Rob Hubbard scite author profile

Helioseismology requires nearly continuous observations of the oscillations of the solar surface for long periods of time in order to obtain precise measurements of the sun's normal modes of oscillation. The GONG project acquires velocity images from a network of six identical instruments distributed around the world. The GONG network began full operation in October 1995. It has achieved a duty cycle of 89 percent and reduced the magnitude of spectral artifacts by a factor of 280 in power, compared with single-site observations. The instrumental noise is less than the observed solar background.

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The Solar Acoustic Spectrum and Eigenmode Parameters

Hill

Stark

Stebbins

et al. 1996

Science

143

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The Global Oscillation Network Group (GONG) project estimates the frequencies, amplitudes, and linewidths of more than 250,000 acoustic resonances of the sun from data sets lasting 36 days. The frequency resolution of a single data set is 0.321 microhertz. For frequencies averaged over the azimuthal order m, the median formal error is 0.044 microhertz, and the associated median fractional error is 1.6 x 10(-5). For a 3-year data set, the fractional error is expected to be 3 x 10(-6). The GONG m-averaged frequency measurements differ from other helioseismic data sets by 0.03 to 0.08 microhertz. The differences arise from a combination of systematic errors, random errors, and possible changes in solar structure.

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Measurements of argon-, helium-, hydrogen-, and nitrogen-broadened widths of methane lines near 9000 cm−1

Fox

Jennings

Stern³

et al. 1988

Journal of Quantitative Spectroscopy and Radiative Transfer

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Fourier transform spectroscopy on the 3ν2, 2ν2 + ν6 and ν3 + ν5 bands of H2CO

Tipton

Choe

Kukolich

et al. 1985

Journal of Molecular Spectroscopy

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Technical challenges of the Advanced Technology Solar Telescope

Rimmelé

Keil

Keller

et al. 2003

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The 4m Advance Technology Solar Telescope (ATST) will be the most powerful solar telescope in the world, providing a unique scientific tool to study the Sun and possibly other astronomical objects, such as solar system planets. We briefly summarize the science drivers and observational requirements of ATST. The main focus of this paper is on the many technical challenges involved in designing a large aperture solar telescope. The ATST project has entered the design and development phase. Development of a 4-m solar telescope presents many technical challenges. Most existing highresolution solar telescopes are designed as vacuum telescopes to avoid internal seeing caused by the solar heat load. The large aperture drives the ATST to an open-air design, similar to night-time telescope designs, and makes thermal control of optics and telescope structure a paramount consideration. A heat stop must reject most of the energy (13 kW) at prime focus without introducing internal seeing. To achieve diffraction-limited observations at visible and infrared wavelengths, ATST will have a high order (order 1000 DoF) adaptive optics system using solar granulation as the wavefront sensing target. Coronal observations require occulting in prime focus, a Lyot stop and contamination control of the primary. An initial set of instruments will be designed as integral part of the telescope. First telescope design and instrument concepts will be presented.

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The wavefront correction system for the Advanced Technology Solar Telescope

Rimmelé

Richards

Roche

et al. 2006

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Advanced Technology Solar Telescope optical design

Hansen

Price

Hubbard

2006

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The Advanced Technology Solar Telescope (ATST) will be the most powerful solar telescope and the world's leading resource for studying solar magnetism that controls the solar wind, flares, coronal mass ejections and variability in the Sun's output. Development of this four-meter off-axis solar telescope has presented many optical design challenges including:• support of both Nasmyth and flexible coudé lab instrumentation,• incorporation of an integrated adaptive optics system, • thermal control of optics, and • optical alignment of multiple off-axis conics.This paper gives an overview of the optical design, error budgeting, and the performance modeling done to ensure the telescope will satisfy its optical performance requirements.

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Advanced Technology Solar Telescope: conceptual design and status

Keil

Oschmann

Rimmelé

et al. 2004

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Rob Hubbard

The Global Oscillation Network Group (GONG) Project

The Solar Acoustic Spectrum and Eigenmode Parameters

Measurements of argon-, helium-, hydrogen-, and nitrogen-broadened widths of methane lines near 9000 cm−1

Fourier transform spectroscopy on the 3ν2, 2ν2 + ν6 and ν3 + ν5 bands of H2CO

Technical challenges of the Advanced Technology Solar Telescope

The wavefront correction system for the Advanced Technology Solar Telescope

Advanced Technology Solar Telescope optical design

Advanced Technology Solar Telescope: conceptual design and status

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