Browsing by Subject "Amplifier"
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Item Linearity and Noise Improvement Techniques Employing Low Power in Analog and RF Circuits and Systems(2012-12-07) Abdel Ghany, EhabThe implementation of highly integrated multi-bands and multi-standards reconfigurable radio transceivers is one of the great challenges in the area of integrated circuit technology today. In addition the rapid market growth and high quality demands that require cheaper and smaller solutions, the technical requirements for the transceiver function of a typical wireless device are considerably multi-dimensional. The major key performance metrics facing RFIC designers are power dissipation, speed, noise, linearity, gain, and efficiency. Beside the difficulty of the circuit design due to the trade-offs and correlations that exist between these parameters, the situation becomes more and more challenging when dealing with multi-standard radio systems on a single chip and applications with different requirements on the radio software and hardware aiming at highly flexible dynamic spectrum access. In this dissertation, different solutions are proposed to improve the linearity, reduce the noise and power consumption in analog and RF circuits and systems. A system level design digital approach is proposed to compensate the harmonic distortion components produced by transmitter circuits? nonlinearities. The approach relies on polyphase multipath scheme uses digital baseband phase rotation pre-distortion aiming at increasing harmonic cancellation and power consumption reduction over other reported techniques. New low power design techniques to enhance the noise and linearity of the receiver front-end LNA are also presented. The two proposed LNAs are fully differential and have a common-gate capacitive cross-coupled topology. The proposed LNAs avoids the use of bulky inductors that leads to area and cost saving. Prototypes are implemented in IBM 90 nm CMOS technology for the two LNAs. The first LNA covers the frequency range of 100 MHz to 1.77 GHz consuming 2.8 mW from a 2 V supply. Measurements show a gain of 23 dB with a 3-dB bandwidth of 1.76 GHz. The minimum NF is 1.85 dB while the input return loss is greater than 10 dB across the entire band. The second LNA covers the frequency range of 100 MHz to 1.6 GHz. A 6 dBm third-order input intercept point, IIP3, is measured at the maximum gain frequency. The core consumes low power of 1.55 mW using a 1.8 V supply. The measured voltage gain is 15.5 dB with a 3-dB bandwidth of 1.6 GHz. The LNA has a minimum NF of 3 dB across the whole band while achieving an input return loss greater than 12 dB. Finally, A CMOS single supply operational transconductance amplifier (OTA) is reported. It has high power supply rejection capabilities over the entire gain bandwidth (GBW). The OTA is fabricated on the AMI 0.5 um CMOS process. Measurements show power supply rejection ratio (PSRR) of 120 dB till 10 KHz. At 10 MHz, PSRR is 40 dB. The high performance PSRR is achieved using a high impedance current source and two noise reduction techniques. The OTA offers a very low current consumption of 25 uA from a 3.3 V supply.Item Low Power High Efficiency Integrated Class-D Amplifier Circuits for Mobile Devices(2015-01-12) Colli-Menchi, Adrian IsraelThe consumer?s demand for state-of-the-art multimedia devices such as smart phones and tablet computers has forced manufacturers to provide more system features to compete for a larger portion of the market share. The added features increase the power consumption and heat dissipation of integrated circuits, depleting the battery charge faster. Therefore, low-power high-efficiency circuits, such as the class-D audio amplifier, are needed to reduce heat dissipation and extend battery life in mobile devices. This dissertation focuses on new design techniques to create high performance class-D audio amplifiers that have low power consumption and occupy less space. The first part of this dissertation introduces the research motivation and fundamentals of audio amplification. The loudspeaker?s operation and main audio performance metrics are examined to explain the limitations in the amplification process. Moreover, the operating principle and design procedure of the main class-D amplifier architectures are reviewed to provide the performance tradeoffs involved. The second part of this dissertation presents two new circuit designs to improve the audio performance, power consumption, and efficiency of standard class-D audio amplifiers. The first work proposes a feed-forward power-supply noise cancellation technique for single-ended class-D amplifier architectures to improve the power-supply rejection ratio across the entire audio frequency range. The design methodology, implementation, and tradeoffs of the proposed technique are clearly delineated to demonstrate its simplicity and effectiveness. The second work introduces a new class-D output stage design for piezoelectric speakers. The proposed design uses stacked-cascode thick-oxide CMOS transistors at the output stage that makes possible to handle high voltages in a low voltage standard CMOS technology. The design tradeoffs in efficiency, linearity, and electromagnetic interference are discussed. Finally, the open problems in audio amplification for mobile devices are discussed to delineate the possible future work to improve the performance of class-D amplifiers. For all the presented works, proof-of-concept prototypes are fabricated, and the measured results are used to verify the correct operation of the proposed solutions.Item Optimized multi-stage amplifier compensation method for wide load variations(2012-08) Marijanovic, Srdjan; Akinwande, Deji; Ranjbar, MohammadDue to variations in process, voltage, and temperature (PVT), amplifiers are almost solely designed for use in a negative feedback loop. The feedback loop mitigates the effect of PVT, however maintaining stability becomes the main design challenge. Further, multi-stage amplifiers with high open-loop gain are used for powering headphone speakers in modern portable electronics. As there are many different headphone manufacturers and compatibility specifications, headphone amplifiers are subjected to a wide variation in capacitive and resistive loads, which further complicates the stability upkeep. This thesis explores a two-stage (Common-Gate Feedback) and three-stage (Impedance Adapting Compensation) amplifier topology with respect to performance under wide load variations. For both compensation topologies, an analytical analysis is presented, followed by a design proposal for a headphone amplifier application. Finally, the trade-offs for maintaining stability under varying loads are discussed.