An ultrasound control unit (10) is for coupling with an ultrasound transducer unit (12). The control unit is adapted to control a drive configuration or setting of the transducers of the transducer unit, each drive setting having a known power consumption level associated with it. The control unit includes a control module (20) adapted to adjust the drive setting from a first setting to a second setting, the second having a lower associated power consumption that the first. The second setting is tested by an analysis module (16), the analysis module adapted to determine a measure of reliability of ultrasound data acquired by the transducer unit, for the purpose of deriving at least one physiological parameter, when configured in the second setting. The second setting is only used if its determined reliability passes a pre-defined reliability condition.

The present disclosure describes ultrasound systems configured to enhance flow imaging and analysis by adaptively adjusting one or more imaging parameters in response to acquired flow measurements. Example systems can include an ultrasound transducer and one or more processors. Using the system components, mean flow velocity magnitude and acceleration can be determined within a target region during an acquisition phase, which may include a cardiac cycle. One or more adjusted flow imaging parameters, such as adjusted ensemble length, temporal smoothing filter length and/or step size, can be determined based on the acquired flow measurements to increase the signal quality of newly acquired ultrasound echo signals. The adjusted flow imaging parameters can then be applied by the ultrasound transducer during a second acquisition phase.

A failure determination apparatus of an ultrasound diagnosis apparatus includes a determination unit configured to, using a trained model trained on data generated in a first ultrasound diagnosis apparatus in a failed state as supervised data, determine whether a second ultrasound diagnosis apparatus is in a failed state based on data generated in the second ultrasound diagnosis apparatus, and a notification unit configured to notify an operator of a result of determination by the determination unit.

A method and ultrasound imaging system including a plurality of probe holders and a plurality of light assemblies attached to the plurality of probe holders. The plurality of light assemblies is configured to be controlled by a processor to selectively illuminate one or more of the plurality of probe holders.

A processor in an ultrasound imaging system identifies faults or errors in the system. In one embodiment, fault or error conditions are detected by monitoring system parameters during a self-test. In another embodiment, a processor provides ultrasound image data to a trained neural network to identify fault conditions in a transducer or the imaging system. In some embodiments, the processor makes adjustments to one or more operating parameters to compensate for the identified fault conditions so that the system continues to operate and produce images with the detected fault condition.

An example medical probe apparatus includes a main body; and a head which is detachably provided in the main body, and includes a transducer array configured to output an ultrasound for diagnosis of an object, the main body including: a transceiver configured to transmit and receive a signal to and from the transducer array through a plurality of channels; and at least one processor configured to control the transceiver to transmit a predetermined test signal to the transducer array of the head mounted to the main body, determine a probe type corresponding to the transducer array of the mounted head based on a feedback signal received through the transceiver in response to the test signal, and make the probe apparatus operate corresponding to the determined probe type.

Disclosed is a method and a device for characterizing, for example identifying at least one object depicted in a raster image (1) or determining the speed of sound of the object, the raster image (1) having pixel rows and pixel columns. In order to efficiently and accurately characterize the object, the invention provides that several pixel columns (Cn) are selected and each of the selected pixel columns (Cn) is converted into a line profile (L), the amplitude of the line profile (L) representing the value (V) of image information of selected pixels of the respective selected pixel column (Cn), wherein the method comprises determining characteristics of the line profiles (L) and using the characteristics to characterize the at least one object depicted in the raster image (1).

An ultrasonic device includes: oscillation elements to generate ultrasonic waves toward a subject, and generate voltages according to ultrasonic waves reflected by the subject; a switch to select voltages generated by a predetermined number of oscillation elements, from among the generated voltages; and semiconductor devices. Each semiconductor device includes: a first terminal to receive a second predetermined number of voltages different from voltages received by other semiconductor devices, among the selected voltages; a first adder to add data based on the second predetermined number of voltages; a second terminal to receive an addition result of data by the first adder of each of the other semiconductor devices; a second adder to add the addition results of the data received by the first adder and the data received by the second terminal; and an image generator to generate image data based on the addition result of the second adder.

Various embodiments enable calibrating a non-invasive blood pressure measurement device by determining multiple parameters defining a stress-strain relationship of an artery of a patient. The device may obtain output signals from a blood pressure sensor at two or more measurement elevations. The obtained measurement signals may be filtered into AC and quasi-DC components, and results fit to exponential functions to calculate an arterial time constant and a veinous time constant related to vein draining/filling rates. The arterial and veinous time constants may be used to calculate an infinity ratio. The infinity ratio and the obtained sensor output may be used to calculate values for multiple parameters defining a stress-strain relationship of a measured artery. Once defined, this stress-strain relationship may be stored and applied to future sensor output signals (e.g., blood pressure measuring sessions) to infer patient blood pressure.

Disclosed herein is a device for modeling properties of an ear. The device includes an artificial tympanic membrane and a housing coupled to the artificial tympanic membrane. The housing defines an interior portion coupled to an interior surface of the artificial tympanic membrane. The interior portion has an adjustable volume or an adjustable type of fluid and an adjustable gas pressure. Adjustment of the volume or type of fluid and the gas pressure changes a membrane movement to produce selected movement properties according to a mobility scale.