Abstract: Navigation data is generated by receiving (502) a new experience data set (321) relating to a new experience capture. At least one stored experience data set (320) relating to at least one previous experience capture is also received (504). An experience data set includes a set of nodes, with each node comprising a series of visual image frames taken over a series of time frames. A candidate set of said nodes is obtained (506) from the stored experience data set that potentially matches a said node in the new experience data set, and then a check (508) if performed to see if a node in the candidate set matches the node in the new experience data set. If the result of the checking is positive then data relating to the matched nodes is added (510) to a place data set useable for navigation, the place data set indicating that said nodes in different said experience data sets relate to a same place.

Abstract: A microelectronic assembly including a dielectric region, a plurality of electrically conductive elements, an encapsulant, and a microelectronic element are provided. The encapsulant may have a coefficient of thermal expansion (CTE) no greater than twice a CTE associated with at least one of the dielectric region or the microelectronic element.

Abstract: Techniques for combining the results of multiple recognizers in a distributed speech recognition architecture. Speech data input to a client device is encoded and processed both locally and remotely by different recognizers configured to be proficient at different speech recognition tasks. The client/server architecture is configurable to enable network providers to specify a policy directed to a trade-off between reducing recognition latency perceived by a user and usage of network resources. The results of the local and remote speech recognition engines are combined based, at least in part, on logic stored by one or more components of the client/server architecture.

Abstract: A method of localising a vehicle hosting a sensor comprises capturing data from the sensor providing a sensed scene around the vehicle at a current time, processing the sensed scene to extract a set of features from the sensed scene and determine a position of the vehicle from the sensed scene in relation to a previous position of the sensor, comparing the extracted set of features to one or more stored experiences, wherein each stored experience comprises a plurality of sets of features, where each set of features has been determined from a previously sensed scene, to ascertain whether the sensed scene can be recognised within any of the stored experiences, and if the extracted set of features of the sensed scene are recognised then that stored experience is used to produce an estimate of the position of the vehicle at the current time with respect to the stored experience.

Abstract: Microelectronic assemblies and methods for making the same are disclosed herein. In one embodiment, a method of forming a microelectronic assembly comprises assembling first and second components to have first major surfaces of the first and second components facing one another and spaced apart from one another by a predetermined spacing, the first component having first and second oppositely-facing major surfaces, a first thickness extending in a first direction between the first and second major surfaces, and a plurality of first metal connection elements at the first major surface, the second component having a plurality of second metal connection elements at the first major surface of the second component; and plating a plurality of metal connector regions each connecting and extending continuously between a respective first connection element and a corresponding second connection element opposite the respective first connection element in the first direction.

Abstract: Techniques for combining the results of multiple recognizers in a distributed speech recognition architecture. Speech data input to a client device is encoded and processed both locally and remotely by different recognizers configured to be proficient at different speech recognition tasks. The client/server architecture is configurable to enable network providers to specify a policy directed to a trade-off between reducing recognition latency perceived by a user and usage of network resources. The results of the local and remote speech recognition engines are combined based, at least in part, on logic stored by one or more components of the client/server architecture.

Abstract: Structures and methods of forming the same are disclosed herein. In one embodiment, a structure can comprise a region having first and second oppositely facing surfaces. A barrier region can overlie the region. An alloy region can overlie the barrier region. The alloy region can include a first metal and one or more elements selected from the group consisting of silicon (Si), germanium (Ge), indium (Id), boron (B), arsenic (As), antimony (Sb), tellurium (Te), or cadmium (Cd).

Abstract: A mounting system for mounting photovoltaic panels on a support structure. The mounting system comprises photovoltaic panel frames in which the photovoltaic panels are mounted, panel support rails, and mounting brackets or cross beams for supporting the panel support rails. The panel frames have inwardly extending panel frame extensions on their back side. The panel support rails are mounted on the support structure with either pivoting brackets or cross beams. In either case, the support rails have pairs of stationary clamps and movable clamps with clamp lips that engage the panel frame extensions of the panel frames.

Abstract: A microelectronic assembly including a dielectric region, a plurality of electrically conductive elements, an encapsulant, and a microelectronic element are provided. The encapsulant may have a coefficient of thermal expansion (CTE) no greater than twice a CTE associated with at least one of the dielectric region or the microelectronic element.

Abstract: A system and method for storing and retrieving data. Data can be stored by resolving a unique identifier with a device. In one embodiment the unique identifier comprises a bar code and an alphanumeric text string. Thereafter, the server receives a query from the device. Then the device transmits the data from the device to the server. Once data has been stored on a server, the server can be retrieved by resolving a unique identifier with a device. The server receives a query from the device, and thereafter transmits data from the server to the device.

Abstract: A microelectronic assembly including a dielectric region, a plurality of electrically conductive elements, an encapsulant, and a microelectronic element are provided. The encapsulant may have a coefficient of thermal expansion (CTE) no greater than twice a CTE associated with at least one of the dielectric region or the microelectronic element.

Abstract: A method and apparatus are disclosed for localizing a vehicle along a route. The method comprises initially surveying the route to be traversed by the vehicle by creating a plurality of orthographic images of the route, at a plurality of locations along the route and subsequently passing the vehicle along the route while obtaining a current view of the route. The method further comprises resolving a pose of the vehicle relative to a survey trajectory by maximising a relation between the orthographic images and the current view.

Abstract: Method and apparatus for localising transportable apparatus (100) within an environment (120) includes obtaining (202) point cloud data (114) representing a 3D point cloud with appearance information of at least part of the environment. The method further obtains (204) first frame data (110) representing an image produced by a sensor (102) onboard transportable apparatus at a first time and location within the environment and second frame data (110) representing an image produced by the sensor at a second time and location within the environment. The method harmonises (206) information about the first frame data, the second frame data and an overlapping subset of the point cloud data in order to determine a location within the point cloud data where at least one of the first frame and the second frame was produced, thereby localising (208) the transportable apparatus within the environment.

Abstract: An interposer can have conductive elements at a first side and terminals at a second side opposite therefrom, for connecting with a microelectronic element and a second component, respectively. The component can include a first element having a thermal expansion coefficient less than 10 ppm/° C., and an insulating second element, with a plurality of openings extending from the second side through the second element towards the first element. Conductive structure extending through the openings in the second element and through the first element electrically connects the terminals with the conductive elements.

Abstract: A method of determining extrinsic calibration parameters for at least one sensor (102, 104, 106) mounted on transportable apparatus (100). The method includes receiving (202) data representing pose history of the transportable apparatus and receiving (202) sensor data from at least one sensor mounted on transportable apparatus. The method generates (204) at least one point cloud data using the sensor data received from the at least one sensor, each point in a said point cloud having a point covariance derived from the pose history data. The method then maximises (206) a value of a quality function for the at least one point cloud, and uses (208) the maximised quality function to determine extrinsic calibration parameters for the at least one sensor.

Abstract: A method of localising transportable apparatus (100) within an environment including receiving (402) data obtained from a ranging sensor device (102) of the transportable apparatus configured to collect information relating to at least a surface (120) over which the transportable apparatus is moving in an environment, and using (404) the ranging sensor device data to generate a new 3D point cloud (110) of the environment. The method further obtains (406) data representing an existing 3D point cloud (114) of at least part of the environment, and seeks to match (408) the new 3D point cloud with, or within, the existing 3D point cloud in order to localise the transportable apparatus with respect to the existing point cloud.

Abstract: A mounting system for mounting photovoltaic panels on a support structure. The mounting system comprises photovoltaic panel frames in which the photovoltaic panels are mounted, panel support rails, and mounting brackets or cross beams for supporting the panel support rails. The panel frames have inwardly extending panel frame extensions on their back side. The panel support rails are mounted on the support structure with either pivoting brackets or cross beams. In either case, the support rails have pairs of stationary clamps and movable clamps with clamp lips that engage the panel frame extensions of the panel frames.

Abstract: Microelectronic elements and methods of their manufacture are disclosed. A microelectronic element may include a substrate including an opening extending through a semiconductor region of the substrate, a dielectric layer cover a wall of the opening within at least a first portion of the opening, a first metal disposed within the first portion of the opening, a second metal disposed within a second portion of the opening. The second metal may form at least part of a contact of the microelectronic element.

Abstract: Methods of forming a microelectronic assembly and the resulting structures and devices are disclosed herein. In one embodiment, a method of forming a microelectronic assembly includes removing material exposed at portions of a surface of a substrate to form a processed substrate having a plurality of thinned portions separated by integral supporting portions of the processed substrate having a thickness greater than a thickness of the thinned portions, at least some of the thinned portions including a plurality of electrically conductive interconnects extending in a direction of the thicknesses of the thinned portions and exposed at the surface; and removing the supporting portions of the substrate to sever the substrate into a plurality of individual thinned portions, at least some individual thinned portions including the interconnects.

Abstract: A method for making an interconnect element includes depositing a thermally conductive layer on an in-process unit. The in-process unit includes a semiconductor material layer defining a surface and edges surrounding the surface, a plurality of conductive elements, each conductive element having a first portion extending through the semiconductor material layer and a second portion extending from the surface of the semiconductor material layer. Dielectric coatings extend over at least the second portion of each conductive element. The thermally conductive layer is deposited on the in-process unit at a thickness of at least 10 microns so as to overlie a portion of the surface of the semiconductor material layer between the second portions of the conductive elements with the dielectric coatings positioned between the conductive elements and the thermally conductive layer.