-dimensional image data is stored. Data is sent to the monitor 9, and a two-dimensional ultrasonic tomographic image corresponding to the two-dimensional image data is displayed on the monitor 9 (step S703).

Here, when the probe 2 is performing a radial scan, that is, when the power switch of the operation unit 4 is on, the control unit 33 does not receive the power-off information corresponding to the power-off state of the probe 2 ( Step S704, No). In this case, the control unit 33 repeats the processing steps after step S701 described above. That is, when the control unit 33 performs n radial scans before the probe 2 is turned off, the control unit 33 repeats the above-described processing steps after step S701 n times. , D _n are obtained, and the above-described orthogonal coordinate system is associated with each of these two-dimensional image data. Further, FIG. 3 shows the correspondence between the two-dimensional image data D ₁ , D ₂ ,. As shown, the obtained n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n are stored in the image data storage unit 11 in a state of being arranged on the spatial coordinate system xyz.

  Next, when the operator turns off the power switch of the operation unit 4 after performing n radial scans, the control unit 33 receives the power-off information of the probe 2 (Yes in step S704). Thereafter, the operator uses the input device 8 to perform the switching instruction information for switching the two-dimensional ultrasonic tomographic image displayed on the screen to another two-dimensional ultrasonic tomographic image without performing the input operation of the designated point information described above. Is input, the control unit 33 receives a switching instruction corresponding to the switching instruction information (Step S706, Yes) without receiving the designated point information (No at Step S705). In this case, the control unit 33 reads the two-dimensional image data stored in the image data storage unit 11 based on the switching instruction based on the switching instruction information received and inputs the two-dimensional image data via the display circuit 12. The image is sent to the monitor 9, and the screen display is switched to a two-dimensional ultrasonic tomographic image corresponding to the two-dimensional image data (step S707). Then, the control part 33 repeats the process after step S705 mentioned above. If neither the designated point information nor the switching instruction information is input to the control unit 33, the control unit 33 does not accept the designated point information (No in step S705), and issues a switching instruction corresponding to the switching instruction information. Not accepted (step S706, No). In this case, the control part 33 repeats the process after step S705 mentioned above.

  On the other hand, when the operator uses the input device 8 to input the specified point information of two specified points that are specified at each desired position on the desired two-dimensional ultrasonic tomographic image, the control unit 33 receives the input. The designated point information is received (step S705, Yes), and two designated points corresponding to the designated point information for which the input was accepted are set in the orthogonal coordinate system of the two-dimensional image data corresponding to the two-dimensional ultrasonic tomographic image. . When the two designated points are set on the orthogonal coordinate system of one of the n two-dimensional image data, the control unit 33 stores the coordinate information of the two designated points as in step S108 described above. In addition, two designated points and straight lines passing through the two designated points are set on each orthogonal coordinate system of the n pieces of two-dimensional image data, and n pieces of 2 arranged in the spatial coordinate system xyz. This straight line is set as the longitudinal section position of the dimensional image data.

  Thereafter, similarly to step S108 described above, the control unit 33 obtains all the pixels on each obtained straight line and the luminance of each pixel for each two-dimensional image data, and 1 column j rows (j = 1). , 2, 3,...), And a pixel position vector in the spatial coordinate system xyz is set for the pixels in each row of the obtained one-column image data. Accordingly, the control unit 33 sets one-column image data in which the pixel position of each row corresponds to the coordinates of the spatial coordinate system xyz for n pieces of two-dimensional image data (step S708).

  When the control unit 33 sets one-row image data for each two-dimensional image data, the image data calculation unit 13b performs n two-dimensional image data in which the one-row image data is set, similarly to step S109 described above. Is used to linearly interpolate between adjacent one-row image data, and the above-mentioned designated tomographic image data of the cut surface is created (step S709).

When the image data calculation unit 13b creates designated tomographic image data, the surface image processing unit 33a uses n pieces of two-dimensional image data D ₁ , D ₂ ,..., D _n arranged in the spatial coordinate system xyz. The two-dimensional image data D ₁ , D ₂ ,..., D _n are linearly interpolated between adjacent two-dimensional image data for the upper end, lower end, and side end. Figure 22 is a surface image processing unit 33a is, two-dimensional image data D _1, D _2, ..., upper portions of the D _n, the lower end, and the side edge portion, between adjacent two-dimensional image data by linearly interpolating, It is a figure explaining the process (surface image creation process) which produces upper surface image data, lower surface image data, and side part surface image data. Incidentally, in FIG. 22, the straight line L _1, L ₂ to determine the cutting plane, ..., L _n 2-dimensional image data D ₁ that has been set respectively, D _2, ..., D _n are arranged in the spatial coordinate system xyz The state which was made is shown typically.

As shown in FIG. 22, a surface image processing unit 33a, the two-dimensional image data D _1, D _2, ..., the upper end of the D _n, the upper surface image data when linear interpolation between adjacent two-dimensional image data create a I _1, 2-dimensional image data D _1, D _2, ..., the lower end of the D _n, to create a lower surface image data I ₂ when linear interpolation between adjacent two-dimensional image data, two-dimensional Side surface image data I ₃ is created when linear interpolation is performed between adjacent two-dimensional image data for the side edges of the image data D ₁ , D ₂ ,..., D _n (step S710). As described above, this cut surface is set as a plane or curved surface including straight lines L ₁ , L ₂ ,..., L _n and is a two-dimensional ultrasonic tomogram corresponding to at least two-dimensional image data D ₁ , D _n. Cut the image.

Next, the surface image processing unit 33a includes the designated tomographic image data H ₁ created by the image data calculation unit 13b in step S709, the upper surface image data I ₁ created by the surface image processing unit 33a in step S710, and the lower surface image. Using the data I ₂ , the side surface image data I _3, and the two-dimensional image data D ₁ and D _n cut by the above-described cutting plane, a three-dimensional tomographic image for displaying a designated tomographic image three-dimensionally Three-dimensional tomographic image data is created (step S711).

FIG. 23 is a diagram for explaining processing (three-dimensional tomographic image creation processing) in which the surface image processing 33a creates three-dimensional tomographic image data. As shown in FIG. 23, a surface image processing 33a connects the 2-dimensional image data D ₁ to the front end of the specified tomographic image data H _1, connecting the two-dimensional image data D _n to the rear end of the specified tomographic image data H ₁ To do. The surface image processing unit 33a, to the upper surface image data I _1, to connect each upper end of the specified tomographic image data H _1, 2-dimensional image data D _1, D _n, and the side surface image data I ₃ The lower end of the designated tomographic image data H ₁ , the two-dimensional image data D ₁ and D _n , and the side surface image data I ₃ is connected to the lower surface image data I ₂ . Accordingly, the surface image processing unit 33a creates three-dimensional tomographic image data. When the surface image processing unit 33a creates three-dimensional tomographic image data, the upper surface image data I ₁ , the lower surface image data I ₂ , the side surface image data I ₃ , the designated tomographic image data H ₁ , and 2 In the dimensional image data D ₁ and D _n , the parts corresponding to the same coordinates in the spatial coordinate system xyz are connected.

When the surface image processing unit 33a creates the three-dimensional tomographic image data, the control unit 33 sends the three-dimensional tomographic image data to the monitor 9 via the display circuit 12, and corresponds to the three-dimensional tomographic image data. A three-dimensional tomographic image is displayed on the monitor 9 (step S712). FIG. 24 is a diagram illustrating a three-dimensional tomographic image displayed on the screen of the monitor 9. As shown in FIG. 24, the three-dimensional tomographic image W includes a duodenal image E _{1 of} the two-dimensional ultrasonic tomographic image G ₁ corresponding to the two-dimensional image data D ₁ , a duodenal tomographic image E of the designated tomographic image H, and a three-dimensional image. Connected to each other, it is observed as a three-dimensional tomographic image. That is, the three-dimensional tomographic image W is less distorted in shape and the like than the subject in the body cavity in which the probe 2 has performed three-dimensional scanning, and exhibits a tomographic image having substantially the same shape as the actual subject. It is possible to capture a tomographic image of the region of interest in the three-dimensional manner. In this case, the operator can easily grasp the state of the region of interest in the body cavity.

Note that when the operator inputs instruction information regarding image display using the input device 8, the control unit 33, as shown in FIG. The sonic tomographic image G ₁ may be displayed and output within the same screen. In this case, the two-dimensional ultrasonic tomographic image G ₁ may be superimposed on the two-dimensional ultrasonic tomographic image G ₁ with the straight line L ₁ that determines the cutting plane as an auxiliary line. The auxiliary line the straight line L _1, it corresponds to L ₁ of the three-dimensional tomographic image W, the operator, by looking at the two-dimensional ultrasonic tomographic image G ₁ and the three-dimensional tomographic image W, 2-dimensional ultrasound It is easy to grasp the positional relationship between the tomographic image G ₁ and the three-dimensional tomographic image W.

  Further, if the operator causes the ultrasonic transducer 3a to perform a radial scan following the above-described step S712 and also pulls the probe 2, the three-dimensional scanning by the ultrasonic transducer 3a is resumed, and the control unit 33 Generates the above-mentioned designated tomographic image data based on the designated point already set in step S708 described above and the two-dimensional image data sequentially obtained by this three-dimensional scanning. A three-dimensional tomographic image having a corresponding designated tomographic image is displayed on the monitor 9 on the screen. In this case, the control unit 33 sequentially performs the specified tomographic image created in accordance with the guidance of the probe 2 by the operator and the three-dimensional scanning on the three-dimensional tomographic image W already displayed on the monitor 9. A three-dimensional tomographic image created based on the obtained two-dimensional ultrasonic tomographic image is additionally displayed, so that the control unit 33 sequentially sequentially according to the guide operation of the probe 2 by the operator in the three-dimensional scanning. The three-dimensional tomographic image W is extended.

  In the third embodiment, the upper surface image, the lower surface image, and the upper surface image, the lower surface image, and the side surface are linearly interpolated with respect to the upper end, the lower end, and the side end of the two-dimensional image data arranged in spatial coordinates. Although the side surface image has been created, the present invention is not limited to this, and image processing such as linear interpolation is performed on all pixels between adjacent two-dimensional image data to obtain an upper surface image and a lower surface. Images and side surface images may be created.

  As described above, in the third embodiment, the two-dimensional ultrasonic wave first obtained by three-dimensional scanning at the front end and the rear end of the specified tomographic image of the cut surface set based on the specified point information. Since the tomographic image and the finally obtained two-dimensional ultrasonic tomographic image are connected to create a three-dimensional tomographic image, compared to the subject in the body cavity where the three-dimensional scanning was performed. The tomographic image has almost the same shape as the actual subject with little distortion of the shape, etc., and the tomographic image of the region of interest in the body cavity can be captured three-dimensionally. An ultrasonic diagnostic apparatus that makes it easy to grasp accurately can be realized. When this ultrasonic diagnostic apparatus is used, the operator can easily observe an image that accurately captures the state of the region of interest in the body cavity, so that it is possible to efficiently perform the ultrasound diagnosis in the body cavity for the patient. .

(Embodiment 4)
Next, a fourth embodiment of the present invention will be described in detail. In Embodiment 3 described above, a three-dimensional tomographic image, which is a three-dimensional tomographic image, is displayed on the screen using each two-dimensional ultrasonic tomographic image and designated tomographic image obtained first and last by three-dimensional scanning. However, in the fourth embodiment, after setting the cutting plane based on the specified point information, the cutting plane is rotated using a preset step angle, and the specified fault on the cutting plane after the rotation is set. A three-dimensional tomographic image, which is a three-dimensional tomographic image, is displayed on the screen using the image and each two-dimensional ultrasonic tomographic image obtained first and last by three-dimensional scanning.

  FIG. 25 is a block diagram illustrating a schematic configuration of an ultrasonic diagnostic apparatus according to the fourth embodiment of the present invention. The ultrasonic diagnostic apparatus 41 includes an image processing apparatus 42 instead of the image processing apparatus 32. The image processing apparatus 42 includes a control unit 43 including an update processing unit 43a instead of the control unit 33. . Like the control unit 33, the control unit 43 is realized using a ROM that stores various data such as processing programs, a RAM that stores each calculation parameter, and a CPU that executes the processing program stored in the ROM. Is done. Other configurations are the same as those of the third embodiment, and the same components are denoted by the same reference numerals.

FIG. 26 is a diagram illustrating a three-dimensional tomographic image and a two-dimensional ultrasonic tomographic image displayed on the screen of the monitor 9. As shown in FIG. 26, this three-dimensional tomographic image W is similar to the above-described third embodiment, and the duodenum image E _{1 of} the two-dimensional ultrasonic tomographic image G ₁ corresponding to the two-dimensional image data D ₁ It is three-dimensionally connected to the duodenal tomogram E of the designated tomogram H. A two-dimensional ultrasonic tomographic image G _m is displayed on the same screen as the three-dimensional tomographic image W. Based on the instruction information input by the operator operating the input device 8, the control unit 43 displays a straight line L _m indicating the position of the two-dimensional ultrasonic tomographic image G _{m in} the three-dimensional tomographic image W as the three-dimensional tomographic image W. Display above. Further, the control unit 43 sets the cut line CL corresponding to the cut surface on which the designated tomographic image H of the three-dimensional tomographic image W is formed on the basis of the instruction information input by the operator operating the input device 8. displayed on tomographic images G _m. Incidentally, the cut line CL is a straight line passing through the image center C _m of the two-dimensional ultrasonic tomographic image G _m.

Here, if the operator operates the input device 8 and inputs instruction information for rotating the cut line CL displayed on the two-dimensional ultrasonic tomographic image G _m in a predetermined direction, the control unit 43 Under the instruction by the instruction information, the step angle θ _s set in advance is read from the storage unit 13a, read in a predetermined direction, for example, counterclockwise, in the positive direction, and the image center C _m as the rotation center. The cut line CL is rotated by an angle θ _s . In this case, the image data calculation unit 13b creates designated tomographic image data of the cut surface corresponding to the rotated cut line CL, and then the update processing unit 43a is the same as in the second embodiment described above. Then, the designated tomographic image data is updated using the created designated tomographic image data as the latest designated tomographic image data. Thereby, the control unit 43 uses the designated tomographic image corresponding to the latest designated tomographic image data updated by the update processing unit 43a and the two-dimensional ultrasonic tomographic images G ₁ and G _n , and the above-described embodiment. As in the case of 3, the three-dimensional tomographic image W is displayed on the screen of the monitor 9. That is, when the control unit 43 rotates the cut line CL, the control unit 43 updates the cut surface according to the rotation of the cut line CL, updates the designated tomographic image of the cut surface, and updates the updated designated tomographic image. Use to reconstruct a 3D tomogram. Thereafter, the control unit 43 updates the screen display to the reconstructed three-dimensional tomographic image.

The operator can input instruction information for rotating the cut line CL in a predetermined direction by the step angle θ _s each time a key on the keyboard is pressed, for example, by pressing a key or a button on the input device 8. Each time this instruction information is input, the cut line CL is rotated in a predetermined direction by the step angle θ _s , and then the above-described three-dimensional tomogram is reconstructed and the screen display of the three-dimensional tomogram is updated. Achieve processing.

Also, the operator operates the input device 8, by entering the instruction information to switch the two-dimensional ultrasonic tomographic image G _m which are displayed in three-dimensional tomographic image W and the same screen, the control unit 43, the instruction Under the instruction by the information, the two-dimensional image data is read from the storage unit 13a, and the screen display is switched to the two-dimensional ultrasonic tomographic image corresponding to the two-dimensional image data. For example, if a two-dimensional ultrasonic tomographic image image G _m two-dimensional ultrasonic tomographic image image G _m-1 to the instruction information to switch the input, the control unit 43, the two-dimensional ultrasonic tomographic image image G _m-1 The corresponding two-dimensional image data 2D _m-1 is read from the image data storage unit 11 and the two-dimensional ultrasonic tomographic image G _m-1 is displayed on the monitor 9 on the screen. In this case, the update processing unit 43a is configured to update the screen display of the two-dimensional ultrasonic tomographic image from the two-dimensional ultrasonic tomographic image image G _m in a two-dimensional ultrasonic tomographic image image G _m-1, 3-dimensional tomographic image W update straight line L _m which is shown above the straight line L _m-1. Similarly, if instruction information for switching the two-dimensional ultrasonic tomographic image image G _m in a two-dimensional ultrasonic tomographic image image G _{m + 1} is input, the control unit 43, two-dimensional ultrasonic tomographic image image G _{m + 1} 2D image data 2D _{m + 1} corresponding to is read from the image data storage unit 11 and the two-dimensional ultrasonic tomographic image G _{m + 1} is displayed on the monitor 9. In this case, the update processing unit 43a is configured to update the screen display of the two-dimensional ultrasonic tomographic image from the two-dimensional ultrasonic tomographic image image G _m in a two-dimensional ultrasonic tomographic image image G _{m + 1,} 3-dimensional tomographic image W The straight line L _m displayed above is updated to a straight line L _{m + 1} .

That is, if the operator inputs instruction information for switching the screen display of the two-dimensional ultrasonic tomogram every time the key of the input device 8 is pressed or a button is pressed, for example, a key on the keyboard, the control unit 43 causes the instruction to Each time information is input, the screen display of the two-dimensional ultrasonic tomogram is updated, and a new two-dimensional super image whose screen display is updated with respect to the straight line L _m displayed on the three-dimensional tomogram W. A process of updating the acoustic tomogram to a straight line indicating the position in the three-dimensional tomogram W is performed. Further, the operator, by a key operation or a button operation of the input device 8, for example by entering the command information to update the straight line L _m which is displayed on the three-dimensional tomographic image in each press a key on the keyboard, the control unit 43 Each time this instruction information is input, the straight line L _m is updated to another straight line (for example, straight lines L _m−1 , L _{m + 1} ), and the position of the updated straight line in the three-dimensional tomographic image W is updated. The screen display can be updated to a binary ultrasonic tomographic image corresponding to.

  Further, after the three-dimensional tomographic image and the two-dimensional ultrasonic tomographic image are displayed on the same screen, if the operator causes the ultrasonic transducer 3a to perform a radial scan and guides the probe 2, ultrasonic waves The three-dimensional scanning by the vibrator 3a is resumed, and the control unit 43 creates designated tomographic image data based on the designated point that has already been set and the two-dimensional image data obtained sequentially by this three-dimensional scanning, A three-dimensional tomographic image having the designated tomographic image data is displayed on the monitor 9 on the screen. In this case, the control unit 43 sequentially performs the specified tomographic image created according to the guidance of the probe 2 by the operator and the three-dimensional scanning on the three-dimensional tomographic image W already displayed on the monitor 9. A three-dimensional tomographic image created based on the obtained two-dimensional ultrasonic tomographic image is additionally displayed, so that the control unit 43 sequentially sequentially according to the guide operation of the probe 2 by the operator in the three-dimensional scanning. The three-dimensional tomographic image W is extended.

  As described above, in the fourth embodiment, a three-dimensional tomographic image created based on a plurality of two-dimensional image data and a two-dimensional image corresponding to any one of the two-dimensional image data. The ultrasonic tomographic image is displayed and output on the same screen, and a straight line corresponding to the position of the two-dimensional ultrasonic tomographic image in the three-dimensional tomographic image is displayed on the three-dimensional tomographic image. The cut line corresponding to the cut surface of the designated tomographic image possessed by is displayed on the two-dimensional ultrasonic tomographic image, and further, when this cut line is rotated, the cut surface corresponding to the rotated cut line The three-dimensional tomographic image is updated so as to have the designated tomographic image, and when this two-dimensional ultrasonic tomographic image is switched to another two-dimensional ultrasonic tomographic image, the straight line on the three-dimensional tomographic image is separated. 3D tomogram of 2D ultrasonic tomogram Since it is configured to update to a straight line corresponding to the position in the operator, it is easy for the operator to grasp the mutual positional relationship between the three-dimensional tomographic image displayed on the same screen and the two-dimensional ultrasonic tomographic image. An ultrasonic diagnostic apparatus that can easily display and output a tomographic image that accurately captures a region of interest such as a characteristic site in a body cavity or a diseased site such as a tumor can be realized. An operator can easily find a desired region of interest by using this ultrasonic diagnostic apparatus.

1 is a block diagram illustrating a schematic configuration of an ultrasound diagnostic apparatus that is Embodiment 1 of the present invention. It is a figure which illustrates the two-dimensional image data matched with position data. It is a figure explaining the operation | movement which arranges the two-dimensional image data matched with position data to a space coordinate. It is a flowchart explaining each processing process until the ultrasonic diagnostic apparatus which is Embodiment 1 of this invention displays a designated tomogram on the screen. It is a figure which illustrates the designated tomogram displayed on the screen. It is a flowchart explaining in detail a processing process until the ultrasonic diagnostic apparatus which is Embodiment 1 of this invention achieves a one-row image data setting process. It is a figure explaining the process which the ultrasonic diagnostic apparatus which is Embodiment 1 of this invention sets two designated points and the straight line which passes through these two designated points for every two-dimensional image data. It is a figure explaining the process which interpolates between adjacent 1 row image data. It is a block diagram which illustrates schematic structure of the ultrasonic diagnosing device which is Embodiment 2 of this invention. It is a flowchart explaining each processing process until the ultrasonic diagnostic apparatus which is Embodiment 2 of this invention displays a designated tomogram on a screen. It is a flowchart explaining the processing process until the ultrasound diagnosing device which is Embodiment 2 of this invention displays a default tomogram on a screen. It is a figure explaining the process which sets two default points and the default straight line which passes through this default point. It is a figure which illustrates the default tomogram displayed on the screen. It is a flowchart explaining in detail the processing process until the ultrasound diagnosing device which is Embodiment 2 of this invention updates a default tomogram to a designated tomogram. It is a figure explaining the process which updates a default straight line. It is a figure which illustrates the state where the updated designated tomogram was displayed on the screen. It is a flowchart explaining the processing process until the ultrasonic diagnostic apparatus of the modification of this Embodiment 2 memorize | stores a new designated tomogram. It is a figure explaining the process which updates the designated point and the straight line which passes through this designated point for every two-dimensional image data. It is a figure explaining the state in which the straight line on 2D image data was updated for every 2D image data. It is a block diagram which illustrates schematic structure of the ultrasonic diagnosing device which is Embodiment 3 of this invention. It is a flowchart explaining each processing process until the ultrasound diagnosing device which is Embodiment 3 of this invention displays a three-dimensional tomogram on a screen. It is a figure explaining surface image creation processing. It is a figure explaining a three-dimensional tomographic image creation process. It is a figure which illustrates the three-dimensional tomogram displayed on the screen. It is a block diagram which illustrates schematic structure of the ultrasonic diagnosing device which is Embodiment 4 of this invention. It is a figure which illustrates the three-dimensional tomogram and the two-dimensional ultrasonic tomogram which the ultrasound diagnostic apparatus which is Embodiment 4 of this invention displayed on the screen.

Explanation of symbols

1, 21, 31, 41 Ultrasonic diagnostic apparatus 2 Probe 3 Insertion section 3a Ultrasonic transducer 3b Shaft 4 Operation section 4a Motor 5 Ultrasonic observation apparatus 6a Transmission coil 6b Reception antenna 7 Position data calculation apparatus 8 Input apparatus 9 Monitor 10 , 22, 32, 42 Image processing device 11 Image data storage unit 12 Display circuit 13, 23, 33, 43 Control unit 13a Storage unit 13b Image data calculation unit 13c Cutting plane calculation unit 23a, 43a Update processing unit 33a Surface image processing unit

Claims (12)

A tomographic image acquisition means for acquiring a plurality of two-dimensional ultrasonic tomographic images of a subject in a body cavity by performing transmission / reception of ultrasonic waves by an ultrasonic transducer disposed at a tip of a probe;
Detecting means for detecting information indicating the reference position of each two-dimensional ultrasonic tomographic image and the orientation of the tomographic plane;
Image generating means for generating a belt-like longitudinal cross-sectional image having a curved surface along the movement path of the ultrasonic transducer based on the reference position, the orientation of the tomographic plane, and each two-dimensional ultrasonic tomographic image; Prepared,
The image generating means is set so that the straight line that cuts through each two-dimensional ultrasonic tomographic image is the same on a relative coordinate system fixed on the two-dimensional ultrasonic tomographic image , and on each straight line . An ultrasonic wave characterized in that an image having a curved surface generated when a certain pixel is arranged on an absolute coordinate system fixed in a space and is interpolated between the straight lines is generated as the band-shaped longitudinal section image. Diagnostic device.   The ultrasonic diagnostic apparatus according to claim 1, further comprising position specifying means for specifying the position of the straight line indicating the longitudinal section position on the two-dimensional ultrasonic tomographic image. The position specifying means specifies the position of the straight line indicating the longitudinal sectional position on the two-dimensional ultrasonic tomographic image before acquiring the two-dimensional ultrasonic tomographic image or after acquiring the two-dimensional ultrasonic tomographic image. The ultrasonic diagnostic apparatus according to claim 2.   The ultrasonic diagnostic apparatus according to claim 1, further comprising a three-dimensional longitudinal section image generating unit configured to generate a three-dimensional longitudinal section image including the belt-shaped longitudinal section image on one surface.   The reference position is the position of the ultrasonic transducer, and the orientation of the tomographic plane is a vector in a predetermined direction on the tomographic plane of the two-dimensional ultrasonic tomographic image with the reference position as a base point, and the predetermined direction. 5. The ultrasonic diagnostic apparatus according to claim 1, wherein the ultrasonic diagnostic apparatus is a plane formed by an outer product of a vector and a normal vector having the reference position as a base point.   The ultrasonic diagnostic apparatus according to claim 5, wherein the relative coordinates are coordinates having the reference position as an origin and the vector in the predetermined direction, the outer product, and the normal vector as three orthogonal axes. .   7. The display device according to claim 1, further comprising a display unit configured to display at least one of the two-dimensional ultrasonic tomographic image, the belt-like longitudinal sectional image, and the three-dimensional longitudinal sectional image. Ultrasound diagnostic equipment. Rotation instruction means for instructing rotation on at least one of the strip-like longitudinal cross-sectional image and the three-dimensional longitudinal cross-sectional image displayed on the display means;
Display processing means for performing display processing of the belt-like vertical cross-sectional image and the three-dimensional vertical cross-sectional image corresponding to the rotation instruction of the rotation instruction means;
The ultrasonic diagnostic apparatus according to claim 7, further comprising:   The ultrasonic diagnosis according to claim 7 or 8, wherein the display unit simultaneously displays at least two of the two-dimensional ultrasonic tomographic image, the belt-like vertical cross-sectional image, and the three-dimensional vertical cross-sectional image. apparatus.   The detection means detects information indicating a reference position of each two-dimensional ultrasonic tomographic image and an orientation of a tomographic plane by detecting a magnetic field generated from a magnetic field generation source provided near the tip of the probe. The ultrasonic diagnostic apparatus according to any one of claims 1 to 9. The tomographic image acquisition means sequentially acquires a plurality of two-dimensional ultrasonic tomographic images along the movement path of the ultrasonic transducer by scanning by hand pulling out the probe,
The image generation unit generates a band-like longitudinal cross-sectional image that is sequentially extended according to a guide for pulling out the probe, using the plurality of two-dimensional ultrasonic tomograms sequentially input from the tomogram acquisition unit. The ultrasonic diagnostic apparatus according to claim 1, wherein the ultrasonic diagnostic apparatus is characterized in that The display means displays the two-dimensional ultrasonic tomographic image and the three-dimensional longitudinal section image;
The image generating means displays a straight line indicating the position of the two-dimensional ultrasonic tomographic image on the three-dimensional longitudinal sectional image on the three-dimensional longitudinal sectional image, and a surface on which the belt-like longitudinal sectional image is formed When the cut line corresponding to the position of the cut line is displayed on the two-dimensional ultrasonic tomographic image and then the cut line is rotated, the belt-like vertical cross-sectional image and the belt-like vertical cross-sectional image according to the rotation of the cut line When the two-dimensional ultrasonic tomographic image is switched to another two-dimensional ultrasonic tomographic image, a straight line indicating the position of the two-dimensional ultrasonic tomographic image is updated. The ultrasonic diagnostic apparatus according to claim 7, wherein the ultrasonic diagnostic apparatus updates a straight line corresponding to a position of the another two-dimensional ultrasonic tomographic image on a three-dimensional longitudinal cross-sectional image.

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