Abstract: A system and method for providing adaptive threshold selection for detecting a signal in the presence of interference or noise. The system and method thus enables a node, such as a mobile user terminal, in an ad-hoc communications network to reduce the number of false alarms it experiences in the detection of communications signals due to, for example, sudden noise bursts or reception of a high powered signal that overloads the automatic gain control (AGC) device of the receiver in the node. The system and method employ two correlation circuits which correlate the received signal with two reference sequences and output a correlated signal, a threshold generating circuit which generates a threshold value based on the estimation of the variance of the output of the first correlation circuit, and a comparison circuit which compares the correlated signal to the threshold value to determine whether the received signal includes a valid data signal, as opposed to only noise.
Abstract: A system and method for providing secure communication between nodes (102, 106, 107) in a wireless multihopping communication network (100). The system and method achieve secure communication in a multihopping wireless network (100) by, for example, providing a transport medium for transmission of multihopping authentication messages (400) by the infrastructure devices, such as intelligent access points (106) or wireless routers (107), and user devices, such as mobile nodes (102). The authentication messages (400) are used to verify the identity of a node (102, 107) to thus permit the node (102, 107) to communicate within the network (100). The system and method further use, for example, encryption techniques for protecting the content data packet (1000) traffic being transmitted the nodes (102, 106, 107) within the wireless network (100).
Abstract: A system and method for controlling the dissemination of Routing packets, and decreasing the latency in finding routes between nodes. The system and method provides message exchanges between wireless devices to determine optimized communication routes with a minimum of overhead messages and buffered data. Exchanged messages are reduced to a specific series of exchanges indicating destination, destination node detection, and route, preferably using a series of IAP devices. Routes are discovered in an efficient manner and latency in finding routes between nodes is reduced, thereby reducing buffered information levels at individual devices.
Abstract: A system and method for enhancing media access control (MAC) address privacy in a multi-hop wireless network, comprising providing at least one node which generates a temporary MAC address for itself for use in the network by at least one other node, and which ensures that the temporary MAC address is unique among other nodes in the network prior to using the temporary MAC address.
Abstract: A system and method for evaluating at least one communication link between a transmitting node and a receiving node in a communications network, such as a wireless ad-hoc communications network in accordance with the 802.11 standard. The system and method perform the operation of assigning respective link quality values to the respective communication links based on a transmit power level (TPL) value at which the respective data packets were transmitted by the transmitting node over the respective links, a received sensitivity (RS) value of the receiving node receiving the data packets, and a receive signal strength indication (RSSI) value provided by the network for each respective link. The system and method can examine a content of a data packet being sent between the two nodes to determine the TPL, and can receive the RSSI value from a physical layer of the communications network.
Type:
Grant
Filed:
March 6, 2002
Date of Patent:
June 6, 2006
Assignee:
MeshNetworks, Inc.
Inventors:
William Vann Hasty, Jr., Peter J. Stanforth
Abstract: A dual mode, dual band wireless communication network (100) and a method for using the same. The wireless communication network (100) includes nodes, such as mobile nodes (102), access points (106) and wireless routers (107), that can communicate wirelessly over two different frequencies, for example, 2.4 GHz and 4.9 GHz, to provide high mobility and high data rate capabilities, and for communication with 802.11 compliant and non-802.11 compliant devices.
Abstract: A system and method for improved Time Of Arrival (TOA) distance measurements between nodes of a wireless ad-hoc network. Specifically, the present invention is a system and method of distance estimation using square-root raised-cosine pulse shaping and chip matched filters on direct sequence spreading waveforms, the multiplication of which produces raised-cosine filtered pulse responses. The responses are used to identify a time when a function is at a maximum, corresponding to the actual signal reception time. The system and method produces a raised-cosine filtered pulse response and an auto-correlation function based on a received signal. A peak value of the auto-correlation function is calculated based on a quadratic approximation, which is corrected using a signal sampling phase offset detected between the raised-cosine filtered pulse response and the calculated peak value. The calculated peak value is then corrected to represent an actual reception time for received signals.
Abstract: A system and method for applying an algorithm to distance measurements between nodes in an ad-hoc communications network. The algorithm is located at an individual node of the ad-hoc network and processes collected data via a multi-path filter to ensure that range measurement data is correct, and if so, include such measurement data in a historical data matrix in which old measurement data is eliminated. During periods where received signals are unable to provide correct distance measurements due to reflections affecting the path between nodes or media absorption or radio energy, distance estimates may be obtained from this accurate historical data.
Abstract: A system and method for decreasing the route convergence time in a wireless communication network, such as a wireless ad-hoc peer-to-peer network, by finding an alternate route if the nodes anticipate weakening or breakage of a route currently in use. The system and method which enables reactive routing protocols to find optimal routes between nodes in these types of networks when those routes cannot otherwise be found in certain conditions. The system and method thus decrease the route convergence time, provide an effective and efficient way to find optimal routes, and improve overall performance of the network with regard to throughput, delay, packet completion rate and other factors.
Abstract: A method and system for routing data in a wireless network (400) that enables all nodes (106, 402, 404, 406, 408) to find routes to each other even if the nodes are incapable of operating as a router to route packets received from other nodes (106, 402, 404, 406, 408). The meshed nodes (106, 402) which are capable of performing packet routing act as proxy nodes for their associated non-meshed nodes (STA 13-STA 15) to route packets from their associated non-meshed nodes (STA 13-STA 15) to destination nodes. Some of the meshed nodes further operate as intelligent access points (106) to provide the non-meshed nodes and other meshed nodes with access to other networks, such as the Internet (402).
Type:
Application
Filed:
September 7, 2005
Publication date:
May 11, 2006
Applicant:
MeshNetworks, Inc.
Inventors:
Avinash Joshi, Surong Zeng, William Hasty, Charles Barker, Robin Roberts, Keith Goldberg
Abstract: A method and system for routing data in a wireless network (400) that enables all nodes (106, 402, 404, 406, 408) to find routes to each other even if the nodes (106, 402, 404, 406, 408) are non-meshed which are incapable of operating as a router to route packets received from other nodes (106, 402, 404, 406, 408), and for associating and reassociating the non-meshed and meshed nodes with other meshed nodes (106, 402, 404, 406, 408). The non-meshed nodes (STA 13-STA 15) request association with one of the meshed nodes (AP5) which are capable of performing packet routing, to request that the meshed node (AP5) with which the non-meshed node (STA 13) is associating operate as a proxy node to route packets between the associated non-meshed node (STA 13) and other meshed or non-meshed nodes (106, 402, 404, 406, 408).
Type:
Application
Filed:
September 7, 2005
Publication date:
May 11, 2006
Applicant:
MeshNetworks, Inc.
Inventors:
Avinash Joshi, Surong Zeng, William Hasty, Charles Barker, Robin Roberts, Keith Goldberg
Abstract: A system and method for providing efficient allocation of slots in a wireless multi-hopping network including a plurality of nodes, the method comprising: providing communications pertaining to the average packet completion rate (PCR) for reception and transmission slots at one or more intermediate nodes from the one or more intermediate nodes to one or more predecessor nodes, so that the one or more predecessor nodes can employ one slot allocation scheme when a congestive condition exists at the one or more intermediate nodes, and so that the one or more predecessor nodes can employ another slot allocation scheme when no congestive condition exists at the one or more intermediate nodes.
Abstract: A system and method for providing security to a wireless network by using a mobile node's location as a parameter for deciding if access is to be given to the node. The system and method employ access points, wireless routers and mobile nodes, each including at least one transceiver adapted to transmit and receive communication signals to and from other wireless routers, mobile nodes and other mobile access points. Each access point is connected to a network management system which allows enhanced network monitoring and control. Each network node includes technology which may determine an absolute node location containing latitude, longitude and altitude of a node, or a relative node location containing the distance and angle between nodes, or a combination of both absolute and relative location data.
Abstract: A system and method for providing a traffic control scheme for QoS provision and congestion control across multiple interfaces of wireless nodes (102, 106 and 107), such as wireless access points (107 and 106), communicating in a wireless multihopping communication network (100). The nodes (102, 106 and 107) can include multiple transceivers. The system and method detects bottleneck interfaces in these nodes (102, 106, 107) to control the traffic along the path of the corresponding traffic flow. Different measurements and cross-layer feedback are used to differentiate the cause of the congestion, such as wireless link quality degradation due to fading or degradation due to congestion in a shared medium. The nodes (102, 106, 107) inform each other on the status of their congestion level. High and low level signaling and interruption mechanisms are used to control the interfaces of the congested node (102, 106 or 107) to adjust traffic flow and alleviate the congestion.
Type:
Application
Filed:
October 27, 2005
Publication date:
April 27, 2006
Applicant:
MeshNetworks, Inc.
Inventors:
Sebnem Ozer, Surong Zeng, Charles Barker
Abstract: A system and method for creating a spectrum agile wireless multi-hopping network, such as a wireless ad-hoc peer-to-peer multi-hopping network. The spectrum agile multi-hopping network that can respond to conditions affecting spectrum, such as FCC rulings or business related agreements on spectrum licensing related to a location or other measurable parameters of the network.
Abstract: A system and method for transmitting data in a wireless network is provided. Routing table information includes a system weight associated with each available node. An optimal node is selected based at least in part on the system weight, quality of service requirements, among other factors associated with each available node. Nodes are preferably selected on a per packet basis.
Abstract: A system and method for allowing network users to securely administer and deploy network nodes (102). These networks (100) may comprise wired and/or wireless connections. Examples would include wired networks (104) with shared infrastructure in an office building, as well as ad-hoc multi-hopping peer-to-peer network applications for the home. The system and method provides a key (130) that allows new nodes (102) and thus new devices (124, 126, 132) to gain access to a network (100) via an existing node (122) of that network (100).
Abstract: A system and method for enabling the coexistence of waveforms that do not comply with IEEE Standard 802.11 in the presence of 802.11 compliant waveforms in a wireless communication network (100), in particular, a wireless multi-hopping ad-hoc peer-to-peer communication network (100). More particularly, the system and method controls 802.11 compliant devices (102, 106, 106) in the communication network to refrain from accessing a transmission medium for a predetermined time so that communication not complying with 802.11 can be performed, such as transmission of signals between devices (102, 106, 107) to perform time-of-flight measurements.
Abstract: A system and method that creates an abstraction of the physical layer of a wireless communication network (100), in particular, a wireless ad-hoc peer-to-peer communication network (100), and that normalizes the feedback from the physical layer to enable multiple types of nodes (102, 106, 107) in the wireless network to operate using a common wireless routing protocol. This routing protocol uses a link quality metric to determine the best route regardless of how it actually chooses the route or disseminates such link quality information. The generalized routing metric can be derived for any node (102, 106, 107), regardless of its relative performance or its media access control (MAC) technology. The system and method also create a transaction summary that can be used for link adaptation and link quality estimation to determine, for example, future data rates, link quality/routing metrics, and transmit powers.
Type:
Application
Filed:
August 10, 2005
Publication date:
February 16, 2006
Applicant:
MeshNetworks, Inc.
Inventors:
Guenael Strutt, Avinash Joshi, William Hasty, Sebnem Ozer, Charles Barker
Abstract: The present invention provides a bandwidth efficient system and method of measuring the range between nodes (102, 106, 107) in a wireless communications network (100) with one-way data transfer, where each node (102, 106, 107) periodically transmits a message that contains information regarding neighboring nodes (102, 106, 107) from which any prior messages have been received by the transmitting node (102, 106, 107). A node (102, 106, 107) receives the messages transmitted from neighboring nodes (102, 106, 107) in the network (100), and records the times of arrival of the received messages. The node (102, 106, 107) receiving those messages can thus determine the respective distances between itself and the neighboring nodes (102, 106, 107) based on the respective time of arrivals of the received messages and the respective information included in the respective messages.
Type:
Application
Filed:
August 5, 2005
Publication date:
February 9, 2006
Applicant:
MeshNetworks, Inc.
Inventors:
Pertti Alapuranen, Eduardo Lorenzo-Luaces, John Belcea