A method for backlash compensation in motion control systems includes homing a payload of a motion control system, and performing a tooth-pitch non-uniformity procedure on the motion control system to identify a non-uniformity correction. A backlash lookup table is generated for use in backlash correction during normal operation of the motion control system. The backlash lookup table is generated using a training process that includes selecting a move sequence for operating the motion control system, and executing the move sequence with the non-uniformity correction. The training process further includes computing a backlash measurement describing backlash of one or more components of the motion control system during the move sequence, and storing the backlash measurement in the backlash lookup table.

Provided is a sensing system (1) in which a desired trajectory determining section (32) determines a first desired trajectory th(t) (where t<t1) whose first derivative is continuous, a second desired trajectory th(t) (where t2t<t3) whose first derivative is continuous, a third desired trajectory th(t) (where t1t<t2) configured with a common tangent line to the first and second desired trajectories, and a fourth desired trajectory th(t) (where t35t<t4) configured with a common tangent line to the second desired trajectory in the current-time cycle and a first desired trajectory in a next-time cycle. A drive mechanism controlling section (33) controls an operation of the drive mechanism so as to track the desired trajectories.

Techniques involve detecting a mechanical play (W.sub.s) in a system having a hydraulic valve and a valve drive for driving the hydraulic valve. A valve slide, which is driven by the valve drive of the hydraulic valve, is clamped with at least one return spring which is designed, in the case of a de-energized valve drive, to push the valve slide from any arbitrary valve slide position back into a neutral position of the valve slide.

A motor-driving apparatus for driving a motor having a plurality of windings respectively corresponding to a plurality of phases is provided. The motor-driving apparatus includes a first inverter having a plurality of first switching devices and connected to first ends of the plurality of windings and a second inverter having a plurality of second switching devices and connected to second ends of the plurality of windings. A third switching device is configured to selectively connect and disconnect points at which a number of turns of each of the windings is divided in a preset ratio. A controller is configured to adjust an on/off state of the first to third switching devices based on required output of the motor.

A motor driving device and driving method of the same used to surely suppress the influence of counter electromotive force is provided. The motor driving device 100 includes an auto-decay portion 141. The auto-decay portion 141 controls a path of a electric current flow in a motor coil when supplying the electric current and when decaying the electric current. The influence of counter electromotive force generated in a stepping motor 200 can be suppressed by the auto-decay portion 141 configured to control so that a ratio or an decay time of a slow decay mode and a fast decay mode of previous cycle is different from a ratio or an decay time of the slow decay mode and the fast decay mode of current cycle.

A driving device for a stepping motor includes a motor driving circuit configured to generate a current waveform representing an electrical angle in synchronization with a mechanical angle of the stepping motor, and excite the stepping motor using the current waveform; a memory configured to store a value of the electrical angle; and a controller configured to: when a power supply to the stepping motor and the motor driving circuit is stopped, store a first value of the electrical angle held by the motor driving circuit in the memory; and when the power supply is resumed, replace a value of the electrical angle of the motor driving circuit with the first value while suppressing a rotational operation of the stepping motor.

A gaming machine of the present invention stores a bet area on which a bet is placed through a gaming terminal and a game value placed as the bet, determines a resulting symbol from a plurality of symbols, rotates the wheel based on an operation of the lever in one of the plurality of gaming terminals, whose lever has been activated, stops the rotation of the wheel so that the pointer points at a symbol arrangement area with the resulting symbol, and awards a payout based on the resulting symbol and the odds set for the bet area in which the bet is placed through the gaming terminal.

A gaming machine of the present invention stores a bet area on which a bet is placed through a gaming terminal and a game value placed as the bet, determines a resulting symbol from a plurality of symbols, rotates the wheel based on an operation of the lever in one of the plurality of gaming terminals, whose lever has been activated, stops the rotation of the wheel so that the pointer points at a symbol arrangement area with the resulting symbol, and awards a payout based on the resulting symbol and the odds set for the bet area in which the bet is placed through the gaming terminal.

A stator assembly for an electric motor includes a drive plate, a first magnetic core and a second magnetic core. A first core slot is formed in the first magnetic core and a second slot is formed in the second magnetic core. The first and second magnetic cores each include two elongated members joined at one end by a base member which are defined by the respective core slots. The two elongated members extend from the base member substantially parallel to each other toward the drive plate. A stator coil is wound through the first core slot and the second core slot. An electrical current flowing in the stator coil generates a magnetic field about the stator coil that is absorbed by the first magnetic core and the second magnetic core to generate a magnetic flux in each of the magnetic cores that magnetically attracts the drive plate.

A stator assembly for an electric motor includes a drive plate, a first magnetic core and a second magnetic core. A first core slot is formed in the first magnetic core and a second slot is formed in the second magnetic core. The first and second magnetic cores each include two elongated members joined at one end by a base member which are defined by the respective core slots. The two elongated members extend from the base member substantially parallel to each other toward the drive plate. A stator coil is wound through the first core slot and the second core slot. An electrical current flowing in the stator coil generates a magnetic field about the stator coil that is absorbed by the first magnetic core and the second magnetic core to generate a magnetic flux in each of the magnetic cores that magnetically attracts the drive plate.