Abstract: A system, method, and optical switch for communicating timing. A determination is made whether one of a number of data streams are available. Packets are received at a remote node in response to determining one of the number of data streams is available. A timing characteristic of the at least one of the packets is associated with a tick of a reference clock. The tick of the reference clock is extracted utilizing the timing characteristic of the at least one of the packets. A secondary clock is disciplined with the reference clock by adjusting the secondary clock based on a difference between times measured by the reference clock and the secondary clock to generate a clock signal. The clock signal is communicated to one or more interfaces for distributing.

Abstract: A system, method, and optical switch for communicating timing. A determination is made whether one of a number of data streams are available. Packets are received at a remote node in response to determining one of the number of data streams is available. A timing characteristic of the at least one of the packets is associated with a tick of a reference clock. The tick of the reference clock is extracted utilizing the timing characteristic of the at least one of the packets. A secondary clock is disciplined with the reference clock by adjusting the secondary clock based on a difference between times measured by the reference clock and the secondary clock to generate a clock signal. The clock signal is communicated to one or more interfaces for distributing.

Abstract: A system and method for redundant synchronizing to a reference clock for data communications. A determination is made whether a first data stream and a second data stream are available. The first data stream and the second data stream are received through opposing directions of a communications ring. A first data packet and second data packet are received at a remote node in response to the first data stream and second data stream being available. A timing characteristic of the first data packet and the second data packet correspond to a tick of a reference clock. The tick of the reference clock is extracted utilizing a timing characteristic of the first data packet or second data packet in response to the first data stream or the second data stream being available. A secondary clock is disciplined with the reference clock by adjusting the secondary clock based on a difference between times measured by the reference clock and the secondary clock to generate a clock signal.

Abstract: A system and method for redundant synchronizing to a reference clock for data communications. A determination is made whether a first data stream and a second data stream are available. The first data stream and the second data stream are received through opposing directions of a communications ring. A first data packet and second data packet are received at a remote node in response to the first data stream and second data stream being available. A timing characteristic of the first data packet and the second data packet correspond to a tick of a reference clock. The tick of the reference clock is extracted utilizing a timing characteristic of the first data packet or second data packet in response to the first data stream or the second data stream being available. A secondary clock is disciplined with the reference clock by adjusting the secondary clock based on a difference between times measured by the reference clock and the secondary clock to generate a clock signal.

Abstract: A system and method for synchronizing a clock for data transmissions. A data packet is received at a remote node. A timing characteristic of the data packet corresponds to a tick of a clock form a reference clock. A tick of the clock is determined based on the timing characteristic of the data packet. A secondary clock is disciplined with the reference clock by adjusting the secondary clock based on a difference between times measured by the reference clock and the secondary clock to generate a clock signal. The clock signal is communicated to one or more interfaces.

Abstract: A system and method for synchronizing a clock for data transmissions. A data packet is received at a remote node. A timing characteristic of the data packet corresponds to a tick of a clock form a reference clock. A tick of the clock is determined based on the timing characteristic of the data packet. A secondary clock is disciplined with the reference clock by adjusting the secondary clock based on a difference between times measured by the reference clock and the secondary clock to generate a clock signal. The clock signal is communicated to one or more interfaces.

Abstract: A system for testing a communication network includes a test system and a cross-connect system. The test system generates a plurality of independent low data rate test signals with first data rates. The test system combines the independent low data rate test signals to generate a high data rate test signal. The test system then transmits the high data rate test signal from the test system to a shared test port. The cross-connect system transfers the high data rate test signal to a cross-connect matrix that connects the independent low data rate test signals to the communication network. The cross-connect system then receives the independent low data rate test signals from the communication network into the shared test port. The cross-connect system transmits the high data rate test signal from the shared test port to the test system. The test system separates the high data rate test signal into the independent low data rate test signals.

Abstract: A system for testing a communication network includes a test system and a cross-connect system. The test system generates a plurality of independent low data rate test signals with first data rates. The test system combines the independent low data rate test signals to generate a high data rate test signal. The test system then transmits the high data rate test signal from the test system to a shared test port. The cross-connect system transfers the high data rate test signal to a cross-connect matrix that connects the independent low data rate test signals to the communication network. The cross-connect system then receives the independent low data rate test signals from the communication network into the shared test port. The cross-connect system transmits the high data rate test signal from the shared test port to the test system. The test system separates the high data rate test signal into the independent low data rate test signals.