Abstract: A portable electronic device with a touch-sensitive display (such as a cellular telephone) provides a wireless remote control for an entertainment device (such as a consumer-electronic device). Based on device-state information that specifies a current state of the entertainment device (which is determined by an audio/video (A/V) hub that communicates with the entertainment device) and one or more related states of the entertainment device, the A/V hub may generate user-interface information that specifies a user interface that includes one or more virtual command icons. Note that the one or more related states are related to the current state in a state diagram by corresponding operations that transition the entertainment device from the current state to the one or more related states. Then, the A/V hub provides the user interface to the portable electronic device. In this way, the A/V hub device dynamically adapts the user interface.

Abstract: A portable electronic device with a touch-sensitive display (such as a cellular telephone) provides a wireless remote control for an entertainment device (such as a consumer-electronic device). Based on device-state information that specifies a current state of the entertainment device (which is determined by an audio/video (A/V) hub that communicates with the entertainment device) and one or more related states of the entertainment device, the A/V hub may generate user-interface information that specifies a user interface that includes one or more virtual command icons. Note that the one or more related states are related to the current state in a state diagram by corresponding operations that transition the entertainment device from the current state to the one or more related states. Then, the A/V hub provides the user interface to the portable electronic device. In this way, the A/V hub device dynamically adapts the user interface.

Abstract: A portable electronic device with a touch-sensitive display (such as a cellular telephone) provides a wireless remote control for an entertainment device (such as a consumer-electronic device). Based on device-state information that specifies a current state of the entertainment device (which is determined by an audio/video (A/V) hub that communicates with the entertainment device) and one or more related states of the entertainment device, the A/V hub may generate user-interface information that specifies a user interface that includes one or more virtual command icons. Note that the one or more related states are related to the current state in a state diagram by corresponding operations that transition the entertainment device from the current state to the one or more related states. Then, the A/V hub provides the user interface to the portable electronic device. In this way, the A/V hub device dynamically adapts the user interface.

Abstract: In order to maintain performance during wireless communication, a transmitting electronic device may concurrently and independently communicate redundant information to a receiving electronic device. In particular, information associated with a data stream may be communicated to the receiving electronic device using one or more channels by two radios using one or more wireless local area network communication protocols. The packets transmitted by the radios may preferentially include the same information. Moreover, the transmitting electronic device may attempt to maintain the redundant communication if a performance metric associated with the one or more channels degrades. For example, the transmitting electronic device may transfer communication to a different channel or may compress the information in the packets in the one or more channels if the throughput drops below a threshold value.

Abstract: A controlled motion system having a plurality of movers controlled as they travel along both smart and simple sections of a track. The controlled motion system comprises a control system for controlling the speed of a mover as it travels along a simple section, and permits the pitch or distance between movers to increase or decrease as they travel along a simple section. In a preferred embodiment the controlled motion system includes at least one coupling feature having a driving feature on a simple section for engaging and operably driving a driven feature on each mover such that positive control of each mover is maintained throughout its transition from a smart section to a simple section.

Abstract: A 3D printer calibration system and method includes a controller controlling movement of the 3D printer printhead in a first axis, such as the z-axis. The printhead includes a hotend for depositing material to generate the 3D printing. The hotend is connected to the printhead via a connector being moveable along the first axis. The hotend further includes an arm that extends outward from the side of the hotend. An optical sensor assembly is affixed to the printhead, the optical sensor assembly that has a light emitter and a light detector. The controller calibrates a starting position for the printhead based on the first axis deflection of the hotend as detected by the optical sensor assembly. The connector allowing first axis deflection of the hotend distinct from the first axis movement of the printhead.

Abstract: An adhesive application valve comprising an applicator, a Z-axis actuator operably connected to the applicator, wherein the Z-axis actuator and the rotation device are each capable of moving independently of each other to position the applicator in a position to apply an amount of adhesive to a top substrate prior to bonding with a bottom substrate is provided. Furthermore, a machine comprising an end effector, and an adhesive application valve configured to apply an amount of adhesive onto the top substrate, the end effector configured to place the top substrate into a position of engagement with the adhesive application valve, and place the top substrate onto the bottom substrate to facilitate initial contact between the adhesive applied to the top substrate and a fill material applied to the bottom substrate is also provided. A method of optical bonding is further provided.

Abstract: A collaborative robot employs low ratio drives for three or more axes of movement, such as three primary axes. An arm assembly may be mounted to a support for movement along a vertical linear axis, and the arm assembly may include first and second arm links that are each rotatable about vertical axes, e.g., such that the arm links move in a horizontal plane. Low ratio drives may be used for movement along the vertical linear axis and the rotary axes for the first and second arm links. Feedforward and feedback control may be employed to control the movement of the arm assembly and arm links, and feedback torque components may be limited to 25% or less of the maximum drive torque.

Abstract: Embodiments include a clamping apparatus comprising a pair of adjustable anvils configured to apply a clamping pressure on a workpiece secured between the anvils; a center gear comprising a pair of anvil holders respectively coupled to the pair of anvils; an open center configured to receive the workpiece, the anvils being positioned within said open center; and a pair of outer gears arranged on either side of the center gear, the outer gears being configured to rotate about the open center. Rotation of the outer gears causes a linear movement of the anvils along an axis perpendicular to workpiece. Embodiments also includes a clamping system comprising the clamping apparatus, as well as a positioning device for driving the center gear based on a positioning input and a clamping device for driving the outer gears based on a clamping input.

Abstract: A storage and retrieval system is provided. The storage and retrieval system having a frame and a shuttle movable within the frame, the shuttle having a carriage extending at least partially between a top and bottom of the frame. At least one tension member extends between a first and second ends of the frame and is coupled to the shuttle. At least one drive member extends between the first and second ends of the frame and is coupled to the shuttle. The at least one drive member and the at least one tension member project from opposite sides of the shuttle towards respective first and second ends of the frame and effect stabilization of the carriage against at least rotation relative to the frame. The at least one tension member crosses the at least one drive member and the at least one drive member effects movement of the shuttle.

Abstract: A fluid measurement device and methods of manufacturing and using the same are disclosed. The fluid measurement device includes a conduit configured to transport a fluid, a conductivity sensor in the conduit, and a voltage sensor in the conduit and having first and second rings, probes, or plates. The conductivity sensor is configured to determine the conductivity of the fluid. The voltage sensor is configured to receive a first voltage on the first ring, probe, or plate and detect a capacitance or a second voltage on the second ring, probe, or plate. A value of the capacitance or second voltage corresponds to the amount of fluid in the voltage sensor. The total amount of fluid through the conduit may be determined from amount of fluid in the voltage sensor, the fluid flow rate, the fluid velocity, and the number of samples or the sampling rate.

Abstract: A modular cluster tool is disclosed. According to one embodiment, a system, comprises a wafer transfer station that includes a first vacuum chamber that stores a plurality of semiconductor wafers. The system also includes an equipment front end module interface, and two or more shuttle lock interfaces.

Abstract: An automated bonding sequence system and method for customizing a bonding sequence is provided. The method includes the steps of detecting that a first substrate is in close proximity with the a second substrate, during an optical bonding operation, wherein at least the first substrate includes an amount of adhesive for optically bonding to the second substrate, stopping an automated process of optically bonding of the optical bonding operation, in response to the detecting, recording operator feedback control signals, the operator feedback control signals being received from a controller being operated by an operator to contact the first substrate and the second substrate, analyzing the operator feedback control signals to determine a bonding sequence for automatically optically bonding the first substrate and the second substrate, and resuming, by the processor, the automated process of the optical bonding operation.

Abstract: In accordance with an embodiment of the invention, there is provided a system for cooling a load.

Abstract: A collaborative robot employs low ratio drives for three or more axes of movement, such as three primary axes. An arm assembly may be mounted to a support for movement along a vertical linear axis, and the arm assembly may include first and second arm links that are each rotatable about vertical axes, e.g., such that the arm links move in a horizontal plane. Low ratio drives may be used for movement along the vertical linear axis and the rotary axes for the first and second arm links. Feedforward and feedback control may be employed to control the movement of the arm assembly and arm links, and feedback torque components may be limited to 25% or less of the maximum drive torque.

Abstract: A collaborative robot employs low ratio drives for three or more axes of movement, such as three primary axes. An arm assembly may be mounted to a support for movement along a vertical linear axis, and the arm assembly may include first and second arm links that are each rotatable about vertical axes, e.g., such that the arm links move in a horizontal plane. Low ratio drives may be used for movement along the vertical linear axis and the rotary axes for the first and second arm links. Feedforward and feedback control may be employed to control the movement of the arm assembly and arm links, and feedback torque components may be limited to 25% or less of the maximum drive torque.

Abstract: An audio/video (A/V) hub that determines an environment of a portable electronic device is described. In particular, the A/V hub may identify the environment based on performance information about communication between the portable electronic device and receiver devices (which was received from the receiver devices), and a history of behavior of an individual associated with the portable electronic device and the A/V hub. Alternatively, the A/V hub may identify the environment based on performance information about communication between the portable electronic device and the A/V hub and the portable electronic device and another A/V hub (which was received from the portable electronic device and/or the other A/V hub), and a history of behavior of an individual associated with the portable electronic device and the A/V hub. Based on the determination, the A/V hub provides an instruction to power on an A/V display device in the environment.

Abstract: An audio/video (A/V) hub that identifies A/V content is described. In particular, A/V hub may identify the A/V content based on an image associated with the A/V content in a user interface that was selected by a user. For example, the user interface may include, at different locations, images (such as thumbnail images) that are associated with different A/V content. When the user selects the A/V content associated with one of the images, the A/V hub may request the A/V content from a content provider. However, while the A/V content is indirectly requested based on the location (i.e., based on the user's actions or user-interface activity), the specific A/V content may be unknown to A/V hub. Consequently, the A/V hub may identify the A/V content by performing image analysis on the image based on predefined available A/V content from the content provider.

Abstract: In response to identifying a type of change in audio/video (A/V) content that was received from a content source, an A/V hub may generate display instructions specifying a display layout of the A/V content on a display in an A/V display device, and may provide the display instructions and the A/V content to the display to dynamically modify the display of the A/V content. For example, the A/V hub may display the A/V content in a central window of the display. This may involve swapping the A/V content with other A/V content that was previously displayed in the central window, and the other A/V content may be displayed in a tiled window (which may be smaller than the central window and may be located proximate to a periphery of the display). Alternatively, the A/V hub may display the A/V content in a new tiled window of the display.

Abstract: The present disclosure envisages a system and method for self-calibration of an actuator. The system comprises a pressure spike sensing and control circuit, a travel limit setting circuit and a profile generation circuit. The pressure spike sensing and control circuit is configured to check and set an operating pressure of the actuator. The travel limit setting circuit is configured to check and set the travel limit of the actuator. The profile generation circuit is configured to generate the profiles of a set of parameters of the actuator.