Tuesday, June 29, 2021

Red Dot Finder

Red Dot Finder
What is this strange looking piece of plastic doing on my telescope?


Telescope companies began shipping telescopes with a red dot finder, a cheap piece of plastic that projects a red dot onto a small piece of viewing plastic. Using the human eye, objects visible can be found and centered. This is usually the Moon and brighter stars. For areas of heavy light pollution, it won't show any stars dimmer than what the human eye can see, so basic star hopping may not be an option. The illustration shows the Orion EZ Finder II for $39.99 and it's included on beginner telescopes. The same red dot finder sells for about $12 from China sources. The device uses a button battery and it's easy to forget and leave the finder on and then the battery burns out and needs replacing. Button batteries are not always easy to find at the store.

The finder design is not new. Many old timers will remember the Telrad finder from decades ago. It originated in the late 1970s when Steve Kufeld of Huntington Beach, California came up with the idea to manufacture an economical sight to help amateur and professional astronomers find their way across the night sky. "The Telrad is a different kind of device for aiming a telescope. It has been very popular with amateur astronomers since its introduction in 1978. The Telrad works on an entirely different principle, and has some distinct advantages over its optical finder scope cousin. 

Using a lens and light from a red LED and a glass beam splitter, the Telrad projects a nearly parallax-free, illuminated red bulls-eye into the observer’s eye. When the observer looks through the glass window, the bulls-eye appears to be projected onto the sky." Source

While the red dot finder is a great invention, and good for bright objects and beginners, the telescope may need another finder for dim objects. I recommend a 5x24 finderscope with lenses to see dimmer stars over the human eye, but not too many stars making the star field confusing. A 6x50 finderscope might show too many stars. It depends on the location and application. One could keep the red dot finder for locating bright objects and add another finder to the telescope for seeing dimmer stars when starhoping.

More about red dot finders, etc.
Orion Starblast Telescopes have a red dot finder
Celestron FirstScope 5x24 Finderscope

Orion StarBlast Telescopes Order Update


Orion StarBlast Telescopes
Order Update


The order was placed online late night (around 11 pm) Wednesday, June 23rd, 2021 and was shipped on Friday, June 25th by Orion. It's scheduled to arrive internationally in only two more days (today is Tuesday, June 29). It took a phone call to Orion's international phone number to find out the UPS tracking number and get the order shipping details. Ordering internationally is always far more expensive. Here's a breakdown of the details: nternational: 1-831-763-7000 (not toll-free). Monday through Friday 6:00 AM - 5:00 PM Pacific Time and Saturday 8:00 AM - 2:00 PM Pacific Time. Closed Sunday.
$229.99 StarBlast II 4.5 EQ Reflector & AstroTrack Motor Drive  (US $253.47)
$199.99 StarBlast 4.5 Astro Reflector Telescope  (US $220.33)
$199.99 1.25" Premium 20-Piece Color Planetary Filter Set x 1 (US $220.33)
Shipping UPS Expedited 4-7 Days (US $501.47)
Customs Duty and Tax (US $125.47)
Order Total  (US $1320.95)

Saturday, June 26, 2021

New Orion Telescopes on Order

New Orion Telescopes on Order
The goal is to have old school smaller telescopes which are lighter weight, easy to carry, fast to set up, adjustable, occupy a small footprint, and easy to use!


STARBLAST II EQ
First up is this Orion StarBlast II 4.5" EQ f/4 parabolic Reflector & AstroTrack Motor Drive is capable of astro imaging and has a total weight of only 20.7 pounds. The OTA is 4lbs. and the mount with tripod is only 11.9lbs. The German Equatorial counterweight adds a mere 4.8lbs. One welcomed old school feature is the clock drive. It can set a simple sidereal tracking drive rate with only one button. Power is from a simple 9-volt battery. Setting circles and a finder will facilitate star hopping to find deep sky objects without a computer. A computer however can dedicate
itself to imaging and processing images.

STARBLAST
The second telescope ordered is the tabletop "grab and go" Dobsonian version StarBlast. Remarkably, the total weight of this telescope is only 13lbs (7.7lbs lighter than the EQ). It can carry with one hand, and will be ideal for Lucky Imaging of sky objects where they are left to drift across the FOV without a drive, a camera takes thousands of short exposure images, and a video is captured and processed. This works for both telescopes.

TELESCOPES COMPARED
The OTAs appear to have a blue and green color variation and they come with different oculars - the EQ has better Sirius Plossls,  a 25.0mm and 10.0mm giving a magnification of 18x and 45x respectively. The tabletop comes with lesser quality Explorer II Kellner 17.0mm and a 6.0mm giving magnifications of 26x and 75x respectively. Another curious difference quoted in the specs concerns the primary mirrors. EQ has soda-lime plate glass and the tabletop has low thermal expansion borosilicate glass. Both versions offer the EZ Finder II finderscope. This is 1:1 and has no light gathering ability - it can be replaced with a standard lens finder or a cell phone with a sky app for starhopping.

ADVANTAGES ARE MANY
These telescopes are physically small taking up very little space - a footprint ideal for operating from a room and window in the home or a small observatory. The tabletop is extremely easy to use with only a simple altitude knob. The tabletop and the EQ can adjust weight by rotating and changing the OTA tube position to compensate for the addition of accessories.

MODIFICATIONS
For serious starhopping, the EZ Finder II finderscope will need to be replaced or supplemented. At 1:1 and no light gathering ability - it does not offer ability to show dimmer stars over that of the human eye. In a severe light polluted environment, it's likely the EZ Finder II finderscope will show no stars or only one or two of the brightest. It may have strength in quickly centering the Moon and bright planets. The addition of a cel phone finder with a sky app will create a push to goto telescope. These generally lose accuracy when moving across a large section of the sky, from East to West or North to South for example. However, observing from a room or deck, only one quadrant of the sky is viewed at a time and the cell phone finder will perform well.

EQ-1 MOUNT
This mount is compatible with other small telescopes, like the Orion 80mm refractor and rings. Having a clock drive gives it many advantages.

EMULATION & APPLICATIONS
Emulating a $3,000.00 4.5" aperture Unistellar eVscope with a $200 Orion StarBlast is one project, for imaging deep sky objects. Instead of trying to find objects using an unreliable eVscope's internal computer, the StarBlast telescopes will use manual starhopping to locate objects and a new technique called Lucky Imaging, with and without a drive. A computer will handle the camera software and processing.

Indoor Observatory

Inventing the Indoor Observatory
Above: observing indoors with a focus on the Moon - the sky portal size, area of visibility and which objects are visible at any given date and time, are calculated with an astronomy app. The Celestron CGX/L goto mount with the short OTA 14-inch EdgeHD catadioptric is ideal for indoor observing through an opened window or window glass. Adjacent to the telescope are indoor electrical receptacles, camera imaging computers and accessory racks - the epitome of indoor observatory convenience.

Indoor Observatory
The indoor observatory includes telescopes kept in a room inside a home, and are used for observing through window glass or an open window, in a comfortable regulated environment. This achieves the greatest convenience.

Left: small Dobsonian tabletop telescopes, like the upgraded "grab and go" collector's
signature edition Celestron FirstScope, are extremely convenient when observing indoors

Chromatism
Instruments, such as optical atmospheric chromatic dispersion correctors (ADC), may be used to compensate window glass to improve the overall image quality and to reduce and mitigate optical defects. 

Plane Dimension
Telescope optical orientation to the plane of window glass is corrected through software.

Observing Through Window Glass
Obtaining good astro imaging through window glass necessitates image processing to correct double images, image softening, planar deviation, contrast reduction, color skewing and other factors.

Left: the Moon through the indoor Celestron 14" Edge HD

Experiments were performed with large and small telescopes and the result compared for the notion of an indoor observatory. Telescopes reside indoors, completely isolated from the outdoor elements, such as bugs and mosquitoes, extreme heat and humidity, and bitter cold and wind.

Remote Controls
Extra remote observatory control elements are not needed and power is readily available, often with several computers. Visual observing and imaging are possible with astro imaging using computer image processing to improve the images. 

Telescope Aperture
Telescope size makes a difference in the quality of the observation. Observing through window glass is a lot like observing through the atmosphere - small telescopes perform better across the smaller wavefront than larger scopes because they look through a smaller diameter of window glass which will have less deviations.

Window Glass Quality
Other defects up for compensation and correction include off axis planar orientation, nonhomogeneous glass, and chromatism. The quality of the float window glass can also widely vary.

Room Reflections
Eliminate and minimize internal nuisance ghost reflections from the glass window by turning off indoor lighting.

Left: the Moon image taken with the indoor 2.99-inch Celestron FirstScope Dobsonian is processed to subtract window glass. Imaging through window glass can change the focus, reduce contrast and soften the image.

Double Image
The double image anomaly can result from two sided reflections off the window glass, front and back surfaces. Design image processing to subtract (more complex) or suppress (more simple) the weaker of the two images, which is normally the backside image coming back through the first surface.

Glass Thermal Insulation
Be sure to avoid thermally insulated glass of the double pane type. This would create additional unwanted reflective images and aberrations. Window glass can also cause thermal convection if the indoor and outdoor temperatures vary too much. In this case there are two corrective options. Make the temperature indoors the same as outdoors, or use lucky imaging techniques.

Polar Align Indoors
The indoor telescopes are set up, calibrated to north as needed using a compass, and positioned for maximum viewing. 

Window Size
It helps to observe through a large deck glass door to see more of the sky. Of course a small telescope and a small bedroom window sill may be ideal.

Glass Avoidance
As a simple option, put on bug repellant, slide the window open, equalize the temperature differential, and bypass the glass.

Telescopes Indoors
Telescopes kept indoors under regulated temperature and humidity have an advantage and will not be as prone to dewing. In some cases, expensive large outdoor telescopes were known to dew over inside the sealed Schmidt-Cassegrain tubes, ruining the telescope or causing a very complicated repair disassembly.

Sky Area of Visibility
A portal of sky visibility is determined and a planetarium app calculates which objects will be visible in the window on any given date and time. It can also determine how long the object will be visible.

Blast from the Past: Old school telescopes often had the front end capped with a flat of conventional 1:1 plate glass. These telescopes were primarily visual and the user dealt with any problems caused by the telescope's glass window. Essentially these old telescopes were looking through a window, not much different than a house window.

Left: Celestron's cell phone mobile sky app, free SkyPortal, can determine the window of opportunity for available objects at a given date and time when observing from indoors

Indoor Observatory

Wednesday, June 23, 2021

Telescope Thoughts

Telescope Thoughts

Rambling through telescope thoughts tonight

Nobody knows why the three thousand + dollar Unistellar eVscope failed so miserably. Yeah, we were prepared to be amazed as they promised in their advertising, but we only got a disappointing defect that had to be returned to the dealer. Perhaps the telescope could not deal with the heavy light pollution that exceeds the Bortle scale, or high altitude mist that blocks some stars, or just maybe the metal in the building killed the WIFI. After that fiasco, our taste for digital telescopes went to zero indefinitely. And with advertising filling our box for its competition, Stellina, we easily look the other way and delete the claims readily.

What about the long standing GOTO Celestron digital mounts as in the Celestron CGX/L? We've had a mental block in using one and after three years, still no luck with the system. Blame it on a different Asian set of GPS satellites, or problems with the Asian time zones, or a magnetized slag mount needing a protective Faraday Cage, or whatever. After that, my taste for digital mounts went to zero.

Alas, the working solution is at hand. I'm going back to trusted old school, reliable setting circles, finding objects manually with a finderscope and a small equatorial mount, and running a clock drive from a 9-volt battery that has one simple knob. I will use small telescopes that can be lifted with one hand, easily moved and ones that are fun to transport, and a real joy to use. I'm taking back astronomy and astrophotography the way it was, fun and exciting and every time out was a new discovery.

Wednesday, June 2, 2021

Light Pollution City

 

Light Pollution City
This city has a rating beyond a Bortle number with all its light pollution and air pollution sky haze

The author has invented the Penetrator, an invention to cut through sky dynamics such as light pollution, haze, fog, smog, air pollution, light overcast, a sheen of atmospheric water vapor, and thin clouds.