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benzomobile

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Everything posted by benzomobile

  1. Your scope has got a parabolic mirror 🙂 B
  2. Ordinary barlows used in low-priced short newts (as Seben ones are), actually, don't correct SA. It only extends the distance of the focus. Beppe
  3. PS: The mirror of the Seben Big Boss - if it is not a real Jones Bird, should be parabolic. In this case, good images at the primary focus require a coma corrector, optimized for f/4 aperture ratio. If, on the other hand, the mirror is spherical - as I believe, the result will unfortunately be far from good 😞 B
  4. Hi. Barlowed newtonians unfortunally are not Jones Bird! A Barlow lens simply increases the focal length, whereas the negative doublet of a Jones Bird is a true corrector that eliminates both spherical aberration and coma at the cost of increased astigmatism and field curvature. Sub-aperture lens correctors for single-mirror telescopes (telescope-optics.net) A true Jones Bird was the Celestron (Vixen) Comet Catcher Jr. but it is no longer in production. I have one (which I modified to be easily collimated): for planetary imaging it is a very good instrument. Beppe
  5. It works in Windows 10 64bit too. Beppe
  6. Bravo! There are only just one defect in your excellent astrographic elaboration : Wynne-Riccardi coma corrector costs, perhaps, more than the rest of the telescope 🙂 Beppe
  7. Of course. I'm actually doing a tutorial with photo documentation. I haven't used that tool in many years, so I need a few days for this. Beppe
  8. I think you don't have to worry about that. Well done! B
  9. I am afraid that the seat where the mirror is glued has deep edges ... B
  10. Do you you tried soaking it in boiling water? B
  11. I definetely hate GSO mechanic solutions ... Beppe
  12. Hi to all, Bird Jones scopes have three advantages respect Newt ones: 1) their size is compact, so they are lighter; 2) their primary mirrors have spherical shape (very easy to figure out); 2) they show neither axial nor extra-axial distorsions as Newt ones do, having same aperture ratio. I purchased back in 1985 a Comet Catcher Jr (Cometron). The instrument, as you may know, is a TRUE ONE Bird-Jones 125mm diameter and 1000mm equivalent focal length. I had noticed early on that the trouble with this OTA depended on a huge collimation difficulty, NOT because bad optics!Its mechanical arrangement has been designed in a very rough way : a cylindric 'mug' housed the small elliptical secondary. It also supported the corrector at its end, and what's more, the entire block was precariously supported by only three rods attached to the tube. In addition, the primary mirror apparently had no possibility of being collimated.However, the instrument by some stroke of ... luck (!) could occasionally give me planetary images of better quality than a classic very good Newtonian, having the same optical-geometric characteristics (5" f/8). I noticed that on the primary cell edge, there were three threaded holes (M3). It was evident they were used to collimate the mirror ONCE FOR ALL, before the scope being placed on the market (only tightening thoroughly the three screws that secure the cell to the tube). Once the cell was removed - or even accidentally moved, it was impossible to reposition it properly. At that point I set to work to make its collimation more precise and stable possible. This was my intervention: 1) I fastened three short M4 hook screws 120° apart on the inside edge of the cell. I then put three more screws from the outside of the tube - secured on the inside with nuts, about 90mm from the end of the tube and in line with the screws on the cell. Once I extracted the mirror (it slides out from the outside, after removed the round plate that holds it in place, I then applied three coil springs of appropriate strength between each of the two pairs of screws. I put the mirror back in and reposition the plate in its place. I buy short M3 knobs to screw them into the 3 threaded holes of the cell. Now the primary mirror coluld be easily and precisely collimated! 2) A well trusted glazier drilled a hole of 35 mm exactly in the center of the glass plate. The precision was pinpoint and the work was perfect. With the lathe I make a round plaque + an extension ring - both aluminum, that I will use to secure at the glass plate the cylindrical block housing the corrector + the secondary. The extension ring has adequate length to ensure the original distance corrector/primary mirror. In this way, the block cannot longer move by itself. I replaced the original secondary pivot with a piece of M4 bar, I put a coil spring on it and I placed three adjustment knobs - which were not originally designed to be there (!). Knobs of course go through the central round plaque. Now, the secondary position could thus be either adjusted along the optical axis, or tilted from it, and it was fairly locked in a suitable position with two nuts screwed on its the axial bar. Here you can also very well collimate the secondary mirror, too! Beppe
  13. Polyvinyl autoadhesive sheets: carbon fiber like outside and velvet black inside. Beppe
  14. Is it profitably usable in DSO imaging? Thank you in advance https://terramex.neocities.org/astro/ Beppe
  15. I can understand you, because I'm an old doctor. I wish you all the best for a full recovery. Polemaster aside ... 🙂 Beppe
  16. Try it, Carole. You won't be disappointed with this solution that allows you to do a quick, precise and intuitive polar alignment! What was tried several years ago was not really of much use, then worse than today now (I agree with malc-c in this sense only). Moreover, I know it very well because I tried it myself at that old time 🙂 Beppe
  17. Oh, I know that very well ! I made my first attempt to make a polarcam with CCD Logitech QuickCam (same sensor as Philips Toucam Pro) in 2008 ... I will be 68 yrs old very soon! 🙂 The one I have presented here is a different story, estremely different story. If you look carefully at my polar field snapshot, you can find stars up to almost the 11th magnitude. More than twentyfive years have not passed in vain since the days of Toucam ! !
  18. I'm sorry to contradict you, but this is something completely different. What's new: practically everything. First of all: newest technology. New Sony Exmor sensors have 100 fold more sensitivity as older Philips ccd webcam: 0.005 lux vs 0.5 lux! In addiction, integratd modules have sophisticated controllers, such as ISP chips (NVP2441 with IMX225) to process imaging data. Absolutely nothing to do with the old SPC webcams ! ! ! Those who say it is the same old thing do not know what they are talking about. 🙂
  19. This topic has become: 'Video assisted polar alignment - VAPA' Beppe
  20. Unfortunately, webcams (only the old CCD ones are good for that task) don't have enough sensitivity, so you can see Polaris and, perhaps four other stars only in their FOV. No modern CMOS webcams are useful, due to their very high intrisic noise 😞 Analog CCTV CMOS sensors as IMX225 or IMX322 (or few others) have high sensitivity (0.005 lux) and low noise. More sensitive (0.001 lux) CCD sensors as Effio A (ICX810/811) also are utilized in EAA: An Introduction to Electronically-Assisted Astronomy (EAA) | AstronomyConnect The electronics of the module are also too important as they allow you to configure all the necessary parameters to make these cameras an excellent choice for video astronomy. Beppe
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