The subject matter of this specification can be embodied in, among other things, a position sensor system that includes a fluid effector that includes a housing having an inner surface defining a cavity, and a moveable body having a first face and a second face opposite the first face and configured to contact the inner surface and subdivide the cavity to define a first chamber and a second chamber, an acoustic transmitter system configured to emit a first emitted waveform toward the first face, and emit a second emitted waveform toward the second face, and an acoustic receiver system configured to detect a first reflected waveform based on a first reflection of the first emitted waveform based on the moveable body, and detect a second reflected waveform based on a second reflection of the second emitted waveform based on the moveable body.

A body tissue to be detected is automatically detected certainly with high precision. An ultrasonic body tissue detecting device may include a transmission/reception unit, a two-dimensional data acquisition unit, a spatial frequency distribution calculation unit and a determination unit. The transmission/reception unit may transmit an ultrasonic signal into a body of a sample and receive an echo signal of the ultrasonic signal. The two-dimensional data acquisition unit may form two-dimensional echo image in a transmitting direction of the ultrasonic signal and in a scanning direction. The spatial frequency distribution calculation unit may perform a spatial frequency conversion of the two-dimensional echo image and calculate a spatial frequency distribution for a determining position. The determination unit may determine whether the determining position is the body tissue to be detected based on a distribution of amplitude in the transmitting direction of the ultrasonic signal and a distribution of amplitude in the scanning direction of the spatial frequency distribution.

Disclosed are ultrasound medical detection devices and an imaging method, an imaging system and a display terminal. This method comprises: displaying an ultrasonic image on a first display screen, obtaining a mark point within the active area of a bicuspid valve on the ultrasonic image, automatically searching for a ventricular internal diameter reference point according to the mark point, calculating a hemodynamic parameter according to the internal diameter reference point and outputting the calculation result of the hemodynamic parameter.

A diffuse acoustic confocal imager device for use with a data analyzer for providing a three dimensional and state information on an object based on an at least one phase image, the device comprising a coherent acoustic source for producing an acoustic confocal beam ranging from about 0.5 megahertz to about 100 megahertz, an acoustic coherent beam focuser for focusing the acoustic coherent beam to a virtual source, an acoustic detector for detecting an at least one diffusely scattered beam from the virtual source and a vector network analyzer, which is for measuring a phase of the acoustic confocal beam and a phase of the at least one diffusely scattered beam to provide the at least one phase image, the vector network analyzer in electronic communication with each of the coherent acoustic source and the acoustic detector. A method of detecting and treating diseases such as prostate cancer and ovarian cancer is also provided.

Acoustic imaging based on angular coherence is provided. The target is insonified with collimated acoustic beams at several different incidence angles. The resulting images are processed to determine angular coherence averaged over angle, and then integration of the angular coherence for relatively small angular differences is used to provide the output angular coherence image. In cases where flow imaging is done, the images are first filtered to suppress signals from stationary features of the target, multiple acquisitions are acquired, and the final flow image is computed by summing the squares of the angular coherence images (on a pixel by pixel basis).

An image generation apparatus includes an arithmetic processing unit that generates an ultrasonic image based on a received signal obtained by receiving a reflected wave from a subject of an ultrasonic wave incident on the subject. The arithmetic processing unit calculates an attenuation feature value at each position in an incidence direction of the ultrasonic wave based on the received signal, performs signal processing on the attenuation feature value at each position in the incidence direction, and generates an attenuation feature image using the attenuation feature value subjected to the signal processing.

Ultrasound-based acoustic streaming for deciding whether material is fluid is dependent upon any one or more of a variety of criteria. Examples are displacement, speed (230), temporal or spatial flow variance, progressive decorrelation, slope or straightness of accumulated signal to background comparisons over time, and relative displacement to adjacent soft tissue. Echogenicity-based area identification is combinable with the above movement characteristic detection in the deciding. Fluid pool identification is performable from the area-limited acoustic streaming testing and ultrasound attenuation readings. Candidates from among the areas (210) are screenable based on specific shapes or bodily organs detected. Natural flow can be excluded from streaming detection by identification of blood vessels (206). Processing for each FAST ultrasound view (202), or for the entire procedure, is performable automatically, without need for user intervention or with user intervention to identify suspected areas.

In backscatter coefficient imaging, a backscatter coefficient of one region of interest relative another region of interest is used to avoid calibration. The system effects are removed by using a frequency-dependent measure of the backscatter. The relative frequency-dependent backscatter coefficient is determined by an ultrasound scanner.

An ultrasound diagnostic equipment is equipped with an ultrasound probe which transmits an ultrasound wave toward an inner part of a subject and receives the ultrasound wave reflected with a particle body in the subject and acquires a received signal to displays internal body information in the subject based on the received signal. The ultrasound diagnostic equipment includes: an acquisition section to acquire the received signal for each of ultrasound waves of which frequencies differ; an intensity ratio calculation section to calculate an intensity ratio of the ultrasound wave for each of frequencies; and a display section to display the information on the intensity ratio.

A percutaneously delivered medical device and its method of use includes a catheter, at least two electromagnetic sensing coils located within the distal tip of the catheter, and at least one within the proximal handle, and a multi-element planar ultrasound transducer array located within the distal tip of the catheter and configured to transmit and receive ultrasonic energy in at least two imaging modes. The device also includes an imaging system coupled to the ultrasound transducer and is used for creating an image of tissue in a first target plane that extends orthogonally from the catheter body. The medical device also includes a backscatter evaluation system for use in receiving and evaluating the acoustic spectral characteristics of tissues within a second target area within the first target plane.