A silicon photonics integrated beam steering device includes a light source operably coupled to a light dispenser, a chained optical switch array including a first optical switch having a first control circuit and a second optical switch having a second control circuit, and a pixel array having a first pixel and a second pixel, wherein the light dispenser is operably coupled to first optical switch, the first optical switch is operably coupled to both the second optical switch and the first pixel, and the second optical switch is operably coupled to the second pixel, and wherein the device is configured to selectively transmit light along a plurality of optical paths to the first pixel, the second pixel, or both the first pixel and the second pixel in response to a first control voltage applied to the first control circuit and a second control voltage applied to the second control circuit.

A system is described for multi-frequency ultrasonically-encoded optical tomography of target tissue. A light source generates light input signals to the target tissue. An ultrasound transducer array has ultrasound transducers each generating a different time-dependent waveform to form a plurality of ultrasound input signals to an imaging volume within the target tissue. An optical sensor senses scattered light signals from the imaging volume, wherein the scattered light signals include light input signals modulated by acousto-optic interactions with the ultrasound input signals. Spectral analysis of the scattered light signals is performed to create a three-dimensional image map representing biomarker characteristics of the target tissue.

A system is described for multi-frequency ultrasonically-encoded tomography of a target object. One or more probe inputs generate probe input signals to the target object. An ultrasound transducer array is placed on the outer surface of the target object and has multiple ultrasound transducers each generating a different time-dependent waveform to form a plurality of ultrasound input signals to a target probe volume within the target object. One or more sensors sense tomography output signals from the target probe volume, wherein the tomography output signals contain an interaction component generated by interaction of the probe input signals with the ultrasound input signals. A tomography analysis of the tomography output signals is performed to create a three-dimensional object map representing structural and/or functional characteristics of the target object.

A system and corresponding method are described for multi-frequency ultrasonically-encoded tomography of a target object. One or more probe inputs generate probe input signals to the target object. An ultrasound transducer array is placed on the outer surface of the target object and has multiple ultrasound transducers each generating a different time-dependent waveform to form a plurality of ultrasound input signals to a target probe volume within the target object. A photorefractive crystal mixes scattered light output signals from the target probe volume with an optical reference beam input to produce optical tomography output signals including ultrasound sum frequencies components. A photodetector senses the optical tomography output signals from the photorefractive crystal. A tomography analysis of the tomography output signals including the ultrasound sum frequencies components is performed to create a three-dimensional object map representing structural and/or functional characteristics of the target object.

A system and corresponding method are described for multi-frequency ultrasonically-encoded tomography of a target object. One or more probe inputs generate probe input signals to the target object. An ultrasound transducer array is placed on the outer surface of the target object and has multiple ultrasound transducers each operating at a different ultrasound frequency to generate ultrasound input signals to a target probe volume within the target object. A photorefractive crystal mixes scattered light output signals from the target probe volume with an optical reference beam input to produce optical tomography output signals including ultrasound sum frequencies components. A photodetector senses the optical tomography output signals from the photorefractive crystal. A tomography analysis of the tomography output signals including the ultrasound sum frequencies components is performed to create a three-dimensional object map representing structural and/or functional characteristics of the target object.

An object information acquiring apparatus comprising: a processor generating image data representing characteristic information on an object, based on signals acquired by receiving an acoustic wave generated from an object by a plural light irradiations; and a display controller allowing a display to display an image, wherein the display controller performs first display in which an image is displayed in parallel with irradiation and second display in which an image is displayed based on more signal than in the first display, and the processor acquires the characteristic information for a smaller number of units of reconstruction when generating image data.

Ultrasound image devices, systems, and methods are provided. An ultrasound imaging system, comprising an array of acoustic elements configured to transmit ultrasound energy into an anatomy in accordance with a first preset acquisition setting, and to receive ultrasound echoes associated with the anatomy; and a processor circuit in communication with the array of acoustic elements and configured to receive, from the array, ultrasound channel data corresponding to the received ultrasound echoes; generate a first set of beamformed data by applying a predictive network to the ultrasound channel data, wherein the first set of beamformed data is associated with a second preset acquisition setting different than the first preset acquisition setting; generate an image of the anatomy from the first set of beamformed data; and output, to a display in communication with the processor circuit, the image of the anatomy.

A transponder is used for tracking a position of a distal end of a medical device in an ultrasound image and/or enhancing an ultrasound image.

Mixed sensor array devices are provided herein. Mixed sensor arrays as described herein include acoustic energy generating elements and optical fiber based acoustic sensors. Optical fiber based sensors may optical structures responsive to physical parameters including acoustic signals, pressure, and temperature, and are configured to detect and receive acoustic signals and other physical parameters and provide associated optical signals to a system for processing and interpretation to implement tracking, location, imaging, and other sensing capabilities. Optical fiber based sensors provided herein may be disposed at ends of or along the length of optic fibers. Optical fiber based sensors may be included within various devices, including, for example, medical devices.

Techniques are described herein that are capable of providing a modularized acoustic probe that includes multiple acoustic transducers that have discrete substrates. A first acoustic transducer is configured to generate an acoustic signal and to transmit the acoustic signal toward an object. The second acoustic transducer is configured to detect a reflected acoustic signal, which results from the acoustic signal reflecting from the object, and to convert the reflected acoustic signal to an electrical signal. The first and second acoustic transducers have respective discrete substrates. In an example, the second acoustic transducer may not be configured to generate acoustic signals. In another example, the first and second acoustic transducers may be in respective first and second rows of a two-row transducer array. In accordance with this example, the first and second acoustic transducers may be designed to have an acoustic parameter having respective first and second parameter values.