Abstract: The invention discloses a combination of PVY monoclonal antibodies capable of recognizing different antigenic determinants, and a use thereof, and belongs to the biotechnological field. Monoclonal antibodies N1, M1, M2, M3 and C1 obtained in the invention have specific CDRs, and are significantly different from existing reported monoclonal antibodies. The five monoclonal antibodies and a combination thereof can recognize all or most PVY isolates which have been reported, thus reducing the possibility of detection omissions; and the five monoclonal antibodies do not react with other congeneric viruses and non-congeneric viruses, thus reducing the possibility of detection errors. Therefore, the monoclonal antibodies and the combination thereof can realize accurate PVY detection.

Abstract: The invention discloses a combination of PVY monoclonal antibodies capable of recognizing different antigenic determinants, and a use thereof, and belongs to the biotechnological field. Monoclonal antibodies N1, M1, M2, M3 and C1 obtained in the invention have specific CDRs, and are significantly different from existing reported monoclonal antibodies. The five monoclonal antibodies and a combination thereof can recognize all or most PVY isolates which have been reported, thus reducing the possibility of detection omissions; and the five monoclonal antibodies do not react with other congeneric viruses and non-congeneric viruses, thus reducing the possibility of detection errors. Therefore, the monoclonal antibodies and the combination thereof can realize accurate PVY detection.

Abstract: Disclosed are a hypertext transfer protocol (HTTP) request transmission method and device. The HTTP request transmission method and device resolve a problem that data finally obtained through splicing is invalid because dividing an original HTTP request into a plurality of HTTP requests to pull data from different content distribution network (CDN) servers may cause inconsistency of the pulled data. When an electronic device needs to download data from a plurality of CDN servers, an overlapping range may be designed for byte ranges allocated to the different CDN servers. This means that the electronic device downloads data in the overlapping range from all the different CDN servers. Therefore, this part of data is used to check consistency of the data pulled from the different CDN servers. When determining that the data pulled from the different CDN servers is consistent, the electronic device may splice the data to obtain finally required data.

Abstract: An NFC tag verification method is provided. The method is applied to a first electronic device, and includes: detecting NFC tag information of a second electronic device; performing verification on the NFC tag information based on a locally stored first verification list, to obtain a first verification result; if the first verification result is that the verification succeeds, starting to run an application service associated with the NFC tag information; sending the NFC tag information to a cloud server; receiving a second verification result obtained by the cloud server by performing verification on the NFC tag information; and if the second verification result is that the verification fails, stopping running the application service. In the solution of embodiments of this application, when verification is performed on an NFC tag, the application service is first started to run after local verification succeeds, and then cloud verification is performed.

Abstract: Disclosed are a hypertext transfer protocol (HTTP) request transmission method and device. The HTTP request transmission method and device resolve a problem that data finally obtained through splicing is invalid because dividing an original HTTP request into a plurality of HTTP requests to pull data from different content distribution network (CDN) servers may cause inconsistency of the pulled data. When an electronic device needs to download data from a plurality of CDN servers, an overlapping range may be designed for byte ranges allocated to the different CDN servers. This means that the electronic device downloads data in the overlapping range from all the different CDN servers. Therefore, this part of data is used to check consistency of the data pulled from the different CDN servers. When determining that the data pulled from the different CDN servers is consistent, the electronic device may splice the data to obtain finally required data.

Abstract: A method for mapping a packet service onto an optical transport network is disclosed. An embodiment of the method includes: receiving a packet service message from an access side, identifying the message by using a first board number of a first line board in which a first egress is located and a first port number of the first egress; sending the message to the first line board corresponding to the first board number; and encapsulating the message that is sent to the first line board, mapping the encapsulated message onto a first optical channel data unit ODU corresponding to the first port number, and sending the first ODU by using the first egress. Cross-connect scheduling of any bandwidth in any direction is implemented based on a packet service, and packet services on different tributary boards share different ODU timeslots or a same ODU timeslot on a same line board.

Abstract: A method for testing an air interface device by simulating multi-UE uplink virtual MIMO includes receiving, by a multi-UE simulator, a downlink signal transmission from an air interface device under test. The method further includes decoding, by the multi-UE simulator, the downlink signal transmission to identify simulated UEs with uplink resource block grants. The method further includes assigning, by the multi-UE simulator, uplink data transmissions for the simulated UEs with uplink resource block grants to antennas or cables such that uplink data transmissions for simulated UEs with overlapping uplink resource block grants are assigned to different antennas or cables. The method further includes testing, by the multi-UE simulator, uplink virtual MIMO processing capability of the air interface device under test by generating and transmitting uplink signals from the simulated UEs with the overlapping uplink resource block grants to the air interface device under test using the different antennas or cables.

Abstract: A method for mapping a packet service onto an optical transport network is disclosed. An embodiment of the method includes: receiving a packet service message from an access side, identifying the message by using a first board number of a first line board in which a first egress is located and a first port number of the first egress; sending the message to the first line board corresponding to the first board number; and encapsulating the message that is sent to the first line board, mapping the encapsulated message onto a first optical channel data unit ODU corresponding to the first port number, and sending the first ODU by using the first egress. Cross-connect scheduling of any bandwidth in any direction is implemented based on a packet service, and packet services on different tributary boards share different ODU timeslots or a same ODU timeslot on a same line board.

Abstract: The present invention provides a base station deployment configuration method. The method includes: receiving, by a base station after being powered on for a first time, a virtual local area network identity and composite information, receiving, by the base station, a plurality of ping packets, and learning, by the base station, the received virtual local area network identity in the service packet and virtual local area network identities in all the received ping packets; traversing, by the base station, the learned virtual local area network identities, and sending a DHCP request to a DHCP server; receiving, by the base station, a DHCP response message returned by the DHCP server; and establishing, by the base station, an OM IP address connection to a management channel of the wireless network manager according to the OM IP address, and receiving a complete configuration delivered through the management channel.

Abstract: The present disclosure provides a language model training method and device, including: obtaining a universal language model in an offline training mode, and clipping the universal language model to obtain a clipped language model; obtaining a log language model of logs within a preset time period in an online training mode; fusing the clipped language model with the log language model to obtain a first fusion language model used for carrying out first time decoding; and fusing the universal language model with the log language model to obtain a second fusion language model used for carrying out second time decoding. The method is used for solving the problem that a language model obtained offline in the prior art has poor coverage on new corpora, resulting in a reduced language recognition rate.

Abstract: The subject matter described herein includes methods, systems, and computer readable media for simulating per-UE Doppler shifts. One exemplary method includes generating uplink signals to be transmitted from a plurality of different simulated UEs to an air interface device under test. The method further includes applying per-UE Doppler shifts to the signals, wherein applying per-UE Doppler shifts includes applying different Doppler shifts to at least some of the signals. The method further includes transmitting the signals to the air interface device under test.

Abstract: Methods, systems, and computer readable media for testing an air interface device using per user equipment (UE) channel noise are disclosed. One method includes, generating uplink signals at a network equipment test device to be transmitted from plural simulated UEs to an air interface device under test. The method further includes generating and applying per-UE channel noise to the signals, where applying per-UE channel noise includes applying different channel noise to at least some of the uplink signals. The method further includes transmitting the uplink signals with the per-UE channel noise to the air interface device under test.

Abstract: The present invention provides a base station deployment configuration method. The method includes: receiving, by a base station after being powered on for a first time, a virtual local area network identity and composite information, receiving, by the base station, a plurality of ping packets, and learning, by the base station, the received virtual local area network identity in the service packet and virtual local area network identities in all the received ping packets; traversing, by the base station, the learned virtual local area network identities, and sending a DHCP request to a DHCP server; receiving, by the base station, a DHCP response message returned by the DHCP server; and establishing, by the base station, an OM IP address connection to a management channel of the wireless network manager according to the OM IP address, and receiving a complete configuration delivered through the management channel.

Abstract: The present invention discloses a method for maintaining quality of service QoS, which includes: identifying a CLP and a service type of a newly received ATM cell, and obtaining a corresponding QoS label; when the QoS label corresponding to the newly received ATM cell is different from a QoS label corresponding to a buffered ATM cell, encapsulating the buffered ATM cell into a pseudo wire PW packet in a concatenation manner and sending the pseudo wire PW packet, where the QoS label corresponding to the buffered ATM cell is used as a QoS label of a PSN transport header of the PW packet, or is used as QoS labels of both the PSN transport header and a PW header of the PW packet, and buffering the newly received ATM cell. The present invention further provides a corresponding provider edge PE device and a corresponding ATM PWE3 system.

Abstract: Methods, systems, and computer readable media for testing an air interface device using per user equipment (UE) channel noise are disclosed. One method includes, generating uplink signals at a network equipment test device to be transmitted from plural simulated UEs to an air interface device under test. The method further includes generating and applying per-UE channel noise to the signals, where applying per-UE channel noise includes applying different channel noise to at least some of the uplink signals. The method further includes transmitting the uplink signals with the per-UE channel noise to the air interface device under test.

Abstract: The subject matter described herein includes methods, systems, and computer readable media for simulating per-UE Doppler shifts. One exemplary method includes generating uplink signals to be transmitted from a plurality of different simulated UEs to an air interface device under test. The method further includes applying per-UE Doppler shifts to the signals, wherein applying per-UE Doppler shifts includes applying different Doppler shifts to at least some of the signals. The method further includes transmitting the signals to the air interface device under test.

Abstract: The present invention relate to a packet processing method, an access device, and a communication system. The method includes: receiving, by an access device, a multicast packet from a network side via a first network port of the access device; identifying, by the access device, a protocol type of the multicast packet; if identifying that the multicast packet is a virtual router redundancy protocol packet, sending the virtual router redundancy protocol packet via a second network port of the access device to the network side according to a snooping port list used for forwarding the virtual router redundancy protocol packet; and if identifying that the multicast packet is a non-virtual router redundancy protocol packet, sending the non-virtual router redundancy protocol packet via a user port of the access device to a user side.

Abstract: According to one aspect, the subject matter described herein includes a method for dynamically controlling a Turbo decoding process in a long term evolution (LTE) multi-user equipment (UE) traffic simulator. The method includes steps occurring in an LTE traffic simulator configured to simulate plural UE devices. The steps include receiving, from an evolved NodeB under test, a plurality of transport blocks. The steps also include dynamically determining a maximum number of Turbo decoding iterations for each of the transport blocks. The steps further include Turbo decoding each of the transport blocks for no more than its determined maximum number of Turbo decoding iterations.

Abstract: The present invention discloses a method for maintaining quality of service QoS, which includes: identifying a CLP and a service type of a newly received ATM cell, and obtaining a corresponding QoS label; when the QoS label corresponding to the newly received ATM cell is different from a QoS label corresponding to a buffered ATM cell, encapsulating the buffered ATM cell into a pseudo wire PW packet in a concatenation manner and sending the pseudo wire PW packet, where the QoS label corresponding to the buffered ATM cell is used as a QoS label of a PSN transport header of the PW packet, or is used as QoS labels of both the PSN transport header and a PW header of the PW packet, and buffering the newly received ATM cell. The present invention further provides a corresponding provider edge PE device and a corresponding ATM PWE3 system.

Abstract: According to one aspect, the subject matter described herein includes a method for dynamically controlling a Turbo decoding process in a long term evolution (LTE) multi-user equipment (UE) traffic simulator. The method includes steps occurring in an LTE traffic simulator configured to simulate plural UE devices. The steps include receiving, from an evolved NodeB under test, a plurality of transport blocks. The steps also include dynamically determining a maximum number of Turbo decoding iterations for each of the transport blocks. The steps further include Turbo decoding each of the transport blocks for no more than its determined maximum number of Turbo decoding iterations.