Abstract: A method and apparatus for calibrating a voltage-controlled device in a control loop is disclosed. The method and apparatus of the present invention maintains a control voltage of a voltage-controlled device within a high tuning sensitivity range, and thus improves the performance of the voltage-controlled device. The present inventive method and apparatus features a voltage windowing method wherein a high tuning sensitivity window is a subset of the low tuning sensitivity window. In one embodiment, the present invention maintains a control voltage within a predetermined tuning sensitivity window or range. In another embodiment, the present inventive method and apparatus calibrates a PLL that includes multiple VCOs. In yet another embodiment, the present invention calibrates control voltages to account for changes in operating temperature.

Abstract: A simple, scalable cross-degeneration circuit topology is described. The inventive cross-degeneration method and apparatus provides a circuit design having substantially improved linearity as compared to traditional circuit designs having similar power consumption. The improvement in linearity is achieved without unduly increasing circuit noise and without substantially reducing circuit bandwidth. Using the present inventive method and apparatus, a fixed circuit configuration can be used to accommodate a continuous range of specifications simply by varying component values, in contrast to the prior art requirements of providing additional devices or modifying device wiring. The inventive topology can be implemented using bipolar technologies and conventional MOS processes operating above threshold. Additionally, the inventive circuits can be implemented using other three-terminal (or multi-terminal) amplifying device technologies.

Abstract: A low-diversity antenna diversity receiver suitable for TDMA PCS handset implementation employing two diversity branches. The receiver is capable of selecting a diversity scheme which is anticipated to give optimum signal reception among a plurality of diversity schemes installed on the receiver. This receiver, more conveniently termed multi-diversity receiver comprises a single conventional wireless digital receiver chain augmented with a few additional low-cost passive RF components and minor control circuits. A plurality of diversity algorithms, for example, selection diversity (SD), equal-gain combining (EGC) or interference-reduction combining (IRC) scheme, which are suitable for implementing on this multi-diversity receiver are also described. Simulation results showing performance of this multi-diversity receiver are also presented.

Abstract: A receiver for down-converting a modulated carrier into its in-phase (I) and quadrature (Q) components for further processing is proposed. This is accomplished using a sampling method in which the signal is sampled directly using a sampling circuit which is driven by a single sampling clock frequency substantially lower than the carrier frequency while allowing the I and Q components to be precisely obtained. Each of the signal samples comprises sub-samples taken successively which represent the in-phase, quadrature, negative in-phase and negative quadrature components of the signal. The negative components permit flexible application of the invention in several modes, including differential mode for the removal of common-mode noise. The invention is useful because it provides an integrated circuit means for precisely obtaining I and Q components of a very high frequency modulated carrier.