In a method for operating a fingerprint sensor including a plurality of ultrasonic transducers and a presence sensor, the presence sensor proximate the fingerprint sensor is activated, where the presence sensor is for detecting interaction between an object and the fingerprint sensor. Subsequent to detecting interaction between an object and the fingerprint sensor at the presence sensor, a subset of ultrasonic transducers of the fingerprint sensor is activated, the subset of ultrasonic transducers for determining whether the object is a human finger, where the subset of ultrasonic transducers is proximate the presence sensor such that the subset of ultrasonic transducers and the presence sensor can concurrently interact with the object.

A dynamic power reduction method and apparatus for use in an ultrasound system are described. In one embodiment, the ultrasound system comprises: a transducer assembly and imaging subsystem having a transmit data path having a transmitter to transmit acoustic signals and a receive data path having including signal acquisition circuitry with a receiver to receive acoustic signals representing echoes; a plurality of real-time signals indicative of status of imaging operations being performed by the transmit and receive paths; a clock generator to generate one or more clocks for use by the transmit and receive data paths; clock gating circuitry coupled to the clock generator and the transmit and receive paths and having circuits to gate clocks to at least one of the transmit and receive paths; and a clock gating controller coupled to the clock gating circuitry to control the circuits to gate or pass clock signals to at least one of the transmit and receive paths automatically in response to receipt of one or more signals from the plurality of real-time signals.

In one embodiment, an ultrasonic diagnostic apparatus includes a plurality of transmission-wave generation circuits configured to supply a plurality of transducers of an ultrasonic probe with a plurality of transmission waves for driving the plurality of transducers via a plurality of channels; and a transmission control circuit configured to independently and dynamically control each of the plurality of transmission-wave generation circuits at a timing different for each channel.

An ultrasound imaging system includes a processor that is programmed to operate the system in a normal operating state and two or more lesser power states. The processor lowers the operating power state to a lesser power state upon detecting one or more operating conditions such as no tissue been imaged in a predetermined time limit or that the imaging system or transducer has not been moved in a time limit. Upon awakening from a power off state, the processor implements a lesser power state before operating at the normal operating state to avoid undue power use until the transducer is positioned to image tissue.

Disclosed is a method for operating an ultrasound probe which is wirelessly connected to an ultrasound image providing apparatus via a communication channel. The method includes acquiring bandwidth information that relates to the communication channel, determining at least one from among at least one parameter value associated with a quality of an ultrasound image and a transmission speed of a frame that constitutes the ultrasound image, based on the bandwidth information, generating ultrasound image data that relates to an object, based on the at least one parameter value, and transmitting the ultrasound image data to the ultrasound image providing apparatus. The ultrasound image data is used to display the ultrasound image by using the ultrasound image providing apparatus.

Circuitry for ultrasound devices is described. A multi-level pulser is described, which can support time-domain and spatial apodization. The multi-level pulser may be controlled through a software-defined waveform generator. In response to the execution of a computer code, the waveform generator may access master segments from a memory, and generate a stream of packets directed to pulsing circuits. The stream of packets may be serialized. A plurality of decoding circuits may modulate the streams of packets to obtain spatial apodization.

A system and method from improving the image quality achievable with an ultrasound transducer by using a composite aperture for receiving ultrasound echoes. By using two receive cycles per vector, twice as many transducers may be used for receiving ultrasound imaging data than there are physical channels available in the ultrasound probe. An ultrasound probe utilizing a composite aperture can achieve high image quality from a system have reduced power, size, cost and complexity.

An ultrasound probe in which there is local amplification, time gain compensation and digitization of each transducer element output. Inverting arrangements surround the time gain compensation and digitization units, and a synchronous inversion function enables deterministic distortion to be cancelled.

In an embodiment, a medical device is disclosed. The medical (imaging) device comprises a housing configured for handheld use, a transducer array, a display coupled to the housing, a plurality of sensors distributed about a periphery of the housing and configured to detect when a hand of an operator is positioned around the housing, and a computing device disposed within the housing, wherein the computing device is in communication with the transducer array, the display, and the sensors. The computing device is operable to: monitor the sensors, determine whether a reading from a first sensor at a first edge of the periphery of the housing exceeds a threshold, set the first edge as a primary edge based at least in part on the reading from the first sensor, and orient the display such that the primary edge is at the bottom of the display.

The present invention relates to an ultrasonic diagnosis apparatus and a power supply device. The ultrasonic diagnosis apparatus comprises: an ultrasonic host including a pluggable main battery pack; a backup power supply device including a plurality of pluggable backup battery packs, for powering the ultrasonic host; and a trolley for carrying the ultrasonic host and the backup power supply device; wherein a specification of each of the plurality of backup battery packs is identical to that of the main battery pack.