A transducer for an ultrasound imaging system includes an array of transducer elements and an analog-to-digital converter configured to convert analog signals produced by the transducer elements into corresponding digital samples that are encoded with a first number of bits. One or more memories are used to store digital samples associated with frames of ultrasound data. A processor or logic circuit in the transducer is configured to compress the digital ultrasound data by calculating differences between the samples and encoding the differences with a second number of bits that is less than the first number of bits. In addition, the logic circuit is configured to transmit a packet that includes the differences encoded with the second number of bits and an overflow portion that encodes the differences that are too large to be encoded with the second number of bits.

There are provided an ultrasound image generating apparatus, which generates a high-quality ultrasound image even in a deep portion of a subject, and a control method thereof. In an ultrasound image (Img), for a portion (Ar1) equal to or less than a depth threshold value (D1), a real scanning line (L1) obtained from an acoustic wave echo signal is used. In the ultrasound image (Img), for a portion (Ar2) deeper than the depth threshold value (D1), an interpolation scanning line (L2) located between the real scanning lines (L1) is generated from an acoustic wave echo signal having a positional deviation between a focusing position of ultrasound waves and an observation target position. Also for a portion deeper than the interpolation scanning line (L2), a high-quality ultrasound image (Img) is obtained.

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.

A handheld ultrasound device may comprise components configured to provide decreased size, weight, complexity, and power consumption. The handheld ultrasound device may comprise a beamformer configured to implement and compress a flag table in place of a delay table. These improvements can decrease the amount of memory used to generate ultrasound images, which can decrease the size, weight, and power consumption of the handheld ultrasound device. Ultrasound image data on a handheld imaging probe can be compressed on the handheld imaging probe prior to transmission from the probe in order to decrease the amount of data transmitted from the probe. The compressed data may comprise compressed pixels to maintain spatial image resolution. The compression circuitry may comprise an amount of memory related to a dynamic range of the compressed data that is independent of the dynamic range of the input data, which can decrease memory, power consumption, and latencies.

Systems and methods for encoding radiofrequency, RF, data, e.g., electrical signals, by a microbeamformer are disclosed herein. The microbeamformer may use a pseudo-random sampling pattern (700) to sum samples of the RF data stored in a plurality of memory cells. The memory cells may be included in a delay line of the microbeamformer in some examples. The summed samples may form an encoded signal transmitted to a decoder which reconstructs the original RF data from the encoded signal. The decoder may use knowledge of the pseudo-random sampling pattern to reconstruct the original data in some examples.

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.

An acoustic wave probe (2) includes a reception circuit (13) that generates a sound ray signal from a reception signal of a transducer array (11); a Doppler processing unit (15) that performs Doppler processing on the sound ray signal to generate Doppler data; a Doppler image generation unit (16) that generates a Doppler image; a compression processing unit (17) that compresses the Doppler image; a wireless communication circuit (18) that wirelessly transmits the compressed Doppler image to the information terminal; and a processing frequency setting unit (19) that sets a processing frequency F2 of the compression processing such that the processing frequency F2 becomes a frequency higher than twice a processing frequency F1 of the Doppler processing, and at least the reception circuit (13), the Doppler processing unit (15), the Doppler image generation unit (16), and the compression processing unit (17) are disposed on the same substrate (24).

Ultrasound beamformer-based channel data compression allows for software-based image formation. To increase the amount of data transferred, ultrasound beamformer-based channel data compression is provided. A beamformer is used to compress instead of or in addition to traditional beamformation. The compression reduces the data bandwidth while allowing reconstruction of the original channel data.

A system for ultrasound beamforming is provided, including a sampled analog beamformer, an array of ultrasound transducers, and a high voltage amplifier coupled to the sampled analog beamformer and the array of ultrasound transducers. The sampled analog beamformer includes a sampled analog filter for filtering an incoming analog signal and adding a fractional delay, and transmitting a filtered analog ultrasound signal. The array of ultrasound transducers further transmits the filtered analog ultrasound signal. The high voltage amplifier drives transducers in the array of ultrasound transducers.

To implement a single-chip ultrasonic imaging solution, on-chip signal processing may be employed in the receive signal path to reduce data bandwidth and a high-speed serial data module may be used to move data for all received channels off-chip as digital data stream. The digitization of received signals on-chip allows advanced digital signal processing to be performed on-chip, and thus permits the full integration of an entire ultrasonic imaging system on a single semiconductor substrate. Various novel waveform generation techniques, transducer configuration and biasing methodologies, etc., are likewise disclosed. HIFU methods may additionally or alternatively be employed as a component of the “ultrasound-on-a-chip” solution disclosed herein.