This Is About The Extraordinary Journey of One of The Greatest Human Creations- The Voyager

Every 176 years, the four planets in our outer solar system presents us with a rare opportunity. They’ll align in such a unique way, that it’s possible to

object slingshot method using gravity for probe launches

use their gravitational forces to slingshot from one planet to the next.

original news paper copy stating the possible discovery

A PhD student figured this out back in 1965 during his summer job at the Jet Propulsion Laboratory, using just a slide rule and simple computer programs. This insight became part of an ambitious mission to send two probes and golden records out into space for a grand tour.

The Voyagers took some of the first detailed snapshots of planets and moons. And after cruising for over 43 years with 18 billion kilometers traveled, they’re taking humanity into the next great beyond: interstellar space.

The Voyager probes are two obscure looking robots, weighing about 800 kilograms with giant arms and big ears designed to sense what’s out there.

engineers working on the probes

And it took 1,500 engineers and scientists to bring these robotic explorers to life.

“I started working on Voyager right out of college. It was my very first job as an engineer. “

Her “5o’ clock update on Voyager” show footage

Suzanne Dodd, Project Manger, Voyager

So, Voyagers were really developed in the early 70’s. They were launched in 1977, and the original goal was just a 4 year mission to explore the Jupiter and Saturn systems. With the possible opportunity to go further out to Uranus & Neptune, the NASA engineers developed a mission within a mission, outfitting the probes with 11 different instruments redundant systems and autonomous controls. They each also carried a golden record for a potential extraterrestrial to decipher.

stage 1 of golden record writing

That’s a time capsule of us here on Earth. And if any other being were to find it, they would know what we on Earth were like in 1977. We have liftoff of the Titan Centaur carrying the first of two Voyager spacecraft to

final snapshot of golden record

extend man’s senses farther into the solar system than ever before. As they hit each planet, the Voyagers beamed back observations of Jupiter’s turbulent atmosphere, Saturn’s moons, and Titan’s hazy layers.

“I really think that the Neptune encounter was probably the most significant thing in my career. I was involved with all the design on the closest approach sequence, I really felt like I owned what the spacecraft was going to execute. And it went flawlessly. We got a big send-off afterwards. The Planetary Society had Chuck Berry come and play because his Johnny B. Goode song is on the record. I’ll always remember that as one of the highlights of my career. If not, the highlight. “_ Suzanne Dodd

As the Voyagers cruised beyond our neighborhood, Carl Sagan convinced NASA to tell Voyager1 to flip its camera around, and take the first planetary family portrait.

The Family Photo

That’s us, 6 billion kilometers away, the pale blue dot. And that should have been the end of the mission. But to everyone’s surprise, the Voyagers kept going, entering a place no one had ever seen before, the final frontier.

“Since flying past all the planets, we turned off the instruments basically that were designed to take pictures and repurposed the memory for this long Voyager Interstellar Mission. The space beyond the planets is very empty, very dark, very cold. And as you travel further and further, you see less strength of the Sun. The heliosphere is the bubble of charged particles around our star, our Sun. They expand out, and then eventually they stop.

heliospere

And they stop due to the pressure from the interstellar medium and the wind from the interstellar medium. The interstellar medium wind is actually created by exploding stars,

A supernova simulation demonstrated in hours/sec ratio

supernova, all the other stars and material that are out there are pushing on our bubble and that is what keeps the shape of it.”_ Suzanne Dodd

In 2012, Voyager 1 started detecting changes in its immediate environment.

“We started to see dropouts in particles from the Sun, and increases in particles from the interstellar medium. They dropped down, and then they’d go back up again. And then on August 25 of 2012, they just dropped down and stayed down. And similarly, the particles from interstellar space do the opposite. They bumped up, and they stayed up.”_ Suzanne Dodd

original plasma instrument before installation

The plasma instrument on Voyager 1 wasn’t working properly, so it was hard to confirm if it really crossed the boundary.

“There was a lot of debate and by a nice coincidence there was a solar flare that happened 13 months previously. Finally reached Voyager 1, and that solar flare

actual colored picture of solar flare

excited the plasma around the spacecraft. That was when the particle instruments said, “Hey, we’re in interstellar space. We see the change in the particles.” Voyager 2 has an active working plasma science instrument. So we saw the density of the plasma change almost instantaneously.”_ Suzanne Dodd

As they travel through the interstellar medium, the sheer scale of the universe really comes into perspective.

“It’s studying the interaction of our star, our Sun, with what’s beyond it. And when you study our Sun, you’re studying the energy that’s giving us life

actual shot of earth and sun rise from space

here on Earth.”_ Suzanne Dodd

Voyager 1 detected unexpected pressure at the edge of our solar system for the first time, giving scientists clues about the dynamics we might find in other star & planetary systems. To keep data like this coming in, the Voyager Flight team has to make careful energy management decisions.

“We use a nuclear power source

Radioisotope Thermoelectric Generator

that decays at 4 watts per year, and so one of our biggest concerns now, and what will really limit the lifetime of the mission, is just how much power the spacecraft has to continue operations. We also have to pay attention to the temperature of the spacecraft. We don’t want to freeze the propellant lines that we use to keep the antenna pointed at the Deep Space Network. It’s 20 hours to get the signal from Earth to the spacecraft, and 20 hours for the spacecraft to turn around and acknowledge that they got that signal. Which really means that the Voyager spacecraft They have to be able to sense for themselves what’s going wrong, put itself in a safe state if it feels like it’s under stress.

first view of Voyager in space from ISS

Our day to day engineering activities relate toward keeping the spacecraft warm enough, making determinations of whether we have to turn off another instrument heater or not,

Instrument Diagram

and then which instrument would you turn off? All of these instruments have been on since 1977. Now these principal investigators who are in their 80’s now, they don’t want to see their instrument turn off. “_ Suzanne Dodd

The Voyager engineers are still manning this mission today until the signals eventually stop.

“One day we’ll come in to the office, and it won’t be there. And that will be the loss of the spacecraft. And that will be a very sad day but also one where you can reflect on how great the mission was. I think Voyager has touched humanity in many ways. And I think that connects us, as humans, to space exploration.”_ Suzanne Dodd

GALLERY:

The Golden Being Placed on Voyager 1

Officially released shot of Voyager 2 under development

The Golden records 1 year before the launch

A letter to Chuck Berry About his Song is going to live for ever through this Golden Record

The very first SLR shot from ISS of Voyager 2

Suzanne Dodd, Before this interview(september, 2019)

Original copy of the record on earth

Chuck Berry’s “ Johnny B. Goode” performance in the success party

The Voyager Prototype

Images Voyager took of Jupiter

Jupiter and two moons

Jupiter’s ring

Jupiter’s great red spot

Jupiter’s moon Io with active volcanoes

portion of Jupiter and moons

Images Voyager Took of Saturn

First look of Saturn by Voyager 2

False-color view of Saturn

The ring and moons

Saturn’s Northern Hemisphere.Aug.19, 1981. Range 4.4 million miles

Enhanced Image. Saturn’s clouds. Photo Nov. 5, 1980. Range 8 million Km.

Saturn’s C-ring with many ringlets. Flase-color image. Aug. 23, 1981

Saturn’s rings. Color variations indicate different chemical composition

Saturn’s rings with “spoke&aquote;features in B-ring. Aug. 22, 1981. 2.5 million miles”

F-rings. Two braided separate orbit rings. Photo Nov. 12, 1980. Range 750,000Km.

Moon Titan and thick haze. Photo Nov. 12, 1980. Range 435,000 Km

Saturn’s Moon Enceladus. 310 miles in diameter. Aug. 25, 1982. 74,000 miles.

Images Voyager Took of Uranus

Uranus’s Moon Miranda

Uranus’s Outermost Ring

False-color view of Uranus

Backlit View shows continuous distribution of the fine particles throughout the ring system. Jan 24, 1986

Three of the moons discovered by Voyager 2

Ture-color(left) and False-color views of Uranaus. Jan 17, 1986

Images Voyager Took of Neptune

Voyager image of Neptune

Neptune’s ring

Parting view of Neptune and moon Triton

Neptune’s moon Triton

False-color image of Neptune

Cloud system in Neptune’s Southern hemisphere

Neptune’s Great Dark Spot, accompanied by white high-alttitude clouds

Triton’s south polar terrain. About 50 dark plumes mark what may be ice volcanos

Details of Neptune’s rings

Triton from 80,000 miles. Long feature is probably a narrow down-dropped fault block.

High resolution color mosaic of Triton

Great Dark Spot. This storm system rotates counterclockwise.