JPH01168000A - Preprocessing data producing device of neutral particle incident unit - Google Patents

Abstract

PURPOSE:To produce a prepro-data highly efficiently and highly accurately by providing the first prepro-data based on the control object value, then producing the second prepro-data by monitoring the first prepro-data, then deciding the quality of the second prepro-data, and repeating the data correction and the test operation when the quality of the second prepro-data is not satisfactory. CONSTITUTION:A control object value is input to a control object input member 1. Then, the first prepro-data to operate a neutral particle incident unit NBI at an ideal condition is produced by using the first prepro-data producing member 2. Then, the produced first prepro-data is output to the unit NBI by the first prepro-data output member 3, and its response is picked up in the first prepro-data monitor 4. After that, by using the said response, the second prepro- data is produced by using the second prepro-data producing member 5. Then, it is decided by an examination result deciding member 6 whether the second prepro-data is satisfactory or not. When it is not satisfactory, it is corrected by using a prepro-data correction member 7, and then a test operation is repeated. And when a satisfactory result is obtained, the role of the device is completed.

Description

[Detailed Description of the Invention] [Object of the Invention] (Field of Industrial Application) The present invention is directed to a method in which the incident energy itself in a neutral particle injector (NBI) used as a heating device for a nuclear fusion experiment device is preprogrammed in advance. The present invention relates to a pre-pro data creation device for creating pre-pro data for controlling the total incident power by changing the total incident power.

(Prior art) In nuclear fusion experimental equipment, one of the conditions to achieve critical conditions is to increase the temperature of the plasma.
Neutral particle injection devices are attracting attention as a promising means.

A neutral particle injection device is a device that injects electrically neutral particles with high energy into a plasma, and increases the temperature of the plasma by imparting that energy (incident energy) to the plasma. Generally, in a neutral particle injection device, the total incident energy to the plasma is controlled by repeating the injection and interruption of a beam having a constant incident energy.

(Problems to be Solved by the Invention) However, there are limits to the above energy control because there are limits to the plasma behavior conditions and the operation of the neutral particle injection device. Therefore, the incident energy itself must be prepared in advance.
Attempts have been made to control the total incidence/power by changing it to a programmed value.

In this Gregorian control, it is necessary to know the various characteristics of the neutral particle injection @ location and the fusion experimental device, and to create pre-pro data that realizes the incident energy required for the fusion experiment. However, since the characteristics of this type of neutral particle injection device are not clear or change depending on the surrounding conditions, it is difficult to create pre-pro data that realizes the incident energy required for the experiment. Even those who are skilled in the art have to spend a lot of effort and time, and the accuracy is insufficient.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a pre-pro data creation device that can efficiently and highly accurately create a pre-pro data group for determining a control target value in a neutral particle injection device.

[Structure of the Invention] (Means for Solving the Problems) In order to achieve the above object, a pre-pro data creation device for a neutral particle injection device according to the present invention is configured to create a neutral particle injection device based on a control target value inputted from an external source. A first means for generating first prepro data by simulating a control system including the above and applying it to the neutral particle injection device, and a response of the neutral particle injection device based on the first prepro data. a second means for monitoring the response monitor information and operating the control system including the neutral particle injection device again in a simulated manner to create second pre-pro data; Comparing the pre-pro data group created by the plurality of operations of the second means with the control target value to determine whether the pre-pro data is good or bad, and if the pre-pro data group is judged to be good, outputs the pre-pro data group as regular pre-pro data.

In the case of a negative determination, the present invention is characterized by comprising a third means for correcting the pre-pro data group to become regular pre-pro data based on the control target value by repeating data correction and test operation.

(Function) According to this configuration, a large number of complicated Bregrono 4
7-- can be created efficiently and accurately, making it possible to quickly conduct experiments using the required set target values, and greatly increasing the efficiency of use of the neutral particle injection device. can be improved.

(Embodiment) An embodiment of the pre-pro data creation device for a neutral particle injection device according to the present invention will be described below with reference to the block diagram of FIG. 1 and the operation flowchart of FIG. 2.

In FIG. 1, 1 is a control target value input unit that inputs a control target value (1) from the outside, and 2 is a neutral particle injection device NBI based on the control target value (1) from the control target value input unit 1.
a first pre-pro data creation unit that generates first pre-pro data by simulating the control system including the
Reference numeral 3 denotes a first pre-process data output unit that supplies the first pre-pro data from the first pre-pro data creation unit 2 to the neutral particle injection device (1). 4 is a first pre-pro data monitor unit that monitors the response of the neutral particle injection device NBI based on the first pre-pro data, and 5 is a second pre-pro data monitor unit that simulates the control system again based on this monitor information. 6 is a second pre-pro data creation section that creates pre-pro data; Create the second pre-pro data, and compare the pre-pro data group created by multiple monitor operations with the control target value (1) to determine the quality (the pre-pro data group contains many errors due to the accuracy of the simulation) 7 is a test result judgment unit that outputs the pre-pro data group as regular pre-pro data if the judgment is good, and 7 is a data correction part when the test result judgment unit 6 makes a negative judgment. This is a pre-pro data correction unit that corrects the above-mentioned pre-pro data group to become regular pre-pro data based on the control target value (1) by repeating the above-mentioned pre-pro data group and test operation.

Next, regarding the operation of this embodiment configured as described above, fs
This will be explained with reference to FIG.

That is, it starts in process S1, and in process S2, the control target value (1
) is input through the control target input section 1.

Next, in process S3, first pre-pro data that allows the neutral particle injection device NBI to be operated under ideal conditions is created based on the control target value (1). For example, when the first pre-pro data is the deflection magnet current and the second pre-pro data is the accelerating voltage, the relationships under ideal conditions are as shown in equations (1) and (2) below.

Irm5(t) ``y(t)' Brmobj(t
) ・・・・・・(2) However, vase・.

bj is the acceleration voltage target value, ■, □ are the deflection magnet currents, F(t) is the transfer function, B rmo b j is the deflection magnetic field set value, Ko. is a constant.

Here, the deflection magnet device and the acceleration power source are the neutral particle injection device NB.
The deflection magnet device provided in the I is used to hit the beam beam with the ions that could not be neutralized in the neutralization cell, and the acceleration power source accelerates the ions created in the ion source using an electric field. It is used to

The transfer function y (t) in the above equation (2) can be calculated by a method such as outputting an in/heral deflection magnet current to the deflection magnet device, monitoring the response to the deflection magnetic field, and performing Fourier transformation on the response. It is possible to calculate.

Next, as a process S4, the first prepro data created as described above is output to the neutral particle injection device NBI by the first prepro data output unit 3, and as a process S5, the response is output to the first prepro data. The data is captured by the data monitor section 4.

Next, in step S6, ideal second pre-pro data corresponding to the first pre-pro data is created using the second pre-pro data creation section 5 using the above response. For example, similarly to the creation of the LOf regro data described above, when the first prepro data is the deflection current and the second prepro data is the acceleration voltage, the relational expression under ideal conditions is the above equation (1).
is transformed into the following equation (3).

vlee fist e (t) = Kacc ・
Brm ” m2 (t) = =
(3) However, v, ce-0 are the calculated acceleration voltage values, "rm
-1 is the deflection magnetic field monitor value, and KILee is a constant.

Next, in process S7, the test result determination unit 6 is used to determine whether the first pre-pro data and the second pre-pro data created based on the control target value (1) as described above are satisfactory pre-pro data. to determine. As a specific method for this determination, there is a method such as comparing the control target value (1) with the second preliminary production data corresponding thereto.

FIG. 3 is a characteristic diagram showing the relationship between the control target value (1) and the prepared pre-pro data, and the control target value (1) is provided with a certain allowable upper limit value Du and a certain allowable adjustment value Dj. Here, from the problem of transfer function, etc., create! If the real log data contains many errors, and the pre-pro data created by the first tab is outside the allowable range, it is determined that the pre-pro data needs to be corrected.

In step S8, the pre-pro data correction section 7t is used to correct the pre-pro data for the ninth part of the value outside the allowable range, and then the test run is repeated. Then, when a satisfactory result is obtained in step S9, the process ends. By the above-described method, the convergence efficiency of creating pre-pro data can be increased, and highly accurate pre-pro data can be created efficiently and easily.

When correcting the pre-pro data, the influence of the corrected part on the post-correction pre-pro data should be calculated by considering the transfer function of the neutral particle injection device NBI and using a weighting function, etc. This calculation result is then used for subsequent data correction.

[Effects of the Invention] As described above, according to the present invention, many complicated pre-pro A? To greatly improve the usage efficiency of a neutral particle injection device by making it possible to create turns efficiently and accurately, thereby making it possible to quickly conduct experiments using required set target values. It is possible to provide a pre-pro data creation device for a neutral particle injection device that can perform the following steps.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing an embodiment of a pre-pro data creation device for a neutral particle injection device according to the present invention, Fig. 2 is an operation flowchart of the embodiment, and Fig. 3 explains the operation of the embodiment. FIG. DESCRIPTION OF SYMBOLS 1... Control target input section, 2... First pre-pro data creation section, 3... First pre-pro data output section, 4.
... first pre-pro data monitor section, 5... second pre-pro data creation section, 6... test result determination section, 7...
・Pre-soro data correction section.

Claims (1)

[Claims] In a pre-pro data creation device that changes the incident energy itself of the energy injection target from a neutral particle injection device to a value pre-programmed in advance, and creates pre-pro data that controls the total incident power, the above-mentioned information is generated based on the control target value of external input. a first means for generating first prepro data by simulating a control system including the neutral particle injection device and providing it to the neutral particle injection device; and a first means for generating first prepro data to the neutral particle injection device; a second means for creating second pre-pro data by monitoring the response of the controller and performing a simulation operation of the control system including the neutral particle injection device again based on the response monitor information; and the first and second means. The pre-pro data group created by multiple operations is compared with the control target value to determine whether it is good or bad. If the pre-pro data group is judged to be good, the pre-pro data group is output as regular pre-pro data, and if the judgment is not, the data is and a third means for correcting the pre-pro data group to become regular pre-pro data based on the control target value by a method of repeating correction and test operation. Data creation device.