Abstract: Provided herein are functionalized pegylated cyanine compounds containing a reactive group suitable for labeling a biomolecule or pharmaceutical compositions and methods of use thereof. In one embodiment, the compounds are based on formula I shown below. In other embodiments, the compounds can be pegylated at one or more of the following locations R1, R4, R6, R9, or L.

Abstract: The present invention discloses encoding and decoding methods and apparatuses of an Ethernet physical layer, the encoding method includes: determining a to-be-encoded first information group, where the first information group includes m characters, m?2, and m is an integer, where a character attribute of any character is a data character, a boundary character, or a third-type character, and one character occupies one byte; detecting a character attribute of each character in the first information group; if the first information group includes n boundary characters, where n?1, and n is an integer, deleting the n boundary characters, and generating a second information group by using a character, except the n boundary characters, in the first information group, and type information and position information that are of the n boundary characters, where the second information group includes m bytes; and adding header information to the second information group.

Abstract: An FEC coding/decoding data processing method and a related apparatus are provided. The method includes: performing, at an FEC coding processing sublayer by using m data code blocks as one group, FEC coding on a data code block sequence output by a physical coding sublayer, to generate n FEC check code blocks; respectively distributing m×t2 data code blocks and n×t2 FEC check code blocks to M virtual channels of a first virtual channel group and N virtual channels of a second virtual channel group; and respectively multiplexing, according to geared speed bit by bit multiplexing, data distributed to the first virtual channel group and data distributed to the second virtual channel group to at most H interfaces of a first physical channel group and at most K interfaces of a second physical channel group, where M is an integral multiple of H, and N is an integral multiple of K.

Abstract: The present invention discloses encoding and decoding methods and apparatuses of an Ethernet physical layer, the encoding method includes: determining a to-be-encoded first information group, where the first information group includes m characters, m?2, and m is an integer, where a character attribute of any character is a data character, a boundary character, or a third-type character, and one character occupies one byte; detecting a character attribute of each character in the first information group; if the first information group includes n boundary characters, where n?1, and n is an integer, deleting the n boundary characters, and generating a second information group by using a character, except the n boundary characters, in the first information group, and type information and position information that are of the n boundary characters, where the second information group includes m bytes; and adding header information to the second information group.

Abstract: Embodiments of the present invention provide a transmission apparatus, a connection device, and a method, where the apparatus includes N Ethernet Medium Access Control MAC ports, where each Ethernet MAC port is corresponding to a first MII interface, K Ethernet physical layer interfaces, where each Ethernet physical layer interface is corresponding to a second MII interface, and a connection device, where both N and K are positive integers; where the connection device is configured to control a time-division interconnect bus in the connection device or a time-division space-division switching matrix in the connection device to implement a connection between a timeslot of the first MII interface and a timeslot of the second MII interface, where the N Ethernet MAC ports and the K Ethernet physical layer interfaces are separately connected to the connection device by using the first MII interfaces and the second MII interfaces.

Abstract: The present invention provides a method, apparatus and system for transmitting and receiving a client signal. A client signal is mapped to a low-order ODU via a GFP scheme, wherein the low-order ODU is sized to M equal sized timeslots of a high-order OPUk, wherein the high-order OPUk is divided into N equal sized timeslots, wherein M is any one of a group from 1 to N; wherein if k=2, then N=8, if k=3, then N=32 and if k=4, then N=80. The low-order ODU with the client signal is mapped to M equal sized timeslots of the high-order OPUk via a GMP scheme; and an OTU with the high-order OPUk and overheads is formed, and then the OTU is transmitted.

Abstract: An embodiment of the present invention provides an optical burst synchronization method. A synchronization method includes: selecting a reference chassis, and transmitting, by an output port corresponding to an FTL in the reference chassis, an optical burst test signal respectively to receive ports corresponding to ORs in other line card chassis, where the optical burst test signal carries a transmission timeslot number; and acquiring, by a receive port corresponding to an OR in each line card chassis, according to an optical path difference between the receive port corresponding to the OR in each line card chassis and the output port corresponding to the FTL in the reference chassis, time of receiving the optical burst test signal, and the transmission timeslot number, a time-phase difference between each line card chassis and the reference chassis, and calibrating a local clock phase according to the time-phase difference.

Abstract: An embodiment of the present invention provides an optical burst synchronization method. A synchronization method includes: selecting a reference chassis, and transmitting, by an output port corresponding to an FTL in the reference chassis, an optical burst test signal respectively to receive ports corresponding to ORs in other line card chassis, where the optical burst test signal carries a transmission timeslot number; and acquiring, by a receive port corresponding to an OR in each line card chassis, according to an optical path difference between the receive port corresponding to the OR in each line card chassis and the output port corresponding to the FTL in the reference chassis, time of receiving the optical burst test signal, and the transmission timeslot number, a time-phase difference between each line card chassis and the reference chassis, and calibrating a local clock phase according to the time-phase difference.

Abstract: The present invention provides a method, apparatus and system for transmitting and receiving a client signal. A client signal is mapped to a low-order ODU via a GFP scheme, wherein the low-order ODU is sized to M equal sized timeslots of a high-order OPUk, wherein the high-order OPUk is divided into N equal sized timeslots, wherein M is any one of a group from 1 to N; wherein if k=2, then N=8, if k=3, then N=32 and if k=4, then N=80. The low-order ODU with the client signal is mapped to M equal sized timeslots of the high-order OPUk via a GMP scheme; and an OTU with the high-order OPUk and overheads is formed, and then the OTU is transmitted.

Abstract: The present invention provides a method, apparatus and system for transmitting and receiving a client signal. The method for transmitting a client signal includes, at the transmitting end, mapping a client signal to be transmitted to a corresponding low-order Optical Channel Data Unit (ODU) in a low-order ODU set, wherein low-order ODUs in the low-order ODU set having rates increased in order, and having rate correspondence relations with the client signals; mapping the low-order ODU to a timeslot of a high-order Optical Channel Payload Unit (OPU) in a high-order OPU set; and adding overheads to the high-order OPU to form an Optical Channel Transport Unit (OTU), and transferring the OTU to an Optical Transport Network (OTN) for transmission.

Abstract: The present invention provides a method, apparatus and system for transmitting and receiving a client signal. The method for transmitting a client signal includes, at the transmitting end, mapping a client signal to be transmitted to a corresponding low-order Optical Channel Data Unit (ODU) in a low-order ODU set, wherein low-order ODUs in the low-order ODU set having rates increased in order, and having rate correspondence relations with the client signals; mapping the low-order ODU to a timeslot of a high-order Optical Channel Payload Unit (OPU) in a high-order OPU set; and adding overheads to the high-order OPU to form an Optical Channel Transport Unit (OTU), and transferring the OTU to an Optical Transport Network (OTN) for transmission.

Abstract: The present invention provides a method, apparatus and system for transmitting and receiving a client signal. The method for transmitting a client signal includes, at the transmitting end, mapping a client signal to be transmitted to a corresponding low-order Optical Channel Data Unit (ODU) in a low-order ODU set, wherein low-order ODUs in the low-order ODU set having rates increased in order, and having rate correspondence relations with the client signals; mapping the low-order ODU to a timeslot of a high-order Optical Channel Payload Unit (OPU) in a high-order OPU set; and adding overheads to the high-order OPU to form an Optical Channel Transport Unit (OTU), and transferring the OTU to an Optical Transport Network (OTN) for transmission.

Abstract: The present invention provides a method, apparatus and system for transmitting and receiving a client signal. The method for transmitting a client signal includes, at the transmitting end, mapping a client signal to be transmitted to a corresponding low-order Optical Channel Data Unit (ODU) in a low-order ODU set, wherein low-order ODUs in the low-order ODU set having rates increased in order, and having rate correspondence relations with the client signals; mapping the low-order ODU to a timeslot of a high-order Optical Channel Payload Unit (OPU) in a high-order OPU set; and adding overheads to the high-order OPU to form an Optical Channel Transport Unit (OTU), and transferring the OTU to an Optical Transport Network (OTN) for transmission.

Abstract: A method for sending overhead information includes: encoding customer information into a 64B/66B customer information code block; encoding configured overhead information into a 64B/66B code block, and marking the code block as an overhead code block; and sending the customer information code block and the overhead code block, where M of every N sent code blocks are overhead code blocks (M and N are positive integers and M is smaller than N). A method for receiving overhead information includes: receiving the 64B/66B code block; identifying the overhead code block according to an identifier of the overhead code block and extracting overhead information from the overhead code block; and decoding the customer information code blocks other than the overhead code blocks and obtaining the customer information. Through the foregoing methods, fixed bandwidth of the overhead information is ensured, and the OAM information transmission performance is improved.