A transmission device includes: a data symbol generation unit; a static sequence generation unit generating a sequence of static symbols; a multiplexing unit generating a block signal in which static symbols are arranged in leading and trailing parts, while data symbols are arranged in a central part; a DFT unit transforming the block signal to a frequency-domain signal; a band reduction processing unit removing a predetermined number of signals in parts of both ends from the block signal after having been transformed to a frequency-domain signal; an interpolation processing unit performing interpolation processing on the block signal after a predetermined number of signals in parts of both ends have been removed; an IDFT unit transforming the block signal after having undergone the interpolation processing to a time-domain signal; and a transmission unit transmitting the block signal after having been transformed to a time-domain signal.

The implementations allow increases in data rate provided by the Faster-Than-Nyquist multi-carrier signaling to he balanced against system conditions to maintain transmission error rates on channels within an acceptable range. If conditions such as channel traffic load, inter-system interference, intra-system interference, available transmission power, and/or available bandwidth change, the Faster-Than-Nyquist multi-carrier signaling acceleration factor used on system channels may be adjusted based on the changing conditions. If conditions change unfavorably, the acceleration factor may be increased to lower the data rate so that the error rate improves on the one or more channels. If conditions change favorably, the acceleration factor may be decreased to increase the data rate in the improved channel conditions. During system operation, channel conditions may be monitored, and the acceleration factor on the channels may be adjusted to provided higher or lower data rates according to any changes in the channel conditions.

A method for transmitting a signal is described, wherein the method has transforming a signal into a frequency domain to obtain a spectrum, forming a filtered spectrum according to a filter spectrum and occupying a set of subcarriers of a frequency domain representation of an Orthogonal Frequency Division Multiplex (OFDM) signal with the filtered spectrum. A temporary signal is obtained by transforming the frequency domain representation of the OFDM signal into a time domain. The temporary signal is subjected to a phase modulation.

A transmission apparatus includes a symbol arrangement unit to receive multiple symbols constituting a block, duplicate a first symbol of a block one block previous to the block, and output a block symbol being the present block with the duplicated duplicate symbol inserted at a first position thereof, a frequency conversion unit to convert the block symbol into a frequency domain signal, a frequency component removal unit to remove one or more frequency components from the frequency domain signal, a time conversion unit to convert, after interpolation on the frequency domain signal with the frequency components removed, the interpolated frequency domain signal into a time domain signal, and a cyclic prefix insertion unit to duplicate, in the time domain signal, a signal from a position based on the first position through an end as a cyclic prefix, and insert the cyclic prefix at a beginning of the time domain signal.

A transmission apparatus includes a symbol arrangement unit to receive multiple symbols constituting a block, duplicate a first symbol of a block one block previous to the block, and output a block symbol being the present block with the duplicated duplicate symbol inserted at a first position thereof, a frequency conversion unit to convert the block symbol into a frequency domain signal, a frequency component removal unit to remove one or more frequency components from the frequency domain signal, a time conversion unit to convert, after interpolation on the frequency domain signal with the frequency components removed, the interpolated frequency domain signal into a time domain signal, and a cyclic prefix insertion unit to duplicate, in the time domain signal, a signal from a position based on the first position through an end as a cyclic prefix, and insert the cyclic prefix at a beginning of the time domain signal.

A signal processing device including a first signal processing chain having a first output signal; a second signal processing chain comprising a second output signal with a higher accuracy than the first output signal; a controller configured to switch, based on a desired accuracy, whether to switch between the first and second signal processing chains as a path for an original input signal; and a modifier configured to modify the original input signal, the first output signal, or the second output signal to generate a modified input, a modified first output, or a modified second output signal when the controller switches between the first and second signal processing chains.

Provided are a data transmission method, a data modulation method, an electronic device and a storage medium. The data transmission method includes: transmitting to-be-transmitted data in N frequency domain resource blocks, where each frequency domain resource block includes K(n) subcarriers, where n=1, 2, . . . , N, a value of N is greater than or equal to 1, and a value of K(n) is greater than or equal to 1; performing inverse Fourier transform and multiplication operation processing on to-be-transmitted data on the each frequency domain resource block of the N frequency domain resource blocks to form N groups of data sequences; and transmitting the N groups of data sequences.

A signal processing device including a first signal processing chain having a first output signal; a second signal processing chain comprising a second output signal with a higher accuracy than the first output signal; a controller configured to switch, based on a desired accuracy, whether to switch between the first and second signal processing chains as a path for an original input signal; and a modifier configured to modify the original input signal, the first output signal, or the second output signal to generate a modified input, a modified first output, or a modified second output signal when the controller switches between the first and second signal processing chains.

A system, apparatus, and related method for receiving and correlating Manchester encoded data signals includes a receiver for receiving 1090ES/ADS-B or other Manchester encoded signals. A sampler extracts and oversamples data strings from the received signals. Sample correlators compare the oversampled data strings to oversampled versions of each possible pattern for the extracted data string and determine a score indicating how closely the possible pattern (or its oversampled counterpart) matches the extracted data string (or its oversampled version) on a bitwise or symbolwise basis. The system outputs correlated and decoded data string most closely matching the extracted data string based on the set of determined scores.

A method for transmitting a signal is described, wherein the method has transforming a signal into a frequency domain to obtain a spectrum, forming a filtered spectrum according to a filter spectrum and occupying a set of subcarriers of a frequency domain representation of an Orthogonal Frequency Division Multiplex (OFDM) signal with the filtered spectrum. A temporary signal is obtained by transforming the frequency domain representation of the OFDM signal into a time domain. The temporary signal is subjected to a phase modulation.