Abstract: The present invention is directed to the processing of medical image data in a network environment as a network service. In an embodiment of the invention, a network image fusion service is provided that is configured to receive a plurality of image data and to execute at least one image fusion processes in both software and hardware. The image fusion process logic has been divided between instructions to be executed in software and logic to be executed in hardware. The software instructions may be executed by a processor within the network element or in a processor associated with network service. The hardware logic is executed in a reconfigurable programmable logic device such as a Field Programmable Gate Array (FPGA). The network service may be included within the network element, be separate from a network element but associated therewith, or may be external to the network and accessible by a plurality of network elements.

Abstract: A method and apparatus for monitoring the transportation of medical images on a communication network includes a medical image transport service (MITS) that may be used to notify clients of the status of scheduled requests. The MITS may be configured to provide numerous notifications, such as the scheduled time for delivery, changes in scheduled time for delivery, delays associated with delivery at the scheduled time, and likely resolutions to network or other delays attendant to the requested transaction. The notifications may be sent in-band on the network or out-of-band on a parallel network. Where the notification relates to a delayed transaction, the notification message may contain the reason for the delay, the source of the delay, its location, and if other images can still be retrieved. The notification may also include a likely resolution of the problem and an estimate of when the problem will be resolved.

Abstract: A method and apparatus for facilitating the transportation of medical images on a communication network includes a medical image transport service (MITS) that may be used to set policy associated with the delivery of medical images on the network. The MITS may be configured to schedule transactions in an equitable manner taking into account the relative priority of the various contending medical image transactions and mediate delivery of images associated with the transactions. The MITS may include a data management service configured to interact with clients to handle transfers on the network, and a network resource manager configured to interface with network devices performing the transport services to enable network resources such as routes, paths, and bandwidth, to be reserved on the network. An administration client enables policy to be set on the MITS to enable operation of the transport service to be controlled.

Abstract: A check valve includes a valve housing and at least one control member. The valve housing includes a sidewall and an opening extending therethrough. The sidewall defines the opening and includes at least one recess formed therein. Each control member is rotatably coupled to the valve housing within the sidewall recess, and each control member is configured to allow flow of fluid through the valve opening in a first direction. Each control member is further configured to substantially prevent flow of fluid through the valve opening in a second direction that is opposite the first direction.

Abstract: A system, device, and method for managing communication services in an optical communication system utilizes a optical service agent (OSA) that operates within the domain of the network user and manages various communication services on behalf of the network user. The OSA interacts with the optical communication network to obtain various communication services and manages those communication services for the network user based upon predetermined parameters defined by the network user. An authenticated auto-discovery mechanism is used to automatically identify and authenticate OSA-enabled users and to distribute information between peer OSA-enabled users. A peer-to-peer signaling mechanism is used to extend OSA functionality to OSA-enabled users that do not interface directly with the optical communication network.

Abstract: A check valve includes a valve housing and at least one control member. The valve housing includes a sidewall and an opening extending therethrough. The sidewall defines the opening and includes at least one recess formed therein. Each control member is rotatably coupled to the valve housing within the sidewall recess, and each control member is configured to allow flow of fluid through the valve opening in a first direction. Each control member is further configured to substantially prevent flow of fluid through the valve opening in a second direction that is opposite the first direction.

Abstract: A method for improving modal bandwidth in computer networks using multimode optical fiber and laser sources is disclosed in which an annular beam is generate by the laser source, thus preventing center fiber transmission modes from reaching the detector. This prevents or lessens a pulse-splitting effect at the detector. The annular beam is generated preferably by configuring a vertical cavity surface emitting laser to have a center totally-reflecting block of 5-7 microns to generate a substantially dark-centered beam.

Abstract: A system and apparatus for photonic switching combines photonic add/drop multiplexing capabilities with photonic cross-connect switching capabilities. The photonic switch is coupled to a number of incoming fibers and to a number of outgoing fibers. Each incoming fiber is fed into a demultiplexer that demultiplexes the incoming optical signal into its component optical data streams. The demultiplexed optical data streams from each incoming fiber are fed into a corresponding drop-only fabric, which, for each demultiplexed optical data stream, either drops or passes the optical data stream. The passed optical data streams from the various drop-only fabrics are fed into a number of input ports of a photonic cross-connect switch. The photonic cross-connect switch switches each optical data stream from an input port to an output port. The signals from a number of output ports are combined to form an outgoing optical signal, which is sent over an outgoing fiber.

Abstract: A method and apparatus for coupling a plurality of local nodes to a wavelength division multiplexed network. Each local node is connected to an I/O port of an optical cross-connect. Other I/O ports of the optical cross-connect are connected to a wavelength division multiplexer/demultiplexer for coupling the optical cross-connect to a fiber ring network. Additionally, one or more optical-to-tunable-optical converters are connected to ports of the optical cross-connect to transmit data from the local nodes to the WDM mux/demux at a specified wavelength for uplinking onto the fiber ring network.

Abstract: A system, device, and method for producing optical data streams in an optical communication network uses M fixed wavelength lasers and N external modulators (N<M). The M fixed wavelength lasers are coupled to the N external modulators through a photonic cross-connect switch that is capable of routing the outputs of any N of the M fixed wavelength lasers to the N external modulators. The photonic cross-connect switch is configured to route N optical carriers at N specific wavelengths to the N external modulators. N data signals are fed to the N external modulators for producing N optical data streams at the N specific wavelengths. The photonic cross-connect switch maintains the polarity of the N optical carriers that are routed to the N external modulators.

Abstract: A method of improving modal bandwidth in computer networks using multimode optical fiber and single mode sources is disclosed in which the optical signal from a center of the optical fiber is prevented from reaching the detector. This is accomplished according to a number of different techniques including the use of opaque spots on the fiber media/fiber couplers or the use of dark-cored fiber couplers. These configurations prevent pulse splitting that occurs in single mode source/multimode fiber systems by preventing light from the multimode fiber's center from interfering with the detector. When this is achieved, the detector is insulated from the effects of pulse splitting, supporting increased data rates by increasing the modal bandwidth.

Abstract: A method for improving modal bandwidth in computer networks using multimode optical fiber and single mode sources is disclosed in which the optical signal from a center of the optical fiber is blocked from reaching detector. This is accomplished according to a number of different techniques including the use of opaque spots on the fiber media/fiber couplers or the use of dark-cored fiber couplers. These configurations prevent pulse splitting that occurs in single mode source/multimode fiber systems by preventing light from the multimode fiber's center from interfering with the detector. When this is achieved, the detector is insulated from the effects of any pulse splitting, supporting data rates of greater than one GBPS by increasing the modal bandwidth.

Abstract: Input values are data encoded for improved signal characteristics (e.g., limited maximum run length and limited cumulative DC-offset) so as to form "data codewords," and then a number of the data codewords, collectively referred to as a block, are error protection encoded, preferably using a conventional linear and systematic forward error control ("FEC") code, to yield an FEC code block. Preferably, an FEC code block is formed by generating a number of check bits or FEC bits equal to the number of data codewords in the block, and then concatenating one FEC bit and its binary complement with each data codeword, so that one FEC bit and its complement is interposed between each successive codeword.

Abstract: Input values are data encoded for improved signal characteristics (e.g., limited maximum run length and limited cumulative DC-offset) so as to form "data codewords, " and then a number of the data codewords, collectively referred to as a block, are error protection encoded, preferably using a conventional linear and sytematic forward error control ("FEC") code, to yield an FEC code block. Preferably, an FEC code block is formed by generating a number of check bits or FEC bits equal to the number of data codewords in the block, and then concatenating one FEC bit and its binary complement with each data codeword, so that one FEC bit and its complement is interposed between each successive codeword.

Abstract: A fiber-optic communication system (10) employs a Fabry-Perot laser (14) that launches its output onto a single-mode pigtail (16) physically coupled to a mode scrambler (22), which is air coupled to a transmission medium consisting of multi-mode fiber-optic cable. Because the mode scrambler (22) divides the laser output power among many modes, the fraction of any reflected light that is coupled back into the cavity of the laser (14) can be made small enough to permit sufficient laser coherence for high-data-rate-transmission.