A synchronization method is suitable between a first electronic apparatus and a second electronic apparatus. The synchronization method include following steps. A first interrupt signal is generated to trigger a first timer on the first electronic apparatus. A radio frequency packet is transmitted from the first electronic apparatus to the second electronic apparatus. In response to that the radio frequency packet is received by the second electronic apparatus, a second interrupt signal is generated to trigger a second timer on the second electronic apparatus. The second timer is synchronized with the first timer or a timestamp of the first timer is estimated according to the second interrupt signal and the radio frequency packet.

An ultrasound imaging system integrated on a chip for autonomous scanning includes an on-chip input memory configured to store scan sequence instructions and parameters, an on-chip processor configured to read the scan sequence instructions and parameters in the input memory, and an on-chip beamformer configured to be programmed and timed by the processor according to the scan sequence instructions and parameters. In some examples, the scan sequence instructions and parameters are stored in a nonvolatile input memory programmed at the factory. In other examples, they are received from an external user device. The scan parameters are optimized or minimized to accommodate the limited input memory capacity. In some examples, the scan sequence instructions and parameters include programmable nested loops, and each of the programmable nested loops corresponds to a transmit and/or receive event in a scan sequence.

Disclosed herein are an ultrasound imaging apparatus and a control method thereof. The ultrasound imaging apparatus includes: a display unit configured to display an ultrasound image and an external image such that a first reference line overlaps the ultrasound image and a second reference line overlaps the external image; an ultrasound probe configured to receive a command for moving or rotating at least one image of the ultrasound image and the external image based on a predetermined reference coordinate system; and a controller configured to determine whether the ultrasound image matches with the external image according to manipulation of the ultrasound probe, and to control the display unit to synthesize the ultrasound image with the external image and to display the ultrasound image and the external image, if determining that the ultrasound image matches with the external image.

A 3D ultrasonic diagnostic imaging system produces 3D cardiac images at a 3D frame rate of display which is equal to the acquisition rate of a 3D image dataset. The volumetric cardiac region being imaged is sparsely sub-sampled by separated scanning beams. Spatial locations between the beams are filled in with interpolated values or interleaved with acquired data values from other 3D scanning intervals depending upon the existence of motion in the image field. A plurality of different beam scanning patterns are used, different ones of which have different spatial locations where beams are located and beams are omitted. A sequence of different beam scanline patterns may be continuously repeated, or the patterns of the sequence synchronized with the cardiac phases such that, over a sequence of N heartbeats, the same respective phase is scanned by N different scanline patterns.

A method of ultrasound imaging includes acquiring plural groups of ultrasound data sets in an imaged volume that at least partially encompasses an object. The groups of ultrasound data sets include ultrasound image data obtained by transmitting one or more ultrasound pulses from one or more transducer elements into different zones of the imaged volume. The method also includes arranging the ultrasound data sets into one or more temporal groups based on when the ultrasound data sets are acquired. The ultrasound data sets in each temporal group are acquired during a common time period. The method further includes constructing a three-dimensional image of the object based on the ultrasound data sets in at least one of the temporal groups.

An ultrasonic device includes a plurality of ultrasonic element groups each including at least one transmitting element adapted to transmit an ultrasonic wave and at least one receiving element adapted to receive an ultrasonic wave, and arranged along an X direction, and in each of the ultrasonic element groups, a centroid position of the receiving area, in which the receiving element included in the ultrasonic element group is disposed, overlaps a transmitting area, in which the transmitting element included in the ultrasonic element group is disposed, in a projection view along a Y direction.

An ultrasonic imaging system including an insertion member, a calculator, an estimator, and a synchronization controller are provided. The insertion member inserted into a living body has a light absorption element that absorbs a light pulse to generate a photoacoustic wave. The calculator calculates an actual measurement value of a synchronization deviation based on a reception signal sequence before a phase alignment addition or a pseudo-reception signal sequence corresponding to the reception signal sequence. The estimator estimates an estimation value of the synchronization deviation based on a synchronization deviation history. The synchronization controller changes a light pulse cycle or a reception cycle based on the actual measurement value in a case where the photoacoustic wave is detected, or changes the light pulse cycle or the reception cycle based on the estimation value in a case where the photoacoustic wave is not detected.

Systems and methods for ultrafast imaging include: a memory having stored thereon a delay profile matrix and a field programmable gate array (FPGA) coupled with the memory. The delay profile matrix comprises a two-dimensional matrix in which each row corresponds to a delay profile at a particular depth. The FPGA is configured to: acquire radio frequency (RF) ultrasound data from a subject; load a delay profile from the delay profile matrix to a memory buffer of the FPGA, wherein the delay profile corresponds to a particular depth; read a first row of the RF ultrasound data based on a first delay value of the delay profile; generate beamformed data at the particular depth by beamforming the first row of RF ultrasound data; and generate an image of the subject based on the beamformed data.

A method of distributing data to a transducer array of an ultrasonic device, the transducer array including transduction elements arranged in module units, includes generating a data packet using an optical transceiver controlled by a controller, the data packet including activation instructions encoded in a first wavelength, transmitting the data packet from the controller to a target device via a signal in an optical fiber, the target device having a beam divider device, splitting the data signal, using the beam divider device, into a plurality of data streams, where each of the data streams carries the data packet in an identical phase, transmitting the data streams to the module units, and activating the transduction elements based on the received data streams.