Abstract: The present invention aims to provide a technical solution for recognizing a target device from a plurality of devices as follows: sending a first and second wireless signal to a plurality of devices and determining the target device according to the signal strength differences between the first and second signal strengths. By using the technical solutions of the present invention, the “near-far-effect” caused by a single antenna can be overcome, and different offsets in the measured received signal strengths caused by the diversity of the receiving antennas can also be eliminated, and thus the accuracy of recognition is improved efficiently.

Abstract: The machine comprises: a brewing unit (3); a water reservoir (7); a boiler (11) for the production of hot water to supply to the brewing unit; a coffee container (13); an electronic control unit (27); a user interface (33). At least one capacitive sensor (31) is associated to the coffee container to detect the quantity of residual coffee in the container (13). The sensor is connected to the electronic control unit, which is programmed to supply to a user by means of the interface at least a piece of information regarding the quantity of coffee in said container.

Abstract: The invention relates to a method of MR imaging of at least a portion of a body of a patient placed in an examination volume of an MR device. The object of the invention is to improve CEST contrast enhanced imaging. The method of the invention comprises the following steps: a) saturation of nuclear magnetization of exchangeable protons of a CEST contrast agent administered to the patient by subjecting the portion of the body to at least one frequency-selective saturation RF pulse matched to the MR frequency of exchangeable protons of the CEST contrast agent, wherein the saturation period, i.e.

Abstract: The invention provides a mirror unit having a mirror unit front with a mirror surface and having a lighting unit comprising a plurality of light sources and a lenticular lens array. The light sources and the lenticular lens array are arranged to provide mirror unit light in a space in front of the mirror unit front.

Abstract: The invention relates to a system and a method for visualizing a time-variant parameter at a plurality of positions in a biological structure, wherein a visualization display is configured to display a first representation showing a first visualization parameter at a plurality of time intervals, determined in a first volume between a first and a second boundary of the structure, and to display a second representation showing first and second visualization parameters determined in the first and in a second volume extending between the first and the second boundary of the structure. By providing the user with this combination of the two representations, a higher resolution of data may be processed and meaningfully visualized for intermediate volumes between the first and the second boundary. This is based on the insight that it is desirable to view data between boundaries of a structure as well as at different positions through the structure.

Abstract: A method and apparatus are provided to improve large field of view CT image acquisition by using at least two scanning procedures: (i) one with the radiation source and detector centered and (ii) one in an offset configuration. The imaging data obtained from both of the scanning procedures is used in the reconstruction of the image. In addition, a method and apparatus are provided for detecting motion in a reconstructed image by generating a motion map that is indicative of the regions of the reconstructed image that are affected by motion artifacts. Optionally, the motion map may be used for motion estimation and/or motion compensation to prevent or diminish motion artifacts in the resulting reconstructed image. An optional method for generating a refined motion map is also provided.

Abstract: A method according to embodiments of the invention includes providing an epitaxial structure comprising a donor layer and a strained layer. The epitaxial structure is treated to cause the strained layer to relax. Relaxation of the strained layer causes an in-plane lattice constant of the donor layer to change.

Abstract: In some embodiments of the invention, a device includes a first semiconductor layer, a second semiconductor layer, a third semiconductor layer, and a semiconductor structure comprising a III-nitride light emitting layer disposed between an n-type region and a p-type region. The second semiconductor layer is disposed between the first semiconductor layer and the third semiconductor layer. The third semiconductor layer is disposed between the second semiconductor layer and the light emitting layer. A difference between the in-plane lattice constant of the first semiconductor layer and the bulk lattice constant of the third semiconductor layer is no more than 1%. A difference between the in-plane lattice constant of the first semiconductor layer and the bulk lattice constant of the second semiconductor layer is at least 1%. The third semiconductor layer is at least partially relaxed.

Abstract: The invention provides a carpet unit comprising a laminate of a tufted primary backing layer providing a carpet unit top face, an intermediate adhesive layer, and a backing layer providing a carpet unit back face, wherein the carpet unit is selected from the group consisting a carpet and a carpet tile, wherein the carpet unit further comprises an optical sensor, arranged to generate a sensor signal, wherein, seen from carpet unit top face, the optical sensor is arranged behind the primary backing layer, and wherein the carpet unit is arranged to transmit light from the carpet unit top face to the optical sensor.

Abstract: The invention provides a system 100 for providing wireless control on an electronic device 30. The system 100 comprises a control station 10 and a wireless device 20. The control station 10 is configured to send a wireless exciting signal and a wireless control command. The wireless device 20 comprises an exciter module 201 and a processor module 210, wherein the exciter module 201 is configured to collect power from the wireless exciting signal and subsequently change a state of the processor module 210 from an inactive state to an active state, and the processor module 210 is configured to receive the control command and adjust functions of the electronic device 30 in accordance with the control command. The invention also provides a method and a wireless device.

Abstract: The invention provides a light transmissive multi-layer carpet tile having a carpet tile top face and a carpet tile bottom face. The multi-layer carpet tile comprises a tufted primary backing layer, a pre-coat layer, and a tile backing. The multi-layer carpet tile comprises a light transmissive carpet tile section having a carpet tile light transmission in the range of 0.5-15% for light propagating in a direction from the tile backing to the carpet tile top face and having a wavelength in the visible range.

Abstract: The invention discloses an electroluminescent device (10), comprising a substrate (40) and on top of the substrate (40) a substrate electrode (20), a counter electrode (30) and an electroluminescent layer stack with at least one organic electroluminescent layer (50) arranged between the substrate electrode (20) and the counter electrode (30), and an encapsulation means (90) at least encapsulates the electroluminescent layer stack, at least one divide (80,80?) dividing at least the counter electrode (30) into a plurality of electrically separated counter-electrode-segments (110,110?,110?), below the divide (80,80?) an electrically non-conductive protective means (70) is arranged on the substrate electrode (20) exceeding the divide (80, 80?) and the protective means (70) is arranged on the substrate electrode (20) with a shape suitable to prevent the emergence of a shadowing edge.

Abstract: This invention relates to an electroluminescent device (10) comprising an organic light emitting layer (50) and an encapsulation means (70) with a closed contour encapsulating the side of the electroluminescent layer stack (59) and for electrically contacting the counter electrode (40) to an electrical source. Furthermore, the invention relates to a method for providing such a device, the use of the contiguous contour as an encapsulation means and a covered substrate to be used in such a device.

Abstract: A method comprises acquiring at least one magnetic resonance image of a placenta using an ultra-short echo time (UTE) pulse sequence; and processing the at least one magnetic resonance image to generate information indicative of placental calcification. In apparatus embodiments, a gynecology module (20) comprises a digital processor configured to cause a magnetic resonance imaging scanner (10, 12, 14, 16) to acquire at least one magnetic resonance image of a placenta and to process the at least one magnetic resonance image to generate information indicative of placental calcification.

Abstract: A system (100) for analyzing a sequence of datasets representing sequential images of an object, a dataset associating data values with positions, the images having an image region having a first border (210) and a second border (220) associated with the object, the system comprising a ray establishing means (130) for establishing for individual images an analysis ray (232; 234; 236) connecting the first and second border of the image region, the analysis rays being in a respective position representing a substantially same position with respect to the object, a gradient establishing means (140) for establishing, for individual analysis rays, a gradient value which is representative of a rate of change in the data values across the image region and along the analysis ray from the first border to the second border. The system is well suited to locate perfusion deficits in the myocardium through the identification of transmural gradients.

Abstract: A system is provided for obtaining a nuclear image of a moving object. The system comprises an input (14), a processing unit (15) and an output (17). The input (14) is provided for receiving a nuclear image and morphological images of the object. The processing unit (15) is configured to process the morphological images to obtain sparse motion information of the object, to use the sparse motion information and a motion model for obtaining estimated motion information about the object, and to generate a motion-corrected nuclear image based on the estimated motion information and the acquired nuclear image. The output (17) provides the corrected nuclear image.

Abstract: In a method of encoding input signals (CH1 to CH3; 400 to 450) in a multi-channel encoder (5; 15) to generate corresponding output data having down-mix output signals (610, 620) together with complementary parametric data (600), the method includes a first step of down-mixing input signals (CH1 to CH3; 400 to 450) to generate the corresponding down-mix output signals (610, 620), and a second step of processing the input signals (CH1 to CH3; 400 to 450) during down-mixing to generate the parametric data (600) complementary to the down-mix output signals (610, 620). Processing of the input signals (CH1 to CH3; 400 to 450) involves including information in the down-mix signals (610, 620) which is useable during subsequent decoding of the down-mix output signals (610, 620) and the parametric data (600) to determine at least some parameter data and thereby enabling representations of the input signals (CH1 to CH3; 400 to 450) to be subsequently regenerated.

Abstract: The invention relates to a device comprising an ingestible capsule which measures at least one body parameter and starts a drug release program upon predefined changes in the body parameter.

Abstract: The invention relates to a controlling device (10) for a greenhouse (15), with a computerized control element (20), a lighting element (30) and at least one detector element (40), wherein the lighting element (30) and the detector element (40) are connected with the computerized control element (20), wherein the lighting element (30) comprises at least one light emitting mean (31), emitting a light (32), wherein the light (32) illuminates a plant (70) growing in the greenhouse (15).

Abstract: Systems and methods for forming a local network (150) include determining which controllable (120) and controlling (170, 180) devices are located within a local area (110). A controller (130) is configured to communicate with the controllable and controlling devices and to include local devices to the local network (150) associated with the local area, while preventing remaining devices from being associated with the local network. The controller may be further configured to automatically reconfigure itself and/or the local controlling device(s) to properly be commissioned to control the local controllable device(s), such as based on the number and/or type of the local controlling devices allowed to join the local network. The controller distinguishes and determines the local controllable and controlling devices by RF signals, IR signals and/or sonar signals, such as based on time of flight and received signal strength of the RF signals.