USB transmission and reception devices are provided. A USB transmission device comprises a first interface to receive display port (DP) data via N lanes at a first link rate, wherein N is an integer greater than 1; and a switching re-timer including a plurality of de-serializer circuits to de-serialize the received DP data, a plurality of decoder circuits to decode the de-serialized DP data, a plurality of multiplexer circuits to multiplex the decoded de-serialized DP data received via each of the N lanes into 1/M lanes, wherein M is an integer greater than 1, a plurality of encoder circuits to encode the multiplexed DP data, and a plurality of serializer circuits to serialize the encoded multiplexed DP data and output the serialized multiplexed DP data on each of the N/M lanes at a second link rate, the second link rate being equal to the first link rate multiplied by M.

USB transmission and reception devices are provided. A USB transmission device comprises a first interface to receive display port (DP) data via N lanes at a first link rate, wherein N is an integer greater than 1; and a switching re-timer including a plurality of de-serializer circuits to de-serialize the received DP data, a plurality of decoder circuits to decode the de-serialized DP data, a plurality of multiplexer circuits to multiplex the decoded de-serialized DP data received via each of the N lanes into 1/M lanes, wherein M is an integer greater than 1, a plurality of encoder circuits to encode the multiplexed DP data, and a plurality of serializer circuits to serialize the encoded multiplexed DP data and output the serialized multiplexed DP data on each of the N/M lanes at a second link rate, the second link rate being equal to the first link rate multiplied by M.

A data transmission system includes a transmitter having a first switching re-timer and a receiver having a second switching re-timer. The first switching re-timer is configured to double a link rate per lane and halve the number of lanes, and the second switching re-timer is configured to halve the doubled link rate and double the halved number of lanes.

A data transmission system includes a transmitter having a first switching re-timer and a receiver having a second switching re-timer. The first switching re-timer is configured to double a link rate per lane and halve the number of lanes, and the second switching re-timer is configured to halve the doubled link rate and double the halved number of lanes.

A new DC network structure is proposed that addresses various limitations of ASIC switches. In an optical network of the present disclosure, a slight time domain limitation is introduced for transmission from a network node to a same destination node. Data transmission and reception operate in a time slot scheme. A switching bandwidth in the ASIC switch has a bandwidth corresponding to average incoming traffic of a plurality of nodes, and includes a storage medium that stores and processes traffic exceeding the bandwidth. An average bandwidth for the reception ASIC switch can also be set to a bandwidth in which the maximum incoming bandwidth to the node is reduced by a coefficient F. Limiting the bandwidth of the reception ASIC switch can reduce the power consumption of the node, which is beneficial for network scalability.

A new DC network structure is proposed that addresses various limitations of ASIC switches. In an optical network of the present disclosure, a slight time domain limitation is introduced for transmission from a network node to a same destination node. Data transmission and reception operate in a time slot scheme. A switching bandwidth in the ASIC switch has a bandwidth corresponding to average incoming traffic of a plurality of nodes, and includes a storage medium that stores and processes traffic exceeding the bandwidth. An average bandwidth for the reception ASIC switch can also be set to a bandwidth in which the maximum incoming bandwidth to the node is reduced by a coefficient F. Limiting the bandwidth of the reception ASIC switch can reduce the power consumption of the node, which is beneficial for network scalability.

A bufferless ring network including at least two nodes and at least two timeslots, the at least two timeslots include a dedicated timeslot, and a first node in the bufferless ring network has use permission for the dedicated timeslot. The first node is configured to, in a state of having the use permission for the dedicated timeslot, detect whether all dedicated timeslots that pass through the first node are available, set a permission switch signal, and cancel the use permission for the dedicated timeslot according to the permission switch signal after detecting that all the dedicated timeslots that pass through the first node are available. A remaining node in the bufferless ring network is configured to obtain the use permission for the dedicated timeslot according to the permission switch signal. The remaining node is a node that needs to use the dedicated timeslot.

A bufferless ring network including at least two nodes and at least two timeslots, the at least two timeslots include a dedicated timeslot, and a first node in the bufferless ring network has use permission for the dedicated timeslot. The first node is configured to, in a state of having the use permission for the dedicated timeslot, detect whether all dedicated timeslots that pass through the first node are available, set a permission switch signal, and cancel the use permission for the dedicated timeslot according to the permission switch signal after detecting that all the dedicated timeslots that pass through the first node are available. A remaining node in the bufferless ring network is configured to obtain the use permission for the dedicated timeslot according to the permission switch signal. The remaining node is a node that needs to use the dedicated timeslot.

A data transmission system includes a transmitter having a first switching re-timer and a receiver having a second switching re-timer. The first switching re-timer is configured to double a link rate per lane and halve the number of lanes, and the second switching re-timer is configured to halve the doubled link rate and double the halved number of lanes.

A data transmission system includes a transmitter having a first switching re-timer and a receiver having a second switching re-timer. The first switching re-timer is configured to double a link rate per lane and halve the number of lanes, and the second switching re-timer is configured to halve the doubled link rate and double the halved number of lanes.