An inductor driving device includes multiple switching elements and a control circuit, wherein an inductor is driven according to switching of the multiple switching elements. The control circuit is arranged to generate a control signal for controlling the multiple switching elements. In a first mode, the control signal has a constant frequency. In a second mode, the control circuit adjusts a frequency of the control signal and continuously changes a current direction of the inductor, to generate one of multiple audio signals through the inductor.

A wrist mechanism includes a first rotation unit, a second rotation unit, a first brake pad, and a first brake plate. The first rotation unit includes a first motor, a first rotating shaft that is connected to the first motor, and a first encoder. The first motor is operable to drive the first rotating shaft to rotate about a first axis. The first encoder measures an angle of rotation of the first rotating shaft. The second rotation unit is co-rotatable with the first rotating shaft about the first axis. The first brake pad is connected to the first rotating shaft. The first brake plate is operable to move relative to the first brake pad along the first axis. When the first brake plate is urged to move along the first axis to abut against the first brake pad, the rotation of the first rotating shaft is stopped.

A wrist mechanism includes a first rotation unit, a second rotation unit, a first brake pad, and a first brake plate. The first rotation unit includes a first motor, a first rotating shaft that is connected to the first motor, and a first encoder. The first motor is operable to drive the first rotating shaft to rotate about a first axis. The first encoder measures an angle of rotation of the first rotating shaft. The second rotation unit is co-rotatable with the first rotating shaft about the first axis. The first brake pad is connected to the first rotating shaft. The first brake plate is operable to move relative to the first brake pad along the first axis. When the first brake plate is urged to move along the first axis to abut against the first brake pad, the rotation of the first rotating shaft is stopped.

Provided is a method of controlling a gimbal mounted on a camera, the method including, by a control module, generating a value of a first target rotational force for a servo motor module that transmits a rotational force to the gimbal, based on a value of a sensor output received from a gyro sensor module mounted to be aligned in a direction in which the camera faces and a value of a preset angular velocity of a gimbal platform with which the gimbal is engaged, and, by the control module, applying a value of rotational resistance based on the value of the preset angular velocity of the gimbal platform to the value of the first target rotational force to generate a value of a second target rotational force, and transmitting the value of the second target rotational force to the servo motor module.

A control device includes: a command generating unit that generates a command for a motor; a correction-amount calculating unit that performs correction-amount calculation processing for calculating a correction amount for the command on the basis of elastic parameters of elastic elements; and a stage detecting unit that detects the fact that a transition has been made from a first stage in which a driving force generated by the motor acts on the first elastic element to a second stage in which the driving force acts on the second elastic element via the first elastic element. When the transition from the first stage to the second stage is detected, the correction-amount calculating unit switches from first correction-amount calculation processing based on the first elastic parameter of the first elastic element to second correction-amount calculation processing based on the second elastic parameter of the second elastic element and the first elastic parameter.

Methods and systems may provide for an actuator including a circular sidewall having an inner surface, a first edge and a second edge, and a plurality of radial members extending from a hub of the actuator to the inner surface of the circular sidewall, wherein application of a force to an inner end of each radial member at the hub causes an outer end of the radial member to displace the second edge of the circular sidewall to a greater extent than the first edge of the circular sidewall.