Browsing by Subject "Pulse-width modulation"
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Item Design of high fidelity pulse width modulation inverter(2004-12-18) Jiang, Gang; Davis, John H.Pulse-width modulation (PWM) is well established in power electronics as a basis for inverters with sinusoidal output voltages. It provides two crucial advantages: high power delivery efficiency and easy digital-to-analog demodulation. Thus PWM can be applied in audio signal processing chain as a switching function for a bridge inverter, and a low-pass filter extracts the audio. Meanwhile, this process is nonlinear. So it has often been assumed that implementation of PWM in audio benefited us with its efficiency improvement at the price of distortion. This work explored how PWM can be applied to provide high fidelity audio signal processing with nonlinearity compensation. The distortion effects are analyzed in depth. Noise-shaping processes that reduce quantization errors in the process are described. An inverter is presented that processes information directly in digital form PWM sequence with accurate correction added in the front end noise shaping module. The signal processing chain from digital input to the inverter gate drives is entirely digital. Simulation results confirm that a PWM inverter with efficient nonlinearity compensation can achieve high fidelity in practice.Item High performance pulse width modulated CMOS class D power amplifiers(2012-12) Lu, Jingxue; Gharpurey, RanjitThe objective of this research is to explore circuit techniques and architectures suitable for implementation in digital technologies, that can be used to enhance the efficiency of power stages. Specifically, the use of switching power stages with pulse-width modulation techniques is considered. Switching power stages, such as Class D amplifiers, are inherently well-suited for implementation in deep-submicron CMOS. Pulse-width modulation (PWM) employs discrete amplitude levels and encodes signal information in local time-based averages, and as such can also benefit from such technologies. Additionally PWM does not suffer from quantization noise, and is well-suited for low noise applications. PWM designs, that can be applied for a range of signal bandwidth requirements, spanning several tens to hundreds of kHz are proposed. Applications for these architectures include audio systems, powerline communications and wireless communications. Design challenges and requirements that can arise in different application contexts are considered in the specification of the architectures. A common goal in the definition of the architectures is to minimize complexity of the designs. In the first part of the dissertation, a third-order self-oscillating PWM class-D amplifier for audio applications, that utilizes a hysteretic comparator is described. The design is analyzed and its THD is theoretically determined by employing an equivalent model, that relates the approach to natural sampling pulse-width modulation. The architecture eliminates the requirement for a high-quality carrier generator. A low-cost hysteresis compensation technique is utilized to enhance distortion performance at high output power levels. An implementation is presented in a 0.7um CMOS process. The design achieves a dynamic range (DR) of 116.5 dB, and a THD+N of 0.0012%, while delivering a power of 125 mW into an 8[Omega] load at 1 kHz. The THD+N is under 0.006% up to 90% of the maximum output power. The amplifier can deliver 1.45 W into the load with a THD of 5% with a 5 V power supply. The efficiency is greater than 84% for output power larger than 1 W. The area of the amplifier is 6 mm². The achieved performance indicates that the design is well-suited for high-performance audio applications. A class D line driver that utilizes a phase-locked loop (PLL) based PWM generation technique is presented next. The principle of operation, and implementation details relating to loop stability, linearity and noise performance are analyzed. An implementation is presented in a 130nm CMOS process. The amplifier can deliver 1.2 W into an 6.8[Omega] load with a 4.8 V power supply. The architecture eliminates the requirement for a high-quality carrier generator and a fast, continuous voltage comparator that are often required in PWM implementations. The design can achieve a THD of -65 dB, with a switching frequency that can be as high as 20 MHz. The peak efficiency is 83% for output power larger than 1 W, for a switching frequency of 10 MHz. The area of the amplifier is 2.25 mm². This architecture is potentially suitable for powerline applications. Finally, a phase-locked loop based PWM Cartesian transmitter with the capability to drive switched power amplifiers, such as a Class D power amplifier, is proposed. A phase-locked loop based technique is employed to generate a high-frequency PWM pulse stream centered at 1.28 GHz. The prototype is simulated in a 130 nm CMOS process, and achieves 35% peak efficiency for 17 dBm output power with a carrier frequency of 900 MHz. Operation of the architecture with non-constant envelope modulation, such as that employed in the WCDMA standard, is verified in simulation.Item Time-based oversampled analog-to-digital converters in nano-scale integrated circuits(2014-12) Jung, Woo Young; Hassibi, ArjangIn this research, a time-based oversampling delta-sigma (ΔΣ) ADC architecture is introduced. This system uses time, rather than voltage or current, as the analog variable for its quantizer, and the noise shaping process is realized by modulating the width of a variable-width digital “pulse.” The ΔΣ loop integrator, the quantizer and digital-to-analog converter (DAC) are all time-based circuits and are implemented using digital gates only. Hence, no amplifier or voltage-based circuit is required. The proposed architecture not only offers a viable for nano-scale ‘digital’ IC technologies, but also enables improved circuit performance compared to the state-of-the-art. This is in contrast to conventional voltage-based analog circuit design, whose performance decreases with scaling due to increasingly higher voltage uncertainty due to supply voltage. The proposed architecture allows all digital implementation after the Voltage to Time Converter (VTC) and merged multi-bit quantizer/DAC blocks by taking advantage of delay lines reusable in both quantization and DAC operation. The novelty of this architecture is digital pulse width processing to implement the ΔΣ modulation. It is realized with small area and potentially can take advantage from the process scaling. A 3-bit prototype of this ADC in 0.18 μm CMOS process is implemented, tested, and presented. With an OSR of 36 and a bandwidth of 2 MHz, it achieves a SNDR of 34.6 dB while consuming 1.5 mA from a 1.8 V supply. The core occupies an area of 0.0275 mm² (110μm × 250μm = 0.0275 mm²). The second generation of the architecture was fabricated in IBM 45 nm SOI process. The oversampling frequency of this system is 705 MHz and oversampling ratio of 64. The expected performance is 7-bit effective resolution for a 5.5 MHz bandwidth while consuming 8mW of power and occupying a core area of less than 0.02 mm² (160μm × 120μm = 0.0192 mm²).