An ultrasound system comprising a probe adapted for emitting and receiving ultrasound waves inside a medium, and a processing unit connected to said probe and adapted for processing signals from the probe. The probe is configured so as to behave as a Fresnel lens for focusing the ultrasound waves. The processing unit analyses signals from the probe for sensing the medium at a plurality of focal points.

An ultrasound imaging apparatus includes: a processor; and a storage. The storage is configured to store first-type reference data corresponding to a first observation target and second-type reference data corresponding to a second observation target. The processor is configured to transmit, to an ultrasound probe, a signal for making the ultrasound probe transmit an ultrasound wave to an observation target, receive an echo signal, perform frequency analysis based on the echo signal to calculate a frequency spectrum, obtain reference data, correct the frequency spectrum using the reference data, calculate a feature based on the corrected frequency spectrum, when the observation target is the first observation target, obtain the first-type reference data as the reference data, and when the observation target is the second observation target, obtain the second-type reference data as the reference data.

Systems and methods for attenuation measuring using ultrasound. In various embodiments, echo data corresponding to a detection of echoes of one or more ultrasound signals transmitted into tissue are received. The echoes can be received from a range of depths of the tissue. Spectral measurements across the range of depths of the tissue are obtained using the echo data. Attenuation characteristics of the tissue across the range of depths of the tissue can be estimated using the spectral measurements across the range of depths of the tissue. Specifically, the attenuation characteristics of the tissue can be estimated using the spectral measurements and known spectral characteristics of the one or more ultrasound signals transmitted into the tissue.

Systems and methods for attenuation measuring using ultrasound. In various embodiments, echo data corresponding to a detection of echoes of one or more ultrasound signals transmitted into tissue are received. The echoes can be received from a range of depths of the tissue. Spectral measurements across the range of depths of the tissue are obtained using the echo data. Attenuation characteristics of the tissue across the range of depths of the tissue can be estimated using the spectral measurements across the range of depths of the tissue. Specifically, the attenuation characteristics of the tissue can be estimated using the spectral measurements and known spectral characteristics of the one or more ultrasound signals transmitted into the tissue.

A transducer is provided, which includes an oscillator and a broadbanded matching circuit. In the oscillator, a peak frequency corresponding to a peak transmission sensitivity may separate from a center frequency in a given bandwidth, and a transmission sensitivity may increase as a frequency separates from the peak frequency with respect to the center frequency. The broadbanded matching circuit may be configured to perform an impedance matching so that the transmission sensitivity of the oscillator at the peak frequency becomes substantially equal to the transmission sensitivity of the oscillator at the center frequency.

A diagnostic ultrasound apparatus includes a sound ray signal generator, an extractor and an arithmetic unit. The sound ray signal generator generates a sound ray signal based on a reception signal obtained from an ultrasound probe. The ultrasound probe transmits and receives ultrasound to and from a subject. The extractor extracts imaging signals from the sound ray signal by performing filtering of passing different bands. The arithmetic unit generates a difference signal by using the imaging signals, and performs an arithmetic operation on at least one of the imaging signals by using the difference signal.

An ultrasound system is disclosed. Embodiments in accordance with the present invention include a transducer configured to acquire pulse-echo data at each transmit frequency bandwidth of interest. In addition, a bandpass filter is configured to receive a signal of the pulse-echo data, wherein the signal is bandpass-filtered over a plurality of frequencies. Further, a processor is configured to calculate a spatial coherence of the bandpass-filtered signal. The spatial coherence of the signal is calculated in a spatial domain or a frequency domain. The spatial coherence is used to predict target conspicuity. The processor selects a preferred frequency based on and, preferably, to realize, the target conspicuity.

An ultrasound system is described which produces blended fundamental and harmonic frequency images. Successively transmitted, differently modulated pulses are transmitted by an ultrasound probe and both fundamental and harmonic frequencies are received in response. The echo signals received from the two pulses are processed by pulse inversion, producing cleanly separated bands of fundamental and harmonic signals in which undesired components have been cancelled. Since the two bands have been separated by signal cancellation rather than filtering, the two bands are allowed to overlap, providing broadband signals in each band. The bands are filtered by bandpass filtering to define the fundamental and harmonic signals to be imaged. The signals are detected, and the detected signals are combined after weighting to produce a blended fundamental/harmonic image.

A two-dimensional wideband ultrasound transducer array for three or four-dimensional (volume+time) non-invasively imaging/mapping of electrical current in, for example, the brain through the skull, or the heart. The probe also has unique capabilities for three-dimensional transcranial or transthoracic pulse echo ultrasound (tissue structure, motion, bone thickness) and doppler blood flow imaging. The handheld device interfaces with an ultrasound delivery system for applications to human brain or heart imaging, ultrasound neuromodulation, and therapy. The handheld ultrasound array enables three-dimensional steering of an ultrasound beam through the human skull or chest for ultrasound, doppler, and acoustoelectric imaging and related modalities to aid in the diagnosis and treatment of brain or heart disorders.

Methods, systems, and apparatuses are disclosed for ultrasound imaging comprising Time Delay Spectrometry. A frequency swept signal can be transmitted through a medium, such as human tissue. The signal can be a low-voltage signal (e.g., 0 volts to 5 volts peak-to-peak) transmitted for long duration (e.g., 20 milliseconds) at various frequencies. As the signal propagates through the medium it can be reflected and delayed. A delay associated with the signal the can cause a change in the associated frequencies. The signal can be filtered to retain only frequencies in an audio frequency range. The signal can be beamformed and processed to produce an image.