Starship Asterisk*

VictorBorun wrote: ↑Thu May 02, 2024 6:58 pm

AVAO wrote: ↑Thu May 02, 2024 5:46 am

VictorBorun wrote: ↑Wed May 01, 2024 8:12 pm

I wonder why does SSDS fish have a collar (just like APOD fish does) and neither GLIMPSE nor SPITZER fish do?

Good point. Well I think that since both work in the IR range, the view changes from dark dust clouds to bright warm gas clouds which appear practically equally bright in the front and back areas. This causes the dark collar to dissolve.

Here I mix IR-with-collar (as cyan+blue) and IR-without-collar (as yellow+red) to make the things look more 3d.
And hang the fitting fragment of APOD (Hubble colours).

IC 1795 The Fishhead Nebula (2024 May 01)..jpgIC 1795 The Fishhead Nebula (2024 May 01).2.jpg

...

Click to view full size image 1 or image 2

AVAO wrote: ↑Thu May 02, 2024 5:46 am

VictorBorun wrote: ↑Wed May 01, 2024 8:12 pm

AVAO wrote: ↑Wed May 01, 2024 7:03 pm

I still find the area very exciting even in IR.

Click to view full size image 1 or image 2

jac berne (SSDS/GLIMPSE)

Click to view full size image 1 or image 2

jac berne (SSDS/SPITZER)

I wonder why does SSDS fish have a collar (just like APOD fish does) and neither GLIMPSE nor SPITZER fish do?

Good point. Well I think that since both work in the IR range, the view changes from dark dust clouds to bright warm gas clouds which appear practically equally bright in the front and back areas. This causes the dark collar to dissolve.

Chris Peterson wrote: ↑Thu May 02, 2024 1:34 pm

johnnydeep wrote: ↑Thu May 02, 2024 1:15 pm

Chris Peterson wrote: ↑Thu May 02, 2024 12:33 pm
Well, yes... not really an option with most astronomical objects, though!


Angular sizes are usually only given when they are interesting in their own right for some reason (like if an object is the apparent size of the Moon). But they are always easily determined in any image with more than a handful of stars.

Why is that? Is it simply because if the star's identities are known, then we already know their angular separations?

Pretty much any image with stars in it can be solved with local or online software that matches physical stars in an image to a catalog. For instance, here's the Astrometry.net blind solution for this APOD. And below that, a much richer solution identifying many stars, this from PixInsight (not a blind solver, but using the Astrometry.net solution as a starting point).

Of course, from the imager's standpoint, the image scale is known simply from the telescope focal length and the size of the sensor.
_
Screenshot 2024-05-02 072406.jpg
new_image_Annotated.jpg

johnnydeep wrote: ↑Thu May 02, 2024 1:15 pm

Chris Peterson wrote: ↑Thu May 02, 2024 12:33 pm

roses wrote: ↑Thu May 02, 2024 11:51 am

I was declaring the Snowman's height, not estimating.

Well, yes... not really an option with most astronomical objects, though!

Because no subtended angle was explicitly mentioned, my brain decided there were only 2 knowns in a 3-variable equation relating angle, distance and width, and the width estimate was premature.

Perhaps for brevity, angular widths are not mentioned every time in APOD size estimates. From now on, when not mentioned, I'll assume it's known.

Angular sizes are usually only given when they are interesting in their own right for some reason (like if an object is the apparent size of the Moon). But they are always easily determined in any image with more than a handful of stars.

Why is that? Is it simply because if the star's identities are known, then we already know their angular separations?

Chris Peterson wrote: ↑Thu May 02, 2024 12:33 pm

roses wrote: ↑Thu May 02, 2024 11:51 am

Chris Peterson wrote: ↑Wed May 01, 2024 1:46 pm
But in order to determine that the snowman is 2 meters high, we need to know our distance from it and the angle it subtends at that distance. Likewise for the nebula. ...

I was declaring the Snowman's height, not estimating.

Well, yes... not really an option with most astronomical objects, though!

Because no subtended angle was explicitly mentioned, my brain decided there were only 2 knowns in a 3-variable equation relating angle, distance and width, and the width estimate was premature.

Perhaps for brevity, angular widths are not mentioned every time in APOD size estimates. From now on, when not mentioned, I'll assume it's known.

Angular sizes are usually only given when they are interesting in their own right for some reason (like if an object is the apparent size of the Moon). But they are always easily determined in any image with more than a handful of stars.

roses wrote: ↑Thu May 02, 2024 11:51 am

Chris Peterson wrote: ↑Wed May 01, 2024 1:46 pm

Guest wrote: ↑Wed May 01, 2024 1:43 pm I think, regardless of the observer's distance to the object, its width, in light-years, is static.

I.E.

Q:"How tall is Snowman?"
A: 2 meters

Q: I've doubled my viewing distance from Snowman; now how tall is Snowman?
A: 2 meters

But in order to determine that the snowman is 2 meters high, we need to know our distance from it and the angle it subtends at that distance. Likewise for the nebula. ...

I was declaring the Snowman's height, not estimating.

Because no subtended angle was explicitly mentioned, my brain decided there were only 2 knowns in a 3-variable equation relating angle, distance and width, and the width estimate was premature.

Perhaps for brevity, angular widths are not mentioned every time in APOD size estimates. From now on, when not mentioned, I'll assume it's known.

Chris Peterson wrote: ↑Wed May 01, 2024 1:46 pm

Guest wrote: ↑Wed May 01, 2024 1:43 pm I think, regardless of the observer's distance to the object, its width, in light-years, is static.

I.E.

Q:"How tall is Snowman?"
A: 2 meters

Q: I've doubled my viewing distance from Snowman; now how tall is Snowman?
A: 2 meters

But in order to determine that the snowman is 2 meters high, we need to know our distance from it and the angle it subtends at that distance. Likewise for the nebula. ...

VictorBorun wrote: ↑Wed May 01, 2024 8:12 pm

AVAO wrote: ↑Wed May 01, 2024 7:03 pm

johnnydeep wrote: ↑Wed May 01, 2024 4:59 pm In context from a wider field of view image at one of the links in the text:


fish head, heart, and soul nebulas.jpg

I still find the area very exciting even in IR.

Click to view full size image 1 or image 2

jac berne (SSDS/GLIMPSE)

Click to view full size image 1 or image 2

jac berne (SSDS/SPITZER)

I wonder why does SSDS fish have a collar (just like APOD fish does) and neither GLIMPSE nor SPITZER fish do?

AVAO wrote: ↑Wed May 01, 2024 7:03 pm

johnnydeep wrote: ↑Wed May 01, 2024 4:59 pm In context from a wider field of view image at one of the links in the text:


fish head, heart, and soul nebulas.jpg

I still find the area very exciting even in IR.

Click to view full size image 1 or image 2

jac berne (SSDS/GLIMPSE)

Click to view full size image 1 or image 2

jac berne (SSDS/SPITZER)

johnnydeep wrote: ↑Wed May 01, 2024 4:59 pm In context from a wider field of view image at one of the links in the text:


fish head, heart, and soul nebulas.jpg

Chris Peterson wrote: ↑Wed May 01, 2024 1:46 pm

Guest wrote: ↑Wed May 01, 2024 1:43 pm I think, regardless of the observer's distance to the object, its width, in light-years, is static.

I.E.

Q:"How tall is Snowman?"
A: 2 meters

Q: I've doubled my viewing distance from Snowman; now how tall is Snowman?
A: 2 meters

But in order to determine that the snowman is 2 meters high, we need to know our distance from it and the angle it subtends at that distance. Likewise for the nebula. If our estimate for the distance is incorrect (which is often the case in astronomy) than our estimate of size is, as well. The caption is merely making the simple calculation, based on an assumption about distance.

JWP456 wrote: ↑Wed May 01, 2024 2:59 pm "The absolute distance (which is a useful thing to know) is calculated from the angular size of the object. The majority of APOD images of deep sky objects present a physical (absolute) size based upon subtended angle and estimated distance".
Yes, the descriptions usually give the angular diameter (as seen from earth, of course) and estimated distance, from which the estimated diameter of the object may be calculated as the tangent of the given angle times the distance. Thus in this case tan 0.668 x 6000 = 70. While determining the diameter in light years by multiplying the distance in light years by half the subtended angle of the object and then doubling the result is more mathematically precise, I think the distances to objects like this nebula are not in most cases known with sufficient accuracy to justify that step.

roses wrote: ↑Wed May 01, 2024 2:10 pm Your last post mentions spanning an angle, which is reasonable. The article didn't - it mentioned an absolutewidth.

I think the author should re-state the width as an angular diameter, or relative to something else E.G. Moon radius, not light-years.

zforgetaboutit wrote: ↑Wed May 01, 2024 1:18 pm "At that distance, IC 1795 would span about 70 light-years across."

I don't understand how a width, expressed here in absolute units, is related to distance.

Guest wrote: ↑Wed May 01, 2024 1:43 pm I think, regardless of the observer's distance to the object, its width, in light-years, is static.

I.E.

Q:"How tall is Snowman?"
A: 2 meters

Q: I've doubled my viewing distance from Snowman; now how tall is Snowman?
A: 2 meters

zforgetaboutit wrote: ↑Wed May 01, 2024 1:18 pm "At that distance, IC 1795 would span about 70 light-years across."

I don't understand how a width, expressed here in absolute units, is related to distance.