Techniques for dynamically selecting filter parameters for a multi-radio multi-band configuration are described. An example technique includes determining a device class associated with a computing device comprising a plurality of radios operating on a plurality of bands. One or more target operating parameters of the computing device are determined based at least in part on the device class. One or more filter parameters of a plurality of filters for operating the plurality of radios are determined based at least in part on the one or more target operating parameters. The plurality of radios are configured according to the one or more filter parameters.

A communication apparatus includes: a despreading unit that performs despreading processing on a received signal subjected to direct spread processing; a signal detection unit that detects a plurality of signals included in the received signal subjected to the despreading processing; a delay amount estimation unit that estimates an amount of delay in each of the plurality of detected signals; a pilot signal extraction unit that extracts a subcarrier including a pilot signal from the received signal based on the estimated amounts of delay; a spreading unit that performs direct spread processing on the extracted pilot signal by using a spreading sequence used by a source of transmission of the received signal for performing direct spread processing; and a transmission path estimation processing unit that performs transmission path estimation processing based on the pilot signal subjected to the direct spread processing.

A transmission apparatus including the number of antennas different from a reception apparatus and performing transmission by SC-MIMO to and from the reception apparatus includes a training signal generation unit that generates a known signal predetermined, a CP addition unit that adds a CP to each symbol of a transmission signal including the known signal, a weight generation unit that generates a transmission weight based on a transposed adjugate matrix that is a product of a channel matrix estimated based on the known signal by the reception apparatus and a complex conjugate transpose of the channel matrix, and a transmission beam formation unit that uses the transmission weight to form a transmission beam for the transmission signal where the CP is added.

A receiver apparatus 1 estimates a plurality of first electric-power delay profiles from a plurality of digital signals based on signals received via an array antenna; generates a synthesized electric-power delay profile q(m, l) by synthesizing these; generates an array process signal y(k) from the plurality of digital signals; estimates a second electric-power delay profile from the array process signal; generates a difference electric-power delay profile d(m, l) by subtracting the second electric-power delay profile from the synthesized electric-power delay profile; and creates a two-dimensional map indicating a relationship between delay times and arrival angles of incoming waves, on the basis of the difference electric-power delay profile and a direction of a null point. The receiver apparatus 1 changes the direction of the null point and repeats the above process, and estimates an arrival angle .sub.1 of a direct wave on the basis of the two-dimensional map.

Provided is a method of determining timing of arrival of a signal on a path to a receiver in a mobile wireless communications system. The method comprises obtaining a channel impulse response (CIR) of a signal received at the receiver and deriving a power characteristic of the CIR. The method includes producing a first derivative of the power characteristic with respect to time, selecting some or all extrema from the first derivative of the power characteristic as indicative of candidate signal paths, and selecting one or more of said candidate signal paths. The method preferably includes determining timing of arrival of a signal on a first path of arrival at the receiver by assessing an energy value of each of said candidate signal paths against a threshold value.

Wireless communication wherein channel estimation accuracy is improved while keeping the position of each bit in a frame, even when a modulation system having a large modulation multiple value is used for a data symbol. An encoding operation encodes and outputs transmitting data (bit string) and a bit converting operation converts at least one bit of a plurality of bits constituting a data symbol to be used for channel estimation, among the encoded bit strings, into 1 or 0. A modulating operation modulates the bit string inputted from the bit converting operation by using a single modulation mapper and a plurality of data symbols are generated.

A method and apparatus for estimating a channel in a wireless local area network (WLAN) are provided. A channel estimation apparatus may include a channel estimation information combiner to combine at least one channel estimation information based on a difference between cyclic delay diversity (CDD) values, and a phase applier to generate a first phase value and to apply the first phase value to the combined channel estimation information.

The present disclosure discloses a wireless communication device and method with low power modes. According to an aspect of the present embodiment, an object is to provide a wireless communication device and method, which may set an accurate timing advance by synchronizing a clock signal provided to a timer with a clock signal provided to a near-field wireless communication circuit.

The present invention relates to a method and apparatus for demodulation in a wireless communications system transmitted across a wireless communications channel. The described wireless receiver includes a first antenna for receiving a wireless signal including a symbol transmitted across a wireless communications channel perceived by the first antenna, an observation modifier for generating a modified observation (y) of the symbol based on a product of the received observation (r) and the complex conjugate of a channel estimate (h*), a log-likelihood ratio (LLR) module generating log-likelihood ratios (LLRs) based on the modified observation and the channel estimate, and a maximum-likelihood-based decoder for decoding the symbol based on the LLRs.

An equalizer includes: a channel estimator configured to generate a set of time-domain channel coefficients based on a receive signal; a frequency-domain transformer configured to generate a set of frequency-domain channel coefficients based on a frequency transform of the set of time-domain channel coefficients; an equalizer coefficient generator configured to generate a set of frequency-domain equalizer coefficients based on the set of frequency-domain channel coefficients; a time-domain transformer configured to generate a set of time-domain equalizer coefficients based on a time transform of the set of frequency-domain equalizer coefficients; and a filter configured to filter the receive signal based on a filter function that is based on the set of time-domain equalizer coefficients.