A 40 MHz Bandwidth, 91% Peak Efficiency, 2.5 W Output Power Supply Modulator With Dual-Mode Sigma–Delta Control and Adaptive Biasing Amplifier for Multistandard Communications

The envelope tracking (ET) design methodology is routinely adopted to improve the efficiency of radio frequency power amplifiers (PAs). One shortcoming of state-of-the-art ET PAs is that their supply modulators are usually designed and optimized for a single communications standard. They are either incompatible in modern communication devices where multiple communications standards are used, and/or the efficiency unoptimized when the devices operate in standards other than the designed standard. To circumvent this shortcoming, a novel supply modulator for multistandard communications is proposed. The proposed design embodies a proposed dual-mode Sigma–Delta control block and an adaptive biasing Class AB amplifier, which allows the supply modulator self-adjusting its operation and optimizing the efficiency according to the application. A prototype supply modulator IC is designed and fabricated using a 180 nm CMOS process. Based on measurements, the proposed supply modulator features the highest static efficiency of 91% and the highest 3 dB backoff static and dynamic efficiency compared to the state-of-the-art supply modulators. When tracking 40 MHz LTE-A envelope signals, the prototype supply modulator achieves a high efficiency of 85% at 1.8 W output power, and the efficiency remains high >80% for a wide range of output power, from 0.5 to 1.8 W.

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