Disclosed are techniques for wireless communication. In an aspect, a wireless device determines a symbol configuration for transmission of SC-FDE waveform with zero gaps arranged between a communication channel part, RS part, and CP part. The SC-FDE waveform is transmitted to another wireless device, which processes the SC-FDE waveform.

A digitally modulated radar, DMR, transmitter module is disclosed comprising: a sequence generator, configured to generate a repeating digital sequence signal based on a relatively low-frequency clock signal; a mixer configured to combine the digital sequence signal with at least one phase-delayed copy of the digital sequence signal, to provide a combined signal; and a modulator configured to modulate a relatively high-frequency carrier signal, in dependence on the combined signal, to provide a modulated signal. Corresponding systems and methods are also disclosed.

A multi-mode line driver circuit supporting different communication standards includes an output for the network connection, and driver elements connected in parallel to the output. Each driver element is connected to a positive and negative supply voltage, and includes a resistor, a first switch and a second switch. The resistor is connected to the output and via the first switch to the positive supply voltage and via the second switch to the negative supply voltage. The driver circuit also includes at least one coding block with an input for a digital signal to be transmitted over the network connection. The coding block provides control signals for the first switch and the second switch for connecting the resistor of each driver element to the positive supply voltage or the negative supply voltage. The digital signal of the multi-mode line driver circuit is coded according to a communication standard.

Examples of the present disclosure relate to a method, device and apparatus for communication, and a computer-readable medium. An example of the method includes: conducting, based on a channel response between a transmitter and a receiver, spectral shaping on a first sequence at the transmitter, so as to obtain an intermediate sequence, where the spectral shaping at least partially counters the channel response; remapping the intermediate sequence, so as to obtain a second sequence, where the second sequence has less signal levels than the intermediate sequence; and transmitting the second sequence to the receiver, so as to train an equalizer of the receiver. In this way, the method can accelerate training of the equalizer without sacrificing performance of the equalizer or introducing any additional hardware cost.

A semiconductor device capable of communicating with a host apparatus includes a symbol generation unit, a coding unit, and a transmission unit. The symbol generation unit includes a random number generation circuit and generates a symbol according to a random number generated by the random number generation circuit. The coding unit performs 8b/10b coding for the symbol. The transmission unit transmits the symbol coded by the 8b/10b coding unit to the host apparatus.

A system for selecting an equalizer setting of an equalizer to equalize signals received via a communications link. Starting with a first (e.g., minimum) equalizer setting and a threshold voltage near the mid-eye voltage of the equalized output signal, the system estimates the amplitude of the inner eye of the equalized output signal by comparing the equalized output signal to a series of threshold voltages. If the amplitude of the equalized output signal is less than ideal, the system dynamically increases the equalizer setting. The system quickly converges on the equalizer setting for the communication link because, rather than comparing the output signal at every voltage offset using every equalizer setting, the system only evaluates the equalizer settings necessary to select the equalizer setting for the communications link and uses only the voltage offsets necessary to evaluate each equalizer setting.

A signal analysis apparatus includes a first frequency conversion unit 10 that generates an intermediate frequency signal S.sub.IF2 and a second spurious signal S.sub.SP2 from a measured signal S.sub.RF of a frequency f.sub.RF (center frequency f.sub.c), and a second frequency conversion unit 25 that converts the intermediate frequency signal S.sub.IF2 and the second spurious signal S.sub.SP2 into an intermediate frequency signal S.sub.IF2′ of a frequency f.sub.IF2′ and a second spurious signal S.sub.SP2′ of a frequency f.sub.SP2′ by performing frequency shift of the intermediate frequency signal S.sub.IF2 and the second spurious signal S.sub.SP2 by a frequency shift amount Δf, in which the frequency shift amount Δf is a value that does not establish a relationship of −W/2≤f.sub.SP2′−f.sub.IF2′≤+W/2.

A signal equalizer comprising: a feedback system, configured to acquire at least one signal value of an edge region of an input signal, and configured to adjust the signal value according to a crossing part of an eye diagram such that the crossing part converges to a zero point, wherein the crossing part corresponds to the edge region.

A transmission apparatus that transmits a block signal including a plurality of data symbols, includes: a data-symbol generation unit that generates a data symbol; a symbol arrangement unit that arranges the data symbol and a same-quadrant symbol such that one same-quadrant symbol that becomes a signal point in a same quadrant in a complex plane is inserted per block at a predetermined position in each block signal to generate a block symbol; a CP insertion unit that inserts a Cyclic Prefix into the block symbol; and an interpolation unit that performs interpolation processing on the block symbol on which CP insertion has been performed.

A method of compensating electromagnetic emissions of a device for use in a communication bus, the method including: transmitting a test signal over the communication bus; receiving, at the device, the test signal after propagation over the communication bus; performing frequency analysis processing of the test signal received to detect a set of harmonic components of the test signal received having an amplitude exceeding a certain threshold; storing respective values of frequency of harmonic components in the set of harmonic components having an amplitude exceeding the certain threshold; and generating and transmitting over the communication bus a set of compensation signals, each compensation signal in the set of compensation signals being a sinusoidal signal having a respective frequency equal to one of the frequencies stored, and being in anti-phase with respect to the harmonic component of the test signal received having the respective frequency.