Abstract: In one embodiment, a lidar system includes a light source configured to emit optical pulses using multiple pulse intervals (PIs) that include a first PI and a second PI, where the first PI and the second PI are not equal. The lidar system also includes a receiver configured to detect multiple input optical pulses. The lidar system further includes a processor configured to generate multiple pixels, where each pixel of the multiple pixels corresponds to one of the multiple input optical pulses and is associated with one of the PIs. The processor is further configured to (i) determine, for a particular pixel of the multiple pixels, a group of nearby pixels and (ii) determine whether the particular pixel is range-wrapped based at least in part on the PI associated with each pixel of the group of nearby pixels.

Abstract: Provided herein are 4-aminoisoindoline-1,3-dione compounds having the following structure: wherein R, Ring A, and n are as defined herein, compositions comprising an effective amount of a 4-aminoisoindoline-1,3-dione compound, and methods for treating or preventing disorders.

Abstract: Disclosed is a method of providing DOP forecasts for LEO navigation for routing of vehicles, aircraft, alerting humans in vehicles, or wireless devices, and bandwidth forecasts for LEO communications. The method includes accessing a 3D map of an area including structure solids and generating cuboids in spaces not contained in the structure solids; and iteratively over time increments, calculating LEO satellites visible from the cuboids using the map and, using at least the calculated visibility, determining forecasts for the cuboids at the time increments. Also included is compressing the determined forecast spatially and temporally; and distributing the compressed DOP forecast via a CDN, responsive to queries from requestors. Systems of the requestors can take into account the forecast for routing vehicles or alerting humans in vehicles to a predicted navigation impairment. Risk analysis is applied to improving computation and distribution of forecasts. Forecasts are applied to satellite deployment.

Abstract: Disclosed is a method of providing DOP forecasts for LEO navigation for routing of vehicles, aircraft, alerting humans in vehicles, or wireless devices, and bandwidth forecasts for LEO communications. The method includes accessing a 3D map of an area including structure solids and generating cuboids in spaces not contained in the structure solids; and iteratively over time increments, calculating LEO satellites visible from the cuboids using the map and, using at least the calculated visibility, determining forecasts for the cuboids at the time increments. Also included is compressing the determined forecast spatially and temporally; and distributing the compressed DOP forecast via a CDN, responsive to queries from requestors. Systems of the requestors can take into account the forecast for routing vehicles or alerting humans in vehicles to a predicted navigation impairment. Risk analysis is applied to improving computation and distribution of forecasts. Forecasts are applied to satellite deployment.

Abstract: The present disclosure provides methods of inhibiting cell proliferation signaling in a cell. The present disclosure further provides compositions for inhibiting cell proliferation signaling in a cell. The methods and compounds have a range of utilities as therapeutics, diagnostics, and research tools.

Abstract: An access control system is provided to prevent the surreptitious granting of access to privacy related functionality on an electronic device. Software-based events to grant access to device functionality can be validated by confirming that the software event corresponds with a hardware input event. This validation prevents the spoofing of a user interface input that may be used to fraudulently grant access to specific functionality.

Abstract: In one embodiment, a lidar system includes a light source, a receiver, and a controller. The light source is configured to emit an optical signal. The receiver is configured to detect a received optical signal that includes a portion of the emitted optical signal that is scattered by a surface of a target located a distance from the lidar system, where the surface is oriented at an angle of incidence with respect to the emitted optical signal. The receiver is further configured to produce an electrical signal corresponding to the received optical signal. The controller is configured to determine, based on the electrical signal, the angle of incidence of the surface of the target.

Abstract: A guide structure (10) is configured for placement on a patient's skin and holding a medical probe (61) for adjustable positioning over the patient's skin during vascular line placement. A preferred guide structure includes a U-shaped base (12) having two arms (14, 16) separated by an open space (18). A carriage (50) for a medical probe holder (60) is movable along carriage guide surfaces (40, 42) of the arms of the base and thereby forms a movable bridge spanning the open space. The medical probe holder carrying a medical probe is movable in a direction transverse to the arms of the base to set the medical probe to a desired distance into the open space. A carriage translation actuator (62) operatively associated with the carriage enables movement of the carriage and thereby adjusts the position of the medical probe over the surface of the patient's skin.

Abstract: In one embodiment, a lidar system includes a light source configured to emit optical pulses using multiple pulse intervals (PIs) that include a first PI and a second PI, where the first PI and the second PI are not equal. The lidar system also includes a receiver configured to detect multiple input optical pulses. The lidar system further includes a processor configured to generate multiple pixels, where each pixel of the multiple pixels corresponds to one of the multiple input optical pulses and is associated with one of the PIs. The processor is further configured to (i) determine, for a particular pixel of the multiple pixels, a group of nearby pixels and (ii) determine whether the particular pixel is range-wrapped based at least in part on the PI associated with each pixel of the group of nearby pixels.

Abstract: A harvester includes a main frame supported on a ground surface for transport along the ground surface, an inlet for receiving a crop, and a separator for separating the crop into a first portion and a second portion. The separator includes a hood having an outlet, and a fan operable to generate an airflow through the outlet. The hood of the separator is movable relative to the main frame between a transport position and a harvest position. In the transport position, the hood is positioned at a first height above the ground surface. In the harvest position, the hood is positioned at a second height, greater than the first height, above the ground surface.

Abstract: An aircraft lifting assembly includes a jack, a load cell, and a jack adapter. The jack includes an extendable arm having a distal end portion for exerting a force to lift an object. The distal end portion defines a cavity. The jack adapter couples the extendable arm to the load cell and includes a base portion, a cradle portion, and a projection. The base portion defines a jack arm support surface and a load cell support surface. The jack arm support surface opposes the distal end portion of the extendable arm and the load cell support surface opposes the load cell. The cradle portion extends from the base portion to circumscribe a portion of the load cell to secure the jack adapter to the load cell. The projection extends from the base portion into the cavity to secure the jack adapter to the extendable arm of the jack.

Abstract: An access control system is provided to prevent the surreptitious granting of access to privacy related functionality on an electronic device. Software-based events to grant access to device functionality can be validated by confirming that the software event corresponds with a hardware input event. This validation prevents the spoofing of a user interface input that may be used to fraudulently grant access to specific functionality.

Abstract: Devices and methods are provided herein for monitoring tissue condition. A device as described herein may comprise a base layer configured to attach or encompass a portion of the subject's body in proximity to the target site; a plurality of light emitting diodes (LEDs) coupled to the base layer corresponding to one or more predetermined locations on the portion of the subject's body, wherein the plurality of LEDs is configured to emit light signals at the one or more predetermined locations penetrating beneath the skin of the subject to the target site; and a plurality of photodiodes configured to receive reflected light signals associated with the target site, wherein the reflected light signals are analyzed to determine a plurality of physiological parameters comprising at least volumetric blood flow through, at, or in proximity to the target site, and wherein the plurality of physiological parameters is used to monitor a state of the target site.

Abstract: The disclosed systems and methods may include a network device for evaluating, developing, and benchmarking a precision time protocol network. Additionally, the disclosed systems and methods may be directed to utilizing direct server return for content delivery network traffic. The disclosed apparatus may include a grommet and a clip, where the grommet includes an opening shaped to hold at least one cable such as a medusa cable and a groove around an outer diameter of the grommet. The disclosed apparatuses, systems, and methods may include an apparatus for organizationally distributing cables to rackmount network devices. Various other methods, systems, and computer-readable media are also disclosed.

Abstract: Prosthetic augments to improve muscle mechanics are disclosed herein. A prosthetic augment of the present disclosure includes an augment member configured to engage a bone, the augment member having a first face adapted for contacting the bone; and a second face adapted for contacting an underside of a muscle, wherein at least a portion of the second face includes a bulbous surface adapted to alter a wrapping angle of the muscle around the bone, wherein a first thickness is defined between the first face and the second face at a first position on the augment member, wherein a second thickness is defined between the first face and the bulbous surface of the second face, and wherein the first thickness and the second thickness are not equivalent so as to result in the augment member having a non-uniform thickness.

Abstract: Clock generation for capturing a repetitive signal relative to a clock includes clock circuitry to provide a clock with active and inactive clock edges within a clock period, and signal capture circuitry to capture repetitive signal transitions at an active clock edge, based on pre-defined setup and hold times which determine a setup/hold window. Clock phase adjustment circuitry is configured to adjust clock phase so that the repetitive signal transitions occur within a signal capture window between setup/hold windows. Clock phase adjustment can be based on: aligning the clock inactive edges to the repetitive signal transitions; and/or averaging successive phase comparisons of the clock and the repetitive signal transitions; and/or selectively performing an initial polarity inversion to generate a polarity inverted clock, and then adjusting clock phase of the polarity inverted clock. An example implementation is JESD204B (subclass1) to adjust DEVCLK phase relative to a SYSREF timing reference control signal.

Abstract: A harvester includes a main frame supported on a ground surface for transport along the ground surface, an inlet for receiving a crop, and a separator for separating the crop into a first portion and a second portion. The separator includes a hood having an outlet, and a fan operable to generate an airflow through the outlet. The hood of the separator is movable relative to the main frame between a transport position and a harvest position. In the transport position, the hood is positioned at a first height above the ground surface. In the harvest position, the hood is positioned at a second height, greater than the first height, above the ground surface.

Abstract: In one embodiment, a method includes emitting, by a light source of a lidar system, multiple optical pulses using multiple alternating pulse repetition intervals (PRIs) that include a first PRI and a second PRI, where the first PRI and the second PRI are not equal. The method also includes detecting, by a receiver of the lidar system, multiple input optical pulses and generating, by a processor of the lidar system, multiple pixels. Each pixel of the multiple pixels corresponds to one of the input optical pulses, and each pixel includes a PRI associated with a most recently emitted optical pulse of the multiple optical pulses. The method also includes determining a group of neighboring pixels for a particular pixel of the multiple pixels and determining whether the particular pixel is range-wrapped based at least in part on the PRI associated with each pixel of the group of neighboring pixels.

Abstract: A device comprising: a plurality of gold nanoparticles coupled with an intertwined ZnO nanorods network, wherein the device is configured for detecting light in the visible wavelength.