An ultrasonic diagnostic apparatus includes a probe configured to transmit ultrasonic waves to a living body and receive ultrasonic waves reflected by the living body; and a processor configured to, in a moving image mode, cause ultrasonic image data based on ultrasonic waves received by a first subset of the total number of oscillators that the probe has to be output, and, in a static image mode, cause ultrasonic image data based on ultrasonic waves received by a second subset of the total number of oscillators that the probe has to be output, wherein the number of oscillators used in the second subset is greater than the number of oscillators used in the first subset.

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.

The high voltage drive for the transducer of an ultrasonic transducer probe is provided by an active supply that monitors the high voltage supplied to the transducer by means of feedback, and responds to a decline in voltage during high voltage transmission by coupling charge from a capacitor to the high voltage supply line of the probe, thereby preventing a precipitous decline in the high voltage. Preferably the active supply and the capacitor are located in the probe connector enclosure.

The present application provides a power control method, applied in a distance measuring module comprising a light emitting unit. The power control method comprises steps of the light emitting unit emitting an incident light by a first emitting power in a first time; receiving a reflected light corresponding to the incident light; determining a distance between the distance measuring module and a target according to the reflected light; and adjusting an emitting power of the light emitting unit according to the distance.

Systems and methods can facilitate wide broad-band IVUS for peripheral vascular applications with simultaneous improved resolution and penetration depth. A custom analog front end interface can withstand large voltages and recover to receive a sub-mV pulse from less than one mm away. The custom analog front end interface can be on an interface chip that can be sized to be integrated within a tip of the IVUS catheter to connect micro-cables within the IVUS catheter to the broad-band transducer. The interface chip can also include a dual-stage amplifier having a pulse mode configured to withstand voltage pulses greater than 30 V.sub.PP during pulsing and an echo reception mode configured to receive sub-mV echoes during echo reception.

In the present invention, an FE device and a BE device communicate using two wireless communication routes in a separate state. Approaching of each device is determined in both devices immediately prior to a docking state by monitoring of a wireless communication state. Wireless communication between the two devices is then stopped, and both devices enter a freeze state (operation-limited state). When the docking state is then formed, wired communication is established between both devices. Then, when an unfreeze input occurs, both devices return to a normal operation state. Both devices temporarily enter the freeze state also when a state change from the docking state to the separate state occurs.

Provided is a wireless probe including: an ultrasound reception/transmission module that receives a first power and scans a target object by transmitting ultrasound signals to the target object and receiving ultrasound echo signals reflected from the target object; a signal processing module that receives a second power, generates pulses for generating the ultrasound signals and generates ultrasound data by using the ultrasound echo signals; a wireless communication module that receives a third power and receives/transmits predetermined data from/to a medical device; a controller that controls supply of at least one of the first power, the second power, and the third power based on an operation state of the wireless probe; and a power unit that supplies or blocks the at least one of the first power, the second power, and the third power according to control of the controller. Each component included in the wireless probe may reduce power consumed by the wireless probe.

An ultrasound apparatus comprising a plurality of ultrasonic transducers, a non-acoustic sensor, a memory circuitry to store control data for operating the ultrasound apparatus to perform an acquisition task, and a controller. The controller is configured to receive an indication to perform the acquisition task, receive non-acoustic data obtained by the non-acoustic sensor, and control, based on the control data and the non-acoustic data, the plurality of ultrasonic transducers to obtain acoustic data for the acquisition task.

An ultrasound apparatus comprising a plurality of ultrasonic transducers, a non-acoustic sensor, a memory circuitry to store control data for operating the ultrasound apparatus to perform an acquisition task, and a controller. The controller is configured to receive an indication to perform the acquisition task, receive non-acoustic data obtained by the non-acoustic sensor, and control, based on the control data and the non-acoustic data, the plurality of ultrasonic transducers to obtain acoustic data for the acquisition task.

An ultrasonic imaging device includes an ultrasonic generating unit and an ultrasonic imaging processing unit. The ultrasonic generating unit repeatedly turns on N of M ultrasonic array elements of the ultrasonic probe multiple times as a group of array elements for linear scanning, and each scan is to emit an ultrasonic signal by each group of array elements and receive an echo signal of the ultrasonic signal. The ultrasonic imaging processing unit extracts a central echo signal from the echo signal in each scan to form a channel signal, and according to the arrival time of the echo signals, each central echo signal in the channel signal is delayed and summed to generate a modified channel signal. The modified channel signal is subjected to image synthesis process to obtain an ultrasonic image.