Translate

Showing posts with label Asteroid. Show all posts
Showing posts with label Asteroid. Show all posts

Aug 7, 2017

The Asteroid 2012 TC4 Has Been Recovered

his animation depicts the safe flyby of asteroid 2012 TC4 as it passes under
 Earth on Oct. 12, 2017. While scientists cannot yet predict exactly how 
close it will approach, they are certain it will come no closer than 4,200
 miles (6,800 kilometers) from Earth's surface.Credits: NASA/JPL-Caltech

The observers  O. Hainaut, D. Koschny, and M. Micheli using the 8.2-meter VLT (Very Large Telescope)  at Cerro Paranal, Chile(MPC Code 309)   have recovered the asteroid 2012 TC4. The asteroid was observed from 2017 07 27.2465042 to 2017 08 05.39707023 and five observations were taken. The new observations greatly lowers the uncertainty where it will be in the future.

Given the closeness of the October 12, 2017 close approach and the fact that 2012 TC4 is listed on  risk list(for 2020 an beyond) created a buzz on the internet 2012 TC4.  On July 28, 2017 NASA  announced an observation campaign  headed by Dr. Vishnu Reddy. NASA plans to close approach to test their "network of observatories and scientists who work with planetary defense."

Background
(as of 2017-07-06)

  •  Object: 2012 TC4
  • Orbit Type: Apollo [NEO]
  • Approximate Diameter: 12 m - 27 m (  39.3701 feet to 88.5827  feet)(Absolute Magnitude: H= 26.7)
  • On the Sentry Risk Table:  Yes 
    •  NOTE this is NOT a prediction of an impact but rather a statement there is insufficient observational data rule out an impact -- for more information read  Understanding Risk Pages by Jon Giorgini
  • Torino Scale 0
    • "The likelihood of a collision is zero, or is so low as to be effectively zero. Also applies to small objects such as meteors and bodies that burn up in the atmosphere as well as infrequent meteorite falls that rarely cause damage.."
  • On the NEODyS CLOMON2 risk page: Yes
    • NEODyS Recovery Campaign: 2017-08-31 to 2017-10-24
  • Discovery observation was made: 2012 10 04.467661
  • Discovery observation was made by Pan-STARRS 1 (MPC Code F51) The Discovery M.P.E.C.: MPEC 2012-T18 : 2012 TC4
  • Last Observation (publish): 2017 08 05.397070(by the 8.2-meter VLT (Very Large Telescope)  at Cerro Paranal, Chile(MPC Code 309)  )
  • Data-Arc Span (publish): 1766 days (4.838  years)
  • Number of Optical Observations(published):301
  • Observatories Reporting (Published) Observations(MPC Code):
    • (089) Nikolaev,  Ukraine.
    • (104) San Marcello Pistoiese, Italy.
    • (113) Volkssternwarte Drebach, Schoenbrunn, Germany.
    • (204) Schiaparelli Observatory, Italy
    • (291) LPL/Spacewatch II, US/Arizona.
    • (300) Bisei Spaceguard Center-BATTeRS, Japan.
    • (309) Cerro Paranal, Chile
    • (461) University of Szeged, Piszkesteto Stn (Konkoly), Hungary.
    • (470) Ceccano, Italy.
    • (568) Mauna Kea, US/Hawaii.
    • (695) Kitt Peak, US/Arizona.
    • (703) Catalina Sky Survey, US/Arizona.
    • (716) Palmer Divide Observatory, Colorado Springs, US/Colorado.
    • (718) Tooele, US/Utah.  
    • (857) Iowa Robotic Observatory, Sonoita, US/Arizona.
    • (900) Moriyama, Japan.
    • (932) John J. McCarthy Obs., New Milford,  US/Connecticut.
    • (B04) OAVdA, Saint-Barthelemy, Italy. 
    • (B88) Bigmuskie Observatory, Mombercelli, Italy.
    • (C32) Ka-Dar Observatory, TAU Station, Nizhny Arkhyz, Russia.
    • (C77) Bernezzo Observatory, Italy.
    • (E10) Siding Spring-Faulkes Telescope South, Australia/NSW.
    • (F51) Pan-STARRS 1, Haleakala, US/Hawaii
    • (F65) Haleakala-Faulkes Telescope North, US/Hawaii.
    • (G40) Slooh.com Canary Islands Observatory, Canary Islands (Spain).
    • (G48) Doc Greiner Research Obs., Rancho Hildalgo,  US/New Mexico.
    • (H06) iTelescope Observatory, Mayhill, US/New Mexico.  
    • (H17) Angel Peaks Observatory, US/Colorado.
    • (H21) Astronomical Research Observatory, Westfield, US/Illinois.
    • (H36) Sandlot Observatory, Scranton, US/Kansas
    • (J16) An Carraig Observatory, Loughinisland, UK.
    • (J84) South Observatory, Clanfield, UK.
    • (J95) Great Shefford, UK.
  • Perihelion Distance: 0.9337118172491301(AU)
  • Aphelion Distance: 1.877545179495153(AU) 
  • Earth MOID (Earth center to NEO center): AU 0.000249707( (0.097 LD)), (5.86 Earth radii)  or  23,211.716 miles ( 37,355.635 (KM))
  • Next Close-Approach to Earth:  Will safely pass Earth on 2017-Oct-12 at a 
    • Nominal Distance(Earth center to NEO center) of 0.000335174413034106(AU) (0.13(LD)), (7.87 Earth radii) or 31,156.408 miles ( 50,141.379 (KM)) 
    • Minimum Distance(Earth center to NEO center) of 0.000332681020635643(AU) (0.129(LD)), (7.81 Earth radii) or 30,924.633 miles (49,768.372 (KM)) 
    • Maximum Distance(Earth center to NEO center) of 0.000337670398414312(AU) ( 0.131(LD)), (7.93 Earth radii) or 31,388.424 miles (50,514.773 (KM))   
Useful Links:

Jan 22, 2017

Virtual Asteroids, The Observatory's Cat, a Lost Car Key, and 2012 TC4 Beyond the 2017-Oct-12 Close-Approach

The Second Part in a Series

An artist’s rendition of 2016 WF9 as it passes Jupiter’s orbit inbound toward
the Sun. Image: Courtesy NASA/JPL-Caltech
Now I plan to give some background on the subject of virtual asteroids and virtual impactors. While asteroid researchers know this topic well this is for the non-researchers, I am going to explain the subject by way of a silly story,

The Observatory's cat and the Lost Car Key

There was an observatory that hosted a monthly Astronomy and Ice Cream Night. This event would consist a free talk on Astronomy and ice cream(at a nominal cost). At the end of one of the events the professor who gave that night's talk discovers he had lost his car key. Everyone knew that the key had to be at the observatory. First, they sent security out to keep an eye on the parking lot, then they started checking under the tables, by the display cases, the podium, and the trash cans. Many other keys were found when asked "is this your key?" the professor said "no." One thing that set this observatory apart was it was adopted by a cat named OC(A.K.A Observatory Cat). OC loved ice cream, and OC was found with the key licking ice cream off it when asked "is this your key?" the professor said "yes" and drove home.

If we think of the story this way, there is a large number of "virtual" keys. One for each "possibility" where the "real" key "may be," as places were searched the "virtual" keys were eliminated. They could not rule out that someone had the key and would steal the car this risk would be a great risk if the vehicle is easy to find in a small lot. On the other hand, if the lot were enormous the and the car was hard to locate the risk would be lower. There may be many keys so one can not assume that they found the key because only one key will start the car. The cat would be the Yarkovsky Effect and gravitational perturbations, the cat moved the key but kept it at the observatory, 

 Now Back to Asteroids

One thing to remember is unlike, car thieves, cats, and lost car keys asteroids follow the laws of planetary motion. Asteroids move through an extensive solar system in elliptical orbits. An asteroid's orbit and position within its orbital path determines where in the sky the asteroid can be seen from a location at a given time. When astronomers(professional and amateur) observe an asteroid, they record its coordinates(sky position) along with the day and time, apparent magnitude, and a code for their location. An asteroid's orbit is determined by finding an orbit that best places it in the sky as it was observed from the given location at the given time.

When it comes to orbit determination there is no such thing as "the" orbit for any asteroid, tiny observational errors come into play. The solution is to generate an enormous number of slightly different orbits that fit the observations acceptably well. Each orbit has it own virtual asteroid.  There is an uncertainty region containing the virtual asteroids.  The "real" asteroid is somewhere within the uncertainty region. After each set of new observations, the orbits are re-generated, and like reality game shows contestants, many virtual asteroids are eliminated.  As time moves forward, the virtual asteroids will move apart from each other. If the asteroid goes unobserved for an extended time, the uncertainty region can become enormous and sometimes can wrap around the solar system more than once.  

Through the use of computers, the positions of the virtual asteroids can be projected into the future, while accounting for the Yarkovsky Effect; and the gravitational forces of the Sun, The Earth, Our Moon, the other planets, and the large asteroids. If any virtual asteroids impact the Earth, they are known as virtual impactors. The percentage of virtual asteroids that "impact" the Earth is used to estimate the risk the "real" asteroid could "impact" the Earth. If the risk is greater than 1 in 10 billion, the asteroid is placed on the risk lists. Asteroids on the risk lists are rated on the Palermo Technical Impact Scale which compares the risk from the asteroid to the risk from all asteroids and the Torino Scale(for the next 100 years) which is used to communicates the level of risk from the asteroid to the public. Whenever an asteroid is posted to one the risk lists, and it is observable, observers will take a particular interest in it. Follow-up observations may be attempted and there maybe a search in archives images for precovery observations.

When reading the risk lists, one should keep in mind that the risk lists are NOT a prediction of an impact or even a close-approach. The "real" asteroid could be on the other side of the solar system when the virtual asteroid "impacts." Also keep in mind as new observations are reported the asteroid will most likely be removed from the risk lists; however, the risk may increase before it drops off the list if the "real" asteroid is making an exceptionally close approach to Earth on the date in question, this is normal.

2012 TC4  beyond the 2017-Oct-12 Close-Approach

On 2017-Oct-12 the Earth will be outside of the uncertainty region of 2012 TC4 this rules out an impact from this asteroid on this date. However, based on all available observations made to date the Earth will pass through the uncertainty region of 2012 TC4 on 2020-Oct-11.72, and there will be a 1 in 1,613,000 chance of impact. The risk does not stop there from 2020 to 2114 there will be 79  Potential Impacts of 2012 TC4 with a cumulative risk of 1 in 12,000 chance of impact. 2012 TC4 could be observed during this year's apparition. If "new" observations are taken the orbits will be re-generated, and like reality game shows contestants, many virtual asteroids will be eliminated. Most likely any risk for the next 100 year will be ruled out.

[!!!Note you are reading this after Fall of 2017 Check for Updates!!!]



Background and Sources
(as of 2017-01-21) 
  • Object: 2012 TC4
  • Orbit Type: Apollo [NEO]
  • Approximate Diameter: 15 m - 33 m (  49.2126 feet to 108.268  feet)(Absolute Magnitude: H= 26.7)
  • On the Sentry Risk Table:  Yes 
    •  NOTE this is NOT a prediction of an impact but rather a statement there is insufficient observational data rule out an impact -- for information read  Understanding Risk Pages by Jon Giorgini
  • Torino Scale 0
    • "The likelihood of a collision is zero, or is so low as to be effectively zero. Also applies to small objects such as meteors and bodies that burn up in the atmosphere as well as infrequent meteorite falls that rarely cause damage.."
  • On the NEODyS CLOMON2 risk page: Yes
    • NEODyS Recovery Campaign: 2017-08-31 to 2017-10-24
  • Discovery observation was made: 2012 10 04.467661
  • Discovery observation was made by Pan-STARRS 1 (MPC Code F51) The Discovery M.P.E.C.: MPEC 2012-T18 : 2012 TC4
  • Last Observation (publish): 2012 10 11.74842 (by Volkssternwarte Drebach, Schoenbrunn(MPC code 113))
  • Data-Arc Span (publish): 7 days
  • Number of Optical Observations(published):301
  • Observatories Reporting (Published) Observations(MPC Code):
    • (089) Nikolaev,  Ukraine.
    • (104) San Marcello Pistoiese, Italy.
    • (113) Volkssternwarte Drebach, Schoenbrunn, Germany.
    • (204) Schiaparelli Observatory, Italy
    • (291) LPL/Spacewatch II, US/Arizona.
    • (300) Bisei Spaceguard Center-BATTeRS, Japan.
    • (461) University of Szeged, Piszkesteto Stn (Konkoly), Hungary.
    • (470) Ceccano, Italy.
    • (568) Mauna Kea, US/Hawaii.
    • (695) Kitt Peak, US/Arizona.
    • (703) Catalina Sky Survey, US/Arizona.
    • (716) Palmer Divide Observatory, Colorado Springs, US/Colorado.
    • (718) Tooele, US/Utah.  
    • (857) Iowa Robotic Observatory, Sonoita, US/Arizona.
    • (900) Moriyama, Japan.
    • (932) John J. McCarthy Obs., New Milford,  US/Connecticut.
    • (B04) OAVdA, Saint-Barthelemy, Italy. 
    • (B88) Bigmuskie Observatory, Mombercelli, Italy.
    • (C32) Ka-Dar Observatory, TAU Station, Nizhny Arkhyz, Russia.
    • (C77) Bernezzo Observatory, Italy.
    • (E10) Siding Spring-Faulkes Telescope South, Australia/NSW.
    • (F51) Pan-STARRS 1, Haleakala, US/Hawaii
    • (F65) Haleakala-Faulkes Telescope North, US/Hawaii.
    • (G40) Slooh.com Canary Islands Observatory, Canary Islands (Spain).
    • (G48) Doc Greiner Research Obs., Rancho Hildalgo,  US/New Mexico.
    • (H06) iTelescope Observatory, Mayhill, US/New Mexico.  
    • (H17) Angel Peaks Observatory, US/Colorado.
    • (H21) Astronomical Research Observatory, Westfield, US/Illinois.
    • (H36) Sandlot Observatory, Scranton, US/Kansas
    • (J16) An Carraig Observatory, Loughinisland, UK.
    • (J84) South Observatory, Clanfield, UK.
    • (J95) Great Shefford, UK.
  • Perihelion Distance: 0.9337184081730526(AU)
  • Aphelion Distance: 1.877515914032821
  • Goldstone Asteroid Schedule: Yes  2017 Oct ( Needs Astrometry: Yes Physical Ob
  • Near-Earth Object Human Space Flight Accessible Targets Study (NHATS): Yes
Useful Links:



Jan 17, 2017

A NEO Re-Confirmation for the Asteroid 2016 VM4

The asteroid 2016 VM4 on 2017-01-15 from
Sierra Remote Observatory. Auberry California USA ( MPC U69)
a stack of 30-120 Second Luminance BIN1 Images
 taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley
The asteroid 2016 VM4 on 2017-01-15 from 
Sierra Remote Observatory. Auberry California USA ( MPC U69) 
a stack of 5-120 Second Luminance BIN1 Images
 taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley
The asteroid 2016 VM4 on 2017-01-15 from 
Sierra Remote Observatory. Auberry California USA ( MPC U69) 
a stack of 5-120 Second Luminance BIN1 Images
 taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley
The asteroid 2016 VM4 on 2017-01-15 from 
Sierra Remote Observatory. Auberry California USA ( MPC U69) 
a stack of 5-120 Second Luminance BIN1 Images
 taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley
The asteroid 2016 VM4 on 2017-01-15 from 
Sierra Remote Observatory. Auberry California USA ( MPC U69) 
a stack of 5-120 Second Luminance BIN1 Images
 taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley
The asteroid 2016 VM4 on 2017-01-15 from 
Sierra Remote Observatory. Auberry California USA ( MPC U69) 
a stack of 5-120 Second Luminance BIN1 Images
 taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley
The asteroid 2016 VM4 on 2017-01-16 from
Sierra Remote Observatory. Auberry California USA ( MPC U69)
 a stack of 12-120 Second Luminance BIN2 Images
taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley
The asteroid 2016 VM4 on 2017-01-16 from
Sierra Remote Observatory. Auberry California USA ( MPC U69)
 a stack of 3-120 Second Luminance BIN2 Images
taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
-- sometimes stars get in the way--
By Steven M. Tilley
The asteroid 2016 VM4 on 2017-01-16 from
Sierra Remote Observatory. Auberry California USA ( MPC U69)
 a stack of 3-120 Second Luminance BIN2 Images
taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley

The asteroid 2016 VM4 on 2017-01-16 from
Sierra Remote Observatory. Auberry California USA ( MPC U69)
a stack of 3-120 Second Luminance BIN2 Images
taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley
The asteroid 2016 VM4 on 2017-01-16 from 
Sierra Remote Observatory. Auberry California USA ( MPC U69) 
a stack of 3-120 Second Luminance BIN2 Images 
taken with iTelescope.net's (TEL T24 0.61-m f/6.5 reflector + CCD)
 By Steven M. Tilley
When seeking out imaging targets I often check the NEO Confirmation Page for an object that is not too faint,  not too fast, not too close to a bright moon, and not too much uncertainty.  This weekend found one and observed it for two nights. With the observations from observers from around the world along with my observations the MPC match to the known asteroid 2016 VM4 (this is not unusual.  2016 VM4 had previously been only observed for 3 days in November of 2016 and had a poorly defined orbit. 

The Asteroid 2012 TC4 is Making a Safe Close-Approach on October-12-2017 Please Stand By For a Media Storm

The First in a Series
This artist's concept shows a broken-up asteroid.
ImageCourtesy NASA/JPL-Caltech 
On October 12, 2017, the asteroid 2012 TC4 is projected to make an exceptionally close approach to Earth, and it is possible that the media (alternative, mainstream,  print, broadcast, and social) will go wild. Writeups will range from well written to poorly written, originally written to carbon copies, well research to poorly research, well intentioned to bad intentioned, and so forth. How is the consumer of media to make heads or tails of the hodgepodge of choices out there? The author plans a series of posts to give some background on 2012 TC4 in particular, some general knowledge about asteroids, their orbit, asteroid observing, asteroid risk list, and source information, to help the read navigate the mishmash of media out there.

What makes the Close-Approach on October 12, 2017, exceptional?

If we count 2008 TC3 and 2014 AA(both were small and impacted the Earth and would tie for first) 2012 TC4 could come in as the sixth closest known approach to date.  While there is some uncertainty about how close the close-approach will be, there is sufficient observational data to rule out an impact on October 12, 2017, When talking about astronomical distances it can be tough to wrap one's head around this can lead one to use of analogies such as close shave which is not aways helpful. If one uses a basketball to serve as a model for the Earth it may be easier to grasp.

Note some of this infomation is outdated See:The Asteroid 2012 TC4 Has Been Recovered

The Model  (the Basketball Size Earth) 

  • Earth (Equatorial) radius: 4.2634965e-5 AU 3963.17 miles (6378.1 KM) - for the model 4.69507082121091 inches (11.93 CM)
  • Earth (Equatorial) Circumference(assuming around Earth): 0.000267883358316 AU 24,901.32 miles (40,074.78 KM) -for the model 29.5 inches (74.93 CM)
  • ISS(Perigee): 2.67383e-6 AU 248.55 miles (400.00 KM) -for the model 0.29 inches ( 0.75CM)
  • ISS(apogee): 2.7407e-6 AU 254.76 miles (400.00 KM) -for the model 0.3 inches ( 0.77CM)
  • Geosynchronous orbit: 0.00023921463 AU (0.093 Lunar Distance (LD)) or 22236.39 miles (35786.00 KM)  -for the model (after subtracting the radius)- 2.2 feet ( 0.67 M)
  • Lunar Distance (LD): 0.003 AU or 238606.54  22236.39 miles (35786.00 KM)  -for the model (after subtracting the radius)-  23.16 feet (7.06 M)
  • Astronomical Unit: 389.171 Lunar Distance (LD) or 9.296e+7 miles (1.496e+8 KM)   -for the model   1.7 miles  (2.7 KM)

Background
(as of 2017-01-16 ) 


  • Object: 2012 TC4
  • Orbit Type: Apollo [NEO]
  • Approximate Diameter: 15 m - 33 m (  49.2126 feet to 108.268  feet)(Absolute Magnitude: H= 26.7)
  • On the Sentry Risk Table:  Yes 
    •  NOTE this is NOT a prediction of an impact but rather a statement there is insufficient observational data rule out an impact -- for information read  Understanding Risk Pages by Jon Giorgini
  • Torino Scale(NEODyS CLOMON2)0
    • "The likelihood of a collision is zero, or is so low as to be effectively zero. Also applies to small objects such as meteors and bodies that burn up in the atmosphere as well as infrequent meteorite falls that rarely cause damage.."
  • On the NEODyS CLOMON2 risk page: Yes
    • NEODyS Recovery Campaign: 2017-08-31t o 2017-10-24
  • Discovery observation was made: 2012 10 04.467661
  • Discovery observation was made by Pan-STARRS 1 (MPC Code F51) The Discovery M.P.E.C.: MPEC 2012-T18 : 2012 TC4
  • Last Observation (publish): 2012 10 11.74842   (by Volkssternwarte Drebach, Schoenbrunn(MPC code 113))
  • Data-Arc Span (publish): 7 days
  • Number of Optical Observations(published):301
  • Observatories Reporting (Published) Observations(MPC Code):
    • (089) Nikolaev,  Ukraine.
    • (104) San Marcello Pistoiese, Italy.
    • (113) Volkssternwarte Drebach, Schoenbrunn, Germany.
    • (204) Schiaparelli Observatory, Italy
    • (291) LPL/Spacewatch II, US/Arizona.
    • (300) Bisei Spaceguard Center-BATTeRS, Japan.
    • (461) University of Szeged, Piszkesteto Stn (Konkoly), Hungary.
    • (470) Ceccano, Italy.
    • (568) Mauna Kea, US/Hawaii.
    • (695) Kitt Peak, US/Arizona.
    • (703) Catalina Sky Survey, US/Arizona.
    • (716) Palmer Divide Observatory, Colorado Springs, US/Colorado.
    • (718) Tooele, US/Utah.  
    • (857) Iowa Robotic Observatory, Sonoita, US/Arizona.
    • (900) Moriyama, Japan.
    • (932) John J. McCarthy Obs., New Milford,  US/Connecticut.
    • (B04) OAVdA, Saint-Barthelemy, Italy. 
    • (B88) Bigmuskie Observatory, Mombercelli, Italy.
    • (C32) Ka-Dar Observatory, TAU Station, Nizhny Arkhyz, Russia.
    • (C77) Bernezzo Observatory, Italy.
    • (E10) Siding Spring-Faulkes Telescope South, Australia/NSW.
    • (F51) Pan-STARRS 1, Haleakala, US/Hawaii
    • (F65) Haleakala-Faulkes Telescope North, US/Hawaii.
    • (G40) Slooh.com Canary Islands Observatory, Canary Islands (Spain).
    • (G48) Doc Greiner Research Obs., Rancho Hildalgo,  US/New Mexico.
    • (H06) iTelescope Observatory, Mayhill, US/New Mexico.  
    • (H17) Angel Peaks Observatory, US/Colorado.
    • (H21) Astronomical Research Observatory, Westfield, US/Illinois.
    • (H36) Sandlot Observatory, Scranton, US/Kansas
    • (J16) An Carraig Observatory, Loughinisland, UK.
    • (J84) South Observatory, Clanfield, UK.
    • (J95) Great Shefford, UK.
  • Perihelion Distance: 0.9337184081730526(AU)
  • Aphelion Distance: 1.877515914032821
  • Goldstone Asteroid Schedule: Yes  2017 Oct ( Needs Astrometry: Yes Physical Ob
  • Near-Earth Object Human Space Flight Accessible Targets Study (NHATS): Yes
Useful Links: