Use of a multiwavelength pyrometer in several elevated temperature aerospace applications
A multiwavelength pyrometer was developed for applications unique to aerospace environments. It was shown to be a useful and versatile technique for measuring temperature, even when the emissivity is ...
A multiwavelength pyrometer was developed for applications unique to aerospace environments. It was shown to be a useful and versatile technique for measuring temperature, even when the emissivity is ...
Fine wire thermometer for air temperature measurement
A resistive temperature sensor constructed from 25 µm platinum wire has been optimized for atmospheric measurements of air temperature, operated with a precision resistance-to-voltage converter....
A resistive temperature sensor constructed from 25 µm platinum wire has been optimized for atmospheric measurements of air temperature, operated with a precision resistance-to-voltage converter....
A wideband lag correlator for heterodyne spectroscopy of broad astronomical and atmospheric spectral lines
Rev. Sci. Instrum. 72, 1531 (2001); doi:10.1063/1.1334629
Issue Date: February 2001
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WASP2 is a lag correlation spectrometer that is optimized for astronomical heterodyne observations of spectral lines from mid-infrared through centimeter wavelengths. Since the instrument is a wideband microwave spectrum analyzer, its basic technology is well suited to radio astronomy, atmospheric remote sensing, and any other application which requires observations of broad spectral lines. In this specific instrument, eight 16 lag correlator boards form a 128 lag spectrometer with 33 MHz spectral resolution. The spectrometer's present microwave components dominate its gain shape, yielding a spectrometer which covers a useful (6 dB bandwidth) single band of 3600 MHz, from 280 to 3880 MHz. The correlator boards have a 3 dB bandwidth of 4000 MHz, from below 100 MHz to near their aliasing limit of 4200 MHz. WASP2 obtains its wide bandwidth with fully analog high frequency components: the voltage multipliers are transistor circuits and the delays are lengths of microstrip transmission line. WASP2 is simple, compact, requires little power, and integrates stably for many hours. ©2001 American Institute of Physics.
| History: | Received 1 August 2000; accepted 26 October 2000 |
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KEYWORDS and PACS
microwave spectrometers,
millimetre wave spectroscopy,
microwave spectroscopy,
radioastronomical techniques,
radiotelescopes,
heterodyne detection,
spectroscopy computing,
spectral analysers,
correlators,
atmospheric measuring apparatus,
analogue multipliers,
signal processing equipment,
astronomy computing,
geophysical signal processing
- 07.57.Pt
Instruments, apparatus, and components common to several branches of physics and astronomy Infrared, submillimeter wave, microwave and radiowave instruments and equipment Submillimeter wave, microwave and radiowave spectrometers; magnetic resonance spectrometers, auxiliary equipment, and techniques - 95.55.Jz
Fundamental astronomy and astrophysics; instrumentation, techniques, and astronomical observations Astronomical and space-research instrumentation Radio telescopes and instrumentation; heterodyne receivers - 93.85.+q
Geophysical observations, instrumentation, and techniques Instrumentation and techniques for geophysical research - 07.50.Qx
Instruments, apparatus, and components common to several branches of physics and astronomy Electrical and electronic instruments and components Signal processing electronics - 95.75.Fg
Fundamental astronomy and astrophysics; instrumentation, techniques, and astronomical observations Observation and data reduction techniques; computer modeling and simulation Spectroscopy and spectrophotometry - 84.40.Ua
Electronics; radiowave and microwave technology; direct energy conversion and storage Radiowave and microwave (including millimeter wave) technology Telecommunications: signal transmission and processing; communication satellites - 93.65.+e
Geophysical observations, instrumentation, and techniques Data acquisition and storage - YEAR: 2001
RELATED DATABASES
PUBLICATION DATA
0034-6748 (print)
1089-7623 (online)
AIP
REFERENCES (15)
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