Patent application number | Description | Published |
20080254797 | SEAMLESS AND VERTICAL CALL HANDOFF SOLUTION ARCHITECTURE - A system, method and apparatus for facilitating handoff of communications with a user device between a first communication network having a first domain technology, and a second communication network having a second domain technology different from the first domain technology, the system, method and apparatus includes an anchor point that establishes a first service flow with the first communication network, and a second service flow with the second communication network based upon a triggering event respectively, with the user device, and a handoff device that receives at least one handoff parameter for determining a handoff operation of the user device from the first communication network to the second communication network. | 10-16-2008 |
20080301773 | METHOD AND APPARATUS FOR SECURITY CONFIGURATION AND VERIFICATION OF WIRELESS DEVICES IN A FIXED/MOBILE CONVERGENCE ENVIRONMENT - A system and method is described that enables autonomic discovery of wireless network security mechanisms by mobile devices. Stateful monitoring of wireless devices facilitates identification of pending network connectivity loss, enabling a handoff server to proactively advertise new points of access and their associated security mechanisms to devices before connectivity is lost. As a result, devices may seamlessly transition between secure networks. Stateful monitoring of device reachability may be used together with device certificates and/or tokens to decrease the potential of MAC spoofing and further secure the network. Stateful monitoring of device connectivity status during network transitions facilitates the identification of rogue access points. The token or certificate on the device may be used to authenticate the device while transitioning between networks by a centralized entity, managing the initiation and the execution of the handover for the device. | 12-04-2008 |
20100104279 | METHOD AND SYSTEM FOR CONFIGURING A CONNECTION-ORIENTED PACKET NETWORK OVER A WAVELENGTH DIVISION MULTIPLEXED OPTICAL NETWORK - A network planning tool and method for configuring a connection-oriented packet network over a WDM optical network without an optical control layer, such as a SONET/SDH layer. The optical network includes a plurality of optical fibers interconnected through nodes and the connection-oriented packet network, such an Ethernet network, MPLS network, or pseudowire network, includes two or more terminal devices. The method and tool function by building an association between the components of the physical layer, such as the optical fiber, and their geographic location or path. The connection-oriented packet network is configured by building multi-link trunks (MLTs) between terminal devices, where the MLTs are built by aggregating lightpaths that traverse distinctive geographic paths. The MLTs are planned and configured through aggregating lightpaths that traverse incongruent sets of photonic elements. A predetermined target for resiliency to physical failure events may determine the degree of congruence allowed between the sets of photonic elements associated with lightpaths in the same MLT. | 04-29-2010 |
20110222852 | METHOD AND SYSTEM FOR CONFIGURING A CONNECTION-ORIENTED PACKET NETWORK OVER A WAVELENGTH DIVISION MULTIPLEXED OPTICAL NETWORK - A network planning tool and method for configuring a connection-oriented packet network over a WDM optical network without an optical control layer, such as a SONET/SDH layer. The optical network includes a plurality of optical fibers interconnected through nodes and the connection-oriented packet network, such an Ethernet network, MPLS network, or pseudowire network, includes two or more terminal devices. The method and tool function by building an association between the components of the physical layer, such as the optical fiber, and their geographic location or path. The connection-oriented packet network is configured by building multi-link trunks (MLTs) between terminal devices, where the MLTs are built by aggregating lightpaths that traverse distinctive geographic paths. The MLTs are planned and configured through aggregating lightpaths that traverse incongruent sets of photonic elements. A predetermined target for resiliency to physical failure events may determine the degree of congruence allowed between the sets of photonic elements associated with lightpaths in the same MLT. | 09-15-2011 |
20140161447 | System and Method for an Agile Cloud Radio Access Network - In one embodiment, a cloud radio access network (C-RAN) includes a first plurality of antennas and a first plurality of radio remote units (RRUs) coupled to the plurality of antennas. The C-RAN also includes a first plurality of broadband base units (BBUs) and a first photonic switch optically coupled between the first plurality of RRUs and the first plurality of BBUs. | 06-12-2014 |
20140161450 | System and Method for Accelerating and Decelerating Packets - In one embodiment, a system for accelerating a packet stream includes a first accelerator configured to re-clock the packet stream from a first clock rate to a second clock rate to produce an accelerated packet stream, where the first clock rate is less than the second clock rate, where the packet stream has a first inter-packet gap, where the accelerated packet stream has a second inter-packet gap, and where the second inter-packet gap is greater than the first inter-packet gap. The system also includes a switch coupled to the first accelerator, where the switch is configured to switch the accelerated packet stream at the second clock rate to produce a switched packet stream. | 06-12-2014 |
20140269351 | System and Method for Steering Packet Streams - In one embodiment, a system for steering an input packet stream includes a traffic splitter configured to split an input packet stream into a first packet stream and a second packet stream, and a photonic switching fabric coupled to the traffic splitter, where the photonic switching fabric is configured to switch the first packet stream. The system may also include an electrical packet switching fabric coupled to the traffic splitter, where the electrical packet switching fabric is configured to switch the second packet stream, and a traffic combiner coupled to the photonic switching fabric and to the electrical packet switching fabric, where the traffic combiner is configured to merge the first switched packet stream and the second switched packet stream to produce a first packet flow. | 09-18-2014 |
20140328154 | Method for Crosstalk and Power Optimization in Silicon Photonic Based Switch Matrices - Crosstalk can be suppressed in photonic switching fabrics by activating unused photonic elements in a manner that manipulates the inactive connections and inhibits the propagation of cross-talk over the switching fabric. For example, unused photonic elements can be set to a cross or bar configuration to block first and second order crosstalk from propagating to the output ports, thereby reducing noise in the output signals. All of the unused elements can be activated in order to maximize crosstalk suppression. Alternatively, fewer than all of the unused elements may be activated to achieve a balance between crosstalk suppression and power conservation. Photonic switch architectures can be configured to use pre-determined cross-talk suppression maps (e.g., patterns of activated unused cells) for the various switching configurations, which may be computed using a recursive algorithm. | 11-06-2014 |
20140334819 | System and Method for Photonic Switching - In one embodiment, method of wrapping photonic packets includes receiving, by a node, a first packet and receiving, by the node, a second packet. The method also includes concatenating the first packet and the second packet to produce a concatenated frame, where concatenating the first packet and the second packet includes removing an inter-packet-gap (IPG) between the first packet and the second packet and converting the concatenated frame to a photonic frame, where the concatenated frame is an electrical frame. | 11-13-2014 |
20140334820 | METHOD AND SYSTEM FOR CONFIGURING A CONNECTION-ORIENTED PACKET NETWORK OVER A WAVELENGTH DIVISION MULTIPLEXED OPTICAL NETWORK - A network planning tool and method for configuring a connection-oriented packet network over a WDM optical network without an optical control layer, such as a SONET/SDH layer. The optical network includes a plurality of optical fibers interconnected through nodes and the connection-oriented packet network, such an Ethernet network, MPLS network, or pseudowire network, includes two or more terminal devices. The method and tool function by building an association between the components of the physical layer, such as the optical fiber, and their geographic location or path. The connection-oriented packet network is configured by building multi-link trunks (MLTs) between terminal devices, where the MLTs are built by aggregating lightpaths that traverse distinctive geographic paths. The MLTs are planned and configured through aggregating lightpaths that traverse incongruent sets of photonic elements. A predetermined target for resiliency to physical failure events may determine the degree of congruence allowed between the sets of photonic elements associated with lightpaths in the same MLT. | 11-13-2014 |
20150043905 | System and Method for Photonic Switching and Controlling Photonic Switching in a Data Center - In one embodiment, data center includes a packet switching core and a photonic switch. The photonic switch includes a first plurality of ports optically coupled to the packet switching core and a second plurality of ports configured to be optically coupled to a plurality of peripherals, where the photonic switch is configured to link packets between the plurality of peripherals and the packet switching core. The data center also includes a photonic switch controller coupled to the photonic switch and an operations and management center coupled between the packet switching core and the photonic switch controller. | 02-12-2015 |
20150055951 | Method for Crosstalk and Power Optimization in Silicon Photonic Based Switch Matrices - Recursive optimization algorithms can be used to determine which idle photonic switching elements to configure in N×N switching fabrics to achieve crosstalk suppression. Different algorithms are used to achieve different levels of optimization. Embodiment full optimization techniques may configure all inactive cells to reduce crosstalk, and consequently may provide the best noise performance and highest power usage. Partial optimizations may configure fewer than all inactive cells to reduce crosstalk, and may provide sub-optimal noise performance at lower power usages. Differential partial optimization algorithms configure inactive cells in different stages of a photonic switching fabric. Fewer than all cells in a given stage may be configured by some algorithms. | 02-26-2015 |
20150271576 | Apparatus and Method for Feedback System for Optical Switch Controller - Embodiments are provided herein for an apparatus and method for controlling an integrated photonic switching device on a photonic lightwave circuit (PLC). The apparatus includes the optical switch with a plurality of input optical signal channels and a plurality of output optical signal channels. The apparatus further includes a plurality of photodetectors that are coupled, via corresponding optical taps, to at least one of the input optical signal channels and at least one of the output optical signal channels. Additionally, a passive electrical circuit is electrically coupled to the photodetectors. The circuit is configured to generate an output electrical signal as a function of the at least one of the input optical signal channels and the at least one of the output optical signal channels. The output electrical signal has a substantially lower frequency than the input optical signal channels and the output optical signal channels. | 09-24-2015 |
20150277036 | Apparatus and Method for an Optical Waveguide Edge Coupler for Photonic Integrated Chips - Embodiments are provided for photonic chip waveguides with improved coupling efficiency to optical fibers. In an embodiment, a photonic chip comprises a semiconductor substrate, a dielectric layer on the substrate, and a tapered silicon or semiconductor waveguide embedded in the dielectric layer. The dielectric layer has lower optical refractive index than the tapered waveguide and serves as a cladding for the tapered waveguide. The chip further includes, on the substrate, a dielectric waveguide adjacent to the dielectric layer. The tip of the tapered waveguide is embedded in the dielectric waveguide. The dielectric waveguide serves to couple the tapered waveguide to an optical fiber, enlarge and better confine the light propagation mode from the taper waveguide to the fiber. | 10-01-2015 |
20150286005 | Apparatus and Method for 2x1 MMI with Integrated Photodiode for Off-State Monitoring of 2x1 Optical Switch - Embodiments are provided for an improved 2×1 switch cell design with integrated photodiode for off-state monitoring. In an embodiment, am optical switch comprises a 2×1 multi-mode interferometer (MMI) coupler including two input waveguides jointly coupled to an output waveguide, and a photodetector coupled to an edge of a first waveguide of the input waveguides, and positioned next to a side of the output waveguide. In another embodiment, an optical chip comprises two input waveguides parallel to each other, and an output waveguide coupled to the two input waveguides. The optical chip further includes a photodetector coupled to a first waveguide of the two input waveguides, and positioned next to the output waveguide, and a branch waveguide extending from the first waveguide into the photodetector. | 10-08-2015 |
20150289035 | System and Method for Photonic Switching - In one embodiment, method of photonic packet switching includes receiving, by a photonic switching fabric from a first top-of-rack (TOR) switch, a destination port request corresponding to a first photonic packet and a first period of time, where the destination port request includes a first output port and determining whether the first output port is available during the first period of time. The method also includes receiving, by the photonic switching fabric from the first TOR switch, the first photonic packet and routing the first photonic packet to the first output port when the first output port is available during the first period of time. Additionally, the method includes routing the first photonic packet to an alternative output port when the first output port is not available. | 10-08-2015 |
20150309265 | Apparatus and Methods for Scalable Photonic Packet Architectures Using PIC Switches - Embodiments are provided for scalable photonic packet fabric architectures using photonic integrated circuit switches. The architectures use compact size silicon photonic circuits that can be arranged in a combined centralized and distributed manner. In an embodiment, an optical switch structure comprises a plurality of core photonic based switches and a plurality of photonic interface units (PIUs) optically coupled to the core photonic based switches and to a plurality of groups of top-of-rack switches (TORs). Each PIU comprises a N×N silicon photonic (SiP) switch optically coupled to a group of TORs associated with the PIU from the groups of TORs, where N is a number of the TORs in each group. The PIU also comprises a plurality of 1×P SiP switches coupled to the group of TORs associated with the PIU and to the core photonic based switches, where P is a number of the core photonic based switches. | 10-29-2015 |
20150312659 | System and Method for Photonic Switching - In one embodiment, optical node includes an input port configured to receive an input optical frame and a first optical switch coupled to the input port, where the first optical switch is configured to remove the input optical frame to produce a removed input optical frame when an address of the input optical frame is a node address of the optical node and to pass the input optical frame to a second optical switch when an address of the input optical frame differs from the address of the optical node. The optical node also includes the second optical switch coupled to the first optical switch, where the second optical switch is configured to output the input optical frame to an output port when the address of the input optical frame is not the node address of the optical node and the address of the input optical frame is not an empty address. | 10-29-2015 |