In accordance with a method for characterization of particles in a fluid-filled hollow structure, an ultrasound signal with a frequency spectrum, which exhibits a local maximum at a variable measurement frequency, is emitted in the direction of a part area of the hollow structure and reflected components are detected. The measurement frequency is tuned in a predetermined measurement interval, and depending on the detected reflected components, a spectral response curve is acquired as a function of the measurement frequency. Depending on the response curve, at least one characteristic property for a part of the particles located in the part area of the hollow structure is determined. The characteristic property includes a measure for an adhesion of the particles of the part of the particles located in the part area of the hollow structure.

The present disclosure discloses an ultrasonic imaging method. The ultrasonic imaging method may include: obtaining emitting instructions for emitting a plurality of ultrasonic waves, gaining instructions, receiving instructions, and idle instructions relating to the plurality of ultrasonic waves, and storing the emitting instructions, the receiving instructions, the gaining instructions, and the idle instructions in a ring buffer; obtaining the emitting instructions from the ring buffer, and emitting the plurality of ultrasonic waves based on the emitting instructions; obtaining a gaining instruction and a receiving instruction corresponding to each emission of the plurality of ultrasonic waves from the ring buffer, and obtaining at least one enhanced echo signal based on the gaining instructions and the receiving instructions; and obtaining the idle instructions from the ring buffer, and processing the at least one enhanced echo signal based on the idle instructions to obtain a target ultrasonic image.

A method of power Doppler imaging may include receiving a plurality of temporally sequential frames of wall-filtered power Doppler signals, wherein the plurality of temporally sequential frames includes at least one previously adjusted output frame. The method may further include adjusting at least one of the plurality of temporally sequential frames to produce an adjusted output frame and generating a power Doppler image based, at least in part, on the adjusted output frame. The adjusting may involve filtering the plurality of temporally sequential frames to suppress the high spatial frequency and high temporal frequency content to produce the adjusted output frame.

The present invention relates to an apparatus for tracking a position of an interventional device respective an image plane of an ultrasound field. The position includes an out-of-plane distance (Dop). A geometry-providing unit (GPU) includes a plurality of transducer-to-distal-end lengths (Ltde.sub.1 . . . n), each length corresponding to a predetermined distance (Ltde) between a distal end of an interventional device and an ultrasound detector attached to the interventional device, for each of a plurality of interventional device types (T.sub.1 . . . n). An image fusion unit (IFU) receives data indicative of the type (T) of the interventional device being tracked; and based on the type (T): selects from the geometry-providing unit (GPU), a corresponding transducer-to-distal-end length (Ltde); and indicates in a reconstructed ultrasound image (RUI) both the out-of-plane distance (Dop) and the transducer-to-distal-end length (Ltde) for the interventional device within the ultrasound field.

An ultrasound signal processing apparatus includes: a receiver configured to receive a positive phase ultrasound reception signal and a negative phase ultrasound reception signal; and a processor including hardware, the processor being configured to perform phasing addition on each of the positive phase ultrasound reception signal and the negative phase ultrasound reception signal, and adding the positive phase ultrasound reception signal subjected to the phasing addition and the negative phase ultrasound reception signal subjected to the phasing addition with shifting of a predetermined period of time.

An ultrasound imaging system which uses multiline receive beamforming for synthetic transmit focusing are phase adjusted to account for speed of sound variation in the transmission medium. The phase discrepancy of the received multilines caused by speed of sound variation in the medium is estimated in the frequency domain for both the transmit angular spectrum and the receive angular spectrum. The phase variation is removed in the frequency domain, then an inverse Fourier transform is used to transform the frequency domain results to the spatial domain. In another implementation, the phase discrepancy of the received multilines is estimated and corrected entirely in the spatial domain.

An acoustic technique can be used for performing non-destructive testing. For example, a method for acoustic evaluation of a target can include generating respective acoustic transmission events via selected transmitting ones of a plurality of electroacoustic transducers, and in response to the respective acoustic transmission events, receiving respective acoustic echo signals using other receiving ones of the plurality of electroacoustic transducers, and coherently summing representations of the respective received acoustic echo signals to generate a pixel or voxel value corresponding to a specified spatial location of the target. Such summation can include weighting contributions from the respective representations to suppress contributions from acoustic propagation paths outside a specified angular range with respect to a surface on or within the target, such as to provide an acoustic path-filtered total focusing method (PF-TFM).

A diagnostic ultrasound apparatus includes: a sound ray signal generator that generates a sound ray signal based on a reception signal obtained from an ultrasound probe that transmits and receives ultrasound to and from a subject; an imaging signal generator that performs filtering of passing different bands on the sound ray signal to generate multiple imaging signals from the sound ray signal; and a calculator that performs an arithmetic operation among the imaging signals.

Methods and systems are provided for receiving beamforming of ultrasound signals to generate ultrasound images with increased resolution. In one example, a method for an ultrasound system including a plurality of ultrasound transducers each coupled to a respective receive channel includes time-delaying a set of ultrasound receive channel signals to form a plurality of time-delayed sets of ultrasound receive channel signals, each time-delayed set of ultrasound receive channel signals time-delayed based on a different beamforming sound speed, calculating a beamforming quality metric for each receive channel and for each time-delayed set of ultrasound receive channel signals, and generating an ultrasound image from ultrasound receive channel signals selected from the plurality of time-delayed sets of ultrasound receive channel signals based on each beamforming quality metric.

Some embodiments relate to the application of a system and a signal processing method for data acquired from a Scanning Acoustic Microscope (SAM) to obtain a high axial resolution and enhanced imaging. The SAM is one of ultrasound imaging methods used for NDE. Embodiments may provide methods for decreasing or reducing the duration (width) of the pulses scattered/reflected by multiple objects/scatters. Such embodiments can accomplish this by eliminating, or at least partially eliminating, the background noise by deconvolving the system responses (i.e., reference signals) obtained from either theoretical modeling or experimental acquiring. In one embodiment, the method minimizes the pulse duration by using a regression technique to predict the spectra responses outside a frequency band.