Abstract: The present invention provides novel systems and methods for processing packages through a delivery network using a hub assist label. Generally described, the hub assist label includes indicia of a sequence of sorting locations that designates the flow of a package through a delivery network.

Abstract: The invention provides a system and method for the autonomous wireless communication between a service provider device and a customer device. The customer device may notify the service provider device whether the customer has work to be performed by the service provider. The service provider device may provide information to the customer about work to be performed by the service provider. In one embodiment, a shipping service is notified autonomously about items that a customer has for pick up and shipment. The shipping service is also capable of wirelessly transferring information to a customer device about items to be delivered to that customer.

Abstract: Systems, methods, apparatus, and computer program products are provided for assigning parameters to a geofenced area. For example, in one embodiment, a geofenced area that (a) corresponds to a geographic area and (b) comprises one or more street segments is defined. Speed parameters can be assigned to the geofenced area. After receiving speed data, it can be determined whether the speed parameters have been exceeded.

Abstract: Systems and methods for reducing problems and disadvantages associated with traditional approaches to cooling information handling resources are provided. A method for cooling information handling resources, may include conveying a flowing fluid proximate to one or more information handling resources such that the flowing fluid is thermally coupled to the one or more information handling resources and heat generated by the one or more information handling resources is transferred to the flowing fluid. The method may also include conveying the flowing fluid to a cooling unit such that heat is transferred from the flowing fluid.

Abstract: A system for manipulating data is provided. Such a system comprises a host system, a discrete portable data acquisition device for collecting the data, at least one of a wireless wide area network (WWAN) data radio, a wireless local area network (WLAN) data radio, and a wireless personal area network (WPAN) data radio operably engaged with the portable data acquisition device and configured to at least one of transmit the data to the host system, communicate with a peripheral device, and receive data, and a memory operably engaged with the portable data acquisition device for storing the data, the memory comprising a FLASH memory module, a DRAM memory module, and an NVDRAM memory module. Associated systems, devices, and methods are also provided.

Abstract: The present invention is generally directed to a tracking and visibility system of a kind that augments aspects of traditional tracking systems by implementing mechanisms for independently detecting and verifying the whereabouts of particular objects moving through a carrier's logistics network. These mechanisms are preferably implemented without having to alter the outward appearance or manner in which such objects would otherwise be shipped. At a high level, the present invention accomplishes this by providing a comprehensive tracking system that includes at least two levels of tracking, one of which involves physically associating a wireless device with an object to be tracked, the wireless device being configured to transmit a signal that can be used to independently detect and verify the location of the particular object as it moves through the carrier's logistics network.

Abstract: Systems, methods, apparatus, and computer program products are provided for assigning parameters to a geographic area, wherein the parameters may be used to associate a speed limit with the geographic area. For example, in one embodiment, a geofenced area that (a) corresponds to a geographic area and (b) comprises one or more street segments is identified. Additionally, speed data associated with one of more of the street segments is received. After receiving the speed data, a speed limit is (a) determined for one or more of the street segments and (b) associated with the geofenced area.

Abstract: Systems, methods, apparatus, and computer program products are provided for assigning parameters to a geographic area to provide more accurate cost and fee estimates associated with a delivery vehicle visit (e.g., a package pickup/delivery) to a location within the geographic area. For example, a geographic area may be defined and information collected that is associated with the geographic area. After defining the geographic area and collecting relevant information, an estimated cost associated with a delivery vehicle visit to a location within the geographic area can be determined, based, for example, at least in part on the information gathered.

Abstract: A routing and scheduling computer system that is adapted to define a plurality of geofenced areas and to monitor vehicle activity within each of those areas (e.g., via telematics sensors mounted on vehicles traveling within the areas). The system may be adapted to use information regarding the monitored vehicle activity to estimate: (1) a first amount of time associated with the delivery of a plurality of parcels to one or more respective locations within a first one of the geofenced areas; and (2) a second amount of time associated with the delivery of a plurality of parcels to one or more respective locations within a second one of the geofenced areas. The system may then route a particular vehicle to make one or more pickups or deliveries within the first or second geographic areas based at least in part on the first and second estimates of time.

Abstract: A computer system that is configured to: (A) define a geofence surrounding a geographic area; (B) gather information associated with the geofenced area; and (C) assign one or more parameters to the geofenced area based on the information gathered, wherein at least one of the assigned parameters is used to monitor the performance of a delivery vehicle driver while the delivery vehicle driver is operating a delivery vehicle within the geofenced area. In particular embodiments, the parameters include a backup limit defining a number of times a delivery vehicle operating within the geofenced area is permitted to back up while operating the delivery vehicle within the geofenced area (e.g., during a particular delivery cycle). In other embodiments, the parameters include a maximum speed limit for the geofenced area. The system may be adapted to automatically generate an alert in response to the delivery vehicle operating outside of the defined parameters.

Abstract: According to various embodiments, a fleet management system is provided for capturing, storing, and analyzing telematics data to improve fleet management operations. The fleet management system may be used, for example, by a shipping entity (e.g., a common carrier) to capture telematics data from a plurality of vehicle sensors located on various delivery vehicles and to analyze the captured telematics data. In particular, various embodiments of the fleet management system are configured to analyze engine idle data in relation to other telematics data in order to identify inefficiencies, safety hazards, and theft hazards in a driver's delivery process. The fleet management system may also be configured to assess various aspects of vehicle performance, such as vehicle travel delays and vehicle speeds.

Abstract: Data collection and evaluation systems that, in various embodiments, include an active RFID tag for collecting, time-stamping, and storing vehicle sensor data. Examples of the type of data collected include door data, ignition data, oil pressure data, temperature data, speed data, global positioning data, and diagnostic and trouble code data. The system further includes an external data acquisition device, such as a mainframe computer system or a hand-held data acquisition device like an iPAQ. The external data acquisition device includes an RFID interrogator for communicating with the RFID tag, which enables the RFID tag to transmit the time-stamped data wirelessly to the external data acquisition device. The ability of the system to automatically collect and transfer data allows for the automation of fleet management processes, vehicle maintenance and repair processes, and certain security features.

Abstract: The invention involves reading RFID transponders affixed to items by rotating the items as they are exposed to an RFID reader as may be incorporated in a normal processing, manufacturing or shipping process such as wrapping items in a protective membrane using a system that includes a commercially-available pallet wrapper adapted to be controlled by computer, and with an RFID transponder reading device mounted to the carriage device of the pallet wrapper. The computer interfaces with a programmable logic controller that controls the pallet wrapper and the RFID reader. The computer causes a predetermined number of wraps of the shipping membrane to be wrapped around a portion of items and the pallet to secure the items to the pallet. The RFID tags on the items on the pallet are read as the items rotate near the fixed RFID reader that is mounted to a carriage holding the shipping membrane.

Abstract: A method of determining a distance to be walked by a delivery vehicle driver including providing a satellite image that has an image of a building to which an item is to be delivered and an image of a street adjacent to the building. The method further includes defining a path, within the image, that corresponds to a path that the delivery vehicle driver will walk when delivering the item to the building. The method also includes the step of determining a length of the path.

Abstract: A system that enables a fleet of vehicles to be maintained is provided. The disclosed system allows a fleet operator to review the history of the vehicles in the fleet along with vehicle sensor data to identify earmarks in the vehicle sensor data that are predictive of faults that the vehicles have experienced. The operator develops statistical algorithms that can detect an earmark in vehicle sensor data. The system then collects vehicle sensor data and applies the statistical algorithms the vehicle data to determine if a potential fault is going to occur in a vehicle. In response to determining that a potential fault is going to occur, the disclosed system automatically alerts the vehicle driver, automatically schedule a maintenance visit, automatically check the fleet inventory for components required for a maintenance visit and order unavailable components, and automatically dispatch the components to the mechanic.

Abstract: The invention is directed to a data collection and evaluation system that includes a telematics device for collecting, time-stamping, and storing vehicle sensor data. Examples of the type of data collected include door data, ignition data, speed data, global positioning data, and diagnostic and trouble code data. The system further includes an external data acquisition device, such as a mainframe computer system or a hand-held computing device like an iPAQ. The external data acquisition device is configured to communicate with the telematics device over a wireless network, which enables the telematics device to transmit the time-stamped data to the external data acquisition device and receive information and instructions from the external data acquisition device.

Abstract: Data collection and evaluation systems that, in various embodiments, include an active RFID tag for collecting, time-stamping, and storing vehicle sensor data. Examples of the type of data collected include door data, ignition data, oil pressure data, temperature data, speed data, global positioning data, and diagnostic and trouble code data. The system further includes an external data acquisition device, such as a mainframe computer system or a hand-held data acquisition device like an iPAQ. The external data acquisition device includes an RFID interrogator for communicating with the RFID tag, which enables the RFID tag to transmit the time-stamped data wirelessly to the external data acquisition device. The ability of the system to automatically collect and transfer data allows for the automation of fleet management processes, vehicle maintenance and repair processes, and certain security features.

Abstract: A method and system for providing improved handling of tractors and trailers (or any powered vehicle and storage devices towed thereby) with a staging area by the automatic locking or unlocking of a trailer door when the trailer leaves or enters the hub, respectively, wherein geofencing and/or Wi-Fi can be used to trigger the automatic locking or unlocking.

Abstract: The invention is directed to a data collection and evaluation system that includes a telematics device for collecting, time-stamping, and storing vehicle sensor data. Examples of the type of data collected include door data, ignition data, speed data, global positioning data, and diagnostic and trouble code data. The system further includes an external data acquisition device, such as a mainframe computer system or a hand-held computing device like an iPAQ. The external data acquisition device is configured to communicate with the telematics device over a wireless network, which enables the telematics device to transmit the time-stamped data to the external data acquisition device and receive information and instructions from the external data acquisition device.

Abstract: The invention is directed to a data collection and evaluation system that includes an active RFID tag for collecting, time-stamping, and storing vehicle sensor data. Examples of the type of data collected include door data, ignition data, oil pressure data, temperature data, speed data, global positioning data, and diagnostic and trouble code data. The system further includes an external data acquisition device, such as a mainframe computer system or a hand-held data acquisition device like an iPAQ. The external data acquisition device includes an RFID interrogator for communicating with the RFID tag, which enables the RFID tag to transmit the time-stamped data wirelessly to the external data acquisition device. The ability of the system to automatically collect and transfer data allows for the automation of fleet management processes, vehicle maintenance and repair processes, and certain security features.