Is it possible to encode a message in such a way that can only be read by someone or something capable of seeing into the very near future?

Question

Say you have some way of seeing somewhere between a microsecond to 0.1 seconds into the future, or at least the most likely future. Is it possible,through something like a flip-book effect or some other illusion, to encode a message only another observer capable of seeing the same distance into the future could also read?

Clarifications

1. Doesn't need to be encrypted, just laid out in/on a method or medium that enables only those with 'future-vision' to observe a message unobservable to someone without future-vision.

2. The message must not be able to be revealed through mundane means, such as high-speed video or any kind of atypical photography.

3. The future-sight capable observer can only see into the future or at the present, not both at the same time.

4. It doesn't matter how briefly the message is available for our future-sight capable observers, just that only they can see it.

5. Future-sight does not extend into space beyond the 'eye' of the observer.

Answer 1

Sure it is, and we can use modern technology to do it

(NB: This relies on being able to see into the future further than the OP requirement, but if that's an acceptable change in scale, this would work.)

So, have you ever heard of an RSA token? These are devices that work on the basis of giving you a passcode that changes every 30 seconds or so; similar to the Steam Authentication codes, which would also work in this case. All you have to do is change the synchronicity of the rotating passcode to be 30 seconds behind - in other words, make the RSA token one cycle backwards, and therefore anyone who types in the passcode displayed gets an error message because it's an old passcode.

But, your future seer knows what the passcode will be. He or she can see that, types it in and you're done. The passcode is valid, because from the perspective of the user of the tag, it's a future passcode. From the perspective of the authentication server, it's the current one.

Of course, this doesn't mean that if you have access to the authentication process directly it can't be subverted, but for normal use it takes an existing technology and applies a secondary layer of security by forcing the user to see the future passcode displayed instead of the current one. Once you use that, it's all just standard encryption processes, albeit with the extant vulnerabilities they incur.

Answer 2

Reaction times

Average reaction times for most people are roughly 200 ms for simple responses. If you can see 100 ms into the future, your reaction time is going to be roughly half that. So have something like a "Simon Says" type decoder that requires hitting a sequence of light-up buttons within an extremely short reaction window.

Of course, electronics are going to have much faster reaction times than humans, so with advance forewarning, something like this could still be defeated with the right hardware.

However, if you can see a bit further into the future (250+ ms or so), you could actually have the buttons to be pressed not light until after the response window closes. Hardware responding <1ms after the button lights doesn't help if the valid-press window closed 20ms before it ever lit.

Answer 3

It's "Heisencoded": your message is only there when no one is looking at it. The more closely you observe it, the less intelligible it becomes. This includes electronic observations.

However, people can blink - closing and reopening their eyes in about 0.1 seconds - to make the message momentarily "unobserved". Your temporally-gifted individual can thus use their precognition to, just before their eyes shut, see the message as it will appear once they can no longer see it.

Quite why many such messages are mysteriously scrawled next to statuary is often debated - as is the "blue box" and the resident "madman" mentioned therein...

Answer 4

This power is completely broken.

Any sort of true futuresight is a form of time travel since you're transmitting data from the future to the past. The precog can not only transmit undetectable messages, he/she can ask any possible question and receive an answer from a possible future self encoded in physical responses that interact with this power. The precog only needs to daisy chain the answer back to when it was asked.

For example, the precog at time = 0 wants to know the answer to a yes or no question, the answer is locked 10m into the future for whatever arbitrary reason, and the precog has decided on an encoding of eyes open = yes, eyes closed = no. Precog + 10m sees that the answer is no and closes his/her eyes, followed by precog + 9m59.9s seeing the closed eyes and responding appropriately etc. Once precog t0 has the answer, he/she is no longer obligated to behave in any particular way in the future so the timelines of precog + 10m etc. collapses and there is no message for anyone else to observe.

Yes/no is of course an analog to basic binary, so any arbitrary message can be passed back once the precog has decided how to code it.

Answer 5

"[...] into the future, or at least the most likely future."

If less likely futures are game, then this is solvable.

Encrypt the message and destroy the key.

At the press of a button, generate a random key from true random numbers, and try to decrypt with it. Show an error message if it fails, but do not display the key.

The seer will be able to see the vanishingly unlikely future in which the random key guess happens to match the key that was used to encrypt.

You could explain it away as saying all the futures where it doesn't get properly decoded "collapse" into one since the outcomes are identical, so it's easier for the precog to see the one where it does get decoded.

Answer 6

I would place the message in a way that reading it would mean instant death to whoever reaches it (for instance, in the walls of a deeeep pit, just before reaching the bottom or a box filled with poisonous gas). This way, if you can see the future, you could intend on walking that path, read the message just before dying (in the future) and then change your mind and not go into the pit.

Answer 7

Asimov wrote some stories about a substance, the thiotimoline, which is so soluble in water that is dissolves before touching the liquid, thus seeing the future.

This as a consequence of the substance complex structure, which fold the space time allowing the molecule to see the future.

In Asimov's writings the endochronicity of thiotimoline is explained by the fact that in the thiotimoline molecule, there is at least one carbon atom such that, while two of the carbon's four chemical bonds lie in normal space and time, one of the bonds projects into the future and another into the past. Thiotimoline is derived from the bark of the (fictitious) shrub Rosacea karlsbadensis rugo, and the thiotimoline molecule includes at least fourteen hydroxy groups, two amino groups, and one sulfonic acid group, and possibly one nitro compound group as well. The nature of the hydrocarbon nucleus is unknown, although it seems in part to be an aromatic hydrocarbon.

In The Micropsychiatric Applications of Thiotimoline Asimov explains that

the rationale for thiotimoline's behaviour: namely that the chemical bonds in the compound's structural formula are so starved of space that some are forced into the time dimension. According to the second article, thiotimoline's time of solubility varies depending on the determination of the person adding the water.

If you use thiotimoline like a sort of invisible ink to cover the text you want to protect, you can remove it only with the right determination, since thiotimoline's time of solubility varies depending on the determination of the person adding the water. In this case is the substance to see the future, not the observer.

Answer 8

If you had a perfect laser (aka doesn't disperse over any distance, not actually possible but still) you could just shine it on a distant object (or mirror) and encode the message in it.

The only way to read it while in transit in space is to intercept it, requiring FTL or similar

Answer 9

Use Qubits

The value of quantum bits can only be described by a probability until they are measured, but once they're measured they are determined.

Using future sight, observe what the determined value of a quantum bit would be. In the present, run the qubits through quantum logic gates that change their value in some predictable way, measure them, then combine the results with the future results from the non-gated observation.

The key needed (the non-gated results) came from the future, and was effectively destroyed when you observed them in the present.

I believe this depends on how your future sight technology interacts with quantum mechanics. (Also, it's possible I'm overlooking something about how quantum bits works.)

Answer 10

It may not be quite what you're looking for, but I think there's an argument that someone who can see into the future in an interesting way, ie. one that allows them to act on the information they see to change the future, can decrypt anything.

• They look into the future and see themselves trying to decrypt the message with some key
• If they see themselves fail, then clearly that key wasn't correct
• So, they pick a key at random different to the one they saw themselves fail with, and try that one - quickly enough that the attempted decryption finishes in less time than the interval that they can look forward into the future
• Now we've changed the future, the past changes too - they must have seen themselves try the second key, so they wouldn't have picked that one, so they must have picked and tried a different one...
• The only way to resolve the situation is when they pick the correct key.

Although we can think of this as a time loop eventually broken by picking the correct key, to any observer involved it actually takes no time at all - in our prescient friend's experience, they just see themselves pick the correct key and go with that one. However, it only works probabilistically - if we use the time loop model, we can see that if the chances of them picking the right key at random are significantly less than the chances of them getting hit by a meteorite, that's what's probably going to break the loop first. Or maybe this persons actions are the only thing that vary between 'loops', but there's still the possibility of them fumbling it and not completing the decryption quick enough for past them to have seen the result in time or something.

In general, time travel allows us to do arbitrarily complex computations in a fixed amount of time by reading the results of a computational step from the future, doing the next one, and sending the results back to the past. As such, to someone who can send information back in time (or equivalently, see the future), most encryption can be treated as just weak encoding.

Answer 11

The only thing I can think of would be to use some manner of "invisible ink" whose presence and almost instant evaporarion were both invisible to the naked eye, but the overlapping presense of both simultaneously created a visible hue (so, only someone "flipbook viewing" both the present and the next moment would see it). Of course, the reader would have to have some sort of chemical reaction they initiated to read the message, and so the writer would need to leave some manner of glyph of identifying mark so a potential reader would know a message was there.

Otherwise, the ability to see moments into the future would not really provide "secret message" potential, except if they could see multiple possible timelines. Then, the "writer" could build the intent to write something, but decide not to, thus, it would only be visible along the possible future that would never happen. The issues with this are myriad, but the big ones are: 1) it would only be good as a "thieve's cant" for coded dialogue/messages in the moment with bother speaker/writer and listener/reader present. This is because the divergent timeline would only exist up until the decision was made, then be lost to those living on the current timeline forever. 2) your spies would need mich longer spans of time to look into the future in order to catch these messages 3) there is no "secret" to this other than having the ability. Anyone with the ability would quickly become privy to this method.

Answer 12

One kinda hilarious answer involve quantum mechanics and being able to observe effects "too soon". I mean, I'm not an expert on quantum mechanics, but from what I understand, it's observation that collapses the waveform down. If you did the double-slit experiment, but were able to "see" where the photon would hit before it actually reached the double slit apparatus, I'm not sure the photon would be able to interfere with itself like usual. I have a feeling that a 'precog' looking at the double-slit experiment would never see a diffraction pattern, because the "observation" would be occurring before the photon actually got a chance to interfere with itself.

If that's the case? Then the solution is hilariously simple: just have a whole bunch of slits/dots/whatever in a sensitive box that breaks when you open it. Shine coherent light in one end, and look at the pattern that comes out. If no precogs were around, everyone would just see a mishmash of interference patterns. If a precog was around, it'd instantly change to be dashes/dots/whatever.

Edit: Delving a bit more into the quantum side of things. Basically, everything is a probability wave. How the double-slit experiment works is a photon is beamed at two slits, which it will pass through and arrive at a sensor that measures where the light hit. Intuitively, you'd expect that the photon would have to go through one of the slits and you'd see a 'hit' along two vertical lines. Repeat it over and over, and you'll get a rather weird result: an interference pattern. Basically, the photon is simultaneously going through both slits, and interfering as a wave - against itself!

Now, stage 2 of weirdness. Let's say you rig up something that can detect which slit the photon travels through. You then repeat the experiment. Now, though, the interference pattern disappears. That's because your information 'collapses' that wave down. You've 'erased' the possibility that it went through one of the slits, and because of that, the wave can no longer go through both slits and interfere with itself.

Stage 3 of weirdness. You use the same rig as Stage 2 - and measure which slit the photon travels through. But... now you delete this information before the photon can reach the detector (this is called the Quantum Eraser Experiment.) Now the interference pattern reappears! Why? Because while you measured which slit it went through, you deleted that information - and in effect, restored the possibility that it could have gone through either slit.

So, now, the big question: what's the effect of seeing where the photon lands before it goes through the slit or actually lands? And... ultimately, it's a time travel paradox.

If you observe the photon landing in a way that indicates it went through a specific slit, then you observe something that collapses the waveform down in a way that forces it to go through the specific slit, which in turn prevents an interference pattern from emerging.

If you observe the photon landing in a way that indicates an interference pattern, then you observe something that doesn't collapse the waveform down in a way that forces a specific slit, which in turn allows the photon to travel through both slits, which allows for the interference pattern.

Now, if this was a science site? I'd say, "There's no way to empirically test this; there's no way to answer this." But we're in a worldbuilding site. So you can resolve a time travel paradox however you want. You can say, "So what if they see an interference pattern a bit earlier than the photon actually hits the screen? The photon, being in an interference pattern, doesn't convey information about the waveform that would actually reduce it down." And you can say, "The precog's going to see the photon's final state on the wall based on which slit it went through - because their observation itself is what forces the photon to not interfere with itself."

Anyway, in my opinion, the thing that makes this answer so cool is... ultimately, it's taking something so ridiculously unintuitive and complicated and mindbending... and the resulting device is something a child could manufacture. (Well, not the 'can't open/scan' part.)

Answer 13

If the user sees where something will be, but sees the object/person as it is now, then some tricks would be possible.

I'm thinking of a sign changing on the side of a subway car, where the future-vision sees it at the station and can read the sign, but that sign changes before actual arrival, therefore the other people would see whatever is changed to (Community College advertisement, I'm sure).

Or they see a person saying something while looking in their direction, but that person is behind a door at the moment, they'll be along shortly. Could be fun and creepy.

Answer 14

You have to copy a password right before it gets shown on the display.

Say you have a small calculator that randomly chooses digits using some on-board entropy device (so actually random, not just pseudo-random). The calculator would flash a digit at a time and to unlock it you must've pressed that digit before it was even generated. Get 10 of these digits right in a row and the calculator reveals the message. Easy if you have future vision of something around 0.2s or near the human reflex limit, impossible if you don't.

Answer 15

_{(This answer relies on a 4-dimensional being, capable of "seeing" the past/future, being able to 'look around' 3D objects in the same way that we do 2D lines - even if they don't quite realise that that's what they are doing)}

Start with 2 layers a special material (Such as e-ink or a liquid crystal) which can change via some mechanism, such as heat or electricity.

The top layer (Layer α) can switch, almost instantly, between Opaque and Transparent.
The bottom layer (Layer ß) can switch, almost instantly, between "Message" and "No Message".

When the Message is Visible on Layer ß, it is completely obscured by Layer α being Opaque. When Layer α is Transparent Layer ß is blank. Because the layers are so tightly fused together, it is impossible to change one without simultaneously changing the other.

However, by focusing on the future (or, alternatively, on the past) of Layer ß, while Layer α is still transparent, you are able to see the message that it will show when it is obscured.

Answer 16

Stronger encryption schemes like AES512 typically take longer than 0.5-1 seconds to encrypt sth. So just use such a scheme. The future looker already sees the encrypted/decrypted message while the computer is still going.

Anyone in the present sees at most an encrypted message (if your computer is that fast).

Answer 17

The observer would have to convert their prescience into information that no-one else could possess. For example, that person might be able to accurately predict the outcome of a chaotic effect. They would have to repeat their future observations of a period of time long enough to ensure they couldn't have achieved it by chance alone.

They would have to add that information to the medium of the message in some way that the message reveals itself only if that information were correct at the instant it were supplied, so the if someone locked in the present were to do it, the information would be out of date by the time it were observed.

The best I can come up with is:

1. The message is written on or with some kind of medium.
2. The medium is reveals the message only if the exact inverse of the waveform of cosmic background radiation is supplied (analogous to noise cancelling headphones but for cosmic background radiation)
3. The observer has a firefly-like radiation emitting organ at the wavelength of cosmic background radiation.
4. The observer has evolved its prescience to observe future cosmic background radiation at a moment far enough in the future to exactly match the latency for their brain to transmit the instruction to their radiation emitting organ to emit the inverse waveform.

Answer 18

Encrypt the message (with modern asymmetric cryptography, but short keys) then destroy the private key. Normal people will only see the message after cracking the code (which involves factorizing a large number), in a few seconds/hours/days/years (depending on the length of the key). People which can see in the future can "guess" what the result of the cracking will be, before it is complete.

Answer 19

Imagine a Morse code that relies on the viewer looking into the future every 3rd signal. This would allow you to include false signals in the message that would not be observed by the intended target. But in the long run it would only be scrambling a message and I imagine it would be breakable if it was recorded and examined for patterns.

I think most messaging done in this way is too limit to be unbreakable, by simply recording it a normal man can observe the whole message out of time.

Alternatively if you used the ability as an identifier you can use the cool trick of an elaborate handshake. Anyone with the ability would be able to make a random handshake by seeing what their partner expects of them with enough time to react accordingly. In this way any one can easily and secretly show you that they possess these powers