I've read about it on a message board  Random
class isn't really random. It is created with predictable fashion using a mathematical formula.
Is it really true? If so, Random
isn't really random??
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I've read about it on a message board  Is it really true? If so, 

closed as off topic by finnw, bmargulies, RobV, ЯegDwight, HaskellElephant Oct 30 '12 at 21:05Questions on Stack Overflow are expected to relate to programming within the scope defined by the community. Consider editing the question or leaving comments for improvement if you believe the question can be reworded to fit within the scope. Read more about reopening questions here.If this question can be reworded to fit the rules in the help center, please edit the question. 


As others have already said, Random creates pseudorandom numbers, depending on some seed value. It may be helpful to know that the .NET class
creates a random number generator with a given seed value, helpful if you want reproducible behaviour of your program. On the other hand,
creates a random number generator with datetime depending seed value, which means, almost every time you start your program again, it will produce a different sequence of (pseudo)random numbers. 


Because deterministic computers are really bad at generating "true" random numbers by themselves. Also, a predictable/repeatable random sequence is often surprisingly useful, since it helps in testing. 


It's really hard to create something that is absolutely random. See the Wikipedia articles on randomness and pseudorandomness 


The sequence is predictable for each starting seed. For different seeds, different sequences of numbers are returned. If the seed used is itself random (such as the DatetTime.Now.Ticks), then the numbers returned a adequately 'random'. Alternatively, you can use a cryptographic random number generator such as the RNGCryptoServiceProvider class. 


It isn't random it's a randomlike number generating algorithm and it's based on a number to generate. If you set that random number to something like the system time the numbers are more close to random, but if you use these numbers to lets say, an encryption algorithm, is the attacker knows WHEN you generate the random numbers and the algorithm you use, then it is more possible that your encryption will break. The only way to generate true random numbers is to measure something natural, for example voltage levels or have a microphone picking up sounds somewhere or something like that. 


It is true, but you can always seed the random number generator with some time dependent value, or if you're really prepared to push the boat out, look at www.random.org... In the case of the Random class though, I think it should be random enough for most requirements... I can't see a method to actually seed it, so I'm guessing it must automatically seed as built in behaviour... 


Correct. Class Random is not absolutely totally random. The important question is, is it as statistically close to being random as you need it to be. The output from class Random is statistically as nearly random as a reasonable deterministic program can be. The algorithm uses a 48bit seed modified by a linear congruential formula. If the Random object is created using the parameterless constructor, the 48 loworder bits of millisecond time get used as the seed. If the Random object is created using the seed parameter (a long), the 48 loworder bits of the long get used as the seed. If Random is instanced with the same seed and make the exact same sequence of next calls are made from it, the exact same sequence of values will result from that instance. This is deliberate to allow for predictable software testing and dmonstrations. Ordinarliy, Random is not used with a constant seed for operational use since it is usually used to get unpredictable psuedorandom sequences. If two instances of Random with the parameterless constructors get created in the same clock millisecond, they will also get the same sequences from both instances. It is important to note that eventually, a Random instance will repeat its pattern. Therefore, a Random instance should not be used for enormously long sequences before creating a new instance. There is no reason not to use the Random class except for highsecurity cryptographic applications or some special need where some aspect of true randomness is of paramount importance, something that is uncommon. In those cases, you really need a hardware randomizer that uses radioactive decay or infinitesimal molecular level brownian motion induced randomness to generate a random result. Sun SPARC hardware platforms had such hardware installable. Other platforms can have them too, along with the hardware drivers that give access to the randomness they generate. The algorithm used in class Random is the result of considerable research by some of the best minds in computer science and mathematics. Given the right parameters, it provides remarkable and outstanding results. Other more recent algorithms may be better for some limited applications, but they also have performance or specific application issues that make them less suitible for general purpose use. The linear congruential algorithm still remains one of the most widely used general purpose pseudorandom number generators. The following quote is from Donald Knuth's book, The Art of Computer Programming, Volume 2, Seminumerical Algorithms, Section 3.2.1. The quote describes the linear congruential method and discusses its properties. If you don't know who Donald Knuth is or have never read any of his papers or books, he, amongst other things, showed that there can be no sort faster than Tony Hoare's Quicksort with partion pivot strategies created by Robert Sedgewick. Robert Sedgewick, who suggested the best simple pivot selection strategies for Quicksort, did his doctoral thesis on Quicksort under Donald Knuth's supervision. Knuth's multivolume work, The Art Of Computer Programming, is one of the greatest expositions of the most important theoretical aspects of computing ever assembled, including sorting, searching and randomizing algorithms. There is a lot of discussion in Chapter 3 of this about what randomness really is, statistically and philosophically, and about software that emmulates true randomness to the point where it is statistically nearly indistinguishable from it for very large, but still finite, sequences. What follows is pretty heavy reading:


