THIS Technology Could REVOLUTIONIZE Airline Safety!

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As an old retired 767 pilot I am amazed at the advances in navigation. However the old ones weren't too bad. Back in the days before GPS we relied on IRS for long range nav. It updated automatically using ground aids before going over water. It never ceased to amaze me when after a few hours over water, arriving over a long/lat reporting point, we could see another aircraft directly overhead or below at the exact same spot. Cheers,, Peter

Hey Petter, the most amazing thing happened today. I am a primary school teacher (ages 5-12) in a public (gov owned) school Sydney, Australia. I current teach science to all grades from Kindergarten to Year 6. Today I taught a Year 4 (10yo). We were discussing reliable sources to use online, including UA-cam channels. I discussed how I was very interested in aviation and how I had found a channel that outlines information about aircraft, how they fly and what causes aviation accidents. I explained that I thought it was a reliable source because the person who researches and presents the information was a captain for an airline. One of the students asked if I meant Mentour Pilot, because he watches it too and he wants to be a pilot.
I just wanted to let you know that you are being watched by future pilots who aren’t even old enough to drive yet!

In 1965, as a fourteen-year-old boy, I flew from New York to Manchester, England on a BOAC Boeing 707. Only three passengers were in the first-class compartment-my mother, myself, and a businessman. About thirty minutes into the flight, the co-pilot emerged from the cockpit seated himself in the first-class compartment, reclined his seat, and lay his head back, apparently intending to sleep.
Moments later, the flight attendant leaned over toward me and said, "The captain requests your presence in the cockpit." I happily followed her into the cockpit, and the captain introduced himself, the radio operator, and the navigator, and instructed me to be seated in the co-captains seat. For the next several hours, the captain explained many of the controls and instructed me in making minor throttle adjustments. I was even allowed to slightly bank the craft and return it to the proper heading. Of course, these adjustments were negligible and the pilot never took his hands from the controls.
Perhaps a half-hour later, my mother was brought into the cockpit and was shown how to celestially navigate by the navigator. There was a sextant installed in the overhead. I wonder if this was a feature on all Boeing 707s or just the British versions of the craft.
I remained in the cockpit until just before landing in Edinburgh, then returned to my seat and remained there until landing in Manchester.

Hey Petr, 40 professional pilot here. Have flown with the old sextant sticking out my celestial port many times and doppler radars for drift. Also have used, Omega, LORAN, Microwave Landing Systems and Pressure navigation in Antarctica. This was one of the best overviews I've seen! Just the right amount of detail for pro and basic enough for the layman. Very well written and edited sir!

If the earth were flat, nothing would exist, because cats would have knocked everything off the edge thousands of years ago.

Not a pilot but I love learning about aviation and Navigation. It adds to the "useless info" that I use or share with others when they say..."how do they do that?"

As a very retired airline pilot and sim instructor I found this video fascinating. Actually your description of current nav systems was one of the best I've heard in over 40 years in the industry. Keep up the good work.

Lol loved the slight dig at flat earthers 😂

I work in Oceanographic survey and construction.
We use RLG, FOG and INS underwater. Mostly FOGs are used and preferred, out of the manufacturers we use, FOGs tend to be a more reliable name in our field however they are more sensitive to shock forces making them lose the accurate specifications though but their high accuracy is not always needed for our work.
I have heard RLGs are much more resilient as the whole mirror and laser assembly is a single glass prizm so they not going to move position away or closer to each other and they are used to aim artillery guns as they can with stand the shocks well.
As for INS we use it, but it will drift in minutes without additional sensors aiding it.
Problem underwater is GPS doesn’t reach so by using GPS to get vessel position we then use an acoustic system to get position of underwater ROVs, structures etc in relation to Vessel and fron this we can know it underwater position. But it is not accurate like GPS but it is accurate enough.
There are different acoustic systems that can be used. You can set up almost like your own temporary satellite array in a local area underwate but the method im most used to is you have vessel ping and remote beacons on underwater objects will reply back. The hydrophones (ears ) on the vessel are numerous and in an array. Depending on the timing between each hearing the reply it can calculate a direction and you can get a range based on the time from the vessel ping to the reply. This is usually done every 2-3 seconds. Remote becons do not always have a power source subsea and so it depends on how long you need the battery to last; more pings, less time you will have battery last.
However sound in water travels slow enough that delay becomes an issue especially in deep water (1000m+) like found in Gulf of Mexico, west Africa for exanple. Sound will travel about 1500m/s, but 2000m depth means possibly getting close to 3 seconds between transmit- travel down and up time- process signal time. In the real world environment it is not unusual to lose replies or chirps not be heard by beacons underwater due to other noise, and masking (not being in line of sight) so on our navigation we will see position but it will only update once every couple of seconds or so in normal use.
However if 1 or 2 of these replies are missed you go considerable time and distance if ROV is traveling where position is not known. This means rocks could appear meters away from their real location in a survey. There are ways to correct for this but correcting is not as good or accurate as getting accurate data during a survey.
This reason is why we use INS on Rov when surveying, so as to assist and it has become standard required equipment a lot of the time. It will fill in the gaps between the replies and especially if we miss replies. So instead of seeing our ROV move as a series of dots updating every few seconds- it will be a smooth line traveling as it is in real life.
They quantim navigation. I could see that making its way to my industry too as iif i understand correctly, i can see it could possibly remove some of the other equipment if it replaced INS units. It would also potentially save time and work when getting everything set up and calibrated i guess.

Back in the 1970s I flew on a Boeing 707 that was equipped with inertial navigation for trans polar flights. The system used gyroscopes and ring lasers to track the changes in position from a fixed starting point. It did drift over time but was still good enough to be within a few miles at the end of several thousand miles of flight. The difference between then and now is that the equipment fits in a shoe box today rather than completely filling an equipment bay and the space between the two pilot seats in the 707. That was also the time that the first GPS systems started to appear. You frequently had to wait six or more hours between fixes from the limited number of satellites available at the time.

My grandfather was a navigator turned electronics warfare officer in the airforce. He said the laser ring gyroscope was the biggest advancement in avionics ever. Before that, with mechanical gyros, the lubricating oil the military used was a highly guarded secret both in terms of composition and location - there were heavily fortified stockpiles around the nation and only a few people knew all the locations of the gyroscope oil.

When I was flying many years ago I always flew IFR (I Follow Roads).

Cryogenic cooling means it's unlikely to be taking over from GPS for anything smaller than an aircraft. I can't see anything running cryo-tanks from a battery for long.

My first job out of university was as a navigator/bombardier in B52’s. Radar, celestial, and dead reckoning.
Talk about becoming technologically unemployed.

My father was a WWII era naval fighter pilot. His writing about his experience included the following:
Navigation was one of the essential flying skills you had to master in the days before GPS. A typical carrier mission required flying over a featureless ocean searching for enemy aircraft, while at the same time charting compass heading, time, and wind drift on a small pullout navigation table in the cockpit. Most importantly, you had to keep track of a floating runway that was sailing away from your starting location at 15-20 knots the whole time you were aloft. Wind drift had to be estimated by looking at ocean whitecaps and waves. So it was with some relief that you came back into visual contact with the carrier when returning from a mission, knowing that you had done your navigation calculation correctly. That relief was followed, however, by a white-knuckle landing on a runway heaving in the ocean swells.

I need to make a small correction. GPS is the United States' navigation system, but there are many more, such as Galileo (European), GLONASS (Russian), BeiDou (Chinese), QZSS (Japanese), and NavIC (Indian). Our mobile phones typically use all of these systems, and I believe aviation does as well. The general term for all of these navigation systems is GNSS (Global Navigation Satellite System).

I enjoy your show and the way you present information, however, I have a couple of comments regarding your assessment of IRS systems:
• I’ve been hearing about “cold atom” navigation (you referred to it as quantum nav) for nearly 20 years. I’m glad it’s finally coming to fruition.
• FOG is not an improvement to RLG. Both systems are spec’d to 0.8nm/hr drift. NGC went full in with FOG while Honeywell stuck with RLG. Honeywell owns the commercial market.
• FOG is not preferred by space applications. Space tends toward Hemispherical Resonator Gyroscope (HRG) “wine glass” systems.
• RLG/FOG systems cannot “detect” the earth’s rotation rate. They assume the rotation rate given the inputted initial position. In a near mishap, an F-22 pilot (in Alaska) inputted 16 degrees vice 61 degrees latitude. The system went “upside down” and the aircraft temporarily departed controlled flight.
• GPS is not “primary” in an IRS. Both inertial and GPS inputs go through a Kalman filter. Inertial is more accurate in the short term. A spurious GPS input will not send the IRS off-kilter.
• Stellar nav is extremely accurate. Several military aircraft use (e.g. LN-120) for different applications. The obvious limitation is clouds…
I’ve been out of the industry for a “few” years so my info might be a little dated. Keep up the great channel!

Excellent explanations!
In the early 2000’s I was on a SWA flight from Sacramento to San Diego. It was the first fight of the day for that aircraft that had the new upturned wing tips. A strong storm was passing through, with winds 35 kts and gusts up to 45 kts. As we boarded, the plane was noticeably bouncing around.
After boarding was complete, we made no move to pushback for over 30 mins when the pilot made a PA saying the aircraft was fine, but the bouncing around would not allow the three gyroscopes to synchronize and we could not take off until they all give the same result. He said the new wingtips made the plane move about more in the unusual lateral wind than the old straight wingtips.
After a few more minutes, he even moved the aircraft behind a hanger in an attempt to shelter the plane from the wind. No joy. We had to stay in the ground another hour until the storm front passed and the plane stopped bouncing around enough so the gyros synced.
Technology is nice…when it works! works. 21:12

The problem with any of the current quantum technologies is, as Petter mentioned, that they need to operate at as close to absolute zero as possible. It is actually not the device that is so big, it is the cooling solution that takes up space of at least a fridge. And it usually uses a consumable (like liquid Helium) to achieve these low temperatures. It is highly questionable how far this can be shrunk down, even a size reduction by half would be great progress.

It fascinates me that even as our technological implementations become 'space age/futuristic' the basics remain the same. And the pilots who understand the basics will always be just a little better prepared to deal with "stuff that happens.' Thanks for another interesting video.

The TV limited series Master's of the Air (2024) frequently showed excellent use of Dead Reckoning Navigation, used by the American Bomber Command in WWII. It was shown in detail on almost every flight, with the Navigator making the calculations using the information he had, as well as how much trouble the rest of the crew could get in to if their Navigator was killed mid-flight.

There is also the Hemispherical resonator gyroscope, used on satelites and Nuclear Subs.
According to Wiki :
It is highly accurate and is not sensitive to external environmental perturbations. The resonating shell weighs only a few grams and it is perfectly balanced, which makes it insensitive to vibrations, accelerations, and shocks.

It's also worth pointing out that some military planes used a form of automatic celestial navigation called astro-inertial navigation. If I remember correctly the SR-71 used such a system and it's rumored that the B-2 uses such a system as well.

I did a research project on this tech (ring trap Bose-Einstein Condensates) 10 years ago, cool to see that it's being implemented now.
An issue is decoherence, or the atom bunches becoming less quantum and useful due to eg warning up. At the time, that was projected to be on the order of months in real deployments

GPS spoofing can easily be detected, we just don't do it yet.
An aircraft needs two GPS antennas, one pointing at the sky and the other one pointing to the ground.
Under normal circumstances the ground antenna receives no signal (no spoofing).
If all of a sudden there's a strong GPS signal coming from the ground, we know there's a spoofing in progress, the aircraft can then disregard those data and revert to inertial navigation until the spoofing has gone away.

As a "boomer" who worked for a while at Decca when I was young, it was interesting to see a quick glimpse of one of those old nav. systems we were making that were rather "secret" at the time.

It might be a great solution. Its also worth mentioning the possibilities for automated IFR and automated celestial navigation (which is already used by satellites): the techniques of those methods, except done via cameras and a computer matches the ground features or stars to their known layout. Ground-detecting radar can perform that by matching the contours of land, forest, and buildings to the features that are expected along the route.
Automated IFR is likely used for cruise missiles and milary drones, as we expect GPS to be jammed or spoofed in their usage areas. And thougg good gyroscopes could be used, those gyroscopes are critical military technology and we dont want to risk an enemy getting them if a weapon fails to detonate. This isnt as much of a worry for a software-based system, as the software can run on RAM (non-saved memory) and be programmed by the aircraft before firing, so a saved copy is never on the weapon - and the software vanishes from RAM within minutes or seconds of the weapon losing electrical power.

Hej Petter! I got my PhD in quantum physics decades ago, and while I still have to check out the details of this system - this seems like a truly ingenious idea. It's like someone connected two dots that appear to have nothing to do with each other. I'll dig deeper, till dess tack för videon, och ha det fint! ;)

Thanks Petter, great story.
I started my career on 747 classics with Carousel IV inertial systems, watched then as we moved on to the dramatic improvement with Laser ring gyros, and then finally GPS came into the mix. Then in the early 2000s we were the first airline in the Southern hemisphere to train on and use RNP approaches. I’m now retired since 2020 (Unfortunately Covid ensured that I had to go and put my feet up- will always miss the flying, though not waking to an alarm clock.)
This looks really encouraging- hopefully it lives up to expectations in every respect.

I currently live in Finland and the amount of spoofing and jamming in this region coming from Russia is crazy. Finnair and others have given up flying to some airports in Finland and Estonia as the parameters have gone beyond safe levels. If I remember then these are smaller airports without state of the art landing systems so they require GPS to give valid info for passenger planes.

I worked for Northrop for 34 years. The changes in the technology was amazing to work with. RLGs were very work intensive, because of the cleanliness requirements before the system is sealed. Other products with fiber optical unit changed the applications possible for improvement. It was all very interesting work. I have been in this type of work for 45 plus years.

Is LORAN-C gone now? Oh... LORAN-C navigation was state of the art back then. good ol' days...

The Gyro in a model helicopter ist absolutly correct. After 100 loopings it knows exactly the position of the helicopter. This is needed for a rescue button. You can see a test in the video 'Vstabi NEO rescue Logo 600 SX'. This flight computer has more computer power than a B2 Spirit. It was developed in Hanau near Frankfurt/Main / Germany where I live.

In the 1980’s, the airport that I worked at lost the ILS to our primary runway. The FAA tried to schedule the outage during good weather months but it ran over time and budget. With no RNAV approach published (it took about two years to publish a new approach procedure at the time) we were left with ASR approaches as the only option for flight crews when the ceiling or visibility dropped. We have come a long long way since then.

Phased array recievers for GPS are probably an easier to impliment solution. Much harder to spoof GPS signals when you can filter out certain directions, and GPS jamming tends to come from below.
I also heard 'near absolute zero' which is an engineering headache that might keep quantum gyroscopes beyond the reach of practical aircraft navigation. (Fridge sized experimental systems non withstanding.)

Nice to hear about new technology as an alternative. Im not a aviator but Im a pilot boat driver in the gulf of Finland and we are getting spoofed several times weekly, being thrown about one to two miles around of the actual position. Thank you Petter

Please bear in mind that Ring Laser and Fibre Optic Gyro based Inertial Guidance systems are currently graded according to their accuracy/ drift rate.
The better the accuracy / lower drift rate, the higher the grading/ category.
Very high grade units have export restrictions and are prohibited for use in the US/Europe for anything other than military equipment.
Commercial airliners are not allowed to use these "high grade" units, not only because of the cost, but because of the risk of theft by "bad" actors/countries.
So I never expect to see these quantum gyros in aircraft, even if the cost comes down.
If they did, Russia / China/ N. Korea / Iran would scavenge the parts for military uses.

There is also another type of navigation being studied that is based on pulsars and quasars in outer space. It's essentially an unjammable combination of GPS (where the pulsars are the satellites) and celestial navigation. Celestial drift is very slow and easy to correct for.

Sounds amazing! The main issue here is temperature management. Keeping the Q-INS system at near absolute zero would likely be difficult, heavy, expensive, and need a robust independent power backup. Unless and until they can make it work at near-room temperature, this is a major hurdle. Even today's IRUs need constant cooling and they don't need to be anywhere near Zero Kelvin. I really like these informative videos, keep them coming!

Probably good to note that Feynman won a Nobel prize for his work in quantum mechanics, for him to say that quote

Fun Fact : The Lockheed SR-71 spyplane also used the stars for navigating (even during the day !) , among other methods I imagine.

Laser-ring or fibre-optic gyros not being standard equipment on aircraft is effectively criminal cost-cutting.

very interesting video as usual! quick question: at 13:54 in the video, how were you able to show the IRS position? didn't know that was possible!

As a UK licenced Avionics Engineer I retired 20 years ago and very impressed by the advancement of aircraft navigation systems over this time. I was also one of the first commercial pilots to use GPS in my private aircraft in the 1980's. Your taĺk was very well presented.

When I learned to fly (just after the Wright brothers LoL!) it was radio beacons and look-out-of-the windshield. In my work as an ecologist GPS was the eighth wonder of the world when it first appeared, and this episode has been a real insight as to where we are and what is to come. In view of how rapidly technology is advancing, it won't surprise me of the quantum inertial systems are in use surprisingly soon. Thank you for your excellent channels.

The implications of this for tactical/strategic aviation are huge too. A lot of important targets are defended by GPS jamming to complicate targeting and weapons guidance.

Traveling at approximately a 600mph at altitude with say a nice tail wind the aircraft is covering 880' per second. I'm amazed piolets can be thinking ahead of position in real time. Blink and your hundreds of feet away from point you closed your eyes. Taking into account how fast out brains perceive reality, piolets are amazing. Thank You one and all.

I’m a long-retired pilot and as such found this video fascinating. You certainly do your research, and the presentation is first class! When I retired GPS was really only just coming on line as a mainstream airline system. It always has worried me that we went from fully a self-contained system (INS) to a satellite-based system, and I’m heartened to hear that self-containment for air navigation is making a return. Thank you so much for sharing! ❤

I get the feeling that it would be prudent to use all of them at the same time.
- A camera on the aircraft scans the ground features (assuming over land flight) and matches those ground features with a mapping database specifically set up for this purpose.
- Another camera on the aircraft scans the skies for signatures of stars, even in daylight because that's actually possible, and uses celestial navigation to determine your location.
- Inertial systems (of varying accuracy, just redundant) are tracking your progress.
- GPS does GPS things.
- Radio beacons do radio beacon things.
- Pilots do pilot things.
- Pitot tubes measure airspeed.
- All other sensors one can think of measures altitude (including lidar) and whatnot.
Everyone TOGETHER paints a picture of where the aircraft is at the specific moment in time, its speed, elevation and PYR etc etc.
And if one system deviates from the average of all other systems, that system is deemed untrustworthy, but not completely blocked, just not trustworthy and you get a "trustworthy" measurement, a "combined measurement" and a "possibly incorrect" measurement from the untrusted source.
The pilot is the final deciding factor. We still can't beat humans when it comes to automated/smart systems. As evident by the pilots clearly knowing they are at 30,000 feet and still getting terrain warnings.
And the horror cases where an aircraft will pull down because it thinks it's going to stall when clearly it isn't going to stall and so it plummets into the ground and the pilots can do nothing but ride along...
Either way, we should not be working to trust any one system. No matter how accurate and incorruptible it is. Systems fail, people fail, the world ends around us and the systems and people are all we got.
Redundancy is the point here. No one system should have a veto over the people it's serving. And at the same time, no one person should have a veto over all other people and systems.
For example, when flying in the clouds. You as a person really have no option but to trust your instruments. As a person you could be flying upside down (in a loop for G force reasons) and still think you are in level flight going towards Gran Canaria.
With redundancy, you can see that the ONLY one who is wrong here is YOU. Since all other systems agree that you are currently doing an inverse loop-de-loop and so you really should start trusting the systems COMBINED reports.
The "terrain, PULL UP" warnings are pretty damn annoying too BTW.
If i am flying in a tunnel, the LAST thing i want to do is PULL UP.
The warning should instead inform me that i need to PAY ATTENTION. And then it should state a reason for the warning. But it shouldn't be telling me what to do.
PAY ATTENTION, TERRAIN IMPACT IN 2 MINUTES.
PAY ATTENTION, POSSIBILITY OF STALL DETECTED.
PAY ATTENTION, YOU FORGOT TO CALL YOUR WIFE.
PAY ATTENTION, BANK ANGLE.
PAY ATTENTION, POSSIBLE GPS FAILURE.
PAY ATTENTION, FUEL LEVEL.
and so on.

A navigation unit the size of a washing machine was programmed in the hanger, inserted into its slot behind the crew, determined its exact location using an IR camera pointing "up" while taxiing for take-off, then operated the auto-pilot to designated way-points while performing ISR operations. All the pilot had to do is keep the plane flying and avoid hostile fires. The plane was designed in 1958, the device was later nick-named R-2, and the aircraft was the SR-71. DARPA admits to atomic clocks built on single circuit boards. A number of ordnance pieces use inertial systems to maintain (reduced) accuracy of impact.

Loved the flat earth reference. Thanks for sharing.

I've been in the navigation industry since 1977. This is in the oilfield and river crossing industries. Ring laser gyros have entered our market about 15 years ago but are still not the primary method for steering the bore as it were. This is primarily due to a company holding a monopoly on the technology. Well that has now come to an end and we have our first ring laser steering tool. This video that you produced is the first thing that really helped me understand how they work. Even though I have found your videos to be my favorite, this one blows everything else out of the water for me as it relates directly to what I do and answered so many questions. I've gone from being a big fan to a super fan! Keep it up.

Thank you for the much more respectful introduction of DR plots, this time (2:54)!

So this is where my avgeek and space geek stuff comes together… The first inertial navigation system using fixed axis gyros and early computers was developed by Charles Draper at MIT and in 1953 was used to fly a B-29 from Boston to LA. It was called SPIRE. The plane appeared to be flying off course towards the end of the flight, but it was simply correcting for sidewinds. Cleared the clouds and they had the destination airport in sight. This system is why MIT got the first contract from NASA for the Apollo program long before any other contracts were signed, and with IBM was refined down to what was used in Apollo and later spaceflight. The starting point was programmed into the computers on the Saturn rocket instrument unit (the stage separator above the second stage). The instrument unit had multiple prisms around it with lasers on the ground pointed at them and these triangulated precisely the rocket’s angles, and then the computer knew how to roll and pitch the rocket using the gimballed F-1 and J-2 engines to orbit using the guidance gyros until the instrument unit was jettisoned. The instrument unit also had rate gyros which sent one electrical pulse for every 0.5g so the rocket knew its velocity so it could control the fuel flow to the engines. The loop from the instrument unit to the engines and back was 2 seconds due to the limitations of the computers then which is why Apollo astronauts described it feeling like being on a freight train. Another smaller inertial navigation system was inside the command module where it was programmed using celestial navigation and 3 points - 2 known stars and KSC in Florida. On Apollo 8, Jim Lovell at one point accidentally told the computer it was back on the pad before correcting it. The comment above about the lasers and prisms - when “guidance is internal” is heard before launch - that’s when the lasers were no longer used and it switched to the inertial guidance system. To think they did this in the 1950s and 60s.

If it works, it will be made smaller very quickly. It's not about a plane or a submarine... if you can put the thing into a missile, you can have a completely unjammable cruise missile that follows terrain in 30m height and hits a preprogrammed target with an unprecedented accuracy. It would be the perfect "remove exactly this building and this building only"-weapon.

Interestingly, we use the same navigation techniques when sailing. Of course, everything is much slower on a boat, but we use a combination of dead reckoning, forward bearings, back bearings and transits to locate ourselves when sailing.

I remember an episode of The Big Bang Theory in which Howard and Raj are working on quantum navigation. It's kind of impressive how much science/tech reality was embedded in that show.

GPS is not the only game in town. The ESA runs the Galileo network independent of the American GPS on different frequencies with its own set of satellites. However because the Galileo signals are still quite week, they can be jammed about as easily at GPS.

It really is too bad that countries like Russia and China feel the need to deploy large GPS jamming equipment, but here we are.

9:13 His depiction of the two beams turning on and off is not the way the RLG works. The timing in the RLG is is achieved by detecting phase differences between the two beams thus causing an interference pattern. Think of it this way. We send out two waves in opposite directions around a loop or ring, if they arrive at the detector at the same time the waves overlap perfectly (in phase) so that crests (high points) line up with crests and troughs (low points) line up with troughs, so the waves generate an interference pattern. If one beam is delayed due to rotation, i.e., it travels a longer distance, then the waves do not line up perfectly and the interference pattern changes. Analysis of this change gives the rate of rotation. There is not any real timing as you might think of using a stopwatch, rate of rotation is accomplished by the analysis of the interference patterns. This is the result of a phenomenon called the "Sagnac Effect."
Here is an example that is similar. I used to have my students measure the speed of light right in the hallway of the science building. It was always exciting to be able to measure of of the fundamentals and most important constants in the universe using a few hundred dollars of equipment set up in a hallway. here is how it was done, which is not that dissimilar to the way an RLG works. We used a LASER which could be modulated, i.e., we could impress a wave of known frequency on it so the intensity (brightness) varied with a known timing. The wave was split by a beam splitter with one beam going directly into a simple photocell detector. The second beam was sent up the hallway a known distance and reflected back to a second detector. Thetwo signals were fed into an oscilloscope which displayed them as two waves. The wave that traveled down the hallway was delayed slightly and so it was shifted slightly in the display. Knowing the scan rate of the oscilloscope allowed the students to determine the travel time difference. Speed is distance divided by time, so they could now determine the speed of light. It worked quite well with errors averaging about ten percent (10%) which is very good for such a simple setup.
If we had more sophisticated (meaning prohibitively more expensive) equipment we could have analyzed an interference pattern as the RLG does and gotten much more precise and accurate results. By the way, precision and accuracy are NOT the same. Accuracy is a measure of how close your measurements are to the correct value. Precision is how fine they are. By that I mean that being able to measure to the nearest ounce is more precise than measuring to the nearest pound. A postal scale used to measure the weight of letters in ounces and fractions of an ounce is more precise than a bathroom scale used to measure the weight of people in pounds

Fantastic Episode - Really appreciate it.
Kindly consider doing an in-depth series of episodes on the currently used navigation systems - That will be very very interesting.
Thanks for the great work n videos you so precisely n passionately put together. 👌🏼

GNSS systems are fantastic and Galileo in particular provides use with stunning accuracy. However, down here on the ground there are problems too, even without jamming and spoofing. Up at higher latitudes and in mountainous country (Scotland? Sverige?), there are two aspects of these systems that cause problems. These satellite constellations are on tilted orbits and most are on 55 or 56 degrees with GLONASS being the outlier at 64 degrees. Although alleviated to some degree by their 20000km altitude, this means that at higher latitudes there are no satellites overhead and even on a mountain summit the number of satellites and the sectors of the sky they are in are reduced slightly. The other factor is that in low lying areas near mountains, the presence of the mountains seriously reduces the amount of sky that is visible and this is made far worse by there being no overhead satellites and worse still if the mountains are steep and towards the equator (to your South in the northern hemisphere). This can produce some weird results. For instance, during a rescue operation in very mountainous terrain in Northwest Scotland during which I travelled in my car, on foot, on a lifeboat and in a helicopter, my GPS device recorded a maximum speed of 1600km/h which is definitely not credible.

10:42 no one on the team noticed the Earth being mirrored? thats so funny

One of the reasons there was so much research in to inertial navigation with cellphones about a decade ago is because if it had been accurate enough it would have made indoors navigation possible, but due to the drift in current MEMS based sensors it's never been accurate enough to be useful. Purely inertial based navigation where you only need to know where you started from and would then know on an atomic level how you moved to pinpoint your exact location is pretty much the holy grail of navigation systems.

Incredibly interesting information. Given how long it has taken just to get a 25 hour CVR, I wonder how long it will take for this type of technology to make its way through the bureaucratic behemoths?!
Does this technology only solve lateral navigation? The final report of NSZ4311 brought up some interesting issues around the vertical component.

To prevent spoofing, GPS receivers can also use beam forming to make it so that GPS signals can only be received from directions where satellites were; GPS can also be augmented with sidechannel signatures for GPS messages.

INS on fighters in 1970's. We always said inertial system just works out where it isn't then can say where it is. Looks like we had quantum already in those days!

I'm a retired seafarer and remember the old gyros on steam ships. There
were two and they took up a whole room. Things have sure changed.

As others have mentioned, calling all global navigation systems "GPS" is extremely inaccurate. GPS itself is actually the most outdated and inaccurate system. Galileo goes to ~20cm precision on the publicly available version. Aircraft can use that even without differential techniques, which of course eliminates the need for ground stations

From Oct 1959 to Aug 1965 I was assigned to the Test and Development of the B-58 Hustler, a Supersonic Delta Wing Bomber in the USAF, as an aircraft Mechanic. That aircraft have an Astronaut Tracker as well as two IRS. In the future all commercial and military aircraft.

Your primary navigation means is not GPS, but GNSS as GPS is only one of the many satellite constellations providing PNT.

We use GNSS for vertical grade control . Around 10 years ago we noticed some vertical elevation drift. Our location is close to a USMC test site . When they testing F35 electronic warfare systems our GNSS system experienced a huge lack of integrity. So out come our old school laser grade control units .
Your presentation is on of best ever.

There are ways to decide whether a GPS beam is reliable or spoofed. Each beam has identifying information and it can be determined if it is orbiting Earth at some 7 m/s or static on Earth. Equipment that analyzes these signals and, for example, only uses signals from space unless an airport has a well-known GPS beam should be possible to make in a matter of months.

Having been retired as a Flight Dispatcher for 23 years, I am amazed at the advances in air (space) navigation. When I started in 1959, LF airways were still around and VORs were just taking over. In the 1990s when we pioneered "over the pole" airways from the US and Europe to Asia we were still using INS. It would experience a few minutes of being "lost" when directly over the North Pole. We encountered that when operating the proving runs prior to certification.

Wouldn't these things be REALLY expensive? Like, having a device with a space inside of it that is constantly kept at almost absolute zero... that must need a lot of power and precision engineering, which isn't cheap

Petter, you had me absolutely NERDING out over this video. I'm working on my PhD in physics playing with lasers and atoms and actually one recent graduate from my research group published a paper on enhancement of gyroscopic signals by multiple factors of 10 based on the quantum gyroscope you described! I can link the paper if there is enough interest, but I wanted to say you gave a wonderful introduction to quantum gyroscopes via lasers! It was so cool to see my love for quantum and aviation combined!
Also worth mentioning, quantum cryptography has been an emerging field, which allows for maximum data security against hackers, due to the fact that quantum states collapse after being observed (vaguely). the technology is far from being practical, but there is a ton of cool research happening in that field which could really enhance the security of aviation navigation systems!

Any chance you could react to Die Hard 2? Terrorists spoofed an entire airport & crashed a plane by altering ground level. Always wondered how realistic it is.

Hi Petter, I don't know if you've come across something called Kalman Filtering, but It is a statistical method of using probability to estimate errors in control systems and has been used for many years in aircraft navigation systems. Certainly the Panavia Tornado used Kalman Filtering in its navigation computers to process the data from various systems and sensors including the Inertial Navigation Unit to get the best estimate of position. This was before the days of GPS which doesn't have the issue of cumulative errors, but I would believe the technique is still employed in the Inertial Navigation Systems of modern aircraft as a backup against loss of GPS.

The main concern I see in the future with GNSS jamming or spoofing, is that a bad actor could spoof the location of the aircraft in a way that gradually deviates from the real location. If the deviation occurred over the course of an hour, who would notice it? The inertial navigation system would also re-calibrate itself off the new location(s). That location deviation could be the difference between flying in hostile airspace or not.

1st method mentioned, locating ground features on a map, is called pilotage. VFR means you are maintaining visibility and cloud separation requirements, regardless of navigation method.

"VFR" has nothing to do with navigation. It is a set of rules for flying while not under positive control and in non-instrument conditions. What you are talking about is called "pilotage".

The first method is "pilotage". I flew a 707 (Flt. Engr.) that had a dome for celestial nav for crossing oceans, in the DC-12 we had 3 INS units. Finally in the 777 I flew the latest in "ring laser gyros". OF course I used all of the other methods you explained. Nice description of the RLGs.

I’m an aero systems engineer with a military background. Of course this us super useful for navigation particularly for the military, initially, then in commercial navigation to be sure. Excellent video.

Half a century ago, I took aviation ground school at my local school. I had no desire to be a pilot, I’m too chicken, but it was a fun elective. Except we had to listen to Wagner, the instructor’s choice, at full blast during every exercise and calculation! I only learned the first three nav methods.

Quantum applications needing such low temperatures is presently their biggest Achille's heel, their energy consumption is gargantuan

Given how easy it is to jam gps for plane now (and this is really occuring as seen in some videos....) , if this system become usable in a form where it can be added easily to a plane (while keeping the other existing systems) , I guess it could just be going through a accelerated certification

The combined quality and frequency of Petter's videos is so very impressive!

One feature of the INS (Inertial Nav System) on the L-1011 that most customers selected was 'self correction'. After a long flight when you parked at the gate, you would manually enter Lat Long. You used the Lat Long from a sign at the gate. The computer would compare its last known position with the one entered manually. The difference would be used by the computer to compensate for drift error. After about 4 flights it became amazing accurate. Except for one bug. The Lat Long manually entered from the sign's info at the gate were wrong. Some one finally figured that out and the correct Lat Long was placed on the signs.

We use the IRS/INS systems on board commercial aircraft to orient the satellite communications systems that provide internet connectivity during flight. Having a precise latitude and longitude as well as info on pitch, yaw, roll, and the rate of change for those, allow the antennas to be pointed very accurately toward the desired satellite. Once the satellite is acquired the antennas will typically do closed loop tracking to maintain accurate pointing regardless of any movement of the airframe due to turbulence or flight maneuvers.
In the event that the IRS from the aircraft isn't available, the satcom system does have a back-up means of acquiring a pointing solution, but it takes longer to initially find the satellite. Given that there are typically three inertial reference units on commercial aircraft that vote between themselves, an outright failure of the IRS is really rare.

Very nice discussion of navigation. BTW, if any readers are in (or visiting) Washington, the Air and space museum has a whole room devoted to navigation and is well-worth a visit.
Advanced inertial navigation systems have been in use by the military for a while, and will make their way into civil aviation over time. In cruise missiles (which are just aircraft by another name) for example, the user wants the missile to have extremely precise position accuracy all the way to the 'landing." But it is very easy to jam GPS, so the last few miles to the destination cannot rely on GPS and must use some form of inertial navigation. One of the key components is the solid state gyro, similar to what you have in your cellphone. Isn't it amazing how your phone will rotate the image as you rotate your phone from portrait to landscape? I'm sure that within my lifetime we will all carry precision navigation devices that do not rely (exclusively) on GPS.

It would be amazing for subterranean navigation. Go into a cave system and your "GPS" could create a track and you could always find your way out and map at the same time.

As I recall, the triple laser IRS system in the eighties had a sinusoidal error and consequently was not cumulative but variable over time.

A big advantage of ring laser gyros and fiber-optic gyros over mechanical gyros is that mechanical gyros drift significantly more over time and the drift gets worse - much worse - as the bearings in the gyros wear.

Not a pilot here, but a data scientist. An av-fan and a quantum enthusiat. I really enjoyed this video ❤
Thanks Petter!!

Not a pilot here but I enjoy flying the MSFS. I cut the GPS out on my modified Stearman panel, get a virtual E6B and fly around Alaska using dead reckoning. I had so much fun doing it.

In the days of the Carousel days the aircraft had to be stationary for 30 minutes while the gyros erected. One good bump from a cargo loader could cause the restart of the 30 minute clock. I only recall one failure though and we detected it when we found the ground speed showed 4200 knots.
Great video. Well done.

I am an old ICBM inertial guidance tech. In my day we still used large stable platforms, real mechanican gyros and mechanical acceleromteres. It is very interesting to see the advances in the field. I was afraid the technology was being lost. I am glad to see it is not. I always felt that the system could be more accurate and more reliable. It is gratifying to see that others agree.
Never be lost, ever.

The Apollo spacecraft used INS which was updated enroute to the moon from earthbound Doppler tracking and celestial navigation. During landing it was updated with the landing radar. F-111s used INS to get close to the target and then would update at a predetermined visual (or radar) fix prior to the final bomb run. It was very accurate. This seems like a superior system provided it is updated periodically, which GPS could do even today, without quantum gyros.

1. It may be simpler to set up localizers in strategic places (even space) to reset inertia nav systems.
2. How much does inertia nav drift? It may not drift enough on, for instance, a 3hr flight to introduce significant error.
3. Consider two seperate systems having opposite ‘rotation’. The primary readings would match, but wouldn’t the drift errors be opposite?