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 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: The present invention relates to a minimally invasive medical instrument (100) having a proximal end (100b) and a distal end (100a) and comprising a sensor arrangement (10) arranged at the distal end (100b) of the medical instrument (100). The sensor arrangement (10) comprises a sensor (20) configured to generate sensor data in the form of an electrical sensor signal, and a data conversion device (40) configured to convert the electrical sensor signal into an optical signal and comprising an electrical input (41) for receiving the electrical sensor signal and an optical output (42) for transmitting the optical signal. The sensor arrangement (10) further comprises an optical fiber (50) configured to transmit the optical signal from the distal end (100a) to the proximal end (100b), the optical fiber (50) coupled to the output of the data conversion device (40) for receiving the optical signal, the optical fiber (50) extending from the distal end (100a) to the proximal end (100b) of the instrument (100).

Abstract: The present invention relates to a driver device (40) for driving a load (52) having a plurality of separate capacitive load elements (52), in particular an ultrasound transducer having a plurality of transducer elements (52), comprising: input terminals (44, 46) for connecting the driver device (40) to power supply (48); a plurality of output terminals (50) each for connecting the driver device (40) to one of load elements (52), a first controllable switch (54) connected to a first of the input terminals (44), and a plurality of driving elements (42) each having a second controllable switch (60) and a resistor (58) connected in series to each other, wherein each of the driving elements (42) is connected in series with the first controllable switch (54) and to a second of the input terminals (46), and wherein each of the output terminals (50) is connected to one of the driving elements (42) for powering the load elements (52).

Abstract: The invention relates to a data communication system (100) and a method that can particularly be applied for communicating data from a medical instrument like a catheter or a guide-wire via a high-speedlink (101). The system (100) comprises (in-vivo) a slave component (150) with a controllable slave clock (153) and a transmitter (151) for transmitting a data signal (ds) that is clocked by the slave clock signal (clk). Moreover, it comprises (ex-vivo) a master component (110) with a clock controller (114,115,116) that receives a master clock signal (ref_clk) and the data signal (ds) and that generates a clock control signal (ccs) for adjusting the slave clock (153) to the master clock (113). The slave clock (153) may thus be realized with low space and energy requirements, e.g. by a voltage controlled oscillator (VCO). Moreover, the link (101) via which the data signal (ds) and the clock control signal (ccs) are exchanged may be realized by just two signal wires.

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: The present invention relates to a driver device (40; 60) for driving a capacitive load (12), in particular an ultrasound transducer (12) having one or more transducer elements, comprising an output terminal (42; 68) for providing an alternating drive voltage (V14; V22) to the load (12), a plurality of voltage supply elements (46, 48, 50, 52; 72, 74) for providing intermediate voltage levels (V16), a plurality of controllable connecting means (S0-S7) each associated to one of the voltage supply elements (46, 48, 50, 52; 72, 74) for connecting the voltage supply elements (46, 48, 50, 52; 72, 74) to the output terminal (42; 68) and for supplying one of the intermediate voltage levels (V16) or a sum of a plurality of the intermediate voltage levels (V16) as the alternating drive voltage (V14; V22) to the output terminal.

Abstract: The present invention relates to a minimally invasive medical instrument (100) having a proximal end (100b) and a distal end (100a) and comprising a sensor arrangement (10) arranged at the distal end (100b) of the medical instrument (100). The sensor arrangement (10) comprises a sensor (20) configured to generate sensor data in the form of an electrical sensor signal, and a data conversion device (40) configured to convert the electrical sensor signal into an optical signal and comprising an electrical input (41) for receiving the electrical sensor signal and an optical output (42) for transmitting the optical signal. The sensor arrangement (10) further comprises an optical fiber (50) configured to transmit the optical signal from the distal end (100a) to the proximal end (100b), the optical fiber (50) coupled to the output of the data conversion device (40) for receiving the optical signal, the optical fiber (50) extending from the distal end (100a) to the proximal end (100b) of the instrument (100).

Abstract: The present invention relates to a driver device (40) for driving a load (52) having a plurality of separate capacitive load elements (52), in particular an ultrasound transducer having a plurality of transducer elements (52), comprising: input terminals (44, 46) for connecting the driver device (40) to power supply (48); a plurality of output terminals (50) each for connecting the driver device (40) to one of load elements (52), a first controllable switch (54) connected to a first of the input terminals (44), and a plurality of driving elements (42) each having a second controllable switch (60) and a resistor (58) connected in series to each other, wherein each of the driving elements (42) is connected in series with the first controllable switch (54) and to a second of the input terminals (46), and wherein each of the output terminals (50) is connected to one of the driving elements (42) for powering the load elements (52).

Abstract: The invention relates to a data communication system (100) and a method that can particularly be applied for communicating data from a medical instrument like a catheter or a guide-wire via a high-speedlink (101). The system (100) comprises (in-vivo) a slave component (150) with a controllable slave clock (153) and a transmitter (151) for transmitting a data signal (ds) that is clocked by the slave clock signal (clk). Moreover, it comprises (ex-vivo) a master component (110) with a clock controller (114,115,116) that receives a master clock signal (ref_clk) and the data signal (ds) and that generates a clock control signal (ccs) for adjusting the slave clock (153) to the master clock (113). The slave clock (153) may thus be realized with low space and energy requirements, e.g. by a voltage controlled oscillator (VCO). Moreover, the link (101) via which the data signal (ds) and the clock control signal (ccs) are exchanged may be realized by just two signal wires.

Abstract: The present invention relates to a driver device (40; 60) for driving a capacitive load (12), in particular an ultrasound transducer (12) having one or more transducer elements, comprising an output terminal (42; 68) for providing an alternating drive voltage (V14; V22) to the load (12), a plurality of voltage supply elements (46, 48, 50, 52; 72, 74) for providing intermediate voltage levels (V16), a plurality of controllable connecting means (S0-S7) each associated to one of the voltage supply elements (46, 48, 50, 52; 72, 74) for connecting the voltage supply elements (46, 48, 50, 52; 72, 74) to the output terminal (42; 68) and for supplying one of the intermediate voltage levels (V16) or a sum of a plurality of the intermediate voltage levels (V16) as the alternating drive voltage (V14; V22) to the output terminal.

Abstract: Medical guide wire assembly comprising a guide wire having a proximal end and a distal end, at least one physiology parameter sensor, and that the proximal end of the guide-wire is provided with an elongated connector part, having connection electrodes, for insertion into a connector housing provided with an elongated tubing adapted to achieve electrical and mechanical connection to the elongated connector part, the connector housing is in its turn electrically or wirelessly connectable to a physiology monitor. The guide wire is provided with a core wire running essentially along the entire guide wire. A sensor signal processing circuitry is arranged in connection with the physiological sensor and is adapted to generate a processed sensor signal in response of a sensed parameter. The sensor signal processing circuitry comprises a modulation unit arranged to modulate the processed sensor signal and to generate a modulated sensor signal.

Abstract: Medical guide wire assembly comprising a guide wire having a proximal end and a distal end, at least one physiology parameter sensor, and that the proximal end of the guide-wire is provided with an elongated connector part, having connection electrodes, for insertion into a connector housing provided with an elongated tubing adapted to achieve electrical and mechanical connection to the elongated connector part, the connector housing is in its turn electrically or wirelessly connectable to a physiology monitor. The guide wire is provided with a core wire running essentially along the entire guide wire. A sensor signal processing circuitry is arranged in connection with the physiological sensor and is adapted to generate a processed sensor signal in response of a sensed parameter. The sensor signal processing circuitry comprises a modulation unit arranged to modulate the processed sensor signal and to generate a modulated sensor signal.