Continuous Mode High Efficiency Power Amplifier Design for X Band

This thesis is focused on the investigation and implementation of novel techniques for the design of X band (8 - 12GHz) power amplifiers. One of the main topics is the expansion and novel implementation of continuous mode theory, with the intention of improving the bandwidth and efficiency of X band power amplifiers. This work builds upon the Class B/J continuous mode theory to incorporate cases where <[ZF0] 6= RL, not described by the original Class B/J theory, with a tool called the “clipping contour”. The clipping contour tool shows a graphical representation on the Smith chart of the boundary between impedances generating a voltage waveform which will modulate or “clip” the current waveform, and a voltage waveform which will leave the current waveform unaltered. This non-clipping space is shown, with measured load pull and amplifier data, to represent the maximum efficiency case for a given ZF0, thus the clipping contour tool thus gives designers the ability to predict the areas of highest efficiency and power given any ZF0, without the need to use costly, time consuming multi harmonic load pull techniques. Push pull amplifiers using quarter wave coupled line baluns are proposed as an ideal matching topology to exploit this new tool. Various balun topologies are studied using a novel extended transmission line model. This model is shown to predict accurately and explain the “trace separation” effect seen in planar baluns and not their 3D coaxial cable equivalents. It also forms the basis of analysis which results in a powerful new equation capable of guaranteeing the elimination of trace separation completely, without compromising performance. This equation is used to design an optimal balun which possesses the largest fractional bandwidth (130%) of any balun ever published on single layer thin film Alumina, whilst simultaneously eliminating trace separation. The optimised Alumina baluns are used to construct push pull output demonstrator circuits which show efficiencies of 40% over greater than an octave bandwidth, a significant advancement of any other comparable published work. These techniques demonstrate the potential to exceed double octave bandwidths with efficiencies greater than 40% once optimised. Initial investigations on MMIC and 2.5D processes show the potential to replicate the Alumina performance over octave and decade bandwidths respectively

60 Watts Broadband Push Pull RF Power Amplifier Using LTCC Technology

The continuous increase in wireless usage forces an immense pressure on wireless communication in terms of increased demand and spectrum scarcity. Service providers for communication services had no choice but to allocate new parts of the spectrum and present new communication standards that are more spectrally efficient. Communication is not only limited to mobile phones but recently attention has been given to intelligent transportation systems (ITS) where cars will be given a significant place in the communication network. Vehicular Ad-Hoc Network (VANET) is already assigned a slice of the spectrum at 5.9GHz using the IEEE802.11p standard also known as Dedicated Short-Range Communication (DSRC); however, this assignment will have limited range and functionality at first, and users are expected to depend on existing wireless mobile channels for some services such as video streaming and car entertainment. Therefore, it is essential to integrate existing wireless mobile communication standards into the skeleton of ITS at launch and most probably permanently. An investigation was carried out regarding the existing communication standards including wireless local area networks (WLAN) and it was found that frequency bands from 400MHz up to 6GHz are being used in various regions around the world. It is also noted that current state of the art transceivers are composed of several transmitter front-ends targeting certain bands and standards. However, the more standards to be supported the more components to be added and the higher the cost not to mention the limited space in mobile devices. Multimode Multiband (MMMB) transmitters are therefore proposed as a potential solution to the existing redundancy in the number of front-end paths in modern transmitters. Broadband amplifiers are an essential part of any MMMB transmitter and they are also among the most challenging especially for high power requirements. This work explains why single ended topologies with efficiencies higher than 50% have a fundamental bandwidth limit such that the highest frequency of operation must be lower than twice the lowest frequency of operation. Hence, Push-Pull amplifier topology is being proposed as it was found that it has inherent broadband capabilities exceeding those of other topologies with comparable efficiency. The major advantage of Push-Pull power amplifiers is its capability of isolating the even harmonics present in the even mode operation of a Push-Pull amplifier from the less critical odd mode harmonics and the fundamental frequency. This separation between even and odd signals comes from the inclusion of a Balun at the output of push-pull amplifiers. Such separation makes it possible to operate amplifiers beyond the existing limit of single ended power amplifiers. To prove the concept, several Baluns were designed and tested and a comparison was made between different topologies in terms of balance, bandwidth and odd and even mode performances; moreover, to illustrate the concept a Push-Pull power amplifier design was implemented using the multilayer Low Temperature Co-fired Ceramics (LTCC) technology with a bandwidth ratio of more than 100%