Abstract: Nonylphenol ethoxylates (NPEs) have been used as surfactants in a wide variety of household products and industrial applications. Despite their effectiveness as surfactants, NPEs can accumulate in the environment and adversely affect aquatic organisms. The dispersants of the present disclosure can be used to disperse oil and/or microbes while avoiding the adverse effects of NPEs. Oil and microbial fouling is of particular concern in refinery cooling towers where the water may be contaminated with oil and microbial growth can cause cooling inefficiencies among other problems. The dispersant may include an oil dispersant comprising a C6-C20 alcohol ethoxylate, a bio-dispersant comprising a copolymer of ethylene oxide and propylene oxide, and 2-butoxyethanol. The oil dispersant, the bio-dispersant, and the 2-butoxyethanol form a dispersant solution, and the solution does not include a nonylphenol ethoxylate.

Abstract: A branded fleet server system includes a pre-assembled third-party computer system integrated into a chassis of the branded fleet server system. The pre-assembled third-party computer system is configured to execute proprietary software that is only licensed for use on branded hardware. A baseboard management controller (BMC) included in the server chassis couples with the pre-assembled computer system via one or more cables coupled to ports of the pre-assembled computer system. The BMC enables remote control of the pre-assembled computer system, such as remote power on and power off. Also the BMC may enable automatic and remote software and/or firmware updates to be performed at the pre-assembled computer system.

Abstract: Techniques are described for enabling users to create reservations for compute capacity at a service provider network intended for use in disaster recovery scenarios. A service provider can use separate geographic areas (sometimes referred to as “regions” or “availability zones”) defined by the service provider network to enable users to share reservations of compute capacity intended for use in disaster recovery scenarios. A disaster recovery launch reservation (DRLR) is a reservation of a given unit of compute capacity that is unique to a source geographic area (that is, a defined area of the service provider network containing computing resource(s) for which a user desires to obtain backup compute capacity) and a destination area (that is, a defined area of the service provider network at which the reserved compute capacity is located), where other users can reserve the compute capacity relative to other source geographic area-to-destination geographic area mappings.

Abstract: A harvesting machine that has a first rotor rotationally coupled to a chassis, a second rotor rotationally coupled to the chassis, and a spine separating the first rotor from the second rotor. Wherein the spine has threshing inserts coupled thereto to facilitate threshing of crop processed by the first and second rotors.

Abstract: Techniques are described herein for tracking an item of interest using a plurality of user equipment that can communicate with a tracking device that is configured to attach to the tracked item. The techniques include: storing a unique tracking device identifier corresponding to a tracking device associated with a first user equipment; receiving a location information of the tracking device from a second user equipment in response to the second user equipment receiving a tracking device signal transmitted by the tracking device, the tracking device signal comprising the location information of the tracking device and the unique tracking device identifier corresponding to the tracking device; authenticating the second user equipment to facilitate communication between the second user equipment and the tracking device; and transmitting the location information of the tracking device to the first user equipment.

Abstract: The disclosed implementations include a method performed by a system on a telecommunications network. The system can store an indication of an association between a user device and a service plan, communicate a message to the user device, and receive an indication that a single-action input was received at the user device on the telecommunications network. The single-action input is in response to the message presented on the user device. In response to receiving the indication, the system can obtain an identifier of the user device to identify the service plan of the user device and determine whether the user device can redeem the third-party service. If the user or user device is eligible, the third-party service is automatically provisioned for the user device.

Abstract: A method includes receiving, at a healthcare platform, account registration information from a user submitted via a mobile application; receiving, at the healthcare platform, an indication of a social media account to link to the user's account; receiving, at a social media interface of the healthcare platform, a message posted by the user via the social media account which includes a command comprising a command identifier; forwarding, based on the presence of the command comprising the command identifier, the command to a command handler of the healthcare platform; retrieving, by the healthcare platform, healthcare information for the user based on the command; and communicating, by the healthcare platform, the retrieved information via text message to a cell phone number associated with the user's account.

Abstract: The disclosed implementations include a method performed by a system on a telecommunications network. The system can store an indication of an association between a user device and a service plan, communicate a message to the user device, and receive an indication that a single-action input was received at the user device on the telecommunications network. The single-action input is in response to the message presented on the user device. In response to receiving the indication, the system can obtain an identifier of the user device to identify the service plan of the user device and determine whether the user device can redeem the third-party service. If the user or user device is eligible, the third-party service is automatically provisioned for the user device.

Abstract: A separator module for an agricultural machine. The separator module includes a feederhouse configured to receive crop from a harvesting platform, a casing enclosing a rotor positioned therein and rotatable relative to the casing for processing crop from the feederhouse, a cover extending between the feederhouse and the casing, and a noise control treatment coupled to the cover.

Abstract: An access door for a combine harvester includes a body having a top, a bottom, a first side, and a second side. The body includes a height defined between the top and the bottom and a width defined between the first side and the second side. A plurality of ribs is integrally formed in the body for adding rigidity thereto, and a deflector is integrally formed with the body and protrudes therefrom. The deflector has a top surface and a width that is substantially the same as the width of the body. The body is defined within a first plane and the top surface is defined within a second plane such that the second plane is disposed at an angle less than 90° from the first plane.

Abstract: Systems and methods for providing incentives to prepaid customers of mobile devices, such as customers of services for mobile devices (e.g., voice, text, and/or data services) provided by a telecommunications carrier, in order to retain these customers, are described. In some embodiments, the systems and methods include a renewal event module that accesses information associated with a renewal event performed by a mobile device customer of a current prepaid service plan, a reward determination module that determines a reward to provide to the mobile device customer in response to the a renewal event performed by the mobile device customer, and a reward provision module that provides the determined reward to the mobile device customer. Further details are described herein.

Abstract: A wideband, radio-frequency localization system may estimate the one-dimensional, two-dimensional or three-dimensional position and trajectory of a static or moving object. These estimates may have a high spatial accuracy and low latency. The localization may be determined based on phase or amplitude of a wideband signal in each frequency band in a set of multiple frequency bands. The localization may be based on a single shot of measurements across a wide band of radio frequencies, without frequency hopping. The measurements of the wideband signal may be taken over time and over space at multiple receivers. The localization may be based on measurements taken while a backscatter node remains in a first reflective state or in a second reflective state, rather than when the backscatter node is transitioning between reflective states. In some cases, the localization achieves sub-centimeter spatial resolution in each of three spatial dimensions.

Abstract: Techniques are disclosed for extending scalable policy management to supporting network devices. A network device comprising a memory and a processor may perform various aspects of the techniques. The memory may be configured to store a policy. The processor may be configured to obtain the policy to be enforced by a supporting network device coupled to a server, and identify a port of the supporting network device to which the server is coupled via the switch fabric. The policy controller may also identify a workload executed by the server to which the policy is associated, and convert the policy into configuration data supported by the network device. The policy controller may further configure, based on the configuration data, the network device to enforce the policy with respect to network traffic received via the identified port.

Abstract: Techniques are described herein for tracking an item of interest using a plurality of user equipment that can communicate with a tracking device that is configured to attach to the tracked item. The techniques include: storing a unique tracking device identifier corresponding to a tracking device associated with a first user equipment; receiving a location information of the tracking device from a second user equipment in response to the second user equipment receiving a tracking device signal transmitted by the tracking device, the tracking device signal comprising the location information of the tracking device and the unique tracking device identifier corresponding to the tracking device; authenticating the second user equipment to facilitate communication between the second user equipment and the tracking device; and transmitting the location information of the tracking device to the first user equipment.

Abstract: The disclosed systems and methods authenticate a user of a telecommunications network for a third-party service provider to seamlessly provision a third-party service. A The telecommunications network receives an indication that a user device on the telecommunications network received an input by a user to access the third-party service. In response, the telecommunications network obtains a network-based identifier (e.g., IP address) that uniquely identifies the user device and associated user, determine that the user is eligible for the third-party service based on the user's subscribed service plan, and communicates information to enable the third-party service provider to automatically provision the third-party service on the user device without needing additional input to activate the third-party service or authenticate the user with the third-party service on the user device.

Abstract: A wideband, radio-frequency localization system may estimate the one-dimensional, two-dimensional or three-dimensional position and trajectory of a static or moving object. These estimates may have a high spatial accuracy and low latency. The localization may be determined based on phase or amplitude of a wideband signal in each frequency band in a set of multiple frequency bands. The localization may be based on a single shot of measurements across a wide band of radio frequencies, without frequency hopping. The measurements of the wideband signal may be taken over time and over space at multiple receivers. The localization may be based on measurements taken while a backscatter node remains in a first reflective state or in a second reflective state, rather than when the backscatter node is transitioning between reflective states. In some cases, the localization achieves sub-centimeter spatial resolution in each of three spatial dimensions.

Abstract: Techniques for private network mirroring are described. Users can select one or more existing private networks to be mirrored in the same or different network area. Any network configuration changes made in the selected private network (e.g., “master” private network) can be propagated automatically to the mirror private network. This enables users to utilize resources in another network area for disaster recovery, ensuring that the network configuration of the mirror private network is consistent with the master private network through real-time updates. Additionally, users managing infrastructure that includes multiple private networks can select one master private network and propagate configuration changes to other private networks, reducing management overhead incurred by these multi-private network installations.

Abstract: A wideband, radio-frequency localization system may estimate the one-dimensional, two-dimensional or three-dimensional position and trajectory of a static or moving object. These estimates may have a high spatial accuracy and low latency. The localization may be determined based on phase or amplitude of a wideband signal in each frequency band in a set of multiple frequency bands. The localization may be based on a single shot of measurements across a wide band of radio frequencies, without frequency hopping. The measurements of the wideband signal may be taken over time and over space at multiple receivers. The localization may be based on measurements taken while a backscatter node remains in a first reflective state or in a second reflective state, rather than when the backscatter node is transitioning between reflective states. In some cases, the localization achieves sub-centimeter spatial resolution in each of three spatial dimensions.

Abstract: A wideband, radio-frequency localization system may estimate the one-dimensional, two-dimensional or three-dimensional position and trajectory of a static or moving object. These estimates may have a high spatial accuracy and low latency. The localization may be determined based on phase or amplitude of a wideband signal in each frequency band in a set of multiple frequency bands. The localization may be based on a single shot of measurements across a wide band of radio frequencies, without frequency hopping. The measurements of the wideband signal may be taken over time and over space at multiple receivers. The localization may be based on measurements taken while a backscatter node remains in a first reflective state or in a second reflective state, rather than when the backscatter node is transitioning between reflective states. In some cases, the localization achieves sub-centimeter spatial resolution in each of three spatial dimensions.