A functional vehicle component and related methods include a functional leather assembly fixed over a vehicle component. The functional leather assembly includes a leather sheet, a flexible electronic circuit arranged on a first surface of the leather sheet that faces away from the vehicle component to thereby define an outermost surface of the leather sheet, and including a piezoelectric switch that can be actuated to make or break a conductive path in the circuit; and a pigmented coating arranged over the circuit. Upon actuation of the piezoelectric switch to make or break the conductive path in the circuit, the piezoelectric switch provides a haptic signal that indicates the actuation of the piezoelectric switch.

Provided are an electroacoustic conversion film web, an electroacoustic conversion film, and a method of manufacturing an electroacoustic conversion film web in which costs can be reduced by reducing the number of operations without damage to thin film electrodes, the points of electrode lead-out portions can be freely determined, and thus high productivity can be achieved. A preparation step of preparing an electrode laminated body in which a single thin film electrode and a single protective layer are laminated and a lamination step of laminating the electrode laminated body and an piezoelectric layer are included. A non-adhered portion that is not adhered to the piezoelectric layer is provided in at least one end portion of the thin film electrode in a case where the electrode laminated body and the piezoelectric layer are laminated in the lamination step.

There is provided a piezoelectric element which includes a first electrode which is formed on a substrate, a piezoelectric layer which is formed on the first electrode, and is formed from a compound oxide having an ABO.sub.3 type perovskite structure in which potassium (K), sodium (Na), niobium (Nb), and manganese (Mn) are provided, and a second electrode which is formed on the piezoelectric layer. The manganese includes bivalent manganese (Mn.sup.2+), trivalent manganese (Mn.sup.3+), and tetravalent manganese (Mn.sup.4+). A molar ratio (Mn.sup.2+/Mn.sup.3++Mn.sup.4+) of the bivalent manganese to a sum of the trivalent manganese and the tetravalent manganese is equal to or greater than 0.31.

Embodiments of the invention include a piezoelectric sensor system. According to an embodiment of the invention, the piezoelectric sensor system may include a piezoelectric sensor, a signal conditioning circuit, and a light source each formed on an organic or flexible substrate. In embodiments of the invention, the piezoelectric sensor may be a discrete component or the piezo electric sensor may be integrated into the substrate. According to an embodiment, a piezoelectric sensor that is integrated into the substrate may comprise, a cavity formed into the organic substrate and a moveable beam formed over the cavity and anchored to the organic substrate. Additionally, the piezoelectric sensor may include a piezoelectric region formed over an end portion of the moveable beam and extending at least partially over the cavity. The piezoelectric sensor may also include a top electrode formed over a top surface of the piezoelectric region.

A piezoelectric element includes a first electrode; a piezoelectric layer, placed on or above the first electrode, containing potassium, sodium, niobium, titanium, and oxygen; and a second electrode placed on or above the piezoelectric layer.

A method of fabricating a piezoelectric/conductive hybrid polymer thin film is provided, which is promoting an electric output of a piezoelectric polymer and includes: a mixing step including: forming a piezoelectric solution by dissolving a PVDF-TrFE in an active solvent; forming a conductive solution by dissolving a PEDOT:PSS in a water; and forming a piezoelectric/conductive hybrid polymer solution by mixing the piezoelectric solution and the conductive solution; a filming step, wherein the piezoelectric/conductive hybrid polymer solution is heated, thus the piezoelectric/conductive hybrid polymer thin film is formed; and an anneal step, wherein the piezoelectric/conductive hybrid polymer thin film is recrystallized and a nano-sized protruding structure is formed on a surface of the piezoelectric/conductive hybrid polymer thin film.

An electromechanical transducer element including a lower electrode, an electromechanical transducer film and an upper electrode formed on the electromechanical transducer film.

Systems, devices, and methods for wirelessly delivering haptic effects are provided. The devices may include haptic actuators secured to various substrates, including the body and clothing of a user. The haptic actuators may be secured via adhesive and/or may be applied as a curable liquid. The haptic actuators may include an actuator element and a power element. The power element may include an antenna for receiving wireless power and control signals that may be transferred to the haptic actuator to cause a haptic effect.

A piezoelectric thin film is manufactured by sequentially executing: a step of coating a substrate by applying a coating solution containing an organic solvent and a piezoelectric thin film precursor to form a coating layer; a step of evaporating the organic solvent from the coating layer in a windless environment to obtain a dried coating layer containing the piezoelectric thin film precursor; and a step of heating the dried coating layer to form a piezoelectric thin film from the dried coating layer containing the piezoelectric thin film precursor.

A piezoelectric element includes a first electrode layer, a piezoelectric layer, and a second electrode layer. The first electrode layer, the piezoelectric layer, and the second electrode layer are stacked in sequence on one another. The first electrode layer has a first part overlapping the piezoelectric layer in a plan view, and a second part at least partially separated from the first part and not overlapping the piezoelectric layer in the plan view. The second electrode layer has a third part overlapping the piezoelectric layer in the plan view, and a fourth part separated from the third part. The fourth part is in contact with the first part and the second part.