Abstract: This document describes techniques and apparatuses for estimating battery cell parameters. In some embodiments, these techniques and apparatuses enable the isolation of a battery cell from other battery cells. Voltage levels of the isolated battery cell are measured while varying amounts of current are drawn from the cell. Parameters of the isolated battery cell can then be estimated based on the measured voltage levels and various amounts of current that are drawn from the cell.

Abstract: A method for mapping touch inputs to inputs on a user input module is described. Touch event data resulting from users interacting with a touch-based application is received at a computing resource. This touch event data is analyzed to identify touch inputs to the application and the analysis is performed independently of the code for the application. Mapping data is then generated which identifies at least one mapping between an identified touch input to the application and a user input via a user input module.

Abstract: In one or more implementations, a static geometry model is generated, from one or more images of a physical environment captured using a camera, using one or more static objects to model corresponding one or more objects in the physical environment. Interaction of a dynamic object with at least one of the static objects is identified by analyzing at least one image and a gesture is recognized from the identified interaction of the dynamic object with the at least one of the static objects to initiate an operation of the computing device.

Abstract: A removable input/output module for a touch-screen device is described. The input/output module comprises a front plate, a rear plate and an edge plate. When attached to the touch-screen device, the front plate contacts with the front face of the touch-screen device, the rear plate contacts with the rear face of the touch-screen device and the edge plate contacts at least an upper part of an edge face of the touch-screen device. The input/output module further comprises a mechanism which provides a force to clamp the front and rear plates onto the touch-screen device and an adjustment mechanism which allows the relative position of the front plate and the edge plate to be adjusted.

Abstract: A charging device for one or more input modules for a touch-screen device is described. The charging device comprises a charging mechanism and portions which are shaped to receive an input module. The charging mechanism comprises a power input and a power output. The power input is configured to receive power from an external power source and the power input is configured to provide power to one or more input modules which are attached to the charging device.

Abstract: Aspects relate to detecting gestures that relate to a desired action, wherein the detected gestures are common across users and/or devices within a surface computing environment. Inferred intentions and goals based on context, history, affordances, and objects are employed to interpret gestures. Where there is uncertainty in intention of the gestures for a single device or across multiple devices, independent or coordinated communication of uncertainty or engagement of users through signaling and/or information gathering can occur.

Abstract: Methods and devices for providing a user input to a device through sensing of user-applied forces are described. A user applies forces to a rigid body as if to deform it and these applied forces are detected by force sensors in or on the rigid body. The resultant force on the rigid body is determined from the sensor data and this resultant force is used to identify a user input. In an embodiment, the user input may be a user input to a software program running on the device. In an embodiment the rigid body is the rigid case of a computing device which includes a display and which is running the software program.

Abstract: Various embodiments provide techniques and devices for scheduling power loads in devices having multiple batteries. Loads are characterized based on the power required to serve them. Loads are then assigned to batteries in response to the type of load and relative monitored characteristics of the batteries. The monitored battery characteristics can change over time. In some embodiments, stored profile information of the batteries can also be used in scheduling loads. In further embodiments, estimated workloads can also be used to schedule loads.

Abstract: Aspects relate to detecting gestures that relate to a desired action, wherein the detected gestures are common across users and/or devices within a surface computing environment. Inferred intentions and goals based on context, history, affordances, and objects are employed to interpret gestures. Where there is uncertainty in intention of the gestures for a single device or across multiple devices, independent or coordinated communication of uncertainty or engagement of users through signaling and/or information gathering can occur.

Abstract: One or more graphical objects are displayed in a fixed orientation with reference to a sensed reference direction. Manipulation is achieved by fixing the orientation or position of a displayed graphical object with reference to an apparatus, such as the display itself or a proxy device, detecting a change in orientation of that apparatus and editing the orientation of the graphical object based on the detected change.

Abstract: A device is described which enables users to interact with software running on the device through gestures made in an area adjacent to the device. In an embodiment, a portable computing device has proximity sensors arranged on an area of its surface which is not a display, such as on the sides of the device. These proximity sensors define an area of interaction adjacent to the device. User gestures in this area of interaction are detected by creating sensing images from data received from each of the sensors and then analyzing sequences of these images to detect gestures. The detected gestures may be mapped to particular inputs to a software program running on the device and therefore a user can control the operation of the program through gestures.

Abstract: A removable input module for a touch-screen device is described. The input module comprises an attachment mechanism to attach the module to the touch-screen device, one or more input controls and an accelerometer and/or magnetometer. The accelerometer and/or magnetometer are configured to provide signals to be used to determine the orientation of the input module relative to the touch-screen device and/or to another input module which is attached to the same touch-screen device. In an embodiment, the input module comprises a processor arranged to analyze the output of the accelerometer and/or magnetometer and determine the orientation of the input module.

Abstract: 3D printing may be optimized by segmenting input jobs and/or combining parts of input jobs together. In an embodiment, a user-defined metric is received associated with each input job and this is used in scheduling input jobs to optimize latency and/or throughput of the 3D printing process, along with the printing envelope and other characteristics of the 3D printers used. In various embodiments, the scheduling may comprise dividing a 3D object into a number of parts and then scheduling these parts separately and/or combining 3D objects, or parts of 3D objects, from various input jobs to be printed at the same time on the same 3D printer. In various embodiments, the scheduling is repeated when a new input job is received and changes made during printing. In various embodiments, a user may submit an updated version of an input job which is already in the process of being printed.

Abstract: A modular development platform is described which enables creation of reliable, compact, physically robust and power efficient embedded device prototypes. The platform consists of a base module which holds a processor and one or more peripheral modules each having an interface element. The base module and the peripheral modules may be electrically and/or physically connected together. The base module communicates with peripheral modules using packets of data with an addressing portion which identifies the peripheral module that is the intended recipient of the data packet.

Abstract: A set of reconfigurable clip-on modules for mobile computing devices includes two or more modules and at least one of the modules has an input button or other control and at least one of the modules can communicate with the computing device without needing to be connected to it via a wire. The input button is mapped to a user input in a program, such as a game, which is running or displayed on the computing device to which the modules are clipped. In an embodiment, user inputs via the buttons or other controls on the clip-on modules are mapped to user inputs in a game running on the device, which may be a touch-screen device, and the mapping between user inputs via the buttons and user inputs in the game may change dependent upon the game being played, user preference, or other criteria.

Abstract: Power transfer between devices such as laptop computers, mobile phones, personal digital assistants, media players and other devices is described. In an embodiment power transfer is achieved either from a power source at a device or to a power source at that device using a bidirectional power transfer connector. In some embodiments a power management module at the device uses context, models or other information to control factors such as the power transfer direction, duration and amount. In examples, user preferences are taken into account. In an example, the bi-directional power transfer connector is provided as a USB connection or a wireless power transfer connection.

Abstract: Methods and devices for providing a user input to a device through sensing of user-applied forces are described. A user applies forces to a rigid body as if to deform it and these applied forces are detected by force sensors in or on the rigid body. The resultant force on the rigid body is determined from the sensor data and this resultant force is used to identify a user input. In an embodiment, the user input may be a user input to a software program running on the device. In an embodiment the rigid body is the rigid case of a computing device which includes a display and which is running the software program.

Abstract: Methods of encryption and decryption are described which use a key associated with an event to encrypt/decrypt data associated with the event. The method of encryption comprises identifying a key associated with an event and encrypting data using the identified key. The encrypted data is then published along with details of the event.

Abstract: A set of reconfigurable clip-on modules for mobile computing devices includes two or more modules and at least one of the modules has an input button or other control and at least one of the modules can communicate with the computing device without needing to be connected to it via a wire. The input button is mapped to a user input in a program, such as a game, which is running or displayed on the computing device to which the modules are clipped. In an embodiment, user inputs via the buttons or other controls on the clip-on modules are mapped to user inputs in a game running on the device, which may be a touch-screen device, and the mapping between user inputs via the buttons and user inputs in the game may change dependent upon the game being played, user preference, or other criteria.

Abstract: In one or more implementations, a static geometry model is generated, from one or more images of a physical environment captured using a camera, using one or more static objects to model corresponding one or more objects in the physical environment. Interaction of a dynamic object with at least one of the static objects is identified by analyzing at least one image and a gesture is recognized from the identified interaction of the dynamic object with the at least one of the static objects to initiate an operation of the computing device.