Meteor showers: 2010

Monday, December 27, 2010

QUADRANTIDS METEOR SHOWER on Jan 4th, 2011

QUADRANTIDS METEOR SHOWER

Peak on Jan 3^rd/4^th, 2011

The Quadrantids are an above average shower, with up to 60-80 meteors per hour at their peak. The shower usually peaks on January 3 & 4, but some meteors can be visible from January 1 - 10. Best viewing will be from a dark location after midnight.

Although the Quadrantids are a major shower, they are seldom observed. One reason is weather. The shower peaks in early January when northern winter is in full swing.

The source of the Quadrantid meteor shower was unknown until Dec. 2003 when Peter Jenniskens of the NASA Ames Research Center found evidence that Quadrantid meteoroids come from 2003 EH1, an "asteroid" that is probably a piece of a comet that broke apart some 500 years ago. Earth intersects the orbit of 2003 EH1 at a perpendicular angle, which means we quickly move through any debris. That's why the shower is so brief.

To Observe:

The Quadrantid meteor shower is one of the year's best, producing more than 100 meteors per hour from a radiant near the North Star. This year the shower peaks on Jan. 4^th early morning. The timing favors observers in western North America and Across the Pacific Ocean.

The radiant of this shower is an area inside the constellation Boötes. The name comes from Quadrans Muralis, an obsolete constellation that is now part of Boötes. It lies between the end of the handle of the Big Dipper and the quadrilateral of stars marking the head of the constellation Draco. To find the location of the radiant, it is recommend that you find Polaris and observe near that area.

This year, a New Moon is slated to entirely strip the night sky of any moonlight close to the predicted maximum, creating perfect circumstances for observers in the northern hemisphere. On average, and under clear skies, observers should see 40 to 60 meteors per hour but every so often these rates can exceed up to 120 meteors per hour in rural locations. In the best conditions, the Quadrantids meteor shower should put on a spectacular viewing experience!

Facts File:

Maximum at: January 4, 01h10m UT (06h 40m IST)

Name origin: Appears inside the constellation Boötes.
Parent: 2003 EH1 (minor planet)
Active Period: January 1^st – 10th
ZHR/Rate on peak: 60-120 per hour

More Details here:

http://meteorshowersonline.com/quadrantids.html

http://www.imo.net/calendar/2011#qua

Geminids 2010 report from SPACE

Geminids 2010 – SPACE observation report

The year ended with one of the best meteor showers of the year putting in an appearance. Two teams from SPACE headed to two separate locations- Jim Corbett National Park and Sakras observing site. Both teams successfully observed a spectacular shower. The report and images are listed below:

Report -

Geminids 2010 were predicted to yield a good ZHR of more than 100. Maxima - Dec 14th at 11h UT or 16:30 h IST ZHR (Zenith Hourly Rate) - around 120. The best time to watch the activity near the peak in India was on 13th December night/early morning on 14th after moonset. SPACE planned observation of Geminids 2010 from two locations:

Location 1 – Jim Corbett Park, Ramnagar, Uttrakhand (29°26'24"N 79°4'35"E)

http://wikimapia.org/#lat=29.4402516&lon=79.0764141&z=16&l=0&m=b&search=BIJrani

Location 2 – SPACE observation site, Sakras, Haryana (27°51'13"N 76°58'21"E)

http://wikimapia.org/#lat=27.8536924&lon=76.9726342&z=18&l=0&m=b&search=sakras

Location 1 Team

SPACE observation team

Sachin Bhamba, C B Devgun, Surender Solanki, Jaishree Soin

Location 2 Team

Astronomicans

Deepak Jose, Deepak Dogra, Ishant, Vikrant, Sneh, Rishabh

Location 1 Experiments/observations planned:

Naked eye observation of the meteor shower

Photography of the shower

Estimating limiting magnitude for project dark skies

Equipment
:

Canon 450D with 18mm f 3.5 lens

Canon 500D with 18mm f 3.5 lens

Nikon D80 with leica 16 mm fisheye lens

Nikon D80 with Nikon 50mm f1.8 lens

Images plus software to control the camera

GPS for time keeping and location

Naked eye observation team:

Sachin Bahmba (SB), C B Devgun (CB), Surender Solanki (SS) and Jaishree Soin (JS)

Time of observation:

13th Dec. 2010

20:30 IST – 23:00 UT

Observation was done in following time spans (M=Shower meteor, S= Sporadic)

Reports have been sent to International Meteor Organisation (IMO)

period Time (UT) M S

period 2030-2045 12 2

period 2045-2100 18 1

period 2100-2115 12 5

period 2115-2130 10 2

period 2130-2145 15 2

period 2145-2200 20 0

period 2200-2205 25 0

period 2205-2210 30 1

period 2210-2220 20 0

period 2220-2230 19 0

period 2230-2235 35 2

period 2235-2240 45 4

period 2240-2250 18 0

period 2250-2255 40 4

period 2255-2300 25 3

Above readings have been taken out of the report sent by Team 1 to International Meteor Organisation (IMO), which can be accessed athttp://imo.net/live/geminids2010/ and at http://imo.net/live/geminids2010/obslist.html

Skies at the Location 1 were almost perfect having a limiting magnitude of almost 6. As the nearest city “Ramnagar” was 7 kms as the crow flies from the site in the jungle, skies were quite good except for the small amount of light pollution from the city in the south east. Observers mainly looked into directions of Leo and Orion for most of the time during observations. The shower intensified in bursts during short intervals of 5 mins at 2235-2240 and 2250-2255 UT. In all 344 meteor belonging to the shower were seen and 26 sporadic ones were seen.

Photography of the shower:

The shower was photographed for the same duration as that of the shower and around 10 frames got the Geminids meteors.

Images will be uploaded in SPACE blog at http://organisationspace.blogspot.com

Picasa gallery at http://picasaweb.google.com/organisationspace/GEMINIDS2010#

and the repository of SPACE soon.

Report sent to IMO by SPACE team at Location 1:

// Header section

night 2010-12-13/14

begin 2010-12-13 2030

end 2010-12-13 2300

observer "chander, sachin, " "devgun, bahmba"

location 79 04 35 E, 29 26 24 N

site "Jim corbett Tiger reserve" "India"

reporter "chander.devgun@gmail.com"

// Shower section

shower GEM 112 +33

shower SPO

// Number section

// Interval RA Dec Teff F Lm GEM SPO

period 2030-2045 090 +00 0.200 1.00 5.50 C 12 C 2

period 2045-2100 090 +00 0.200 1.00 5.50 C 18 C 1

period 2100-2115 150 +10 0.250 1.00 5.50 C 12 C 5

period 2115-2130 150 +10 0.200 1.00 5.50 C 10 C 2

period 2130-2145 090 +00 0.200 1.00 5.00 C 15 C 2

period 2145-2200 090 +00 0.200 1.00 5.00 C 20 C 0

period 2200-2205 090 +00 0.080 1.00 5.00 C 25 C 0

period 2205-2210 090 +00 0.080 1.00 5.00 C 30 C 1

period 2210-2220 150 +10 0.150 1.00 5.50 C 20 C 0

period 2220-2230 090 +00 0.150 1.00 5.00 C 19 C 0

period 2230-2235 090 +00 0.080 1.00 5.00 C 35 C 2

period 2235-2240 090 +00 0.080 1.00 5.00 C 45 C 4

period 2240-2250 090 +00 0.150 1.00 5.00 C 18 C 0

period 2250-2255 090 +00 0.080 1.00 5.00 C 40 C 4

period 2255-2300 090 +00 0.080 1.00 5.00 C 25 C 3

// Magnitude section

// Show Interval -6 -5 -4 -3 -2 -1 +0 +1 +2 +3 +4 +5 +6 +7 Tot

distribution GEM 2030-2100 1.0 1.0 3.0 2.0 2.0 6.0 14.0 1.0 - - - - - - 30.0

distribution GEM 2100-2130 2.0 1.0 2.0 3.0 4.0 5.0 6.0 2.0 2.0 2.0 - - - - 29.0

distribution GEM 2130-2145 - 2.0 - - - - 10.0 - 2.0 1.0 - - - - 15.0

distribution GEM 2145-2200 6.0 - - 3.0 - - 5.0 - 4.0 2.0 - - - - 20.0

distribution GEM 2200-2205 2.0 - 5.0 2.0 2.0 1.0 7.0 5.0 3.0 - 1.0 - - - 28.0

distribution GEM 2210-2220 - 2.0 3.0 - 4.0 - 6.0 2.0 2.0 1.0 - - - - 20.0

distribution GEM 2220-2230 - - 2.0 4.0 2.0 - 6.0 3.0 - - - - - - 17.0

distribution GEM 2230-2235 5.0 3.0 1.0 1.0 - - 15.0 - 1.0 1.0 - - - - 27.0

distribution GEM 2235-2240 7.0 1.0 3.0 - 2.0 - 12.0 - - - - - - - 25.0

distribution GEM 2240-2250 4.0 - - 1.0 - - 8.0 3.0 1.0 - - - - - 17.0

distribution GEM 2250-2255 - 1.0 2.0 3.0 5.0 2.0 10.0 2.0 3.0 1.0 1.0 - - - 30.0

distribution GEM 2255-2300 8.0 - - 2.0 2.0 - 7.0 - - 1.0 1.0 - - - 21.0

// Personal comments

SPACE (Science Popularisation Association of Communicators and Educators) team observed the geminids from Jim Corbett Tiger reserve, a dark sky site 270 kms away from New Delhi, india. Sachin Bahmba, Surender Solanki and Jaishree soin were other observers from the SPACE Observers

---------------------------------------------------------------------------------------------------------------------------------------------

Location 2 Experiments/observations planned:

Following is reported by Vikrant Narang

4 Astronomicans - Deepak Jose, Deepak Dogra, Ishant and Vikrant had gone to Sakars for Geminids observation. Rishabh and Sneh also kept joining the observers team during their session breaks.

Experiments and Photography:

Visual observation: Vikrant, Ishant - Logged 214 meteors (Geminids + Sporadic) in 2 hours.

Astrophotography: Deepak Dogra, Deepak Jose, VIkrant Narang, Ishant, Sneh, RIshabh

Friday, December 17, 2010

images from Geminids 2010

Friday, November 26, 2010

Geminids in Radio Frequency!!!

How to Hear Meteors on Your FM Radio???

Introduction to hearing meteors on your FM radio

There are always meteors burning up in the Earth's atmosphere, and during certain times of the year there are major meteor showers. You want to watch the meteors but it's cloudy or the moon is too bright or you live in the city with too much light pollution. Even if you can't see the meteors, you can still have fun listening to the meteors.

Find out more by clicking here!!

Thursday, November 25, 2010

Fireballs in the Sky -
Geminids Meteor Shower on Dec 14th

Avid star gazers can soon witness another sky theatre spectacle in the mesmerizing night skies - the Geminids Meteor Shower, peaking on 13^th/14^th Dec. This is one of the best meteor showers of the year and never disappoints observers. The peak of the shower this year falls just after the first quarter Moon. Moonset is within half an hour of local midnight across the globe for the maximum, while the Geminid radiant will be overhead around 02h local time.

The source of the Geminids shower is asteroid 3200 Phaethon. There's a cloud of dust trailing the asteroid and the Earth plows through it every year in mid-December. Bits of dust traveling at 80,000 mph hit our atmosphere and turn into glowing meteors.The Geminids got its name because its radiant position, from which it appears to originate, lies in the constellation Gemini.

Observe and Photograph the Geminids:
SPACE has the following handouts and suggestions to ensure that each one of you can go out and observe this wonderful spectacle.

SPACE suggests that students, amateur astronomers and the public go out on Dec 14th morning to a dark site away from lights and observe this nightsky spectacle. Details about timing and observing suggestions can be found listed below.
Meteor Showers provide a wonderful photographic opportunity. Another post in this blog provides details on techniques and suggestions by SPACE to employ for meteor photography.
SPACE will webcast a workshop on 'Meteor Showers and the Geminids' on 14th Dec. Find details on this website.

Record and Report:
This year we would like all observers to become Citizen Scientists and record their results and report it to IMO (International Meteor Organization). Details can be found in the attachment, as well as on the IMO website, listed below. Each citizen scientist who reports their observations will have the privilege to have their names and results listed on the IMO website.

Interested in Joining an Observation?
If you or a group from your school would be interested in joining a tour to beautiful Rishikesh or to nearby Sakra to observe and photograph these spectacular fireballs, then contact STEPL Astrotourism at rishabhj@stepl.org for further details.

SPACE Plans:
SPACE plans to send a scientific team to witness and record the Geminid Meteor Showers to a dark site away from Delhi. In 2009, SPACE observed and created a very successful report for the IMO. This can be found on the blog listed below.

Geminids Details:

Maxima - Dec 14^th at 11h UT or 16:30 h IST

ZHR (Zenith Hourly Rate) - around 120.

The best time to watch the activity near the peak in India is on 13th December night/early morning on 14^th after moonset.

Relevant Websites:
SPACE astrophotography of Geminids:
http://picasaweb.google.com/organisationspace/Geminids2009#

IMO website reporting location:
http://www.imo.net/visual/major/observation Enjoy the last meteor shower of the Year.

Photographing the Geminds

Shoot the Geminids

Photographing meteors such as the Geminids is possible using a Single Lens Reflex (SLR) camera. The camera must have a "T" (time) or "B" (bulb) setting for taking time exposures. You will also need a cable release, a tripod or a very stable surface to place the camera on, for best results. The camera will need a lens that is between "fisheye" and 50mm. Lenses larger than 50mm may capture too small a field of view. This article is written for the film camera but can be used as it is for digital SLRs.

Here is what you will need to do.

Set up your photography equipment in an area that is shaded from any stray lights that may interfere. This is absolutely necessary!

Set the camera on a tripod or some other surface that is very stable. Make sure the focal ratio is set to the lowest possible setting. This means that the aperture of the camera is "wide open". Make sure the camera is set to "B" or "T" for time exposure. Set the focus to infinity.

Aim the camera at the area of the sky that you intend to photograph. Once positioned properly, make sure the tripod is locked down to prevent its "head" from moving under the weight of the camera. If you do not have a tripod, use things to prop the camera up in a way so that it is stable and so that you can still look thru the view finder.

Depress the cable release button and lock it in place. Allow the camera to take a picture for anywhere from 15 to 30 seconds, maybe more. Once the desired time has elapsed, release the cable release lock which will end the exposure. While taking the picture, do not move the camera at all.

The length of time that you should expose the film can be a tricky thing. Light pollution will shorten the amount of time that an exposure can be made before the file reaches it's "Sky Fog Limit" or is effectively overexposed. Experimenting with the length of time an exposure is well worth the effort!

The speed and grain size of the film is an important consideration. Generally speaking, ASA 400 film is "fast" enough for these purposes. Fine grained film such as ASA 100 will give you sharper images than ASA 400 but the pictures would be much darker. With low light levels, "fast" film is highly desired. ASA 800 will expose quicker than ASA 400 but will be grainier. Kodak Gold and Fuji Film's of ASA 400 or ASA 800 should suffice.

The "F" stop or "focal ratio" setting is very important. As mentioned above, you want the camera to be "wide open" or set to lowest focal ratio setting. The reason is that the film will be able to gather more light if the aperture is wider. Your pictures will capture more fainter meteors at a lower focal ratio than at a higher focal ratio. If your camera produces fuzzy results and it is indeed correctly focused, close the aperture down one stop.

Go out on a clear night and test your setup! On a clear night prior to the Geminid meteor shower, set your camera up and take a few pictures. This will help you determine what works best for your camera and how the film reacts to the night sky in your area. Try a few exposures of 15 seconds, 30 seconds, 1 minute, 2 minutes, 3 minutes and 4 minutes using the lowest focal ratio, and record the frame number and exposure time on a scratch pad. Repeat the process with the focal ratio backed off one stop. When you get the film developed, you'll be able to compare the results with your notes and determine what works best for your camera and sky conditions. What you will see are called "star trails". Every star in the photo will appear to be "trailed" for all photos over 20-30 seconds in duration. This is OK though as many meteor photographers do use this method. You would need an "equatorial" mount with a tracking motor to eliminate this effect. Knowing how your camera records light before the main event is essential!

Warn the film developer that your pictures may be very dim! When getting your photographs developed, it is a good idea to make sure they know your photographs are dim and to the untrained eye, may appear to be of nothing at all. If the developer uses normal processing, you should at least get some kind of results. The important thing is that they print them! It is a better idea to have them developed locally, where you can discuss what's on the film prior to processing it.

Some Geminids are exceedingly bright and may possibly overexpose or ruin a time exposure. If a very bright fireball crosses the camera's field of view, end the exposure shortly thereafter. Know where your camera is pointing! Sometimes, a bright meteor will leave a "train" or trail. These make very interesting photographs as the trails become twisted and contorted by winds high in the upper atmosphere.

Framing your picture with natural landscapes will help to make it more interesting and will provide the viewer with a better perspective of the event. Trees, cactus, rock formations and distant mountains are all good objects to try this on. A wide field photograph of meteors while looking across a very still lake or pond may make for astounding poster quality shots, especially if the water surface is very still and reflects the meteor well. If you have a lake or pond nearby, give this a try. It may actually be possible if the meteor counts are high and if they are bright. Although the moon will significantly interfere with meteor observing and photography this year, it may provide a bit of foreground illumination to the setting.

Enjoy the show and Good Luck!

Tuesday, November 16, 2010

Shoot the Leonids

Shoot the Leonids

Photographing meteors such as the Leonids is possible using a Single Lens Reflex (SLR) camera. The camera must have a "T" (time) or "B" (bulb) setting for taking time exposures. You will also need a cable release, a tripod or a very stable surface to place the camera on, for best results. The camera will need a lens that is between "fisheye" and 50mm. Lenses larger than 50mm may capture too small a field of view. This article is written for the film camera but can be used as it is for digital SLRs.

Here is what you will need to do.

Set up your photography equipment in an area that is shaded from any stray lights that may interfere. This is absolutely necessary!

Set the camera on a tripod or some other surface that is very stable. Make sure the focal ratio is set to the lowest possible setting. This means that the aperture of the camera is "wide open". Make sure the camera is set to "B" or "T" for time exposure. Set the focus to infinity.

Aim the camera at the area of the sky that you intend to photograph. Once positioned properly, make sure the tripod is locked down to prevent its "head" from moving under the weight of the camera. If you do not have a tripod, use things to prop the camera up in a way so that it is stable and so that you can still look thru the view finder.

Depress the cable release button and lock it in place. Allow the camera to take a picture for anywhere from 15 to 30 seconds, maybe more. Once the desired time has elapsed, release the cable release lock which will end the exposure. While taking the picture, do not move the camera at all.

The length of time that you should expose the film can be a tricky thing. Light pollution will shorten the amount of time that an exposure can be made before the file reaches it's "Sky Fog Limit" or is effectively overexposed. Experimenting with the length of time an exposure is well worth the effort!

The speed and grain size of the film is an important consideration. Generally speaking, ASA 400 film is "fast" enough for these purposes. Fine grained film such as ASA 100 will give you sharper images than ASA 400 but the pictures would be much darker. With low light levels, "fast" film is highly desired. ASA 800 will expose quicker than ASA 400 but will be grainier. Kodak Gold and Fuji Film's of ASA 400 or ASA 800 should suffice.

The "F" stop or "focal ratio" setting is very important. As mentioned above, you want the camera to be "wide open" or set to lowest focal ratio setting. The reason is that the film will be able to gather more light if the aperture is wider. Your pictures will capture more fainter meteors at a lower focal ratio than at a higher focal ratio. If your camera produces fuzzy results and it is indeed correctly focused, close the aperture down one stop.

Go out on a clear night and test your setup! On a clear night prior to the Geminid meteor shower, set your camera up and take a few pictures. This will help you determine what works best for your camera and how the film reacts to the night sky in your area. Try a few exposures of 15 seconds, 30 seconds, 1 minute, 2 minutes, 3 minutes and 4 minutes using the lowest focal ratio, and record the frame number and exposure time on a scratch pad. Repeat the process with the focal ratio backed off one stop. When you get the film developed, you'll be able to compare the results with your notes and determine what works best for your camera and sky conditions. What you will see are called "star trails". Every star in the photo will appear to be "trailed" for all photos over 20-30 seconds in duration. This is OK though as many meteor photographers do use this method. You would need an "equatorial" mount with a tracking motor to eliminate this effect. Knowing how your camera records light before the main event is essential!

Warn the film developer that your pictures may be very dim! When getting your photographs developed, it is a good idea to make sure they know your photographs are dim and to the untrained eye, may appear to be of nothing at all. If the developer uses normal processing, you should at least get some kind of results. The important thing is that they print them! It is a better idea to have them developed locally, where you can discuss what's on the film prior to processing it.

Some Leonids are exceedingly bright and may possibly overexpose or ruin a time exposure. If a very bright fireball crosses the camera's field of view, end the exposure shortly thereafter. Know where your camera is pointing! Sometimes, a bright meteor will leave a "train" or trail. These make very interesting photographs as the trails become twisted and contorted by winds high in the upper atmosphere.

Framing your picture with natural landscapes will help to make it more interesting and will provide the viewer with a better perspective of the event. Trees, cactus, rock formations and distant mountains are all good objects to try this on. A wide field photograph of meteors while looking across a very still lake or pond may make for astounding poster quality shots, especially if the water surface is very still and reflects the meteor well. If you have a lake or pond nearby, give this a try. It may actually be possible if the meteor counts are high and if they are bright. Although the moon will significantly interfere with meteor observing and photography this year, it may provide a bit of foreground illumination to the setting.

Enjoy the show and Good Luck!

Leonids Meteor Shower - Nov 18th, 2010

Leonids Meteor Shower - Nov 18th, 2010

The Leonids meteor shower will send trails of shooting stars in the sky on the dawn of Nov 18^th. This shower is created by the Earth moving through the debris of comet Tempel-Tuttle. The shower will peak at 2:45 am IST. However, this year the moon is quite full and moonset will only occur around 3:30 am, therefore the shower will be washed out and not offer a good view.

Come November and all amateur astronomers around the world start looking up to the skies for an event which we call the “Leonids Meteor Shower”. One can see trains of shooting stars coming from a particular area in the sky at an amazing rate. This phenomenon can be seen almost any day of the year but a shower of shooting stars is something that happens only a few times a year. Leonids is one of these and the most prominent one.

Leonids are a prolific meteor shower associated with the comet Tempel-Tuttle. The meteor shower is visible every year around November 17 when the Earth moves through the Leonid meteor stream. The stream comprises solid particles, known as meteoroids, ejected by the comet as it passes by the Sun. As the entire meteor streaks are parallel, because of the effect of perspective they appear to originate from a single point in the sky and as a result Leonids get their name from the location of their radiant in the constellation Leo. The Leonids are famous because their meteor showers, or storms, can be among the most spectacular.

Most visible Leonids are between 1 mm and 1 cm in diameter. For example, a Leonid meteor barely visible with the naked eye in a dark sky, is caused by a meteoroid of 0.5 mm in diameter and weights only 0.00006 gram. Just before they enter the Earth's atmosphere, Leonid meteoroids travel at 71 kilometers per second, or 213 times as fast as speed of sound.

It can be seen from Nov 14 till Nov 21. The peak usually occurs around 17/18^th November.

This year the peak is happening on 17th Nov night/18th morning at around 02:45 hrs IST. However this year the moon is quite full and the moonset will only happen around 3:30am, which means this year the meteor shower will be washed out. To try and look for Leonids, go to a dark site and try looking during the dawn of Nov18^th, but as mentioned this year the viewing will not be good. Although the meteors appear to originate from Leo, they really streak across the whole sky.

Tuesday, August 10, 2010

Observing Meteors Visually

Taken from BAA blog

Naked eye observation of meteors is one of the easiest and most pleasant forms of work open to the amateur astronomer. Even a beginner can make useful observations, and it is a good way to learn the constellations. Meteor work is excellent for clubs and societies with little or no equipment; essentially only the human eye is needed.

A meteor during the peak of the 2009 Leonid Meteor Shower. The photograph shows the meteor, afterglow, and wake as distinct components

The notes below assume that a single observer is on watch, though most of what is said is relevant to group observation. Organisation of a meteor watch by a group of observers is more complex, though potentially productive of much more useful data (see Group Gbserving below)

The first requirement for the observer is to find a good dark site. Rural residents are favoured here. Urban lights, smog and haze have a major, adverse, impact on meteor rates. Hence, even if you have to drive some miles to get to a good site, it will be well worth the trouble to have darker skies.

What equipment should I use?

1. Norton’s 2000.0 Star Atlas or similar star maps.

2. Report sheets (will be made available to you during the meteor observation).

3. Timepiece – accurate to better than 30 seconds.

4. Dim red torch – to enable you to note down data, but retain the dark adaptation of your eyes.

5. Several pens or pencils. These have a habit of breaking or getting mislaid in the dark, so have plenty of back-ups!

6. Clothing. Bring plenty of this; even on a summer night it can get chilly, and it is better to have too much clothing than too little. One advantage of a house back-garden site is that one can retreat indoors to warm up if necessary. A hat reduces loss of body heat from the head.

7. Food and drink. Refreshments should be available to be taken during breaks. Alcoholic beverages should, of course, be avoided!

Observer requirements

are rather more stringent

1. Patience. This is the prime requirement. The observer may face long intervals between meteors, or waiting for clouds to pass. Eagerly-awaited shower maxima often appear to turn out cloudy, and observations may have to wait for another year. Remember, however, that observations are required on all possible nights during a shower – so don’t just restrict watches to maximum night. One advantage of group watches is that the company helps to pass cloudy intervals.

2. Alertness. You must always be alert, otherwise the fainter meteors, which generally make the bulk of the bag, will be missed. If you are tired, or cold, or find your attention wandering, you should stop observing, at least for a while, since your results will not be reliable.

3. Honesty. All observers have different eyesight, and perception for meteors. An observer must not be disappointed to see fewer meteors than a colleague. Meteor work is not a competition, and conscious or unconscious ‘doctoring’ of observations is worse than useless, and indeed misleading.

Observing

Having covered the instrumental and personal requirements, we can get down to what is required from the observations. Before going outside to observe, find the radiant co-ordinates for the shower(s) active on the night in question, in this case it would be in perseus.

It is important to note that the radiant position the night of peak activity only. In accordance with theory, radiants generally move among the stars at a rate of about 1 degree per day. So, for a night other than maximum, the radiant will have RA and Dec different from the values mentioned.

Plot this position in Norton’s, and draw a circle of 8 degrees diameter centred on this position. The enclosed area is taken as the radiant for the night in question. Examine this area carefully indoors, until you are confident that you will recognise the area in the sky when you actually begin to observe.

Once outdoors, use the time that you spend getting dark adapted to record your name, address, and observing site (including latitude and longitude), and date on the report sheet. Note the sky conditions, mentioning whether any cloud, moonlight, fog or mist is present. Once you are fully dark-adapted, estimate the magnitude, to the nearest 0.25 mag, of the faintest star you can see in the area of sky being watched (not the zenith). Some observers prefer to estimate this limiting magnitude using the North Polar Sequence.

Now you are ready to begin the watch. Write down the start time of the watch in UT to the nearest minute. All times used in this type of work are required in Universal Time, which is 5.5 hours + IST.

Of course, because astronomers work exclusively at night, the date changes at midnight, halfway through the observing period. To prevent confusion and ambiguity as to exactly which night the observations are carried out, one must record the Double-Date on the report form – for example, 30-31 October.

Some observers, once they get past midnight, use the 24-hour clock beyond the figure 24 so that, for example, 2 am becomes 2600 UT. This is quite acceptable. So long as your record of date and time is unambiguous, do what you find most convenient.

As the name implies, a meteor watch involves concentrating on the sky and noting details of any meteors seen. Solo observers should watch the sky 50 degrees above the horizon, and 30-40 degrees to one side of the shower radiant expected to be active on the night in question; most meteors should be seen here.

As each meteor appears, not whether it was a shower member or a random sporadic, estimate how bright it was, and give its time of appearance to the nearest minute in UT.

To ascertain whether a meteor belonged to a given shower, or was a sporadic, mentally project its path in the sky backwards. If the projected path intersects the 8-degree radiant circle, the meteor is a shower member. Otherwise it is a sporadic. Those with paths tangential to the radiant should be considered as possible shower members. If a stick, or piece of string is held up against the meteor path when the event is seen, this will give you time to collect your thoughts after the meteor has vanished. Estimation of the magnitudes of shower and sporadic meteors may be omitted by those observers wishing only to carry out counts. The others should estimate meteor magnitudes by comparison with nearby stars. It will be adequate to estimate to the nearest whole magnitude. Do not forget that there is a mag. 0 between -1 and +1. Estimation of meteor magnitude is largely subjective, since the meteor is rarely present long enough to enable very accurate visual photometry; it is a remembered impression that is compared with the stars. For bright meteors, errors in magnitude estimation are much larger, due to the lack of suitable comparison standards. Useful tips for bright meteor estimation: Full Moon is mag. -12.5; Venus is -4.4 at its brightest; Jupiter about -2.2. Large scatter in the magnitude estimates of fireballs can hardly be avoided. The list here offers some further suitable comparisons for fainter meteors:

Magnitude Object(s)

-4 Venus

-2 Jupiter

-1 Sirius

0 Capella, Rigel, Arcturus

+1 Regulus, Spica, Pollux

+2 Belt stars of Orion, Beta Aurigae, Gamma Geminorum,
Pointers of Plough, Polaris, Denebola, Alphard

+3 Delta Ursae Majoris, Gamma and Delta Leonis, Epsilon Geminorum

+4 Eta Persei, Delta Aurigae, Rho Leonis

+5 Faintest meteors generally visible to naked eye

Note the time of appearance of the meteor, having made due allowance for the time spent thinking about magnitude and type, and writing these down, perhaps 15-30 seconds.

Then, and only then, you may make any notes about the meteor itself. For example, did it explode? Did it have an intense colour? Did it have a long-duration persistent train?

As this is the first time we have mentioned meteor trains, a few words about them would not go amiss. Many observers, especially beginners, are confused by the difference between meteor trails and persistent trains. A night-time meteor train appears as a faint nebulous streak of light left behind, along the track of a meteor, but AFTER the meteor itself has extinguished. Do not mistake it for the actual moving streak of a fast meteor – this is the trail. Momentary meteor trains are generally likened in appearance to the vapour wake of a jet aircraft, and are only left by about a quarter of all meteors. Meteor trains lasting more than a few seconds are quite rare. Statistically, one must observe about 600 meteors to observe a train of 10 seconds’ duration or more!

Each meteor seen during the watch should be treated similarly; practice makes perfect, and you should soon be able to get down the data quickly and efficiently. Abbreviations such as “S” for sporadic, or “P” for Perseid, and writing the minutes instead of minutes and hour, will help you to cope with the sudden rushes of meteors that sometimes occur. As long as you get all the data down, and you can understand your symbols at a later date, you can use any symbols you like. Many experienced observers, to reduce “dead time” spent looking away from the sky, note meteor details in such a shorthand, for later, neat transcription to the Section’s report forms.

At the end of the watch, note the time to the nearest minute. Then you can stop, or have a break and start another watch later. Ideally, watches should last for an hour, or multiples of an hour, at a time. Monitor the sky conditions during each watch, as these may change.