My kids asked me this question and I couldn't really give a concise, understandable explanation.
So I'm hoping someone on SO can.
My kids asked me this question and I couldn't really give a concise, understandable explanation. So I'm hoping someone on SO can. 


How about, "Because computers just follow instructions, and random numbers are the opposite of following instructions. If you make a random number by following instructions, then it's not very random! Imagine trying to give someone instructions on how to choose a random number." 


Here's a kid friendly explanation:
Now for the answer to your question:
No matter how creative the child is with their algorithm, you should still be able to deduce their algorithm. Tell your child that in the computer world, nothing is hidden and just by observation, even if its just the numbers that was observed, the random number algorithm can be discovered. ...as a side effect, if the child was able to come up with a good algorithm that confused you, in which you can't deduce the next sequence, then you have a bright child. :D 


Ask them to devise a stepbystep method to generate a random number. And don't accept "pick a number from 1 to 10" as an answer ;) Trying out a problem should illustrate the difficulty of having to generate random numbers from a set of instructions, just like what computers actually have to do. 


Here's my attempt at explaining randomness at an approximately eighthgrade level. Hope your kids find it useful! Surprising as it may seem, a computer is not very smart. Computers must follow their instructions blindly, and are therefore completely predictable. A computer that doesn't follow its instructions in this manner is, in fact, broken! We want computers to do exactly what we tell them. That's precisely what makes it hard to do things randomly. Computers must be told a sequence of instructions on how to generate random numbers. But that's not really random, because if you gave anybody else the instructions and the same starting point, they could come up with the same answers. So computers can't be truly random just by following instructions. 


Because computers are deterministic machines. 


Because given any input, an algorithm produces the exact same output every single time. And you can't just provide a "random" input, because you're trying to generate the random number in the first place. 


"Kids, unless they're broken, computers never lie, and they always do what you tell them to do. Even when we are disappointed by the results, it always turns out that they were doing what they were told to do with complete fidelity. They can only do two things: add one and one, and move a number from one place to another. If you want them to produce random numbers, you need to explain to them how to do that in terms of adding one and one and moving. Once you have explained that, the results will not be random." 


Generating random numbers on a computer is like playing "Eenie meenie miney moe" when choosing who's It first in a game of tag. On the surface it does look random, but when you get into the details, it's completely deterministic. It's hard to make eenie meenie miney moe into a scheme that a person really can't predict the outcome of. Also there's some difficulties with getting the distribution nice and even. 


Because the only true source of randomness exists at the quantum level. With suitable hardware assists, computers can access this level. for example, they can sample the decay of a radioactve isotope or the noise from a thermionic valve. But your basic PC doesn't come with this cool stuff. 


A simple explanation for the children: The definition of randomness is a philosophical and mathematical question, beyond the scope of this answer, but by definition there is no such thing as a "random" number. In a metaphysical sense, a number is only random in sequential form; however, there is a probability that a sequence follows certain statistical distributions depending on the sample size. A random number generator (in our case a pseudorandom number generator, or PRNG) is simply a device to produce a quasirandom sequence of numbers that we can only estimate (based on the given probability inherent within the sequence) to be random. You should explain to the children that programs can only mimic these devices using complex mathematical formulas (which guarantee a lack of "randomness" by definition because they are a result of some function, or procedural algorithm). Typically, rigorous statistical analysis is necessary in order to differentiate the use of a quantum hardware PRNG (use this as an opportunity to explain to your kids the Heisenberg Principle!) and that of a strong software PRNG. 


Had to be done really Source: http://xkcd.com/221/ 


Because there is no such thing as a random number. Random is a human concept that we use when we cannot comprehend data and do not understand it. If we are to believe that science will ultimately lead to an understanding of how everything works then surely everything is deterministic. Take away the human and there is no random there is only "this". It happens because it happens, not because it is random. 


Because a program is a system and everything in a system is made to run with consistency and regularity. Randomness has no place in a system. 


It is hard because given the same sets of inputs and conditions, a program will produce the same result everytime. This by definition is not random. 


Algorithms to generate random numbers are inevitably deterministic. They take a small random seed, and use it to obtain a long string of pseudorandom digits. It's very difficult to do this without introducing subtle patterns into the data. A string of digits can look perfectly random but have repeated patterns which make the distribution innappropriate for applications where randomness is required. 


Computers can only execute algorithmic computations, and a truly random number isn't an algorithmic thing. You can get algorithms that produce numbers that behave like random numbers; such algorithms are called 'PseudoRandom number generators'. At various times in the past, people have made random number generators from analogdigital converters connected to sources of electronic noise, but this tends to be fairly specialised kit. 


Primarily because computers don't have any functions that behave in discrete, nonrandom ways. A computer is predictable, which allows us to program reliable software. If it wasn't predictable it would be easier to generate a random number (since our software could rely on this unpredictable method). While it's possible to generate pseudorandom numbers, and numbers that are distributed randomly, you cannot generate truly random numbers without separate hardware. There is hardware that generates truly random numbers based on "quantum" interactions (at least according to the manufacturers). Online poker sites sometimes use these adapters for their generators. Apparently there are even online services to provide random numbers  random.org for example. 


As surprising as it may seem, it is difficult to get a computer to do something by chance. A computer follows its instructions blindly and is therefore completely predictable. (A computer that doesn't follow its instructions in this manner is broken.) There are two main approaches to generating random numbers using a computer: PseudoRandom Number Generators (PRNGs) and True Random Number Generators (TRNGs). 


Actually, on most modern computers it's not hard to produce numbers that are "random enough" for most purposes. As others have noted, the critical thing is having a source of randomness. You can't just write a program that will produce randomness algorithmically, but you can observe randomness in the various activities of most computers of reasonable complexity, i.e., the ones we typically think of when writing programs. One such source is timing data of interrupts from various system devices. At one time many computers had no way to get at this data and could only offer pseudorandomness, that is, a random, but repeatable distribution of numbers based on a particular seed. For many purposes this is sufficient  choosing a different seed each time results in good enough randomness. For other purposes, such as encryption, this isn't strong enough and you need some randomness to start with that isn't repeatable or predictable. Today, most computers (with the exception of embedded devices, perhaps) are sophisticated enough to have a source of randomness that can generate encryptionstrength random numbers. For instance, Linux has /dev/random and the .NET framework supports the cryptographically strong RandomNumberGenerator class which has a number of implementations. 


Its probably helpful to distinguish between a number that is hard to predict (which a computer can create) from something that is not deterministic (which is a bit tougher for computers, and theoretically, any physical being). 


It's easy to come up with an algorithm that generates unexpected numbers, that appear random in some sense. But to design an algorithm that generates true random numbers, well, that's hard. Imagine designing an algorithm to simulate a dice roll. You can easily formulate some procedure to generate different numbers on each iteration. But can you guarantee that, in the long run (I mean, up to the infinity), the amount of times that 6 came out will be the same as any other number? When designing a good random number generator, that's the kind of commitment that you have to assume. You have to provide strong guarantees (i.e. mathematical proofs) about the randomness, if the application (e.g. lottery) requires it. 


It is relevant to note that humans perform very poorly at generating random numbers. Computers are worse because they just follow a strict set commands. Humans can only generate good (pseudo) random numbers when following an algorithm, a set of commands. Computers are the same. Although it should be noted that computers can gather entropy from the "environment" connected to it, like keyboard and mouse actions, what aids in generating random numbers (either directly or by seeding a PRNG). 


To make the computer generate a random number, the computer has to have a source of randomness to start with. It has to be feeded a seed that can't be expected or calculated by just looking at the seed, if the seed comes from a clock then it can be predicted or calculated by knowing the time, if the seed comes from like filming a lavalamp and get numbers from the picture stream then it's harder to just look at the seed to know what next number will be. The computer does not have an built in lava lamp to generate that randomness, thats whats make it hard, we have to substitute real randomness with some input that exists in the computer, maybe by logging passing tcpippackets or other things, but its not many ways to get that randomness sources in. 


Computers just don't have suitable hardware. Ordinary computer's hardware is meant to be deterministic. With suitable hardware like mentioned here random numbers are not a problem at all. 


Awhile back I came across the "DiceOMatic" http://GamesByEmail.com/News/DiceOMatic Kind of interesting real world application of the problem. 


Its not hard, here's a couple for free: 12, 1400, 397.6 

