Abstract: Methods and systems for channel estimation using iterative channel tracking algorithm, in a communication system combined multiple input multiple output (MIMO) technology with orthogonal frequency division multiplexing (OFDM), are disclose. The initial channel estimation of a data packet uses the first preamble inserted in front of the OFDM blocks. After demodulating subsequent one or more OFDM blocks, iterative channel tracking method is used for channel estimation until the next preamble is received. The iterative channel tracking is based on the received signals and the demodulated results of subsequent one or more OFDM blocks.

Abstract: Methods and systems for channel estimation using iterative channel tracking algorithm, in a communication system combined multiple input multiple output (MIMO) technology with orthogonal frequency division multiplexing (OFDM), are disclose. The initial channel estimation of a data packet uses the first preamble inserted in front of the OFDM blocks. After demodulating subsequent one or more OFDM blocks, iterative channel tracking method is used for channel estimation until the next preamble is received. The iterative channel tracking is based on the received signals and the demodulated results of subsequent one or more OFDM blocks.

Abstract: A system and method of frequency offset compensation are disclosed for a wireless system between a fast moving radio terminal associated with a locomotive and a stationary radio terminal associated with a base station. The present invention utilizes advanced frequency offset prediction to quickly track Doppler Shift caused by a fast moving locomotive. In one embodiment according to the present invention, the frequency offset prediction is based on a first plurality of coarse frequency offsets, first-order derivatives of the first plurality of coarse frequency offsets, and second-order derivatives of the first plurality of coarse frequency offsets. In another embodiment according to the present invention, the frequency offset prediction is based on a plurality of previous frequency offsets according to a Doppler shift model.

Abstract: A system and method of frequency offset compensation are disclosed for a wireless system between a fast moving radio terminal associated with a locomotive and a stationary radio terminal associated with a base station. The present invention utilizes advanced frequency offset prediction to quickly track Doppler Shift caused by a fast moving locomotive. In one embodiment according to the present invention, the frequency offset prediction is based on a first plurality of coarse frequency offsets, first-order derivatives of the first plurality of coarse frequency offsets, and second-order derivatives of the first plurality of coarse frequency offsets. In another embodiment according to the present invention, the frequency offset prediction is based on a plurality of previous frequency offsets according to a Doppler shift model.

Abstract: The present invention provides a method and system for operating a wireless communication system in which received signals from a plurality of antennas are weighted and combined with a beam forming operation to form an output signal. In an embodiment of the present invention, beamforming operations are performed with maximal ratio combining (MRC) and an interference nulling algorithm (INA). The INA receives an error signal which is 180° out of phase with a combination of the channels for individual antennas, referred to as the SUM channel. The error signal is determined by complex conjugate multiplication of the individual signals and a reference complex signal. The weight amplitude is controlled by weight normalization to provide faster convergence and prevent integrator overflow.

Abstract: A transmitter architecture and method of modulation that include a rotation-direction control circuit for varying the direction of rotation of phase transitions of a phase modulation based on the occurrence of a predetermined pattern of input data. This variation of rotation direction by the rotation-direction control circuit maintains the output spectrum of a modulated signal within the spectral mask requirements of an associated communications standard and thereby enables the use of non-linear power amplifiers in applications that generally require linear amplifiers.

Abstract: A phase-locked loop capable of being dynamically configured to optimize phase-noise performance during different modes of operation. The phase-locked loop may include a switchable charge pump, loop filter and voltage-controlled oscillator having auxiliary circuit components that may be switched in and out to achieve calibration settings for optimizing phase-noise performance for different modes of operation, while minimizing unnecessary power consumption, and without disturbing the stability of the phase-locked loop.

Abstract: The present invention provides a method and system for operating a wireless communication system in which received signals from a plurality of antennas are weighted and combined with a beam forming operation to form an output signal. The beam forming operation determines weights adjusted to increase a desired signal power in the output signal while reducing the power in the output signal of out-of-band components. In an embodiment of the present invention, beam forming operations are performed with maximal ratio combining (MRC). Alternatively, a constant modulus algorithm (CMA) can be used for beam forming operations. In an alternate embodiment, improved interference suppression is performed with a novel algorithm referred to as an interference nulling algorithm (INA). The INA receives an error signal which is 180° out of phase with a combination of the channels for individual antennas, referred to as the SUM channel.

Abstract: The present invention provides a method and system for operating a wireless communication system in which received signals from a plurality of antennas are weighted and combined with a beam forming operation to form an output signal. In an embodiment of the present invention, beamforming operations are performed with maximal ratio combining (MRC) and an interference nulling algorithm (INA). The INA receives an error signal which is 180° out of phase with a combination of the channels for individual antennas, referred to as the SUM channel. The error signal is determined by complex conjugate multiplication of the individual signals and a reference complex signal. The weight amplitude is controlled by weight normalization to provide faster convergence and prevent integrator overflow.

Abstract: Algorithms are provided to adjust the gain and phase imbalance of I/Q modulators and demodulators. The imbalances are adjusted through an adjustment range and the corresponding image signal powers determined. The minimum image signal power identifies the calibration settings for the gain and phase imbalances.

Abstract: A transceiver is disclosed having a zero intermediate frequency to low intermediate frequency receiver and a direct upconversion transmitter. Calibrations may be performed to minimize direct current voltage offset and in-phase and quadrature-phase path mismatch after downconversion. Automatic gain control is performed prior to downconversion and after upconversion to minimize the introduction of mismatch.

Abstract: A technique is disclosed to estimate the frequency offset in received direct downconverted predetermined signal despite the presence of a DC offset component. After compensation of the received predetermined signal according to the frequency offset estimation, the DC offset component is estimated. DC offset in data signals subsequent to the predetermined signal may then be mitigated based upon the estimated DC offset component.