I've heard that one can encrypt data using drawings of the Mandlebrot set, and that this encryption algorithm is quantum-safe (can't be broken with a quantum computer, unlike many commonly-used algorithms). I looked around on Google for more information but I've only come across some articles intended for a more non-technical audience. Does anyone have any sources on this that I could use to learn more about this fascinating subject?
Here's a general article outlining the process:
This is more in-depth, providing an algorithm and examples:
There is some discussion of it on the sci.crypt group:
And here's a company in Japan that is offering code and samples (it looks like the package costs $50):
This was the result of a few minutes poking around, so your mileage may vary. The topic sounds interesting, though. Even if it isn't immediately practical, it's nice that there are researchers thinking of different approaches to the problem.
First, the reason that most of the write-ups on the internet seem so obtuse is that they all appear to be drawn from a handful of patent applications. Patent applications for new formulas & algorithms always tend appear to be hiding something, because they are. It's notoriously difficult to police unlicensed use of such things and the applicants try to straddle the line between patent protection and trade secret protection. The point here is that it doesn't necessarily mean that it's all BS.
Secondly, all Fractal mappings that I know of are, to some extent or another "lossy", because the mapings are not strictly 1 to 1. While this is a good reason to beleive that there is no effecient way to break the code, it also means that anything directly "encrypted" by a lossy fractal, can not be decrypted either, even with the key. Thus any kind of direct fractal hashing is not reversible.
Therefore, Fratcal Encryption cannot mean that the message itself is directly encrypted with the fractal. Rather, it must mean that the fractal is used as a "master key" to enable simultaneous generation of "local" or "sequential" keys that are then used to encrypt and decrypt the actual messages.
Before we go any further, let's review the basics of encryption:
Encryption Algorithm Principles
Lets say you have a series messages M(j) for j=1 to N that you want to be able to transmit securely to a Receiving party. You'll need a reversible encryption function E like so:
Where (k) is an encryption key and X(j) is the corresponding encrypted message. Then the message is transmitted to our receiver who has a complementary function E' to decipher the encrypted message:
However, AFAIK you cannot make both an E() and E'() function using Fractals. On the other hand, there are some functions, like XOR that are their own complements:
But XOR is also a weak encryption function and although it is perfectly secure for a single message, if we use it more than once with the same key (k), it becomes very easy to reverse-engineer (k), thus making XOR unsafe for single key encryption systems. This can be solved by using a different key every time:
This solves one problem, but introduces another, which is, how do we insure that both sender and receiver have the same set of keys? Transmitting the series of keys is no solution because that takes us back to the original problem of securely transmitting a series of messages.
Instead we want to generate a series of identical keys on both the sender and receiver independently. But we need to be able to generate a series of keys that are cryptographically secure in their own right. That is, even if an external observer knew all of the preceding keys, they still would not be able to predict the next key in the series with any accuracy. And because we will need a completely different series of keys every time (to make them unguessable) we actually need the Key series itself to be key-based.
The solution to this is to use a Master Key MK, and a different encryption function H, to generate the specific keys for each message:
This is where our Fractals come in, because as we can see above, the H function does not need a complementary function H'. So we can freely use a Fractal-based function with a master key to generate our series of local keys.
Example Implementation and Explanation
Below is a VB.NET class that demonstrates this approach, a naive implementation of Fractal Encryption:
A complete Visual Studio Windows project and a Windows exe can be found at http://www.codeplex.com/FractalEncryptDemo
This class uses the Julia set based on the Quadratic recursion Z(i+1) = Z(i)^2 - C in the complex plane. The Master Key generated consists of 5 numbers, 4 Double precision floating-point values between 0 and 1, and 1 integer between 1 and 1,000,000,000. The first two double values define the real and imaginary parts of C in the equation above. The second two doubles define the real and imaginary parts of a seed value that is used to generate the starting Z's.
Both of these values are mapped (via modulus operations) into a small square area from (0.1, 0.1) to approximately (0.55, 0.55). This is done to try and insure that our fractal calculations do not overflow or underflow (though I am not certain that this is not still possible). Finally, the integer value serves as an offset for our sequence values (our "j" in the formulas above).
Message are encoded four ascii characters at a time. First the sequence number (j) is added to the sequence offset which is used along with the 4-byte offset into the the message as a complex number that is multipled by the complex Seed value and then remapped back into the active rectangle to get our starting Z value. Then the Julia set recursion (Z = Z^2 + C) is applied 16 times and the final result is again remapped back into the active rectangle.
This final complex value is then multiplied by 2^30, both real and imaginary parts are converted to integers and then the bottom 16 bits of each are used to provide the 32 bits (4 bytes) of the local key. This then is XOR'd against the corresponding 4 message bytes at the sender to encrypt it, or XOR'd against the encrypted text at the receiver to decrypt it.
I've heard of this approach. But it's much more of a toy than a real world algorithm:
You use a window of coordinates of the mandelbrot set as a "pad", xoring your input or something, and thus the coordinates of the window (and the spacing of your samples) become your "password". If you choose a very deep window within the set, you will need very many iterations to evaluate and it is, in theory, difficult to brute force this.
Watch out for large bands of solid numbers.. perhaps a run-length encoded mandlebrot.
I guess someone thinks this might be "quantum proof" because it's iterative, you can't count how many iterations it will take for a location on the mandlebrot set to converge without actually iterating. I dunno if that's true or not.
However, I don't think there's any advantage to doing this (besides calling it "fractal"), and there's tons of disadvantages and opportunities to create vulnerablities. You'd be much better off using a well studied public/private key encryption algorithm.
I would add that you may wish to take a look at Multivariate Public Key Crypto Systems (often abbreviated MVKP) which is another active area of interest in the realm of Quantum computing resistant cryptography.
Just because something is referenced in Star Trek does not make it the best choice ;)
There isn't an encryption system out there that is "quantum computer proof", let alone normal computer proof. All you're changing is the amount of time it takes to break the encryption. It has not yet been proven that any function exists for which no such reverse algorithms exist.
The only "unbreakable encryption" we have so far is based on a quantum model, and even then we still really don't have what you're thinking of when you see quantum computer.
First, detect the ambient background radiation using a geiger-counter. Use a location where there is no large audio sections of either silence or artificial reaction from a nearby radiation source. I'm not sure of the statistics of it but it was the equivalent of recording the Cosmic Microwave Background. The resulting soundtrack is simultaneously recorded onto twin vinyl albums (the keys) and then labeled. You send one copy to the transmitter, the other to the receiver. It does not take much time or effort to produce large quantities of disk pairs with completely random, and thus unique, recordings.
When it comes time to transmit a secure message, the two stations agree upon which labeled recording to use. The random noise is then used like a carrier by the transmitter such that the receiver can achieve silence by canceling out the noise when their copy of the key is in sync with the transmitting key, same location in the recording and same playback speed.
With this carrier established, you can guarantee that nobody can decypher the message without obtaining the twin disk used to encrypt the message. This translates the security of the message from a mathematical one to a physical one. As long as you can secure the records and only use each pair a single time, you have perfect security.
Since the recording is done in analog, does it affect how many qubits would be needed by a quantum computer to break this type of message?
There is Code Project now with
of course in the comments: