An ultrasonic measuring apparatus includes an ultrasonic transducer device having a substrate and an ultrasonic transducer element array that has a first channel group and a second channel group that are arranged on the substrate, a first integrated circuit apparatus that is mounted on the substrate, at one edge portion of the ultrasonic transducer element array in a first direction, such that a long-side direction coincides with a second direction that intersects the first direction, and performs at least one of signal transmission to the first channel group and signal reception from the first channel group, and a second integrated circuit apparatus that is mounted on the substrate, at the other edge portion of the ultrasonic transducer element array in the first direction, such that the long-side direction coincides with the second direction, and performs at least one of signal transmission to the second channel group and signal reception from the second channel group. In the ultrasonic transducer element array, the first group of channels and the second group of channels are arranged alternately every channel in the second direction.

Exemplary embodiments provide systems and methods for portable medical ultrasound imaging. Certain embodiments provide a multi-chip module for an ultrasound engine of a portable medical ultrasound imaging system, in which a transmit/receive chip, an amplifier chip and a beamformer chip are assembled in a vertically stacked configuration. Exemplary embodiments also provide an ultrasound engine circuit board including one or more multi-chip modules, and a portable medical ultrasound imaging system including an ultrasound engine circuit board with one or more multi-chip modules. Exemplary embodiments also provide methods for fabricating and assembling multi-chip modules as taught herein. A single circuit board of an ultrasound engine with one or more multi-chip modules may include 16 to 128 channels in some embodiments. Due to the vertical stacking arrangement of the multi-chip modules, a 128-channel ultrasound engine circuit board can be assembled within exemplary planar dimensions of about 10 cm×about 10 cm.

Ultrasound imaging systems including transducer probes having wireless tags, and associated systems and methods, are described herein. For example, the wireless tags can store supplemental data about the transducer probes, and the ultrasound system can include a base unit configured to wirelessly communicate with nearby ones of the wireless tags to receive the supplemental data. The base unit can be further configured to display the transducer probes that are nearby. In some embodiments, the operator can filter or sort the displayed nearby transducer probes based on the supplemental data to identify a particular one of the nearby transducer devices that has one or more desired attributes.

Apparatus for adaptively scheduling ultrasound device actions includes a probe interface, a beamer, a receiver, a processor, and a memory. The probe interface may interface with probe units to transmit signals generated by the beamer to the probe units and to receive data signals from the probe units. The processor may be coupled to the probe interface, the beamer, and the receiver. The memory may store instructions, which when executed by the processor, causes the processor to generate a task list that includes a timed beam firing sequence and to signal to the beamer to generate signals to the probe units associated with the plurality of task actions. The task list may include a plurality of task actions associated with probe units, and the processor may signal to the beamer in accordance with the timed beam firing sequence. Other embodiments are also described.

A beam composition method and device and an ultrasonic imaging device are provided. The method of beam composition comprises: obtaining the point-by-point delay data of the ultrasonic probe channel; compressing the point-by-point delay data according to the compression method to obtain the compressed data; and sending the compressed data to the hardware of the ultrasonic imaging system, so that the hardware can decompress the compressed data according to the compression method to obtain the point-by-point delay data and carry out beam composition according to the point-by-point delay data. The method can enhance the focusing precision of ultrasonic beam composition.

Various methods and systems are provided for a removable transducer module having memory. In one example, a transducer module for an ultrasound imaging system comprises a casing configured to fit into a module receiver of the ultrasound imaging system, an array of transducer elements, and a non-transitory memory configured to store at least one of usage data and specification data for the transducer module.

An ultrasound imaging system comprising a multi-use electronic display device and an ultrasound imaging device. The multi-use electronic display device is capable of communicating with one or more ultrasound imaging devices and selecting which to connect with based on at least one of previously store information, user input, and information gathered from the ultrasound imaging devices. The multi-use electronic display device may communicate with the ultrasound imaging devices while they are in a low power standby state. This approach reduces the complexity of the pairing process and provides a means for quickly and easily selecting between multiple ultrasound imaging devices.

An ultrasound imaging system comprising a multi-use electronic display device and an ultrasound imaging device. The multi-use electronic display device is capable of communicating with one or more ultrasound imaging devices and selecting which to connect with based on at least one of previously store information, user input, and information gathered from the ultrasound imaging devices. The multi-use electronic display device may communicate with the ultrasound imaging devices while they are in a low power standby state. This approach reduces the complexity of the pairing process and provides a means for quickly and easily selecting between multiple ultrasound imaging devices.

An ultrasound imaging device, including: a processor (10), N ultrasound systems (20), a communication channel (30) and an ultrasonic probe (40); where N is a positive integer greater than 1; the processor (10) is configured to receive an ultrasound system setting instruction input by a user, so that a ultrasound system (20) of the N ultrasound systems (20) is in an enabled state; the ultrasound system (20) in the enabled state is configured to send a control instruction to the ultrasonic probe (40) via the communication channel (30); and the ultrasonic probe (40) is configured to cooperate with the ultrasound system (20) in the enabled state to operate according to the control instruction.

Ultrasound image devices, systems, and methods are provided. In one embodiment, an ultrasound imaging system includes an ultrasound imaging probe configured to acquire image data associated with an object at an acquisition data rate; and a communication interface in communication with the ultrasound imaging probe and configured to transmit a first subset of the image data in real time based on the acquisition data rate; and transmit a second subset of the image data at a delayed time. In one embodiment, a method of ultrasound imaging includes acquiring, by an ultrasound imaging probe, image data associated with an object at an acquisition data rate; transmitting, to a host via a communication link, a first subset of the image data in real time based on the acquisition data rate; and transmitting, to the host via the communication link, a second subset of the image data at a delayed time.