An operation method of an ultrasound diagnostic apparatus includes executing one or more imaging series of steps with an ultrasound transducer; and applying a polarization processing to the ultrasound transducer one or more of before, after, and interleaved between the one or more imaging series of steps, where the polarization processing is separate from the one or more imaging series of steps.

An ultrasound probe includes a probe housing, a heat generating electronic component disposed within the housing, and a heat exchanger disposed within the housing and thermally coupled with the heat generating electronic component, wherein the heat exchanger is a monolithic structure without seams. The heat exchanger includes a flow path defined by a plurality of baffles, a fluid inlet connected to one end of the flow path, a fluid outlet connected to the opposite end of the flow path, and one or more turbulating elements disposed within the flow path, the flow path configured for passing a cooling fluid therethrough. The heat exchanger is additively manufactured of a suitable material, such as to form part of a probe central support member.

Systems and methods are provided for thermally conductive shock absorbers for medical imaging probes. An example medical imaging probe may have, at least, a transducer disposed underneath a contact surface of the medical imaging probe, with the transducer configured to transmit and receive signals based on a medical imaging technique; a support structure disposed underneath the transducer; and a thermally conductive shock absorber (TCSA) layer disposed between the transducer and the support structure, with the thermally conductive shock absorber (TCSA) layer is configured to facilitate both of thermal transfer in a direction from the contact surface into the support structure, and absorbing at least a portion of impact force applied to at least the contact surface. The support structure may include a heat sink.

An ultrasound imaging device or an ultrasound imaging probe includes an imaging device including at least one heat generating component and at least one thermal energy storage insert spaced from and disposed in thermal contact with the imaging device, the at least one thermal energy storage insert containing a phase change material (PCM) therein. The thermal energy storage insert is manufactured to closely confirm to a shape of a space defined within the interior of the probe. A method of forming the ultrasound imaging probe includes the steps of manufacturing a thermal energy storage insert from a thermally conductive material, filling the thermal energy storage insert with a phase change material (PCM) and positioning the thermal energy storage insert within an interior of the probe.

An imaging device includes a two dimensional array of piezoelectric elements. Each piezoelectric element includes: a piezoelectric layer; a bottom electrode disposed on a bottom side of the piezoelectric layer and configured to receive a transmit signal during a transmit mode and develop an electrical charge during a receive mode; and a first top electrode disposed on a top side of the piezoelectric layer; and a first conductor, wherein the first top electrodes of a portion of the piezoelectric elements in a first column of the two dimensional array are electrically coupled to the first conductor.

An ultrasound imaging system comprises an ultrasound imaging apparatus operable to acquire ultrasound image data and comprising a power accepting interface; and a dual function charging and cooling unit configured to detachably couple to the ultrasound imaging apparatus; wherein the dual function charging and cooling unit comprises i) a power conveying element to convey power to the ultrasound imaging apparatus and ii) an active cooling element for removing heat from the ultrasound imaging apparatus.

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.

A hand-held ultrasound system includes integrated electronics within an ergonomic housing. The electronics includes control circuitry, beamforming and circuitry transducer drive circuitry. The electronics communicate with a host computer using an industry standard high speed serial bus. The ultrasonic imaging system is operable on a standard, commercially available, user computing device without specific hardware modifications, and is adapted to interface with an external application without modification to the ultrasonic imaging system to allow a user to gather ultrasonic data on a standard user computing device such as a PC, and employ the data so gathered via an independent external application without requiring a custom system, expensive hardware modifications, or system rebuilds. An integrated interface program allows such ultrasonic data to be invoked by a variety of such external applications having access to the integrated interface program via a standard, predetermined platform such as visual basic or c++.

Systems and methods of transmitting heat away from an ultrasound probe are disclosed within. In one embodiment, a handheld ultrasound probe includes a transducer, electronics configured to drive the transducer, and a housing surrounding the transducer assembly and the electronics. A slot extending from a first side of the housing to a second side of the housing and can allow air to pass adjacent transducer and the electronics. The slot can be sized to inhibit accessibility of an operator's finger to an inner surface of slot.

An ultrasound probe including an active thermal management system is disclosed. The active thermal management system may include a fluid chamber coupled to a transducer assembly of the ultrasound probe. The fluid chamber may include a coolant that may dissipate heat from the transducer assembly. The active thermal management system may further include a heat sink coupled to the fluid chamber and thermal management system. The heat sink may include fins that extend into the coolant. The coolant may be a liquid or a gas. The coolant may be circulated within the fluid chamber by a circulation device. The circulation device may be a pump, a fan, or an impeller. An ultrasound probe may further include a window that forms an enclosure over the lens of the transducer assembly. The enclosure may be fluidly coupled to the fluid chamber and filled with coolant to dissipate heat from the lens.