An apparatus may include an ultrasonic sensor array and a control system. The control system may be configured to acquire first image data generated by the ultrasonic sensor array corresponding to at least one first reflected ultrasonic wave received by at least a portion of the ultrasonic sensor array from a target object during a first acquisition time window. The control system may be configured to acquire second image data generated by the ultrasonic sensor array corresponding to at least one second reflected ultrasonic wave received by at least a portion of the ultrasonic sensor array from the target object during a second acquisition time window that is longer than the first acquisition time window. The control system may further be configured to initiate an authentication process based on the first image data and the second image data.

A testing system for testing a work piece. The testing system may be non-destructive. An associated method. The method may include obtaining C-scan images and corresponding S-scan images. The C-scan images and the corresponding S-scan images are of the same portion of the work piece being tested.

Provided is a method of generating an ultrasound image corresponding to a cross-section of interest, which is performed by an ultrasound imaging apparatus. Exemplary embodiments include a method of generating an ultrasound image corresponding to a cross-section of interest of an object by storing ultrasound echo signals respectively corresponding to a plurality of frames that constitute a three-dimensional (3D) ultrasound image of the object, performing beamforming on a focal point on the cross-section of interest of the object, and generating beam focused data for the focal point.

An apparatus may include an ultrasonic sensor array and a control system. The control system may be configured to acquire first image data generated by the ultrasonic sensor array corresponding to at least one first reflected ultrasonic wave received by at least a portion of the ultrasonic sensor array from a target object during a first acquisition time window. The control system may be configured to acquire second image data generated by the ultrasonic sensor array corresponding to at least one second reflected ultrasonic wave received by at least a portion of the ultrasonic sensor array from the target object during a second acquisition time window that is longer than the first acquisition time window. The control system may further be configured to initiate an authentication process based on the first image data and the second image data.

An apparatus may include an ultrasonic sensor array and a control system. The control system may be configured to acquire first image data generated by the ultrasonic sensor array corresponding to at least one first reflected ultrasonic wave received by at least a portion of the ultrasonic sensor array from a target object during a first acquisition time window. The control system may be configured to acquire second image data generated by the ultrasonic sensor array corresponding to at least one second reflected ultrasonic wave received by at least a portion of the ultrasonic sensor array from the target object during a second acquisition time window that is longer than the first acquisition time window. The control system may further be configured to initiate an authentication process based on the first image data and the second image data.

The present invention provides an audio device and a display device. The audio device comprises a vibrating diaphragm, an ultrasonic emitting element and a processing unit. The vibrating diaphragm is used for converting an acoustical signal into an electrical signal or converting an electrical signal into an acoustical signal, receiving a reflected wave signal of an ultrasonic signal generated by the ultrasonic emitting element after reflected from the a surface of an object to be detected, converting the reflected wave signal into an electrical signal, and sending the electrical signals to the processing unit. The processing unit is used for processing the converted electrical signals to obtain surface feature information of the object to be detected.

A testing system for testing a work piece. The testing system may be non-destructive. An associated method. The method may include obtaining C-scan images and corresponding S-scan images. The C-scan images and the corresponding S-scan images are of the same portion of the work piece being tested.

A non-destructive testing system for testing a work piece. The non-destructive testing system includes an ultrasonic probe, including a matrix of transducers, and a control unit including a display. The control unit is configured to control the ultrasonic probe. The ultrasonic probe and the control unit are configured to obtain multiple S-scan images. The ultrasonic probe and the control unit are configured to obtain a first S-scan image at a first direction orientation, and the ultrasonic probe and the control unit are configured to obtain a second S-scan image at a second direction orientation different from the first direction orientation. The control unit is configured to process the first and second S-scan images to provide at least an image upon the display.

A medical imaging apparatus, such as including a processor circuit, can be used to construct a first image of a plane parallel to the surface of an ultrasonic imaging transducer, the plane corresponding to a locus at a specified depth within a first region of tissue. The apparatus can obtain information about a location of a vessel in the first image, then obtain, from a second region of tissue, imaging information corresponding to loci in planes parallel to the surface of the transducer, the planes at depths automatically determined at least in part using the obtained information about the location of the vessel in the first image. In an example, the apparatus can automatically determine an adjusted depth corresponding to the location of the vessel in the second region, and construct a second image of a plane corresponding to the adjusted depth within the tissue.

The present invention provides an audio device and a display device. The audio device comprises a vibrating diaphragm, an ultrasonic emitting element and a processing unit. The vibrating diaphragm is used for converting an acoustical signal into an electrical signal or converting an electrical signal into an acoustical signal, receiving a reflected wave signal of an ultrasonic signal generated by the ultrasonic emitting element after reflected from the a surface of an object to be detected, converting the reflected wave signal into an electrical signal, and sending the electrical signals to the processing unit. The processing unit is used for processing the converted electrical signals to obtain surface feature information of the object to be detected.