A system comprising a multi-modal ultrasound probe configured to operate in a plurality of operating modes associated with a respective plurality of configuration profiles; and a computing device coupled to the handheld multi-modal ultrasound probe and configured to, in response to receiving input indicating an operating mode selected by a user, cause the multi-modal ultrasound probe to operate in the selected operating mode.

A universal ultrasound device having an ultrasound probe includes a semiconductor die; a plurality of ultrasonic transducers integrated on the semiconductor die, the plurality of ultrasonic transducers configured to operate a first mode associated with a first frequency range and a second mode associated with a second frequency range, wherein the first frequency range is at least partially non-overlapping with the second frequency range; and control circuitry configured to: control the plurality of ultrasonic transducers to generate and/or detect ultrasound signals having frequencies in the first frequency range, in response to receiving an indication to operate the ultrasound probe in the first mode; and control the plurality of ultrasonic transducers to generate and/or detect ultrasound signals having frequencies in the second frequency range, in response to receiving an indication to operate the ultrasound probe in the second mode.

Implementations of the present disclosure are directed to an injection device that includes a medicament reservoir, a stopper including a rigid core and an ultrasound probe disposed in a housing, the ultrasound probe configured to transmit an emitted ultrasound signal through the rigid core along a longitudinal direction of the rigid core into the medicament reservoir and to receive an ultrasound signal generated by reflections of the emitted ultrasound signal, the reflections including at least a reflection from a distal end of the medicament reservoir, a control component configured to be electronically coupled with the ultrasound probe and to process the ultrasound signal to generate injection device data, and an antenna configured to be electronically coupled with the control component and to transmit the injection device data to an external computing device.

Image data acquired by transmitting and receiving an ultrasonic wave are stored in a storage. A controller is configured to control, based on an available capacity of the storage and a performance capability of an ultrasonic diagnostic apparatus incorporating the controller, an optimization process to optimize the image data stored in the storage. The optimization process is, for example, a process to relocate the image data stored in the storage, or a process to delete data of an image from the storage. The controller may be configured to prompt a user to initiate the optimization process or automatically perform the optimization process.

Based on a set of preset data for setting operation conditions, which is selected prior to an ultrasonic examination, a transfer control unit determines an image attribute of an image obtained in the ultrasonic examination. The transfer control unit selects, from among a plurality of servers, a transfer destination server assigned a server attribute suitable for the image attribute. The transfer control unit transfers the image to the transfer destination server.

An ultrasonic device may include an electromechanical ultrasonic system defined by a predetermined resonant frequency and include an ultrasonic transducer coupled to an ultrasonic blade. A method of delivering energy to the device may include applying energy to the blade at a first power level via the transducer coupled to the blade, measuring a complex impedance of the transducer, receiving a complex impedance feedback data point, comparing the complex impedance feedback data point to a reference complex impedance characteristic pattern, and determining that the blade is contacting a vessel based on the comparison. The method may also include disabling the power applied to the transducer and switching to a lower power level. The method may further include generating a warning that the blade is contacting a vessel, such as a light or a sound. An ultrasonic surgical instrument may effect the method.

An ultrasonic imaging method includes emitting ultrasonic pulses in different directions and acquiring ultrasonic echo signals from an object, calculating an attenuation rate of the ultrasonic echo signals, correcting the acquired ultrasonic echo signals based on the attenuation rate, and outputting the corrected ultrasonic echo signals as an ultrasonic image.

The invention relates to the technical field of medical image processing, and more particularly, to a distributed ultrasonic scanning system and a communication method. The method comprises at least one ultrasonic scanning device, comprising at least one scanning probe for performing an ultrasonic scanning operation on a patient to obtain echo data; a data acquisition unit, connected to the at least one ultrasonic scanning device, configured to receive the echo data and to compress the echo data to generate compressed data; and a processing host, connected to the data acquisition unit, configured to obtain the compressed data and to generate a first ultrasonic image according to the compressed data. The present invention has the beneficial effects that a data acquisition unit is provided to enable ultrasonic image data to effectively flow in the network, so that the problem of a poor flow of the image is avoided.

A wireless handheld ultrasound system an ultrasound front end to transmit ultrasonic waves into a subject and convert received ultrasonic echoes into digital data; an image processor coupled to the ultrasound front end to convert the digital data into an image; and a power section coupled to the ultrasound front end and the image processor. The power section may include a battery; a charging circuit to charge the battery; and a wireless power transducer coupled to the charging circuit to convert wireless power received from an external source into electrical energy for the charging circuit.

An ultrasound imaging probe includes a housing, a circuit board assembly disposed within the housing including a microcontroller, and a motion sensor operably connected to the microcontroller and capable of sensing motion of the housing based on at least one operator interaction with the housing to generate sensor data, a memory chip disposed within the housing and storing information regarding particular operational configurations for the ultrasound imaging probe associated with stored sensor data representing types of stored operator interactions, and a power source disposed at least partially within the housing and operably connected to the assembly. The microcontroller is configured to receive sensor data from the motion sensor in response to the operator interaction with the housing, to compare the received sensor data with the stored sensor data, and to change an operational configuration of the ultrasound probe in response to matching the received sensor data with stored sensor data.