Browsing by Author "Shahid, Zeeshan"

This thesis presents the proposed design, working principle, simulation and experimental details of a transformer-less multilevel grid-tied inverter. Grid connectivity requires DC-to-AC inversion with efficient synchronization, reduced total harmonic distortion (THD), real-time control and monitoring. The generation of multi-level output can reduce harmonic with effective sinusoidal wave generation and increased efficiency; however, it requires more complex control and implementation. This research has applications in terms of integration of renewable energy sources with utility grids in stand-alone or industrial generation as well as in case of DG systems. This research proposes a six-level DC supply using novel switching technique with DC-DC converter, embedded with an element of adaptability choosing if Buck or Boost is required for addressing amplitude synchronization. Other issues with fly-back mitigation, low pass filter design for THD reduction and almost near to pure sine wave generation are addressed. The H-bridge transformer-less inverter is designed with four IGBTs (operated at 20kHz) synchronized pulse width modulation (PWM). Two additional fly-back IGBTs are introduced in H-bridge inverter to mitigate fly-back spike generation. For grid connectivity, a versatile technique of phase and frequency synchronization is proposed by using analog to digital converters (ADCs). The feedback and monitoring control scheme is proposed and tested for any abnormal occurrence on grid side. This enables continuous observation of the performance of inverters in terms of power sharing, synchronization and stability. Simulation results are validated experimentally; discussed and analyzed. The DC-DC supply under synchronized condition has a voltage variation range from 308V to 356V. In the proposed design, the IGBTs are reduced to active five. The maximum efficiency achieved is 99.3% (compared to 98.6% on the market) and the lowest is 98% under 1.8kW load. The use of six level generation (0V - 372V) has reduced THD to 2.4% following the EN-50160 and IEEE-1547 international standards.

This dissertation presents the design, working principle, simulation results and analysis of a sub-nanosecond pulse generator. This design is a mix of devices and ideas derived from contemporary reported works with results showing up ringing both at the leading and trailing ends of the pulse. Additionally, experimental implementation requires fabrication on chip designs, making the final product to be an expensive and time consuming venture. The design is simulated using NI MULTISIM tool, and the achieved results are supported by the relevant theory of the components involved. The functionality of the circuit shows how pulses are generated as final product when proceeding from input onward to the output. The resulting pulse is studied for its normal pulse characteristic parameters including rise and fall time, pulse width, amplitude and with a power spectral density. The achieved characteristic parameters show a clear margin of the utility of the suggested circuit when compared with results of contemporary works. The waveform results show that pulses generated are of high quality with a good level of amplitude stability over a wide radio frequency range. Such features are leverage and key elements for high performance impulse radar sensing. The signal power results prove the signal to be of low power, creating a possibility of low power simple transmitter designs well within the FCC defined range. The limitation of this work lies in the laboratory implementation demanding for high response measurement and monitoring equipments for an effective display of the characteristics of pulses in terahertz range.