Propagation of uncertainty

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In statistics, propagation of uncertainty (or propagation of error) is the effect of variables' uncertainties (or errors, more specifically random errors) on the uncertainty of a function based on them. When the variables are the values of experimental measurements they have uncertainties due to measurement limitations (e.g., instrument precision) which propagate due to the combination of variables in the function.

The uncertainty u can be expressed in a number of ways. It may be defined by the absolute error Δx. Uncertainties can also be defined by the relative error x)/x, which is usually written as a percentage. Most commonly, the uncertainty on a quantity is quantified in terms of the standard deviation, σ, which is the positive square root of the variance. The value of a quantity and its error are then expressed as an interval x ± u. However, the most general way of characterizing uncertainty is by specifying its probability distribution. If the probability distribution of the variable is known or can be assumed, in theory it is possible to get any of its statistics. In particular, it is possible to derive confidence limits to describe the region within which the true value of the variable may be found. For example, the 68% confidence limits for a one-dimensional variable belonging to a normal distribution are approximately ± one standard deviation σ from the central value x, which means that the region x ± σ will cover the true value in roughly 68% of cases.

If the uncertainties are correlated then covariance must be taken into account. Correlation can arise from two different sources. First, the measurement errors may be correlated. Second, when the underlying values are correlated across a population, the uncertainties in the group averages will be correlated.[1]

In a general context where a nonlinear function modifies the uncertain parameters (correlated or not), the standard tools to propagate uncertainty, and infer resulting quantity probability distribution/statistics, are sampling techniques from the Monte Carlo method family.[2] For very large datasets or complex functions, the calculation of the error propagation may be very expensive so that a surrogate model[3] or a parallel computing strategy[4][5][6] may be necessary.

In some particular cases, the uncertainty propagation calculation can be done through simplistic algebraic procedures. Some of these scenarios are described below.

Linear combinations

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Let   be a set of m functions, which are linear combinations of   variables   with combination coefficients  :   or in matrix notation,  

Also let the variance–covariance matrix of x = (x1, ..., xn) be denoted by   and let the mean value be denoted by  :     is the outer product.

Then, the variance–covariance matrix   of f is given by  

In component notation, the equation   reads  

This is the most general expression for the propagation of error from one set of variables onto another. When the errors on x are uncorrelated, the general expression simplifies to   where   is the variance of k-th element of the x vector. Note that even though the errors on x may be uncorrelated, the errors on f are in general correlated; in other words, even if   is a diagonal matrix,   is in general a full matrix.

The general expressions for a scalar-valued function f are a little simpler (here a is a row vector):    

Each covariance term   can be expressed in terms of the correlation coefficient   by  , so that an alternative expression for the variance of f is  

In the case that the variables in x are uncorrelated, this simplifies further to  

In the simple case of identical coefficients and variances, we find  

For the arithmetic mean,  , the result is the standard error of the mean:  

Non-linear combinations

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When f is a set of non-linear combination of the variables x, an interval propagation could be performed in order to compute intervals which contain all consistent values for the variables. In a probabilistic approach, the function f must usually be linearised by approximation to a first-order Taylor series expansion, though in some cases, exact formulae can be derived that do not depend on the expansion as is the case for the exact variance of products.[7] The Taylor expansion would be:   where   denotes the partial derivative of fk with respect to the i-th variable, evaluated at the mean value of all components of vector x. Or in matrix notation,   where J is the Jacobian matrix. Since f0 is a constant it does not contribute to the error on f. Therefore, the propagation of error follows the linear case, above, but replacing the linear coefficients, Aki and Akj by the partial derivatives,   and  . In matrix notation,[8]  

That is, the Jacobian of the function is used to transform the rows and columns of the variance-covariance matrix of the argument. Note this is equivalent to the matrix expression for the linear case with  .

Simplification

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Neglecting correlations or assuming independent variables yields a common formula among engineers and experimental scientists to calculate error propagation, the variance formula:[9]   where   represents the standard deviation of the function  ,   represents the standard deviation of  ,   represents the standard deviation of  , and so forth.

This formula is based on the linear characteristics of the gradient of   and therefore it is a good estimation for the standard deviation of   as long as   are small enough. Specifically, the linear approximation of   has to be close to   inside a neighbourhood of radius  .[10]

Example

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Any non-linear differentiable function,  , of two variables,   and  , can be expanded as   If we take the variance on both sides and use the formula[11] for the variance of a linear combination of variables   then we obtain   where   is the standard deviation of the function  ,   is the standard deviation of  ,   is the standard deviation of   and   is the covariance between   and  .

In the particular case that  ,  ,  . Then   or   where   is the correlation between   and  .

When the variables   and   are uncorrelated,  . Then  

Caveats and warnings

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Error estimates for non-linear functions are biased on account of using a truncated series expansion. The extent of this bias depends on the nature of the function. For example, the bias on the error calculated for log(1+x) increases as x increases, since the expansion to x is a good approximation only when x is near zero.

For highly non-linear functions, there exist five categories of probabilistic approaches for uncertainty propagation;[12] see Uncertainty quantification for details.

Reciprocal and shifted reciprocal

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In the special case of the inverse or reciprocal  , where   follows a standard normal distribution, the resulting distribution is a reciprocal standard normal distribution, and there is no definable variance.[13]

However, in the slightly more general case of a shifted reciprocal function   for   following a general normal distribution, then mean and variance statistics do exist in a principal value sense, if the difference between the pole   and the mean   is real-valued.[14]

Ratios

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Ratios are also problematic; normal approximations exist under certain conditions.

Example formulae

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This table shows the variances and standard deviations of simple functions of the real variables   with standard deviations   covariance   and correlation   The real-valued coefficients   and   are assumed exactly known (deterministic), i.e.,  

In the right-hand columns of the table,   and   are expectation values, and   is the value of the function calculated at those values.

Function Variance Standard deviation
     
     
     
     
     
   [15][16]  
   [17]  
     
     
   [18]  
   [18]  
   [19]  
     
     
     
     
     
     

For uncorrelated variables ( ,  ) expressions for more complicated functions can be derived by combining simpler functions. For example, repeated multiplication, assuming no correlation, gives  

For the case   we also have Goodman's expression[7] for the exact variance: for the uncorrelated case it is   and therefore we have  

Effect of correlation on differences

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If A and B are uncorrelated, their difference AB will have more variance than either of them. An increasing positive correlation ( ) will decrease the variance of the difference, converging to zero variance for perfectly correlated variables with the same variance. On the other hand, a negative correlation ( ) will further increase the variance of the difference, compared to the uncorrelated case.

For example, the self-subtraction f = AA has zero variance   only if the variate is perfectly autocorrelated ( ). If A is uncorrelated,   then the output variance is twice the input variance,   And if A is perfectly anticorrelated,   then the input variance is quadrupled in the output,   (notice   for f = aAaA in the table above).

Example calculations

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Inverse tangent function

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We can calculate the uncertainty propagation for the inverse tangent function as an example of using partial derivatives to propagate error.

Define   where   is the absolute uncertainty on our measurement of x. The derivative of f(x) with respect to x is  

Therefore, our propagated uncertainty is   where   is the absolute propagated uncertainty.

Resistance measurement

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A practical application is an experiment in which one measures current, I, and voltage, V, on a resistor in order to determine the resistance, R, using Ohm's law, R = V / I.

Given the measured variables with uncertainties, I ± σI and V ± σV, and neglecting their possible correlation, the uncertainty in the computed quantity, σR, is:

 

See also

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References

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  1. ^ Kirchner, James. "Data Analysis Toolkit #5: Uncertainty Analysis and Error Propagation" (PDF). Berkeley Seismology Laboratory. University of California. Retrieved 22 April 2016.
  2. ^ Kroese, D. P.; Taimre, T.; Botev, Z. I. (2011). Handbook of Monte Carlo Methods. John Wiley & Sons.
  3. ^ Ranftl, Sascha; von der Linden, Wolfgang (2021-11-13). "Bayesian Surrogate Analysis and Uncertainty Propagation". Physical Sciences Forum. 3 (1): 6. arXiv:2101.04038. doi:10.3390/psf2021003006. ISSN 2673-9984.
  4. ^ Atanassova, E.; Gurov, T.; Karaivanova, A.; Ivanovska, S.; Durchova, M.; Dimitrov, D. (2016). "On the parallelization approaches for Intel MIC architecture". AIP Conference Proceedings. 1773 (1): 070001. Bibcode:2016AIPC.1773g0001A. doi:10.1063/1.4964983.
  5. ^ Cunha Jr, A.; Nasser, R.; Sampaio, R.; Lopes, H.; Breitman, K. (2014). "Uncertainty quantification through the Monte Carlo method in a cloud computing setting". Computer Physics Communications. 185 (5): 1355–1363. arXiv:2105.09512. Bibcode:2014CoPhC.185.1355C. doi:10.1016/j.cpc.2014.01.006. S2CID 32376269.
  6. ^ Lin, Y.; Wang, F.; Liu, B. (2018). "Random number generators for large-scale parallel Monte Carlo simulations on FPGA". Journal of Computational Physics. 360: 93–103. Bibcode:2018JCoPh.360...93L. doi:10.1016/j.jcp.2018.01.029.
  7. ^ a b Goodman, Leo (1960). "On the Exact Variance of Products". Journal of the American Statistical Association. 55 (292): 708–713. doi:10.2307/2281592. JSTOR 2281592.
  8. ^ Ochoa1, Benjamin; Belongie, Serge "Covariance Propagation for Guided Matching" Archived 2011-07-20 at the Wayback Machine
  9. ^ Ku, H. H. (October 1966). "Notes on the use of propagation of error formulas". Journal of Research of the National Bureau of Standards. 70C (4): 262. doi:10.6028/jres.070c.025. ISSN 0022-4316. Retrieved 3 October 2012.
  10. ^ Clifford, A. A. (1973). Multivariate error analysis: a handbook of error propagation and calculation in many-parameter systems. John Wiley & Sons. ISBN 978-0470160558.[page needed]
  11. ^ Soch, Joram (2020-07-07). "Variance of the linear combination of two random variables". The Book of Statistical Proofs. Retrieved 2022-01-29.
  12. ^ Lee, S. H.; Chen, W. (2009). "A comparative study of uncertainty propagation methods for black-box-type problems". Structural and Multidisciplinary Optimization. 37 (3): 239–253. doi:10.1007/s00158-008-0234-7. S2CID 119988015.
  13. ^ Johnson, Norman L.; Kotz, Samuel; Balakrishnan, Narayanaswamy (1994). Continuous Univariate Distributions, Volume 1. Wiley. p. 171. ISBN 0-471-58495-9.
  14. ^ Lecomte, Christophe (May 2013). "Exact statistics of systems with uncertainties: an analytical theory of rank-one stochastic dynamic systems". Journal of Sound and Vibration. 332 (11): 2750–2776. doi:10.1016/j.jsv.2012.12.009.
  15. ^ "A Summary of Error Propagation" (PDF). p. 2. Archived from the original (PDF) on 2016-12-13. Retrieved 2016-04-04.
  16. ^ "Propagation of Uncertainty through Mathematical Operations" (PDF). p. 5. Retrieved 2016-04-04.
  17. ^ "Strategies for Variance Estimation" (PDF). p. 37. Retrieved 2013-01-18.
  18. ^ a b Harris, Daniel C. (2003), Quantitative chemical analysis (6th ed.), Macmillan, p. 56, ISBN 978-0-7167-4464-1
  19. ^ "Error Propagation tutorial" (PDF). Foothill College. October 9, 2009. Retrieved 2012-03-01.

Further reading

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