Thrust constant derivation method and movement control method of linear motor, and thrust constant derivation device and movement control device of linear motor

The invention claimed is: 1. A thrust constant derivation method of a linear motor for deriving a thrust constant representing an occurrence rate of a thrust in relation to a current in the linear motor which is provided with a track member, which includes one of a magnet and a coil extending in a movement direction, and a moving body, which includes the other of the magnet and the coil mounted to the track member in a movable manner, the linear motor generating a thrust in the movement direction between the magnet and the coil by causing a current to flow in the coil, the method comprising: causing the moving body to move along a long movement zone on the track member, the long movement zone including a plurality of locations on the track member; deriving a first thrust constant in the long movement zone on the track member based on actual measurements of current as the moving body moves across the long movement zone; causing the moving body to perform movements in the movement direction at each of the plurality of locations; deriving second thrust constants of the plurality of locations on the track member based on an actual measurement of an alternating current and positional information at each of the plurality of locations; and deriving the thrust constant, of an arbitrary position on the track member including a position between two of the plurality of locations on the track member, based on the first thrust constant and the second thrust constants. 2. The thrust constant derivation method of a linear motor according to claim 1 , wherein causing the moving body to perform the movements in the movement direction includes causing the moving body to perform micro-movements in the movement direction, and the method further comprises: calculating a difference between an average value of the second thrust constants and the first thrust constant; correcting the second thrust constant of each of the plurality of locations by the difference to obtain a corrected second thrust constant of each of the plurality of locations; and deriving the thrust constant, of the arbitrary position on the track member, by interpolating the corrected second thrust constants. 3. The thrust constant derivation method of a linear motor according to claim 2 , the method further comprising: performing, at the plurality of locations on the track member, the following: actually measuring the alternating current and the positional information of the moving body while causing a variable frequency alternating current to flow in the coil and exciting the moving body forward and backward in the movement direction; deriving a transfer function of a frequency domain based on a chronological change in the alternating current and a chronological change in the positional information of the moving body; estimating a modeled mass of the moving body by calibrating a physical model in which the mass of the moving body and friction conditions during movement are variably modeled using the transfer function of the frequency domain; obtaining a correction scaling factor by dividing an actual measurement mass or a design mass of the moving body by the modeled mass of the moving body; and calculating the second thrust constant of each of the plurality of locations by multiplying the correction scaling factor by a design value of the thrust constant. 4. The thrust constant derivation method of a linear motor according to claim 3 , the method further comprising: using a sinusoidal current for the variable frequency alternating current; gradually changing the variable frequency chronologically using a high-speed sinusoidal sweeping method; and subjecting the chronological change in the positional information of the moving body to a Fourier transformation to derive the transfer function of the frequency domain. 5. The thrust constant derivation method of a linear motor according to claim 2 , the method further comprising: moving the moving body across the long movement zone at a fixed velocity; performing an actual measurement of a friction compensation current necessary in compensation of a friction resistance at a plurality of velocities; storing a friction compensation table in which a velocity is correlated with a corresponding friction compensation current; moving the moving body across the long movement zone at a fixed acceleration; actually measuring an acceleration required current and a velocity of the moving body which are necessary at the time; and calculating the first thrust constant based on an acceleration net current which is obtained by acquiring the friction compensation current corresponding to the velocity of the moving body which is actually measured from the friction compensation table and subtracting the acquired friction compensation current from the acceleration required current. 6. The thrust constant derivation method of a linear motor according to claim 1 , wherein a plurality of magnets or coils are provided to line up in an area of a predetermined length in the movement direction of the moving body, and the plurality of locations on the track member, at which the second thrust constants are derived, are set at an interval which is narrower than the predetermined length. 7. A movement control method of a linear motor, the method comprising: storing a thrust constant table in which the thrust constant, of the arbitrary position on the track member, which is derived using the thrust constant derivation method of a linear motor device according to claim 1 is correlated with a positional coordinate of the arbitrary position on the track member; detecting a current positional coordinate on the track member of the moving body when the moving body is subjected to movement control; and using a thrust constant corresponding to the current positional coordinate of the thrust constant table to control a current to be caused to flow in the coil. 8. A movement control device of a linear motor, the device comprising: storage for storing a thrust constant table in which the thrust constant, of the arbitrary position on the track member, is derived using the thrust constant derivation method of the linear motor according to claim 1 is correlated with a positional coordinate of the arbitrary position on the track member; and a controller configured to detect a current positional coordinate on the track member of the moving body when the moving body is subjected to movement control, and use a thrust constant corresponding to the current positional coordinate of the thrust constant table to control a current to be caused to flow in the coil. 9. A thrust constant derivation device which derives a thrust constant representing an occurrence rate of a thrust in relation to a current in linear motor which is provided with a track member, which includes one of a magnet and a coil extending in a movement direction, and a moving body, which includes the other of the magnet and the coil mounted to the track member in a movable manner, the linear motor generating the thrust in the movement direction between the magnet and the coil by causing the current to flow in the coil, the device comprising: a processing device programmed to cause the moving body to move along a long movement zone on the track member, the long movement zone including a plurality of locations on the track member; derive a first thrust constant in a long movement zone on the track member based on actual measurement of current as the moving body moves across the long movement zone; cause the moving body to perform movements in the movement direction at each of the plurality of locations; derive second thrust constants of the plurality of locations on the track member ba