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Planetary Observing Presented by John Bishop June 2007 This Talk Focused on visual observing only No planetary mechanics (go to S&T for what’s up tonight) Lots of ‘how-to’s Some equipment considerations There’s also a “human side” Planets Are Different! Small Bright Detailed
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Planetary Observing Presented by John Bishop June 2007
This Talk • Focused on visual observing only • No planetary mechanics (go to S&T for what’s up tonight) • Lots of ‘how-to’s • Some equipment considerations • There’s also a “human side”
Planets Are Different! • Small • Bright • Detailed • Individual
Planets are Small • Neptune is 2 arc-seconds; Venus can be almost 60 arc-seconds during a transit – but that’s still quite small! • Small means you need to magnify • Small means seeing is very important • Small means smoothness (quality) of optics is important
How Much To Magnify? • Atmosphere limits us to about one arc-second seeing: image blur pixels are thus about one arc-second dots • Our eyes have pixels that are about one arc-minute dots • The minimum magnification to see all the detail is thus about 60x. • But there’s more!
More on Magnification Use changes in magnification to: • Adjust the brightness to a comfortable level • Change the visibility of colors (more later) • Change the contrast (more later) • Tease out more detail by matching the pixels of the contrast to your eye pixels • Prepare your image for the “lucky instant” of good seeing
Magnification and Tracking • Magnification magnifies Earth’s rotation as well • You can hand-track at 300x – but then you can’t do anything else! • Tracking is a huge help • Equatorial mount • Tracking table • If you can’t track, use a lower magnification
Planets Are Bright • Magnitude 8 to -4 (Venus is the third brightest natural thing in the sky!) • Don’t need to gather lots of light • Glare (too much light) can be a problem • Color sensed varies by light level • Too much or too little washes out color • Good news: brightness permits the use of filters
Planets Are Detailed • They have details going way below 1 arc-second • They have color and brightness variations • They have high-contrast and low-contrast features • Only Mars (and Mercury, in theory) have a visible surface; Jupiter has long-lasting cloud features; Saturn has ring features • They can be oblate; Venus and Mercury can be crescents
Color and Colored filters • Colored filters can increase contrast at the cost of dimming (use lower magnification) • Named by “Wratten” numbers (+”A”…) • Light filters are better than dark ones: we’re after subtle effects, not mood lighting • Dark filters require a bright image (big aperture and/or low magnification) • There are special “Planetary Contrast” filters; I haven’t tried them • Try any you have!
The Filters I Use Most Often • light yellow (#8) • light blue (#82) • magenta (#30, “Minus Green”; hard to find, worth finding) • orange (#21) • nebula (e.g., DGM VHT, good on Mars if you don’t have magenta) • neutral (“Moon” filter)
Filters I Have And Don’t Use • Green (#56) • Dark Blue (#80) • Red (#25) • Dark Yellow (#12 – “Minus Blue”) • Violet (#47)
Filters Which Might Be Useful • Yellow-Green (#11) • Light Amber or “Salmon Pink” (#85) • “Planetary Contrast” • Mars “BandMates”,: Mars A, Mars B • O-III • H-α • H-β
Filters I Can’t Find • “Minus Yellow” – Cyan (?) • “Minus Red” – Blue-green (#44)
Planets Are Individual • Each planet is different and should be treated differently • Some are very rewarding to observe, some are not • They have history and a connection to myth • They are well-placed or otherwise!
Rewarding Planets • The rewarding ones are also the big crowd-pleasers at sky-watches • Mars: the winner for those who like science fiction • Jupiter: the winner for those who like moons • Saturn: the winner for those who like rings
The Planet Mars • Varies in apparent size up to 27 arc-seconds • Good “apparitions” about every 2 years • Lots of surface detail (and it’s a real surface!) • Cool names (Syrtis Major, etc.) • Ice cap, clouds vary from day to day • Sandstorms
Mars Observing How-to • Yellow, orange or red filters bring out dark areas • Neutral can bring out Hellas basis • Blue can bring out cloud details • Magenta filters are great – close to natural color and greater contrast of dark areas! • Nebula filter exaggerates colors, makes a bit blurry • Check ice cap edge – varies as melting happens • Rotates at near-Earth rate – so you’ll see the same side night after night • Responds well to changing magnification
The Planet Jupiter • Huge: 40 to 44 arc-seconds • Many different colors (blue, brown, white, pink…) • Lots of cloud detail, to limit of resolution • Rotates very fast – changes as you watch • Visibly oblate • Moons add interest
Jupiter Observing How-to • Try all your color filters! • Try varying magnification • Two big dark bands; look for detail beyond them: • Zones (white stripes) • Thinner bands (dark lines) • Spots (in zones and bands) • Festoons (diagonal stripes or interrupted lines) • Barges (next level down of detail, I think) • “Great Red Spot” is a “Pale Pink Spot” these days; look for “Red Jr.”
Jupiter’s Moons • Move while you watch • Moon goes behind Jupiter – occultation • Moon goes into Jupiter’s shadow – eclipse • Moon in front of Jupiter – transit (hard to see) • Moon’s shadow on Jupiter – shadow transit (dramatic)
Observing Saturn • Everyone loves the rings – use yellow filter to bring out Cassini’s Division • Use blue filter to emphasize ring details • 1 to 6 moons visible; the inner ones move while you watch • Planet has subtle banding (use yellow and blue filters)
Not-so-Rewarding Planets • Mercury • Venus • Uranus • Neptune • The “rest”
Observing Mercury • Has phases • Always close to sun and thus usually near horizon – can use “Horizon Wedge” to see without color blur • No easily-visible surface detail (like highlands of Moon: all craters) • “Old guys” thought they saw features and timed Mercury’s rotation – they were wrong!
Horizon “Wedges” • Atmosphere acts like a prism near the horizon (“atmospheric dispersion”) • You can get 2- or 4-degree prisms to compensate for atmospheric dispersion • Get the 2-degree prism; if you want 4-degrees of correction, get two of them • Require lots of back-focus; may need Barlow-ing to achieve focus • Big improvement, but can’t completely compensate for dispersion • Really only good for Mercury or sky-watches when you want to show a planet and the only one around is low
Observing Venus • Has phases • Very large at times – good in small scopes • Usually no surface detail -- violet filters are said to show cloud detail
Observing Uranus • No detail visible in 4 arc-second disc • Gorgeous bright yellow-green or green • Obvious, non-stellar color • Titania is mag 14, visible in very large telescopes
Observing Neptune • No detail visible in 2 arc-second disc • Dark blue – edge indistinct due to limb darkening • Greener in big telescopes • Obvious, non-stellar color • Triton visible in larger scopes, mag 13.6
Observing the “Rest” • Mostly you look at these just to say you saw them • Pluto – just a mag 13 dot • Asteriods – brighter dots • Galilean Moons – 1 arc-second discs but bright; people have seen detail on Ganymede
The Ideal Planetary Telescope • Right eyepieces – simple, narrow-angle • Right focal length – long, f/big • Right aperture – small • Right design – unobstructed, driven • The “old guys” weren’t so dumb after all!
The Right Eyepieces • You want non-coloring, contrast-saving designs • Small number of surfaces is best (less scattering) • Some edge distortion is ok • Wide angles are definitely not needed • Most eyepiece designs work best between 10 mm and 20 mm • Barlows remove contrast – you want single eyepieces if possible • Orthoscopics and Monocentrics are the classic choices; Plossls ok
The Right Focal Length • You want powers between 60x and 300x • 300x with a 10 mm eyepiece means a focal length of 3000 mm; 60x with a 20 mm means a focal length of 1200 mm • You have to make some compromises • The ideal focal length is at least 1500 mm; 2000 mm is better.
The Right Aperture • You don’t need lots of light-gathering • You want resolution, but the maximum the sky supports is about 1 arc-second • 4 inches gives 1 arc-second resolution, 8 gives ½ arc-second • Larger apertures may have more seeing issues • Larger apertures are hard to make high-quality • The ideal aperture is thus a bit over 4 inches: 5 or 6 is great, 8 maybe too much of a good thing.
The Right Design • Obstructions rob contrast • Under 15% not too bad – planetary-optimized Newtonians • Maksutovs and SCTs are losers here (30% or more) • Refractors are good if they are long enough • Long focal lengths (4-inch f/10, 6-inch f/20) mean that achromats will have almost no color error; superior correction of apochromats not needed; short apo-s not long enough • Unobstructed reflectors have no color problems at all: • Off-axis Newtonian • Schiefspieglers • Yolos • Even-more exotic designs exist (tetra-schiefs...) • Schupman medials are great (ATMOB has one) • Mounting and tracking a long scope is an issue
If Your Scope Isn’t Perfect • Non-planetary Newtonian • Short-focus apochromat • Short-focus achromat • SCT or Maksutov
Newtonians • Use high and low magnifications • Try an off-axis mask on 12-inch or bigger • Hole should be a convex shape • Position between spider vanes • Re-collimate telescope for best results • Collimate normally • Add mask • Re-center secondary to point to off-axis section • Re-collimate primary with star collimation
Short-focus Apochromat • Use Barlow or Powermate to get higher magnifications • Learn to see details at low magnifications
Short-focus Achromat • Use Barlow or Powermate to get higher magnifications • Use “anti-violet” filters to eliminate color fringes at higher powers • Better – get used to the color-error and train yourself to see “past” it. • Consider a mask (90%, 80%) • Raises f-number • Reduces color error
Achromat Example • Rule of thumb is “for an N-inch achromat to have minimal color error, it should be f/3N” • Orion 120 mm f/8.3 has a 1000 mm focal length • A 110 mm mask produces a 4.3-inch f/9 • A 100 mm mask produces a 4-inch f/10 • A 92 mm mask produces a 3.6 f/10.8 (fits the rule) • Trade color error for brightness and resolution
SCT Or Maksutov • Use very high or very low magnifications to put the contrast frequency of interest in the “sweet” spot (rapid variation) • Aperture will compensate somewhat for obstruction
The Human Side • Your eye is not a camera and your brain is very involved with perception • Your perception can be trained: the more you know, the more you’ll see • You can accumulate perceptions (even if you can’t accumulate photons) • If you just look, you won’t observe: engage your mind • Therefore…
Draw What You See • Accumulates transitory details • Even “one flash” of detail is probably real • Accumulates information from all magnifications and filters • Forces you to really see details (“a blob” vs. “a one-tenth diameter dot two-thirds of the way out from the center towards 2 o’clock”) • Gives you a permanent record to show other people
How to Draw Planets • Make a circle 2-inches or more in diameter beforehand • Sketch in details with pencil as you observe • Talk to yourself and take notes • Use a dim red light to guide your drawing; note color with labels • Have a solid base for the paper; tape down so wind doesn’t move it • Finish or copy afterwards using ink and colored pencils