An ultrasound signal processing device: performing events involving transmitting ultrasound towards a subject; receiving ultrasound reflection from the subject in response to each event; and generating a frame signal from sub-frame signals generated based on the ultrasound reflection. The device, in each event, causes a transmission aperture to transmit ultrasound focusing in the subject. A transmission aperture for one event differs in position, in a transducer element array direction, from a transmission aperture for a previous event by a shift amount of at least twice a transducer element width. The device, for each event, sets a target area which includes a position where transmitted ultrasound focuses and whose width in the transducer element array direction, at a depth where the transmitted ultrasound focuses, is equal to or greater than the shift amount. The device generates a sub-frame signal covering measurement points included in the target area.

Synthetic-aperture ultrasound tomography systems and methods using scanning arrays and algorithms configured to simultaneously acquire ultrasound transmission and reflection data, and process the data for improved ultrasound tomography imaging, wherein the tomography imaging comprises total-variation regularization, or a modified total variation regularization, particularly with edge-guided or spatially variant regularization.

A Multiple Aperture Ultrasound Imaging system and methods of use are provided with any number of features. In some embodiments, a multi-aperture ultrasound imaging system is configured to transmit and receive ultrasound energy to and from separate physical ultrasound apertures. In some embodiments, a transmit aperture of a multi-aperture ultrasound imaging system is configured to transmit an omni-directional unfocused ultrasound waveform approximating a first point source through a target region. In some embodiments, the ultrasound energy is received with a single receiving aperture. In other embodiments, the ultrasound energy is received with multiple receiving apertures. Algorithms are described that can combine echoes received by one or more receiving apertures to form high resolution ultrasound images. Additional algorithms can solve for variations in tissue speed of sound, thus allowing the ultrasound system to be used virtually anywhere in or on the body.

Acoustic data, such as a full matrix capture (FMC) matrix, can be reconstructed by applying a previously trained decoder machine learning model to one or more encoded acoustic images, such as the TFM image(s), to generate reconstructed acoustic data. A processor can use the reconstructed acoustic data, such as an FMC matrix, to recreate new encoded acoustic images, such as TFM image(s), using different generation parameters (e.g., acoustic velocity, part thickness, acoustic mode, etc.)

Systems, devices, and methods are disclosed for acquiring and providing information about orthopedic features of a body using acoustic energy. In some aspects, an acoustic orthopedic tracking system includes portable acoustic transducers to obtain orthopedic position information for feeding the information to an orthopedic surgical system for surgical operations.

Techniques, systems, and devices are disclosed for synthetic aperture ultrasound imaging using a beamformer that incorporates a model of the object. In some aspects, a system includes an array of transducers to transmit and/or receive acoustic signals at an object that forms a synthetic aperture of the system with the object, an object beamformer unit to (i) beamform the object coherently as a function of position, orientation, and/or geometry of the transducers with respect to a model of the object, and (ii) produce a beamformed output signal including spatial information about the object derived from beamforming the acoustic echoes; a data processing unit to process data and produce an image of the object based on a rendition of the position, the orientation, the geometry, and/or the surface properties of the object, relative to the coordinate system of the array, as determined by the data processing unit.

According to one embodiment, an ultrasonic diagnostic apparatus includes processing circuitry. The processing circuitry determines whether or not to increase the number of beams to be compounded based on the information on the examination mode and increases the number of beams to be compounded when determining that the number of beams to be compounded is to be increased.

Systems and methods are provided for suppressing the side-lobe artifacts in ultrasound imaging with plane wave compounding. The use of discrete angles in transmitting plane waves may be used to suppress side-lobes and the resulting side-lobe artifacts without increasing the number of firings required. A method is provided that utilizes nulls in Rx beam pattern to suppress side-lobes based on the beam pattern formula. An apodization technique that uses window functions according to Tx angles and/or Rx aperture may also be used. A method using aperiodic sampling angles may also be used to suppress artifacts. Application to arbitrary interval sampling angles may be found. Suppressing artifacts according to the present disclosure may provide for wider field of view imaging without resorting to increasing the number of firings required (NFR).

Systems and methods of ultrasound imaging are provided. In some embodiments, unfocused and diverging ultrasound signals can be transmitted into a target medium from an apparent point source located aft of a concave probe surface. The echoes can be received, and a location of a reflector within the target medium can be determined. The location can be determined by obtaining element position data describing a position of the spherical center point of the apparent point source r and a position of the receive element, calculating a total path distance as a sum of a first distance between the spherical center point and the reflector and a second distance between the reflector and the receive element, and determining a locus of possible points at which the reflector may lie. A data set can then be produced for the entire target medium.

An intraluminal imaging device includes a flexible elongate member configured to be inserted into a lumen within a body of a patient, the flexible elongate member comprising a longitudinal axis; an imaging assembly coupled to the flexible elongate member, the imaging assembly comprising: a plurality of ultrasound transducer elements disposed around the longitudinal axis of the flexible elongate member; a plurality of controllers configured to control the plurality of ultrasound transducer elements to obtain imaging data associated with the lumen; and a plurality of electrical wires extending between the plurality of the ultrasound transducer elements and the plurality of controllers and configured to facilitate communication between the plurality of the ultrasound transducer elements and the plurality of controllers.