The communication industry leverages technical advancements in various domains, such as semiconductors, optics, signal processing, and integrated circuits, leading to remarkable evolution over the last decades. This progress paves the way for ever-expanding networks and systems that demand more information capacity, which results in exponential data growth. Unique wireless concepts and technologies are emerging to enable next-generation communication. This dissertation explores the techniques and architectures to realize massive MIMO, extreme bandwidths through channel aggregation, TeraHertz band utilization, and the use of III-V technologies to enhance performance via heterogeneous integration, ultimately maintaining ubiquitous connectivity.
The first chapter discusses the various recent research trends in communication technologies: the allocation of millimeter-wave frequencies to benefit from the broad available spectrum, 2D scalability to enhance system performance and overcome link budget requirements, MIMO, and channel aggregation concepts to extend data capacity, heterogeneous integration to exploit benefits of various technologies, transitioning to THz region to improve spectrum efficiencies and diversify applications.
The key insight of this dissertation is that we implement distinct system/architecture-level solutions to achieve target data rates for the continuation of the advancements in communication technologies. The first project in this thesis presents a MIMO receiver array that utilizes a simplified single-wire interface for IF/LO signals that overcomes the high-frequency input/output distribution complexity for large-scale systems. Code-domain multiplexing is performed on the single-wire interface to preserve and transfer individual information of all channels. The four-channel receiver prototype that operates at 28GHz and achieves >20dB channel-to-channel isolation is presented. Digital beamforming and MIMO capability of the array have been demonstrated.
The later chapter of this dissertation discusses the fundamental limitation of code-domain multiplexing, the trade-off between isolation and interface bandwidth, and explains our novel frequency-domain multiplexing approach. A harmonic rejection mixer has been used to generate the required multiple LO tones to de-multiplex individual channel signals simultaneously. A 60GHz four-element MIMO transmitter prototype is presented, and its functionalities are illus- trated. The prototype achieves >30dB channel-to-channel isolation for an overall bandwidth of 10GHz, supports 64QAM modulated signals, and is capable of performing MIMO beamforming.
Next, benefiting from our research experience on FDM and HRM, we proposed a frequency- interleaving architecture for wideband channel aggregated systems. We divided the total IF band- width into four sub-channels and individually up/down-converted them to the baseband, alleviating the requirements of Analog-to-Digital/Digital-to-Analog Converters. HRM is utilized to generate multiple LO frequencies, as in the FDM-based transmitter work. The prototype system comprises two baseband channelizer ICs (TX/RX) and two mm-wave beamformer ICs (TX/RX), where channelizers perform FI aggregation and despread IF signals, and beamformers are responsible for beam steering and tapering. The four-channel transceiver chipset operates at 60GHz, provides >25dB isolation for an overall IF bandwidth of 8GHz, and supports 64QAM modulated signals.
The next section of the dissertation presents a wideband sub-THz transceiver phased array system with SWI. We propose a D-band scalable 16-element transceiver system with novel front- end block designs to satisfy link budget requirements and enable high data rates and complex modulation data transfer. The prototype consists of one phased array transmitter and one phased array receiver. Simulated performance shows that the receiver system has ∼34dB gain, -30dBmIP1dB with a minimum 5.4dB NF. While, transmitter achieves ∼34dB gain with a 9dBm OP1dB.
The last chapter looks beyond CMOS technology and presents front-end blocks at III-V technologies. Two circulator prototype designs with different architectures are implemented using GaN technology. Better linearity performance is targeted by leveraging heterogeneous integration, using GaN devices for the core and CMOS circuitry for clock generation. In addition, a future direction for THz systems, GaN-assisted beamformer architecture, is presented.
| Identifer | oai:union.ndltd.org:columbia.edu/oai:academiccommons.columbia.edu:10.7916/z4vq-1z83 |
| Date | January 2024 |
| Creators | Dascurcu, Armagan |
| Source Sets | Columbia University |
| Language | English |
| Detected Language | English |
| Type | Theses |
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