New Horizons Mission Update 2/27/14

 

 

 

Elapsed Mission Time:
Beginning 1/19/06 19:00:00 UTC
2961 Days (8.11 yrs.) 07 Hours 58 Minutes

Pluto Closest Encounter
Operations Begin:
4/12/15 00:00:00 UTC
407 Days (1.12 yrs.) 21 Hours 01 Minutes

Pluto Closest Approach:
7/14/15 11:49:59 UTC
501 Days (1.37 yrs.) 08 Hours 50 Minutes

 

New Horizons sailed past another milepost today when the NASA spacecraft moved to within four astronomical units (AU) of Pluto – which is less than four times the distance between the Earth and the sun, or about 371 million miles (598 million kilometers).   "We're as close to the Pluto system now as Earth ever gets to Jupiter, a first for any spacecraft,” says New Horizons Principal Investigator Alan Stern.

 

Since launch on January 19, 2006, New Horizons has covered nearly 2.89 billion miles (4.62 billion kilometers). It makes a temporal connection with one NASA’s legendary deep-space explorers this summer when it crosses the orbit of Neptune on Aug. 25 — exactly 25 years after Voyager 2 made its historic flight past that giant planet. When New Horizons arrives at Pluto on July 14, 2015, it will have traveled farther than any spacecraft ever has to reconnoiter its prime target. An astronomical unit (AU) is the average distance between the Earth and sun, about 93 million miles or 149 million kilometers. New Horizons’ journey from Earth to Pluto will have covered more than 32 AU. when it reaches its destination.

 

 

New Horizons Course and Position in Two Dimensions:

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New Horizons Mission Update 2/7/14

 

 

Mission Elapsed Time:
Beginning 1/19/06 19:00:00 UTC
2941 Days (8.06 yrs.) 08 Hours 12 Minutes

Pluto Closest Encounter
Operations Begin:
12/4/15 00:00:00 UTC
427 Days (1.67 yrs.) 20 Hours 48 Minutes

Pluto Closest Approach:
14/7/15 11:49:00 UTC
521 Days (1.42 yrs.) 08 Hours 37 Minutes

New Horizons completed a quick, two-week maintenance wakeup on Jan. 17 and is back in hibernation. They will wake the craft again in mid-June for the last active checkout, lasting about 10 weeks, on the journey to Pluto. Then back to hibernation again from late August through early December, and then they will wake New Horizons  for the encounter that she was built for.  By this time next year, New Horizons will be executing the earliest phases of the Pluto system encounter. Closest approach is now just 17 months away! That may seem like a while to you, but after almost 97 months in flight, it’s just around the corner to the team. Most people may not appreciate it, but 2014 is the last year, forever, that Pluto and its moons will be known only as points of light or smudgy images to humankind.

New Horizons Course and Position in two Dimensions:

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Beginning this summer, the team will take you along with them more intimately on their preparations to explore the Pluto system.  The stories they are  going to tell as the encounter approaches, culminates and recedes will cover more than the progress of the encounter flight plan and the data we’ll receive —though those elements will certainly be covered well too. But in addition, it will also tell the story of how and why this mission was funded – by being ranked the No. 1 priority of the National Academy’s 2000s decadal survey in planetary science. Also, they will be talk about U.S. leadership and preeminence in planetary exploration, of which New Horizons is a one kind of demonstration. But there’s more.

Total Time of Pluto and Vicinity Encounter Observations

They will discuss the danger of debris strikes that our lone spacecraft may face as it flashes through the Pluto system on the morning of Tuesday, July 14, 2015 – and the decisions the team will have to make concerning those risks. They will discuss  the extreme degree of persistence it took on the part of the scientific community and the mission team, withering five cancellations, a plutonium fuel shortage, the death of key project engineers, and more, to get this mission funded, and built and launched on a schedule so tight that many people thought it could not be done.

They will discuss what planetary scientists have discovered lately about the diversity of planets in our solar system — and that vast, new, third zone of the solar system called the Kuiper Belt. They are going to talk about New Horizons launching faster and going farther than any space mission ever has to reach its prime target. They will talk about the high-tech miniaturization that makes New Horizons the successor to the Voyagers at only a fraction of their size, mass and cost.  They will  talk about humankind’s insatiable urge to explore new frontiers.

Science at the Frontier:

Our solar system contains three zones: the inner, rocky planets; the gas giant planets; and the Kuiper Belt. Pluto is one of the largest bodies of the icy, "third zone" of our solar system. The National Academy of Sciences placed the exploration of the third zone in general - and Pluto-Charon in particular - among its highest priority planetary mission rankings for this decade. New Horizons is NASA's mission to fulfill this objective.

The Pluto Solar System and it’s newly discovered and named moons

In those zones, our solar system has three classes of planets: the rocky worlds (Earth, Venus, Mercury and Mars); the gas giants (Jupiter, Saturn, Uranus and Neptune); and the ice dwarfs of the Kuiper Belt. There are far more ice dwarf planets than rocky and gas giant worlds combined - yet, no spacecraft has been sent to a planet in this class. The National Academy of Sciences noted that our knowledge of planetary types is therefore seriously incomplete. As the first mission to investigate this new class of planetary bodies, New Horizons will fill this important gap and round out our knowledge of the planets in our solar system.

As of Today

Binary Planet:

Pluto's largest moon, Charon, is half the size of Pluto. The pair form a binary planetary system, whose gravitational balance point is between the two bodies. Although binary planets are thought to be common in the galaxy, as are binary stars, no spacecraft has yet explored one. New Horizons will be the first mission to explore a binary object of any type.

Charon as seen from the surface of Pluto

Ancient Relics:

Largest Known Kuiper Belt Objects

The ice dwarfs are planetary embryos, whose growth stopped at sizes (200 to 2,000 kilometers across) much smaller than the full-grown planets in the inner solar system and the gas giants region. The ice dwarfs are ancient relics that formed over 4 billion years ago. Because they are literally the bodies out of which the larger planets accumulated, the ice dwarfs have a great deal to teach us about planetary formation. New Horizons seeks those answers.

A Mission with Impact:

The Kuiper Belt is the major source of cometary impactors on Earth, like the impactor that wiped out the dinosaurs. New Horizons will shed new light on the number of such Kuiper Belt impactors as a function of their size by cataloging the various-sized craters on Pluto, its moons, and on Kuiper Belt Objects.  Pluto and the Kuiper Belt are known to be heavily endowed with organic (carbon-bearing) molecules and water ice — the raw materials out of which life evolves. New Horizons will explore the composition of this material on the surfaces of Pluto, its moons and Kuiper Belt Objects.

The Need to Explore:

As the first voyage to a whole new class of planets in the farthest zone of the solar system, New Horizons is a historic mission of exploration. The United States has made history by being the first nation to reach every planet from Mercury to Neptune with a space probe. The New Horizons mission to Pluto and the Kuiper Belt - the first NASA launch to a "new" planet since Voyager more than 30 years ago - allows the U.S. to complete the reconnaissance of the solar system.

 

 

Into the Kuiper Belt:

Plans for an extended mission include one to two encounters with Kuiper Belt Objects, ranging from about 25 to 55 miles (40 to 90 kilometers) in diameter. New Horizons would acquire the same data it collected at Pluto - where applicable - and follow a timeline similar to the Pluto  encounter:

Closest Approach - 4 weeks: object observations
Closest Approach + 2 weeks: post-encounter studies
Closest Approach + 2 months: all data returned to Earth

New Horizons: Going for the Planetary Gold Medal of the Planetary Space Olympics:

New Horizons Mission Update 1/8/14

 

 

Mission Elapsed Time:
Beginning 1/19/06 19:00:00 UTC
2911 Days (7.96 yrs.) 08 Hours 23 Minutes

Pluto Closest Encounter
Operations Begin:
4/12/15 00:00:00 UTC
457 Days (1.25 yrs.) 20 Hours 36 Minutes

Pluto Closest Approach:

7/14/15 11:49:59: UTC
551 Days (1.51 yrs.) 08 Hours 25 Minutes

 

With Pluto encounter operations now just a year away, the New Horizons team has brought the spacecraft out of hibernation for the first of several activities planned for 2014.   Mission operators at the Johns Hopkins Applied Physics Lab in Laurel, Md., “woke” New Horizons on Jan. 5. Over the next two weeks the team will test the spacecraft’s antenna and repoint it toward Earth; upload commands into the onboard Guidance and Control and Command and Data Handling systems, including a check on the backup inertial measurement unit and update of the spacecraft’s navigational star charts; and conduct some navigational tracking, among other routine maintenance duties. “We’ve had busier wakeup periods, but with long-distance Pluto encounter operations starting only a year from now, every activity is important,” says APL’s Alice Bowman, New Horizons mission operations manager.

The pace of operations picks up significantly later this year. In late June the team will wake New Horizons for two and a half months of work, including optical-navigation (“homing”) activities using the Long-Range Reconnaissance Imager (LORRI) to refine the probe’s course to Pluto. The team will also check out the spacecraft’s backup systems and science instruments; carry out a small course correction to trim up New Horizons’ approach trajectory and closest-approach timing at Pluto; and gather some science data by measuring the variations in Pluto’s and Charon’s brightness as they rotate.

New Horizons Position in 2 Dimensions:

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New Horizons: Solar System Distances:

 

New Horizons is placed back into electronic slumber on Aug. 29, a “rest” that lasts only until Dec. 7. “From there it will stay awake for two years of Pluto encounter preparations, operations and data downlinks,” Bowman says.  Distant-encounter operations begin Jan. 12, 2015.

“The future has finally arrived,” says New Horizons Principal Investigator Alan Stern, of the Southwest Research Institute in Boulder, Colo. “After all the time and miles in the rearview mirror, the turning of the calendar page last week to 2014 means we'll be exploring the Pluto system next year!”

The Student Dust Counter (SDC) flies aboard the New Horizons mission, a NASA mission to Pluto and the Kuiper Belt. A dust counter is an instrument that counts particles of dust in space; the SDC collects this information when grains of dust hit the instrument as it travels to Pluto.  The SDC will travel out into the solar system 40 times the distance from the Earth to the sun, or 40 astronomical units. The record-holding dust counter, on Pioneer, only measured dust to about 18 astronomical units.  As it travels to Pluto and beyond, SDC will provide information on the dust that strikes the spacecraft during its fourteen-year journey across the solar system. These observations will advance our understanding of the origin and evolution of our own solar system, as well as helping scientists study planet formation in dust disks around other stars.

Student Dust Counter

Compared to previous, similarly designed dust counters, the SDC is lighter—only 1.6 kilograms (3.5 pounds)—uses less power, and was much less expensive to develop. Stringent constraints on mass, power, and budget are part of any planetary or space mission; these characteristics help make SDC an attractive dust instrument for future missions.  The SDC has a set of detectors, about the size of an 18 x 12-inch cake pan, which detect incoming particles. The detectors are made of a plastic film called Polyvinylidine Fluoride (PVDF). The detectors are all mounted to a large piece of honeycombed aluminum, which is then bolted with aluminum feet to the New Horizons spacecraft.

A computer simulation of the density of dust throughout the solar system.

The Student Dust Counter has three main goals:

1) To map dust distribution and density. Dust is not spread evenly throughout space; it varies in density throughout the solar system.

2) To help scientists understand variation in where different-sized particles are located in the solar system.

3) To determine how fast the Kuiper Belt produces dust. The small, icy bodies in the Kuiper Belt are constantly colliding and causing little bits of each other to chip off. Through additional collisions over time, these chips are ground to dust; scientists want to understand how quickly this process happens.

The New Horizons spacecraft has a high-gain antenna that transmits scientific data about dust back to Earth as radio waves. Moving at the speed of light, it still takes the data hours to arrive at Earth. For example, from Pluto, the data will take four hours to arrive at the NASA Deep Space Network here on Earth. The Network receives the data and sends it out to the New Horizons team.

The high-gain antenna on the New Horizons spacecraft

Comparing with past mission data:

Scientists have already completed initial comparisons SDC data to existing data. The first results, published in Geophysical Research Letters, indicate that SDC measurements of dust inside 5 astronomical units agree well with the earlier measurements made by the Galileo and Ulysses missions.

Testing theories:

Scientists will not be comparing SDC data on dust further out than 18 astronomical units to other missions because such data doesn't exist. Instead, scientists will be testing their theoretical understanding of dust in the solar system, adjusting their theories to accommodate the new data.

Improving computer simulations:

Scientists will also compare the SDC data retrieved to several computer simulations of expected dust distribution and density. Computer models of the dynamics of Kuiper-Belt dust grains show that dust tends to get trapped near Neptune in sync with the planet's orbit. SDC will take data in this region so that scientists can improve their computer models with real data.

The detector panels of the SDC are being assembled in this image.

Each time a dust particle hits a detector, the electronics store five pieces of data:

1. Detector number that the dust particle hit

2. Minimum sensitivity of the detector

3. Size of the electronic pulse generated, which is turned into the particle  size using ground calibrations

4. Time of impact

5. Time of day the data was streamed to Earth

A visualization of data generated from the SDC.

After scientists receive all the data from the SDC and ensure that the instrument has worked properly, the next step is to analyze the data.  Data analysis can be difficult. If the data differs greatly from what scientists were expecting to find, they have to decide whether their instrument was wrong, or whether their theories were wrong. If the data is what was expected, scientists have to make sure they've analyzed it correctly so no bias occurs. If scientists come to the conclusion that their data are valid and good, then they determine what new information they have gained.

A team of 20 students from the University of Colorado have collaborated, designed, and built the SDC for the New Horizons Mission.