Abstract: A monitoring device with a board case having an open end and a closed end partially defining a lower housing space; a lid connected to the board case at the closed end to define an upper housing space; a power supply within the first housing space; a printed circuit board assembly (PCBA) within the lower housing space and electrically connected through the closed end of the board case to the power supply, the PCBA having a CPU module with computer readable memory; a bracket assembly within the lower housing space; a camera module mechanically fixed to the bracket assembly; and a lens cover at least partially surrounding the camera module. In a network with a plurality of such devices, each device may be configured to communicate directly with each of the other monitoring devices without the use of a centralized server.

Abstract: A monitoring device with a board case having an open end and a closed end partially defining a lower housing space; a lid connected to the board case at the closed end to define an upper housing space; a power supply within the first housing space; a printed circuit board assembly (PCBA) within the lower housing space and electrically connected through the closed end of the board case to the power supply, the PCBA having a CPU module with computer readable memory; a bracket assembly within the lower housing space; a camera module mechanically fixed to the bracket assembly; and a lens cover at least partially surrounding the camera module. In a network with a plurality of such devices, each device may be configured to communicate directly with each of the other monitoring devices without the use of a centralized server.

Abstract: A passive full-duplex bidirectional ZPL tap includes first and second network ports and tap ports. A signal separator is configured to receive a data stream from at least one of the first or second network ports and pass through the data stream and configured to obtain a first signal portion comprising at least the first signal component and obtain a second signal portion comprising at least the second signal component. A DSP stage is configured to substantially remove any second data component from the first signal portion and to substantially remove any first data component from the second signal portion. A first receive only Phy is configured to receive the first signal portion and provide the first signal portion to the first tap port and a second receive only Phy is configured to receive the second signal portion and provide the second signal portion to the second tap port.

Abstract: A receive or listen only Physical Interface Device (Phy). The receive or listen only Phy is configured to have a front end configured to only receive data from a communications network. The receive only Phy may be implemented a part of a tap device including a first network port for receiving a first network signal having a first format; a receive only Phy for converting the first network signal into a second signal format; and a transmit and receive Phy for receiving the first network signal in the second signal format and converting it into the first signal format.

Abstract: The principles of the present invention relate to passive full-duplex bidirectional Zero Packet Loss (ZPL) network taps that include single, dual, or dual differential couplers that are placed in the communication path between two network devices that communicate using a full-duplex bidirectional data stream that include a first and a second data component. The bidirectional couplers are configured to at least partially obtain a second data stream that includes at least the first data component and to obtain a third data stream that includes at least the second data component. In some embodiments, the bidirectional couplers may include a signal separation module or stage that is configured to further separate the first and second data components.

Abstract: A passive full-duplex bidirectional ZPL tap includes first and second network ports and first and second tap ports. A passive signal separator is configured to receive a data stream from at least one of the first or second network port and pass through the data stream and a first signal portion comprising at least the first signal component and a second signal portion comprising at least the second signal component. A first receive only physical interface device (Phy) is configured to receive the first signal portion from the signal separator and provide the first portion to the first tap port and a second receive only Phy is configured to receive the second signal portion from the signal separator and provide the second signal portion to the second tap port.

Abstract: A network tap device array including one or more passive full-duplex bidirectional ZPL network tap devices is disclosed. The array enables data from multiple nodes in a communications network to be tapped and forwarded to a plurality of monitoring devices. In one embodiment the network tap device array includes a chassis that is configured to receive a plurality of passive full-duplex bidirectional ZPL network tap devices. Each passive full-duplex bidirectional ZPL network tap device includes network ports for passing network data via communication cables and tap ports for forwarding the tapped network data to the monitoring device. In another embodiment, a sub-chassis includes a plurality of passive full-duplex bidirectional ZPL network tap devices and an aggregator that aggregates tapped data from each of the tap devices. The aggregator then forwards the aggregated data to the monitoring device. The sub-chassis can be included in a chassis that is configured to receive multiple populated chassis.

Abstract: This disclosure is generally concerned with systems and methods for selectively enabling an electronic device that is configured to communicate with a remote computer. In one example of such a method, identification data is initially transmitted from the electronic device to the remote computer. At the remote computer, a determination is made as to whether the identification data is valid. If the identification data is valid, the remote computer generates encrypted data based upon the valid identification data. The encrypted data is then transmitted to the electronic device, where the encrypted data and the identification data are process to facilitate a determination as to whether operation of the electronic device will be enabled. The scope or extent to which the electronic device can be enabled is defined by predetermined criteria.

Abstract: An optoelectronic transceiver includes a laser transmitter, a photodiode receiver, an optical transmitter, and circuitry. The circuitry includes memory, which includes one or more memory arrays for storing information related to the transceiver. The circuitry also includes analog to digital conversion circuitry for receiving a plurality of analog signals from the laser transmitter and photodiode receiver, converting the received analog signals into digital values, and storing the digital values in predefined locations within the memory. The circuitry further includes a status transmitter for reading from the memory and transmitting via the optical transmitter transceiver status information corresponding to a plurality of the digital values stored in the memory.

Abstract: Methods and devices provide for a dynamic bias voltage control in detector photodiodes. The methods and systems use a bias control loop to make continuous detections of changes in the effective breakdown current of the detector photodiodes, thereby enabling the devices to change the bias voltage as needed. In one embodiment, a sense diode is added and operated at the breakdown current while the detector diode is operated at a small offset from the breakdown current. As performance conditions change, a feedback loop with the sense diode detects changes in the breakdown current and is used to adjust the bias voltage as necessary. In another embodiment, no sense diode is used. Rather, the detector diode itself is maintained at the breakdown current by a low frequency feedback loop. The optical signal is measured by a high frequency filter.

Abstract: This disclosure is generally concerned with optical transceivers. In one example, an optical transceiver implements electronic dispersion compensation in the receive path, as well as optical preemphasis on the transmitted signal in order to improve aspects of optical performance on multimode fiber links, relative to systems that do not implement transmitter preemphasis. Among other things, such optical transceivers can be used to achieve longer link lengths over a given fiber and/or to improve the percentage of fibers that can be used with a given performance electronic dispersion implementation.