Abstract: A network node determines a system load of the network node for the UE. When the UE is capable of receiving control information on EPDCCH, the system load is determined based on a first and a second system load metrics on a physical resource shared by PDSCH and EPDCCH, which first load metrics comprises a load due to EPDCCH and a load due to multiplexed PDSCH and which second load metrics comprises a load due to multiplexed EPDCCH and a load due to PDSCH. When the UE is not capable of receiving control information on EPDCCH, the system load is determined based on the first system load metrics on the physical resource shared by the PDSCH and EPDCCH and a third system load metrics on a physical resource for carrying PDCCH. The network node further determines whether or not to allocate resources to the UE based on the determined system load metrics.

Abstract: An interposer device comprising an interposer substrate; a plurality of conducting vias extending through the interposer substrate; a conductor pattern on the interposer substrate, and a nanostructure energy storage device. The nanostructure energy storage device comprises at least a first plurality of conductive nanostructures formed on the interposer substrate; a conduction controlling material embedding each nanostructure in the first plurality of conductive nanostructures; a first electrode connected to each nanostructure in the first plurality of nanostructures; and a second electrode separated from each nanostructure in the first plurality of nanostructures by the conduction controlling material, wherein the first electrode and the second electrode are configured to allow electrical connection of the nanostructure energy storage device to the integrated circuit.

Abstract: The system comprises the ability to detect certain gestures made by sliding a finger or stylus on a touch sensitive screen on a handheld device, even when a so called “screen lock” is active where the gesture is used to unlock the device and trigger the desired function associates with the gesture.

Abstract: Assigning resources for control signalling for a wireless device is described wherein the resources can be used for user data when not used for control signalling. A network node obtains a collection of at least one configuration group, wherein each configuration group refers to a selection of the resources; determines a load for each one of the configuration groups; when no configuration group of the collection has a load which is less than a first threshold value, instantiates a new configuration group referring to a selection of the resources, and assigns at least part of the resources of the new configuration group to the wireless device; and when there is a first configuration group in the collection having a load which is less than the first threshold value, assigns at least part of the resources of the first configuration group to the wireless device.

Abstract: An assembly platform for arrangement as an interposer device between an integrated circuit and a substrate to interconnect the integrated circuit and the substrate through the assembly platform, the assembly platform comprising: an assembly substrate; a plurality of conducting vias extending through the assembly substrate; at least one nanostructure connection bump on a first side of the assembly substrate, the nanostructure connection bump being conductively connected to the vias and defining connection locations for connection with at least one of the integrated circuit and the substrate, wherein each of the nanostructure connection bumps comprises: a plurality of elongated conductive nanostructures vertically grown on the first side of the assembly substrate, wherein the plurality of elongated nanostructures are embedded in a metal for the connection with at least one of the integrated circuit and the substrate, at least one connection bump on a second side of the assembly substrate, the second side being

Abstract: Methods for improving gaze tracking are presented. These methods eliminate the need for a separate initial calibration step to determine whether the subject is properly centrally fixated during testing. In one embodiment, whether the subject is centrally fixated is determined by identifying inlier and outlier gaze descriptors; the inliers are assumed to be associated with central fixation. This reduces the total time required for testing. These methods also improve the accuracy of gaze tracking during testing without the need for individual subject calibration. Instead, a database of reference eyes is used. The subject's eye can be compared to the reference eyes, and the mapping function for one or more reference matches can be used to estimate the subject's gaze direction. In another embodiment, previous calibration data from the same subject can be used to determine whether the subject is properly centrally fixated and/or the direction of the subject's gaze.

Abstract: It is presented a method of allocating resources of a first uplink subframe being part of a radio frame, each resource being a combination of a frequency range, and a time slot and a code. The method is performed in a network node and comprises: determining a first set of resources allocated for Hybrid Automatic Repeat Request, HARQ, feedback in the first uplink subframe; determining a second set of resources allocated for HARQ feedback in a second uplink subframe being part of the radio frame; identifying free resources in the first uplink subframe by identifying resources of the second set of resources which have no correspondence in the first set of resources; and allocating when a free resource is found, at least part of the free resources to a use other than HARQ feedback. A corresponding network node is also presented.

Abstract: The invention relates to a radiation curable ink formulation comprising—10 to 70% by weight of at least one trifunctional (meth)acrylate monomer as component A, —1 to 40% by weight of at least one (meth)acrylate monomer with a functionality of 4 or higher as component B, —0 to 20% by weight of one or more monofunctional (meth)acrylate monomers and/or difunctional (meth)acrylate monomers as component C, —2 to 30% by weight of at least one photoinitiator as component D, —5 to 50% by weight of at least one amine synergist as component E, —0 to 40% by weight of one or more meth(acrylate) oligomer as component F, and—0 to 60% by weight of one or more pigment and/or additive as component G. The invention further relates to a printing process using the ink formulation and to a printed food packaging or label for food packaging.

Abstract: In various examples there is a computer-implemented method for forming an optimized three-dimensional model for a three-dimensional graphics image. The method comprises: obtaining the three-dimensional graphics image, the three-dimensional graphics image represented as at least one polygon mesh having a plurality of vertices connected by edges. The method selects one or more of the vertices to be removed by collapse decimation operation, the selection based on an amount of change in the polygon mesh introduced as a result of the decimation operation. The amount of change is computed using information about intersections where two different faces of the polygon mesh pass through one another.

Abstract: An interposer device comprising an interposer substrate; a plurality of conducting vias extending through the interposer substrate; a conductor pattern on the interposer substrate, and a nanostructure energy storage device. The nanostructure energy storage device comprises at least a first plurality of conductive nanostructures formed on the interposer substrate; a conduction controlling material embedding each nanostructure in the first plurality of conductive nanostructures; a first electrode connected to each nanostructure in the first plurality of nanostructures; and a second electrode separated from each nanostructure in the first plurality of nanostructures by the conduction controlling material, wherein the first electrode and the second electrode are configured to allow electrical connection of the nanostructure energy storage device to the integrated circuit.

Abstract: A system, method (400), and network node (102) is presented for setting the size of a control region, the PDCCH region (201) of a subframe (200). The PDCCH control region may have a size, indicated by the Control Format Indicator, CFI, transmitted on the PCFICH, that varies between 1 and 3 OFDM symbols. The network node (102) may select (402) an initial size for the control region (201), and determine (404) whether the initial size for the control region is less than a predetermined maximum control region size. In response to determining that the initial size is less than the predetermined maximum control region size, the network node (102) selects (406) a final size for the control region (201) based on a data region load. The data region load indicates a load on all physical downlink shared channels, PDSCHs, on all enhanced PDCCHs, ePDCCHs, in the data region.

Abstract: A nanoparticle having a solid core comprising a biologically active substance, said core being enclosed by an inorganic coating, a method for preparing the nanoparticle, and the use of the nanoparticle in therapy. A kit comprising the nanoparticle and a pharmaceutical composition comprising the nanoparticle.

Abstract: The present disclosure provides a method of determining a DTX cause at an access node, comprising: transmitting, to a User Equipment (UE), an Uplink (UL) grant and a Downlink (DL) assignment in a same DL subframe; detecting whether Discontinuous Transmission (DTX) of at least one of UL data to be transmitted in response to the UL grant received by the UE and Hybrid Automatic Repeat Request (HARQ) Acknowledgement (ACK)/Negative Acknowledgement (NACK) to be transmitted in response to DL data related to the DL assignment received by the UE occurs; and determining a cause of the DTX based on a result of the DTX detection. The present disclosure further provides an access node using the method and a computer program product.

Abstract: The proposed technology concerns network units and, which are typically remotely located, and from the perspective of one of the network units, the other network unit is therefore referred to as a remote network unit. The network unit is configured to provide Radio Resource Control, RRC, and/or Packet Data Convergence Protocol, PDCP, protocol functionality, and comprises an X2 unit for providing an X2 interface between the RRC and/or PDCP protocol functionality of the network unit and lower protocol layer(s) and/or sub-layer(s) of the remote network unit. The network unit is configured to provide Radio Link Control, RLC, and/or Medium Access Control, MAC, protocol functionality, and comprises an X2 unit for providing an X2 interface between the RLC and/or MAC protocol functionality of the network unit and higher protocol layer(s) and/or sub-layer(s) of the remote network unit.

Abstract: Assigning resources for control signalling for a wireless device is described wherein the resources can be used for user data when not used for control signalling. A network node obtains a collection of at least one configuration group, wherein each configuration group refers to a selection of the resources; determines a load for each one of the configuration groups; when no configuration group of the collection has a load which is less than a first threshold value, instantiates a new configuration group referring to a selection of the resources, and assigns at least part of the resources of the new configuration group to the wireless device; and when there is a first configuration group in the collection having a load which is less than the first threshold value, assigns at least part of the resources of the first configuration group to the wireless device.

Abstract: A network node determines a system load of the network node for the UE. When the UE is capable of receiving control information on EPDCCH, the system load is determined based on a first and a second system load metrics on a physical resource shared by PDSCH and EPDCCH, which first load metrics comprises a load due to EPDCCH and a load due to multiplexed PDSCH and which second load metrics comprises a load due to multiplexed EPDCCH and a load due to PDSCH. When the UE is not capable of receiving control information on EPDCCH, the system load is determined based on the first system load metrics on the physical resource shared by the PDSCH and EPDCCH and a third system load metrics on a physical resource for carrying PDCCH. The network node further determines whether or not to allocate resources to the UE based on the determined system load metrics.

Abstract: A method (40) performed in a communications network (1) is provided for assigning, in a cell (9), enhanced physical downlink control channel, EPDCCH, resources used in the communications network (1) for transmitting scheduling assignments. The method (40) comprises obtaining (41) a EPDCCH subframe pattern that is based on load in the cell (9), wherein the subframe pattern indicates EPDCCH enabled subframes and non-EPDCCH enabled subframes, and assigning (42) EPDCCH resources to a wireless device (3) according to the obtained EPDCCH subframe pattern. A corresponding communications network (1) is provided, and computer programs and computer program products.

Abstract: A nanoparticle having a solid core comprising a biologically active substance, said core being enclosed by an inorganic coating, a method for preparing the nanoparticle, and the use of the nanoparticle in therapy. A kit comprising the nanoparticle and a pharmaceutical composition comprising the nanoparticle.

Abstract: A method for allocating space for a plurality of control sets for Hybrid Automatic Repeat Request (HARQ), wherein each control set comprising elements for carrying HARQ indicators. The method is performed in a network node and comprises determining a largest set size, in number of resources, of any one of the plurality of control sets; determining a target size, in number of resources, to be allocated for HARQ; allocating a HARQ space, wherein the HARQ space having a size, in number of resources, being a maximum of the largest set size and the target size; and spreading the plurality of control sets within the HARQ space. The HARQ space can be used in the uplink, for providing HARQ feedback on downlink information.

Abstract: The invention discloses a tray system and a method for preparing such tray system. The tray system including a tray with a base having holding arrangements for holding implant components, instruments and/or instrument holders, at least a first and a second information sheet which both are adapted to be independently removably arranged on said base of said tray. Each information sheet has its own distribution of holes, which are placed in register with the holding arrangements of the base when the information sheet is arranged on the base, so that an implant component, instrument or instrument holder is arrangable into one of said holing arrangements through a respective one of said holes.