Astroblog: February 2024

The Last Quarter Moon is Monday March 4. Jupiter is low in the north-western sky but still dominates the early evening sky. Venus is visible in the morning twilight below Mars. Mars continues to climb away from Venus as the week progresses.

The Last Quarter Moon is Monday March 4.

Evening sky on Saturday, March 2 as seen from Adelaide at 21:18 ACDST (90 minutes after sunset). Jupiter is low above the north-western horizon. The inset is the telescopic view at this time.

Similar views will be seen from the rest of Australia at the equivalent local time (90 minutes after sunset).

Morning sky on Saturday, March 2 as seen from Adelaide at 06:07 ACDST, (60 minutes before sunrise, click to embiggen). Venus and Mars are close, but get progressively further apart over the week. The inset in the approximate telescopic view of Venus at this time.

Similar views will be seen from the rest of Australia at the equivalent local time (60 minutes before sunrise).

Whole sky on Saturday, March 2 as seen from Adelaide at 21:18 ACDST, 90 minutes after sunset (click to embiggen). Jupiter is low in the north-west.

Orion is almost due north. Bright Sirius is high in the eastern sky. Between the bright star Canopus and the Southern Cross are a wealth of binocular objects to discover.

Elsewhere in Australia will see a similar view at the equivalent time (90 minutes after sunset).

Mercury is lost in the twilight.

Venus is in the morning twilight, it is sinking towards the horizon but will remain visible for all of March. Mars and Venus draw further apart.

Mars is rising in the morning twilight and moving away from Venus.

Jupiter is visible low in the early evening sky.

Saturn is lost in the twilight.

Printable PDF maps of the Eastern sky at 10 pm AEST, Western sky at 10 pm AEST. For further details and more information on what's up in the sky, see Southern Skywatch.

Star Map via Virtual sky. Use your mouse to scroll around and press 8 when your pointer is in the map to set to the current time.

Cloud cover predictions can be found at SkippySky.

Here is the near-real time satellite view of the clouds (day and night) http://satview.bom.gov.au/

Labels: weekly sky

# posted by Ian Musgrave @ 10:26 pm 0 comments

I don’t know about you folks, but the feed in the social media formerly known as twitter is currently dominated by “cute poop” ads (who seem to have displaced the chemtrailers) and flat earthers.

The former is a mildly puzzling Japanese phenomenon, while the latter appears to be dominated by people who have not progressed past a pre-Babylonian view of the world, but who possess P1000 cameras they don’t know how to focus.

Now as a long-time viewer of the the skies and their wonders, these folks give me the screaming irrits, but I take this as a chance for a teachable moment, and get people involved in measuring the distance to the Moon in a way that anyone can undertake. One of the tenets of the flat earth movement is that the sun and moon are both small and local (that sound you are hearing is the ghost of Aristarchus howling at the said Luna).

Now, Aristarchus used the time it took for earth's shadow to cross the Moon in a lunar eclipse and got a figure that was 1/3 the modern distance, not bad for unaided eye observation without modern clocks (and thousands of times further than the flat earth requirement of “local”).

Now there are no convent total lunar eclipses this year, so we can’t reproduce Aristarchus’s methods.

The most common method for determining the distance to the moon, if you are not bouncing lasers off the mirrors left by the Apollo Astronauts or Soviets, is parallax. For parallax you and a mate a couple of hundred kilometers away have to take an image of the Moon at the same Universal Time, close to one or more bright stars, with equipment that gives an image of roughly the same scale. And you both need clear skies. Then all you have to do is measure the distance between the stars and the moon, do a bit of maths and viola, you have the distance to the Moon.

Probably the next best time for parallax is May 23, when the Moon is close to delta Scorpii. Of course, all this requires a bit of organisation, as does most of the demonstrations of the sphericity of earth.

Fortunately, this is a way to determine the distance to the Moon that one can do just by themselves. All you need is a digital camera with a decent optical zoom function (or attached to a telescope), an accurate timestamp function, a clear horizon, and the patience to take images for most for the night, and an image analysis program like AstroimageJ to measure the Moons diameter https://www.astro.louisville.edu/software/astroimagej/index.html or a Python script.

The basic idea is that the moon at moon-rise is further away than the moon at the zenith by approximately the radius of the earth. (see figure 1, from https://arxiv.org/ftp/arxiv/papers/1405/1405.4580.pdf used under that fair use for research provisions).

All you have to do is measure the radius of the Moon as it rises and the radius of the Moon when it is highest, as well as an accurate measurement of the time the images were taken apply a bit of maths with the radius of the Moon and hey presto, the distance to the Moon! (full details in “The simplest method to measure the geocentric lunar distance: a case of citizen science” at https://arxiv.org/ftp/arxiv/papers/1405/1405.4580.pdf)

(Figure 2, from https://arxiv.org/ftp/arxiv/papers/1405/1405.4580.pdf used under that fair use for research provisions).

Well, of course it’s not that simple. Close to the horizon atmospheric distortion “squashes” the image messing with the accurate measurement of the radius (this is not the horizon illusion, where the Moon appears bigger, when, in fact it isn’t), also, it needs to be a full moon far from apogee or perigee, when there will be enough change in the Moons diameter as it reaches the furthest and nearest points in its orbit to mess up the calculation.

The Full Moon of February 24th is such a Moon, and this is my challenge: to take images of the Moon between moon rise and the Moon at zenith, then measure their diameter (making sure the images a re time stamped in some way, usually file creation data in the image header will suffice, just make sure you cameras clock is set correctly).

(Figure 5. Best fit of the measured apparent sizes (error-bars) to the theoretical model (continuous line. The shaded region
correspond to solutions statistically compatible with the observed apparent sizes at a 5% confidence level, from https://arxiv.org/ftp/arxiv/papers/1405/1405.4580.pdf .used with permission).

Of course then you have to run the Python scripts given in “The simplest method to measure the geocentric lunar distance: a case of citizen science” (at https://arxiv.org/ftp/arxiv/papers/1405/1405.4580.pdf. I did mention you needed python didn’t I? sadly, the links in that paper no longer work, but Jorge Zuluaga has kindly passed the scripts on to me so I can send them on. This link takes you to the Zip file with the Python Scripts. https://drive.google.com/drive/folders/1FXCgbYINt3hBBSU3gPzaY13MgSNIbtL1?usp=sharing

(Figure 6. Instantaneous distance as a function of time elapsed since the first observation. from https://arxiv.org/ftp/arxiv/papers/1405/1405.4580.pdf .used with permission).

You also need more than two Moon shots for the statistical analysis (see the figures and the linked paper). So, what do you think? Are you up for the challenge?

Labels: astrophotography, citizen science, Moon

# posted by Ian Musgrave @ 10:03 pm 1 comments

The Full Moon Moon is Saturday February 24. This is an apogee (or mini) Moon. Jupiter is low in the north-western sky but still dominates the early evening sky. Venus is visible in the morning twilight near Mars. Mars begins to climb away from Venus as the week progresses.

The Full Moon Moon is Saturday February 24. This is an apogee (or mini) Moon, with apogee on the 26th.

Evening sky on Saturday, February 24 as seen from Adelaide at 21:29 ACDST (90 minutes after sunset). Jupiter is low above the north-western horizon. The inset is the telescopic view at this time.

Similar views will be seen from the rest of Australia at the equivalent local time (90 minutes after sunset).

Morning sky on Saturday, February 24 as seen from Adelaide at 06:00 ACDST, (60 minutes before sunrise, click to embiggen). Venus and Mars are close, but get progressively further apart over the week. The inset in the approximate telescopic view of Venus at this time.

Similar views will be seen from the rest of Australia at the equivalent local time (60 minutes before sunrise).

Whole sky on Saturday, February 24 as seen from Adelaide at 21:29 ACDST, 90 minutes after sunset (click to embiggen). Jupiter is low in the north-west.

Orion is almost due north. Bright Sirius is high in the eastern sky. Between the bright star Canopus and the Southern Cross are a wealth of binocular objects to discover.The full Moon will make them hard to see though.

Elsewhere in Australia will see a similar view at the equivalent time (90 minutes after sunset).

Mercury is lost in the twilight.

Venus is in the morning twilight, it will now sink towards the horizon but will remain visible for all of February. Mars and Venus are close but draw apart.

Mars is rising in the morning twilight and moving away from Venus.

Jupiter is highest around civil twilight and is now visible low in the early evening sky.

Saturn is lost in the twilight.

Printable PDF maps of the Eastern sky at 10 pm AEST, Western sky at 10 pm AEST. For further details and more information on what's up in the sky, see Southern Skywatch.

Star Map via Virtual sky. Use your mouse to scroll around and press 8 when your pointer is in the map to set to the current time.

Cloud cover predictions can be found at SkippySky.

Here is the near-real time satellite view of the clouds (day and night) http://satview.bom.gov.au/

Labels: weekly sky

# posted by Ian Musgrave @ 12:00 am 0 comments


Black and white printable Spotters map for the Nova in Scorpius, at 5:14 ACDST (90 minutes before sunrise). Similar views will be seen in the rest of Australia at 90 minutes before sunrise. The Nova is in the "sting" of Scorpius, close to Lambda Sco. Click to embiggen and print.	Black and white printable binocular map for the Nova in Scorpius, use the spotter map to locate the general area then use this map for detailed location. The Nova is in the "sting" of Scorpius, close to l Scorpii and u Scorpii. Click to embiggen and print.

A bright Nova has been reported in Scorpius.PNV J17261813-3809354 was discovered by Andrew Pearce (Nedlands, W. Australia) on 2024 Feb. 09.8438 UT. It has been confirmed spectroscopically as a classical galactic nova. The nova is currently magnitude 6.4, just below unaided eye visibility, but easily seen in binoculars, see http://www.cbat.eps.harvard.edu/unconf/followups/J17261813-3809354.html for the details. You can get printable magnitude comparison charts at the AAVSO Variable Star Plotter https://app.aavso.org/vsp/

You will have to get up early in the morning to see it though. It doesn't rise until 1 am.

Labels: nova

# posted by Ian Musgrave @ 12:37 am 0 comments

The First Quarter Moon is Saturday February 17. Saturn is lost to view. Jupiter is now in the north-western sky but still dominates the early evening sky. Jupiter is near the Moon on the 15th. Venus is visible in the morning twilight above Mars. Mars climbs higher in the morning twilight closing in on Venus.

The First Quarter Moon is Saturday February 17. Maximum Libration is on the 19th.

Evening sky on Thursday, February 15 as seen from Adelaide at 21:42 ACDST (90 minutes after sunset). Jupiter is low above the north-western horizon and not far from the waxing crescent Moon. The inset is the telescopic view at this time.

Similar views will be seen from the rest of Australia at the equivalent local time (90 minutes after sunset).

Morning sky on Thursday, February 22 as seen from Adelaide at 05:58 ACDST, (60 minutes before sunrise, click to embiggen). Venus and Mars come progressively close over the week, and are now at their closest, less than half a finger-width ways. The inset in the approximate binocular view at this time, the pair will alos be visible in wide field telescope eye pieces.

Mercury is lost in the twilight.

Similar views will be seen from the rest of Australia at the equivalent local time (60 minutes before sunrise).

Whole sky on Saturday, February 17 as seen from Adelaide at 21:39 ACDST, 90 minutes after sunset (click to embiggen). Jupiter is low in the north-west.

Orion is almost due north. Bright Sirius is high in the eastern sky. Between the bright star Canopus and the Southern Cross are a wealth of binocular objects to discover.The waxing Moon will make them progressively harder to see though.

Elsewhere in Australia will see a similar view at the equivalent time (90 minutes after sunset).

Mercury is lost in the twilight.

Venus is in the morning twilight, it will now sink towards the horizon but will remain visible for all of February. Mars and Venus are spectacularly close on the 22nd.

Mars is rising in the morning twilight and is coming closer to Venus. The pair re spectacularly close on the 22nd.

Jupiter is highest around civil twilight and is now visible low in the early evening sky. Jupiter is near the Moon on the 15th.

Saturn is lost in the twilight.

Printable PDF maps of the Eastern sky at 10 pm AEST, Western sky at 10 pm AEST. For further details and more information on what's up in the sky, see Southern Skywatch.

Star Map via Virtual sky. Use your mouse to scroll around and press 8 when your pointer is in the map to set to the current time.

Cloud cover predictions can be found at SkippySky.

Here is the near-real time satellite view of the clouds (day and night) http://satview.bom.gov.au/

Labels: weekly sky

# posted by Ian Musgrave @ 11:11 pm 1 comments


ISS and Tiangong as seen from Adelaide on the evening of Friday 9 February at 21:07 ACDST. Simulated in Stellarium (the ISS will actually be a bright dot). Click to embiggen.	ISS and Tiangong as seen from Sydney on the evening of Friday 9 February at 21:37 AEDST. Simulated in Stellarium (the ISS will actually be a bright dot). Click to embiggen.	ISS and Tiangong as seen from Hobart on the evening of Friday 9 February at 21:37 AEDST. Simulated in Stellarium (the ISS will actually be a bright dot). Click to embiggen.

All sky chart showing local times from Heavens Above for Friday 9 February for Adelaide.	All sky chart showing local times from Heavens Above for Friday 9 February for Sydney.	All sky chart showing local times from Heavens Above for Friday 9 February for Hobart.

Tonight (Friday 9 February) most of Australia will see bright asses of the ISS and the Tiangong space station. Most are concurrent, but for Adelaide, Sydney and Hobart the occur at the same time (see above). There are too many passes for me to do all of Australia, so go to Heavens Above and look at the dedicated pass times for your site.

Adelaide:

ISS

Event	Time	Altitude	Azimuth	Distance (km)	Brightness	Sun altitude
Rises	21:00:26	0°	335° (NNW)	2,350	0.0	-9.1°
Reaches altitude 10°	21:02:40	10°	346° (NNW)	1,494	-1.1	-9.5°
Maximum altitude	21:05:38	30°	49° (NE)	788	-2.9	-10.1°
Drops below altitude 10°	21:08:39	10°	112° (ESE)	1,512	-1.3	-10.7°
Enters shadow	21:10:04	3°	119° (ESE)	2,048	-0.6	-10.9°

Date:	09 February 2024
Orbit:	416 x 419 km, 51.6° (Epoch: 08 February)

Tiangong

Event	Time	Altitude	Azimuth	Distance (km)	Brightness	Sun altitude
Rises	21:00:30	0°	244° (WSW)	2,261	4.2	-9.2°
Reaches altitude 10°	21:02:45	10°	232° (SW)	1,404	2.2	-9.6°
Maximum altitude	21:05:35	29°	169° (SSE)	736	-0.6	-10.1°
Enters shadow	21:08:22	10°	106° (ESE)	1,390	0.2	-10.6°

Date:	09 February 2024
Orbit:	373 x 383 km, 41.5° (Epoch: 08 February)

Sydney:

ISS

Event	Time	Altitude	Azimuth	Distance (km)	Brightness	Sun altitude
Rises	21:32:01	0°	306° (NW)	2,357	0.3	-19.0°
Reaches altitude 10°	21:34:08	10°	301° (WNW)	1,500	-0.7	-19.4°
Maximum altitude	21:37:27	57°	221° (SW)	505	-3.1	-20.0°
Enters shadow	21:40:04	15°	144° (SE)	1,224	-1.4	-20.4°

Date:	09 February 2024
Orbit:	416 x 419 km, 51.6° (Epoch: 08 February)

Tiangong

Event	Time	Altitude	Azimuth	Distance (km)	Brightness	Sun altitude
Rises	21:33:13	0°	241° (WSW)	2,258	3.4	-19.2°
Reaches altitude 10°	21:35:22	10°	233° (SW)	1,401	1.9	-19.6°
Enters shadow	21:38:22	42°	161° (SSE)	552	-1.3	-20.1°

Date:	09 February 2024
Orbit:	373 x 383 km, 41.5° (Epoch: 08 February)

Hobart:

ISS

Event	Time	Altitude	Azimuth	Distance (km)	Brightness	Sun altitude
Rises	21:33:18	0°	332° (NNW)	2,359	0.0	-11.7°
Reaches altitude 10°	21:35:34	10°	344° (NNW)	1,503	-1.1	-12.1°
Maximum altitude	21:38:29	27°	44° (NE)	848	-2.8	-12.5°
Enters shadow	21:40:04	19°	86° (E)	1,088	-2.2	-12.7°

Date:	09 February 2024
Orbit:	416 x 419 km, 51.6° (Epoch: 08 February)

Tiangong

Event	Time	Altitude	Azimuth	Distance (km)	Brightness	Sun altitude
Rises	21:31:42	0°	265° (W)	2,261	3.0	-11.5°
Reaches altitude 10°	21:33:52	10°	273° (W)	1,404	1.6	-11.8°
Maximum altitude	21:36:50	38°	342° (NNW)	605	-1.3	-12.2°
Enters shadow	21:38:22	22°	37° (NE)	892	-0.9	-12.5°

Date:	09 February 2024
Orbit:	373 x 383 km, 41.5° (Epoch: 08 February)

Labels: ISS, Satellite, tiangong, unaided eye

# posted by Ian Musgrave @ 8:03 am 0 comments

The Autumn equinox this year is on March 20th, where the Sun rises due east and sets due west and day and night are equal length.

Aside from marking the transition from summer to winter, this is an opportuity to see some "City Henges".

Unlike the famous Stonehenge, whose stones are aligned to catch the summer and winter solstices. City henges are found in cities with a regular grid of east-west streets, where the rising and setting sun can shine through these human-made canyons at various times of the year. The most famous is Manhattan henge, where the skyscrapers of New York provide dramatic chasms for the setting sun to illuminate.

Less well known but still dramatic is Melbourne Henge. Where great views are to be had down Collins Street and Bourke street amongst others as the setting sun washes the streets in golden glow.

Did I say east-west? while our CBD streets are nominally east west, they are in fact slightly out of alignment with true east.

The streets of Melbourne are even more out of true being angled at 250 degrees west, which is why the dates for Melbourne Henge for the setting sun is 7 February and 4 November, not on the days of the equinox.

The 'Henge' occurs twice a year when the sun sets perfectly aligned looking down Bourke St from the steps of Parliament house at sunset. The Sunset is at 8:28 pm. But the henge phenomenon should be visible along the Hoddle Grid at around 8:20 pm.

And the phenomenon can be seen in Adelaide too. We lack the skyscraper canyons, but our CBD east-west streets can still be illuminated with a golden glow.

As Adelaide streets are closer to East-west (North terrace being 87 degrees east and 263 degrees west as measured by my trusty compass) Adelaide henge is closer to the equinox. Our best time This is on the 16th at 19:33, when the sun is setting at 263 degrees. However, the sun moves slowly from this ideal alignment and our streets are broad, so good sunsets almost aligned with the streets such as North terrace, Rundle Mall and Hindle street should be available over a few days.

In contrast, best theoretical sunrise is not until 28 March, when the sun is 87 degrees from East and rising at 7:25. However, to the east is the Adelaide hills, and by the time the sun rises above then it will have moved off the direct line. Ironically the best time for the sunrise to shine down the street is on the 21st, at 7:36, as the sun just clears the Adelaide hills.

Again, those are the best times, but a few days either side of those it will still be good. So get up early or stay in the city for sunset, and you might see something wonderful.

Labels: Henge

# posted by Ian Musgrave @ 3:56 pm 0 comments

The New Moon is Saturday February 10. Saturn is low in the western twilight and is close to the thin crescent Moon on the 11th. Jupiter is now in the north-western sky but still dominates the early evening sky. Jupiter is near the Moon on the 15th. Venus is visible in the morning twilight above Mars and Mercury. Mars climbs higher in the morning twilight closing in on Venus.

The New Moon is Saturday February 10. The Moon is at perigee, when it is closes to the earth, on the 11th.

Evening sky on Sunday, February 11 as seen from Adelaide at 20:55 ACDST (45 minutes after sunset), Saturn is low above the western horizon close to the crescent moon. you will need a clear level horizon and binoculars to see the pair.

The inset is the approximate binocular view at this time.

Similar views will be seen from the rest of Australia at the equivalent local time (45 minutes after sunset).

Evening sky on Thursday, February 15 as seen from Adelaide at 21:42 ACDST (90 minutes after sunset). Jupiter is low above the north-western horizon and not far from the waxing crescent Moon. The inset is the telescopic view at this time.

Similar views will be seen from the rest of Australia at the equivalent local time (90 minutes after sunset).

Morning sky on Saturday, February 10 as seen from Adelaide at 05:44 ACDST, (60 minutes before sunrise, click to embiggen). Venus is beginning to lower in the morning twilight. Mercury and Mars are below Venus, with Mercury scraping the horizon.

Similar views will be seen from the rest of Australia at the equivalent local time (60 minutes before sunrise).

Whole sky on Saturday, February 10 as seen from Adelaide at 21:49 ACDST, 90 minutes after sunset (click to embiggen). Saturn has set, and Jupiter is low in the north-west.

Orion is almost due north. Bright Sirius is high in the eastern sky. Between the bright star Canopus and the Southern Cross are a wealth of binocular objects to discover.

Elsewhere in Australia will see a similar view at the equivalent time (90 minutes after sunset).

Mercury is low in the morning twilight. It is heading towards the horizon.

Venus is in the morning twilight, it will now sink towards the horizon but will remain visible for all of February.

Mars is rising in the morning twilight and is coming closer to Venus.

Jupiter is highest around civil twilight and is now visible low in the early evening sky. Jupiter is near the Moon on the 15th

Saturn is now a difficult to see low in the west and is close to the thin crescent Moon on the 11th.

Printable PDF maps of the Eastern sky at 10 pm AEST, Western sky at 10 pm AEST. For further details and more information on what's up in the sky, see Southern Skywatch.

Star Map via Virtual sky. Use your mouse to scroll around and press 8 when your pointer is in the map to set to the current time.

Cloud cover predictions can be found at SkippySky.

Here is the near-real time satellite view of the clouds (day and night) http://satview.bom.gov.au/

Labels: weekly sky

# posted by Ian Musgrave @ 12:25 am 0 comments


Tiangong as seen from Melbourne on the evening of Thursday 1 February at 21:44 AEDST. Simulated in Stellarium (the ISS will actually be a bright dot). Click to embiggen.	Tiangong as seen from Adelaide on the evening of Thursday 1 February at 21:12 ACDST. Simulated in Stellarium (the ISS will actually be a bright dot). Click to embiggen.	Tiangong as seen from Perth on the evening of Thursday 1 February at 20:14 AWST. Simulated in Stellarium (the ISS will actually be a bright dot). Click to embiggen.

All sky chart showing local times from Heavens Above for Thursday 1 February for Melbourne.	All sky chart showing local times from Heavens Above for Thursday 1 February for Adelaide.	All sky chart showing local times from Heavens Above for Thursday 1 February for Perth.

Relatively bright passes of the Chinese space station Tiangong visible in the evening from Australia aren't that common. Over the next few days there are a series of bright Tiangong passes in the late evening twilight/early evening and the early morning. Tiangong passes close to Jupiter and several bright stars.Jupiter is a handy orientation point for many passes.

The following tables are from data provided from Heavens Above. Particularly impressive passes are highlighted in yellow, passes entering the shadow in blue.

Passes from Adelaide (ACDST)

Date	Brightness	Start			Highest point			End			Pass type
Date	(mag)	Time	Alt.	Az.	Time	Alt.	Az.	Time	Alt.	Az.	Pass type
31 Jan	-1.3	22:12:16	10°	W	22:15:20	49°	SSW	22:15:57	42°	SSE	visible
01 Feb	-2.2	21:10:43	10°	WNW	21:13:52	87°	SSW	21:17:03	10°	ESE	visible
01 Feb	0.3	22:48:06	10°	WSW	22:50:04	24°	SW	22:50:04	24°	SW	visible
02 Feb	-0.6	21:46:18	10°	W	21:49:14	34°	SSW	21:51:46	13°	SE	visible
02 Feb	1.5	23:23:50	10°	SW	23:23:52	10°	SW	23:23:52	10°	SW	visible
03 Feb	-1.3	20:44:33	10°	W	20:47:39	53°	SSW	20:50:46	10°	ESE	visible
03 Feb	-0.1	22:22:07	10°	WSW	22:24:46	24°	S	22:25:21	22°	SSE	visible
04 Feb	-0.2	21:20:17	10°	WSW	21:23:04	27°	S	21:25:51	10°	SE	visible
04 Feb	0.8	22:57:36	10°	SW	22:58:46	17°	SW	22:58:46	17°	SW	visible
05 Feb	0.0	21:55:56	10°	SW	21:58:34	23°	S	22:00:01	17°	SE	visible
06 Feb	0.0	20:54:06	10°	WSW	20:56:47	24°	S	20:59:27	10°	SE	visible
06 Feb	0.0	22:31:09	10°	SW	22:33:14	26°	SSW	22:33:14	26°	SSW	visible
07 Feb	-0.2	21:29:31	10°	SW	21:32:14	25°	S	21:34:20	13°	ESE	visible
07 Feb	1.3	23:06:07	10°	WSW	23:06:25	12°	WSW	23:06:25	12°	WSW	visible
08 Feb	-1.1	22:04:32	10°	SW	22:07:29	40°	SSE	22:07:29	40°	SSE	visible
09 Feb	-0.6	21:02:54	10°	SW	21:05:45	29°	SSE	21:08:32	10°	ESE	visible
09 Feb	0.5	22:39:29	10°	WSW	22:40:37	20°	WSW	22:40:37	20°	WSW	visible

Passes from Brisbane (AEST)

Date	Brightness	Start			Highest point			End			Pass type
Date	(mag)	Time	Alt.	Az.	Time	Alt.	Az.	Time	Alt.	Az.	Pass type
31 Jan	0.2	20:08:00	10°	W	20:10:39	24°	SSW	20:13:18	10°	SSE	visible
01 Feb	-1.0	19:06:05	10°	WNW	19:09:08	47°	SSW	19:12:11	10°	SE	visible
01 Feb	1.2	20:45:32	10°	SSW	20:46:21	11°	SSW	20:47:09	10°	S	visible
02 Feb	0.8	19:42:35	10°	WSW	19:44:38	16°	SSW	19:46:40	10°	SSE	visible
04 Feb	1.0	19:17:28	10°	SW	19:18:33	11°	SSW	19:19:36	10°	S	visible
09 Feb	0.7	20:37:28	10°	SSW	20:38:32	14°	S	20:38:32	14°	S	visible

Passes from Darwin (ACST)

none in this time frame

Passes from Hobart (AEDST)

Date	Brightness	Start			Highest point			End			Pass type
Date	(mag)	Time	Alt.	Az.	Time	Alt.	Az.	Time	Alt.	Az.	Pass type
31 Jan	-0.3	21:09:33	10°	N	21:11:28	15°	NNE	21:13:23	10°	ENE	visible
31 Jan	-0.2	22:44:41	10°	WNW	22:45:58	21°	NW	22:45:58	21°	NW	visible
01 Feb	-1.4	21:43:31	10°	NW	21:46:25	33°	NNE	21:47:57	21°	ENE	visible
01 Feb	0.7	23:19:47	10°	W	23:20:04	12°	W	23:20:04	12°	W	visible
02 Feb	-2.2	22:18:23	10°	WNW	22:21:31	59°	N	22:21:46	56°	NE	visible
03 Feb	-1.8	21:17:02	10°	WNW	21:20:05	45°	NNE	21:23:08	10°	E	visible
03 Feb	-0.7	22:53:30	10°	W	22:55:21	31°	WNW	22:55:21	31°	WNW	visible
04 Feb	-2.2	21:52:01	10°	W	21:55:10	67°	N	21:56:41	27°	E	visible
04 Feb	1.0	23:28:41	10°	W	23:28:46	11°	W	23:28:46	11°	W	visible
05 Feb	-2.0	22:27:07	10°	W	22:30:01	58°	NW	22:30:01	58°	NW	visible
06 Feb	-2.1	21:25:32	10°	W	21:28:43	68°	N	21:31:10	15°	E	visible
06 Feb	0.3	23:02:17	10°	W	23:03:15	17°	WNW	23:03:15	17°	WNW	visible
07 Feb	-1.8	22:00:37	10°	W	22:03:43	50°	NNW	22:04:21	41°	NNE	visible
08 Feb	-2.0	20:58:57	10°	W	21:02:07	62°	N	21:05:15	10°	ENE	visible
08 Feb	-0.2	22:35:51	10°	W	22:37:29	21°	NW	22:37:29	21°	NW	visible
09 Feb	-1.3	21:34:01	10°	W	21:37:00	38°	NNW	21:38:32	22°	NE	visible

Passes from Melbourne (AEDST)

Date	Brightness	Start			Highest point			End			Pass type
Date	(mag)	Time	Alt.	Az.	Time	Alt.	Az.	Time	Alt.	Az.	Pass type
31 Jan	-1.1	21:07:38	10°	NNW	21:10:21	27°	NNE	21:13:06	10°	E	visible
31 Jan	-0.9	22:43:48	10°	W	22:45:57	39°	W	22:45:57	39°	W	visible
01 Feb	-2.3	21:42:20	10°	WNW	21:45:29	81°	NNE	21:47:57	15°	ESE	visible
01 Feb	0.8	23:19:20	10°	WSW	23:20:04	15°	WSW	23:20:04	15°	WSW	visible
02 Feb	-1.3	22:17:43	10°	W	22:20:49	49°	S	22:21:46	34°	SE	visible
03 Feb	-1.8	21:16:06	10°	W	21:19:14	68°	SSW	21:22:25	10°	ESE	visible
03 Feb	-0.3	22:53:12	10°	WSW	22:55:21	32°	SW	22:55:21	32°	SW	visible
04 Feb	-1.0	21:51:32	10°	WSW	21:54:35	42°	S	21:56:41	17°	ESE	visible
04 Feb	1.2	23:28:28	10°	WSW	23:28:46	12°	WSW	23:28:46	12°	WSW	visible
05 Feb	-1.2	22:26:53	10°	WSW	22:29:56	43°	S	22:30:00	42°	S	visible
06 Feb	-1.0	21:25:13	10°	WSW	21:28:14	40°	S	21:31:10	11°	ESE	visible
06 Feb	0.4	23:02:01	10°	WSW	23:03:14	21°	WSW	23:03:14	21°	WSW	visible
07 Feb	-1.5	22:00:24	10°	WSW	22:03:31	51°	SSE	22:04:21	38°	ESE	visible
08 Feb	-1.1	20:58:43	10°	WSW	21:01:47	42°	S	21:04:49	10°	ESE	visible
08 Feb	-0.7	22:35:27	10°	WSW	22:37:29	36°	W	22:37:29	36°	W	visible
09 Feb	-2.0	21:33:46	10°	WSW	21:36:56	68°	SSE	21:38:32	26°	E	visible

Passes from Perth (AWST)

Date	Brightness	Start			Highest point			End			Pass type
Date	(mag)	Time	Alt.	Az.	Time	Alt.	Az.	Time	Alt.	Az.	Pass type
31 Jan	-0.2	21:14:30	10°	W	21:17:16	28°	SSW	21:18:06	24°	S	visible
01 Feb	-1.1	20:12:41	10°	W	20:15:43	46°	SSW	20:18:47	10°	SE	visible
01 Feb	1.0	21:50:50	10°	SW	21:52:12	15°	SSW	21:52:12	15°	SSW	visible
02 Feb	0.4	20:48:45	10°	WSW	20:51:13	20°	SSW	20:53:42	10°	SE	visible
03 Feb	-0.2	19:46:44	10°	W	19:49:33	29°	SSW	19:52:24	10°	SE	visible
03 Feb	0.7	21:25:01	10°	SW	21:26:54	15°	S	21:27:27	14°	S	visible
04 Feb	0.6	20:22:58	10°	SW	20:25:07	17°	S	20:27:16	10°	SSE	visible
04 Feb	1.4	22:00:33	10°	SSW	22:00:51	11°	SSW	22:00:51	11°	SSW	visible
05 Feb	0.6	20:58:55	10°	SW	21:00:47	14°	S	21:02:05	12°	SSE	visible
06 Feb	0.6	19:56:59	10°	SW	19:58:54	15°	S	20:00:49	10°	SSE	visible
06 Feb	0.7	21:34:00	10°	SW	21:35:19	16°	SSW	21:35:19	16°	SSW	visible
07 Feb	0.5	20:32:29	10°	SSW	20:34:30	16°	S	20:36:24	11°	SE	visible
08 Feb	-0.2	21:07:16	10°	SW	21:09:33	24°	S	21:09:33	24°	S	visible
09 Feb	0.1	20:05:46	10°	SW	20:08:06	18°	SSE	20:10:25	10°	ESE	visible
09 Feb	1.0	21:42:00	10°	WSW	21:42:41	15°	SW	21:42:41	15°	SW	visible

Passes from Sydney (AEDST)

Date	Brightness	Start			Highest point			End			Pass type
Date	(mag)	Time	Alt.	Az.	Time	Alt.	Az.	Time	Alt.	Az.	Pass type
31 Jan	-2.2	21:07:53	10°	WNW	21:11:02	89°	SSW	21:13:48	13°	ESE	visible
31 Jan	1.1	22:45:22	10°	WSW	22:45:57	13°	WSW	22:45:57	13°	WSW	visible
01 Feb	-0.4	21:43:32	10°	W	21:46:26	32°	SSW	21:47:57	21°	SSE	visible
02 Feb	-1.3	20:41:47	10°	W	20:44:53	51°	SSW	20:47:59	10°	SE	visible
02 Feb	0.4	22:19:31	10°	WSW	22:21:46	21°	SSW	22:21:46	21°	SSW	visible
03 Feb	0.0	21:17:38	10°	WSW	21:20:19	25°	SSW	21:23:01	10°	SE	visible
03 Feb	1.5	22:55:10	10°	SW	22:55:21	11°	SW	22:55:21	11°	SW	visible
04 Feb	0.2	21:53:29	10°	SW	21:55:54	20°	S	21:56:41	18°	SSE	visible
05 Feb	0.2	20:51:36	10°	WSW	20:54:07	21°	S	20:56:39	10°	SE	visible
05 Feb	0.8	22:28:48	10°	SW	22:30:01	17°	SSW	22:30:01	17°	SSW	visible
06 Feb	0.1	21:27:11	10°	SW	21:29:40	20°	S	21:31:10	15°	SE	visible
07 Feb	0.2	20:25:23	10°	SW	20:27:49	20°	S	20:30:15	10°	SE	visible
07 Feb	-0.1	22:02:14	10°	SW	22:04:21	26°	SSW	22:04:21	26°	SSW	visible
08 Feb	-0.2	21:00:39	10°	SW	21:03:17	23°	S	21:05:25	13°	ESE	visible
08 Feb	1.3	22:37:08	10°	WSW	22:37:29	13°	WSW	22:37:29	13°	WSW	visible
09 Feb	-1.3	21:35:31	10°	SW	21:38:32	43°	SSE	21:38:32	43°	SSE	visible

When and what you will see is VERY location dependent, so you need to use Heavens Above to get site specific predictions for your location, a small difference in location can mean the difference between Tiangong passing over a star or planet or missing it completely.

As always, start looking several minutes before the pass is going to start to get yourself oriented and your eyes dark adapted. Be patient, there may be slight differences in the time of Tiangong appearing due to orbit changes not picked up by the predictions. Use the most recent prediction for your site.

Labels: Satellite, tiangong, unaided eye

# posted by Ian Musgrave @ 7:31 am 0 comments