JPH0415048A - Ct value correcting method in x-ray ct device - Google Patents

Abstract

PURPOSE:To regularly perform the optimum CT value correction and obtain a highly precise CT value by automatically selecting a parameter for CT value correction according to the size of a body to be inspected to perform CT value offset quantity correction. CONSTITUTION:It is detected whether the SUM value of the measurement data of each channel of a multichannel X-ray detector 31 in a first measured view of a body to be inspected is less than a preset first threshold or not. When it is acknowledged, a CT value correcting parameter C1 according to a CT value correcting phantom A having a preset size is selected. When it is denied, whether the SUM value satisfies K1<SUM<=K2 or not is judged, and when it is acknowledged, a CT value correcting parameter C2 according to a CT value correcting phantom B having a preset size is selected. When it is denied, a CT value correcting parameter C3 according to a CT value correcting phantom C having a preset size is selected, the CT value correcting parameter selection is thus terminated to propose the selected parameter to CT value correction.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a CT value correction method in an X-ray CT apparatus.

[Conventional technology]

In an X-ray CT device, the CT value is O1 for water and 1000 for air.
However, in reality, the above value is not achieved due to measurement errors in the measurement system and errors due to changes in the quality of X-rays, and errors occur in the subject measurement data.

Therefore, in order to correct this, the measurement data of a phantom (phantom for calibration correction) close to the amount of attenuation of the subject is used as calibration data (sensitivity correction value).
Save the actual object measurement data as
By correcting with the above calibration data,
Efforts are being made to improve measurement accuracy.

Furthermore, the final image reconstructed using the corrected measurement data is
Here again, the CT value is different from the actual one. For this reason, measure the reference water phantome (reference water phantome for CT value correction) and set its CT value (lft) to the final image so that the CT value of the surrounding air becomes 1000. Offset correction and gain correction (these are collectively referred to as CT value lower positive) are performed.

In this case, depending on the size of the subject, CT41M
The above-mentioned calibration correction phantom and CT value correction reference water phantom will be less effective unless the amount of attenuation (size of the subject) is the same as that of the subject. Several types of correction phantoms are prepared depending on the size, and CT values are corrected by appropriately selecting them.

(For CT value correction, see Yoshinishige Iwai, rCT Scanner J published by Corona Publishing, pages 127 to 132.) [Problems to be Solved by the Invention] However, such conventional correction methods have the following problems. was there. That is, since the above-mentioned cage l/-version correction is performed in proportion to the difference in the amount of attenuation in each measurement channel of the X-ray detector, the error thereof is small.

On the other hand, since CT value correction is performed using CT value correction parameters (measurement parameters) for the final image, that is, using the same value, errors are likely to occur. Therefore, in reality, we prepare two types of correction reference water phantoms, one for the head and one for the abdomen, or even more precisely, by dividing the measurement area into three or more types according to the classification, and measure them. A method has been adopted in which CT value correction parameters corresponding to each phantom are obtained, and correction parameters corresponding to a phantom corresponding to the size of the subject are selected from among them for correction.

However, in such a CT value correction method, each correction reference water phantom and correction parameter are set in a fixed (one-to-one) combination, so the measured object and correction reference water phantom are set in a fixed (one-to-one) combination. If the combination of
value is obtained, but if the operator makes a mistake in the above combination, C
There was a problem in that an error occurred in the T value.

An object of the present invention is to be able to always perform optimal CT value correction, regardless of the operator's setting of the C'F value supplementary reference water fandom or selection of correction parameters, and to achieve high precision C'F value correction.
The purpose of this invention is to find out a CT value correction method for an X-ray CT apparatus that can obtain T values.

[Means to solve the problem]

The above purpose is to measure each CT value obtained by measuring each of the CT value correction phantoms of different sizes, which are set according to the size of the subject, and each of the above CT value correction fans. The difference from the original CT value of the tome is determined in advance as a CT value correction parameter, and the above CT value correction parameter is automatically selected according to the size of the subject obtained by subject measurement. This is achieved by correcting the CTT value offset amount.

Here, in order to estimate the size of the object from the object measurement data, it is easy to distinguish between the air area and the object area from the measurement data of one channel with the X-ray detector. However, in order to improve its accuracy, it is necessary to estimate it using measurement data from multiple channels of the X-ray detector.

Furthermore, depending on the measurement site of the subject, even if the external shape is large, such as the lung field, the constituent material may be mainly air and the amount of attenuation may be small. In such cases, it is necessary to identify both the size and the amount of attenuation, which takes a lot of time. Since a CT device must quickly process a large amount of measurement data, if the above-mentioned identification is performed during measurement, the processing time increases, resulting in a device with low response. Therefore, in the present invention, the size identification method is as follows. , (2) The size of the object is determined by the sum value (SUM value) of the output of each channel of the multi-channel X-ray detector, and (3) CT
Similarly, the SUM value of the value correction phantom is calculated using the method (2) above, and the CT value correction parameters corresponding to the SUM value of each CT value correction phantom are calculated. When lower, the size of the object (SUM value)
The CT value correction parameters corresponding to the CT value correction phantom having the same size (SUM value) are selected using a table or a correction curve.

[Effect]

The parameters for CT value correction are the measured CT value of each CT value correction phantom set according to the size of the subject and the original CT value (theoretical value) of each CT value correction phantom described above. It is determined in advance by the difference between In addition, depending on the size of the subject obtained by subject measurement, the above CT
CT value offset amount correction is performed by automatically selecting parameters for value correction. Thereby, M-appropriate CT value correction is always performed, and highly accurate CT values can be obtained.

In addition, if the size of the object to be examined is determined by the SUM value (sum value) of each channel output of the multi-channel X-ray detector of the measurement data, it can be determined regardless of the position, orientation, shape, or measurement start direction of the object. and the size of this object can be calculated only from the initial data at the time of measurement.
Image processing becomes faster.

(Example) Hereinafter, the present invention will be described in detail with reference to the drawings.

First, before a detailed explanation of the present invention, the -C CT value correction method, which has already been outlined, will be explained. Here, two methods of correcting CT values for the head and abdomen will be described.

As the reference water phantom for CT value correction, a phantom having a value close to the attenuation amount of the measurement subject is used. Usually, a phantom of about 200φ (diameter 200mm) is used for the head, and a phantom of 300φ (diameter 300mm) is used for the abdomen.
m) degree of fandom is used. When the CT value of the phantom person is measured without CT value correction, the value of water is not O but has a certain offset, and this offset amount changes depending on the size of the phantom.

Conversely, in the case of a specific measurement (here, measurement of the head and abdomen), the CT value of water will always be O if the offset amount is subtracted.

Similarly, the CT value difference between water and air is 1. OOOl Also, since the distance between water and acrylic must be about 125, put air or acrylic in the water phantom, and the CT 4ff difference between the two is equal to the CT value difference 12.
By multiplying by a gain constant of about 5,
A certain prescribed CTT value in scale (CTT value positive table) will always be obtained.

This offset correction and gain correction, that is, CT value correction, corrects errors that cannot be corrected by calibration correction, defects in calculation constants and their accuracy in image processing, etc.
Furthermore, it is to correct CT value fluctuations that occur due to the calculation method of the system, and here two types of CT value correction tables (parameters) are required, one for the head and one for the abdomen.

This CT value correction parameter must be set correctly before measuring the object. In actual OCT equipment, the above C
The selection of the T value correction parameter, that is, the distinction between the head and the abdomen, is generally performed based on the size of the effective field of view (display area), a value given in advance at the time of the first examination of the subject, and the like. However, if the operator's selection of the CT value correction parameters is inappropriate, a sufficient correction effect cannot be obtained and CT value fluctuations occur.

The present invention provides a CT value correction method for an X-ray CT apparatus that always performs optimal CT value correction and obtains highly accurate CT values by automatically selecting parameters for CT value correction according to the size of the subject. An example of this is described below.

Figure 5 shows the relationship between the subject and each channel output of the multi-channel X-ray detector. If the channel output (measurement data) here is after the LOG calculation in the X-ray CT device, the amount of attenuation The larger the value, the larger the measurement data.

Here, the size of the object is determined by the SUM value (sum value, shaded area in Figure 5) of the measurement data of each channel of the multi-channel X-ray detector (output value of each channel), (P(i) : Output value of each channel), the SUM value is small in the head of a small subject (see Figure 5 (a)), and the SUM value is large in the abdomen of a large subject (see Figure 5 (a)). b)).

Furthermore, even if the subject is horizontal (see FIG. 5(C)) or the set position of the subject is off-center, the size of the subject can be appropriately determined.

To actually select appropriate CT value correction parameters,
A threshold value is set for the above SUM value, and when the SUM value is below the threshold value, CT value correction parameters are selected according to the small head fan 1-1, and when the SUM value is greater than the above threshold value, CT according to large abdominal phantom
Allows you to select parameters for value correction.

FIG. 6 shows the relationship between the output waveform of X-rays and the measurement time of measurement data. Part 6 (a) is pulsed X-ray, (1))
shows the waveform of continuous X-rays, and measurement is usually started after the X-ray waveform becomes stable as shown in (C).

Judging the size of the object (calculating the SUM value above) is based on the first data at the start of measurement (for X-ray pulses, the measurement data of all channels of the X-ray detector for the first pulse, continuous X-ray In this case, the measurement data of all channels of the X-ray detector in the first view) is used as DI. This SUM
By calculating the value, the optimum CT value correction parameter for the measurement of the object is set.

Note that, as shown at D2 in FIG. 6(d), it is also possible to use measurement data during the rising and falling periods of the X-ray waveform for determining the size of the subject.

The above example describes the case where two sizes of the subject's head and abdomen are determined, that is, two types of CT value correction parameters are selected. to CT
It is also possible to correct the value. For this purpose, three or more types of
Set the CT value correction fan) and calculate the above SUM.
Set the number of value selection areas to 3 or more, in other words, set the number of thresholds to 2.
You can make it more than one.

FIG. 1 shows an example of the processing flow of the method of the present invention when the number of thresholds is two. As shown in FIG. 1, CT value correction is started at or before the end of measurement of the subject. In the CT value correction, first, the St and JM values of the measurement data of each channel of the multi-channel X-ray detector of the first view (or first pulse) ['' of object measurement are calculated (step 101).

Next, it is determined whether or not this SLIM value is less than a preset first threshold value (step 102). CT value correction parameter C1 is selected (step 103). When the result in step 102 is negative, in step 104 the above SUM value is determined to be Kl<SUM
It is determined whether or not ≦2 is satisfied, and if it is affirmative, a CT value correction parameter C2 corresponding to the CT value lower pressure phantom B having a preset size is selected (step 1).
05). When the result in step 104 is negative, in step 105, the CT value correction parameter C3 corresponding to the CT value lower pressure phantom C having a preset size is selected (step 106), and the CT value correction parameter is selected. is completed and subjected to CT value correction.

Here, the threshold value Kl, 2 and the CT value correction parameters 01 to C3 are preset values, and the relationship between these and the SUM value and an example of the contents of the CT value correction parameters 01 to C3 are described in the second section. It is shown in the figure.

FIG. 3 is a block diagram showing an example of the processing system of FIG. 1. In FIG. 3, numeral 31 is a detection system consisting of a multi-channel X-ray detector, an integrator, an A/I converter, and the like. The CPU 32 and the main memo IJ 33 constitute a computer, which performs the processing shown in FIG. 1 and various other arithmetic processing. The auxiliary memory 34 is a memory that stores the CT value correction parameters (CT value correction table), and also stores image data and the like. 35 is a CRT for displaying a reconstructed image, and 36 is a common bus.

In the above embodiment, a case has been described in which the CT value correction parameters are stored as a table in the memory and are uniquely selected based on the relationship between the SUM value and the threshold value, but the present invention is not limited to this. For example, as shown in Figure 4,
Multiple types, here three types of CT value lower pressure phantom A-
Obtain a correction curve that approximates the relationship between the measured SUM value of C and the CT value correction amount by a linear approximation or a quadratic function, and perform the subject measurement SU
The CT value correction amount, that is, the CT value correction parameter may be selected in a stepless manner corresponding to the M value.

In the above embodiment, the calibration correction phantom and the CT value correction phantom are described as separate phantoms, but the present invention is not limited to this.

If the CT value relationship between air and water is satisfied, a CT value corresponding to the substance constituting the calibration correction phantom and the CT value fan 1 is inevitably obtained. Therefore, the phantom for CT value correction does not need to be water, and the fan for calibration correction
Water or polyethylene) itself can be used as the CT value lower 5 andome. If the phantom for CT value correction at this time is made of polyethylene, the CT value will be 1000. The correction parameters may be set so as to have a relationship of polyethylene-60.

[Effects of the Invention] According to the present invention, regardless of the setting of the reference water phantom for CT value correction by the operator or the selection of correction parameters,
Highly accurate CT that can always perform optimal CT value correction
It has the effect of being able to obtain a value.

Also, check the size of the object before or after the start of object measurement.
By determining the SUM value of the X-ray detector channel output of the th pulse or view, the position and orientation of the subject can be determined.
The size of the object can be determined regardless of the shape, etc., and there is also the effect of speeding up image processing.

[Brief Description of the Drawings] Fig. 1 is a flowchart 1 for explaining an embodiment of the method of the present invention, and Fig. 2 is a flow chart 1 for explaining an embodiment of the method of the present invention.
Figure 3 is a bronch diagram showing an example of the processing system in Figure 1; The figure is a graph showing the relationship between the SUM value and the CT value correction amount of the CT value lower pressure band measurement, Figure 5 is a graph showing the relationship between the subject and each channel output of the X-ray detector, and Figure 6 is a time chart showing the relationship between the output waveform of X-rays and the measurement operation. 31...Detection system, 32...CPU, 33...Main memory, 34...Auxiliary memory, 35...CRT , 36
...Common lotus. Patent applicant Hitachi Medical Co., Ltd. Agent Patent attorney Masami Akiki and 1 other person Figure Is2 Figure 3-281,-

Claims (1)

[Claims] 1. Each CT value obtained by measuring a plurality of CT value correction phantoms of different sizes set according to the size of the subject and each of the above CT values. The difference from the original CT value of the value correction phantom is determined in advance as a CT value correction parameter, and the above CT value correction parameter is automatically determined according to the size of the subject obtained by subject measurement. 1. A CT value correction method in an X-ray CT apparatus, characterized in that CT value offset amount correction is performed by selecting . 2. Set several types of substances in the above CT value correction phantom and calculate the CT value difference between those substances, or the CT value difference between the substances inside the above CT value correction phantom and outside the phantom. In the X-ray CT apparatus according to claim 1, a CT value correction parameter is set such that the CT value becomes an original CT value difference, and the CT value offset amount is corrected based on the parameter.
T value correction method. 3. Set CT value correction parameters according to each of the above CT value correction phantoms and create a table of them.
The X according to claim 1, wherein when correcting the CT value, a CT value correction parameter corresponding to a CT value correction phantom corresponding to the size of the measurement subject is read from the table, and thereby the CT value offset amount is corrected. C in line CT equipment
T value correction method. 4. The size of the object is determined by the SUM value of each channel of the multi-channel X-ray detector based on the measurement data, and the CT value correction parameter is selected based on this. CT value correction method in an X-ray CT apparatus. 5. Regarding the plurality of CT value correction phantoms mentioned above,
The correspondence relationship between each of the above SUM values and the optimal value of the CT value correction parameter set accordingly is as follows:
CT that has the same SUM value as the above SUM value of the subject, obtained by calculating a correction curve by linear approximation or quadratic function approximation.
Claim 4: A CT value correction parameter corresponding to a value correction phantom can be selected steplessly from the correction curve.
A CT value correction method in an X-ray CT apparatus according to . 6. The CT value correction method in an X-ray CT apparatus according to claim 4 or 5, wherein the SUM value of the subject is calculated before starting measurement of the subject or using the first measurement data.