Research could lead to longer talk time and higher data rates in 5G devicesBy integrating the design of antenna and electronics, researchers have boosted the energy and spectrum efficiency for a new class of millimeter wave transmitters, allowing improved modulation and reduced generation of waste heat. The result could be longer talk time and higher data rates in millimeter wave wireless communication devices for future 5G applications.
The new co-design technique allows simultaneous optimization of the millimeter wave antennas and electronics. The hybrid devices use conventional materials and integrated circuit technology, meaning no changes would be required to manufacture and package them. The co-design scheme allows fabrication of multiple transmitters and receivers on the same IC chip or the same package, potentially enabling multiple-input-multiple-output (MIMO) systems as well as boosting data rates and link diversity.
Researchers from the Georgia Institute of Technology presented their proof-of-concept antenna-based outphasing transmitter at the 2018 IEEE Radio Frequency Integrated Circuits Symposium in Philadelphia. Intel Corp. and the U.S. Army Research Office sponsored the research.
"In this proof-of-example, our electronics and antenna were designed so that they can work together to achieve a unique on-antenna outphasing active load modulation capability that significantly enhances the efficiency of the entire transmitter," says Hua Wang, an assistant professor in Georgia Tech's School of Electrical and Computer Engineering. "This system could replace many types of transmitters in wireless mobile devices, base stations, and infrastructure links in data centers."
Key to the new design is maintaining a high-energy efficiency regardless whether the device is operating at its peak or average output power. The efficiency of most conventional transmitters is high only at the peak power but drops substantially at low power levels, resulting in low efficiency when amplifying complex spectrally efficient modulations. Moreover, conventional transmitters often add the outputs from multiple electronics using lossy power combiner circuits, exacerbating the efficiency degradation.
"We are combining the output power though a dual-feed loop antenna, and by doing so with our innovation in the antenna and electronics, we can substantially improve the energy efficiency," says Wang, the Demetrius T. Paris Professor in the School of Electrical and Computer Engineering. "The innovation in this particular design is to merge the antenna and electronics to achieve the so-called outphasing operation that dynamically modulates and optimizes the output voltages and currents of power transistors, so that the millimeter wave transmitter maintains a high energy efficiency both at the peak and average power."
Beyond energy efficiency, the co-design also facilitates spectrum efficiency by allowing more complex modulation protocols. That will enable transmission of a higher data rate within the fixed spectrum allocation that poses a significant challenge for 5G systems.
"Within the same channel bandwidth, the proposed transmitter can transmit six to ten times higher data rate," says Wang. "Integrating the antenna gives us more degrees of freedom to explore design innovation, something that could not be done before."
Sensen Li, a Georgia Tech graduate research assistant, says the innovation resulted from bringing together two disciplines that have traditionally worked separately.
"We are merging the technologies of electronics and antennas, bringing these two disciplines together to break through limits," he says. "These improvements could not be achieved by working on them independently. By taking advantage of this new co-design concept, we can further improve the performance of future wireless transmitters."
The new designs have been implemented in 45-nanometer CMOS SOI IC devices and flip-chip packaged on high-frequency laminate boards, where testing has confirmed a minimum two-fold increase in energy efficiency, Wang says.
The antenna electronics co-design is enabled by exploring the unique nature of multi-feed antennas.
"An antenna structure with multiple feeds allows us to use multiple electronics to drive the antenna concurrently. Different from conventional single-feed antennas, multi-feed antennas can serve not only as radiating elements, but they can also function as signal processing units that interface among multiple electronic circuits," Wang says. "This opens a completely new design paradigm to have different electronic circuits driving the antenna collectively with different but optimized signal conditions, achieving unprecedented energy efficiency, spectral efficiency, and reconfigurability."
The cross-disciplinary co-design could also facilitate fabrication and operation of multiple transmitters and receivers on the same chip, allowing hundreds or even thousands of elements to work together as a whole system. "In massive MIMO systems, we need to have a lot of transmitters and receivers, so energy efficiency will become even more important," Wang says.
Having large numbers of elements working together becomes more practical at millimeter wave frequencies because the wavelength reduction means elements can be placed closer together to achieve compact systems, Wang says. These factors could pave the way for new types of beamforming that are essential in future millimeter wave 5G systems.
Power demands could drive adoption of the technology for battery-powered devices, but Wang says the technology could also be useful for grid-powered systems such as base stations or wireless connections to replace cables in large data centers. In those applications, expanding data rates and reducing cooling needs could make the new devices attractive.
"Higher energy efficiency also means less energy will be converted to heat that must be removed to satisfy the thermal management," he says. "In large data centers, even a small reduction in thermal load per device can add up. We hope to simplify the thermal requirements of these electronic devices."
The research team also included Taiyun Chi, Huy Thong Nguyen, and Tzu-Yuan Huang from Georgia Tech.
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