Abstract: Systems and methods define a stimulation pattern for a juvenile product utilizing a mobile device that executes a mobile application that is linked to the juvenile product. The method comprises the step of recognizing, by the mobile device when executing the mobile app, the user-defined stimulation pattern for the juvenile product. The stimulation pattern can be a vibration pattern or a motion pattern, and can be detected in a number of different ways by the mobile device. The method further comprises the step of determining control signals for the actuator(s) of the juvenile product based on the user-defined stimulation pattern that is recognized by the mobile device. The method further comprises the step of, in response to receiving a command to execute the user-defined stimulation pattern, controlling the actuator(s) of the juvenile product based on the stored control signals for the user-defined stimulation pattern.

Abstract: A remote control apparatus capable of communicating with a control apparatus of an autonomously running work vehicle via a communication apparatus, the remote control apparatus comprising a communication apparatus, a control apparatus, a display apparatus, and cameras for obtaining images of the front and rear, wherein the display apparatus is provided with at least a remote control region for controlling the autonomously running work vehicle, a peripheral image region for displaying images captured by the cameras, and a work status display region, wherein the peripheral image region is provided with a frontal view and a rear view.

Abstract: Systems and methods may use a drone swarm to increase cargo capacity. A drone swarm may include a networked drone system or two or more drones, such as a parent drone and a child drone. A method may include receiving support component balance information captured by an inertial measurement unit on the support component supported by a parent drone, adjusting movement of the parent drone according to a control system using the support component balance information, receiving an indication of a low battery in a drone in the networked drone system, the indication including an identification of a replacement drone to replace the drone with the low battery in the networked drone system, and sending a reconfiguration command to at least one child drone to incorporate the replacement drone in the networked drone system.

Abstract: Methods and systems for autonomous and semi-autonomous vehicle control, routing, and automatic feature adjustment are disclosed. Autonomous operation feature usage levels or settings may be automatically adjusted to optimize performance using suitability data for road segments along a route traveled by a vehicle, such as when operating conditions change. Data regarding road segment suitability may be generated from prior operating data for the road segments and retrieved from a map database to aid autonomous vehicle routing, as well as to implement automatic adjustments to feature usage. In some instances, vehicle control may be returned to a vehicle operator, in which case advance warning may be given to enable the operator to prepare to resume control of the vehicle.

Abstract: A vehicle control system includes: an automated driving controller configured to execute one driving mode from out of a plurality of driving modes including an automated driving mode and a manual driving mode; a vehicle information collection section configured to collect information related to control history of one or both out of speed control and steering control performed based on operation by the occupant of the vehicle while the manual driving mode is being executed; and a driving characteristics derivation section configured to derive driving characteristics for each occupant of the vehicle based on information collected by the vehicle information collection section. The automated driving controller executes the automated driving mode by reflecting the driving characteristics for each occupant of the vehicle to the automated driving.

Abstract: Systems and computer-implemented methods for executing a command in an autonomous vehicle are provided, including the steps of: generating at least three independent vehicle data-sets; transmitting the at least three independent vehicle data-sets to at least three command determination modules, respectively; and, at each one of the at least three command determination modules, using the respective received vehicle data-set to determine a command. The method further includes the step of, during a monitoring phase, comparing the commands to each other to determine if any one of these commands is desynchronized from the other commands. If a command is determined to be desynchronized from the other commands during the monitoring phase, the method includes the step of excluding the command determination module which determined the desynchronized command.

Abstract: A drone identifies situational context (based on signals from at least one sensor) and selects an action in response to the situational context, based on a personality of the drone. The drone then communicates its personality to other drones within a swarm of drones, the drone being a member of the swarm of drones.

Abstract: Systems and methods for automatically self-correcting or correcting in real-time one or more neural networks after detecting a triggering event, or breaching boundary conditions are provided. Such a triggering event may indicate incorrect output signal or data being generated by the one or more neural networks. In particular, machine controllers of the invention limit the operations of neural networks to be within boundary conditions. Autonomous machines of the invention can be self-corrected after a breach of a boundary condition is detected. Autonomous land vehicles of the invention are capable of determining the timing of automatic transition to the manual control from automated driving mode. The controller of the invention filters and saves input-output data sets that fall within boundary conditions for later training of neural networks. The controllers of the invention include security architectures to prevent damages from virus attacks or system malfunctions.

Abstract: A method and system for controlling a position of a marine vessel near an object are disclosed. A location sensor determines a location of the marine vessel, and a speed sensor determines a speed of the marine vessel. A control module is in signal communication with the location sensor and the speed sensor. A marine propulsion system is in signal communication with the control module. The control module determines if the marine vessel is within a predetermined range of the object based on the marine vessel's location. In response to determining that the marine vessel is within the predetermined range of the object, the control module controls the propulsion system to produce at least one of a braking linear thrust and a braking moment to counter current movement of the marine vessel.

Abstract: A method controls a motion of the host vehicle in the environment according to a trajectory and adjusts the trajectory of the vehicle based on the levels of risk posed by the motion of other vehicles. The method determines a set of feasible trajectories of hypothetical vehicles traveling in a driving area of the host vehicle and determines a level of risk of each feasible trajectory as a combination of the probability of the feasible trajectory to intersect with the trajectory of the host vehicle and the probability of the feasible trajectory to be followed by at least one vehicle. The method adjusts the trajectory of the host vehicle in response to assessing the levels of risk of the feasible trajectories.

Abstract: Provided is a vehicle control device mounted on a vehicle including an environment recognition unit and an automatic operation control unit. The environment recognition unit is configured to acquire information on surrounding environment around the vehicle, and provide the automatic operation control unit with the information on the surrounding environment. The automatic operation control unit is configured to acquire select one proposed traveling line, as a target traveling line of the vehicle, from a plurality of proposed traveling lines, on a basis of the information on the surrounding environment, and allow the vehicle to travel along the target traveling line. The vehicle control device is configured to acquire provide display of an image of one or more non-selected traveling lines other than the proposed traveling line selected as the target traveling line from the plurality of proposed traveling lines, together with display of an image of the target traveling line.

Abstract: An autonomous traveling apparatus includes a body, a travel control unit that controls a drive member to cause the autonomous traveling apparatus to travel, an obstacle detection unit that detects an object located within a predetermined obstacle sensing area, a restart switch disposed on the body and operable to cause the autonomous traveling apparatus to resume traveling from a stop mode, and a restart control unit that, when an operation of activating the restart switch is performed by a user, causes the obstacle detection unit to resume obstacle detection so as not to detect the user as an obstacle until the user who has performed the operation of activating the restart switch moves out of the obstacle sensing area, and causes the autonomous traveling apparatus to resume traveling.

Abstract: A vehicle control device includes a lane shape acquisition unit which acquires lane shape data of a lane of a predetermined region from map information, at a stage at which a host vehicle has arrived at the predetermined region or prior to the host vehicle arriving at the predetermined region, a peripheral image acquisition unit which acquires peripheral image data including lane markings of the predetermined region, and a lane marking selection unit which collates the acquired lane shape data with the peripheral image data, and from within the peripheral image data, selects lane markings to be used at least for lane keeping.

Abstract: The present disclosure in the field of automobile engineering is a method and system for generating a safe navigation path for navigating a driverless vehicle. A path generating system receives one or more pre-generated paths between source point and destination point and an environmental data corresponding to each pre-generated path from one or more sources in real-time. Further, the path generating system identifies one or more navigation points in real-time based on the environmental data, vehicle capability characteristics and vehicle parameters by tracing virtual rays in a preconfigured angle range up to preconfigured distance from each of one or more originating points along each of the one or more pre-generated paths. Finally, the path generating system links the navigation points based on predefined techniques to generate the safe navigation path for navigating driverless vehicle. In the present disclosure, safe navigation path is generated without usage of any sensor.

Abstract: Vehicles and methods of navigating vehicles comprise at least three receiver antennae configured to receive radio frequency (RF) signals from one or more RF-transmitting antennae coupled to an object, receiver circuitry coupled to the receiver antennae to acquire the RF signals and to determine timing information from the acquired RF signals, memory storing information related to fixed distances between each receiver antenna and each other receiver antenna, a processor configured to determine a relative position of the vehicle with respect to the one or more RF-transmitting antennae based on the stored information related to the fixed distances between each receiver antenna and each other receiver antenna and on the timing information determined by the receiver circuitry, and a control system configured to control operation of the vehicle in response to the relative position of the vehicle with respect to the one or more RF-transmitting antennae determined by the processor.

Abstract: Techniques are provided for controlling a movable object such as a UAV. A baseline change between a controlling object and a controllable object can be determined with centimeter or sub-centimeter accuracy based on satnav measurements from the controlling object and the controllable object. The baseline change can be mapped to a state change for the controllable object. Control commands can be generated for effecting the state change for the controllable object.

Abstract: A system for localizing a swarm of robotic platforms utilizing ranging sensors. The swarm is localized by purposely leaving some of the platforms of the swarm stationary, providing localization to the moving ones. The platforms in the swarm can alternate between a stationary and moving state.

Abstract: A system and method for continuous measurement of multiple fluids in multiple tanks and computation of physical properties for each of the multiple fluids continuously, which uses a plurality of probes, at least one client device, a master control processor, and a master control data storage. The system and method can use computer instructions for receiving data from the plurality of probes, receiving data from other detection devices associated with the fluid in each tank, mapping received data to a relational database, and comparing mapped data to stored values associated with prioritized alarm functions. The system and method can also use computer instructions for generating alarms to both a display connected with the master control processor and to at least one client device using a network, generating reports associated with each generated alarm, generating an alarm log, and generating a history of actions taken by a user.

Abstract: A method for wireless communication within a building automation system is disclosed. The method includes establishing a communications link between a first automation component and a second automation component, detecting a change in the communications link at the second automation component, and initiating a reset function on the second automation component in response to the detected change in the communications link. A building automation system is further disclosed. The system includes a first automation component, a second automation component in communication with the first automation component via a communication link. The second automation component further includes a reset function stored on a memory and executable by a processor in communication with the memory, such that the reset function is activated in response to a change in the communications link.

Abstract: A portable plant instrument freezing and bursting prevention device using a non-directional serial connector includes a main body portion, a plurality of heat wire portions, each of the plurality of heat wire portions comprising a male connector having a cylindrical shape, a heat wire having resistance, and a female connector having a cylindrical shape and having a hollow portion with both ends open, which are sequentially coupled to one another, and an end cap inserted into the female connector at an end of the plurality of heat wire portions to short-circuit the female connector, in which the male connector of one of the plurality of heat wire portions is inserted into the female connector of another one of the plurality of heat wire portions, and thus the plurality of heat wire portions are serially connected to one another.

Abstract: A multiphase voltage regulator includes a plurality of phases and a controller. Each phase is configured to output a phase current to a load through an inductor in response to a control signal input to the phase. The controller is operable to: generate the control signals input to the phases; set a switching frequency of the control signals to a first value; and change the switching frequency from the first value to a second value different than the first value if the load current changes repetitively at a frequency that is within a predetermined range of the first value of the switching frequency. A corresponding method of operating the multiphase voltage regulator is also provided.

Abstract: A low-dropout voltage regulator (2) comprises: a differential amplifier portion (4) including a first amplifier input connected to a reference voltage (16), a second amplifier input, and a differential output which is determined by a difference between the reference voltage and a voltage on the second amplifier input; an output portion (10) arranged to provide a regulator output voltage (62) which is controlled by the differential output of the amplifier portion, the second amplifier input being connected to or derived from (70) the regulator output voltage; and a biasing portion (8) arranged to measure an external load current and to provide a biasing current to the differential amplifier portion which depends on the load current.

Abstract: A regulator configured to provide at an output node a load current at an output voltage is described. The regulator comprises a pass transistor for providing the load current at the output node. Furthermore, the regulator comprises feedback means for deriving a feedback voltage from the output voltage at the output node. In addition, the regulator comprises a differential amplifier configured to control the pass transistor in dependence of the feedback voltage and in dependence of a reference voltage. The regulator further comprises compensation means configured to determine a sensed current which is indicative of the load current at the output node. Furthermore, the compensation means are configured to adjust an operation point of the regulator in dependence of the sensed current and in dependence of a value of a track impedance of a conductive track which links the output node to a load.

Abstract: An energy storage system for a building includes a battery and an energy storage controller. The battery is configured to store electrical energy purchased from a utility and to discharge stored electrical energy for use in satisfying a building energy load. The energy storage controller is configured to generate a cost function including a peak load contribution (PLC) term. The PLC term represents a cost based on electrical energy purchased from the utility during coincidental peak hours in an optimization period. The controller is configured to modify the cost function by applying a peak hours mask to the PLC term. The peak hours mask identifies one or more hours in the optimization period as projected peak hours and causes the energy storage controller to disregard the electrical energy purchased from the utility during any hours not identified as projected peak hours when calculating a value for the PLC term.

Abstract: A body bias voltage generating circuit for supplying a body bias voltage to a body of a transistor of a functional circuit is provided, including: a first transistor and a second transistor connected in series between a supply voltage terminal and a ground terminal, wherein a control terminal of the first transistor is coupled with a control terminal of the second transistor; a third transistor, wherein a body of the third transistor is electrically coupled with any one of the body of the first transistor and the second transistor, and a terminal of the third transistor is coupled with the body of the third transistor; and a resistance element coupled between the terminal of the third transistor and a current input terminal of the first transistor or a current output terminal of the second transistor. The terminal of the third transistor is the body bias voltage.

Abstract: A button assembly that couples and releases a hitch insert to and from a hitch is described. A button of the button assembly may be configured to be pressed to a degree that allows the hitch insert to be inserted into and removed from a hitch. However, the button assembly may be configured to prevent a user's finger (or other extremity) from entering an aperture of the hitch insert that accommodates the button. For example, in a pressed orientation, a surface of the button that a user contacts may remain flush (or substantially flush) with an outer surface of the hitch insert.

Abstract: A gimbal support that senses rotational displacement and provides haptic feedback in one, two or three dimensions of a manually-operated control member used to generate control inputs using a single hand while also limiting cross-coupling.

Abstract: An actuator comprising two devices each comprising an out-of-plane deformable element, said deformable element comprising a first fixed end anchored on a substrate and a second free end relative to the substrate, said device also comprising means to guide the second free end in in-plane translation along a first direction, the first deformable element being capable of deforming out-of-plane through application of a stimulus so that the second free end draws close to the first fixed end following in-plane translational movement. The actuator also comprises an element mobile in rotation about an axis orthogonal to the plane and mechanically linked to the free ends of the deformable elements, and a translationally mobile element mechanically linked to the rotationally mobile element.

Abstract: The present application provides a signal generator, comprising a control circuit configured to receive input information, and generate variable control word information based on the received input information; a base time unit generation circuit configured to generate a base time unit; and a signal generation circuit configured to receive the variable control word information from the control circuit and receive the base time unit from the base time unit generation circuit, and generate a target signal having a variable frequency based on the received variable control word information and the received base time unit.

Abstract: A device with an I/O interface includes a replica clock distribution path matched to a clock distribution path of an unmatched receiver circuit. The device can monitor changes in delay in the replica path, and adjust delay in the real clock distribution path in response to the delay changes detected in the replica path. The receiver circuit includes a data path and a clock distribution network in an unmatched configuration. A ring oscillator circuit includes a replica clock distribution network matched to the real clock distribution network. Thus, delay changes detected for the replica clock distribution network indicates a change in delay in the real clock distribution network, which can be compensated accordingly.

Abstract: A time of day (TOD) synchronization mechanism in a first processor transmits a latency measure message simultaneously on two links to a second processor. In response, the receiver in the second processor detects latency differential between the two links, detects the delay in the second processor, and sends the latency differential and delay to the first processor on one of the two links. The first processor stores TOD delay values in the two links that account for the latency differential between the two links. When a TOD message needs to be sent, a link loads a counter with its stored TOD delay value, then decrements the counter until the TOD message is ready to be sent. The resulting counter value is the receiver delay value, which is transmitted to the receiver as data in the TOD message, thereby reducing TOD jitter between the two links.

Abstract: A smartphone device may have thin borders at the left, right, top, and/or bottom edges of the display screen. To accommodate, e.g., a front camera in spite of a border that is too thin for a camera module and lens, at least one corner of the display may be cut out. Optical sensor(s), emitter(s), or the lens of a front camera may be disposed at the location(s) of the cutout(s). A wide-screen movie may be displayed in letterbox mode with horizontal bars above and/or below the movie, wherein the cutout(s) are located, at least partially, in the region(s) of the horizontal bars, thereby avoiding that larger parts of the movie are hidden by the cutout(s). In other embodiments, an uninterrupted status bar may be displayed between a cutout in the upper-left corner and a cutout in the upper-right corner of the display.

Abstract: An electronic device is provided. The electronic device includes a window panel having a front area and a curved area extending from the front area, a display panel disposed beneath the window panel, and a fixed part which supports a curved area of the display panel. The display panel includes a front display area, a side display area extending from the front display area so as to be curved, and a wiring area extending from the side display area, and the fixed part supports a curved shape of the side display area or the wiring area.

Abstract: Embodiments of the present disclosure provide techniques and configurations for an apparatus for detection of a change of electromagnetic field in response to a gesture, to identify the gesture that caused the field change. In one instance, the apparatus may include a first conducting component having first features for the disposal on or around a portion of a user's body, to generate an electromagnetic field in response to a receipt of a source signal. The apparatus may further include a second conducting component having second features for the disposal on or around a portion of the user's body, at a distance from the first conducting component, to provide an indication of a change in the electromagnetic field over time, to identify a change of a position of the user's body portion (gesture) that causes the change in the electromagnetic field. Other embodiments may be described and/or claimed.

Abstract: A base of tablet computer includes a housing, a moving member, and an interface assembly. The housing has a trench, a first sidewall, and a second sidewall connected to the first sidewall. The first sidewall forms a portion of the trench and has a first opening. The second sidewall forms another portion of the trench and has a second opening. The moving member is configured to move relative to the housing to selectively enter or exit the trench via the first opening. The interface assembly protrudes to a side of the second sidewall adjacent to the trench via the second opening, and is configured to rotate relative to the second opening based on an axis. The interface assembly is operatively connected to the moving member, so as to be rotated by the moving member while the moving member is moved relative to the housing.

Abstract: An electronic device can include a camera and a cover glass arrangement disposed over the camera. The cover glass arrangement includes a thinner region or cover glass that is positioned over a light-receiving region of the camera. Additionally, the thinner region or cover glass can be disposed over the light-receiving region and at least parts of one or more non-light receiving regions of the camera.

Abstract: A computing device can include a processor; memory accessible by the processor; a base that includes a first platform at a first height and a second platform at a second height that differs from the first height; an arm operatively coupled to the base; and a display operatively coupled to the processor and operatively coupled to the arm.

Abstract: The present invention provides a curved backboard assembly and a curved display device. The curved backboard assembly of the present invention includes a curved ferrous metal plate and a curved plastic plate mounted to a back side of the curved ferrous metal plate. The curved ferrous metal plate is provided, on a back surface thereof, with a plurality of longitudinal positioning slots and at least one set of transverse positioning slots, and the curved plastic plate is provided, on a front surface thereof, with a plurality of longitudinal positioning pawls and at least one set of transverse positioning pawls. The one set of transverse positioning pawls are respectively received into and set in engagement with the one set of transverse positioning slots. Each of the longitudinal positioning pawls is received into and set in engagement with one of the longitudinal positioning slots.

Abstract: Systems and methods for active pop-up finger access in a portable information handling system. The portable system may include a housing having a first housing portion and a second housing portion rotationally coupled by a hinge. The first housing portion may include an electromagnet disposed proximate a front portion of the first housing portion. The second housing portion may include a finger access feature proximate a front portion of the second housing portion and a second magnet disposed proximate the front portion of the second housing portion. The processor may, when a sensor detects a finger of a user proximate the finger access feature, activate the electromagnet to create a magnetic repulsion force with the first magnet. The magnetic repulsion force may cause the portable information handling system to move from a closed position to a finger access open position.

Abstract: A high strength hinge mechanism is described herein. In one or more implementations, a computing device includes a display portion which includes a display device, and a base portion which includes a keyboard. A hinge mechanism is attached to the display portion and the base portion to enable rotation of the display portion relative to the base portion. The hinge mechanism includes a friction element and a cylindrical shaft secured to the friction element and to a chassis of the display portion. The friction element is configured to apply friction to the shaft in a radial direction as the shaft is rotated. The rotation of the shaft enables the display portion to be rotated from a closed position to a fully-open position. The hinge mechanism also includes a frame structure to support the friction element and the shaft.

Abstract: A hinge assembly includes a first and a second set of friction elements engaged each other by an applied force perpendicular to the friction elements. The first and the second set of friction elements are capable of rotational movement about a cylindrical element that passes through each of the friction elements. Also, the first set of friction elements is capable of movement relative to the second set of friction elements. However, the first set friction elements can remain in a fixed position based upon the applied force, until an external force overcomes the applied. During rotation of the first set of friction elements about the cylindrical element, the frictional engagement that controls the position of the first set of friction elements is based primarily on engagement between the friction elements, as opposed to engagement, if any, between the friction elements and the cylindrical element.

Abstract: A speaker module includes a DC-DC converter device including a switching circuit device and a choke coil connected to the switching circuit device and a speaker device that converts an electric signal generated using output voltage from the DC-DC converter device into sound. A magnetic substrate which includes the choke coil and on which the switching circuit device is mounted is disposed between the switching circuit device and the speaker device.

Abstract: A bezel comprises a base, a cover and at least one insertable component. The base comprises a plurality of openings. The cover is configured for mounting to a front of the base, and the cover comprises at least a first aperture. When the cover is mounted to the base, the first aperture aligns with at least a first one of the plurality of openings in the base. The at least one insertable component is configured for mounting to the base in the first opening through the first aperture of the cover. The bezel is configured for attachment to a front portion of an electronic equipment chassis.

Abstract: A storage device mounting system includes a cage assembly configured to receive one or more storage devices. A pivot assembly is configured to pivotally attach the cage assembly to a chassis assembly. A flexible conductor assembly is configured to electrically couple the one or more storage devices to a system board assembly while allowing the cage assembly to pivot with respect to the chassis assembly.

Abstract: A heat dissipation assembly includes a pressing unit and a heat dissipation module. The pressing unit includes a pressing plate, a plurality of elastic cantilevers and contacting members. The pressing plate can be secured on a bottom plate so that a heat source can be sandwiched between the pressing plate and the bottom plate. The elastic cantilevers are respectively disposed on the pressing plate and protruded outwards from the pressing plate to be suspended in midair. The contacting members are respectively disposed on the elastic cantilevers for abutting the bottom plate. The heat dissipation module is fixedly connected to the pressing plate and a carrier member for thermally guiding the heat source.

Abstract: In the examples provided herein, an apparatus has modules to be cooled during operation, where each module is coupled to a heatsink, and the heatsinks are coupled to a first surface of a thermally conductive plate. The modules are positioned along a direction from a first side of the plate toward an opposite side of the plate. The apparatus also has heat pipes coupled to a second surface of the plate to transport heat away from the modules during operation, where the heat pipes are positioned nonuniformly along the direction.

Abstract: Methods, systems, and apparatus for enabling a power path between a power source and a host device via an accessory. A host device may send, to an accessory arranged within the power path, via a first data pin arranged in the host device, a request for an accessory identifier. The accessory identifier identifies the accessory. The host device may then determine whether the accessory identifier is received from the accessory within a specified period of time or whether a received accessory identifier is valid. If the accessory identifier is not received from the accessory within the specified period of time, or a received accessory identifier is not valid, the host device sends a new request for the accessory identifier to the accessory via a second data pin different than the first data pin.

Abstract: A method and apparatus of controlling a network node by providing a virtual power distribution unit. The method comprises: providing a virtual PDU by using a computing device; and causing the virtual PDU to control power supply of the network node coupled to the virtual PDU according to a type of the network node. In some embodiments, not only physical nodes can be controlled, but also virtual nodes can be controlled.

Abstract: Systems and methods of the present disclosure relate to automatically and/or dynamically generating one or more power management sequences for SoC and NoC architectures from a given input specification having one or a combination of NoC design specification, traffic specification, traffic profile, power profile information, initiator-consumer relationship, interdependency between components, retention information, external factors, among other allied configurations/information to enable efficient switching of one or more hardware elements from one power profile to another.

Abstract: A storage unit stores therein first information indicating the correspondence among each acquisition time point at which a result of measuring cumulative energy consumed during the execution of a program was acquired, the cumulative energy, and the memory address of an instruction executed at the acquisition time point. The storage unit stores therein second information indicating the correspondence between each executed part of the program and a range of the memory addresses of instructions of the program. A computation unit determines time points in the execution of a predetermined executed part, on the basis of the first and second information, and calculates cumulative energy for each of the time points with linear interpolation.