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2018-09-08 11:29:38-18:55:38
HOP 81 N Pole Deep Scan Mode
Polar Monitoring Campaign during the Solar Cycle
x,y:-19",913"
Max FOV:320"x162"
Target:N Pole
Nearby Events
6302A Continuum Intensity320"x162"2042 spectra
6302A Longitudinal Flux Density320"x162"2042 spectra
6302A Transverse Flux Density320"x162"2042 spectra
6302A Velocity 6301.5A320"x162"2042 spectra

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SOTSP: HOP 81 N Pole Deep Scan Mode
2018-09-08T11:29:38 to 2018-09-08T18:55:38
Science Goal: Polar Monitoring Campaign during the Solar Cycle
Program: Deep mode, 2048 slit position
Target: N Pole
xcen=-19 ycen=913
Instrument: SOTSP
HOP/JOP: 81
Description: Objectives: 1: To observe the evolution of the magnetic field distribution around the poles during the solar cycle. 2: To understand the relationship between photospheric magnetic field and the coronal structures (include the solar wind) around the poles. Scientific Background: The polar observations by SOT/SP revealed that there are many strong patchy magnetic poles around the poles. Such strong magnetic fields in the polar region may strongly relate with the dynamo and it is very important to observe the evolution of the magnetic field distribution for understanding the dynamo. The strong patchy magnetic poles have the trumpet-like vertical magnetic structure. Although we think that the trumpet structures may relate with the fast solar wind, there are no coronal (X-ray/EUV) structures on most of the magnetic structures. To understand the fast solar wind, the relationship between photospheric magnetic fields and coronal structures in the polar coronal hole is very essential. During the polarity reversal, the opposite polarity magnetic field invade the polar region. At the time, the relationship between coronal activities/structures and photospheric magnetic field is very interesting for understanding the solar wind. request to SOT For DSM Day 1 ? BFI G-band: FoV 221"x111", Binning: 2x2, Time resolution: 30 min, JPEG Quality: Q75 Note: One image per one observation period. ? NFI Na I: IVDG mode, FoV: 328? x 164?, Binning: 2x2, Time resolution: 5 min, JPEG Quality: Q75 Note: One image per one observation period. ? SOT-SP FoV 320? x 164?, Pixel size: 0.16?/pix, Binning: 1x1, Single side mode Exposure: 12.8 sec (16 Cycles), JPEG Quality: Q75, Data rate: >
2280Mbits/map Note: If the exposure time may cause the saturation, please decrease it. Note: Since the data size of SP is very huge for the allocation data size of SOT, we can observe only one SP map during two days. It is OK. Note: set margin factors to 1.4 for FG and SP

Objectives: 1: To observe the evolution of the magnetic field distribution around the poles during the solar cycle. 2: To understand the relationship between photospheric magnetic field and the coronal structures (include the solar wind) around the poles. Scientific Background: The polar observations by SOT/SP revealed that there are many strong patchy magnetic poles around the poles. Such strong magnetic fields in the polar region may strongly relate with the dynamo and it is very important to observe the evolution of the magnetic field distribution for understanding the dynamo. The strong patchy magnetic poles have the trumpet-like vertical magnetic structure. Although we think that the trumpet structures may relate with the fast solar wind, there are no coronal (X-ray/EUV) structures on most of the magnetic structures. To understand the fast solar wind, the relationship between photospheric magnetic fields and coronal structures in the polar coronal hole is very essential. During the polarity reversal, the opposite polarity magnetic field invade the polar region. At the time, the relationship between coronal activities/structures and photospheric magnetic field is very interesting for understanding the solar wind. request to SOT For DSM Day 1 ? BFI G-band: FoV 221"x111", Binning: 2x2, Time resolution: 30 min, JPEG Quality: Q75 Note: One image per one observation period. ? NFI Na I: IVDG mode, FoV: 328? x 164?, Binning: 2x2, Time resolution: 5 min, JPEG Quality: Q75 Note: One image per one observation period. ? SOT-SP FoV 320? x 164?, Pixel size: 0.16?/pix, Binning: 1x1, Single side mode Exposure: 12.8 sec (16 Cycles), JPEG Quality: Q75, Data rate: >2280Mbits/map Note: If the exposure time may cause the saturation, please decrease it. Note: Since the data size of SP is very huge for the allocation data size of SOT, we can observe only one SP map during two days. It is OK. Note: set margin factors to 1.4 for FG and SP

Annotations:
Hits: 55
Chief Observer
Cruz (RCO)
Related Links
Cites: HOP 81 N Pole Deep Scan Mode     
Timeline: gif use
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wavelength: 6302A Continuum Intensity cadence: -1 min fov: 320,162 images: 2042 JavaScript Landing Page
wavelength: 6302A Velocity 6301.5A cadence: -1 min fov: 320,162 images: 2042 JavaScript Landing Page
wavelength: 6302A Transverse Flux Density cadence: -1 min fov: 320,162 images: 2042 JavaScript Landing Page
wavelength: 6302A Longitudinal Flux Density cadence: -1 min fov: 320,162 images: 2042 JavaScript Landing Page