Abstract: Disclosed is a method of managing power consumption of a system with a first device coupled to a communication device of a communication network by way of a first communication link and a second device coupled to the communication device of the communication network by way of a second communication link.

Abstract: Disclosed is a method of managing power consumption of a system with a first device coupled to a communication device of a communication network by way of a first communication link and a second device coupled to the communication device of the communication network by way of a second communication link.

Abstract: A network-centric, power management system and method is disclosed for monitoring and controlling device nodes attached to a network. The monitoring and controlling includes collecting and processing information available on the network about the device nodes and using the collected information to manage power on the device nodes.

Abstract: A network-centric, power management system and method is disclosed for monitoring and controlling device nodes attached to a network. The monitoring and controlling includes collecting and processing information available on the network about the device nodes and using the collected information to manage power on the device nodes.

Abstract: A network-centric, power management system and method is disclosed for monitoring and controlling device nodes attached to a network. The monitoring and controlling includes collecting and processing information available on the network about the device nodes and using the collected information to manage power on the device nodes.

Abstract: A predictive network service provisioning method uses personal schedule information of a user [120] to predict the geographic/network location of the user, the operational context of a user, and/or the computation and communication needs of a user. These predicted user attributes may be used to reduce network latency by prepositioning user data [122] at a location [126] closer to the user, allocating services and/or resources for the user at the predicted location, and/or providing the user with access to the prepositioned personal data files [138] and services when requested by the user.

Abstract: A network-centric, power management system and method is disclosed for monitoring and controlling device nodes attached to a network. The monitoring and controlling includes collecting and processing information available on the network about the device nodes and using the collected information to manage power on the device nodes.

Abstract: A network-centric, power management system and method is disclosed for monitoring and controlling device nodes attached to a network. The monitoring and controlling includes collecting and processing information available on the network about the device nodes and using the collected information to manage power on the device nodes.

Abstract: A network-centric, power management system and method is disclosed for monitoring and controlling device nodes attached to a network. The monitoring and controlling includes collecting and processing information available on the network about the device nodes and using the collected information to manage power on the device nodes.

Abstract: A network-centric, power management system and method is disclosed for monitoring and controlling device nodes attached to a network. The monitoring and controlling includes collecting and processing information available on the network about the device nodes and using the collected information to manage power on the device nodes.

Abstract: A method and system for determining an optimal throughput of a communications channel in a highly mobile wireless environment, which includes selecting power control measures, determining a throughput of the communications channel for each of the selected power control measures using a throughput model of the communications channel and the selected power control measure, wherein the throughput model is based on a probability of a packet error averaged over a packet fade, and wherein the probability of the packet error averaged over the packet fade is a function of the selected power control measure, and determining the optimal throughput as a maximum one of the throughputs determined for each of the selected power control measures.

Abstract: A distributed power control technique for wireless networking efficiently balances communication delay against transmitter power on each wireless link. Packets are transmitted over a wireless link from a transmitter to a receiver using a dynamically controlled transmit power level that is periodically updated at the transmitter. The transmit power is computed from i) an observed noise plus interference value of the wireless link and ii) a parameter that determines a balance between per-packet average delay and per-packet average power. In a preferred implementation, the dynamically controlled transmit power level is computed by minimizing the sum of an average delay cost and an average power cost, weighted by the parameter.

Abstract: A distributed power control technique for wireless networking efficiently balances communication delay against transmitter power on each wireless link. Packets are transmitted over a wireless link from a transmitter to a receiver using a dynamically controlled transmit power level that is periodically updated at the transmitter. The transmit power is computed from i) an observed noise plus interference value of the wireless link and ii) a parameter that determines a balance between per-packet average delay and per-packet average power. In a preferred implementation, the dynamically to controlled transmit power level is computed by minimizing the sum of an average delay cost and an average power cost, weighted by the parameter.

Abstract: An approach for managing data transmissions from multiple sources using a common channel addresses the problem of interference caused by two or more sources transmitting simultaneously. In one embodiment, the communication system provides a state of the channel, for example, an indication of the recent or current channel state such as interference level. Before transmitting, a transmitter station buffers blocks of data and selects a transmission mode for use in transmitting at least one of the buffered data blocks as a function of the buffered data sets and the indication of the recent channel state (interference). More specific embodiments are directed to, among other aspects, use of algorithms for evaluating the channel state and processing the transmissions using various types of transmission modes including, for example, setting the power level, modulation scheme, access point, coding scheme, and combinations of these adjustable parameters.

Abstract: A network-centric, power management system and method is disclosed for monitoring and controlling device nodes attached to a network. The monitoring and controlling includes collecting and processing information available on the network about the device nodes and using the collected information to manage power on the device nodes.

Abstract: A predictive network service provisioning method uses personal schedule information of a user [120] to predict the geographic/network location of the user, the operational context of a user, and/or the computation and communication needs of a user. These predicted user attributes may be used to reduce network latency by prepositioning user data [122] at a location [126] closer to the user, allocating services and/or resources for the user at the predicted location, and/or providing the user with access to the prepositioned personal data files [138] and services when requested by the user.

Abstract: A parallel packet processing queueing architecture and method are described. A packet is divided up into cells. A first or start processor queue is selected for the first cell. The following cells of the packet are then placed in the queues in a predetermined order. An example of a predetermined order is placing the cells in consecutive processor queues modulo (the number of processor queues) after the start processor. Such a predetermined order is illustrated in the context of a per Cell Contiguous Queueing (CCQ) architecture. The architecture provides benefits of alleviating the pre-processing and post-processing buffering burdens and decreasing the amount of information required for reassembly of the packet.

Abstract: A method and system for determining an optimal throughput of a communications channel in a highly mobile wireless environment, which includes selecting power control measures, determining a throughput of the communications channel for each of the selected power control measures using a throughput model of the communications channel and the selected power control measure, wherein the throughput model is based on a probability of a packet error averaged over a packet fade, and wherein the probability of the packet error averaged over the packet fade is a function of the selected power control measure, and determining the optimal throughput as a maximum one of the throughputs determined for each of the selected power control measures.

Abstract: A method and system for ranging an object are disclosed. The method includes illuminating a field of view potentially including the object, synchronously receiving reflected signals from the field of view with and without illumination, capturing first and second images within an array, and generating a subtraction image using the images. One image is captured in the array while the other image is in the array. The first and second images include reflected signals from the field of view with and without illumination, respectively. The array includes first and second groups of lines that are unmasked and masked, respectively. In one exposure, the first group of lines is loaded with the first or second image. The image in the first group of lines is shifted into the second group. In another exposure, the first group of lines is loaded with the other image, which is shifted into the second group.

Abstract: The claimed system measures the relative position of objects with retroreflective surfaces, such as those contained in the taillights of all cars, trucks, and motorcycles. This system comprises an illuminator operating in the visible or near-infrared waveband, one or more imagers, each placed behind an e.g. fixed-focus optical lens and a bandpass filter, and a microprocessor. The microprocessor runs the software that operates the illuminator and the imagers, and processes the data collected from the imagers to produce the ranging information. Each set of ranging data is obtained by recording two images, the first one with the illuminator turned off and the second one with the illuminator turned on, and then subtracting the first image from the second one. The purpose of the subtraction process is to remove all data from the resulting image except for the returns of the retroreflective surfaces.