Abstract: An additive printing method depositing a functional print pattern on a surface of a 3D object, an associated computer program, and a computer-readable medium storing the program. The method comprises as steps (i) providing the object on a planar surface; (ii) providing a print head having print nozzles defining a plane non-parallel to the planar surface; (iii) generating 3D geometrical surface data of an exposed surface of the object on the planar surface; (iv) generating 2D geometrical surface data of the exposed surface on the basis of the 3D geometrical surface data; (v) determining an amount of printing fluid to be discharged at a discharge time from each of the print nozzles; (vi) generating a relative movement between the object and the print head; and (vii) printing a print pattern on at least one portion of the exposed surface during the relative movement. A step of correcting data is included.

Abstract: An electronic module having at least two electronic components mounted on a substrate. The electronic components are covered by a dielectric material. The dielectric material has a recess between adjacent electronic components. The surface of the recess facing at least one electronic component is coated with a conductive layer while the opposite surface to that coated recess surface is substantially free of a conductive layer. Also disclosed is a process for making the above-specified electronic module.

Abstract: The present invention relates to an assembly to be used in an inkjet printer, an inkjet printer and a method for printing. The assembly comprises (i) a first fixture configured to hold a first print head; and (ii) at least two processing lines A, B, C, D, wherein each processing line A, B, C, D includes a first printing section in which a functional layer is printed on a surface of an electronic device, a sintering section spaced apart from the first printing section and configured to sinter the functional layer, wherein the sintered functional layer exhibits a crystal lattice structure, and a transport mechanism (4) configured to move from the printing section to the sintering section. The first fixture is movable from one processing line A, B, C, D to another processing line A, B, C, D.

Abstract: An additive printing method depositing a functional print pattern on a surface of a 3D object, an associated computer program, and a computer-readable medium storing the program. The method comprises as steps (i) providing the object on a planar surface; (ii) providing a print head having print nozzles defining a plane non-parallel to the planar surface; (iii) generating 3D geometrical surface data of an exposed surface of the object on the planar surface; (iv) generating 2D geometrical surface data of the exposed surface on the basis of the 3D geometrical surface data; (v) determining an amount of printing fluid to be discharged at a discharge time from each of the print nozzles; (vi) generating a relative movement between the object and the print head; and (vii) printing a print pattern on at least one portion of the exposed surface during the relative movement. A step of correcting data is included.

Abstract: Technology for near infrared (NIR) based communication and/or sensing of implantable medical devices and systems as well as method of operating the same.

Abstract: A method for waking up an implantable medical device from a dormant state, an implantable medical device, and a system that includes such an implantable medical device and an external device. The implantable medical device is woken up from a dormant state by sending a modulated wakeup signal via a wireless link from an external device. The modulated wakeup signal is demodulated by way of a demodulator circuitry of the implantable medical device so as to produce a demodulated wakeup signal. The demodulator circuitry is permanently ready for operation. An awake state of the implantable medical device is then activated in response to the demodulated wakeup signal.

Abstract: An electronic module having at least two electronic components mounted on a substrate. The electronic components are covered by a dielectric material. The dielectric material has a recess between adjacent electronic components. The surface of the recess facing at least one electronic component is coated with a conductive layer while the opposite surface to that coated recess surface is substantially free of a conductive layer. Also disclosed is a process for making the above-specified electronic module.

Abstract: Technology for near infrared (NIR) based communication and/or sensing of implantable medical devices and systems as well as method of operating the same.

Abstract: A method for waking up an implantable medical device from a dormant state, an implantable medical device, and a system that includes such an implantable medical device and an external device. The implantable medical device is woken up from a dormant state by sending a modulated wakeup signal via a wireless link from an external device. The modulated wakeup signal is demodulated by way of a demodulator circuitry of the implantable medical device so as to produce a demodulated wakeup signal. The demodulator circuitry is permanently ready for operation. An awake state of the implantable medical device is then activated in response to the demodulated wakeup signal.

Abstract: A lead has at least a first and a second conductor. The first conductor and the second conductor each have an electrically conducting core that is surrounded by an electrical insulator. The electrical insulator of the first conductor if formed from a first material, and the electrical insulator of the second conductor is formed from a second material. The first material differs from the second material.

Abstract: The invention relates to methods by which radio signals can be transmitted to, and received by, a radio receiver such that the receiver consumes very little power from a battery or energy source. The invention also relates to methods by which radio signals, modulated with data information, can be produced by a transmitter that consumes very little power. The invention is applicable not only to medical implants, but any application requiring a radio receiver to operate with very low power consumption.

Abstract: The invention relates to methods by which radio signals can be transmitted to, and received by, a radio receiver such that the receiver consumes very little power from a battery or energy source. The invention is applicable not only to medical implants, but any application requiring a radio receiver to operate with very low power consumption.

Abstract: The invention relates to a patient's device having an at least unidirectional, wireless interface for receiving a data signal. The wireless interface is adapted to receive medical or operational data from a medical device, in particular an implantable medical device like a cardiac pacemaker or a cardioverter/defibrillator, a data communication interface for accessing a wide area network or a public telecommunication network or both. The device comprises an automatic routing/dialling module connected to the data communication interface, adapted to establish an automatic access to a modem connected to the data communication interface by automatically selecting one of a plurality of possible connection parameters. The connection parameters are selected from at least one of an individual modem, if more than one modem is connected to the data communication interface, and a prefix number for a remote access to a remote device over a public network automatically selecting a dial-up telephone number.

Abstract: The invention relates to methods by which radio signals can be transmitted to, and received by, a radio receiver such that the receiver consumes very little power from a battery or energy source. The invention is applicable not only to medical implants, but any application requiring a radio receiver to operate with very low power consumption.

Abstract: The invention relates to methods by which radio signals can be transmitted to, and received by, a radio receiver such that the receiver consumes very little power from a battery or energy source. The invention also relates to methods by which radio signals, modulated with data information, can be produced by a transmitter that consumes very little power. The invention is applicable not only to medical implants, but any application requiring a radio receiver to operate with very low power consumption.

Abstract: The invention relates to a patient's device having an at least unidirectional, wireless interface for receiving a data signal. The wireless interface is adapted to receive medical or operational data from a medical device, in particular an implantable medical device like a cardiac pacemaker or a cardioverter/defibrillator, a data communication interface for accessing a wide area network or a public telecommunication network or both. The device comprises an automatic routing/dialling module connected to the data communication interface, adapted to establish an automatic access to a modem connected to the data communication interface by automatically selecting one of a plurality of possible connection parameters. The connection parameters are selected from at least one of an individual modem, if more than one modem is connected to the data communication interface, and a prefix number for a remote access to a remote device over a public network automatically selecting a dial-up telephone number.