What was Amelia Earhart's goal in 1937?

Amelia Earhart aimed to become the first female pilot to fly around the world.

How was Earhart's route different from others?

Earhart chose a longer Equatorial route rather than the shorter northern route that others had taken.

What error was made with radio communication?

There were miscommunications about frequencies between Earhart and the Itasca, along with a failure to utilize lower frequencies for directional finding.

What was the role of the support ships during her flight?

Support ships were deployed to assist with navigation by sending directional signals, but due to various communication mishaps, they could not effectively help.

What could have potentially saved Earhart?

Switching the radio receiver setting to pick up lower frequency signals might have guided her safely to Howland Island.

Why was Earhart's final destination difficult to find?

Howland Island is a very small speck in the Pacific Ocean, making it extremely challenging to spot without precise navigation.

What lesson does the video emphasize from Earhart's tragedy?

The importance of both knowledge and responsibility to prevent disasters in challenging tasks like aviation.

The Real Reason Amelia Earhart’s Plane Crashed

00:36:35

https://www.youtube.com/watch?v=zTDFhWWPZ4Q

Ringkasan

TLDRThe video explores the tragic last flight of Amelia Earhart in 1937, emphasizing how her lack of knowledge in physics and radio navigation led to her disappearance. The video hypothesizes that had Earhart toggled a specific radio switch, it might have saved her life. It covers how Earhart attempted to become the first female pilot to circumnavigate the globe, detailing the meticulous yet flawed planning involving navigation and radio communication. Despite exhaustive preparations, a series of miscommunications, technical failures, and a lack of thorough understanding of radio waves resulted in Earhart's final tragic message before disappearing over the Pacific. Emphasis is also placed on the importance of knowledge and responsibility in overcoming challenges, suggesting that greater communication understanding might have altered history.

Takeaways

🚀 Amelia Earhart aimed to be the first female pilot to fly around the world.
🎯 She chose a new, longer Equatorial route.
🗺️ Navigating the vast Pacific Ocean posed significant challenges.
📡 Radio communication was critical but failed due to technical issues.
⏳ Earhart missed relay signals that were crucial for navigation.
🚢 Support ships were not enough to assist due to miscommunication.
🔋 Knowledge gaps in radio technology contributed to her fate.
🗣️ Effective two-way communication was lacking on the Electra.
🔍 Mismanagement of resources and incorrect planning led to her demise.
📚 The tragedy underscored the need for knowledge and responsibility in challenging endeavors.

Garis waktu

00:00:00 - 00:05:00
Amelia Earhart faced navigational troubles over the Pacific Ocean in 1937, exacerbated by a series of avoidable decisions due to a lack of physics knowledge. To maximize flight range, she stripped her plane of unnecessary weight, converting it into a flying gas can to cover the long distance across the Pacific, relying on the small Howland Island as a refueling stop.
00:05:00 - 00:10:00
Earhart lobbied successfully for a runway on Howland Island, showcasing her connections and determination. Navigational strategies included dead reckoning and celestial navigation, complicated by a stronger than expected headwind. Communication breakdowns with the ground highlighted dangers of her daring flight path near the Equator.
00:10:00 - 00:15:00
The radio technology of the time, key for navigation, faced challenges. Earhart's equipment aimed to use radio signals to triangulate her location but was hindered by technical and procedural issues. Miscommunications about signal frequencies and equipment capabilities further complicated navigation.
00:15:00 - 00:20:00
An experiment demonstrates radio wave direction finding using simple antennas. The inability to properly triangulate signals due to outdated or misaligned equipment was a critical flaw in Earhart's plan, illustrating the technological limitations and the complexity involved in aerial navigation of that era.
00:20:00 - 00:25:00
Earhart anticipated using radio signals to navigate close to Howland Island. However, miscommunication about signal frequencies and time zones with the Itasca led to missed connections. Equipment limitations and misunderstanding contributed significantly to the navigational failure.
00:25:00 - 00:30:00
Technical and administrative oversights coupled with Earhart's misunderstanding of her equipment capabilities resulted in a failed navigation attempt to Howland Island. Suggestions that her equipment could have been mishandled underline the importance of aligning knowledge with responsibility during such missions.
00:30:00 - 00:36:35
Amelia Earhart's tragic flight highlighted the need for deep technical understanding and effective communication in challenging expeditions. Even with adequate knowledge, the absence of clear responsibilities and procedural oversight turned small errors into a catastrophic event, depicted through the lens of KiwiCo's project-like endeavor in engaging with scientific curiosity and learning.

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Video Tanya Jawab

What was Amelia Earhart's goal in 1937?
Amelia Earhart aimed to become the first female pilot to fly around the world.
What factors contributed to Earhart's disappearance?
Her disappearance was largely due to miscommunications, technical failures, and a lack of thorough understanding of radio navigation.
How was Earhart's route different from others?
Earhart chose a longer Equatorial route rather than the shorter northern route that others had taken.
What error was made with radio communication?
There were miscommunications about frequencies between Earhart and the Itasca, along with a failure to utilize lower frequencies for directional finding.
What was the role of the support ships during her flight?
Support ships were deployed to assist with navigation by sending directional signals, but due to various communication mishaps, they could not effectively help.
What could have potentially saved Earhart?
Switching the radio receiver setting to pick up lower frequency signals might have guided her safely to Howland Island.
Why was Earhart's final destination difficult to find?
Howland Island is a very small speck in the Pacific Ocean, making it extremely challenging to spot without precise navigation.
What lesson does the video emphasize from Earhart's tragedy?
The importance of both knowledge and responsibility to prevent disasters in challenging tasks like aviation.

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Teks

Gulir Otomatis:

00:00:00
- [Derek] As the sun rose on July 2nd, 1937,
00:00:04
Amelia Earhart knew she was in trouble.
00:00:07
Over the radio, she called,
00:00:09
"We must be on you but cannot see you.
00:00:11
Gas is running low.
00:00:13
Been unable to reach you by radio.
00:00:15
We are flying at 1,000 feet."
00:00:18
Beneath her was water
00:00:20
in every direction as far as the eye could see.
00:00:24
She got herself into this predicament
00:00:26
through a series of unfortunate events and bad decisions.
00:00:30
Many of them could have been avoided
00:00:32
with a better knowledge of physics.
00:00:35
But even so,
00:00:36
there was one thing she could have done in this moment,
00:00:39
one switch she could have flipped
00:00:41
that would likely have saved her life and changed history.
00:00:48
This video is sponsored by KiwiCo.
00:00:50
More about them at the end of the show.
00:00:54
Amelia Earhart was vying to become the first female pilot
00:00:57
to fly around the world.
00:00:58
- I hope to accomplish something
00:01:00
really scientifically worthwhile for aviation.
00:01:04
- And she wasn't taking any shortcuts.
00:01:06
Other successful circumnavigations
00:01:08
had followed a northern route,
00:01:10
mostly staying close to land.
00:01:13
But Earhart's route would be the longest
00:01:15
by following a path close to the Equator.
00:01:19
This meant the last part of her journey was the hardest,
00:01:23
crossing the full width of the Pacific Ocean.
00:01:26
The starting point for this crossing was Lae,
00:01:29
a city on the eastern side of New Guinea.
00:01:32
At the time, it was one of the world's busiest airports,
00:01:35
a hub of traffic from Asia and Australia.
00:01:39
At 10:00 a.m. on a hot July day,
00:01:41
Earhart piloted her Lockheed Electra down the runway
00:01:44
and took off on what would be her final flight.
00:01:52
The Pacific Ocean is huge.
00:01:55
It's way bigger than the Atlantic.
00:01:57
I mean, if you look at the globe from that side,
00:02:00
you see almost no land.
00:02:02
The problem was, in 1937,
00:02:05
most planes could only fly a maximum
00:02:07
of a few thousand kilometers,
00:02:10
so Earhart removed everything unnecessary from her plane.
00:02:14
She ripped out the insulation to reduce weight,
00:02:17
but that made the engine noise so overwhelming
00:02:20
she had to communicate with her navigator
00:02:22
sitting right beside her
00:02:23
using written notes.
00:02:26
She packed almost nothing, telling her husband,
00:02:29
"Extra clothes and extra food
00:02:31
would have been extra weight and extra worry."
00:02:34
She replaced the passenger seats with fuel tanks,
00:02:38
effectively turning her plane into a flying gas can.
00:02:42
But even so, the Electra's maximum range
00:02:45
was between 6,600 and 7,200 kilometers in perfect weather.
00:02:50
It could be just enough to reach Hawaii from Lae,
00:02:53
or she might come up disastrously short.
00:02:58
So Earhart needed a place to stop and refuel along the way.
00:03:03
Now, it might seem like there's no land here,
00:03:05
but if you zoom in,
00:03:07
there is this tiny island
00:03:09
halfway between Australia and Hawaii.
00:03:12
Howland Island is just over two kilometers long
00:03:16
and less than one kilometer wide.
00:03:18
The US had claimed it
00:03:20
as part of the Guano Islands Act of 1856.
00:03:22
But in 1937, it was barely inhabited
00:03:25
with just a handful of colonists.
00:03:28
It would be an ideal location to refuel,
00:03:31
if only it had a runway.
00:03:34
Fortunately for Earhart,
00:03:35
by the time of her around the world flight,
00:03:37
she was already famous.
00:03:40
In 1928, she became the first female passenger
00:03:43
to cross the Atlantic by airplane.
00:03:45
This made her an international celebrity.
00:03:48
- [Announcer] She said she could, and she did it.
00:03:50
(lively music)
00:03:54
- [Derek] But she wanted to fly herself, saying,
00:03:57
"Maybe someday I'll try it alone."
00:03:59
So, in 1932,
00:04:01
she attempted to pilot a plane solo across the Atlantic
00:04:05
heading for Paris.
00:04:06
She brought with her only a toothbrush,
00:04:08
one container of soup and three cans of tomato juice.
00:04:12
(thunder booms)
00:04:15
But storms, ice, and dense fog battered her small plane.
00:04:20
A seam in the exhaust manifold cracked
00:04:22
and flames from the engine spewed out into the night.
00:04:26
Gas leaked down her neck from a broken tank,
00:04:29
and after 14 hours,
00:04:30
she landed in a pasture in Northern Ireland.
00:04:33
Her face was so covered in grease,
00:04:35
a farmhand couldn't tell if she was a man or a woman.
00:04:39
He asked if she had flown far.
00:04:41
"From America," she replied.
00:04:44
- I wish I could have done it faster.
00:04:46
- [Derek] These adventures brought her
00:04:48
into the orbits of powerful people,
00:04:50
like the First Lady, Eleanor Roosevelt.
00:04:52
- And Mrs. Roosevelt,
00:04:53
won't you go for a ride tonight over Washington?
00:04:56
It's really lovely from the air at night.
00:04:58
- And using her new connections,
00:05:00
she lobbied the president to hire her friend, Eugene Vidal,
00:05:03
to head the Bureau of Commerce.
00:05:05
Vidal had promised Earhart a runway on Howland Island,
00:05:09
but red tape stalled progress
00:05:11
only months before her planned takeoff.
00:05:14
So Earhart wrote directly to President Roosevelt.
00:05:18
She explained that the airstrip funds
00:05:19
required immediate approval,
00:05:21
writing, "Please forgive troublesome female flyer
00:05:24
for whom this Howland Island project is key
00:05:27
to world flight attempt."
00:05:29
The president approved the project four days later,
00:05:32
and three runways were soon cleared.
00:05:37
So she had a place to land,
00:05:39
but how would she find this tiny speck of an island
00:05:43
in a vast ocean?
00:05:46
Well, flying with her in the Electra
00:05:48
was her navigator, Fred Noonan,
00:05:50
and he would calculate the flight plan.
00:05:53
They knew the direction of Howland,
00:05:55
so they could use the onboard compass
00:05:57
to set their bearing toward it.
00:05:59
They knew their air speed
00:06:00
and could figure out their ground speed
00:06:02
by subtracting or adding the wind,
00:06:05
and then they could calculate how long it should take
00:06:07
to reach the island.
00:06:09
This method is known as dead reckoning.
00:06:13
But they wouldn't aim directly at the island,
00:06:15
because if they did that
00:06:16
and they didn't see it at the prescribed time,
00:06:19
they wouldn't know in which direction they were off.
00:06:22
So instead, they intentionally picked a point
00:06:25
either north or south of the island.
00:06:27
Let's say they picked south.
00:06:29
They estimated the trip would take 18 hours,
00:06:32
so they would fly through day and night.
00:06:36
And once they had traveled
00:06:37
for the calculated length of time,
00:06:39
they could confidently turn north and spot the island.
00:06:44
Before takeoff, the ground crew estimated
00:06:46
they would encounter a headwind of 24 kilometers per hour.
00:06:50
But just 20 minutes after takeoff,
00:06:52
Lae radioed Earhart to warn
00:06:54
that the headwinds would be stronger.
00:06:56
She didn't acknowledge their message.
00:07:00
Knowing the correct wind speed was critical
00:07:02
because it would affect how long it would take
00:07:04
to reach the island.
00:07:05
If it took longer, Earhart would have to turn later.
00:07:08
So she couldn't rely on dead reckoning alone
00:07:11
to reach Howland.
00:07:14
As an independent check on their location,
00:07:16
Noonan would take measurements of the sun, moon, and stars.
00:07:20
This is known as celestial navigation.
00:07:24
He had an almanac that listed 58 navigation stars
00:07:27
and the point on Earth each one would be directly overhead
00:07:31
for the day and time of his measurement.
00:07:34
If they found themselves directly under a navigation star,
00:07:37
well, then they would immediately know their position.
00:07:40
But generally they would not be that lucky,
00:07:43
so Noonan would measure the angle above the horizon
00:07:46
to a navigation star
00:07:48
and use that to work out how far away they were
00:07:51
from the point on the Earth
00:07:53
where that star would be directly overhead.
00:07:55
So he could trace out a circle on the globe
00:07:58
of possible locations,
00:08:00
and then he would measure the angle
00:08:01
to another navigation star
00:08:03
and draw out a second circle.
00:08:06
And now they must be
00:08:07
at one of these two circle intersections.
00:08:11
Normally the circles were so large
00:08:13
that only one of the intersections
00:08:14
would be a plausible position.
00:08:17
That way they could continually update their location
00:08:20
and adjust bearings as needed.
00:08:22
But even with celestial navigation,
00:08:24
errors could accumulate over long trips.
00:08:27
Earlier in the journey, when Earhart crossed the Atlantic,
00:08:30
they missed their intended airport in hazy conditions.
00:08:34
Noonan's calculations were reasonable,
00:08:36
but small errors put them off course.
00:08:39
Luckily, in Africa,
00:08:40
there were plenty of other places to land safely.
00:08:43
The same could not be said for Howland.
00:08:48
So, for the flight across the Pacific,
00:08:50
Earhart commandeered three US Navy and Coast Guard ships.
00:08:54
The Itasca would be stationed at Howland Island,
00:08:57
the Ontario would be halfway along the route,
00:09:00
and the Swan was positioned midway
00:09:02
between Howland and Hawaii.
00:09:05
The Itasca would send out smoke signals
00:09:07
as Earhart approached to help her spot the island.
00:09:11
But even more importantly,
00:09:12
all ships were equipped with radio.
00:09:16
Now, in 1937, radio was still fairly new tech.
00:09:20
German physicist Heinrich Hertz discovered radio waves
00:09:23
in the late 1880s.
00:09:24
He excited electrons to oscillate back and forth
00:09:27
in his transmitter,
00:09:29
and a few meters away his receiver was a loop of wire
00:09:32
with a small gap in it.
00:09:34
When Hertz looked at it through a microscope in the dark,
00:09:37
he saw faint sparks jumping across the gap.
00:09:41
The sparks were strongest when the receiving loop was flat.
00:09:44
If it was vertical, then no sparks were observed.
00:09:48
This demonstrated that radio waves are transverse waves
00:09:51
with electric and magnetic fields
00:09:53
oscillating perpendicular to each other
00:09:56
and perpendicular to the direction of the wave motion.
00:09:59
When the receiving loop was aligned
00:10:01
with the direction the wave was traveling,
00:10:03
the changing magnetic field through the loop
00:10:05
induced an EMF that created the spark.
00:10:08
But if the loop was facing the transmitter,
00:10:11
then there was no change in magnetic flux through the loop,
00:10:14
and so no spark was observed.
00:10:18
Now, Hertz couldn't see the future he had ushered in.
00:10:21
He said, "I do not think
00:10:23
that the wireless waves I have discovered
00:10:25
will have any practical application."
00:10:28
But within a few years,
00:10:29
people started sending messages using radio.
00:10:32
And by the 1920s, radio entertainment broadcast took off.
00:10:36
Ships and planes routinely used radio to send Morse code,
00:10:39
and some, including Earhart,
00:10:41
could send and receive voice messages.
00:10:46
In fact, Earhart had five radio antennas around the plane,
00:10:50
each for a specific purpose.
00:10:52
The largest antenna could be reeled in and out
00:10:55
like a fishing line behind the plane.
00:10:57
It was 76 meters long,
00:10:59
which was necessary
00:11:00
to efficiently send and receive Morse code
00:11:03
via the 4 or 500 kilohertz radio waves
00:11:06
used by ships and remote stations.
00:11:09
Ideally, an antenna should be at least 1/4 of the wavelength
00:11:12
of the radio wave it's transmitting or receiving.
00:11:15
This improves the efficiency
00:11:16
of the conversion from electrical energy
00:11:19
to radiated electromagnetic energy.
00:11:22
Earhart's trailing antenna
00:11:23
was only around 1/8 of the wavelength.
00:11:26
But it was connected to a high-power transmitter,
00:11:29
so its signals could still be detected
00:11:31
over 1,000 kilometers away.
00:11:33
Next were two antennas for voice communications
00:11:36
on higher frequencies.
00:11:38
A transmitting V antenna on the roof of the plane
00:11:40
and a receiving antenna along its belly.
00:11:44
Higher frequencies were useful for two reasons.
00:11:47
First, they require smaller antennas,
00:11:49
which save weight and can be better accommodated
00:11:52
on small sparse planes.
00:11:54
And second, high frequency radio waves
00:11:56
can travel long distances
00:11:58
by bouncing off a layer of the atmosphere
00:12:00
called the ionosphere.
00:12:02
Starting about 50 kilometers above Earth's surface,
00:12:05
radiation from the Sun splits electrons off molecules
00:12:09
forming a layer of ions and free electrons.
00:12:12
Radio waves with certain frequencies
00:12:15
interact with these free electrons
00:12:16
and are effectively reflected back to Earth.
00:12:19
It's as if they've bounced off
00:12:21
a big wobbly mirror in the sky.
00:12:24
This effect is called skipping
00:12:26
and it scatters radio waves all over the place.
00:12:29
These radio waves can then reflect off the ocean
00:12:32
and back off the ionosphere,
00:12:34
making multiple hops to travel thousands of kilometers.
00:12:39
During the daytime,
00:12:39
the intense radiation from the sun
00:12:41
means the ionosphere starts lower in denser atmosphere.
00:12:45
And because of this,
00:12:46
lower frequency radio waves are more likely
00:12:49
to be absorbed than reflected.
00:12:51
So aviators would typically use the higher 6210 kilohertz
00:12:55
to skip their signals during the day,
00:12:57
and then the lower 3105 kilohertz at night
00:13:00
once the bottom of the ionosphere had lifted
00:13:02
into thinner air.
00:13:07
Four hours after takeoff,
00:13:08
Earhart radioed an update to Lae
00:13:10
on her daytime frequency of 6210.
00:13:13
She reported her altitude at 7,000 feet
00:13:16
and speed at 140 knots
00:13:18
before concluding with
00:13:19
her typical sign-off, "Everything okay."
00:13:23
But she never acknowledged calls from Lae
00:13:25
about the headwind.
00:13:26
They radioed again at 11:20 and 12:20,
00:13:30
but never got a response from Earhart.
00:13:33
In all likelihood, she never heard them.
00:13:36
She did radio six hours into her flight
00:13:38
to report stronger headwinds,
00:13:40
but she makes no mention of Lae's earlier warnings.
00:13:44
It's possible the receiving belly antenna
00:13:46
was broken, fell off,
00:13:48
or something in the receiving electronics wasn't working.
00:13:52
But her ability to receive voice messages
00:13:55
was clearly impaired.
00:13:58
Nine hours into the flight,
00:13:59
Earhart expected to come upon the Ontario.
00:14:03
She listened for Morse code Ns on 400 kilohertz,
00:14:07
but she heard nothing.
00:14:11
The original plan was
00:14:13
that the Ontario would wait for her to radio them
00:14:16
to request that they start transmitting.
00:14:18
But the day before takeoff,
00:14:20
Earhart realized she had made a mistake.
00:14:23
The Ontario had told her
00:14:25
they wouldn't be able to receive any high frequency signals,
00:14:28
which meant no voice communication.
00:14:31
So she sent an urgent telegram asking the Ontario
00:14:34
to transmit the Morse code Ns repeatedly
00:14:37
10 minutes after each hour.
00:14:41
The purpose of the Morse code from the Ontario
00:14:44
was actually to allow Amelia Earhart
00:14:46
to make use of her two final antennas.
00:14:48
So she had a loop antenna just like this one
00:14:52
and a sense antenna.
00:14:54
These were designed to allow her
00:14:55
to locate the source of radio waves.
00:14:58
This was the final and most critical way
00:15:00
that Earhart planned to stay on course
00:15:02
and locate Howland Island.
00:15:04
She wrote, "I doubt if I'd try the flight
00:15:06
to tiny Howland Island
00:15:07
without it supplementing Fred Noonan's skill."
00:15:11
Woo. Alright, so I have an antenna here
00:15:16
and I'm aligning it vertically in this tree.
00:15:18
How are we, how are we there?
00:15:20
So the Ontario was sending out Morse code signals
00:15:23
on their antenna,
00:15:25
and here we have a transmitter tuned to about 3.6 megahertz.
00:15:29
I'm gonna put on this blindfold
00:15:32
and use the loop antenna to try to locate the transmitter.
00:15:37
And because I already know where the transmitter is,
00:15:38
we'll spin me around a few times to really disorient me.
00:15:41
So, Clifford. Oh, sorry.
00:15:43
- [Clifford] Oh, which way are you going?
00:15:47
- Alright. Whoa, I'm a bit dizzy.
00:15:51
So the radio waves are gonna be emitted in all directions
00:15:56
radially away from the antenna,
00:15:57
the electric field will be oscillating up and down,
00:16:00
and the magnetic field will be oscillating back and forth.
00:16:04
So if I hold up this loop like this
00:16:08
sort of parallel to the direction
00:16:10
that the waves are traveling,
00:16:12
then the magnetic field is gonna be changing
00:16:14
through the loop.
00:16:15
And because of that,
00:16:16
it's going to create an EMF and current
00:16:18
and I can pick that up
00:16:20
because I'm tuned to the right frequency here.
00:16:23
So I got a fairly strong signal.
00:16:24
Woo, it's very strong.
00:16:27
But if I rotate the loop like that,
00:16:29
well, now the magnetic field is oscillating back and forth
00:16:32
but not changing through the loop itself
00:16:34
because it's parallel to the loop.
00:16:36
And so, in this orientation, I'm gonna get a null reading.
00:16:40
If I turn it this way, there's a null.
00:16:44
But if you turn it 90 degrees,
00:16:47
now all the magnetic field is passing through this loop
00:16:50
and so I can hear a maximum here.
00:16:53
So this is what Earhart wanted to measure
00:16:55
using her loop antenna
00:16:56
to detect the repeated N Morse code from the Ontario.
00:17:00
She would turn it until she found the null
00:17:03
and then she would know the direction to the ship.
00:17:06
Something that's interesting is, if I turn it away,
00:17:10
we get another null because again
00:17:12
there's no magnetic flux passing through this loop.
00:17:16
Now, the first time she picked up the signal,
00:17:18
she would probably be heading straight towards the ship
00:17:22
or close enough,
00:17:23
so she would know that it's roughly that way.
00:17:27
But there's a chance that she's gone past it.
00:17:30
And if you go past it, well, then you also get a null,
00:17:33
but the ship is behind you, not in front of you.
00:17:36
So that's where the sense antenna comes in.
00:17:38
The sense antenna gives you a cardioid pickup pattern
00:17:41
so it has a single null instead of two nulls,
00:17:44
and so that allows you to determine
00:17:46
whether it is in front or behind you.
00:17:49
- [Clifford] If you walk a bit,
00:17:50
you'll know if it's getting weaker or stronger.
00:17:53
- Alright, I feel like I've picked the wrong direction.
00:17:57
I'll try the sense antenna to see if I can figure it out.
00:18:01
With the sense antenna,
00:18:03
the only null points directly away from the transmitter,
00:18:06
so it's easy to use the sense antenna
00:18:09
to check which null is correct
00:18:11
but then only use the loop when navigating
00:18:13
because it gives a sharper null.
00:18:15
I think using the sense antenna
00:18:17
that the transmitter's right in front of me now.
00:18:22
I'm looking for another null here.
00:18:25
Oh, there's a null.
00:18:29
- [Clifford] Give it a go.
00:18:32
- There, there. Definitely louder, louder.
00:18:39
Oh, it's funny 'cause you move a little bit
00:18:43
and then you start hearing signal again.
00:18:46
This does not feel like I'm walking in the right direction.
00:18:48
- [Clifford] Well, that's either the right way to go
00:18:49
or it's the wrong way to go.
00:18:51
- Oh no. (Clifford laughs)
00:18:52
- Trying to fly a plane and do this would be very hard,
00:18:56
especially with the sound of that engine
00:18:59
would have been roaring.
00:19:03
Oh, I feel like it's getting loud.
00:19:07
It's really loud here.
00:19:09
It drops out right there.
00:19:11
I mean, there's a null here.
00:19:13
And I was convinced this was the right way.
00:19:16
Yeah, this is a clear null right here.
00:19:21
Whoa. Loud, loud, loud.
00:19:24
I feel like I've gotta be close.
00:19:26
(antenna humming)
00:19:30
It's gotta be like right here.
00:19:33
Whoa! Ah! (laughs)
00:19:37
This worked amazingly well.
00:19:39
I had no idea I was that close, that's impressive.
00:19:43
- On the nail. - That's awesome.
00:19:46
Now, aviators could have used where the signal is loudest
00:19:49
and try to go in that direction,
00:19:52
but it's actually easier to get a precise null,
00:19:55
a point where the signal drops out.
00:19:57
The loud section could range for quite a distance
00:20:01
and so you wouldn't really know where it is,
00:20:03
but the null is more precise
00:20:04
so that's why they would look for the point
00:20:06
where the signal drops out.
00:20:08
If Earhart could hone in on the Ontario
00:20:10
using her radio direction finding loop,
00:20:12
that would ensure she was on course
00:20:14
and eliminate any navigation errors
00:20:16
that may have occurred to that point.
00:20:19
But her telegram asking the Ontario
00:20:21
to transmit 10 minutes after each hour
00:20:24
didn't make it to the ship in time.
00:20:26
And since Earhart couldn't talk to the Ontario,
00:20:29
they never sent out any signals.
00:20:32
So they passed like ships in the night.
00:20:37
By this point, Earhart was around halfway to Howland.
00:20:40
With no other landing strips within 1,000 kilometers,
00:20:44
she would have to find the tiny island or return to Lae now.
00:20:48
But multiple delays had already plagued her journey.
00:20:53
In fact, this was not Earhart's first attempt
00:20:55
to fly around the world.
00:20:57
Earlier that year, in March of 1937,
00:21:00
she had taken off from California for Hawaii,
00:21:03
heading west instead of east.
00:21:06
On board were Fred Noonan
00:21:07
and another crew member, Harry Manning.
00:21:11
As a Merchant Marine captain,
00:21:12
he was an expert in radio, Morse code,
00:21:15
and traditional navigation.
00:21:17
He was also a pilot.
00:21:20
The flight to Hawaii was successful
00:21:22
thanks in part to Manning using the loop antenna
00:21:25
to hone in on a radio beacon on the destination island.
00:21:31
Three days later, the trio set off for Howland Island.
00:21:35
But just as they were taking off,
00:21:36
the plane drifted to the right.
00:21:38
Earhart corrected by throttling back the left motor,
00:21:41
but it was too much.
00:21:43
The plane turned to the left
00:21:44
and the right wing dipped down.
00:21:46
Going up on one wheel, the right landing gear collapsed,
00:21:49
then the left.
00:21:51
The plane skidded out on its belly,
00:21:53
spinning around to face the way it had come.
00:22:01
Thankfully, no one was hurt,
00:22:03
but the Electra took months to repair.
00:22:06
And during that time, the seasonal winds shifted.
00:22:09
So, on her next attempt,
00:22:10
Earhart would have to fly east instead of west.
00:22:13
And most importantly, Captain Manning left the crew.
00:22:18
Officially, the press reported
00:22:19
that he needed to return to the Merchant Marines,
00:22:22
but rumors spread that he had lost confidence in Earhart,
00:22:25
or that Earhart believed
00:22:27
Noonan was a better navigator than Manning
00:22:29
and she could operate the radio on her own.
00:22:32
Whatever the case,
00:22:33
when Earhart took off again three months later,
00:22:35
she was accompanied only by Noonan.
00:22:40
And now they had made it 80% of the way around the world.
00:22:44
And in the dark of night,
00:22:46
Earhart had to make the critical decision
00:22:48
whether to keep going or turn back.
00:22:51
The lack of signal from the Ontario
00:22:53
must have been concerning,
00:22:54
but maybe they never got her telegram.
00:22:57
And she knew that at Howland,
00:22:59
the Itasca would be transmitting the letter A
00:23:02
over Morse code every half hour,
00:23:04
even if they didn't hear from her.
00:23:06
And they could send and receive voice signals.
00:23:09
They promised to be ready
00:23:11
on a range of different frequencies.
00:23:13
So she flew on.
00:23:17
Around 6:15 a.m. local time,
00:23:19
radiomen aboard the Itasca heard Earhart clearly.
00:23:23
"Please take a bearing on 3105.
00:23:25
We'll whistle into the mic.
00:23:27
We are about 200 miles out."
00:23:29
She then began to whistle.
00:23:33
But the men were confused.
00:23:35
They expected Earhart to take a bearing on them,
00:23:38
not the other way around.
00:23:40
And while they had told her
00:23:41
that they had radio direction finding equipment,
00:23:44
the signal needed to be lower frequency,
00:23:46
between 270 and 550 kilohertz.
00:23:50
Her voice frequency would skip off the ionosphere
00:23:53
and reflect off the ocean,
00:23:55
scattering in all directions.
00:23:57
So there would be no way to find a null
00:23:59
because the signal would be coming
00:24:01
literally from everywhere.
00:24:04
In the Electra, Earhart heard only static.
00:24:09
By now, she must have been worried
00:24:11
that they hadn't heard anything from either ship.
00:24:13
Almost blind from the rising sun
00:24:16
and deaf from the roar of the engines,
00:24:18
Earhart twisted the radio dial,
00:24:20
listening for Itasca's response. Nothing.
00:24:27
She may have expected Howland
00:24:29
to have a high frequency radio direction finder
00:24:31
called an Adcock antenna array.
00:24:34
These systems solve the skipping problem
00:24:36
with five vertical antennas
00:24:37
at the corners and center of a square.
00:24:40
The direction of the radio wave
00:24:42
can be calculated from the slightly different arrival times
00:24:45
and signal strengths at each antenna.
00:24:48
But these antennas were massive,
00:24:50
so they were really only installed at larger airports.
00:24:55
Now, as it happens,
00:24:56
there was a portable high frequency radio direction finder
00:24:59
on Howland Island,
00:25:01
but the operator reported that Earhart's transmissions
00:25:03
didn't last long enough for him to take a bearing.
00:25:06
And trying to conserve his low battery,
00:25:09
he missed parts of the later transmissions.
00:25:13
Around 6:45, Earhart again asked them
00:25:15
to take a bearing on 3105 kilohertz
00:25:18
and report back in a half hour.
00:25:20
But a bearing taken now and reported back in a half hour
00:25:23
would be at best outdated and at worst misleading.
00:25:28
This confusion likely had to do with time zones.
00:25:32
Earhart was using Greenwich Civil Time,
00:25:35
but the Itasca set their clocks to their current position
00:25:38
which was GCT -11.5 hours.
00:25:41
And to make matters worse,
00:25:43
Howland Island used Hawaii Time,
00:25:45
which back in those days was GCT -10.5 hours.
00:25:50
So the three parties attempting a rendezvous
00:25:52
on a tiny island in the middle of the Pacific
00:25:55
were on three different time zones.
00:25:57
And crucially, Earhart's hours didn't even line up
00:26:01
with the others.
00:26:02
Earhart told the Itasca she would be using GCT,
00:26:05
but somehow it never made it to the radiomen.
00:26:10
So, when the Itasca heard Earhart's request,
00:26:12
it was 6:45 a.m.
00:26:14
But in the cockpit, it was 6:15 p.m.
00:26:17
So Earhart likely didn't say "in a half hour"
00:26:20
but "on the half hour,"
00:26:22
which for her was only 15 minutes away.
00:26:25
And also it was a prearranged time
00:26:27
that Earhart would be listening for them.
00:26:30
Earhart was careful to set times she would transmit
00:26:33
and times she would listen for the ship
00:26:35
because she could only power one antenna at a time.
00:26:39
And the ships used the same antenna
00:26:42
for receiving and transmitting,
00:26:43
so if they both broadcasted at the same time,
00:26:46
they would miss each other's messages.
00:26:48
If Earhart sent another message
00:26:50
at a quarter after the hour,
00:26:52
the Itasca blocked it with their own message.
00:26:54
"Cannot take a bearing on 3105 very good.
00:26:58
Please send on 500, or do you wish to take a bearing on us?
00:27:01
Go ahead please."
00:27:03
There was no response.
00:27:05
But she couldn't transmit on 500 kilohertz anyway
00:27:08
because she had removed the long trailing antenna
00:27:11
that could transmit lower frequencies.
00:27:13
Since it could only be used for Morse code,
00:27:16
something neither she nor Noonan
00:27:17
were particularly well versed in,
00:27:19
she saw it as dead weight after Manning left.
00:27:22
So, after the Hawaii crash, it was removed during repairs.
00:27:26
So she had no way of sending radio waves
00:27:29
that would allow the Itasca to take a bearing on her.
00:27:33
But she could take a bearing on the Itasca
00:27:36
using her loop antenna,
00:27:38
if they sent her the right frequency.
00:27:41
Before the trip, the Itasca had asked Earhart
00:27:43
to specify the frequency they should broadcast.
00:27:46
Earhart was unsure,
00:27:47
so she consulted a radio expert in Lae
00:27:50
and they recommended the Itasca send Morse code A,
00:27:53
just repeated dot dashes,
00:27:55
on the half hour at 750.
00:27:58
But at that time it was typical to talk about radio waves
00:28:01
using their wavelength,
00:28:02
so the expert had meant 750 meters or 400 kilohertz.
00:28:07
But Earhart made a terrible mistake
00:28:10
relaying this plan to the Itasca.
00:28:12
She requested the signal be sent on 7,500 kilohertz
00:28:16
instead of 750 meters or 400 kilohertz.
00:28:20
But she did explicitly say,
00:28:23
"If frequencies mentioned unsuitable, inform me."
00:28:27
But no one ever corrected her.
00:28:31
At 7:42 a.m.,
00:28:33
Earhart's voice came through so loud
00:28:36
men even went above deck to see if they could hear a motor
00:28:39
or spot the plane.
00:28:41
She said, "We must be on you but cannot see you.
00:28:45
But gas is running low.
00:28:46
Been unable to reach you by radio.
00:28:49
We are flying at 1,000 feet."
00:28:51
On Howland, the high frequency radio direction finder
00:28:54
was so low on battery
00:28:56
the radiomen didn't even hear Earhart's message,
00:28:58
much less take a bearing on it.
00:29:01
10 minutes later, Earhart said,
00:29:03
"We are circling but cannot hear you.
00:29:05
Go ahead on 7,500."
00:29:08
The Itasca immediately sent As on 7,500 kilohertz.
00:29:12
In the Electra, Earhart heard the stutter stop of As
00:29:16
filling the cabin.
00:29:17
The relief of finally hearing something
00:29:20
must have been overwhelming.
00:29:22
She quickly turned her radio direction finding loop
00:29:24
to locate the null,
00:29:26
but the signal never dropped out.
00:29:29
The frequency was too high,
00:29:31
so the radio waves from the Itasca were reflecting
00:29:33
and arriving from different directions.
00:29:36
Joseph Gurr, a radio mechanic who worked on Earhart's plane,
00:29:39
later said that they knew there were limitations
00:29:41
to high frequencies
00:29:42
which had a tendency to skip and bend,
00:29:45
creating a false radio direction bearing.
00:29:48
Without a minimum, she was still lost.
00:29:53
Earhart frantically called Itasca.
00:29:56
"We received your signals but unable to get a minimum.
00:29:59
Please take a bearing on us and answer with voice."
00:30:02
Itasca attempted to explain the problem.
00:30:05
"Your signals received okay.
00:30:07
It is impractical to take a bearing on your voice."
00:30:10
No response. Without the belly antenna,
00:30:12
she probably never heard any of their communications.
00:30:16
And it wouldn't have mattered
00:30:17
if the Itasca had sent low frequency signals
00:30:20
because Earhart's loop was tuned to pick up 7,500 kilohertz.
00:30:27
So, why didn't the Itasca
00:30:29
correct the frequency she suggested?
00:30:32
Commander Thompson of the Itasca
00:30:33
was aware of her radio direction finding limits.
00:30:36
He had received messages
00:30:37
both from Earhart's husband, George Putnam,
00:30:40
and the Coast Guard's San Francisco division
00:30:43
stating Earhart could only take bearings
00:30:44
on frequencies between 200 and 1,500 kilohertz.
00:30:49
But he either thought Earhart knew more
00:30:51
about her radio equipment,
00:30:52
or that it wasn't his place to make suggestions
00:30:55
and take more responsibility for her flight.
00:30:59
When she asked the Itasca
00:31:00
to tell her if these frequencies weren't suitable,
00:31:02
she could have been referring to the ship's capabilities
00:31:05
rather than her own.
00:31:06
The Itasca said they'd be ready
00:31:07
on the frequencies she wanted and more
00:31:10
instead of giving specific suggestions.
00:31:14
San Francisco's Coast Guard division
00:31:16
tried to get Commander Thompson to take more responsibility
00:31:19
for Earhart's radio communications
00:31:21
by suggesting they directly tell Earhart
00:31:23
which frequencies to use.
00:31:25
But Thompson essentially told them to butt out.
00:31:28
The Itasca communicated directly with Earhart from then on.
00:31:34
The radiomen continued to try to reach Earhart,
00:31:37
and just before 9:00 a.m.,
00:31:38
Earhart's voice suddenly burst through again.
00:31:41
"We are on the line 157-337.
00:31:44
We will repeat this on 6,210 kilohertz.
00:31:48
We are running on line north and south."
00:31:51
Her voice was desperate.
00:31:53
It sounded as if she was
00:31:54
about to burst into tears or scream.
00:31:57
This was the last message the Itasca heard.
00:32:02
There are a number of conspiracy theories
00:32:04
about what happened to Earhart after that,
00:32:06
but the evidence seems clear.
00:32:09
She ran out of fuel somewhere over the Pacific
00:32:11
and crashed into the sea.
00:32:14
Two hours after her last message,
00:32:16
the Itasca left Howland
00:32:17
to search north and west for the Electra.
00:32:21
Other Navy and Coast Guard ships and planes
00:32:23
joined the search for over two weeks.
00:32:26
To that point in US history,
00:32:28
it was the most intensive and expensive
00:32:31
search and rescue operation,
00:32:33
costing around $4 million,
00:32:35
which is almost 100 million in today's money.
00:32:40
No one has ever found a trace of Noonan, Earhart,
00:32:44
or her Electra.
00:32:46
All of these mistakes could have been resolved
00:32:49
if Earhart had two-way communication,
00:32:51
but her belly antenna somehow malfunctioned.
00:32:54
Some theories suggest
00:32:55
it fell off during takeoff in New Guinea,
00:32:57
but without physical evidence,
00:32:59
it's impossible to say.
00:33:01
But Earhart did confirm receiving signals
00:33:04
on her loop antenna.
00:33:06
Her loop could only direction find with lower frequencies,
00:33:09
but it could receive signals on a wide range.
00:33:12
If she had switched to using the loop
00:33:14
for all communications,
00:33:17
she could have received Itasca's voice messages
00:33:20
and then the Itasca could have requested
00:33:22
she take a bearing on a lower frequency,
00:33:25
which would have guided her safely to Howland Island.
00:33:31
When I began researching this video,
00:33:33
I expected to find
00:33:34
that Amelia Earhart's demise was inevitable.
00:33:37
That what she was trying to do was just so difficult
00:33:41
that nothing could have saved her.
00:33:43
But instead, I found the opposite.
00:33:45
There were at least a half dozen things
00:33:47
that if they went differently
00:33:49
would have allowed her to land safely.
00:33:52
So to me, this story comes down to two things.
00:33:55
Knowledge and responsibility.
00:33:58
Earhart lacked knowledge of radio systems,
00:34:00
which would've allowed her to specify
00:34:02
the right direction finding frequency.
00:34:05
But Commander Thompson of the Itasca had that knowledge.
00:34:08
He knew her direction finding limits,
00:34:10
but he didn't take on the responsibility to correct her.
00:34:14
When attempting any challenging endeavor,
00:34:17
you need someone with the right knowledge
00:34:19
who will also take responsibility for getting things right.
00:34:23
That's what you need
00:34:24
to battle the inherent chaos and disorder of the universe.
00:34:29
Otherwise, what you get is disaster.
00:34:38
This video was sponsored by KiwiCo,
00:34:40
so I thought it would be appropriate
00:34:42
to build their radio-controlled delivery bot.
00:34:46
But my oldest kid was out for the afternoon,
00:34:48
so I sat down to make it by myself,
00:34:50
but very quickly I was joined
00:34:52
by my 4-year-old and 6-year-old
00:34:54
who were really excited to help.
00:34:56
You know, we have been getting KiwiCo delivered to our door
00:34:58
for years now
00:34:59
and it's one of my kids' favorite things to do with me.
00:35:03
They have a lot of fun
00:35:04
while we're also spending quality time together.
00:35:07
And somewhat secretly, they're also learning,
00:35:10
not only technical knowledge,
00:35:11
but also knowledge of how simple and understandable
00:35:14
machines that at first appear complex can be.
00:35:18
I think it's great that they're getting hands-on
00:35:21
with wheels and motors and radio transmitters.
00:35:24
I think it enables them to build up this resilience
00:35:27
and an attitude that, well, I can understand that,
00:35:31
I could probably build that.
00:35:33
And KiwiCo takes responsibility
00:35:35
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00:35:38
which means no extra trips to the store.
00:35:40
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00:35:42
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00:35:45
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00:35:48
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00:35:50
and rigorously tested by kids
00:35:52
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00:35:54
and is just generally really fun to do.
00:35:57
I noticed that their instructions keep getting better
00:35:59
with helpful hints to ensure
00:36:00
you've done everything correctly.
00:36:02
And with KiwiCo Labs for ages six and up,
00:36:05
kids use the problem-solving skills they've developed
00:36:08
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00:36:12
(child laughing)
00:36:13
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00:36:15
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00:36:16
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00:36:19
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00:36:21
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00:36:26
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00:36:29
So I wanna thank KiwiCo for sponsoring this video
00:36:32
and I wanna thank you for watching.