Abstract: An ultrasound probe includes: a metal case including a bottom wall portion having a vibration surface, and a side wall portion connected to the bottom wall portion; a coil mounted on one surface of the side wall portion; and a magnet mounted in such a way as to sandwich the coil between the magnet and the one surface of the side wall portion, in which the coil causes an eddy current to occur in the one surface of the side wall portion, and causes the bottom wall portion to vibrate, by using a Lorentz force occurring in the side wall portion because of the interaction between the eddy current and a magnetic field generated by the magnet.

Abstract: A test object includes a sensor housing for vibrating together with a test object in synchronism with vibration of the test object; a piezoelectric substrate for vibrating together with the sensor housing in synchronism with vibration of the sensor housing, where a first interdigital electrode, a first terminal, a second interdigital electrode, and a second terminal are disposed on a first surface of the piezoelectric substrate, and the piezoelectric substrate is disposed inside the sensor housing to be fixed to the sensor housing; an amplifier for receiving a signal output from the second terminal as an input signal, amplifying the received input signal, and transmitting the input signal after the amplification to the first terminal as an output signal; a deformable layer being elastic and having a first surface adhered to a second surface of the piezoelectric substrate; and a heavy object having a first surface adhered to a second surface of the deformable layer.

Abstract: Disclosed is a vibration sensor including a piezoelectric substrate, a first electrode and a second electrode that are arranged on the piezoelectric substrate, an amplifier electrically connected between the first electrode and the second electrode, and a solid medium having a first surface part in contact with the piezoelectric substrate, and a second surface part disposed opposite to the first surface part and used for contact with a target substance, the solid medium having a sound speed lower than the phase speed of a plate wave in the piezoelectric substrate, in which an oscillation loop includes the piezoelectric substrate, the first electrode, the second electrode, the amplifier, and the solid medium, and a vibration of the target substance is detected as a result of variation in the loop length of the oscillation loop in response to the vibration of the target substance.

Abstract: An ultrasound probe includes: a metal case including a bottom wall portion having a vibration surface, and a side wall portion connected to the bottom wall portion; a coil mounted on one surface of the side wall portion; and a magnet mounted in such a way as to sandwich the coil between the magnet and the one surface of the side wall portion, in which the coil causes an eddy current to occur in the one surface of the side wall portion, and causes the bottom wall portion to vibrate, by using a Lorentz force occurring in the side wall portion because of the interaction between the eddy current and a magnetic field generated by the magnet.

Abstract: A test object includes a sensor housing for vibrating together with a test object in synchronism with vibration of the test object; a piezoelectric substrate for vibrating together with the sensor housing in synchronism with vibration of the sensor housing, where a first interdigital electrode, a first terminal, a second interdigital electrode, and a second terminal are disposed on a first surface of the piezoelectric substrate, and the piezoelectric substrate is disposed inside the sensor housing to be fixed to the sensor housing; an amplifier for receiving a signal output from the second terminal as an input signal, amplifying the received input signal, and transmitting the input signal after the amplification to the first terminal as an output signal; a deformable layer being elastic and having a first surface adhered to a second surface of the piezoelectric substrate; and a heavy object having a first surface adhered to a second surface of the deformable layer.

Abstract: Disclosed is a vibration sensor including a piezoelectric substrate, a first electrode and a second electrode that are arranged on the piezoelectric substrate, an amplifier electrically connected between the first electrode and the second electrode, and a solid medium having a first surface part in contact with the piezoelectric substrate, and a second surface part disposed opposite to the first surface part and used for contact with a target substance, the solid medium having a sound speed lower than the phase speed of a plate wave in the piezoelectric substrate, in which an oscillation loop includes the piezoelectric substrate, the first electrode, the second electrode, the amplifier, and the solid medium, and a vibration of the target substance is detected as a result of variation in the loop length of the oscillation loop in response to the vibration of the target substance.

Abstract: An ultrasonic sensor transmits an ultrasonic wave, and receives the ultrasonic wave reflected by an obstacle. An electrical characteristic measuring means measures the electrical characteristic of the ultrasonic sensor, and outputs electrical characteristic information. An environmental state determining means receives the electrical characteristic information from the electrical characteristic measuring means, and outputs environmental information on at least one of the temperature and humidity of the ultrasonic sensor.

Abstract: An attachment member (1) has a through hole (11). An ultrasonic sensor (2) is fixed to the attachment member (1) in such a manner that an emitting surface (22) of the ultrasonic sensor (2) is exposed from the through hole (11) of the attachment member (1). A vibration propagation preventing layer (3) is interposed between the entire periphery of a side surface of the ultrasonic sensor (2) and a wall surface of the through hole (11) of the attachment member (1). Vibration plates (41) and (42) are disposed on one of a first straight line passing through the center point of the emitting surface (22) of the ultrasonic sensor (2) on a horizontal plane parallel to the emitting surface (22) and a second straight line perpendicular to the first straight line, and connect the emitting surface (22) of the ultrasonic sensor (2) to the attachment member (1).

Abstract: In a calibration device, a calibration matrix calculation processing part estimates a calibration matrix by using an orthogonal vector stored in an orthogonal vector storage part and an array mode vector stored in an array mode vector storage part. A calibration matrix output part transmits the calibration matrix computed by the calibration matrix calculation processing part to an unknown parameter estimation device.

Abstract: In a calibration device, a calibration matrix calculation processing part (104) estimates a calibration matrix (M) by using an orthogonal vector stored in an orthogonal vector storage part (103b) and an array mode vector (a(?)) stored in an array mode vector storage part (103a). A calibration matrix output part (105) transmits the calibration matrix (M) computed by the calibration matrix calculation processing part (104) to an unknown parameter estimation device.