Abstract: This invention relates to a lighting system (100) which provides front side lighting, where a main portion of the light is outputted in the front direction of the lighting system, and back side lighting, where a sub portion of the light is outputted in a back side direction of the lighting system. The lighting system is arranged such that light from a light unit (103) is mixed in a mixing chamber (105). The mixing chamber has a first light exit portion (106) which is arranged for outputting a main portion of the mixed light for front side lighting. The mixing chamber is further arranged with a second light exit portion (101) arranged in association with the mixing chamber for outputting a sub portion of the mixed light for back side lighting from the lighting system. The invention is based on an insight that by utilizing the mixing chamber in the lighting system, back side lighting is achieved and thereby hardly affecting the beam shape of the front side lighting from the lighting system.

Abstract: The invention concerns a system for monitoring and controlling a patient (1), with a patient sensor (2) for capturing a patient signal, and a user interface (6) for providing a user with information on the captured patient signal, wherein the system comprises an integrated closed loop controller (4) which is fed with the patient signal and which controls a patient treating device (5) for treating the patient (1). Thus, an easy and efficient way of monitoring and controlling a patient is provided.

Abstract: The invention relates to an OLED device with a stack comprising: a light emitting organic layer (2), a cathode layer (1), and a transparent anode layer (3), the organic layer (2) being arranged between the cathode layer (1) and the anode layer (3), wherein a macro extractor layer (5) is arranged on top of a transparent substrate (4), wherein the macro extractor in optical contact with the transparent substrate (4), and wherein the macro extractor (5) layer comprises a plurality of mirror surfaces which extend from the bottom to the top of the macro extractor layer (5), preferably embedded in a matrix which has a refractive index matching the one of the transparent substrate. Preferably, the macro extractor layer comprises a crash glass device with a pre-stressed crash glass pane (6) having air-filled cracks (9). Since these cracks (9) act as mirrors for the light emitted by the organic layer (2), trapping of light is avoided and, thus, light extraction from the device is enhanced.

Abstract: This invention relates to an activity monitoring system adapted to eliminate passive movement components caused by external forces from readout data produced by a first and a second motion sensor when attached to a subject during movement. The readout data include gravitational components, movement components caused by active movement of the subject or subject parts, and the passive movement components. A processor estimates first and second gravitational components produced by the at least first and a second motion sensors. It determines a rotation matrix based on the estimated gravitational components, the rotation matrix denoting rotation required for the first sensor to get aligned with the second sensor in orientation. It then multiplies the readout data produced by the first motion sensor with the rotation matrix when rotating the first sensor towards the second sensor.

Abstract: A luminaire having a plurality of LED boards mounted within a housing is provided. Each LED board has at least one light emitting diode mounted thereon and an axis extending from a first end of the board to a second end of the board. Each LED board is adjusted about its respective axis to an orientation that is unique from at least two other LED boards.

Abstract: A semiconductor structure comprises a light emitting layer disposed between an n-type region and a p-type region. A wavelength converting material is disposed over the semiconductor structure. The wavelength converting material is configured to absorb light emitted by the semiconductor structure and emit light of a different wavelength. A filter configured to reflect blue ambient light is disposed over the wavelength converting material. A scattering structure is disposed over the wavelength converting layer. The scattering structure is configured to scatter light. In some embodiments, the scattering structure is a transparent material having a rough surface, containing non-wavelength-converting particles that appear substantially white in ambient light, or including both a rough surface and white particles.

Abstract: A device according to embodiments of the invention includes a waveguide, typically formed from a first section of transparent material. A light source is disposed proximate a bottom surface of the waveguide. The light source comprises a semiconductor light emitting diode and a second section of transparent material disposed between the semiconductor light emitting diode and the waveguide. Sidewalls of the second section of transparent material are reflective. A surface to be illuminated is disposed proximate a top surface of the waveguide. In some embodiments, an edge of the waveguide is curved.

Abstract: The invention relates to a light emitting diode arrangement comprising a first light emitting diode (101), in particular an organic light emitting diode, comprising a first light emitting layer (105) and a first electrode (109) arranged on the first light emitting layer (105), and a second light emitting diode (103), in particular an organic light emitting diode, being arranged upon the first light emitting diode (101), the second light emitting diode (103) comprising a second light emitting layer (113) and a second electrode (117) arranged on the second light emitting layer (113), the second electrode (117) being translucent.

Abstract: An ambulatory medical telemetry device (10) is provided. The device includes at least one sensor (18) for detecting at least one physiological parameter of a patient and a housing that is securable to the patient. A circuit (50) is located in the housing for receiving and processing a signal representative of the physiological parameter from the sensor to generate recordable physiological data. An audio transducer (16) is located in the housing and operationally coupled to the circuit for generating an audio signal indicating at least one operational state of the device.

Abstract: The invention relates to an apparatus for skin imaging, a system for skin analysis and a method for skin analysis, using a combination of near-field and far-field skin images under different angles of illumination. The apparatus provides a tool that may be employed for rapid screening of the skin for lesions that may be indicative of skin diseases, in particular skin cancers such as melanoma.

Abstract: A method includes detecting radiation that traverses a material having a known spectral characteristic with a radiation sensitive detector pixel that outputs a signal indicative of the detected radiation and determining a mapping between the output signal and the spectral characteristic. The method further includes determining an energy of a photon detected by the radiation sensitive detector pixel based on a corresponding output of the radiation sensitive detector pixel and the mapping.

Abstract: An underfill formation technique for LEDs molds a reflective underfill material to encapsulate LED dies mounted on a submount wafer while forming a reflective layer of the underfill material over the submount wafer. The underfill material is then hardened, such as by curing. The cured underfill material over the top of the LED dies is removed using microbead blasting while leaving the reflective layer over the submount surface. The exposed growth substrate is then removed from all the LED dies, and a phosphor layer is molded over the exposed LED surface. A lens is then molded over the LEDs and over a portion of the reflective layer. The submount wafer is then singulated. The reflective layer increases the efficiency of the LED device by reducing light absorption by the submount without any additional processing steps.

Abstract: A method of maintaining a state in a subject comprises measuring one or more physiological parameters of the subject, calculating, using the measured parameter(s), a value, determining if the calculated value is below a lower threshold or above an upper threshold, and generating an output to the subject if the calculated value is determined to be below the lower threshold or above the upper threshold. In one embodiment, the generating an output to the subject comprises generating a first output if the calculated value is determined to be below the lower threshold and generating a second output if the calculated value is determined to be above the upper threshold, the second output being different from the first output.

Abstract: A controllable light angle selecting device (100) is provided. It comprises a fixed light selecting means (110) adapted to transmit light incident thereon within a limited acceptance angle, optically connected to at least one light redirecting means (120) capable of obtaining a variable angular difference between light entering said light redirecting means (120) and light exiting said light redirecting means. A photometer, comprising a controllable light angle selector arranged in the path of light between a light source and a light measuring sensor is also provided.

Abstract: A perfusion analysis system includes a perfusion modeller (120) and a user interface (122). The perfusion modeller (120) generates a patient specific perfusion model based on medical imaging perfusion data for the patient, a general perfusion model, and a quantification of one or more identified pathologies of the patient that affect perfusion in the patient. The user interface (122) accepts an input indicative of a modification to the quantification of the one or more identified pathologies. In response, the perfusion modeller (120) updates the patient specific perfusion model based on the medical imaging perfusion data for the patient, the general perfusion model, and the quantification of the one or more identified pathologies of the patient, including the modification thereto.

Abstract: An imaging device (300), a lighting control system (400) including the imaging device (300), and a method for aligning with a reference image lighting of a site (220) illuminated by least one light source (240) are provided. The imaging device (300) and/or the lighting control system (400) include at least one processor (410) configured to control the imaging device (300) and the light source (240). The imaging device (300) has an array of reflectors (320) including selectable reflectors; a lens configured to receive image rays (330) for forming an image including pixels and provide the image rays (330) to the array of reflectors (320) for reflection as reflected rays (355); and a detector (310) configured to receive the reflected rays (355) and detect characteristics of each pixel of the image for form a resolved image. The processor (410) is further configured to sequentially select each reflector (350) of the array of reflectors (320) for reflecting the reflected rays (355) towards the detector (310).

Abstract: A robust MR compatible ECG monitor (40) includes a connector (50) for connecting ECG electrode leads (44) to an internal circuit board (52). The connector (50) includes connector pins (54) that run parallel to the circuit board (52) and tangentially contact solder pads (56) of the circuit board (52) at the edge of the circuit board (52), eliminating sharp or right angle turns in conduction paths. The connector prevents movement of the connections due to mechanical stresses in all ranges of motion relative to four degrees of freedom, including translation, pitching, yawing, and rolling.

Abstract: The present inventions concerns a display system (2) for displaying multiplex information, whereby an individual selection of information is individually addressed to a different user or user groups, whereby the display system for displaying multiplex information comprises at least one display panel of a plurality of light emitting dot-like means and a plurality of sensors (6a, 6b), whereby a user or user groups are located by sensor so that individual information can be individually addressed depending on the position of each sensor-located user or user groups.

Abstract: An optical measurement device for measuring an optical appearance of a surface of a sample, in particular the surface of a human skin, wherein the optical measurement device comprises: a first illumination device (16) for illuminating the surface (14) with a first illumination beam (22), wherein the first illumination beam (22) is incident at a first angle of incidence (38) onto the surface (14); and a detection device (28) for detecting a response beam (22), wherein the response beam (42) is a response of the sample (12) to the first illumination beam (22), comprising at least one screen (27) for intercepting the response beam (42) and at least an image detection component (29). The optical measurement device (10) comprises a second illumination device (18), wherein the second illumination device (18) is providing a second illumination beam (24) with a second angle of incidence (54) at the surface (14), wherein the first angle of incidence (38) is different from the second angle of incidence (54).