2,705 research outputs found
Integrated On-Silicon and On-glass Antennas for Mm-Wave Applications
The paper presents several integrated high frequency antenna prototypes based on Si/CMOS and on-glass technologies for millimeter-wave (mm-wave) applications. On-chip loop antenna and dipole radiator are presented. In addition, a wide-band dipole-patch antenna design for the range of 74 – 104 GHz is integrated into a CMOS chip with an on-chip pulse generator. In addition, an implementation of a fully on-Silicon antenna array integrated with a timed-array transmitter. To control the beam-forming of this array, a digital-based time adjustment circuit is integrated together with the antenna array. Simulated and measured data including return loss, and radiation patterns are presented. This paper also introduces an on-glass antenna prototypes fabricated on quartz substrate. The on-glass antenna is to demonstrate for handset or automobile’s windshield/windows applications where radio waves could be transmitted and received from various directions. The results show several compact antenna candidates integrated by both Silicon and quartz substrates towards mm-Wave/sub-mm-Wave sensing and communication applications
The Conference on High Temperature Electronics
The status of and directions for high temperature electronics research and development were evaluated. Major objectives were to (1) identify common user needs; (2) put into perspective the directions for future work; and (3) address the problem of bringing to practical fruition the results of these efforts. More than half of the presentations dealt with materials and devices, rather than circuits and systems. Conference session titles and an example of a paper presented in each session are (1) User requirements: High temperature electronics applications in space explorations; (2) Devices: Passive components for high temperature operation; (3) Circuits and systems: Process characteristics and design methods for a 300 degree QUAD or AMP; and (4) Packaging: Presently available energy supply for high temperature environment
An Integrated-Photonics Optical-Frequency Synthesizer
Integrated-photonics microchips now enable a range of advanced
functionalities for high-coherence applications such as data transmission,
highly optimized physical sensors, and harnessing quantum states, but with
cost, efficiency, and portability much beyond tabletop experiments. Through
high-volume semiconductor processing built around advanced materials there
exists an opportunity for integrated devices to impact applications cutting
across disciplines of basic science and technology. Here we show how to
synthesize the absolute frequency of a lightwave signal, using integrated
photonics to implement lasers, system interconnects, and nonlinear frequency
comb generation. The laser frequency output of our synthesizer is programmed by
a microwave clock across 4 THz near 1550 nm with 1 Hz resolution and
traceability to the SI second. This is accomplished with a heterogeneously
integrated III/V-Si tunable laser, which is guided by dual
dissipative-Kerr-soliton frequency combs fabricated on silicon chips. Through
out-of-loop measurements of the phase-coherent, microwave-to-optical link, we
verify that the fractional-frequency instability of the integrated photonics
synthesizer matches the reference-clock instability for a 1
second acquisition, and constrain any synthesis error to while
stepping the synthesizer across the telecommunication C band. Any application
of an optical frequency source would be enabled by the precision optical
synthesis presented here. Building on the ubiquitous capability in the
microwave domain, our results demonstrate a first path to synthesis with
integrated photonics, leveraging low-cost, low-power, and compact features that
will be critical for its widespread use.Comment: 10 pages, 6 figure
One way Doppler extractor. Volume 1: Vernier technique
A feasibility analysis, trade-offs, and implementation for a One Way Doppler Extraction system are discussed. A Doppler error analysis shows that quantization error is a primary source of Doppler measurement error. Several competing extraction techniques are compared and a Vernier technique is developed which obtains high Doppler resolution with low speed logic. Parameter trade-offs and sensitivities for the Vernier technique are analyzed, leading to a hardware design configuration. A detailed design, operation, and performance evaluation of the resulting breadboard model is presented which verifies the theoretical performance predictions. Performance tests have verified that the breadboard is capable of extracting Doppler, on an S-band signal, to an accuracy of less than 0.02 Hertz for a one second averaging period. This corresponds to a range rate error of no more than 3 millimeters per second
Hybrid Electro-Optically Modulated Microcombs
Optical frequency combs based on mode-locked lasers have proven to be
invaluable tools for a wide range of applications in precision spectroscopy and
metrology. A novel principle of optical frequency comb generation in
whispering-gallery mode microresonators ("microcombs") has been developed
recently, which represents a promising route towards chip-level integration and
out-of-the-lab use of these devices. Presently, two families of microcombs have
been demonstrated: combs with electronically detectable mode spacing that can
be directly stabilized, and broadband combs with up to octave-spanning spectra
but mode spacings beyond electronic detection limits. However, it has not yet
been possible to achieve these two key requirements simultaneously, as will be
critical for most microcomb applications. Here we present a key step to
overcome this problem by interleaving an electro-optic comb with the spectrum
from a parametric microcomb. This allows, for the first time, direct control
and stabilization of a microcomb spectrum with large mode spacing (>140 GHz)
with no need for an additional mode-locked laser frequency comb. The attained
residual 1-second-instability of the microcomb comb spacing is 10^-15, with a
microwave reference limited absolute instability of 10^-12 at a 140 GHz mode
spacing.Comment: 8 pages, 4 figures; accepted for publication in Physical Review
Letter
Ultra Low Power Analog Circuits for Wireless Sensor Node System.
This thesis will discuss essential analog circuit blocks required in ultra-low power wireless sensor node systems. A wireless sensor network system requires very high energy and power efficiency which is difficult to achieve with traditional analog circuits. First, 5.58nW real time clock using a DLL (Delay Locked Loop)-assisted pulse-driven crystal oscillator is discussed. In this circuit, the operational amplifier used in the traditional circuit was replaced with pulsed drivers. The pulse was generated at precise timing by a DLL. The circuit parts operate in different supply levels, generated on chip by using a switched capacitor network. The circuit was tested at different supply voltage and temperature. Its frequency characteristic along with power consumption were measured and compared to the traditional circuit. Next, a Schmitt trigger based pulse-driven crystal oscillator is discussed. In the first chapter, a DLL was used to generate a pulse with precise timing. However, testing results and recent study showed that the crystal oscillator can sustain oscillation even with inaccurate pulse timing. In this chapter, pulse location is determined by the Schmitt trigger. Simulation results show that this structure can still sustain oscillation at different process corners and temperature. In the next chapter, a sub-nW 8 bit SAR ADC (Successive Approximation Analog-to-Digital Converter) using transistor-stack DAC (Digital-to-Analog Converter) is discussed. To facilitate design effort and reduce the layout dependent effect, a conventional capacitive DAC was replaced with transistor-stack DAC with a 255:1 multiplexer. The control logic was designed with both TSPC (True Single Phase Clock) and CMOS logic to minimize transistor count. The ADC was implemented in a 65nm CMOS process and tested at different sampling rates and input signal frequency. Its linearity and power consumption was measured. Also, a similar design was implemented and tested using 180nm CMOS process as part of a sensor node system. Lastly, a multiple output level voltage regulator using a switched capacitor network for low-cost system is discussed.PhDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/111626/1/dmyoon_1.pd
A RISC-V SOC for Terahertz IoT Devices: Implementation and design challenges
Terahertz (THz) communication is considered a viable approach to augmenting
the communication capacity of prospective Internet-of-Things (IoT) resulting in
enhanced spectral efficiency. This study first provides an outline of the
design challenges encountered in developing THz transceivers. This paper
introduces advanced approaches and a unique methodology known as Modified
Pulse-width Modulation (MPWM) to address the issues in the THz domain. In this
situation involving a transceiver that handles complex modulation schemes, the
presence of a mixed signal through a high-resolution digital-to-analog
converter (DAC) in the transmitter greatly contributes to the limitation in
maintaining linearity at high frequencies. The utilization of Pulse-width
Modulation-based Digital-to-Analog Converters (PWM-DACs) has garnered
significant attention among scholars due to its efficiency and affordability.
However, the converters' performance is restricted by insufficient conversion
speed and precision, especially in the context of high-resolution, high-order
modulation schemes for THz wireless communications. The MPWM framework offers a
multitude of adjustable options, rendering the final MPWM-DAC highly adaptable
for a diverse array of application scenarios. Comparative performance
assessments indicate that MPWM-DACs have enhanced conversion speed compared to
standard PWM-DACs, and they also provide greater accuracy in comparison to
Pulse-count Modulation DACs (PCM-DACs). The study presents a comprehensive
examination of the core principles, spectrum characteristics, and evaluation
metrics, as well as the development and experimental validation of the MPWM
method. Furthermore, we present a RISC-V System-on-Chip (SoC) that incorporates
an MPWM-DAC, offering a highly favorable resolution for THz IoT communications.Comment: 18 pages, 17 figures, journa
Doctor of Philosophy
dissertationThis thesis presents the design, fabrication and characterization of a microelectromechanical system (MEMS) based complete wireless microsystem for brain interfacing, with very high quality factor and low power consumption. Components of the neuron sensing system include TiW fixed-fixed bridge resonator, MEMS oscillator based action-potential-to-RF module, and high-efficiency RF coil link for power and data transmissions. First, TiW fixed-fixed bridge resonator on glass substrate was fabricated and characterized, with resonance frequency of 100 - 500 kHz, and a quality factor up to 2,000 inside 10 mT vacuum. The effect of surface conditions on resonator's quality factor was studied with 10s of nm Al2O3 layer deposition with ALD (atomic layer deposition). It was found that MEMS resonator's quality factor decreased with increasing surface roughness. Second, action-potential-to-RF module was realized with MEMS oscillator based on TiW bridge resonator. Oscillation signal with frequency of 442 kHz and phase noise of -84.75 dBc/Hz at 1 kHz offset was obtained. DC biasing of the MEMS oscillator was modulated with neural signal so that the output RF waveform carries the neural signal information. Third, high-efficiency RF coil link for power and data communications was designed and realized. Based on the coupled mode theory (CMT), intermediate resonance coil was introduced and increased voltage transfer efficiency by up to 5 times. Finally, a complete neural interfacing system was demonstrated with board-level integration. The system consists of both internal and external systems, with wireless powering, wireless data transfer, artificial neuron signal generation, neural signal modulation and demodulation, and computer interface displaying restored neuron signal
High data rate systems for the future
Information systems in the next century will transfer data at rates that are much greater than those in use today. Satellite based communication systems will play an important role in networking users. Typical data rates; use of microwave, millimeter wave, or optical systems; millimeter wave communication technology; modulators/exciters; solid state power amplifiers; beam waveguide transmission systems; low noise receiver technology; optical communication technology; and the potential commercial applications of these technologies are discussed
Electronics for Sensors
The aim of this Special Issue is to explore new advanced solutions in electronic systems and interfaces to be employed in sensors, describing best practices, implementations, and applications. The selected papers in particular concern photomultiplier tubes (PMTs) and silicon photomultipliers (SiPMs) interfaces and applications, techniques for monitoring radiation levels, electronics for biomedical applications, design and applications of time-to-digital converters, interfaces for image sensors, and general-purpose theory and topologies for electronic interfaces
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