828 research outputs found
Noise properties of a resonance-type spin-torque microwave detector
We analyze performance of a resonance-type spin-torque microwave detector
(STMD) in the presence of noise and reveal two distinct regimes of STMD
operation. In the first (high-frequency) regime the minimum detectable
microwave power is limited by the low-frequency Johnson-Nyquist
noise and the signal-to-noise ratio (SNR) of STMD is proportional to the input
microwave power . In the second (low-frequency) regime is limited by the magnetic noise, and the SNR is proportional to
. The developed formalism can be used for the optimization
of the practical noise-handling parameters of a STMD.Comment: 3 pages, 2 figure
An adjustable RF tuning element for microwave, millimeter wave, and submillimeter wave integrated circuits
Planar RF circuits are used in a wide range of applications from 1 GHz to 300 GHz, including radar, communications, commercial RF test instruments, and remote sensing radiometers. These circuits, however, provide only fixed tuning elements. This lack of adjustability puts severe demands on circuit design procedures and materials parameters. We have developed a novel tuning element which can be incorporated into the design of a planar circuit in order to allow active, post-fabrication tuning by varying the electrical length of a coplanar strip transmission line. It consists of a series of thin plates which can slide in unison along the transmission line, and the size and spacing of the plates are designed to provide a large reflection of RF power over a useful frequency bandwidth. Tests of this structure at 1 GHz to 3 Ghz showed that it produced a reflection coefficient greater than 0.90 over a 20 percent bandwidth. A 2 GHz circuit incorporating this tuning element was also tested to demonstrate practical tuning ranges. This structure can be fabricated for frequencies as high as 1000 GHz using existing micromachining techniques. Many commercial applications can benefit from this micromechanical RF tuning element, as it will aid in extending microwave integrated circuit technology into the high millimeter wave and submillimeter wave bands by easing constraints on circuit technology
An Analog Phase Interpolation Based Fractional-N PLL
A novel phase-locked loop topology is presented. Compared to conventional designs, this architecture aims to increase frequency resolution and reduce quantization noise while maintaining the fractional-N benefits of high bandwidth and low phase noise up-conversion. This is achieved utilizing a feedforward mechanism for offset cancellation from the integer-N frequency. The design is implemented in a 0.13μm CMOS process technology. A frequency resolution of 1.16Hz is achieved on a 5GHz differential delay cell VCO with a 100MHz reference oscillator. A ping-pong swallow counter topology alleviates pipeline latency to achieve 1-64 divide ratios. A digital pulse generator and nested phase-frequency detector provide tunable offset cancellation. A 5-bit current-steering DAC capable of 200ps pulses reduces output spurs. Theoretical calculations and Simulink modeling provides insight to the effects of non idealities in the system. Test structures and loop configurability are programmed via SPI interface through a custom GUI and prototype PCB
Multi-impairment and multi-channel optical performance monitoring
Next generation optical networks will evolve from static to dynamically reconfigurable architectures to meet the increasing bandwidth and service requirements. The benefits of dynamically reconfigurable networks (improved operations, reduced footprint and cost) have introduced new challenges, in particular the need for complex management which has put pressure on the engineering rules and transmission margins. This has provided the main
drive to develop new techniques for optical performance monitoring (OPM) without using optical-to-electrical-to-optical conversions. When considering impairments due to chromatic dispersion in dynamic networks, each channel will traverse a unique path through the network thus the channels arriving at the monitoring point will, in general, exhibit different
amounts of residual dispersion. Therefore, in a dynamic network it is necessary to monitor all channels individually to quantify the degradation, without the requirement of knowing the data path history. The monitoring feature can be used in conjunction with a dispersion compensation device which can either be optical or electrical or used to trigger real-time alarms for traffic re-routing.
The proposed OPM technique is based on RF spectrum analysis and used for simultaneous and independent monitoring of power, chromatic dispersion (CD), polarisation mode
dispersion (PMD) and optical signal-to-noise ratio (OSNR) in 40Gbit/s multi0channel systems.
An analytical model is developed to describe the monitoring technique which allows the prediction of the measurement range. The experimental results are given for group velocity
dispersion (GVD), differential group delay (DGD) and OSNR measurements. This technique is based on electro-optic down-conversion that simultaneously down-converts multiple
channels, sharing the cost of the key components over multiple channels and making it cost
effective for multi-channel operation. The measurement range achieved with this method is equal to 4742±100ps/nm for GVD, 200±4ps for DGD and 25±1dB for OSNR. To the knowledge of the author, these dispersion monitoring ranges are the largest reported to date for the bit-rate of 40Gbit/s with amplitude modulation formats
Displacement Detection with a Vibrating RF SQUID: Beating the Standard Linear Limit
We study a novel configuration for displacement detection consisting of a
nanomechanical resonator coupled to both, a radio frequency superconducting
interference device (RF SQUID) and to a superconducting stripline resonator. We
employ an adiabatic approximation and rotating wave approximation and calculate
the displacement sensitivity. We study the performance of such a displacement
detector when the stripline resonator is driven into a region of nonlinear
oscillations. In this region the system exhibits noise squeezing in the output
signal when homodyne detection is employed for readout. We show that
displacement sensitivity of the device in this region may exceed the upper
bound imposed upon the sensitivity when operating in the linear region. On the
other hand, we find that the high displacement sensitivity is accompanied by a
slowing down of the response of the system, resulting in a limited bandwidth
Digitally-Assisted RF IC Design Techniques for Reliable Performance
Semiconductor industries have competitively scaled down CMOS devices to attain benefits of low cost, high performance, and high integration density in digital integrated circuits. On the other hand, deep scaled technologies inextricably accompany a large process variation, supply voltage scaling, and reduction in breakdown voltages of transistors. When it comes to RF/analog IC design, CMOS scaling adversely affects its reliability due to large performance variation and limited linearity. For addressing the issues related to variations and linearity, this research proposes the following digitally-assisted RF circuit design techniques: self-calibration system for RF phase shifters and wide dynamic range LNAs.
Due to PVT variations in scaled technologies, RF phase shifter design becomes more challenging with device scaling. In the proposed self-calibration topology, we devised a novel phase sensing method and a pulsewidth-to-digital converter. The feedback controller is also designed in digital domain, which is robust to PVT variations. These unique techniques enable a sensing/control loop tolerant to PVT variations. The self-calibration loop was applied to a 7 to 13GHz phase shifter. With the calibration, the estimated phase error is less than 2 degrees.
To overcome the linearity issue in scaled technologies, a digitally-controlled dual-mode LNA design is presented. A narrowband (5.1GHz) and a wideband (0.8 to 6GHz) LNA can be toggled between high-gain and high-linearity modes by digital control bits according to the input signal power. A compact design, which provides negligible performance degradation by additional circuitry, is achieved by sharing most of the components between the two operation modes. The narrowband and the wideband LNA achieves an input-referred P1dB of -1.8dBm and +4.2dBm, respectively
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