JP2014018365A - X-ray apparatus and control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simultaneously perform IF adjustment for an X-ray tube and a bulb warm-up.SOLUTION: An X-ray apparatus 100 includes: an X-ray generating part 22 having an X-ray tube for generating an X-ray; a tube current measuring part 8 for measuring the tube current of the X-ray tube; an IF value setting part 7 for setting a filament current value (IF value) of the X-ray tube in radiography in an IF adjustment mode, and updating the IF value on the basis of the comparison result between a measured value of the tube current measured by the tube current measuring means in the radiography based on the IF value and a tube current under a preset standard irradiation condition; a standard IF value storage 6 for saving the updated IF value as a standard IF value; a warm-up characteristic calculating part 10 for calculating a bulb warm-up characteristic of the X-ray tube on the basis of the measurement result of the tube current; and a warm-up characteristic display part 11 for displaying the calculation result of the bulb warm-up characteristic.

Description

  Embodiments described herein relate generally to an X-ray apparatus and a control program capable of automatically adjusting a filament current of an X-ray tube necessary for X-ray irradiation on a subject.

  Medical image diagnosis using an X-ray CT apparatus or an X-ray diagnostic apparatus has made rapid progress with the development of computer technology, and is indispensable in today's medical care. The X-ray CT system enables real-time display of image data by increasing the speed and performance of the X-ray detector and arithmetic processing unit. In addition, the helical scan method and multi-slice scan method can be used to develop multiple slice sections. Image data can be collected in a short time. By applying the above-described scanning method, the time required for collecting image data in a wide area in the slice direction (the body axis direction of the subject) has been dramatically reduced, and the examination efficiency has been greatly improved. On the other hand, X-ray diagnostic apparatuses have progressed with the development of catheter techniques, etc., mainly in the circulatory organ region, and are widely used for the entire arteries and veins including the cardiovascular system.

  Such an X-ray CT apparatus and an X-ray diagnostic apparatus (hereinafter collectively referred to as an X-ray apparatus) include an X-ray generation unit that irradiates the subject with X-rays, and an X transmitted through the subject. The unit includes a projection data generation unit that detects lines and generates projection data, and an image data generation unit that generates image data based on the projection data.

  And when a time-dependent change generate | occur | produces in the tube current output from the X-ray tube with which the above-mentioned X-ray generation part is provided, it has the problem that it becomes impossible to collect quality image data. For this reason, a service engineer who is in charge of maintenance of the X-ray apparatus, for example, visits the customer at the regular inspection every three months to maintain the tube current at a predetermined value by adjusting the filament current of the X-ray tube. The method has been carried out.

  In recent years, in order to reduce the burden on service engineers during periodic inspections and the cost of periodic inspections, a dedicated unit with an automatic filament current adjustment function has been provided, and the tube current can be reduced by operating this automatic adjustment function in a timely manner. X-ray devices that can be stabilized have been proposed.

JP 2011-147806 A

  According to the method of Patent Document 1 in which the filament current is automatically adjusted, X-ray imaging using an X-ray tube having good characteristics is possible even if a service person performing maintenance does not frequently visit customers such as medical facilities. Can always be performed.

  However, in such a method, the tube warm-up of the X-ray tube and the adjustment of the filament current, which are performed prior to the X-ray imaging, are performed independently over a relatively long time, so that a long downtime ( The time during which X-ray imaging by the X-ray apparatus is impossible) occurs, and the inspection efficiency is remarkably lowered.

  The present disclosure has been made in view of the above-described problems. The purpose of the present disclosure is to adjust the filament current to the tube warm-up of the X-ray tube performed before the X-ray imaging in the main imaging mode for the subject. An object of the present invention is to provide an X-ray apparatus and a control program capable of efficiently performing X-ray imaging in the main imaging mode having high accuracy by performing simultaneously.

  In order to solve the above problems, an X-ray apparatus of the present disclosure includes an X-ray generation unit having an X-ray tube that generates X-rays, a tube current measurement unit that measures a tube current of the X-ray tube, and an IF The filament current value (IF value) of the X-ray tube in the X-ray imaging in the adjustment mode is set, and the measured value of the tube current measured by the tube current measuring means in the X-ray imaging based on the IF value is set in advance. IF value setting means for updating the IF value based on a comparison result with the tube current of the set standard irradiation condition, standard IF value storage means for storing the updated IF value as a standard IF value, and the tube The apparatus includes a warm-up characteristic calculating unit that calculates a tube warm-up characteristic of the X-ray tube based on a current measurement result, and a display unit that displays the calculation result of the tube warm-up characteristic. .

1 is a block diagram showing the overall configuration of an X-ray apparatus in the present embodiment. The block diagram which shows the specific structure of the X-ray imaging part with which the X-ray apparatus of this embodiment is provided. The figure for demonstrating the tube voltage and tube current of IF adjustment mode set by the standard irradiation condition setting part of this embodiment. The figure for demonstrating the standard IF value preserve | saved beforehand by the standard IF value memory | storage part of this embodiment. The figure which shows the specific example of the tube warm-up characteristic calculated by the warm-up characteristic calculation part of this embodiment. The flowchart which shows the procedure of IF adjustment in this embodiment.

  Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.

  In the X-ray apparatus according to the present embodiment, various standard irradiation conditions set in advance for X-ray imaging in the filament current (hereinafter referred to as IF) adjustment mode performed prior to X-ray imaging in the main imaging mode. The IF value corresponding to the tube current of the X-ray tube is set using the standard IF value obtained in the past IF adjustment, and the measured value of the tube current measured in the X-ray imaging using the IF value is used to warm the X-ray tube. While calculating the up characteristic, the above-mentioned IF value is sequentially updated based on the comparison result between the measured value of the tube current and the tube current under the standard irradiation condition. Then, when the difference between the tube current measurement value in the X-ray imaging using the updated IF value and the tube current under the standard irradiation condition is minimized or smaller than a predetermined threshold value, this IF value is temporarily set as the optimum IF value. Based on the update instruction signal input by the operator, the standard IF value is updated by the above-described optimum IF value.

  In the following description, an X-ray apparatus including an X-ray imaging unit capable of X-ray CT imaging will be described. However, an X-ray apparatus including an X-ray imaging unit capable of X-ray imaging such as X-ray fluoroscopy It does not matter.

  The configuration and function of the X-ray apparatus according to the embodiment of the present disclosure will be described with reference to FIGS. 1 to 5. FIG. 1 is a block diagram illustrating the overall configuration of the X-ray apparatus according to the present embodiment, and FIG. 2 is a block diagram illustrating a specific configuration of an X-ray imaging unit included in the X-ray apparatus.

  An X-ray apparatus 100 shown in FIG. 1 is an IF adjustment mode for adjusting filament current (IF adjustment) and warming up an X-ray tube prior to X-ray imaging in the main imaging mode for a subject 30. X-ray imaging unit 2 for performing X-ray imaging in the main imaging mode for the purpose of collecting X-ray imaging and diagnostic image data, and reconstructing projection data obtained by X-ray imaging in the main imaging mode An image data generation unit 3 that generates two-dimensional or three-dimensional image data, an image data display unit 4 that displays the generated image data, and an IF that is supplied from the input unit 12 described later via the system control unit 13 Standard irradiation that sets standard tube voltage, tube current, irradiation time, irradiation timing, etc. in each shooting mode as standard irradiation conditions based on selection information for adjustment mode and main shooting mode The standard irradiation condition supplied from the standard setting unit 5, the standard IF value storage unit 6 for storing the standard filament current value (standard IF value) corresponding to the standard irradiation condition in the IF adjustment mode, and the standard irradiation condition supplied from the standard irradiation condition setting unit 5 The corresponding standard IF value is extracted from the various standard IF values stored in the standard IF value storage unit 6 to set the IF value of the X-ray imaging. Further, in the IF adjustment mode, the IF value is updated. Accordingly, the difference between the measured value of the tube current supplied from the tube current comparison unit 9 described later and the tube current of the standard irradiation condition supplied from the standard irradiation condition setting unit 5 is minimum or smaller than a predetermined threshold value. An IF value setting unit 7 for setting an IF value (hereinafter referred to as an optimal IF value) is provided.

  The X-ray apparatus 100 is measured by the tube current measuring unit 8 that measures the tube current in the X-ray imaging in the IF adjustment mode using the IF value set by the IF value setting unit 7 and the tube current measuring unit 8. A tube that detects the difference between the tube current measured in the X-ray imaging and the tube current of the standard irradiation condition by comparing the tube current and the tube current of the standard irradiation condition supplied from the standard irradiation condition setting unit 5 Tube current measurement results measured in a time series by the tube current measurement unit 8 in a series of X-ray imaging based on various standard irradiation conditions set by the current comparison unit 9 and the standard irradiation condition setting unit 5 for the IF adjustment mode , A warm-up characteristic calculation unit 10 for calculating the tube warm-up characteristic of the X-ray tube, a warm-up characteristic display unit 11 for displaying the calculated tube warm-up characteristic, an imaging mode selection, and an optimum I An input unit 12 for inputting an update instruction signal for updating the standard IF value using the value, inputting subject information in the main imaging mode, setting various imaging conditions including irradiation conditions, image data generation conditions, and the like. And a system control unit 13 for comprehensively controlling the above-described units.

  Next, a specific configuration of the X-ray imaging unit 2 that performs X-ray imaging in the IF adjustment mode and X-ray imaging in the main imaging mode for the subject 30 will be described with reference to the block diagram of FIG.

  As shown in FIG. 2, the X-ray imaging unit 2 is based on the IF value supplied from the IF value setting unit 7 or the standard irradiation condition supplied from the standard irradiation condition setting unit 5 via the IF value setting unit 7. X-rays based on the irradiation control signal supplied from the irradiation control unit 21 and the irradiation control unit 21 for controlling the X-ray irradiation intensity and irradiation timing in the X-ray imaging in the IF adjustment mode and the X-ray imaging in the main imaging mode An X-ray generation unit 22 that irradiates, a projection data generation unit 23 that generates X-rays by detecting X-rays emitted from the X-ray generation unit 22 and transmitted through the subject 30 in the main imaging mode, and X-ray generation A rotating gantry unit 27 that is mounted with the unit 22 and the projection data generation unit 23 and rotates at high speed around the subject 30, and the subject 30 is placed and moved in the body axis direction (z direction in FIG. 2). The target part of the rotary mount 27 A top plate 29 disposed Kageno, and a moving mechanism 24 for moving or high-speed rotation of the rotating gantry portion 27 of the top plate 29.

  For example, the irradiation control unit 21 generates a tube voltage / irradiation time control signal based on various standard irradiation conditions in the IF adjustment mode supplied from the standard irradiation condition setting unit 5, and is further supplied from the IF value setting unit 7. An IF control signal is generated based on the IF value.

  The X-ray generation unit 22 applies an X-ray tube 221 that irradiates the subject 30 with X-rays, and outputs a high voltage pulse having a voltage and a pulse width corresponding to the voltage / irradiation time control signal described above to the anode of the X-ray tube 221. A high voltage generator 222 applied between the cathode and the cathode, an X-ray diaphragm 223 for controlling the irradiation range of the X-rays emitted from the X-ray tube 221, and a high-voltage pulse and irradiation generated by the high-voltage generator 222 A slip ring 224 is provided for supplying the IF control signal supplied from the control unit 21 to the X-ray tube 221 attached to the rotary mount unit 27.

  The X-ray tube 221 is a vacuum tube that generates X-rays, and generates X-rays by colliding electrons accelerated by a high voltage supplied from the high-voltage generator 222 with a tungsten target. The filament (not shown) of the X-ray tube 221 is supplied with a filament current corresponding to the IF control signal supplied from the irradiation control unit 21 via the slip ring 224. By adjusting this filament current, the X-ray tube The tube current is adjusted at 211.

  On the other hand, the X-ray restrictor 223 is provided between the X-ray tube 221 and the subject 30, and has a function of narrowing X-rays emitted from the X-ray tube 221 to a predetermined irradiation range and X-ray irradiation to the subject 30. It has a function to set the intensity distribution. For example, the X-ray beam radiated from the X-ray tube 221 is formed into a cone beam-like or fan-beam-like X-ray beam corresponding to a preset imaging region.

  The projection data generation unit 23 detects an X-ray detector 231 that detects X-rays transmitted through the subject 30 in X-ray imaging in the main imaging mode, and a plurality of channels of detection signals output from the X-ray detector 231 in a predetermined manner. A switch group 232 bundled in the number of channels, a data acquisition unit (hereinafter referred to as a DAS (data acquisition system) unit) 233 that performs current / voltage conversion and A / D conversion on the output signal of the switch group 232, A data transmission circuit 234 that performs parallel / serial conversion, electrical / optical / electrical conversion, and serial / parallel conversion on the output signal of the DAS unit 233 is provided.

  The X-ray detector 231 of the projection data generation unit 23 includes two-dimensionally arranged X-ray detection elements (not shown). Each of the X-ray detection elements includes, for example, a scintillator that converts X-rays into light and electric light. It has a photodiode that converts it into a signal. These X-ray detection elements are attached to the rotating gantry 27 along an arc centered on the focal point of the X-ray tube 221, and detect X-rays transmitted through the subject 30 to generate projection data.

  On the other hand, the switch group 232 includes a multiplexer (not shown), and when supplying projection data supplied from the X-ray detector 231 to the DAS unit 233, the slice direction (z direction in FIG. 2) output from the X-ray detection element. The projection data of the N1 channel at is “data bundled” into the projection data of the N2 (N2 <N1) channel, thereby determining the acquisition position (slice cross section) and the acquisition width (slice width) of the projection data in the slice direction.

  The DAS unit 233 performs current / voltage conversion and A / D conversion on the N2 channel projection data supplied from the X-ray detector 231 via the switch group 232. The data transmission circuit 234 includes a parallel / serial converter, an electrical / optical / electrical converter, and a serial / parallel converter (not shown), and the projection data of the N2 channel output from the DAS unit 233 is sent to the rotary mount unit 27. The parallel / serial converter provided converts the projection data into time-series one-channel projection data, and supplies the data to the serial / parallel converter of the fixed gantry 28 by optical communication using the electrical / optical / electrical converter. The serial / parallel converter converts the time-series 1-channel projection data back to the N2-channel projection data corresponding to the N2 slice sections and supplies the projection data to the image data generation unit 3.

  Next, the moving mechanism unit 24 includes a gantry rotating mechanism unit 241 that rotates the rotating gantry unit 27 to which the X-ray tube 221 of the X-ray generation unit 22 and the X-ray detector 231 of the projection data generation unit 23 are attached at high speed. The top plate moving mechanism unit 242 that moves the top plate 29 in the body axis direction of the subject 30 (the z direction in FIG. 2), and the mechanism control unit 243 that controls the gantry rotating mechanism unit 241 and the top plate moving mechanism unit 242 are provided. I have.

  The mechanism control unit 243 generates a gantry rotation control signal based on the imaging start instruction signal supplied from the input unit 12 via the system control unit 13, and supplies the gantry rotation control signal to the gantry rotation mechanism unit 241. As a result, the rotating gantry 27 to which the X-ray tube 221 and the X-ray detector 231 are attached is rotated at a high speed in a predetermined direction.

  The mechanism control unit 243 generates a top plate movement control signal based on the top plate movement instruction signal supplied from the input unit 12 via the system control unit 13, and uses the top plate movement control signal as the top plate movement mechanism. By supplying to the unit 242 and moving the top plate 29 in the body axis direction, the site to be inspected of the subject 30 placed on the top plate 29 is placed in the imaging field formed in the center of the rotary mount 27. .

  Returning to FIG. 1, the image data generation unit 3 includes a projection data storage unit 31 and a reconstruction processing unit 32. The projection data storage unit 31 captures projection data collected in a predetermined imaging section and imaging range. Cross-section identification information and imaging range identification information are stored as supplementary information. On the other hand, the reconfiguration processing unit 32 includes an arithmetic processing unit that performs reconfiguration processing and a program storage unit (none of which is shown) in which various processing programs necessary for the reconfiguration processing are stored in advance. The arithmetic processing unit receives the image data generation conditions supplied from the system control unit 13, and extracts a processing program corresponding to the reconstruction method of the image data generation conditions from various processing programs stored in the program storage unit To do. Then, two-dimensional or three-dimensional image data is generated by reconstructing the projection data read from the projection data storage unit 31 based on the incidental information and the processing program described above, and the obtained image data is converted into image data. Supply to the display unit 4.

  The image data display unit 4 includes a display data generation unit, a conversion processing unit, and a monitor (not shown). The display data generation unit generates display data by adding incidental information such as subject information and imaging conditions to the image data generated by the reconstruction processing unit 32 of the image data generation unit 3, for example. On the other hand, the conversion processing unit performs conversion processing such as D / A conversion and television format conversion on the display data generated by the display data generation unit and displays the display data on the monitor.

  The standard irradiation condition setting unit 5 includes an irradiation condition storage unit and an irradiation condition extraction unit (not shown). The irradiation condition extraction unit is based on the selection information of the imaging mode supplied from the input unit 12 via the system control unit 13. By extracting suitable standard irradiation conditions from the various standard irradiation conditions stored in the above-described irradiation condition storage unit, the standard irradiation conditions of the IF adjustment mode and the main photographing mode are set.

  FIG. 3 shows tube currents and tube voltages for various standard irradiation conditions stored in the irradiation condition storage unit described above, and tube voltages and tubes extracted by the irradiation condition extraction unit as standard irradiation conditions for the IF adjustment mode. The tube current and tube voltage are generally classified into large focus X-ray imaging and small focus X-ray imaging.

  For example, as shown in FIG. 3, four types of tube voltages V1 to V4 are set in advance as tube voltages for standard irradiation conditions in large focus X-ray imaging and small focus X-ray imaging stored in the irradiation condition storage unit, respectively. Further, M types of tube currents I1 to IM are preset for each tube voltage.

  Then, the irradiation condition extraction unit of the standard irradiation condition setting unit 5 that has received the IF adjustment mode selection information supplied from the input unit 12 via the system control unit 13 is the above-described various standards stored in the irradiation condition storage unit. A standard irradiation condition having a combination of a tube current and a tube voltage indicated by a circle is extracted from the irradiation conditions as a standard irradiation condition for the IF adjustment mode.

  Returning to FIG. 1 again, the standard IF value storage unit 6 of the X-ray apparatus 100 stores in advance the optimum IF value obtained in the past IF adjustment for the standard irradiation condition in the IF adjustment mode as the standard IF value. .

  FIG. 4 shows a specific example of the standard IF value stored in the standard IF value storage unit 6 in correspondence with the standard irradiation condition of FIG. 3 stored in the irradiation condition storage unit of the standard irradiation condition setting unit 5. For example, the optimum IF value A11 obtained in the past large-focus X-ray imaging based on the standard irradiation condition of the IF adjustment mode having the tube current I1 and the tube voltage V1 (that is, while sequentially updating the IF value) The difference between the tube current Ix1 measured by the tube current measuring unit 8 (to be described later) and the tube current I1 of the standard irradiation condition supplied from the standard irradiation condition setting unit 5 in the above-described X-ray imaging is minimized or less than a predetermined threshold value. (IF value when small) is stored as a standard IF value in the I1-V1 storage area of FIG.

  Similarly, in the IF adjustment mode having tube current I1 and tube voltage V2, tube current I1 and tube voltage V3,..., Tube current I2 and tube voltage V1, tube current I2 and tube voltage V2,. The optimum IF values A12, A13,..., A21, A22,... Obtained by past large-focus X-ray imaging based on the standard irradiation conditions are the I1-V2 storage area of FIG. V3 storage area,... I2-V1 storage area, I2-V2 storage area,.

  The IF value setting unit 7 in FIG. 1 includes an optimum IF value storage unit and an interpolation calculation unit (not shown). Then, by extracting the standard IF value corresponding to the standard irradiation condition of the IF adjustment mode supplied from the standard irradiation condition setting unit 5 from various standard IF values stored in the standard IF value storage unit 6, The IF value of the radiography is set, and the obtained IF value is supplied to the irradiation control unit 21 of the X-ray imaging unit 2.

  For example, when the standard irradiation condition in the IF adjustment mode having the tube current I1 and the tube voltage V1 is set in the standard irradiation condition setting unit 5, the IF value setting unit 7 that has received this setting information receives the tube current I1 and the tube current I1. By extracting the standard IF value A11 corresponding to the tube voltage V1, the IF value in the X-ray imaging using the above-described standard irradiation conditions is set. When a significant difference is observed between the tube current Ix1 measured in the X-ray imaging using the IF value and the tube current I1 under the standard irradiation conditions, the update is sequentially performed by increasing / decreasing the IF value. Then, by supplying the updated IF value to the irradiation control unit 21 of the X-ray imaging unit 2, X-ray imaging in the IF adjustment mode is repeatedly performed.

  At this time, the IF value setting unit that receives the comparison result between the tube current Ix1 measured by the tube current measurement unit 8 and the tube current I1 of the standard irradiation condition supplied from the standard irradiation condition setting unit 5 from the tube current comparison unit 9. 7 stores an IF value at which the difference between the tube current Ix1 and the tube current I1 is minimum or smaller than a predetermined threshold based on the comparison result as an optimum IF value in its own optimum IF value storage unit.

  Further, the standard irradiation in the IF adjustment mode having tube current I1 and tube voltage V2, tube current I1 and tube voltage V3,..., Tube current I2 and tube voltage V1, tube current I2 and tube voltage V2,. The optimum IF value is set for the condition by the same procedure, and the obtained optimum IF value is stored in its own optimum IF value storage unit.

  The optimal IF value stored in the optimal IF value storage unit by the above-described procedure is stored in the standard IF value storage unit 6 according to the update instruction signal supplied from the input unit 12 via the system control unit 13, and the next and subsequent times. It is used as a standard IF value in IF adjustment.

  On the other hand, the interpolation calculation unit included in the IF value setting unit 7 includes standard IF values A11 to A14 corresponding to tube currents I1, I3,... (See FIG. 3) set as standard irradiation conditions in the IF adjustment mode. A tube current that is not set as a standard irradiation condition in the IF adjustment mode by interpolating the optimum IF value obtained based on B11 to B14, A31 to A34, B31 to B34 (see FIG. 4). The optimum IF values corresponding to I2, I4, I5,... Are calculated and stored in the optimum IF value storage unit. These optimum IF values are also stored in the standard IF value storage unit 6 in accordance with the update instruction signal described above, and are used as standard IF values in subsequent IF adjustments.

  Next, the tube current measuring unit 8 controls the X-ray tube 211 of the X-ray generation unit 22 in the X-ray imaging in the IF adjustment mode performed by the X-ray imaging unit 2 using the IF value supplied from the IF value setting unit 7. The flowing tube current is measured, and the measurement result is supplied to the tube current comparison unit 9 and the warm-up characteristic calculation unit 10. Then, the tube current comparison unit 9 compares the measurement result of the tube current supplied from the tube current measurement unit 8 with the tube current of the standard irradiation condition supplied from the standard irradiation condition setting unit 5, and compares the comparison result with IF. The value is supplied to the value setting unit 7.

  On the other hand, the warm-up characteristic calculation unit 10 includes a program storage unit and an arithmetic processing unit (not shown), and the program storage unit includes a calculation program capable of calculating the warm-up characteristic of the tube based on the tube current. Stored in advance. The arithmetic processing unit measures the tube current supplied in time series from the tube current measuring unit 8 in the X-ray imaging in the IF adjustment mode sequentially performed in accordance with the setting and updating of the IF value in the IF value setting unit 7. By inputting the result to the calculation program read from the program storage unit, a tube warm-up characteristic indicating a temporal change in tube temperature in the X-ray tube 221 is calculated.

  FIG. 5 shows a specific example of the tube warm-up characteristic calculated by the warm-up characteristic calculation unit 10, for example, based on the same IF value or different IF values as shown in FIG. FIG. 5B shows the tube warm-up characteristics measured when the X-ray irradiation for the irradiation time Δτ is performed at times t1, t2, t3,. In addition, the vertical axis | shaft of Fig.5 (a) has shown the intensity | strength or tube voltage of X-ray irradiation, and the vertical axis | shaft of FIG.5 (b) has shown the tube temperature in tube warm-up. 5 (a) and 5 (b) indicate the elapsed time since the start of IF adjustment, and the alternate long and short dash line in FIG. 5 (b) is necessary for tube warm-up. The lower limit of the tube temperature is shown.

  Next, the warm-up characteristic display unit 11 of FIG. 1 includes a display data generation unit, a conversion processing unit, and a monitor (not shown). The display data generation unit generates display data (tube warm-up characteristic data) based on the calculation result of the warm-up characteristic calculated by the warm-up calculation unit 10, and the conversion processing unit is generated by the display data generation unit. The display data is subjected to conversion processing such as D / A conversion and television format conversion and displayed on the monitor.

  Next, the input unit 12 includes input devices such as a display panel, a keyboard, a switch, a selection button, a mouse, and the like, and an update instruction signal for executing selection of a shooting mode and update of a standard IF value using an optimal IF value. , Setting of threshold values for tube current comparison results, input of object information in the main imaging mode, setting of various imaging conditions including irradiation conditions and image data generation conditions, input of various instruction signals, and the like. Imaging conditions other than irradiation conditions include imaging position, scanning method, slice section interval, number of slice sections, imaging area size, etc., and image data generation conditions include reconstruction method, reconstruction area size, reconstruction matrix size, etc. There is.

  The system control unit 13 includes a CPU and an input information storage unit (not shown), and the above-described input information, setting information, and selection information input from the input unit 12 are stored in the input information storage unit. The CPU comprehensively controls the above-described units included in the X-ray apparatus 100 based on these pieces of information, and generates and displays image data in the IF adjustment mode, tube warm-up, and main imaging mode. Is executed.

(IF adjustment procedure)
Next, the procedure of IF adjustment in the present embodiment will be described using the flowchart of FIG.

  Prior to X-ray imaging in the main imaging mode using the X-ray apparatus 100, the operator selects an IF adjustment mode for IF adjustment of the X-ray tube 221 and tube warm-up in the input unit 12 (FIG. 6). Step S1). The standard irradiation condition setting unit 5 then selects IF from various standard irradiation conditions stored in its own irradiation condition storage unit based on the selection information supplied from the input unit 12 via the system control unit 13. By extracting standard irradiation conditions suitable for adjustment and tube warm-up, for example, standard irradiation conditions in the IF adjustment mode as shown by the circles in FIG. 3 are set (step S2 in FIG. 6).

  On the other hand, the IF value setting unit 7 stores the standard IF value A11 corresponding to the first standard irradiation condition (tube current I1 and tube voltage V1) in the IF adjustment mode supplied from the standard irradiation condition setting unit 5 as a standard IF value. The IF value A11 for the X-ray imaging is set by extracting from various standard IF values stored in the unit 6, and the obtained IF value A11 is supplied to the irradiation control unit 21 of the X-ray imaging unit 2. (Step S3 in FIG. 6).

  Next, the irradiation control unit 21 generates a tube voltage / irradiation time control signal based on the first standard irradiation condition supplied from the standard irradiation condition setting unit 5 via the IF value setting unit 7, and further, the IF value An IF control signal is generated based on the IF value A11 corresponding to the first standard irradiation condition supplied from the setting unit 7. Then, by supplying these control signals to the X-ray generation unit 22 of the X-ray imaging unit 2, a plurality of X-ray imagings based on the first standard irradiation condition and the IF value A11 are performed at predetermined time intervals ( Step S4 in FIG.

  It should be noted that the number of repetitions of X-ray imaging performed in this case and the irradiation time in each X-ray imaging are included in the standard irradiation conditions of the IF adjustment mode, and the tube warm-up of the X-ray tube 221 is performed simultaneously with the IF adjustment. Is set in advance.

  On the other hand, the tube current measuring unit 8 is a tube current that flows through the X-ray tube 211 of the X-ray generation unit 22 in the above-described X-ray imaging performed by the X-ray imaging unit 2 based on the first standard irradiation condition and the IF value A11. Ix1 is measured (step S5 in FIG. 6). The tube current comparison unit 9 compares the tube current measurement value Ix1 supplied from the tube current measurement unit 8 with the tube current I1 of the first standard irradiation condition supplied from the standard irradiation condition setting unit 5, The comparison result is supplied to the IF value setting unit 7 (step S6 in FIG. 6).

  Next, the IF value setting unit 7 that has received the comparison result described above determines that the difference between the tube current measurement value Ix1 and the standard irradiation condition tube current I1 is greater than a predetermined threshold value α. A new IF value is set by increasing / decreasing the IF value A11 in the direction in which the current decreases, and X-ray imaging, tube current measurement, and tube current comparison based on the IF value are performed (steps S3 to S3 in FIG. 6). S6). Such a procedure is repeated until the difference between the tube current Ix1 and the tube current I1 is minimized or smaller than the threshold value α.

  On the other hand, if the difference between the tube current Ix1 and the tube current I1 is minimum or smaller than the threshold value α in step S6 described above, the IF value setting unit 7 sets the updated IF value to the optimum IF value Ax11, It is stored in its own optimum IF value storage unit (step S7 in FIG. 6).

  Next, the IF value setting unit 7 extracts the standard IF value A12 corresponding to the second standard irradiation condition (tube current I1 and tube voltage V2) in the IF adjustment mode supplied from the standard irradiation condition setting unit 5 and this. Setting of the IF value A12 of the X-ray imaging based on the standard IF value A12, X-ray imaging based on the second standard irradiation condition and IF value A12, tube current measurement, tube current comparison, IF value update, optimum IF The value Ax12 is set and stored in the same procedure as in the above steps S3 to S7, and further, the third standard irradiation condition (tube current I1 and tube voltage V3), the fourth standard irradiation condition (tube current I1 and The optimum IF values Ax13, Ax14,... Corresponding to the tube voltages V4),.

  When the setting and storage of the optimum IF value for the standard irradiation condition in the IF adjustment mode are completed by the above procedure, the IF value setting unit 7 corresponds to the tube currents I1, I3,. Optimal IF values Ax11 to Ax14, Bx11 to Bx14, Ax31 to Ax34, Bx31 to Bx34,... Obtained based on the standard IF values A11 to A14, B11 to B14, A31 to A34, B31 to B34,. Are interpolated, and the optimum IF values Ax21 to Ax24, Bx21 to Bx22, Ax41 to Ax44, Bx41 corresponding to the tube currents I2, I4, I5,. Thru | or Bx44, ... are calculated and preserve | saved at the above-mentioned optimal IF value memory | storage part.

  At this time, for example, on the display panel provided in the input unit 12, the standard IF value read from the standard IF value storage unit 6 (see FIG. 4) and the optimum IF value storage unit of the IF value setting unit 7 are read. A dialog in a predetermined format for inquiring about the update of the standard IF value using the optimum IF value and the optimum IF value is displayed.

  When an update instruction signal for updating the standard IF value is input by the operator who has observed the difference between the standard IF value and the optimum IF value displayed on the display panel and the above dialog, The value setting unit 7 updates the standard IF value by storing all the optimum IF values read from its own optimum IF value storage unit in the standard IF value storage unit 6 (step S8 in FIG. 6). If the update of the IF value is completed, the IF adjustment is terminated, and X-ray imaging in the main imaging mode for the subject 300 is started based on the newly set standard IF value (step S9 in FIG. 6).

  On the other hand, if the input of the update instruction signal by the operator is not performed at the input unit 12, the IF adjustment is terminated with the standard IF value stored in the standard IF value storage unit 6 as it is, and this standard IF is terminated. X-ray imaging in the main imaging mode using values is started (step S9 in FIG. 6).

  If the tube current measurement unit 8 measures the tube current with respect to the IF value set or updated by the IF value setting unit 7 in step S5 described above, the warm-up characteristic calculation unit 10 includes the tube current measurement unit 8. Tube current warm-up characteristics indicating the temporal change of the tube temperature in the X-ray tube 221 by inputting the measured value of the tube current supplied from the time series to the calculation program read from its own program storage unit Is calculated and displayed on the monitor of the warm-up characteristic display unit 11 (step S10 in FIG. 6).

  According to the present embodiment described above, the tube warm-up of the X-ray tube, which is performed prior to the X-ray imaging in the main imaging mode for the subject, is performed simultaneously with the adjustment of the filament current (IF adjustment), thereby achieving high accuracy. The X-ray imaging in the main imaging mode can be performed efficiently.

  That is, by performing tube warm-up of the X-ray tube by X-ray imaging in the IF adjustment mode for the purpose of IF adjustment, a high frequency IF is performed during the tube warm-up period always performed on the X-ray examination day. Since the adjustment is performed without increasing the downtime of the apparatus, it is possible to perform X-ray imaging using an X-ray tube in which the latest IF adjustment is always performed.

  In particular, it is possible to obtain an optimum IF value corresponding to an arbitrary tube current not set as the standard irradiation condition by interpolating an optimum IF value corresponding to the tube current preset as the standard irradiation condition in the IF adjustment mode. Therefore, the optimum IF value can be set efficiently, and the IF adjustment for the purpose of setting the optimum IF value can be completed within the tube warm-up period.

  In addition, according to the above-described embodiment, since the tube warm-up characteristic is calculated based on the tube current obtained at the time of IF adjustment, it is possible to easily estimate the accurate tube warm-up characteristic. Further, based on the optimum IF value obtained by comparing the tube current of the X-ray tube measured while sequentially updating the IF value at the time of IF adjustment and the tube current of a preset standard irradiation condition, Since the standard IF value used for IF adjustment is set, the standard IF value effective for IF adjustment can be set efficiently.

  On the other hand, according to the above-described embodiment, the IF adjustment performed prior to the X-ray imaging in the main imaging mode is automatically performed in each unit included in the X-ray apparatus, and is in charge of maintenance of the X-ray apparatus. Not only is the labor and maintenance costs of service personnel, etc. significantly reduced, but also the X-ray device downtime associated with IF adjustment and tube warm-up is reduced, enabling efficient X-ray inspection. .

  As mentioned above, although embodiment of this indication has been described, this indication is not limited to the above-mentioned embodiment, and it can change and carry out. For example, in the above-described embodiment, the X-ray apparatus 100 including the X-ray imaging unit 2 capable of X-ray CT imaging has been described. However, an X-ray imaging unit capable of X-ray imaging such as X-ray fluoroscopy is provided. An X-ray apparatus may be used.

  Further, the image data collected by the X-ray imaging in the main imaging mode and the tube warm-up characteristics calculated in the X-ray imaging in the IF adjustment mode are different from each other (that is, the image data display unit 4 and the warm-up characteristic display unit). 11), the image data and the tube warm-up characteristic can be displayed on a common display unit.

  Moreover, although the case where the dialog etc. which inquires the update of the standard IF value using the optimal IF value is displayed on the display panel provided with the input unit 12 has been described, the present invention is not limited to this. For example, the image data display unit 4 or the warm-up characteristic display unit 11 or may be displayed on the above-described display unit capable of displaying the image data and the tube warm-up characteristic.

  Furthermore, the above-described tube warm-up characteristics, dialog, and the like may be displayed on the display unit of the terminal device provided in the service center in charge of maintenance of the X-ray apparatus 100. By sending these data to a service center connected via a network or the like, efficient normal maintenance or remote maintenance becomes possible.

  On the other hand, in the above-described embodiment, the standard used for the next and subsequent X-ray imaging based on the optimum IF value obtained by measuring the tube current and the optimum IF value newly obtained by interpolating the optimum IF value. Although the case of setting the IF value has been described, the standard IF values corresponding to these optimum IF values are set based on the above-mentioned optimum IF values obtained by measuring the tube current, and these standard IF values are further set. Other standard IF values may be set by the interpolation processing used.

  Note that each unit included in the X-ray apparatus 100 of the present embodiment can also be realized by using, as hardware, a computer including a CPU, a RAM, a magnetic storage device, an input device, a display device, and the like. . For example, the system control unit 13 of the X-ray apparatus 100 can realize various functions by causing a processor such as a CPU mounted on the computer to execute a predetermined control program. In this case, the above-described control program may be installed in advance in the computer, or may be stored in a computer-readable storage medium or installed in the computer of the control program distributed via the network. .

  As mentioned above, although some embodiment of this invention was described, these embodiment was shown as an example and is not intending limiting the field | area of invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the invention described in the claims and equivalent areas thereof.

2 ... X-ray imaging unit 21 ... Irradiation control unit 22 ... X-ray generation unit 23 ... Projection data generation unit 24 ... Movement mechanism unit 3 ... Image data generation unit 31 ... Projection data storage unit 32 ... Reconstruction processing unit 4 ... Image data Display unit 5 ... Standard irradiation condition setting unit 6 ... Standard IF value storage unit 7 ... IF value setting unit 8 ... Tube current measurement unit 9 ... Tube current comparison unit 10 ... Warm-up characteristic calculation unit 11 ... Warm-up characteristic display unit 12 ... Input unit 13 ... system control unit 100 ... X-ray apparatus

Claims (9)

X-ray generation means having an X-ray tube for generating X-rays;
Tube current measuring means for measuring the tube current of the X-ray tube;
The filament current value (IF value) of the X-ray tube in the X-ray imaging in the IF adjustment mode is set, and the measured value of the tube current measured by the tube current measuring means in the X-ray imaging based on the IF value IF value setting means for updating the IF value based on a comparison result with a tube current of a preset standard irradiation condition;
Standard IF value storage means for storing the updated IF value as a standard IF value;
A warm-up characteristic calculating means for calculating a tube warm-up characteristic of the X-ray tube based on a measurement result of the tube current;
An X-ray apparatus comprising: display means for displaying a calculation result of the tube warm-up characteristic.   The IF value setting means sets an IF value in the first X-ray imaging in the IF adjustment mode based on a preset standard IF value, and sequentially updates the IF value based on the comparison result of the tube current. The X-ray apparatus according to claim 1, wherein an IF value for X-ray imaging subsequent to the first X-ray imaging is set.   The IF value setting means sets an IF value in the first X-ray imaging in the IF adjustment mode based on a standard IF value set in a past X-ray examination and stored in the standard IF value storage means. The X-ray apparatus according to claim 2.   A standard irradiation condition setting unit configured to set a standard irradiation condition in the IF adjustment mode, and the IF value setting unit stores the standard IF stored in the standard IF value storage unit corresponding to a tube current of the standard irradiation condition. 4. The X-ray apparatus according to claim 3, wherein an IF value in the first X-ray imaging in the IF value setting mode is set based on the value.   In the X-ray imaging in the IF adjustment mode performed in conjunction with the update of the IF value, the tube current measurement value supplied in time series from the tube current measuring means is compared with the tube current under the standard irradiation condition. A tube current comparison unit, and the IF value setting unit calculates an IF value that minimizes a difference between the tube current measurement value obtained by the tube current comparison unit and the tube current under the standard irradiation condition. 2. The X-ray apparatus according to claim 1, wherein the value is stored in the standard IF value storage means.   In the X-ray imaging in the IF adjustment mode performed in conjunction with the update of the IF value, the tube current measurement value supplied in time series from the tube current measuring means is compared with the tube current under the standard irradiation condition. Tube current comparing means, and the IF value setting means calculates an IF value at which a difference between the measured value of the tube current obtained by the tube current comparing means and the tube current under the standard irradiation condition is smaller than a predetermined threshold value. The X-ray apparatus according to claim 1, wherein the standard IF value is stored in the standard IF value storage means.   The IF value setting means includes a standard IF corresponding to an unmeasured tube current by interpolating a standard IF value set based on a comparison result between the measured tube current value and the tube current under the standard irradiation condition. 2. The X-ray apparatus according to claim 1, wherein a value is set and stored in the standard IF value storage means.   Displaying at least one of the tube warm-up characteristic calculated by the warm-up characteristic calculating means and the standard IF value updated by the IF value setting means on a display unit of a service center connected via a network; The X-ray apparatus according to claim 1. For an X-ray apparatus that performs X-ray imaging in IF adjustment mode prior to X-ray imaging in the main imaging mode for the subject,
An X-ray generation function for generating X-rays using an X-ray tube;
A tube current measuring function for measuring the tube current of the X-ray tube;
The filament current value (IF value) of the X-ray tube in the X-ray imaging in the IF adjustment mode is set, and the measured value of the tube current measured in the X-ray imaging based on the IF value and a preset standard An IF value setting function for updating the IF value based on a comparison result with a tube current of an irradiation condition;
A standard IF value storage function for storing the updated IF value as a standard IF value;
A warm-up characteristic calculation function for calculating a tube warm-up characteristic of the X-ray tube based on the measurement result of the tube current;
A control program for executing a display function for displaying a calculation result of the tube warm-up characteristic.

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