Abstract: The described embodiments relate to a self-regulating patch for taking biopotential measurements and balancing accurate measurements and user comfort. The self-regulating patch including: a heating element operable to generate heat that causes formation of sweat at the skin surface; a biopotential sensor; an exterior surface constructed of a moisture wicking material enveloping the heating element; and a logic to concurrently activate the biopotential sensor and transition the self-regulating patch between a plurality of modes, including a comfort mode and an accuracy mode, where in the comfort mode the heating element is inactive and in the accuracy mode the heating element is active.

Abstract: A positioning system (10) for positioning a patient (101) for diagnostic imaging is provided. The system comprises a sensor arrangement (12) with at least one sensor (14, 16) configured to provide a sensor signal indicative of at least one body parameter of the patient (101), a controller (18) configured to determine a value of the at least one body parameter based on the sensor signal of the at least one sensor (14, 16), and at least one actuatable support (20) configured to move at least one of an arm (105) and a leg (107) of the patient with respect to a torso of the patient.

Abstract: Various embodiments described herein relate to a method, apparatus, and computer-readable medium including one or more of the following: displaying a first attribute display representative of a first attribute of a data set, the first attribute display comprising a first input element for receiving an indication of a first attribute value; displaying a second attribute display representative of a second attribute of the data set, the second attribute display comprising a second input element for receiving an indication of a second attribute value; receiving an indication of a first attribute value for the first attribute of a data set; and after receiving the indication of the first attribute value, altering the second input element of the second attribute display to reflect a portion of the data set matching a query including the first attribute value.

Abstract: The invention provides a method for the production of a 3D printed object (100), wherein the method comprises (i) a 3D printing stage, the 3D printing stage comprising 3D printing a 3D printable material (110) to provide the 3D printed object (100) of printed material (120), wherein the 3D printing stage further comprises forming during 3D printing a channel (200) in the 3D printed object (100) under construction, wherein the method further comprises (ii) a filling stage comprising filling the channel (200) with a curable material (140) and curing the curable material (140) to provide the channel (200) with cured material (150), wherein the cured material (150) has a lower stiffness than the surrounding printed material (120).

Abstract: There is provided an apparatus (100) for rendering one or more visual representations in an augmented and/or virtual reality environment. The apparatus (100) comprises a processor (102) configured to determine a first distance from a proximal end of a limb or part of the limb of a user to a first body part located at a distal end of the limb or part of the limb of the user. The processor is further configured to define a first surface in the augmented and/or virtual reality environment at the determined first distance. The first surface is defined by a rotation at a joint located at the proximal end or the distal end of the limb or part of the limb of the user. The processor is also configured to render a visual representation at a first position on the defined first surface in the augmented and/or virtual reality environment.

Abstract: Method for the production of a 3D printed object (100), wherein the method comprises (i) a 3D printing stage, the 3D printing stage comprising 3D printing a 3D printable material (110) to provide the 3D printed object (100) of printed material (120), wherein the 3D printing stage further comprises forming during 3D printing a channel (200) in the 3D printed object (100) under construction, wherein the method further comprises (ii) a filling stage comprising filling the channel (200) with a curable material (140) and curing the curable material (140) to provide the channel (200) with cured material (150), wherein the cured material (150) has a lower stiffness than the surrounding printed material (120).

Abstract: There is provided a method and apparatus comprising a processor to provide guidance for placement of a wearable device. At least one image of the body of a subject is acquired from one or more cameras (502). The at least one acquired image is analysed to recognise body parts of the subject and to identify a body part of the subject at which to place the wearable device (504). Guidance to place the wearable device at the identified body part of the subject is provided (506).

Abstract: Various embodiments relate to a method, apparatus and system for automatically setting up meta profiles of a co-user, the method including the steps of receiving basic information about the co-user, extracting and analyzing from a social media and online behavior module, detailed information about the co-user based on the basic information, creating the meta profile of the co-user, checking and completing the detailed information in the meta profile which is missing about the co-user; and translating the detailed information into an actionable to be used by a virtual assistant.

Abstract: Techniques are described for detecting erythema caused by wearable devices. In various embodiments, a wearable device (104) may include light source(s) (106) to emit light at multiple wavelengths; light sensor(s) (108) to receive light reflected from tissue (100) of an individual that wears the wearable device; and logic (110) configured to: operate the light source(s) to emit light at multiple wavelengths; receive a signal generated by the light sensor(s), wherein the signal is generated by the light sensor(s) in response to detection of light reflected from the tissue; analyze the signal to determine a first metric from a first wavelength of the light reflected from a first depth of the tissue and a second metric from a second wavelength of the light reflected from a second depth of the tissue; identify a correlation between the first and second metrics; and provide output indicative of tissue erythema based on the correlation.

Abstract: A printing head (100) for a 3-D printing device is disclosed that comprises a nozzle (110) arranged to print a layer (140) of a printing material on a receiving surface (130) and a texturing member (120) arranged to texture the layer or the receiving surface during printing of said layer. The nozzle comprises an outlet including the texturing member (120) and the outlet is shaped to form protrusions (145) extending from a main surface of the layer (140) for interlocking with a subsequent layer. The texturing member ensures that contacting layers formed with the printing head exhibit improved adhesion due to the increased contact surface area between the layers. This yields stronger 3-D articles printed in this manner. A printing apparatus including the printing head, a printing method and an article printed in accordance with the printing method are also disclosed.

Abstract: The described embodiments relate to a sensor patch that can be temporarily removed and re-applied in the same location using a side element of the sensor patch. The side element can be folded onto the sensor patch when the sensor patch is adhered to an object such as an appendage of a person. The side element can be unfolded and adhered to the appendage in order to preserve the placement of the sensor patch on the appendage. In this way, maintenance such as cleaning can be performed on the area where the sensor patch is located without having to dispose of the sensor patch. Once maintenance is completed, the side element can be folded back onto a surface of the sensor patch until maintenance is to be performed again.

Abstract: The invention provides a lighting unit (1000) comprising a lighting device (100), wherein the lighting device (100) comprises a light source (10) configured to provide light source light (11) and beam shaping optics (20) configured to shape the light source light into a lighting device beam (101), wherein the lighting device (100) comprises a window (30) comprising an upstream face (31) directed to the light source (10) and a downstream face (32), wherein the lighting unit (1000) further comprises a beam modifier (200) configured adjacent to the window (30) and configured to intercept at least part of said lighting device beam (101), wherein the lighting device (100) and the beam modifier (200) are configured to modify said lighting device beam (101) to provide a lighting unit beam (1001) downstream from said beam modifier (200), wherein the beam modifier (200) comprises a printed beam modifying element (210).

Abstract: The invention provides a lighting device configured to present to an observer a spatially dynamic sparkling light dis play. The device comprises a luminaire containing a plurality of light sources (28) located on a first surface portion, and arranged to direct light in a direction of a plurality of light transmissive areas (32) formed within an opposing second surface portion. The opposing second surface portion may at least partially bound a chamber (14) within which the primary light sources are disposed, where an internal surface arrangement of the chamber is configured to absorb at least part of the spectral composition of any light emitted by the primary light sources which does not fall directly onto the light transmissive areas.

Abstract: The invention provides a lighting device (12) configured to provide both functional lighting for illuminating a space, and simultaneously to present a spatially dynamic sparkling light display. The device comprises a chamber (14) containing one or more light sources (28). The light sources are arranged to direct light in the direction of a translucent surface portion (20), and in the direction of a plurality of light exit areas (32) delimited by the translucent surface portion. The light exit areas each have a higher transmittance than the surrounding surface portion.

Abstract: The invention provides a lighting unit (1000) comprising a lighting device (100), wherein the lighting device (100) comprises a light source (10) configured to provide light source light (11) and beam shaping optics (20) configured to shape the light source light into a lighting device beam (101), wherein the lighting device (100) comprises a window (30) comprising an upstream face (31) directed to the light source (10) and a downstream face (32), wherein the lighting unit (1000) further comprises a beam modifier (200) configured adjacent to the window (30) and configured to intercept at least part of said lighting device beam (101), wherein the lighting device (100) and the beam modifier (200) are configured to modify said lighting device beam (101) to provide a lighting unit beam (1001) downstream from said beam modifier (200), wherein the beam modifier (200) comprises a printed beam modifying element (210).

Abstract: The invention provides a 3D printing device (500) comprising a printer nozzle (502) for depositing a material on a support structure (550) for the formation of a 3D object (10), wherein the printer nozzle (502) and the support structure (550) are arranged to be translated relative to each other with a translation speed in a translation direction (52, 62), and a vibration actuator arranged for providing a vibrating motion (50, 60) of at least a first part of the support structure (550) relative to the printer nozzle (502) in a direction different from the translation direction (52, 62).

Abstract: The invention provides a method for printing a 3D printed object (100), the 3D printed object (100) comprising a first type of printed material (1120) having electrically conductive properties and a second type of printed material (2120) having electrically insulating properties, wherein the method comprises: (I) providing printable material (110), wherein the printable material (110) has electrically insulating properties and wherein the printable material (110) is convertible by heat to a material (1110,1120) having electrically conductive properties; (II) printing with a 3D printer (500) said printable material (110) to generate printed material (120); and (III) subjecting to heat part of the printed material (120) after deposition; to provide said 3D printed object (100).

Abstract: Method and apparatus for the production of a 3D printed object (100), wherein the method comprises (i) a 3D printing stage, the 3D printing stage comprising 3D printing a 3D printable material (110) to provide the 3D printed object (100), wherein the 3D printing stage further comprises forming during 3D printing a channel (200) in the 3D printed object (100) under construction, wherein the method further comprises (ii) a filling stage comprising filling the channel (200) with a flowable material (140), wherein the flowable material (140) comprises a functional material (140a), wherein the functional material (140a) has one or more of electrically conductive properties, thermally conductive properties, light transmissive properties, and magnetic properties, and immobilizing said functional material (140a).

Abstract: A printing head (100) for a 3-D printing device is disclosed that comprises a nozzle (110) arranged to print a layer (140) of a printing material on a receiving surface (130) and a texturing member (120) arranged to texture the layer or the receiving surface during printing of said layer. The nozzle comprises an outlet including the texturing member (120) and the outlet is shaped to form protrusions (145) extending from a main surface of the layer (140) for interlocking with a subsequent layer. The texturing member ensures that contacting layers formed with the printing head exhibit improved adhesion due to the increased contact surface area between the layers. This yields stronger 3-D articles printed in this manner. A printing apparatus including the printing head, a printing method and an article printed in accordance with the printing method are also disclosed.

Abstract: The invention provides a process for the production of a (particulate) luminescent material comprising particles, especially substantially spherical particles, having a porous inorganic material core with pores, especially macro pores, which are at least partly filled with a polymeric material with a first material embedded therein, wherein the process comprises (i) impregnating the particles of a particulate porous inorganic material with pores with a first liquid (“ink”) comprising the first material and a curable or polymerizable precursor of the polymeric material, to provide pores that are at least partly filled with said first material and curable or polymerizable precursor; and (ii) curing or polymerizing the curable or polymerizable precursor within pores of the porous material, as well as a product obtainable thereby.