Abstract: Base units, systems and methods for wireless energy transfer are described. A wireless energy transfer system according to some examples includes a transmitter of wireless energy located within a communication device, such as a mobile phone, or attached to the communication device and a distance separated receiver located within an electronic wearable device other than the communication device, wherein the receiver is configured to receive wireless energy from the transmitter and convert the wireless energy into electrical power, which may be used to power the electronic wearable device.

Abstract: Camera systems and methods configured to receive power wirelessly are described. A wireless energy transfer system according to some examples includes a transmitter of wireless energy located within a communication device, such as a mobile phone, or attached to the communication device and a distance separated receiver located within an electronic wearable device other than the communication device, such as a wearable camera.

Abstract: Base units, systems and methods for wireless energy transfer are described. A wireless energy transfer system according to some examples includes a transmitter of wireless energy located within a communication device, such as a mobile phone, or attached to the communication device and a distance separated receiver located within an electronic wearable device other than the communication device, wherein the receiver is configured to receive wireless energy from the transmitter and convert the wireless energy into electrical power, which may be used to power the electronic wearable device.

Abstract: Ophthalmic devices with dynamic electro-active elements offer variable optical power and/or depth of field that restore lost accommodation in individuals suffering from presbyopia or aphakia. An illustrative device senses physiological processes indicative of the accommodative response and actuates a dynamic electro-active element to provide the desired change in optical power and/or depth of field. The illustrative device includes two application-specific integrated circuits (ASICs) for processing the accommodative response and actuating the electro-active element: a high-voltage ASIC that steps up a low voltage from a power supply to a higher voltage suitable for actuating the electro-active element, and another ASIC that operates at low voltage (and therefore consumes little power) and controls the operating state of the high-voltage ASIC. Because each ASIC operates at the lowest possible voltage, the illustrative ophthalmic device dissipates less power than other ophthalmic devices.

Abstract: Many modern implantable ophthalmic devices include electronic components, such as electro-active cells, that can leak harmful substances into the eye and/or surrounding tissue. In the implantable ophthalmic devices disclosed herein, electronic components are hermetically sealed within cavities formed by bonding together two or more glass wafers. Bonding the glass wafers together with laser fusion bonding, pressure bonding, or anodic bonding creates a seal that leaks at a rate of less than about 5×10?12 Pa m3s?1 when subjected to a helium leak test. Hermetically sealed feedthroughs formed of conductive material running through channels in the wafers provide electrical connections to components inside the sealed cavities. In some cases, the conductive material has a coefficient of thermal expansion (CTE) that is roughly equal to (e.g., within 10% of) the CTE of the glass wafers to minimize leakage due to thermally induced expansion and contraction of the conductive material and the glass wafer.

Abstract: Many modem implantable ophthalmic devices include electronic components, such as electro-active cells, that can leak harmful substances into the eye and/or surrounding tissue. In the implantable ophthalmic devices disclosed herein, electronic components are hermetically sealed to facilitate mechanically connecting components of an implantable ophthalmic device. Furthermore, the device includes at least one battery with a surface comprising electrical contact portions, a housing for the at least one battery, a first wafer bonded to the housing such that the housing and the first wafer form a hermetically sealed surface around the battery, and an electronic circuit electrically connected to the electrical contact portions of the battery.

Abstract: The invention relates to a device for the stimulation of thermal receptors in the skin of a patient by means of thermal stimuli. The device comprises a plurality of noninvasive stimulation units for irradiating the skin of the patient with electromagnetic radiation, wherein thermal stimuli are produced by absorption of the electromagnetic radiation in the skin of the patient and the wavelength range of the electromagnetic radiation emitted by the stimulation units can be adjusted. The device also comprises a control unit for controlling the stimulation units.

Abstract: Many modern implantable ophthalmic devices include electronic components, such as electro-active cells, that can leak harmful substances into the eye and/or surrounding tissue. In the implantable ophthalmic devices disclosed herein, electronic components are hermetically scaled within cavities formed by bonding together two or more glass wafers. Bonding the glass wafers together with laser fusion bonding, pressure bonding, or anodic bonding creates a seal that leaks at a rate of less than about 5×10?12 Pa m3 s?1 when subjected to a helium leak test. Hermetically sealed feedthroughs formed of conductive material running through channels in the wafers provide electrical connections to components inside the sealed cavities. In some cases, the conductive material has a coefficient of thermal expansion (CTE) that is roughly equal to (e.g., within 10% of) the CTE of the glass wafers to minimize leakage due to thermally induced expansion and contraction of the conductive material and the glass wafer.

Abstract: Systems and methods of the disclosure relate to managing power consumption of an implantable device, such as an implantable ophthalmic device, that includes one or more rechargeable batteries and a processor operably coupled to the rechargeable batteries. The processor can be configured to implement a quick-charge process that includes charging each rechargeable battery for a first time interval using a first constant current, for a second time interval using a second constant current less than the first constant current, and for a third time interval using a constant voltage. This quick charge process is faster than conventional charging. The processor also manages discharge of two batteries in an alternating fashion so as to increase time between charging cycles, reduce the total number of charging cycles, and extend battery life.

Abstract: The present disclosure relates to an accommodating device for a dispensing or infusion device, comprising: a displaceable element which is displaced within the accommodating device when a cartridge is inserted into the accommodating device; and at least one sensor which can detect the presence or absence of the displaceable element or a detection element disposed on or in the displaceable element.

Abstract: The invention relates to method for bonding at least two substrates, for example made from glass, silicon, ceramic, aluminum, or boron, by using an intermediate thin film metal layer for providing the bonding, said method comprising the following steps of: a) providing said two substrates; b) depositing said thin film metal layer on at least a part of a surface of a first substrate of the two substrates; c) bringing a surface of the second substrate into contact with said thin film metal layer on said surface of the first substrate such that a bonding between the second substrate and the thin film metal layer on the first substrate is provided; and d) at least locally strengthening the bonding between the second substrate and the thin film metal layer on the first substrate. The invention also relates to a device comprising two substrates, for example made from glass, silicon, ceramic, aluminum, or boron, and an intermediate thin film metal layer.

Abstract: A medical infusion system with pulse width modulation and a safety circuit and a method thereof are disclosed. Embodiments of the system include a switching device and a pump motor, wherein the pump motor and the switching device are connected in series and constitute a power supply circuit to be connected to a power supply. Embodiments of the system further includes a control signal generator configured to generate a control signal e.g. PWM, and which is connected to input of the safety circuit. Output of the safety circuit is connected to a control input of the switching device such that the pump motor will not operate if there is no control signal applied to the input of the safety circuit.

Abstract: A contact lens shaped measuring device (1) comprises sensor (3) having a protrusion (14) towards the cornea (22). The measuring device (1) is flexible to a degree that it is flattened by a closing eye lid and the protrusion creates an indentation of the cornea. The occurring force on the protrusion is measured by the sensor. Applying a constant lid acceleration/deceleration model to the movement of the lid and a mechanical model to the cornea, the tension of the cornea is determined and deduced from the force measured with the lid closed, yielding the true intraocular pressure. In an alternative, the protrusion is characterized by a discontinuity in its shape, or the sensor is subdivided, each subsensor being characterized by a protrusion of different shape. With the values obtained as extrema and at the discontinuity or with different protrusions, the cornea tension can be obtained by a (linear) extrapolation.

Abstract: Ophthalmic devices with dynamic electro-active elements offer variable optical power and/or depth of field that restore lost accommodation in individuals suffering from presbyopia or aphakia. An illustrative device senses physiological processes indicative of the accommodative response and actuates a dynamic electro-active element to provide the desired change in optical power and/or depth of field. The illustrative device includes two application-specific integrated circuits (ASICs) for processing the accommodative response and actuating the electro-active element: a high-voltage ASIC that steps up a low voltage from a power supply to a higher voltage suitable for actuating the electro-active element, and another ASIC that operates at low voltage (and therefore consumes little power) and controls the operating state of the high-voltage ASIC. Because each ASIC operates at the lowest possible voltage, the illustrative ophthalmic device dissipates less power than other ophthalmic devices.

Abstract: An electronic device (12) for processing information that includes data and clock information and that is wirelessly received from another electronic device (14) may include a first processor (18) that controls only wireless communications with the another electronic device (14) and excluding operations associated only with the electronic device (12), a second processor (16) that controls the operations associated only with the electronic device (12) and excluding the wireless communications with the another device (14), and means (30-30??) for extracting the clock information and the data from the wirelessly received information and providing a corresponding clock signal and the data to the second processor (16) for synchronous receipt of the data by the second processor (16) using the clock signal.

Abstract: A battery cell casing comprises a first casing element (1) with a first contact surface (7) and a second casing element (2) with a second contact surface (8). In an assembled position the first and second contact surfaces (7, 8) contact each other and the first and second casing elements (1, 2) encase active materials (9, 10) of a battery cell in an interior space. At least one seal layer is arranged between the first and second contact surfaces (7, 8) to seal the interior space, wherein one of first and second contact surface (7; 8) comprises a void volume layer and the other of first and second contact surface (7; 8) comprises a formable material layer, which fills voids on a surface of the void volume layer hermetically in the assembled position and forms the seal layer.

Abstract: An electronic device may communicate wirelessly with another electronic device. The electronic device may include a first processor configured to control only wireless communications with the another device but not operations associated only with the electronic device, a second processor configured to control the operations associated only with the electronic device but not the wireless communications with the another device, and a memory device connected between the first and second processors. The first and second processors may each be configured to exchange information with the memory device separately and independently of the exchange of information by the other of the first and second processors with the memory device.

Abstract: Devices and methods are disclosed which automatically reconstitute a drug, such as e.g., a lyophilized drug. A vial (30) containing the drug is fluidly coupled to a cartridge (12) containing a reconstitution liquid with a fluid conduit (14f), wherein an entry point is defined where the fluid conduit enters the vial (30). The device (10) automatically adjusts orientation of the vial (30) such that the entry point of the vial is gravitationally higher than the drug in the vial (30), and automatically transfers the reconstitution liquid out of the cartridge (12) and into the vial (30) to create a reconstituted drug. The device (10) also automatically adjusts the orientation of the vial (30) such that the entry point of the vial is gravitationally lower than the reconstituted drug, and automatically transfers the reconstituted drug from the vial (30) and into the cartridge (12).

Abstract: A sensor system includes at least two sensors for distinguishing accommodative stimuli from changes in ambient lights levels and task-induced changes in the pupil diameter. When implanted, the first sensor is disposed completely within the pupil; even when fully constricted, the pupil does not occlude the first sensor, allowing the sensor to make precise measurements of ambient luminous flux levels. The pupil occludes part of the second sensor's active area(s) as the pupil dilates and constricts. As a result, the second sensor measures both ambient luminous flux and pupil diameter. A processor estimates the pupil diameter and determines whether it's changing in response to accommodative stimuli or other factors by comparing to predetermined values. The sensor system sends a signal to an optical component, which in turn can respond by changing optical power to focus for near vision upon detection of accommodative stimuli.

Abstract: Many modem implantable ophthalmic devices include electronic components, such as electro-active cells, that can leak harmful substances into the eye and/or surrounding tissue. In the implantable ophthalmic devices disclosed herein, electronic components are hermetically sealed to facilitate mechanically connecting components of an implantable ophthalmic device. Furthermore, the device includes at least one battery with a surface comprising electrical contact portions, a housing for the at least one battery, a first wafer bonded to the housing such that the housing and the first wafer form a hermetically sealed surface around the battery, and an electronic circuit electrically connected to the electrical contact portions of the battery.