Provided is a vibration wave motor including a holding structure that does not inhibit vibration of the entire vibrator. The vibration wave motor includes: a vibrator that generates an elliptic motion; a holding means that holds the vibrator; and a driven body driven by the vibrator, wherein the holding means includes a first abutting portion and a second abutting portion abutting the vibrator, the vibrator includes a first displacement portion at a part abutting the first abutting portion and includes a second displacement portion at a part abutting the second abutting portion, a displacement of the first displacement portion is smaller than a displacement of the second displacement portion, and an area of the first abutting portion of the holding means is greater than an area of the second abutting portion.

A linear driving mechanism capable of moving a driven object smoothly and lengthening its service life. A first vibration element and a second vibration element sandwich a friction member therebetween. A first holding member holding the first vibration element is rotatably supported by a first shaft. A second holding member holding the second vibration element is rotatably supported by a second shaft. An urging part moves the first holding member and the second holding member to press these vibration elements against the friction member. A coupling member couples the first holding member with a driven object. A pressing part presses the coupling member against a moving body including the first and second holding members. A direction of a pressing force of the pressing part intersects with the first shaft when the coupling member couples with the first holding member.

A piezoelectric motor according to one embodiment may include: a vibrating body including an elastic body and a piezoelectric element attached to the elastic body; and a rod coupled to the vibrating body and configured to move on the basis of vibration of the vibrating body. The piezoelectric element may include a first surface and a second surface facing opposite to the first surface of the piezoelectric element and attached to the elastic body. The rod can extend perpendicular to the piezoelectric element. The vibrating body can be configured to generate a bending vibration in the longitudinal direction of the rod on the basis of a voltage applied to the piezoelectric element, and can be configured to define a nodal position during the bending vibration. The elastic body may include a base portion attached to the second surface of the piezoelectric element and a protruding portion protruding from the base portion and formed at a position corresponding to the nodal position of the vibrating body.

A vibration actuator includes a vibrating body, a contact body, and an abutment body. The vibrating body includes an electro-mechanical energy conversion element and an elastic body and have two vibration modes having a common node area that is of both the two vibration modes and is shared between the two vibration modes. The contact body comes into contact with the elastic body. The abutment body includes an abutment member that abuts on the common node area on a side opposite to a side on which the abutment body faces the contact body. The vibration actuator is configured such that an attraction force between the vibrating body and the abutment body is generated by a magnetic force.

The invention relates to an ultrasonic motor comprising a plate-shaped piezoelectric ultrasonic actuator (2) and a of friction element (5) arranged on a side surface thereof, wherein the connection line (V) through the friction point and the focal point (S) of the ultrasonic actuator defines an operating direction, and a perpendicular plane intersecting the ultrasonic actuator defines an operating plane (W). A holder (6) has two force inlet sections (7) in order to move the holder and thereby the ultrasonic actuator in a direction parallel to the operating direction, and to press same against an element to be driven. The force inlet sections, preferably based on permanent magnets (8, 9) are each arranged in the operating plane and laterally next to and at a distance from the the ultrasonic actuator, and the intersection point (SP) of the connection line (V) with the operating plane (W) either coincides with the focal point (S) or lies between the focal point and the side surface having the friction element.

An image pickup apparatus is capable of decreasing a space capacity occupied by component elements and being downsized compared to a case where an actuator is arranged independently of a supporting unit. The image pickup apparatus has an image pickup unit driven by the actuator, a base unit, and the supporting unit provided in a standing manner from the base unit and rotatably supports the image pickup unit. The actuator has a piezoelectric element and an oscillator including a transmission unit which transmits driving force caused by vibration excited by the piezoelectric element. The transmission unit is arranged in the supporting unit so that it is in pressure contact with the image pickup unit. The image pickup unit has a transmitted plane with which the transmission unit is brought into pressure contact, and the vibration excited by the oscillator causes the transmitted plane to move relatively to the oscillator.

An optical driving mechanism is provided, configured to force an optical element, including a base, a movable portion, and a driving portion. The movable portion is disposed and connected to the base. The movable portion includes a holder configured to sustain the optical element, a magnetic element, and a fixing member. The magnetic element and the fixing member are affixed to the holder, wherein the fixing member has a permeable material. The driving portion is configured to force the movable portion to move relative to the base, wherein the driving portion includes a piezoelectric element and a support member connecting thereto. The piezoelectric element and the support member are disposed on the base and connected to the movable portion. The fixing member makes contact with the support member via a magnetic attraction force between the magnetic element and the fixing member.

An electromechanical actuator includes an oscillation resonator having the shape of a rod. The oscillation resonator is divided by a dividing plane that is not parallel to the longitudinal direction of the oscillation resonator into a first resonator portion and a second resonator portion. At least the first resonator portion includes electromechanical means which, when activated, are configured to generate a 3-dimensional acoustic bulk wave are with a mode shape asymmetric with respect to the dividing plane.

A first member, a second member, a bearing that rotatably supports the second member about a rotation axis relative to the first member, a driven member placed on the first member, and a plurality of piezoelectric actuators that transmit driving forces for rotating the second member about the rotation axis relative to the first member to the driven member are provided, and the piezoelectric actuators are supported by the second member while being pressed against the first member or the member fixed thereto, and, as seen from a direction along the rotation axis, a center of pressing forces from the plurality of piezoelectric actuators to the driven member is located inside of an outer circumferential part of the bearing.

A vibration drive device can suppress separation between members thereof when an external force is applied thereto. The vibration drive device excites vibration in a vibrating body to move the vibrating body and a driven body relative to each other. The vibrating body has a piezoelectric element joined to a first surface of an elastic body. Protrusions for pressure contact with the driven body are formed on a second surface of the elastic body. The elastic body is supported by support plates, and the support plates are held on a base. An equalizing stage is disposed on a side facing the first surface of the elastic body. A vibration damping member disposed between the vibrating body and the equalizing stage suppresses transmission of vibration from the vibrating body to the equalizing stage.