Class / Patent application number | Description | Number of patent applications / Date published |
455130100 | With plural repeater or relay systems | 22 |
20080214107 | Upstream Broad Beam Diversity - A satellite communication system is provided according to one embodiment of the invention. The satellite communication system includes a gateway with first and second antennas. The first antenna receives a signal from a first satellite that includes at least a first signal from a first user. The second antenna receives a second signal from a second satellite, that includes at least a second primary signal from a second user and a version of the first signal. The gateway may include circuitry to isolate the first signal from the second signal. The gateway may also include a combiner configured to combine the first signal from the first satellite and the first signal isolated from the second signal. Various other embodiments are disclosed that isolate a secondary signal received from a satellite and combine the secondary signal with the same signal received from other antennas at the gateway. | 09-04-2008 |
20080233866 | SATELLITE AIDED LOCATION TRACKING AND DATA SERVICES USING GEOSYNCHRONOUS AND LOW EARTH ORBIT SATELLITES - A system and method for satellite aided location tracking and data services using geosynchronous (GEO) and low earth orbit (LEO) satellites. In one embodiment, a mobile terminal is designed for communication with both GEO and LEO satellites. This dual satellite functionality enables the asset tracking service to provide service across international service areas without hardware modification or reconfiguration of the mobile terminal device. | 09-25-2008 |
20080261522 | Multi-Antenna Satellite System With Wireless Interface To Vehicle - A wireless satellite communication device is provided according to one embodiment of the invention. The wireless satellite communication device may include one or more satellite antennas, one or more local antennas and circuitry. A satellite antenna may be configured to communicate with one or more satellites. The local antenna may be configured to communicate with one or more wireless user devices within the vicinity of the wireless satellite communication device. The local antennas may include a local antenna. The circuitry may be coupled with the satellite antenna and the local antenna and may be configured to receive data from the satellite antenna and transmit the data with the local antenna. The wireless satellite communication device may also include a solar panel configured to provide electrical power to at least the satellite antenna, the local antenna, and the circuitry. | 10-23-2008 |
20090004967 | Method and apparatus for mitigating interference from terrestrial broadcasts sharing the same channel with satellite broadcasts using an antenna with posterior sidelobes - An apparatus for simultaneously receiving a first signal from a non-terrestrial source and a second signal from a terrestrial source on the same or overlapping channels using a receive antenna with posteriorly-directed sidelobes is disclosed. The apparatus comprises at least one terrestrial transmitter transmitting information on at least one frequency simultaneously usable by at least one satellite transmitting to a satellite receive antenna having a sensitivity characterizable by a primary sensitive axis directed substantially at satellite. The terrestrial transmitter includes a azimuthal gain characteristic directed substantially away from the Earth's Equator. In an alternative embodiment, the terrestrial transmitter is disposed at a location defining a vector angularly displaced from the primary sensitive axis by an angle of less than 90 degrees. | 01-01-2009 |
20090023385 | METHOD FOR SYNCHRONZING USER SIGNAL TRANSMISSIONS WITHIN A HYBRID COMMUNICATION NETWORK - A method is devoted to synchronizing the transmission of user signals within a single-frequency hybrid network comprising at least one transmission satellite (SAT) and regenerative emitters (E | 01-22-2009 |
20090053995 | INTER-SATELLITE CROSSLINK COMMUNICATIONS SYSTEM, APPARATUS, METHOD AND COMPUTER PROGRAM PRODUCT - A communications system, apparatus, method, and computer program product for inter-satellite and inter-spacecraft crosslinks (ISL) with non-ISL optimized antennas on spacecraft. The system includes a mobile communications platform that includes an ISL antenna configured to transmit information to a target satellite through a non-ISL antenna of the target satellite. The mobile communications platform is configured to relay transmissions through the non-ISL antenna of the target satellite to another communications platform. The mobile communications platform includes a controller configured to determine a location of the mobile platform; determine whether the target satellite is within communications range; and prepare a signal for relayed transmissions through a non-ISL antenna of the target satellite to another communications platform in a signal format that is decipherable by this other communications platform. | 02-26-2009 |
20090088071 | METHOD AND SYSTEM FOR SIGNAL REPEATER WITH GAIN CONTROL AND SPATIAL ISOLATION - A repeater device may be utilized to enable forwarding extreme high frequency (EHF) communication between EHF-enabled wireless devices. The repeater device may utilize spatial isolation to prevent and/or reduce interference between received and transmitted EHF RF signals, wherein reception and/or transmission of EHF RF signals in the repeater device may be performed via narrow beams that may enable minimal interference by transmit EHF RF signals to reception of EHF RF. The repeater device may utilize phased arrays to enable performing beamforming, and signal processing operations, including shift and/or amplitude adjustment, may be performed on signals received and/or transmitted via antenna elements in the phased arrays to enable beamforming during reception and transmission of EHF RF signals. Signal processing operations performed in the repeater device may be modifiable to enable continued spatial isolation between receive and transmit EHF RF signal in the repeater device. | 04-02-2009 |
20090088072 | METHOD AND SYSTEM FOR COMMUNICATING UP TO EXTREME HIGH FREQUENCIES USING A MESH NETWORK OF REPEATERS - A plurality of repeater devices, each of which may enable forwarding extreme high frequency (EHF) communication between EHF-enabled wireless devices, may form a repeater mesh network. One or more routes may be formed within the repeater mesh network to enable forwarding EHF RF signals via the repeater mesh network. Different technique may be utilized, while forming routes within the repeater mesh network, to reduce and/or prevent interference that might be caused by EHF RF signals received and/or transmitted by repeater devices in the routes to other repeater devices in the repeater mesh network. These techniques may comprise frequency shifting, spatial isolation, and/or polarization isolation. Multiple routes may be utilized simultaneously to forward EHF RF communication. The simultaneous use of multiple routes may enable increasing the bandwidth and/or improving reliability of forwarding EHF RF communication within the repeater mesh network. | 04-02-2009 |
20090088073 | METHOD AND SYSTEM FOR UTILIZING EHF REPEATERS AND/OR TRANSCEIVERS FOR DETECTING AND/OR TRACKING AN ENTITY - A plurality of repeater devices may utilize extreme high frequency (EHF) interface to detect and/or track entities that may be located within the plurality of repeater devices. Each of the plurality of repeater devices may transmit EHF signals that may enable identification of the transmitting repeater device. Identification of the transmitting repeater devise may comprise use of unique information and/or transmission parameters. Each of the plurality of repeater devices may determine characteristics of received EHF signals to enable determining presence and/or location of entities within the plurality of repeater devices. These characteristics may comprise identity of transmitting repeater devices, signal power, signal amplitude, delay of signal, and/or reception angle. Non-extremely high frequency (non-EHF) connections may be utilized within the plurality of repeater devices to coordinate and/or update detection and/or tracking of entities within the plurality of repeater devices. | 04-02-2009 |
20090098824 | METHOD AND SYSTEM FOR UTILIZING OUT OF BAND SIGNALING FOR CALIBRATION AND CONFIGURATION OF A MESH NETWORK OF EHF TRANSCEIVERS/REPEATERS - A plurality of repeater devices, each of which may enable forwarding extreme high frequency (EHF) communication between EHF-enabled wireless devices, may form a repeater mesh network. Some or all of the plurality of repeater devices may utilize non-extremely high frequency (non-EHF) control connection in communicating with other repeater devices in the repeater mesh network. The non-EHF control connections may be utilized in establishing, configuring, and/or managing the repeater mesh network. The non-EHF control connections may be also be utilized to enable sending, requesting, and/or receiving periodic and/or dynamic control information. The non-EHF control connections may also be utilized while forming, and/or managing forwarding routes of EHF communication via the repeater mesh network, to enable negotiating and/or setting different isolation techniques among the repeater devices, such as polarization isolation, spatial isolation, and/or use of different frequencies. | 04-16-2009 |
20100029198 | System and method for transmitting and receiving image data - A communication system and method for transmitting and receiving signals is provided. The system and method include a source provider that provides image data, at least one transmitter, at least one satellite, and at least one receiver. The at least one transmitter transmits the image data obtained from the source provider. The at least one satellite is in communication with the at least one transmitter and receives and retransmits the image data. The at least one receiver is in communication with the at least one satellite, wherein the at least one receiver is adapted to receive the retransmitted image data, is mobile, and includes at least one antenna. The at least one antenna includes at least a first antenna that has a horizontal length of less than approximately twelve inches (12 in.). | 02-04-2010 |
20100304669 | SATELLITE AND WIMAX COMMUNICATION SYSTEM AND METHOD - A method for maintaining satellite diversity for a WiMAX system comprising: A. Dividing a set of UTs or users into subsets wherein each set is devised such that the maximal time delay between its members does not exceed the GI length; B. One or more BS's or satellites acquires information or estimation regarding relative delay between subsets; C. A different FFT is performed for each subset, wherein each has its own time alignment; D. Interference reduction means are implemented in the frequency domain between subsets. | 12-02-2010 |
20110256828 | METHOD AND SYSTEM FOR RESPONDER-AWARE RELAY STATION SELECTION IN WIRELESS COMMUNICATION NETWORKS - Responder-aware relay station selection in a wireless communication network is provided. One implementation includes evaluating operational parameters of multiple candidate wireless relay stations, and selecting a wireless relay station among the multiple candidate wireless relay stations based on the evaluation. A wireless communication is transmitted to the selected wireless relay station over a wireless communication medium. | 10-20-2011 |
20120238204 | AIRCRAFT COMMUNICATIONS SYSTEM WITH SATELLITE NETWORK SELECTION CONTROLLER AND ASSOCIATED METHOD - A communications system for an aircraft carrying at least some personnel having personal electronic devices (PEDs) for wireless data communications outside the aircraft includes a satellite-based communications network that includes a plurality of satellites, at least one access point in the aircraft for providing a wireless local area network (WLAN) for data communications with the PEDs, and a satellite transceiver in the aircraft cooperating with the at least one access point for data communications with the satellite-based communications network to the PEDs. At least one network selection controller is for selecting a satellite among the plurality of satellites so that data communications is sent to the PEDs through the satellite transceiver based on a needed channel capacity of the data communications to be sent. | 09-20-2012 |
20150024677 | SYSTEM AND ARCHITECTURE FOR SPACE-BASED AND MOBILE TERRESTRIAL SENSOR VEHICLES, AND END-TO-END NETWORK FOR AGGREGATION AND PROCESSING OF SENSOR DATA - A system is provided for reducing latency data collection from space-based sensor satellites. A mobile vehicle platform includes a sensor module configured to monitor certain conditions, circumstances, environments and situations occurring on or around, or associated with, the Earth, and to generate sensor data resulting from the monitoring. A relay satellite terminal is configured to execute data communications via a communications channel of a first satellite beam, wherein the data communications are configured to relay the sensor data, via satellites, to respective gateways for forwarding to a central processing facility for one or more of aggregation, processing, analysis and dissemination of the data. The relay satellite terminal is further configured to switch the data communications from the communications channel of the first satellite beam to a communications channel of a second satellite beam based on a position of the relay satellite terminal relative to the first and second satellite beams. | 01-22-2015 |
20150147959 | Integrated Resource Planning for Satellite Systems - A system, method, and apparatus for integrated resource planning for satellite systems are disclosed. The method involves obtaining user communication demand for at least one region. The method further involves generating a beam map comprising at least one beam for each of the regions according to the user communication demand. Also, the method involves generating at least one configuration profile for the satellite system by using the beam map. Additionally, the method involves performing a performance analysis by comparing: the user communication demand versus one of the configuration profiles, the user communication demand versus actual communication demand, one of the configuration profiles versus the actual communication demand, and/or one of the configuration profiles versus another one of the configuration profiles. Further, the method optionally involves determining power flux spectral density (PFSD) for the beam frequency spectrum for each of the beams by using at least one of the configuration profiles. | 05-28-2015 |
20150295638 | LOW LATENCY GLOBAL COMMUNICATION THROUGH WIRELESS NETWORKS - Embodiments describe a communication system optimized for low latency and includes one or more high altitude platforms disposed at intervals in data communication with each other forming a communication path and at least two network centers separated from each other by a predetermined distance, where the high altitude platforms receive data signals from the network centers, travel along a communication path between the network centers, forming a data relay and transferring the data signals along the communication path. Additional embodiments may include intervals that are at different altitudes or different distances and/or provide one or more high altitude platforms that comprise at least one of satellites, high altitude balloons, or unmanned aerial vehicles. | 10-15-2015 |
20150318916 | SYSTEM AND ARCHITECTURE FOR SPACE-BASED AND MOBILE TERRESTRIAL SENSOR VEHICLES, AND END-TO-END NETWORK FOR AGGREGATION AND PROCESSING OF SENSOR DATA - A system is provided for reducing latency data collection from space-based sensor satellites. A mobile vehicle platform, configured to travel around the Earth, includes a sensor module and a relay satellite terminal. The sensor module monitors certain conditions, circumstances, environments and/or situations occurring on or around, or associated with, the Earth, and generates sensor data resulting from the monitoring. The relay satellite terminal executes data communications with a first of a plurality of satellites while the mobile vehicle platform is in a first area within a communications range of the first satellite, and, upon moving to a second area within a communications range of a second of the plurality of satellites, the relay satellite terminal switches the data communications to the second satellite. The data communications relay the sensor data, via the satellites, to a central processing facility for aggregation, processing, analysis and/or dissemination of the data. | 11-05-2015 |
20150358861 | SATELLITE COMMUNICATION SYSTEM FOR A CONTINUOUS HIGH-BITRATE ACCESS SERVICE OVER A COVERAGE AREA INCLUDING AT LEAST ONE POLAR REGION - A system comprises a constellation of satellites placed in non-geostationary orbit, user terminals located in a coverage area, and N anchor stations able to ensure bidirectional communications with the user terminals by way of at least one satellite. The system furthermore comprises a network of routers interconnected with one another and to the Worldwide Internet Network, each anchor station is connected to the Worldwide Internet Network by way of a router, and each anchor station comprises a management device for managing the handovers to ensure service continuity for the communications. This management device is able to control the handovers between the successive orbiting satellites progressing over the coverage area, the handovers between anchor stations, or the handovers between simultaneously successive satellites and anchor stations. | 12-10-2015 |
20160073359 | Method and System for Controlling a Communications Carrier's Power Spectral Density (PSD) Using Spread Spectrum for Matched Spectral Allocation - A method of reducing adjacent satellite interference, the method comprising monitoring, by a processor, a power spectral density (PSD) of a signal transmitted by a remote transmitter, determining, by the processor, that the PSD of the signal transmitted by the remote transmitter is above a predetermined level, and reducing the PSD of the signal transmitted by the remote transmitter by adjusting at least one of a spread spectrum spreading factor, a power level, a modulation factor, and a forward error correction (FEC) rate using a modulator while maintaining a constant spectral allocation and center frequency of the signal. | 03-10-2016 |
20160149599 | Communication-Satellite System That Causes Reduced Interference - A system of low-orbiting communication satellites that can share radio spectrum with geostationary satellites and methods mitigating interference to enable sharing are disclosed. In some embodiments, the satellite progressively tilts as it travels along its orbit, or its transmission beams are mechanically or electronically tilted. As a consequence of the tilting, as a satellite approaches the equatorial plane, its transmission beams are aimed more and more toward the equatorial plane, compared to when the satellite is far from the equatorial plane. Using this technique, an angular separation sufficient to prevent interference between the satellite's radio signals and GEO radio signals at all satellite positions is maintained, and, as a result good coverage is provided to all ground locations. | 05-26-2016 |
20220140890 | GEOLOCATION OF RADIO FREQUENCY DEVICES USING SPACEBORNE PHASED ARRAYS - A communication system has a phased antenna array configured to communicate via a plurality of beams with a wireless device, such as user equipment (e.g., a smart phone). The plurality of beams define a field of view of the phased antenna array, the field of view having a plurality of cells and each of the plurality of beams is associated with one of the plurality of cells within the field of view. A processing device detects the wireless device within the field of view and determines a coarse geographic location of the wireless device within the field of view of the wireless device when the wireless device is within the field of view, or within a cell. The system further determines a fine geographic location for the wireless device based on frequency offset (due to Doppler) and signal flight time. | 05-05-2022 |