Abstract: This invention controls and modulates switched-mode power amplifiers to enable the production of signals that include amplitude modulation (and possibly, but not necessarily, phase modulation), the average power of which may be controlled over a potentially wide range.

Abstract: The present invention, generally speaking, provides for high-efficiency power control of a high-efficiency (e.g., bard-limiting or switch-mode) power amplifier in such a manner as to achieve a desired control or modulation. Unlike the prior art, feedback is not required. That is, the amplifier may be controlled without continuous or frequent feedback adjustment. In one embodiment, the spread between a maximum frequency of the desired modulation and the operating frequency of a switch-mode DC-DC converter is reduced by following the switch-mode converter with an active linear regulator. The linear regulator is designed so as to control the operating voltage of the power amplifier with sufficient bandwidth to faithfully reproduce the desired amplitude modulation waveform. The linear regulator is further designed to reject variations on its input voltage even while the output voltage is changed in response to an applied control signal.

Abstract: The present invention, generally speaking, achieves a highly efficient line driver for high crest-factor signals such as DMT/ADSL signals. In an exemplary embodiment, a digital signal produced by a digital signal processor or the like is processed by a sigma-delta modulator (SDM) to produce one or more binary signal pairs. The signals of a signal pair are low-pass filtered, if necessary, and applied across the winding of a transformer. The transformer has a single secondary winding connected to the line and may has as many primary windings as the number of signal pairs. The transformer may have a unity turns ratio or may have a turns ratio for accomplishing voltage step-up. For one signal pair, the number of possible resulting signals levels on the secondary side is three, for two signal pairs five, etc. Using more than two signal levels, it becomes possible to recreate from the digital signals the corresponding analog waveform with the required accuracy.

Abstract: The present invention, generally speaking, satisfies the foregoing requirements using in combination within a frequency synthesis loop an SDM-based synthesizer and an SDM-based frequency digitizer. Since both blocks are SDM-based, the resulting signals can be differenced and filtered to produce a control signal for an oscillator. Low noise (and low spurs), fine frequency resolution and fast switching times may all be achieved simultaneously.

Abstract: The present invention, generally speaking, provides a highly efficient RF power amplifier having a large output dynamic range. The amplifier avoid the large power dissipation that occurs in the LINC combiner at lower output levels. In general, this is achieved by using power-controlled switch-mode power amplifiers to vary output power at large power outputs, and reverting to LINC only at low output powers. Thus the present invention achieves the desirable combination of high efficiency at all output powers, while maintaining the fine output power control of the LINC method. More particularly, the power amplifier is based on a highly efficient structure in which amplitude modulation/power control of the output of an RF amplifier is achieved by operating the amplifier in switch mode and varying the power supply of the amplifier, as described more fully in U.S. patent application Ser. No. 09/637,269 entitled High-Efficiency Modulating RF Amplifier, filed Aug. 10, 2000 and incorporated herein by reference.

Abstract: A first amplified signal is produced at a first amplifier, a second amplified signal is produced at a second amplifier, and a differential signal representing difference between the first amplified signal and the second amplified signal is generated at a subtraction unit receiving the first amplified signal and second amplified signal, the differential signal being a final amplified signal having a final modulated amplitude and a final modulated phase.

Abstract: This invention controls and modulates switched-mode power amplifiers to enable the production of signals that include amplitude modulation (and possibly, but not necessarily, phase modulation), the average power of which may be controlled over a potentially wide range.

Abstract: The present invention, generally speaking, provides for bandwidth switching of a PLL in a simple, effective manner. In accordance with one embodiment, a phase lock loop includes a controlled oscillator responsive to a control voltage for producing an output signal of some output frequency; a comparator responsive to a feedback signal derived from the output signal and to a reference signal for producing at least one error signal; a charge pump circuit including multiple pairs of unidirectional current sources (or, alternatively, multiple bidirectional current sources); a control circuit responsive to a control signal for activating one or more pairs of unidirectional current sources, at the same time deactivating one or more pairs of unidirectional current sources; and a loop filter responsive to the multiple pairs of unidirectional current sources for producing the control voltage governing the output frequency.

Abstract: A first amplified signal is produced at a first amplifier, a second amplified signal is produced at a second amplifier, and a differential signal representing difference between the first amplified signal and the second amplified signal is generated at a subtraction unit receiving the first amplified signal and second amplified signal, the differential signal being a final amplified signal having a final modulated amplitude and a final modulated phase.

Abstract: The present invention, generally speaking, provides methods and apparatus for avoiding saturation of a transistor, with particular application to communications signal amplifiers. In accordance with one aspect of the invention, feedback circuitry is provided to control a transistor in accordance with a control signal. The combination of current monitor and a threshold comparator detects when the base current of the transistor exceeds a threshold, indicative of the onset of saturation. Feedback control is then modified to prevent saturation.

Abstract: The present invention, generally speaking, provides a circuit that combines the features of a voltage doubler and a boost regulator to achieve a small and efficient voltage boost regulator. A capacitor is used to provide a primary voltage boost effect. An inductor is used to provide further regulation, either further boost or buck. Instead of requiring non-overlapping clock signals, the relative timing and overlap of the clock signals determines the regulation achieved. The inductor can be made significantly smaller than in comparable boost circuits, facilitating size reduction.

Abstract: The present invention, generally speaking, provides methods and apparatus for producing an amplitude modulated communications signal, in which a constant-envelope carrier signal is modified in response to a power control signal to produce a modified constant-envelope carrier signal. The modified constant-envelope carrier signal is amplified in response to an amplitude modulation signal to produce a communications signal having amplitude modulation and having an average output power proportional to a signal level of the modified constant-envelope carrier signal. This manner of operation allows wide dynamic range of average output power to be achieved. Because amplitude modulation is applied after amplitude varying circuitry used to produce the modified constant-envelope carrier signal, the amplitude modulation is unaffected by possible non-linearities of such circuitry.

Abstract: The present invention, generally speaking, provides for bandwidth switching of a PLL in a simple, effective manner. In accordance with one embodiment, a phase lock loop includes a controlled oscillator responsive to a control voltage for producing an output signal of some output frequency; a comparator responsive to a feedback signal derived from the output signal and to a reference signal for producing at least one error signal; a charge pump circuit including multiple pairs of unidirectional current sources (or, alternatively, multiple bidirectional current sources); a control circuit responsive to a control signal for activating one or more pairs of unidirectional current sources, at the same time deactivating one or more pairs of unidirectional current sources; and a loop filter responsive to the multiple pairs of unidirectional current sources for producing the control voltage governing the output frequency.

Abstract: The present invention, generally speaking, provides a highly efficient RF power amplifier having a large output dynamic range. The amplifier avoid the large power dissipation that occurs in the LINC combiner at lower output levels. In general, this is achieved by using power-controlled switch-mode power amplifiers to vary output power at large power outputs, and reverting to LINC only at low output powers. Thus the present invention achieves the desirable combination of high efficiency at all output powers, while maintaining the fine output power control of the LINC method. More particularly, the power amplifier is based on a highly efficient structure in which amplitude modulation/power control of the output of an RF amplifier is achieved by operating the amplifier in switch mode and varying the power supply of the amplifier, as described more fully in U.S. patent application Ser. No. 09/637,269 entitled High-Efficiency Modulating RF Amplifier, filed Aug. 10, 2000 and incorporated herein by reference.

Abstract: The present invention, generally speaking, provides methods and apparatus for avoiding saturation of a transistor, with particular application to communications signal amplifiers. In accordance with one aspect of the invention, feedback circuitry is provided to control a transistor in accordance with a control signal. The combination of current monitor and a threshold comparator detects when the base current of the transistor exceeds a threshold, indicative of the onset of saturation. Feedback control is then modified to prevent saturation.

Abstract: The present invention, generally speaking, satisfies the foregoing requirements using in combination within a frequency synthesis loop an SDM-based synthesizer and an SDM-based frequency digitizer. Since both blocks are SDM-based, the resulting signals can be differenced and filtered to produce a control signal for an oscillator. Low noise (and low spurs), fine frequency resolution and fast switching times may all be achieved simultaneously.

Abstract: A packaging technique for electronic devices includes wafer fabrication of contacts that wrap down the inside surface of a substrate post. Inherently reliable contacts suitable for a variety of devices can be formed, via a simple fabrication process, with good wafer packing density. A trench is formed in the top surface of a substrate parallel to the edge of its electronic circuit. A gold beam wire extends from a connection point within the circuit into the trench. Unless an insulative substrate is used, the wire runs over an insulating layer that ends part way through the trench. After epoxy encapsulating the top of the substrate, it is back planed to form the bottom surface of the post. Then it is selectively back etched, to expose the bottom surface of the wire, to form the inside surface of the post, and to form the bottom surface of the finished device. A solderable lead wire runs from the exposed gold wire, down the inside surface of the post, and across its bottom.

Abstract: The present invention, generally speaking, achieves a highly efficient line driver for high crest-factor signals such as DMT/ADSL signals. In an exemplary embodiment, a digital signal produced by a digital signal processor or the like is processed by a sigma-delta modulator (SDM) to produce one or more binary signal pairs. The signals of a signal pair are low-pass filtered, if necessary, and applied across the winding of a transformer. The transformer has a single secondary winding connected to the line and may has as many primary windings as the number of signal pairs. The transformer may have a unity turns ratio or may have a turns ratio for accomplishing voltage step-up. For one signal pair, the number of possible resulting signals levels on the secondary side is three, for two signal pairs five, etc. Using more than two signal levels, it becomes possible to recreate from the digital signals the corresponding analog waveform with the required accuracy.

Abstract: A packaging technique for electronic devices includes wafer fabrication of contacts on the bottom surface of the substrate underneath the active circuit. Inherently reliable contacts suitable for a variety of devices can be formed, via a simple fabrication process, with good wafer packing density. In one embodiment, a trench is formed in the top surface of a substrate parallel to the edge of its electronic circuit. A gold wire extends from a connection point within the circuit into the trench. The gold wire may run over an insulating layer that ends part way through the trench. After epoxy encapsulating the top of the substrate, it is back thinned to expose the bottom surface of the gold wire. Either the back thinning is selective so as to form a substrate standoff, or an epoxy standoff is applied to the bottom of the substrate. A solderable wire runs onto the standoff from the gold wire exposed on the protrusion, possibly over another insulation layer.

Abstract: A packaging technique for electronic devices includes wafer fabrication of contacts on the bottom surface of the substrate underneath the active circuit. Inherently reliable contacts suitable for a variety of devices can be formed, via a simple fabrication process, with good wafer packing density. In one embodiment, a trench is formed in the top surface of a substrate parallel to the edge of its electronic circuit. A gold wire extends from a connection point within the circuit into the trench. The gold wire may run over an insulating layer that ends part way through the trench. After epoxy encapsulating the top of the substrate, it is back thinned to expose the bottom surface of the gold wire. Either the back thinning is selective so as to form a substrate standoff, or an epoxy standoff is applied to the bottom of the substrate. A solderable wire runs onto the standoff from the gold wire exposed on the protrusion, possibly over another insulation layer.