The present disclosure provides a testing method for optical communication module, and a test device. The testing method includes: reading encoded information from the optical communication module to be tested; obtaining a pre-stored optimal test parameter corresponding to the optical communication module, and adjusting test parameter configuration of test device accordingly to the optimal test parameter; obtaining test mode configuration, and performing a test on the optical communication module to obtain first test result; and obtaining a determination result according to the first test result and expected result. This method improves test efficiency and proposes a test device which emulates the estimated common performance characteristics of the main stream networking devices where the optical communication module attaches to in real-life applications, therefore, a qualified module passing the proposed test method has much lower possibility of having the interoperability issue mentioned in the background of the present disclosure.

The present disclosure provides a testing method for optical communication module, and a test device. The testing method includes: reading encoded information from the optical communication module to be tested; obtaining a pre-stored optimal test parameter corresponding to the optical communication module, and adjusting test parameter configuration of test device accordingly to the optimal test parameter; obtaining test mode configuration, and performing a test on the optical communication module to obtain first test result; and obtaining a determination result according to the first test result and expected result. This method improves test efficiency and proposes a test device which emulates the estimated common performance characteristics of the main stream networking devices where the optical communication module attaches to in real-life applications, therefore, a qualified module passing the proposed test method has much lower possibility of having the interoperability issue mentioned in the background of the present disclosure.

The present invention facilitates optical modulation skew adjustment. Components of an on chip optical device driver system can cooperatively operate to provide modulated driver signals to drive configuration of optical signals. A serializer is configured to receive parallel data signals and forward corresponding serial data signals. A multiplexing component is configured to selectively output an in-phase component and a quadrature component of the serial data signals, including implementing skew adjustments to aspects of a first output signal and a second output signal. An output stage is configured to output signals that modulate an optical signal, including the first output signal and the second output signal. An on chip skew detector is configured to detect a skew difference between the first output signal and the second output signal. A skew calibration component is configured to direct skew adjustment between the first output signal and the second output signal.

The present invention facilitates optical modulation skew adjustment. Components of an on chip optical device driver system can cooperatively operate to provide modulated driver signals to drive configuration of optical signals. A serializer is configured to receive parallel data signals and forward corresponding serial data signals. A multiplexing component is configured to selectively output an in-phase component and a quadrature component of the serial data signals, including implementing skew adjustments to aspects of a first output signal and a second output signal. An output stage is configured to output signals that modulate an optical signal, including the first output signal and the second output signal. An on chip skew detector is configured to detect a skew difference between the first output signal and the second output signal. A skew calibration component is configured to direct skew adjustment between the first output signal and the second output signal.

A plurality of optical sensors (3) are each installed in an optical path control device (1) that controls a corresponding one of the plurality of optical paths (2) without using an electrical element. Each of the plurality of optical sensors (3) detects an optical signal passing through the corresponding one of the plurality of optical paths (2). A transmitter (4) determines a communication state of the corresponding one of the plurality of optical paths (2) based on detection of the optical signal by the corresponding one of the plurality of optical sensors (3), and transmits information on the determined communication state. A power supplying optical signal generation unit (11) generates a power supplying optical signal. An optical signal synthesizing device (12) synthesizes the power supplying optical signal with the optical signal and transmits a signal obtained by the synthesis to the optical path control device (1). A storage battery (13) supplies electric power to the transmitter (1). A photoelectric conversion unit (14) converts the power supplying optical signal branched from the optical signal in the optical path control device (1) into an electrical output and supplies the electrical output to the storage battery (13).

Wearable devices for monitoring light sources, and light fixtures are presented. For instance, a device includes a light detection sensor, a user interface device, and a controller operably coupled to the light detection sensor and the user interface device. The controller configured to: monitor a plurality of light sources for an availability status indication; determine, from the status data availability indication, that status data of the equipment is available from the light source; receive a modulated light signal from the light source; decode the modulated light signal into decoded status data; determine a status of the equipment based on the decoded status data; process the decoded status data to determine a diagnosis of the equipment; and indicate via the user interface device the diagnosis of the equipment and a diagnostic action related thereto. The light fixture includes a light source and a controller operably coupled to the light source, The controller is configured to receive status data from equipment, encode the status data in a modulated light signal, and output the modulated light signal using the light source.

Methods and apparatus are provided for locating a fault in an optical communication link. In one aspect, a method comprises determining a fault in a first optical link, and determining a fault in a second optical link. The method then determines that a first portion of the first optical link is co-located with a second portion of the second optical link and identifies, as a result of determining that the first portion is co-located with the second portion, that the fault in the first optical link is located in the first portion and/or the fault in the second optical link is located in the second portion.

A service data processing method and apparatus is disclosed. A data frame is divided into code blocks with smaller granularity, and service data is mapped to a corresponding quantity of code blocks in the data frame based on a service requirement. In addition, the data frame is used to indicate a location of a code block carrying the service data. In one manner, a code block in a payload area of the data frame is divided into a data code block and an overhead code block, and the overhead code block is used to indicate a location of a data code block carrying the service data. In the another manner, an indication field is configured in an overhead area of the data frame to indicate a location of a code block that carries the service data and that is in the payload area of the data frame.

A method includes determining a first power level by performing a first series of measurements based on a first series of burst transmissions from an optical transmitter of an optical network unit (ONU) in an optical network. Bursts in the first series of burst transmissions include a first modified preamble. A second power level is determined by performing a second series of measurements based on a second series of optical burst transmissions. Bursts in the second series of burst transmissions include a second modified preamble. A first power level (P.sub.0) and a second power level (P.sub.1) are determined based on the first power level and the second power level and one or more additional parameters associated with transmissions from the optical transmitter are determined based on P.sub.0 and P.sub.1. Based on the additional parameters, it is determined whether the optical transmitter complies with specifications of the optical network.

A method includes determining a first power level by performing a first series of measurements based on a first series of burst transmissions from an optical transmitter of an optical network unit (ONU) in an optical network. Bursts in the first series of burst transmissions include a first modified preamble. A second power level is determined by performing a second series of measurements based on a second series of optical burst transmissions. Bursts in the second series of burst transmissions include a second modified preamble. A first power level (P.sub.0) and a second power level (P.sub.1) are determined based on the first power level and the second power level and one or more additional parameters associated with transmissions from the optical transmitter are determined based on P.sub.0 and P.sub.1. Based on the additional parameters, it is determined whether the optical transmitter complies with specifications of the optical network.