Abstract: An antenna arrangement, a system, and method are provided for implementing a wireless communication module capable of performing adaptive beam forming, with a small antenna sail area. The antenna has a large horizontal to vertical aspect ratio. The antenna module is designed to include very few, or potentially a single radiating element in the vertical direction, and many elements in the horizontal direction, in order to create narrow beam in the azimuth plane, while maintaining a small sail area. The novel form factor advantageously provides for reduced wind loading, and for less conspicuous installations on buildings or towers, for example. The module is anticipated to find widespread applications in LOS and NLOS backhaul applications, and other wireless links between stationary nodes.

Abstract: Techniques for access point (AP) operation with respect to a client device are described in various implementations. In one example implementation, a method may include receiving, at an AP, a packet from a client device which was previously disconnected from the AP and has re-connected to the access point. The AP may obtain the SNR of the packet and determine whether to remain connected with the client device or re-disconnect the client device based at least in part on the SNR or the packet.

Abstract: Systems, methods and apparatuses are provided for mitigating interference in wireless networks, and particularly in an advanced backhaul wireless network comprising several hubs, each hub serving its own remote backhaul modules (RBMs). Preferred embodiments provide practical power spectrum adaptation methods for the management of interhub interference. These methods are shown to improve the overall network throughput significantly compared to a conventional network with fixed transmit power spectrum. Optionally, joint scheduling and power control are used to optimize the network utility. Also provided are methods which evoke the channel average gains generated by measurements for managed adaptive resource allocation (MARA). The proposed methods are computationally feasible and fast in convergence. They can be implemented in a distributed fashion across all hubs. Some of the proposed methods can be implemented asynchronously at each hub.

Abstract: A system, method, and software are provided for measuring co-channel interference in a wireless network with particular application for management of resource allocation for Non Line of Sight (NLOS) wireless backhaul in MicroCell and PicoCell networks. Given the difficulty of predicting the mutual interference between multiple links, DownLink and UpLink co-channel interference are characterized between each Hub and each Remote Backhaul Module Unit periodically during active service. Beneficially, the co-channel interference metrics are used as the basis for intelligently and adaptively managing network resources to substantially reduce interference and increase the aggregate data capacity of the network e.g. by grouping of interfering and/or non-interfering links, and managing resource block allocations accordingly, i.e.

Abstract: An antenna arrangement, a system, and method are provided for implementing a wireless communication module capable of performing adaptive beam forming, with a small antenna sail area. The antenna has a large horizontal to vertical aspect ratio. The antenna module is designed to include very few, or potentially a single radiating element in the vertical direction, and many elements in the horizontal direction, in order to create narrow beam in the azimuth plane, while maintaining a small sail area. The novel form factor advantageously provides for reduced wind loading, and for less conspicuous installations on buildings or towers, for example. The module is anticipated to find widespread applications in LOS and NLOS backhaul applications, and other wireless links between stationary nodes.

Abstract: A system, apparatus and methods are provided for extra-corporeal blood treatment, and in particular for establishing and maintaining a neck down differential body temperature, while maintaining near normal brain temperatures, to protect the brain from extended or extreme hypothermia or hyperthermia. A blood treatment apparatus and system is provided for differential control of brain temperature and body temperature below the neck. For example, a first bypass circuit with heat exchanger for brain blood circulation maintains a near normal blood temperature, while a second bypass circuit for below the neck blood circulation provides for thermal treatment to induce a temperature differential, e.g. hyperthermia or hypothermia, relative to brain circulation. Such systems and apparatus have application, for example, for diagnostic and therapeutic treatments using hyperthermia, particularly for treatments of extended duration or at elevated temperatures above 42° C.

Abstract: A combiner for use in a diversity radio receiver (FM) which receives a plurality of diversity I and Q modulated signals each carrying I and Q information signals through spatially separated antennas, the received I and Q signal pairs being digitized at a sampling rate T and converted to baseband I and Q signals. Each converted I and Q signal pair represents a diversity I and Q vector which is input to the combiner. A discriminator is provided for each sample stream of diversity I and Q vectors input to the combiner. Each discriminator produces, for each sample, an output discriminated I and Q vector (I?, Q?) having a phase representative of the frequency of the information signal and an amplitude proportional to the power of the information signal.

Abstract: A combiner for use in a spatial diversity radio receiver which receives multiple data signals through spaced apart antennae. The combiner includes a receiving component configured for receiving strength-indicative signals, each strength-indicative signal being indicative of the strength of one of the received data signals, and demodulated data signals. A control signal generating component configured for generating control signals generates control signals responsive to the strength-indicative signals. A combining component configured for combining signals combines, in linear proportions determined by the control signals, those of the demodulated data signals which are both above a predetermined strength threshold level (“combiner threshold”) and differ in strength by less than a predetermined margin of preferably between 3 dB and 12 dB (e.g. 6 dB) to provide a combined output data signal. When more than the margin separates the signal strengths, only the strongest signal is used.

Abstract: This invention relates to communications (radio) receiver circuitry and, in particular, to circuitry for eliminating a varying DC distortion component of a demodulated received information signal such as comprising data packets. This invention uses an adaptive filter, and a corresponding adaptive (equalization) feedback signal, to remove a slow varying (exponential) DC component of the signal. In the decoding circuitry of a receiver the adaptive filter (e.g. an LMS filter) compares the outputs of an integrate and dump component to adapted outputs of a decision component in order to produce an error signal which inherently corresponds to the varying DC component of the symbol stream. This equalizing adaptive error signal is fed back and subtracted from the symbol integral stream to remove the varying DC component therefrom and thereby restore the information packet to a level DC bias condition.

Abstract: A combiner for use in a diversity radio receiver (FM) which receives a plurality of diversity I and Q modulated signals each carrying I and Q information signals through spatially separated antennas, the received I and Q signal pairs being digitized at a sampling rate T and converted to baseband I and Q signals. Each converted I and Q signal pair represents a diversity I and Q vector which is input to the combiner. A discriminator is provided for each sample stream of diversity I and Q vectors input to the combiner. Each discriminator produces, for each sample, an output discriminated I and Q vector (I&Dgr;, Q&Dgr;) having a phase representative of the frequency of the information signal and an amplitude proportional to the power of the information signal.