Abstract: A capacitive micro-machined ultrasonic transducer (CMUT) device in which integrated probe circuitry includes both the ultrasound transmission and reception circuitry and a DC-DC converter for generating a bias voltage for the CMUT cell. The high voltage pulses of a pulser circuit and a high voltage DC bias voltage are both generated by a single probe circuit, which is local to the CMUT cell.

Abstract: A sensor arrangement is for mounting along an elongate device. The sensor arrangement is for positioning along a line sensor arrangements and has terminal blocks at a proximal and distal side, each for connection to one or more wires. A connection circuit controls the coupling of sensor signals to the proximal wires and the coupling of the distal wires to the proximal wires. In this way, a bypass function is implemented through the connection circuit, which avoids the need for physical wires of a distal sensor arrangement to bypass the sensor arrangement itself.

Abstract: 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.

Abstract: The present invention relates to systems and methods that enable high frequency intraluminal imaging, such as IVUS or intra-cardiac echography (ICE), by reducing an amount of circuitry and wiring required to control the functions of one or more transducer array elements of an intraluminal device (e.g. catheter, guidewire, probe, etc.). In particular, aspects of the invention provide for selectively grouping transducers of an array that receive bias voltages from bias voltage circuitry and that are controlled by transmit and receive circuitry (also referred to as pulser/receiver circuitry). The selective grouping of the invention allows the same transmit and receive circuitry to stimulate one or more transducer elements to transmit signals while stimulating one or more other transducer elements to receive signals.

Abstract: An ultrasound system has a set of CMUT ultrasound transducer devices and a drive circuit for operating the ultrasound transducer devices, for delivering an AC drive signal and receiving a reflected signal. An intermediate circuit is between the drive circuit and the set of ultrasound devices in the form of an array of coupling circuits, each coupling circuit between the drive circuit and an associated at least one ultrasound transducer device. Each coupling circuit comprises a buffer element connected between a bias voltage and a device terminal and as series capacitor. The intermediate circuit serves as a connection link between the set of CMUT transducer elements and the driving/sensing electronics, and is formed as a passive integrated technology circuit. The buffer element prevents a low-impedance short between the CMUT cell bias node and the counter electrode in the case of a CMUT cell drum short circuit.

Abstract: A sensor device comprises at least two sensors at the end of a shaft (such as a guidewire or catheter). One sensor uses signals in a first frequency range and a first voltage range and the other sensor uses signals in a second frequency range different to the first frequency range and a second voltage range different to the first voltage range. The first sensor is shorted based on frequency analysis, thereby to prevent the first sensor being exposed to signals associated with the second sensor. This enables the two sensors to be driven by the same shared pair of wires along the shaft, with automatic selection of the suitable sensor.

Abstract: An ultrasound system (1) is disclosed that comprises a probe (10) including an array (110) of CMUT (capacitive micromachined ultrasound transducer) cells (100), each cell comprising a substrate (112) carrying a first electrode (122) of an electrode arrangement, the substrate being spatially separated from a flexible membrane (114) including a second electrode (120) of said electrode arrangement by a gap (118); a voltage supply (45) coupled to said probe and adapted to provide a first set of said CMUT cells with a sequence of drive voltages each including a bias voltage component and a stimulus component of different frequency for generating a series of temporally distinct pulses each having a different frequency, wherein each pulse is generated in a separate transmit mode and provide a second set of said CMUT cells with a sequence of temporally distinct bias voltages, wherein each temporally distinct bias voltage is provided in a receive mode following one of said transmit modes and is for setting the second

Abstract: The present application discloses a bladder monitoring system comprising a wearable bladder monitoring device (1) including securing means (27, 29) for securing the device to a subject's (40) body; a phased array (11) of ultrasound transducers (10); and a phased array controller (13) adapted to control the phased array to direct a plurality of ultrasound beams (30, 30?, 30?) into the subject's body under a range of beam angles, as well as a signal processor (23) adapted to receive data pertaining to echo signals (31, 31?, 31?) of said ultrasound beams from the phased array.

Abstract: An ultrasound system has a set of CMUT transducer devices and drive electronics for operating a selected device of the set. The drive electronics is shared between all devices of the set. Selection is made by using a set of switches (178), with a respective switch between a DC bias output (166) of the drive electronics and an associated input (160) of each device. This provides a simple way to provide a selection function between the drive electronics and multiple ultrasound devices. In this way, the number of devices may be scale up, to cover a larger area, but without scaling the cost of the system by the same degree.

Abstract: An invasive instrument (1) is disclosed comprising an instrument tip including a sensor chip (10) comprising a sensor (20) adapted to produce a modulated sensor signal having a signal frequency and a non-volatile memory (30) responsive to said sensor signal for storing data relating to said sensor; a first supply wire (11) for connecting the sensor chip to ground and a second supply wire (13) for connecting the sensor chip to a power supply (61) for providing a supply voltage to the sensor chip. The device further comprises a circuitry arrangement arranged to combine said sensor signal and said output into a combined signal and superimpose said combined signal as a modulation over the supply voltage such that simultaneous data communication of the sensor and memory data can be provided using two interface wires only. A system including such an invasive instrument and a method of operating such a system are also disclosed.

Abstract: The invention related to an ultrasound system comprising: an ultrasound array including at least one capacitive micromachined ultrasonic transducer device comprising a membrane coupled to a first electrode, a substrate opposing the membrane with a gas or vacuum cavity there between and coupled to a second and a third electrodes, wherein the second electrode opposes the first electrode in a peripheral region and the third electrode opposes the first electrode in a central region; at least one drive circuit coupled to the array. The system further comprises a high impedance resistor, which electrically couples to the second electrode and the third electrode and has an impedance value higher than an AC impedance between the first and the second electrodes, when the membrane of the CMUT device is in the collapsed state and the CMUT devices is activated at operating frequency.

Abstract: An ultrasound transducer assembly is disclosed, comprising: a plurality of ultrasound transducer elements for receiving ultrasound waves and for providing transducer signals corresponding to the respectively received ultrasound waves. The assembly comprises a plurality of signal combiners for providing different output signals on the basis of the transducer signals, and a plurality of timing elements for providing different time shifts to the transducer signals. Each of the ultrasound transducer elements is connected to a plurality of the signal combiners for providing the transducer signals including the different time shifts to different of the signal combiners.

Abstract: Disclosed is an ultrasound probe (10) including an array (110) of CMUT (capacitive micromachined ultrasound transducer) cells (100), each cell comprising a substrate (112) carrying a first electrode (122) of an electrode arrangement, the substrate being spatially separated from a flexible membrane (114) including a second electrode (120) of said electrode arrangement by a gap (118); an acoustic window (140) over the array of CMUT cells; and a data storage element (150) accessible to an external control module of the ultrasound probe. The data storage element stores configuration information for configuring an operation of the array of CMUT cells in pre-collapse or collapse mode with the external control module to optimize the effective bandwidth of the array. Also disclosed is a calibration method of the ultrasound probe, an ultrasound system and a method of operating the ultrasound system.

Abstract: An ultrasound transducer assembly is disclosed, comprising: a plurality of ultrasound transducer elements for receiving ultrasound waves and for providing transducer signals corresponding to the respectively received ultrasound waves. The assembly comprises a plurality of signal combiners for providing different output signals on the basis of the transducer signals, and a plurality of timing elements for providing different time shifts to the transducer signals. Each of the ultrasound transducer elements is connected to a plurality of the signal combiners for providing the transducer signals including the different time shifts to different of the signal combiners.

Abstract: A capacitive micromachined ultrasonic transducer (CMUT) cell comprising three electrodes: a first electrode coupled to a cell membrane; a second electrode embedded into a cell floor opposing the first electrode and separated therefrom by a gas or vacuum cavity; and a third electrode opposing the second electrode on the cavity side, wherein a dielectric layer is sandwiched between the second electrode and the third electrode to create a capacitive relation between the second electrode and the third electrode. The three electrode CMUT cell provides an ultrasound transducer with two actively driven (controlled) electrodes.

Abstract: An ultrasound transducer assembly (30) is disclosed, comprising: a plurality of ultrasound transducer elements (34, 36, 38) for receiving ultrasound waves and for providing transducer signals (X2, X3, X4) corresponding to the respectively received ultrasound waves. The assembly comprises a plurality of signal combiners (42, 44; 60, 62, 64) for providing different output signals (Y1, Y2) on the basis of the transducer signals, and a plurality of timing elements (48, 52; 68, 70; 72, 74) for providing different time shifts (?) to the transducer signals. Each of the ultrasound transducer elements is connected to a plurality of the signal combiners for providing the transducer signals including the different time shifts to different of the signal combiners.

Abstract: Disclosed are an imaging system (10) or an interventional tool, such as a catheter (20), having a first ultrasound transducer array (23) and a second ultrasound transducer array (21) spaced by a fixed distance (D) from each other; wherein both arrays may be used to generate diagnostic images; and a processing arrangement (31, 32) to process a first sensor signal indicative of the first array imaging a reference location (X) at a first point in time, and to process a second sensor signal indicative of the second array imaging the reference location at a second point in time; and determine a translation (pullback) speed of the catheter from the set distance and the difference between the first point in time and the second point in time. Alternatively, a catheter may be provided comprising an ultrasound transducer array at a distal end of the catheter, and two pressure sensors for determining the translation speed.

Abstract: An ultrasound transducer assembly (30) is disclosed, comprising: a plurality of ultrasound transducer elements (34, 36, 38) for receiving ultrasound waves and for providing transducer signals (X2, X3, X4) corresponding to the respectively received ultrasound waves. The assembly comprises a plurality of signal combiners (42, 44; 60, 62, 64) for providing different output signals (Y1, Y2) on the basis of the transducer signals, and a plurality of timing elements (48, 52; 68, 70; 72, 74) for providing different time shifts (?) to the transducer signals. Each of the ultrasound transducer elements is connected to a plurality of the signal combiners for providing the transducer signals including the different time shifts to different of the signal combiners.

Abstract: An ultrasound probe contains an array transducer and a microbeamformer coupled to elements of the array. The microbeamformer comprises analog to digital converters and digital beamforming circuitry for at least thirty-two digital channels in the microbeamformer. Preferably the analog to digital converters are low power ADCs for reduced power consumption in the probe. Integrated circuits of thirty-two channels can be cascaded to produce 64-channel and 128-channel digital microbeamformers for an ultrasound array probe.

Abstract: An ultrasound probe has a two dimensional matrix array transducer and a digital microbeamformer. The microbeamformer comprises a plurality of transmitters and amplifiers coupled to elements of the array transducer, a plurality of low power analog to digital converters and digital beamforming circuitry coupled to the amplifiers, a microbeamformer controller, a power supply and a USB controller which cumulatively consume three watts or less.