Antenna Problems on SOHO

Image credit: ESA

The NASA/ESA SOHO spacecraft, which observes the Sun, is having problems pointing its high-gain antenna, which it uses to transmit data back to Earth. The cause of the problem hasn’t been figured out yet, but experts think there’s something wrong with its motor or in the gear assembly that steers the antenna – fortunately, its low-gain antenna is still working, so they can still communicate with the spacecraft. If they can’t figure out the problem, SOHO isn’t going to be able to transmit data back as quickly, so there will be blackout periods.

The ESA/NASA SOHO spacecraft, launched in 1995, has been delivering outstanding data about the Sun for over eight years. Recently, however, an anomaly on the pointing mechanism of its high-gain antenna has been recorded.

The high-gain antenna is required to transmit the large amounts of data from SOHO’s scientific observations to Earth. From SOHO’s orbit, the antenna has to be pointed in the proper direction – like a flashlight – for the data to be received at Earth.

The exact nature of the antenna problem is not yet known, but the experts think that a malfunction has occurred in its motor or in the gear assembly that steers the antenna.

SOHO is safe, as the spacecraft has a low-gain antenna, used to control the spacecraft and monitor both spacecraft and instrument health and safety, which remains operational. However, if the high-gain antenna problem persists, there will be periodic losses in the real-time transmission of scientific data of about two and a half weeks each three months. The first blackout is estimated to begin sometime late in the week of 22 June 2003.

A number of options are currently being investigated by the SOHO team to fully recover or minimise any real-time scientific data loss. A joint ESA/NASA press release will follow shortly.

Original Source: ESA News Release

Stardust Completes Course Correction

Image credit: NASA

NASA’s Stardust probe completed a minor course correction on Thursday, now only 198 days away from its destination: Comet Wild 2. The spacecraft fired its thrusters for 24 minutes and used up nearly 10% of its fuel. Stardust has traveled 2.9 billion kilometres since its launch in 1999, and if all goes well, it will reach the comet in January, 2004 and capture particles from its tail. It will then return the samples to Earth so they can be studied on the ground by scientists.

With 198 days before its historic rendezvous with a comet, NASA’s Stardust spacecraft successfully completed the mission?s third deep space maneuver. This critical maneuver modified the spacecraft?s trajectory, placing it on a path to encounter and collect dust samples from comet Wild 2 in January 2004.

At 2100 Universal Time (2:00 p.m. Pacific Time), Wed., June 18, Stardust fired its eight, 4.4 newton (1 pound) thrusters for a grand total of 1456 seconds, changing the comet sampler?s speed by 34.4 meters per second (about 77 miles per hour). This burn, the second in two days, completed the almost seven-year-long mission?s third deep space maneuver. The June 18 burn required 6.08 kilograms (13.4 pounds) of hydrazine monopropellant to complete. At launch, the spacecraft carried 85 kilograms (187 pounds) of hydrazine propellant.

“It was a textbook maneuver,” said Robert Ryan, Stardust?s mission manager at NASA?s Jet Propulsion Laboratory, Pasadena, Calif. “This was the last big burn we will have prior to our encounter with Wild 2, and it looks very accurate. After sifting through all the post-burn data I expect we will find ourselves right on the money.”

Stardust has traveled over 2.9 billion kilometers (1.8 billion miles) since its February 7, 1999 launch. At present, it is hurtling through the cosmos at 124,300 kilometers per hour (77,200 miles per hour).

In January 2004, Stardust will fly through the halo of dust that surrounds the nucleus of comet Wild 2. The spacecraft will return to Earth in January 2006 to make a soft landing at the U.S. Air Force Utah Test and Training Range. Its sample return capsule, holding microscopic particles of comet and interstellar dust, will be taken to the planetary material curatorial facility at NASA’s Johnson Space Center, Houston, Texas, where the samples will be carefully stored and examined.

Stardust?s cometary and interstellar dust samples will help provide answers to fundamental questions about the origins of the solar system. More information on the Stardust mission is available at http://stardust.jpl.nasa.gov.

Stardust, a part of NASA’s Discovery Program of low-cost, highly focused science missions, was built by Lockheed Martin Astronautics and Operations, Denver, Colo., and is managed by the Jet Propulsion Laboratory, Pasadena, Calif., for NASA’s Office of Space Science, Washington, D.C. JPL is a division of the California Institute of Technology in Pasadena. The principal investigator is astronomy professor Donald E. Brownlee of the University of Washington in Seattle.

Original Source: NASA News Release

Nozomi Makes its Earth Flyby

The Japanese space probe Nozomi, passed an important milestone on its journey to Mars Thursday night with the successfully flyby of Earth. The spacecraft passed within 11,000 km of the Earth in order to use our planet’s gravity to assist its trip to Mars. Its challenges aren’t over yet, however, since its heating system still isn’t functional and required in order to enter Mars orbit at the end of its journey. Space experts give Nozomi a 50/50 chance of being able to fix itself before reaching Mars.

Hubble Looks Way Back in Time

Image credit: Hubble

A new series of images taken by the Hubble Space Telescope contain 25,000 galaxies, many of which are interacting and in the process of formation. Some of these galaxies are so far away, they’re seen when the Universe was only 2 billion years old. Astronomers are using Hubble and the Chandra X-Ray observatory to survey two large areas of the sky to build a deeper understanding of galaxy evolution.

NASA’s Hubble Space Telescope reached back to nearly the beginning of time to sample thousands of infant galaxies. This image, taken with Hubble’s Advanced Camera for Surveys, shows several thousand galaxies, many of which appear to be interacting or in the process of forming. Some of these galaxies existed when the cosmos was less than about 2 billion years old. The foreground galaxies, however, are much closer to Earth. Two of them [the white, elongated galaxies, left of center] appear to be colliding.

This image represents less than one-tenth of the entire field surveyed by Hubble. The full field, consisting of about 25,000 galaxies, is part of a larger survey called the Great Observatories Origins Deep Survey (GOODS), the most ambitious study of the early universe yet undertaken with the Hubble telescope. This survey targeted two representative spots in the sky – one in the Northern Hemisphere and the other in the Southern Hemisphere. This image represents the southern field, located in the constellation Fornax. The entire GOODS survey reveals roughly 50,000 galaxies. Astronomers have identified more than 2,000 of them as infant galaxies, observed when the universe was less than about 2 billion years old.

Because infant galaxies are very faint and very rare, astronomers are using Hubble to search for them over a relatively wide swath of sky. In fact, the new observations cover about 60 times the area of the original Hubble Deep Field Observations, obtained in 1995. Astronomers also are using the Chandra X-ray Observatory to search the GOODS fields for the earliest black holes in the universe. The Space Infrared Telescope Facility (SIRTF) will sample these same fields soon after it is launched in August 2003.

By combining light from all three of NASA’s great observatories with data from ground-based telescopes, astronomers hope to build a coherent picture of galaxy evolution.

This image of the southern field was assembled from observations taken between July 2002 and February 2003.

Original Source: Hubble News Release

Shuttle Flights Will Probably Resume in 2004

Although NASA has made tentative plans to launch the space shuttle Atlantis some time near the end of 2003, it’s more likely to happen in early 2004. NASA is expected to announce the launch date in about six weeks. Although all the technical fixes can be made by December, one of the new regulations is that the shuttle will need to launch only in the daytime, so any problems during launch can be spotted from the ground – but there are only two daylight launch windows available in December. All shuttle flights were halted when Columbia broke up over Texas in February, 2003.

Soyuz Tourist Flights Beginning Soon

Image credit: Space Adventures

Two space tourists will have a chance to fly to the International Space Station in 2005, at a cost of only $20 million each. The flight will include a professional cosmonaut pilot and launch on board a Soyuz rocket from the Baikonur cosmodrome in Kazakhstan. The mission is being organized by Space Adventures, the company that organized the flights for Dennis Tito and Mark Shuttleworth. The Soyuz will completely self-sufficient, providing all the supplies required by the passengers and even some additional supplies for the station.

Commercial space flight took a giant leap forward today with the announcement by Space Adventures, Ltd., the leading space experiences company, of its plans to launch the world’s first privately funded mission to the International Space Station (ISS). Space Adventures recently secured a contract with the Russian Aviation & Space Agency (RASA) to fly two explorers to the ISS aboard a new Soyuz TMA spacecraft.

The mission, Space Adventures-1 (SA-1), continues the company’s record of opening the space frontier to explorers other than government astronauts and cosmonauts. The company brokered the flights for the world’s first private space explorers, American businessman Dennis Tito in 2001, and the first African in space, Mark Shuttleworth, in 2002. SA-1 has the potential to establish several world records, and also marks the first private mission to the International Space Station.

Space Adventures seeks candidates fascinated by one of life’s greatest experiences and who support the exploration of space to participate in the expedition. First “space tourist,” Dennis Tito said, “Private space exploration is an important investment into humanity’s future. Commercial human space flight and space tourism are creating the 21st century technologies and economy that will bring the benefits of space to people on Earth. Helping to make that happen is very meaningful. And of course, being in space itself is a truly blissful experience that I am unable to describe in words, it was worth far more than its cost; truly priceless.”

Space Adventures has established this mission through its longstanding partnership with RASA and Russia’s leading aerospace company, RSC Energia. “We are pleased to provide the means for this Space Adventures’ mission and are equally committed to the future of private space travel,” says Sergey Gorbunov, Press Secretary for the Director General of RASA. SA-1 participants will train in Star City, the cosmonaut training center outside of Moscow, familiarizing themselves with the Soyuz TMA spacecraft, experiencing weightlessness in a zero-gravity jet, and learning how to live and operate aboard the ISS. The mission is planned for liftoff in early 2005 from the Baikonur Cosmodrome in Kazakhstan and seats aboard the Soyuz are available for $20 million each. Gorbunov also stated, “In the future, we intend to carry out additional private missions to ISS in cooperation with Space Adventures.”

Space Adventures’ CEO, Eric Anderson, remarks, “After the loss of Columbia, the President said that our journey into space must go on. The advancement of commercial space flight and space tourism should and will continue, to everyone’s advantage. And, this mission in particular has been designed to provide great benefit to all parties, not only for the explorers who fly, but also to the ISS program as a whole.” Anderson emphasized that SA-1 will be self-sufficient, bringing its own food, water and medical supplies and that it may transport supplemental supplies for the resident crew aboard the ISS.

The announcement was made at the renowned Explorers Club in New York City on June 18. Accompanying Anderson at the event were Tito, Shuttleworth, and Gorbunov.

In addition to orbital flights to the ISS, Space Adventures, the world’s leading space flight experiences and space tourism company, offers a wide range of programs, from zero-gravity and Edge of Space flights, cosmonaut training and space flight qualification programs, to reservations on future sub-orbital spacecraft. Headquartered in Arlington, VA, with an office in Moscow, Russia, Space Adventures is the only company to have successfully launched private individuals to the International Space Station. The company’s advisory board comprises Apollo 11 moonwalker Buzz Aldrin; shuttle astronauts Kathy Thornton, Robert (Hoot) Gibson, Charles Walker, Norm Thagard, Sam Durrance and Byron Lichtenberg; and Skylab astronaut Owen Garriott.

Original Source: Space Adventures News Release

Gamma Ray Bursts and Hypernovae Linked

Image credit: ESO

On March 29, 2003 NASA’s High Energy Transient Explorer detected a bright burst of gamma rays, and shortly after telescopes from around the world focused in on the object; now called GRB 030329 and measured to be 2.6 billion light-years away. By measuring the afterglow of the explosion, astronomers realized that it matches the spectrum of a hypernova – explosions of extremely large stars, at least 25 times larger than our own Sun. By matching the spectra, astronomers have compelling evidence that there is some connection between gamma ray bursts and the explosions of very large stars.

A very bright burst of gamma-rays was observed on March 29, 2003 by NASA’s High Energy Transient Explorer (HETE-II), in a sky region within the constellation Leo.

Within 90 min, a new, very bright light source (the “optical afterglow”) was detected in the same direction by means of a 40-inch telescope at the Siding Spring Observatory (Australia) and also in Japan. The gamma-ray burst was designated GRB 030329, according to the date.

And within 24 hours, a first, very detailed spectrum of this new object was obtained by the UVES high-dispersion spectrograph on the 8.2-m VLT KUEYEN telescope at the ESO Paranal Observatory (Chile). It allowed to determine the distance as about 2,650 million light-years (redshift 0.1685).

Continued observations with the FORS1 and FORS2 multi-mode instruments on the VLT during the following month allowed an international team of astronomers [1] to document in unprecedented detail the changes in the spectrum of the optical afterglow of this gamma-ray burst. Their detailed report appears in the June 19 issue of the research journal “Nature”.

The spectra show the gradual and clear emergence of a supernova spectrum of the most energetic class known, a “hypernova”. This is caused by the explosion of a very heavy star – presumably over 25 times heavier than the Sun. The measured expansion velocity (in excess of 30,000 km/sec) and the total energy released were exceptionally high, even within the elect hypernova class.

From a comparison with more nearby hypernovae, the astronomers are able to fix with good accuracy the moment of the stellar explosion. It turns out to be within an interval of plus/minus two days of the gamma-ray burst. This unique conclusion provides compelling evidence that the two events are directly connected.

These observations therefore indicate a common physical process behind the hypernova explosion and the associated emission of strong gamma-ray radiation. The team concludes that it is likely to be due to the nearly instantaneous, non-symmetrical collapse of the inner region of a highly developed star (known as the “collapsar” model).

The March 29 gamma-ray burst will pass into the annals of astrophysics as a rare “type-defining event”, providing conclusive evidence of a direct link between cosmological gamma-ray bursts and explosions of very massive stars.

What are Gamma-Ray Bursts?
One of the currently most active fields of astrophysics is the study of the dramatic events known as “gamma-ray bursts (GRBs)”. They were first detected in the late 1960’s by sensitive instruments on-board orbiting military satellites, launched for the surveillance and detection of nuclear tests. Originating, not on the Earth, but far out in space, these short flashes of energetic gamma-rays last from less than a second to several minutes.

Despite major observational efforts, it is only within the last six years that it has become possible to pinpoint with some accuracy the sites of some of these events. With the invaluable help of comparatively accurate positional observations of the associated X-ray emission by various X-ray satellite observatories since early 1997, astronomers have until now identified about fifty short-lived sources of optical light associated with GRBs (the “optical afterglows”).

Most GRBs have been found to be situated at extremely large (“cosmological”) distances. This implies that the energy released in a few seconds during such an event is larger than that of the Sun during its entire lifetime of more than 10,000 million years. The GRBs are indeed the most powerful events since the Big Bang known in the Universe, cf. ESO PR 08/99 and ESO PR 20/00.

During the past years circumstantial evidence has mounted that GRBs signal the collapse of massive stars. This was originally based on the probable association of one unusual gamma-ray burst with a supernova (“SN 1998bw”, also discovered with ESO telescopes, cf. ESO PR 15/98). More clues have surfaced since, including the association of GRBs with regions of massive star-formation in distant galaxies, tantalizing evidence of supernova-like light-curve “bumps” in the optical afterglows of some earlier bursts, and spectral signatures from freshly synthesized elements, observed by X-ray observatories.

VLT observations of GRB 030329
On March 29, 2003 (at exactly 11:37:14.67 hrs UT) NASA’s High Energy Transient Explorer (HETE-II) detected a very bright gamma-ray burst. Following identification of the “optical afterglow” by a 40-inch telescope at the Siding Spring Observatory (Australia), the redshift of the burst [3] was determined as 0.1685 by means of a high-dispersion spectrum obtained with the UVES spectrograph at the 8.2-m VLT KUEYEN telescope at the ESO Paranal Observatory (Chile).

The corresponding distance is about 2,650 million light-years. This is the nearest normal GRB ever detected, therefore providing the long-awaited opportunity to test the many hypotheses and models which have been proposed since the discovery of the first GRBs in the late 1960’s.

With this specific aim, the ESO-lead team of astronomers [1] now turned to two other powerful instruments at the ESO Very Large Telescope (VLT), the multi-mode FORS1 and FORS2 camera/spectrographs. Over a period of one month, until May 1, 2003, spectra of the fading object were obtained at regular rate, securing a unique set of observational data that documents the physical changes in the remote object in unsurpassed detail.

The hypernova connection
Based on a careful study of these spectra, the astronomers are now presenting their interpretation of the GRB 030329 event in a research paper appearing in the international journal “Nature” on Thursday, June 19. Under the prosaic title “A very energetic supernova associated with the gamma-ray burst of 29 March 2003”, no less than 27 authors from 17 research institutes, headed by Danish astronomer Jens Hjorth conclude that there is now irrefutable evidence of a direct connection between the GRB and the “hypernova” explosion of a very massive, highly evolved star.

This is based on the gradual “emergence” with time of a supernova-type spectrum, revealing the extremely violent explosion of a star. With velocities well in excess of 30,000 km/sec (i.e., over 10% of the velocity of light), the ejected material is moving at record speed, testifying to the enormous power of the explosion.

Hypernovae are rare events and they are probably caused by explosion of stars of the so-called “Wolf-Rayet” type [4]. These WR-stars were originally formed with a mass above 25 solar masses and consisted mostly of hydrogen. Now in their WR-phase, having stripped themselves of their outer layers, they consist almost purely of helium, oxygen and heavier elements produced by intense nuclear burning during the preceding phase of their short life.
“We have been waiting for this one for a long, long time”, says Jens Hjorth, “this GRB really gave us the missing information. From these very detailed spectra, we can now confirm that this burst and probably other long gamma-ray bursts are created through the core collapse of massive stars. Most of the other leading theories are now unlikely.”
A “type-defining event”

His colleague, ESO-astronomer Palle M?ller, is equally content: “What really got us at first was the fact that we clearly detected the supernova signatures already in the first FORS-spectrum taken only four days after the GRB was first observed – we did not expect that at all. As we were getting more and more data, we realised that the spectral evolution was almost completely identical to that of the hypernova seen in 1998. The similarity of the two then allowed us to establish a very precise timing of the present supernova event”.

The astronomers determined that the hypernova explosion (designated SN 2003dh [2]) documented in the VLT spectra and the GRB-event observed by HETE-II must have occurred at very nearly the same time. Subject to further refinement, there is at most a difference of 2 days, and there is therefore no doubt whatsoever, that the two are causally connected.

“Supernova 1998bw whetted our appetite, but it took 5 more years before we could confidently say, we found the smoking gun that nailed the association between GRBs and SNe” adds Chryssa Kouveliotou of NASA. “GRB 030329 may well turn out to be some kind of ‘missing link’ for GRBs.”

In conclusion, GRB 030329 was a rare “type-defining” event that will be recorded as a watershed in high-energy astrophysics.

What really happened on March 29 (or 2,650 million years ago)?
Here is the complete story about GRB 030329, as the astronomers now read it.

Thousands of years prior to this explosion, a very massive star, running out of hydrogen fuel, let loose much of its outer envelope, transforming itself into a bluish Wolf-Rayet star [3]. The remains of the star contained about 10 solar masses worth of helium, oxygen and heavier elements.

In the years before the explosion, the Wolf-Rayet star rapidly depleted its remaining fuel. At some moment, this suddenly triggered the hypernova/gamma-ray burst event. The core collapsed, without the outer part of the star knowing. A black hole formed inside, surrounded by a disk of accreting matter. Within a few seconds, a jet of matter was launched away from that black hole.

The jet passed through the outer shell of the star and, in conjunction with vigorous winds of newly formed radioactive nickel-56 blowing off the disk inside, shattered the star. This shattering, the hypernova, shines brightly because of the presence of nickel. Meanwhile, the jet plowed into material in the vicinity of the star, and created the gamma-ray burst which was recorded some 2,650 million years later by the astronomers on Earth. The detailed mechanism for the production of gamma rays is still a matter of debate but it is either linked to interactions between the jet and matter previously ejected from the star, or to internal collisions inside the jet itself.

This scenario represents the “collapsar” model, introduced by American astronomer Stan Woosley (University of California, Santa Cruz) in 1993 and a member of the current team, and best explains the observations of GRB 030329.

“This does not mean that the gamma-ray burst mystery is now solved”, says Woosley. “We are confident now that long bursts involve a core collapse and a hypernova, likely creating a black hole. We have convinced most skeptics. We cannot reach any conclusion yet, however, on what causes the short gamma-ray bursts, those under two seconds long.”

Original Source: ESO News Release

Second Mars Rover Launch Pushed Back a Day

NASA announced on Tuesday that it would push back the launch of its second Mars rover, “Opportunity” one day; now tentatively scheduled for June 26. The delay was expected because of the delays with the previous rover, “Spirit”. NASA wanted to give its engineers more time to prepare the Delta rocket for the second launch. The spacecraft has been packed up for launch and was moved to the launch pad Tuesday morning to be mated to the top of its Delta rocket. The other rover, Spirit, is working well now a week into its flight.

Japanese Mars Mission Faces Critical Challenges

With NASA’s Mars Explorer and Europe’s Mars Express missions well on their way to the Red Planet, many are forgetting the Japanese Nozomi spacecraft which was launched almost five years ago. It should have reached Mars a long time ago but a failed flyby of Earth forced the spacecraft to make another trip around to get enough speed. In April last year a solar flare damaged the spacecraft’s heating system and disrupted communications. Even if it makes a final flyby of Earth this week, engineers will need to fix its broken systems so that it can go into orbit around Mars. If everything is fixed, Nozomi is expected to reach Mars in late December 2003 or early 2004.

First Light: An Introduction to Stargazing

Interested in space and astronomy but you’ve never actually looked through a telescope? Until you’ve actually gone out and done some actual observing with your own two eyes, you won’t know what you’re missing. In this article, Fraser gives you a kick in the pants to get out there under the skies and start enjoying the heavens above. You don’t need any special equipment or advanced university degrees, just some enthusiasm, a little time and the ability to look up.

I know there are a lot of subscribers interested in space and astronomy, but I’m wondering how many of you have actually taken a look through a telescope and seen some of the objects I talk about with your own eyes.

One of my fondest memories was when I was 13 years old, and set up my 4″ telescope at my Dad’s birthday party. I was in a darkish corner of our property and would sneak away a few partygoers to show them Saturn. Fortunately the rings were at their greatest angle, and people looking through the eyepiece couldn’t believe their eyes. Looking at pictures taken by Hubble is one thing, but when you’re actually looking through the eyepiece at Saturn, it’s an incredible experience.

Stargazing has since played a big part of my life: I organized a star party, hit on my future wife by pointing out constellations, and started a space-related website, but I’m still amazed at the number of people who’ve never actually gone out there and gotten to know their sky.

With all the new observatories and space news, I think that people are starting to think that astronomy is one of those sciences reserved for people with the expensive instruments, but that couldn’t be further from the truth. It’s one of the few sciences that amateurs still make valuable contributions, and it costs absolutely nothing to get started – you just need your eyes, and a little knowledge.

Find your community
The first thing you need to do is make a commitment to get involved in astronomy. It’s not as easy as just turning on your television; you’ve got to get organized; make some phone calls; set aside some time to explore.

I’ll bet you didn’t know, but there’s an astronomical society lurking in almost every population centre on the planet. We’ve got dozens just here in Canada, and there are literally thousands in the US. The members of the society will usually meet on a regular basis and will have observing nights where they all get together and point their telescopes at different objects. This is a great way to quickly see what the night sky has to offer.

Do a search on Google with the search terms: yourtown astronomical society. For example, I would do a search for: Vancouver astronomical society. If nothing turns up for your specific location, broaden the search a bit. Eventually you should come up with something. Find the contact information for the society and drop them an email or give them a phone call. Trust me, they’ll be happy to give you more information and have you join them for an evening.

Next, see if there’s an observatory in your region. Although most of the largest telescopes are fully booked up for years in advance, some of the smaller ones have open nights where people can come down, ask to see stuff and they’ll move the scope around. Often these open nights are run by the local astronomical society. Once again, contact the society and find out if they can recommend an observatory to check out. Or, you can do a search on Google (search for: yourtown observatory) and contact them directly.

Learn your constellations
Whether you actually contact a society or just decide to go solo is up to you, but your first step is to learn some of your constellations. Maybe you already know the Big Dipper or Orion’s belt, but there are 88 constellations in Northern and Southern hemispheres. It’s pretty cool to be able to ask a person what their sign is, and then point it out in sky.

Learning your constellations is also the first step to finding some of the more interesting stuff to look at in the night sky. They’re like your guides. For example, our nearest galaxy, Andromeda (aka M31) is easily visible in binoculars or a telescope. It’s just a little up from the middle of the constellation Andromeda, which is just above Aries. I can spot M31 in a second whenever a look up in the sky (at the right time of year). Once you start to learn your constellations, they all start to fit together like a puzzle. And the great thing is the knowledge never goes away, even if it’s been a few years since you’ve done any observing.

There are many great resources for learning your constellations. One option is to do a search, once again on Google, for the term: astronomy sky charts. Some of these are fairly detailed, however, and make it hard to just learn the basic constellations.

The book that taught me, and I can’t recommend it highly enough is Nightwatch, by Terrence Dickinson. The book breaks the night sky into seasons and then has single pages for each chunk of sky with clearly defined stars and constellations – similar to one of those road maps that sit open on the car seat next to you. The book also has fabulous information on starting equipment, etc. (Order Nightwatch from Amazon.com – $20.97)

Another handy tool is Astronomy magazine. The middle of each issue is a star chart for the current month. The advantage of using a magazine like Astronomy is that it also has the current positions of the planets. (Click here to get a subscription to Astronomy for 32% off the newsstand price)

Finally, you can use a software product like Starry Nights, which lets you define your location and time to produce a custom star chart that includes the locations of the planets. (Click here for more information on Starry Nights)

Once you’ve got your sky chart together, I suggest you also get a flashlight with a red-light filter. You can usually pick them up at camping stores or army surplus. This way you can look at your charts without ruining your night vision.

Now, hit the road! If you live in an area with reasonably dark skies, you can just turn out the lights in your house and head into your back yard. If you live in a city, you’ll have to get a little ways out. Even a dark park or dimly lit suburb will be a vast improvement over the downtown core. City lights cause two problems: the streetlights will send a glare up into your night sky, dimming your visibility; and the lights will ruin your night vision directly.

Give yourself a couple of hours, and by the end of it you’ll be familiar with most of the constellations in the sky. You’ll probably also see a few meteors and even some satellites. Quality family entertainment if you ask me.

Improving your stargazing experience
Astronomy is one of those hobbies that you can enjoy for free, but you can really improve your experience with some basic equipment.

Binoculars
Chances are you’ve already got one of the most useful pieces of stargazing equipment already in your home: binoculars. Anywhere you look in the night sky is significantly improved by a simple pair of astronomical binoculars, from the Moon to star clusters. In fact, some stuff looks better in binoculars than a more powerful telescope.

Binoculars generally have two measurements: magnification and field of view. For example, a common kind is 7×35. This means it has a 7x magnification and 35mm field of view. For astronomy, power isn’t necessarily a good thing. Some go as high as 20x or even 30x, but this usually creates a very small field of view. And since you’re holding the binoculars with your hands, it can get very shaky.

It’s much better to go with a lower power set of binoculars with a large field of view: 8×50 is a perfect combination of power and field of view.

Obviously it’s important to have good quality optics, but that’s one of those things that you should experience with first to get a sense of the equipment you already have. If it’s too high-power, or you can’t focus the image to get really crisp stars, you might want to consider upgrading your gear.

It’s also really useful to have a tripod adapter hole on the bottom of your binoculars. This will let you screw them onto the top of a tripod and then let other people come and take a look through the eyepieces to share your view.

Here are some links to Binoculars.com for some good astronomical binoculars:

Celestron 7×50 Enduro. Straightforward pair of binoculars with good magnification and field of view. $57.40 USD

Bausch & Lomb 10×50 Legacy. Higher magnification with 50mm field of view. $111.00 USD.

Canon 15×50 IS. Pretty much the best binoculars you can get. Higher resolution but image stabilization keeps the image from shaking. $899.00 USD

Telescope
If you’re thinking of buying a telescope, then you’ve really got the bug. However, don’t just run down and purchase a telescope from a department or toy store. These usually have low quality optics, a jiggly mount and generally stink for astronomy – those “in the know” call them “Christmas trash scopes”.

For the same price or a little more you can purchase a real telescope with quality optics and mount and have a much better experience with the night sky.

There are many different kinds of telescopes, and explaining the differences of how to select a good telescope can fill a book so I won’t go into the details here. Remember your contacts at your local astronomical society? Let them know your budget and objectives and they can probably recommend a good telescope. They might even know someone who’s selling one used. Of course, these folks are going to be astronomy fans, so they might have bigger ideals than what you’re looking for.

There are two main kinds of telescopes: refractors and reflectors.

Refractors work through a series of lenses which focus light into the telescope’s eyepiece (think of your traditional ship captain’s spyglass) and typically have a main lens between 70mm and 100mm. These can be solid telescopes, but the optics can make them more expensive than reflectors.

One example refractors would be the Meade EXT-70AT ($298.00 USD). A small portable refractor with with a computer-controlled mount. Put the telescope on a flat surface, align it with the sky and then it can automatically pick out targets in the sky. These automated telescopes can take some of the fun out of stargazing, but it definitely speeds things up.

Reflectors use a big mirror to reflect and focus incoming light to the telescope’s eyepiece. They’re usually shorter and fatter than a refractor, starting at 4 inches and going up from there. I started, and still use a 4″ telescope, which is perfectly fine to see the major planets and all kinds of astronomical objects.

An example reflector is a Celestron 4.5″ Firstscope ($149.00). No computer on this telescope, so you’ll get a chance to learn the location of sky objects on your own.

Bigger telescopes gather more light, so they can display fainter objects, but they come with a higher price. My recommendation is to start small, get some experience before considering a higher-end telescope.

Probably the best starting telescope is something like a 6″ Dobsonian reflector. Unlike most telescopes you’ve seen, the Dobsonians have their mount down at the base and then point up. They’re solid, inexpensive, and easy to use. Some of the largest, most powerful amateur-built telescopes are Dobsonians.

Here’s a link to a Swift Instruments 6″ Dobsonian telescope ($382.95 USD).

An a link to a much larger Meade Starfinder 16″ Dobsonian ($1,386.00 USD).

Now Get Out There!
Enough reading, start sky watching. Early Summer is a great time to get involved in astronomy (and a terrible time to watch TV) – warm summer nights and stargazing go hand in hand. Do a little research, grab some supplies, gather the friends and family, and get out under the stars. And please, email me your summer experiences. Trust me, you’ll get some memories you’ll never forget.