Abstract: A method and apparatus for predistortion training in an amplifier using predistortion is provided herein. Predistortion takes place by collecting a series of envelope errors and averaging the envelope errors for various amplitude regions. LUT values are modified based on a curve-fit to the average amplitude values for each amplitude region. By utilizing a curve-fitting technique, the pitfalls of modifying individual LUT coefficients is avoided. Particularly, because the errors are collected in relatively broad regions and then averaged, the importance of exact correlation between a measured error and a specific LUT entry is significantly lessened.

Abstract: An adaptive predistortion linearization system includes input path digital-to-analog converters (DACs), error path DACs, a digital signal processor, and a radio frequency (RF) combiner. The digital signal processor includes a look-up table storing complex gain coefficient values. The digital signal processor generates an error signal based on the complex input signal and the complex gain coefficients by using a vector decomposition calculation. Feedback from a power amplifier can be provided to a training algorithm for periodically updating the gain coefficient values stored in the look-up table. By performing separate D/A conversions, the error path and input signals can be separately filtered. This separation also permits the error signal to be decoupled from the complex input signal, which facilitates an improvement in the wide-frequency-offset noise performance of the system.

Abstract: An adaptive predistortion linearization system includes input path digital-to-analog converters (DACs), error path DACs, a digital signal processor, and a radio frequency (RF) combiner. The digital signal processor includes a look-up table storing complex gain coefficient values. The digital signal processor generates an error signal based on the complex input signal and the complex gain coefficients by using a vector decomposition calculation. Feedback from a power amplifier can be provided to a training algorithm for periodically updating the gain coefficient values stored in the look-up table. By performing separate D/A conversions, the error path and input signals can be separately filtered. This separation also permits the error signal to be decoupled from the complex input signal, which facilitates an improvement in the wide-frequency-offset noise performance of the system.

Abstract: A method (100), a device (300), and a radio (500) are described for compensating for modulator frequency drift while allowing for data transmission in a half-duplex frequency modulated communication system. An adjustment is made to a premodulation signal in such a way that when it is passed through a frequency modulator to provide a transmitter excitation signal, frequency drift is corrected. Subsequent to determining a training command, the transmitter excitation signal passes through a switch to a demodulator. The demodulator output is averaged and used in the adjustment.

Abstract: The present invention provides an apparatus (200) and method (500) for providing a baseband digital error signal in an adaptive predistorter. A carrier cancellation circuit (202) provides a difference (212) between a first signal (208) based on an amplifier output and second signal (210) based on a data input. A quadrature demodulator (204) provides a baseband analog error signal (214) based on the difference (212). An analog-to-digital converter (206) provides the baseband digital error signal (216) based on the baseband analog error signal (214).

Abstract: A linear power amplifier is included in a RF transmitter. A mechanism is provided for generating a predistorted input signal to the PA so that nonlinear phase and amplitude characteristics of the PA will be compensated. Another means is provided for generating a feedback signal to the predistortion generating mechanism so that the feedback signal is based on the output of the PA when the predistortion circuit is locked and is based upon the input signal to the PA when the predistortion generating circuit is unlocked. Undesired emissions from the power amplifier are inhibited when the predistortion mechanism is unlocked.

Abstract: An improved RF power amplifier is disclosed whereby a PIN-type diode is utilized to provide temperature tracking for the bias supply. The PIN diode provides proper temperature tracking with the bias supply while exhibiting reduced sensitivity to self-rectification. As a result, the power amplifier's bias supply is more stable and less susceptible to inaccuracies, distortion, and oscillation that may be caused by self-rectification in the presence of high RF fields, especially at UHF and 800 MHz.

Abstract: An improvement to a linear power amplifying system is disclosed which maintains the DC balance of the envelope feedback loop under adverse conditions, thereby improving the accuracy of the system. The improvement is realized through the addition of two differential amplifier stages to the feedback loop. A first differential amplifier 103 is added to the balanced outputs of the synchronous envelope detector 102, which is comprised of an active balanced modulator/demodulator device, to correct for the common-mode DC drift of the detector. An auxiliary feedback loop, comprised of a second differential amplifier 104 and a low-pass filter, compares the average DC value of the envelope error signal to a system reference voltage V.sub.R, and produces a loop gain error signal which corrects for variations in envelope feedback loop gain. The improvement provides envelope modulation transmitters with a substantial reduction in adjacent-channel interference and lower on-channel distortion.