Your search keyword '"Henry G. LeDuc"' showing total 7 results

1. A 275–425-GHz Tunerless Waveguide Receiver Based on AlN-Barrier SIS Technology

Author

Jacob Kooi, R. Ceria, J. A. Stern, Bruce Bumble, Attila Kovács, Henry G. LeDuc, M. C. Sumner, David P. Miller, Goutam Chattopadhyay, and Thomas G. Phillips

Subjects

Noise temperature, Radiation, Materials science, Sideband, business.industry, Superheterodyne receiver, Shot noise, Condensed Matter Physics, Microstrip, law.invention, Caltech Submillimeter Observatory, Optics, Tunnel junction, law, Superconducting tunnel junction, Electrical and Electronic Engineering, business, Caltech Library Services

Abstract

We report on a 275-425-GHz tunerless waveguide receiver with a 3.5-8-GHz IF. As the mixing element, we employ a high-current-density Nb-AlN-Nb superconducting-insulating-superconducting (SIS) tunnel junction. Thanks to the combined use of AlN-barrier SIS technology and a broad bandwidth waveguide to thin-film microstrip transition, we are able to achieve an unprecedented 43% instantaneous bandwidth, limited by the receiver's corrugated feedhorn. The measured double-sideband (DSB) receiver noise temperature, uncorrected for optics loss, ranges from 55 K at 275 GHz, 48 K at 345 GHz, to 72 K at 425 GHz. In this frequency range, the mixer has a DSB conversion loss of 2.3 plusmn1 dB. The intrinsic mixer noise is found to vary between 17-19 K, of which 9 K is attributed to shot noise associated with leakage current below the gap. To improve reliability, the IF circuit and bias injection are entirely planar by design. The instrument was successfully installed at the Caltech Submillimeter Observatory (CSO), Mauna Kea, HI, in October 2006.

Published

2007

2. A dual-polarized quasi-optical SIS mixer at 550 GHz

Author

Jonas Zmuidzinas, Goutam Chattopadhyay, Henry G. LeDuc, and David Miller

Subjects

Frequency response, Noise temperature, Radiation, Materials science, Sideband, Physics::Instrumentation and Detectors, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Harmonic mixer, Electrical engineering, Condensed Matter Physics, Polarization (waves), Microstrip, Optics, Condensed Matter::Superconductivity, Electrical and Electronic Engineering, business, Frequency mixer, Caltech Library Services, Electronic circuit

Abstract

In this paper, we describe the design, fabrication, and the performance of a low-noise dual-polarized quasi-optical superconductor-insulator-superconductor (SIS) mixer at 550 GHz. The mixer utilizes a novel cross-slot antenna on a hyperhemispherical substrate lens, two junction tuning circuits, niobium trilayer junctions, and an IF circuit containing a lumped element 180/spl deg/ hybrid. The antenna consists of an orthogonal pair of twin-slot antennas, and has four feed points, two for each polarization. Each feed point is coupled to a two-junction SIS mixer. The 180/spl deg/ IF hybrid is implemented using a lumped element/microstrip circuit located inside the mixer block. Fourier transform spectrometer measurements of the mixer frequency response show good agreement with computer simulations. The measured co-polarized and cross-polarized patterns for both polarizations also agree with the theoretical predictions. The noise performance of the dual-polarized mixer is excellent giving uncorrected receiver noise temperature of better than 115 K (double sideband) at 528 GHz for both the polarizations.

Published

2000

3. An integrated SIS mixer and HEMT IF amplifier

Author

Raymond Blundell, Marian Pospieszalski, Stephen Padin, Henry G. LeDuc, Jeffrey A. Stern, David P. Woody, and Cheuk-yu Edward Tong

Subjects

Noise temperature, Radiation, Materials science, business.industry, Local oscillator, Impedance matching, Electrical engineering, Input impedance, High-electron-mobility transistor, Condensed Matter Physics, Inductor, Electrical and Electronic Engineering, business, Electrical impedance, Electronic circuit

Abstract

Design details are given for a 205-270 GHz fixed-tuned SIS receiver in which the SIS mixer and HEMT IF amplifier are integrated into a single compact unit. The mixer and IF amplifier are connected with an inductor which provides the reactive part of the optimum input impedance for the HEMT. This simple coupling circuit gives an IF bandwidth of /spl sim/4 GHz. The receiver has a DSB noise temperature in the range 35-80 K over the 205-270 GHz local oscillator band and 0.5-4.5 GHz IF band.

Published

1996

4. Design and characterization of a 250-350-GHz fixed-tuned superconductor-insulator-superconductor receiver

Author

Raymond Blundell, Scott Paine, Cheuk-yu Edward Tong, Henry G. LeDuc, J. Kawamura, D. C. Papa, Xiaolei Zhang, and J. A. Stern

Subjects

Superconductivity, Physics, Noise temperature, Radiation, business.industry, Frequency band, Radio equipment, Electrical engineering, Insulator (electricity), Condensed Matter Physics, Electronic equipment, Optics, Electrical and Electronic Engineering, business

Abstract

A fixed-tuned superconductor-insulator-superconductor (SIS) receiver has been designed to operate in the 250-350-GHz frequency band. This receiver has a double-side-band noise temperature of between 35 and 45 K, or about 3h/spl nu//k/sub B/, over its entire operating band. Extensive characterization of the receiver has been carried out using techniques developed for submillimeter waves. The input noise, side-band ratio, 1 dB compression point, optimum LO drive level, and vector near-field beam profile have all been measured experimentally. The measurement techniques and results are presented and discussed.

Published

1996

5. A wideband fixed-tuned SIS receiver for 200-GHz operation

Author

Henry G. LeDuc, J. A. Stern, D. C. Papa, C.-Yu.E. Tong, B. Bumble, Scott Paine, Raymond Blundell, Xiaolei Zhang, and R. L. Leombruno

Subjects

Physics, Noise temperature, Radiation, RF front end, Radio receiver design, business.industry, Superheterodyne receiver, Tuned radio frequency receiver, Electrical engineering, Condensed Matter Physics, law.invention, law, Heterodyne detection, Electrical and Electronic Engineering, Wideband, business, Frequency mixer

Abstract

We report on the design and development of a heterodyne receiver, designed to cover the frequency range 176-256 GHz. This receiver incorporates a niobium superconductor-insulator-superconductor (SIS) tunnel junction mixer, which, chiefly for reasons of reliability and ease of operation, is a fixed-tuned waveguide design. On-chip tuning is provided to resonate out the junction's geometric capacitance and produce a good match to the waveguide circuit. Laboratory measurements on the first test receiver indicate that the required input bandwidth (about 40%) is achieved with an average receiver noise temperature of below 50 K. Mixer conversion gain is observed at some frequencies, and the lowest measured receiver noise is less than 30 K. Furthermore, the SIS mixer used in this receiver is of simple construction, is easy to assemble and is therefore a good candidate for duplication. >

Published

1995

6. A low noise 230 GHz heterodyne receiver employing 0.25- mu m/sup 2/ area Nb-AlO/sub x/-Nb tunnel junctions

Author

Jacob Kooi, B. Bumble, M. Chan, Henry G. LeDuc, and Thomas G. Phillips

Subjects

Physics, Noise temperature, Radiation, business.industry, Superheterodyne receiver, Impedance matching, Electrical engineering, Condensed Matter Physics, law.invention, Caltech Submillimeter Observatory, law, Optoelectronics, Superconducting tunnel junction, Heterodyne detection, Electrical and Electronic Engineering, business, Electrical impedance, Noise (radio)

Abstract

The authors report recent results for a full-height rectangular waveguide mixer with an integrated IF matching network. Two 0.25 mu m/sup 2/ Nb-AlO/sub x/-Nb superconducting-insulating-superconducting (SIS) tunnel junctions with a current density of approximately=8500 A/cm/sup 2/ and omega RC of approximately=2.5 at 230 GHz have been tested. One of these quasiparticle tunnel junctions is currently being used at the Caltech Submillimeter Observatory in Hawaii. Detailed measurement of the receiver noise have been made from 200-290 GHz for both junctions at 4.2 K. The lowest receiver noise temperatures were recorded at 239 GHz, measuring 48 K DSB at 4.2 K and 40 K DSB at 2.1 K. The 230-GHz receiver incorporates a one-octave-wide integrated low-pass filter and matching network which transforms the pumped IF junction impedance to 50 Omega over a wide range of impedances. >

Published

1992

7. Quasi-optical slot antenna SIS mixers

Author

Henry G. LeDuc and Jonas Zmuidzinas

Subjects

Radiation impedance, Josephson effect, Radiation, Materials science, Physics::Instrumentation and Detectors, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Electrical engineering, Slot antenna, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Condensed Matter Physics, Characteristic impedance, Radiation pattern, Microstrip antenna, Tunnel junction, Condensed Matter::Superconductivity, Optoelectronics, Electrical and Electronic Engineering, business, Frequency mixer, Caltech Library Services

Abstract

A quasi-optical SIS mixer designed for efficient radiation coupling is described. The mixer uses a twin-slot antenna which has the advantages of a good beam pattern and a low impedance. The radiation and impedance characteristics of the antenna were obtained from a moment-matched calculation. Tapered superconducting microstrip transmission lines are used to carry the radiation from the slot antennas to the tunnel junction. The effective impedance seen by the tunnel junction is quite low, about 4 Omega , which allows micron-size junctions to be used at 500 GHz. The mixers have been fabricated using Nb/Al-oxide/Nb tunnel junctions and a receiver noise temperature of 420 K (DSB) was measured at 490 GHz, which is the best yet obtained for a quasi-optical mixer at this frequency. The comparatively large junction area increases the mixer saturation power and allows strong suppression of noise from the Josephson effect by the application of a magnetic field of modest strength. >

Published

1992