The PWM waveform generation device comprises a time-division multiplexing module, wherein the time-division multiplexing module is configured for receiving a first preprocessing signal and a second preprocessing signal output by two system clock sources, performing a first time-division processing on the first preprocessing signal to obtain a first time-division signal, and performing a second time-division processing on the second preprocessing signal to obtain a second time-division signal according to a preset strategy, performing multiplexing processing on the first time-division signal and the second time-division signal to obtain a PWM output signal, wherein an output frequency of the PWM output signal is a default standard clock frequency. The present invention has the advantages that the cycle length of one cycle of a PWM waveform depends on cycles of two preprocessing waveforms and the number of the cycles, such that the output waveform frequency may be calibrated to a desired frequency.

A server system determines, for a group of user sessions assigned to a single modulator, that an aggregate bandwidth for a first frame time exceeds a specified budget for the modulator. The user sessions comprise data in a plurality of classes, each class having a respective priority. In response to a determination that the aggregate bandwidth exceeds a specified budget, the server system allocates a portion of the aggregate bandwidth, including allocating a first portion of the data for a first user session in the group of user sessions and allocating a second portion of the data for a second user session in the group of user sessions, where both the first portion and the second portion are allocated in accordance with the class priorities. The server system transmits the allocated portions of the data for the group of user sessions through the modulator during the first frame time.

A device includes a plurality of blocks. Each block of the plurality of blocks includes a plurality of rows. Each row of the plurality of rows includes a plurality of configurable elements and a routing line, whereby each configurable element of the plurality of configurable elements includes a data analysis element comprising a plurality of memory cells, wherein the data analysis element is configured to analyze at least a portion of a data stream and to output a result of the analysis. Each configurable element of the plurality of configurable elements also includes a multiplexer configured to transmit the result to the routing line.

A switch circuit and a high-speed multiplexer-demultiplexer are provided. The switch circuit includes an equalization module and an MOS transistor. A gate of the first MOS transistor is connected to an output terminal of the equalization module. An input terminal of the first MOS transistor is connected to a signal source. An output terminal of the first MOS transistor is connected to a subsequent circuit. The equalization module is configured to: supply a turning-on signal to the first MOS transistor in a case that an operation signal is acquired, to turn on the first MOS transistor; and generate a compensation signal for compensating an attenuation of the signal transmitted through the first MOS transistor, and apply the compensation signal to the gate of the first MOS transistor. The switch circuit operates in response to the operation signal.

A data communication device communicating with other devices via multiple communication paths includes a transmission unit and a reception unit. The transmission unit is configured to receive a packet containing header information and data, to output the header information to each of the communication paths, to divide the data into multiple data pieces, and to output the data pieces to the respective communication paths. The reception unit is configured to receive header information and a data piece for each of the communication paths, and to reconstruct a packet from the header information and the data piece received from each of the communication paths. In reconstructing the packet, the reception unit adjusts, for each of the communication paths, output timing of the data piece, based on the header information.

Systems and methods for data multiplexing include or use a data serializer having a first set of four serializer outputs and a second set of four serializer outputs. The systems and methods also use or include a pair of 4 to 1 multiplexers each having four first multiplexer inputs and one first multiplexer outputs and a 2 to 1 multiplexer having two multiplexer inputs and one multiplexer output.

Systems and methods for data multiplexing include or use a data serializer having a first set of four serializer outputs and a second set of four serializer outputs. The systems and methods also use or include a pair of 4 to 1 multiplexers each having four first multiplexer inputs and one first multiplexer outputs and a 2 to 1 multiplexer having two multiplexer inputs and one multiplexer output.

A double data rate circuit includes a clock generator, a clock divider and a multiplexer. The clock generator is used to receive a source clock signal to generate a pair of complementary clock signals. The clock divider is coupled to the clock generator, and used to generate four multiphase clock signals using only single-edge transitions of the pair of complementary clock signals. The four multiphase clock signals are successively out-of-phase by 90. The multiplexer is coupled to the clock divider, and used to multiplex multiple data bits into an output data stream by sequentially selecting and deselecting each data bit of the multiple data bits upon a first edge transition of and a second edge transition of two of the four multiphase clock signals, respectively, and outputting each selected data bit as the output data stream.

A circuit structure for efficiently demodulating an FSK signal in a wireless charging device, comprising a data sampling module, a period point counting module, a data distribution module, and a period point processing module. An input terminal of the period point counting module is connected to an output terminal of the data sampling module; an input terminal of the data distribution module is connected to an output terminal of the period point counting module; and an input terminal of the period point processing module is connected to an output terminal of the data distribution module.

Various aspects provide for a multiplexer for high-speed serial links. For example, a system can include a first stage data path multiplexer circuit and a second stage data path multiplexer circuit. The first stage data path multiplexer circuit comprises a first inverter circuit to select a first data signal from a set of data signals and a second inverter circuit to select a second data signal from the set of data signals. The first inverter circuit comprises a first set of inverters and a first set of transmission gates. The second inverter circuit comprises a second set of inverters and a second set of transmission gates. The second stage data path multiplexer circuit is configured as a third inverter circuit to select the first data signal or the second data signal as an output data signal. The third inverter circuit comprises a third set of inverters and a third set of transmission gates.