RF Power Amplifier and Its Envelope Tracking

This dissertation introduces an agile supply modulator with optimal transient performance for the envelope tracking supply in linear power amplifiers. For this purpose, an on-demand current source module, the bang-bang transient performance enhancer (BBTPE), is proposed. Its objective is to follow fast variations in input signals with reduced overshoot and settling time without deteriorating the steady-state performance of the buck regulator. The proposed approach enables fast system response through the BBTPE and an accurate steady-state output response through a low switching ripple and power efficient dynamic buck regulator. Fast output response with the help of the added module induces a slower rise of inductor current in the buck converter that further assists the proposed system to reduce both overshoot and settling time. To demonstrate the feasibility of the proposed solution, extensive simulations and experimental results from a discrete system are reported. The proposed supply modulator shows 80% improvement in rise time along with 60% reduction in both overshoot and settling time compared to the conventional dynamic buck regulator-based solution. Experimental results for a PA using the LTE 16-QAM 5 MHz standard shows improvement of 7.68 dB and 65.1% in ACPR and EVM, respectively. In a polar power amplifier, the input signal splits into phase and amplitude components using a non-linear conversion operation. This operation broadens the spectrum of the polar signal components. The information of amplitude and phase contains spectral images due to the sampling operation in non-linear conversion operation. These spectral images can be large and cause out-of-band emission in the output spectrum. In addition, during the recombination process of phase and amplitude, a delay mismatch between amplitude and phase signals, which can occur due to separate processing paths of amplitude and phase signals, causes out-of-band emissions, also known as spectral regrowth. This dissertation presents solutions to both of the issues of digital polar power amplifier: spectral images and delay mismatch. In order to reduce the problem of spectral images, interpolation of phase and amplitude is proposed in this work. This increases the effective sampling frequency of the amplitude and phase, which helps to improve the linearity by around 10 dB. In addition, a novel calibration scheme is proposed here for the delay mismatch between phase and amplitude path in a digital polar power amplifier. The scheme significantly reduces the spectral regrowth. The scheme uses the same path for phase and amplitude delay calculation after the recombination that allows having a robust calibration. Furthermore, it can be executed during the empty transmission slots. The proposed scheme is designed in a 40 nm CMOS technology and simulated with a 64-QAM IEEE 802.11n wireless standard. The scheme achieved 7.57 dB enhancement in ACLR and 84.35% improvement in EVM for a 3.5 ns mismatch in phase and amplitude path

RF Power Amplifier and Its Envelope Tracking

This dissertation introduces an agile supply modulator with optimal transient performance for the envelope tracking supply in linear power amplifiers. For this purpose, an on-demand current source module, the bang-bang transient performance enhancer (BBTPE), is proposed. Its objective is to follow fast variations in input signals with reduced overshoot and settling time without deteriorating the steady-state performance of the buck regulator. The proposed approach enables fast system response through the BBTPE and an accurate steady-state output response through a low switching ripple and power efficient dynamic buck regulator. Fast output response with the help of the added module induces a slower rise of inductor current in the buck converter that further assists the proposed system to reduce both overshoot and settling time. To demonstrate the feasibility of the proposed solution, extensive simulations and experimental results from a discrete system are reported. The proposed supply modulator shows 80% improvement in rise time along with 60% reduction in both overshoot and settling time compared to the conventional dynamic buck regulator-based solution. Experimental results for a PA using the LTE 16-QAM 5 MHz standard shows improvement of 7.68 dB and 65.1% in ACPR and EVM, respectively. In a polar power amplifier, the input signal splits into phase and amplitude components using a non-linear conversion operation. This operation broadens the spectrum of the polar signal components. The information of amplitude and phase contains spectral images due to the sampling operation in non-linear conversion operation. These spectral images can be large and cause out-of-band emission in the output spectrum. In addition, during the recombination process of phase and amplitude, a delay mismatch between amplitude and phase signals, which can occur due to separate processing paths of amplitude and phase signals, causes out-of-band emissions, also known as spectral regrowth. This dissertation presents solutions to both of the issues of digital polar power amplifier: spectral images and delay mismatch. In order to reduce the problem of spectral images, interpolation of phase and amplitude is proposed in this work. This increases the effective sampling frequency of the amplitude and phase, which helps to improve the linearity by around 10 dB. In addition, a novel calibration scheme is proposed here for the delay mismatch between phase and amplitude path in a digital polar power amplifier. The scheme significantly reduces the spectral regrowth. The scheme uses the same path for phase and amplitude delay calculation after the recombination that allows having a robust calibration. Furthermore, it can be executed during the empty transmission slots. The proposed scheme is designed in a 40 nm CMOS technology and simulated with a 64-QAM IEEE 802.11n wireless standard. The scheme achieved 7.57 dB enhancement in ACLR and 84.35% improvement in EVM for a 3.5 ns mismatch in phase and amplitude path

Doctor of Philosophy

dissertationHigh speed wireless communication systems (e.g., long-term evolution (LTE), Wi-Fi) operate with high bandwidth and large peak-to-average power ratios (PAPRs). This is largely due to the use of orthogonal frequency division multiplexing (OFDM) modulation that is prevalent to maximize the spectral efficiency of the communication system. The power amplifier (PA) in the transmitter is the dominant energy consumer in the radio, largely because of the PAPR of the input signal. To reduce the energy consumption of the PA an amplifier that simultaneously achieves high efficiency and high linearity. Furthermore, to lower the cost for high volume production, it is desirable to achieve a complete System-on-Chip (SoC) integration. Linear amplifiers (e.g., Class-A, -B, -AB) are inefficient when amplifying signals with large PAPR that is associated by high peak-to-average modulation techniques such as LTE. OFDM. Switching amplifiers (e.g., Class-D, -E, -F) are very promising due to their high efficiency when compared to their linear amplifier counterparts. Linearization techniques for switching amplifiers have been intensively investigated due to their limited sensitivity to the input amplitude of the signal. Deep-submicron CMOS technology is mostly utilized for logic circuitry, and the Moore's law scaling of CMOS optimizes transistors to operate as high-speed and low-loss switches rather than high gain transistors. Hence, it is advantageous to use transistors in switching mode as switching amplifies and use high-speed digital logic circuitry to implement linearization systems and circuitry. In this work, several linearization architectures are investigated and demonstrated. An envelope elimination and restoration (EER) transmitter that comprises a class-E power amplifier and a 10-bit digital-to-analog converter (DAC) controlled current modulator is investigated. A pipelined switched-capacitor DAC is designed to control an open-loop transconductor that operates as a current modulator, modulating the amplitude of the current supplied to a class-E PA. Such a topology allows for increased filtering of the quantization noise that is problematic in most digital PAs (DPA). The proposed quadrature and multiphase architecture can avoid the bandwidth expansion and delay mismatch associated with polar PAs. The multiphase switched capacitor power amplifier (SCPA) was proposed after the quadrature SCPA and it significantly improves the power efficiency

Blocker Tolerant Radio Architectures

Future radio platforms have to be inexpensive and deal with a variety of co- existence issues. The technology trend during the last few years is towards system- on-chip (SoC) that is able to process multiple standards re-using most of the digital resources. A major bottle-neck to this approach is the co-existence of these standards operating at different frequency bands that are hitting the receiver front-end. So the current research is focused on the power, area and performance optimization of various circuit building blocks of a radio for current and incoming standards. Firstly, a linearization technique for low noise amplifiers (LNAs) called, Robust Derivative Superposition (RDS) method is proposed. RDS technique is insensitive to Process Voltage and Temperature (P.V.T.) variations and is validated with two low noise transconductance amplifier (LNTA) designs in 0.18µm CMOS technology. Measurement results from 5 dies of a resistive terminated LNTA shows that the pro- posed method improves IM3 over 20dB for input power up to -18dBm, and improves IIP_(3) by 10dB. A 2V inductor-less broadband 0.3 to 2.8GHz balun-LNTA employing the proposed RDS linearization technique was designed and measured. It achieves noise figure of 6.5dB, IIP3 of 16.8dBm, and P1dB of 0.5dBm having a power consumption of 14.2mW. The balun LNTA occupies an active area of 0.06mm2. Secondly, the design of two high linearity, inductor-less, broadband LNTAs employing noise and distortion cancellation techniques is presented. Main design issues and the performance trade-offs of the circuits are discussed. In the fully differential architecture, the first LNTA covers 0.1-2GHz bandwidth and achieves a minimum noise figure (NFmin) of 3dB, IIP_(3) of 10dBm and a P_(1dB) of 0dBm while dissipating 30.2mW. The 2^(nd) low power bulk driven LNTA with 16mW power consumption achieves NFmin of 3.4dB, IIP3 of 11dBm and 0.1-3GHz bandwidth. Each LNTA occupy an active area of 0.06mm2 in 45nm CMOS. Thirdly, a continuous-time low-pass ∆ΣADC equipped with design techniques to provide robustness against loop saturation due to blockers is presented. Loop over- load detection and correction is employed to improve the ADC’s tolerance to blockers; a fast overload detector activates the input attenuator, maintaining the ADC in linear operation. To further improve ADC’s blocker tolerance, a minimally-invasive integrated low-pass filter that reduces the most critical adjacent/alternate channel blockers is implemented. An ADC prototype is implemented in a 90nm CMOS technology and experimentally it achieves 69dB dynamic range over a 20MHz bandwidth with a sampling frequency of 500MHz and 17.1mW of power consumption. The alternate channel blocker tolerance at the most critical frequency is as high as -5.5dBFS while the conventional feed-forward modulator becomes unstable at -23.5dBFS of blocker power. The proposed blocker rejection techniques are minimally-invasive and take less than 0.3µsec to settle after a strong agile blocker appears. Finally, a new radio partitioning methodology that gives robust analog and mixed signal radio development in scaled technology for SoC integration, and the co-design of RF FEM-antenna system is presented. Based on the proposed methodology, a CMOS RF front-end module (FEM) with power amplifier (PA), LNA and transmit/receive switch, co-designed with antenna is implemented. The RF FEM circuit is implemented in a 32nm CMOS technology. Post extracted simulations show a noise figure < 2.5dB, S_(21) of 14dB, IIP3 of 7dBm and P1dB of -8dBm for the receiver. Total power consumption of the receiver is 11.8mW from a 1V supply. On the trans- mitter side, PA achieves peak RF output power of 22.34dBm with peak power added efficiency (PAE) of 65% and PAE of 33% with linearization at -6dB power back off. Simulations show an efficiency of 80% for the miniaturized dipole antenna

Digital Predistortion for High Efficiency Power Amplifier Architectures Using a Dual-input Modeling Approach

In this paper, a novel model is proposed for dual-input high efficiency power amplifier (PA) architectures, such as envelope tracking (ET) and varactor-based dynamic load modulation (DLM). Compared to the traditional single-input modeling approach, the proposed model incorporates the baseband supply voltage/load control as an input. This advantage makes the new approach capable to achieve maximized average power-added efficiency (PAE) and minimized output distortion simultaneously. Furthermore, the new approach has shown to be robust towards time misalignment between the RF input and baseband supply voltage/load control signals, and it can be applied with a reduced-bandwidth baseband supply voltage/load control. Experiments have been performed in a varactor-based DLM PA architecture to evaluate the new modeling approach. The results show that it can achieve 9 dB and 7 dB better performance than the traditional approaches in terms of adjacent channel leakage ratio and normalized mean square error, respectively. At the same time, the average PAE is maximized. Similar results have been achieved with the proposed model even when reduced-bandwidth baseband load control signal is used or time misalignment between the RF and baseband load control input signals exists. Although the new approach is only tested with DLM architecture in this paper, it is very general and can be applied to ET architectures as well

Design and Characterization of Power Converters and Amplifiers for Supply-Modulation based Transmitter Architectures

The rapid evolution of telecommunication systems has strongly influenced our lives, and the way we communicate and exchange information. Nevertheless, much progress is expected to happen in the next years with the introduction of new generations of wireless communications standards, which require signals with large bandwidth and very high Peak-to-Average Power Ratio (PAPR) in order to enhance the spectral efficiency and maximize the data rate. However, such developments can only take place through the evolution of Radio-Frequency (RF) which should be capable of working at higher frequencies, higher bandwidth and with higher efficiencies than before. In order to meet these demanding specifications, transmitter architectures have to evolve from a single linear RF Power-Amplifier (PA) into more complex architectures. Envelope Tracking (ET) is one of the most promising solutions for the efficiency-enhancement of next generation transmitters. The research described in this thesis aims to provide solutions to enhance the efficiency of the RF PA by means of an ET architecture. To this purpose, a novel discrete level supply modulator is investigated, which is based on a direct digital-to-analog power conversion. This supply modulator is capable of synthesizing eight voltage steps by means of three isolated voltage sources, thus behaving like a Power Digital-to-Analog Converter (Power-DAC). A hybrid version of the Power-DAC exploiting very fast GaN devices is developed and tested with an L-band PA achieving efficiency improvement up to 13% with 10 MHz of bandwidth. Furthermore, a monolithic GaN version of the Power-DAC is prototyped and tested with an X-band PA achieving efficiency improvement up to 20% and bandwidth of 20 MHz. This supply modulator is tested with outphasing PAs showing promising results with modulated signals and efficiency improvement up to 9%. Finally, dispersive phenomena, which affect PAs and switches in supply modulators, are investigated, characterized and modeled

Amplitude and phase modulation techniques for an asymmetric multi-level outphasing transmitter

Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2012.Cataloged from PDF version of thesis.Includes bibliographical references (p. 93-95).New techniques for improving outphasing transmitters show potential of breaking the traditional linearity-efficiency trade-off by using highly efficient non-linear switching Power Amplifiers (PAs). This work focuses on two of the main building blocks of modem outphasing systems, the power supply switching network and the phase modulator. Both are ubiquitous building blocks in modern RF transceivers, and both are especially critical in Asymmetric Multilevel Outphasing (AMO) systems. A design of the power supply network and control scheme is proposed for an implementation in mm-wave operating frequencies as part of a complete transmitter in 45nm SOI CMOS utilizing four discrete power supplies and achieving data rates of up to 4GS/s. The design includes analysis and simulation of the control signal data path requirements for optimal system operation as well as switch optimization and effects of the driving strength on overall system performance. A new design concept is proposed for a phase modulator utilizing the phase shifthing capabilities of a resonant tank and the ability to seperately control the circuit properties via its components. A prototype in 65nm CMOS achieves 12 bits of resolution, with an Effective Number Of Bits (ENOB) of 10.2 bits and very fast settling time of less than 5 carrier cycles. The chip is also tested as a stand alone transmitter showing an EVM of less than 5% for 8-PSK modulation at maximum data rate, meeting the requirements for operation at the Medical Implant Communication Services (MICS) band.by Gilad Yahalom.S.M

Analysis and Design of CMOS Radio-Frequency Power Amplifiers

The continuous advancement of semiconductor technologies, especially CMOS technology, has enabled exponential growth of the wireless communication industry. This explosive growth in turn has completely changed people’s lives. The CMOS feature size scale down greatly benefits digital logic integrations, which result in more powerful, versatile, and economical digital signal processing. Further research and development has pushed analog, mixed-signal, and even radio-frequency (RF) circuit blocks to be implemented and integrated in CMOS. Future generations of wireless communication call for even further level of integration, and as of now, the only circuit block that is rarely integrated in CMOS along with other parts of the system is the power amplifier (PA). Due to the fact that the PA in a wireless communication system is the most power-hungry circuit block, the integration of RF PA in CMOS would potentially not only save the cost of the wireless communication system real estate, but also reduce power consumption since die-to-die connection loss can be eliminated. RF PA design involves handling large amounts of voltage and current at the radio frequencies, which in the present wireless communication standards are in the range of giga-hertz. Therefore, a good understanding of many aspects related to RF PA design is necessary. Theoretical analysis of the communication system, nonlinear effects of the PA, as well as the impedance matching network is systematically presented. The analysis of the nonlinear effects proposes a formal mathematical description of the multitone nonlinearity, and through its relationship with two-tone test, the proposed PA design methodology would greatly reduce the design time while improving the design accuracy. A thorough analysis of the available architecture and design techniques for efficiency and linearity enhancement of RF PA shows that despite tremendous amounts of research and development into this topic, the fundamental tradeoff between the two still limits the RF PA implementation largely within SiGe, GaAs, and InP technologies. A RF PA for Wideband Code-Division Multiple Access (WCDMA) application standard is proposed, designed, and implemented in CMOS that demonstrates the proposed segmentation technique that resolved the main tradeoff between power efficiency and linearity. The innovative architecture developed in this work is not limited to applications in the WCDMA communication protocol or the CMOS technology, although CMOS implementation would take advantage of the readily available digital resources