In probability theory, the law of total variance[1] or variance decomposition formula or conditional variance formulas or law of iterated variances also known as Eve's law,[2] states that if and are random variables on the same probability space, and the variance of is finite, then

In language perhaps better known to statisticians than to probability theorists, the two terms are the "unexplained" and the "explained" components of the variance respectively (cf. fraction of variance unexplained, explained variation). In actuarial science, specifically credibility theory, the first component is called the expected value of the process variance (EVPV) and the second is called the variance of the hypothetical means (VHM).[3] These two components are also the source of the term "Eve's law", from the initials EV VE for "expectation of variance" and "variance of expectation".

Explanation

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To understand the formula above, we need to comprehend the random variables   and  . These variables depend on the value of  : for a given  ,   and   are constant numbers. Essentially, we use the possible values of   to group the outcomes and then compute the expected values and variances for each group.

The "unexplained" component   is simply the average of all the variances of   within each group. The "explained" component   is the variance of the expected values, i.e., it represents the part of the variance that is explained by the variation of the average value of   for each group.

 
Weight of dogs by breed

For an illustration, consider the example of a dog show (a selected excerpt of Analysis_of_variance#Example). Let the random variable   correspond to the dog weight and   correspond to the breed. In this situation, it is reasonable to expect that the breed explains a major portion of the variance in weight since there is a big variance in the breeds' average weights. Of course, there is still some variance in weight for each breed, which is taken into account in the "unexplained" term.

Note that the "explained" term actually means "explained by the averages." If variances for each fixed   (e.g., for each breed in the example above) are very distinct, those variances are still combined in the "unexplained" term.

Examples

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Example 1

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Five graduate students take an exam that is graded from 0 to 100. Let   denote the student's grade and   indicate whether the student is international or domestic. The data is summarized as follows:

Student    
1 20 International
2 30 International
3 100 International
4 40 Domestic
5 60 Domestic

Among international students, the mean is   and the variance is  .

Among domestic students, the mean is   and the variance is  .

       
International 3/5 50 1266.6
Domestic 2/5 50 100

The part of the variance of   "unexplained" by   is the mean of the variances for each group. In this case, it is  . The part of the variance of   "explained" by   is the variance of the means of   inside each group defined by the values of the  . In this case, it is zero, since the mean is the same for each group. So the total variation is

 

Example 2

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Suppose X is a coin flip with the probability of heads being h. Suppose that when X = heads then Y is drawn from a normal distribution with mean μh and standard deviation σh, and that when X = tails then Y is drawn from normal distribution with mean μt and standard deviation σt. Then the first, "unexplained" term on the right-hand side of the above formula is the weighted average of the variances, h2 + (1 − h)σt2, and the second, "explained" term is the variance of the distribution that gives μh with probability h and gives μt with probability 1 − h.

Formulation

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There is a general variance decomposition formula for   components (see below).[4] For example, with two conditioning random variables:   which follows from the law of total conditional variance:[4]  

Note that the conditional expected value   is a random variable in its own right, whose value depends on the value of   Notice that the conditional expected value of   given the event   is a function of   (this is where adherence to the conventional and rigidly case-sensitive notation of probability theory becomes important!). If we write   then the random variable   is just   Similar comments apply to the conditional variance.

One special case, (similar to the law of total expectation) states that if   is a partition of the whole outcome space, that is, these events are mutually exclusive and exhaustive, then  

In this formula, the first component is the expectation of the conditional variance; the other two components are the variance of the conditional expectation.

Proof

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Finite Case

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Let   be observed values of  , with repetitions.

Set   and, for each possible value   of  , set  .

Note that

 

Summing these for  , the last parcel becomes

 

Hence,

 

General Case

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The law of total variance can be proved using the law of total expectation.[5] First,   from the definition of variance. Again, from the definition of variance, and applying the law of total expectation, we have  

Now we rewrite the conditional second moment of   in terms of its variance and first moment, and apply the law of total expectation on the right hand side:  

Since the expectation of a sum is the sum of expectations, the terms can now be regrouped:  

Finally, we recognize the terms in the second set of parentheses as the variance of the conditional expectation  :  

General variance decomposition applicable to dynamic systems

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The following formula shows how to apply the general, measure theoretic variance decomposition formula [4] to stochastic dynamic systems. Let   be the value of a system variable at time   Suppose we have the internal histories (natural filtrations)  , each one corresponding to the history (trajectory) of a different collection of system variables. The collections need not be disjoint. The variance of   can be decomposed, for all times   into   components as follows:  

The decomposition is not unique. It depends on the order of the conditioning in the sequential decomposition.

The square of the correlation and explained (or informational) variation

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In cases where   are such that the conditional expected value is linear; that is, in cases where   it follows from the bilinearity of covariance that   and   and the explained component of the variance divided by the total variance is just the square of the correlation between   and   that is, in such cases,  

One example of this situation is when   have a bivariate normal (Gaussian) distribution.

More generally, when the conditional expectation   is a non-linear function of  [4]   which can be estimated as the   squared from a non-linear regression of   on   using data drawn from the joint distribution of   When   has a Gaussian distribution (and is an invertible function of  ), or   itself has a (marginal) Gaussian distribution, this explained component of variation sets a lower bound on the mutual information:[4]  

Higher moments

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A similar law for the third central moment   says  

For higher cumulants, a generalization exists. See law of total cumulance.

See also

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References

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  1. ^ Neil A. Weiss, A Course in Probability, Addison–Wesley, 2005, pages 385–386.
  2. ^ Joseph K. Blitzstein and Jessica Hwang: "Introduction to Probability"
  3. ^ Mahler, Howard C.; Dean, Curtis Gary (2001). "Chapter 8: Credibility" (PDF). In Casualty Actuarial Society (ed.). Foundations of Casualty Actuarial Science (4th ed.). Casualty Actuarial Society. pp. 525–526. ISBN 978-0-96247-622-8. Retrieved June 25, 2015.
  4. ^ a b c d e Bowsher, C.G. and P.S. Swain, Identifying sources of variation and the flow of information in biochemical networks, PNAS May 15, 2012 109 (20) E1320-E1328.
  5. ^ Neil A. Weiss, A Course in Probability, Addison–Wesley, 2005, pages 380–383.
  • Blitzstein, Joe. "Stat 110 Final Review (Eve's Law)" (PDF). stat110.net. Harvard University, Department of Statistics. Retrieved 9 July 2014.
  • Billingsley, Patrick (1995). Probability and Measure. New York, NY: John Wiley & Sons, Inc. ISBN 0-471-00710-2. (Problem 34.10(b))