I am looking for a reason to choose one of the following way to compute geometric mean of a long series of floating point x:

  1. take nth root of each x, then multiply all of them
  2. multiply all of them, then take nth root

I have heard that for floating point numbers, multiplications and divisions lose less information than additions and subtractions do. Therefore I am not considering the sum-exponent trick.

Should I compute geometric mean via 1 or 2, and why?

Update 1, in response to comment:

All x is less than 1 and in double precision. Their order of magnitude ranges between 10^-1 to 10^-6. Please assume the most common method for computing n-th root, since I am using a built-in function of a programming language. Instead of overflow, I am worried about underflow (?) since all values are less than 1. You can assume the length of the series of x to be in order of 10^8

  • How long is the sequence of floating-point numbers (order of magnitude)? How do you plan to compute the n-th root? For method (2), could there be danger of overflowing the floating-point format of your choice? Is performance any consideration?
    – njuffa
    Commented Jun 9, 2016 at 2:13
  • 3
    Assuming there is no danger of overflowing double-precision floating point format and that accuracy is the most important design criterion, I would suggest using method (2), using a compensated product, then taking the n-th root at the end. For the compensated product (which can be computed very efficiently if FMA is available), see: Stef Graillat, "Accurate Floating-Point Product and Exponentiation", IEEE Transactions on Computers, Vol. 58, No. 7, July 2009, pp. 994-1000. (online copy)
    – njuffa
    Commented Jun 9, 2016 at 4:11
  • 1
    Just a comment: in the exp-sum-log method, it's not really the additions and subtractions that are the main cause of accuracy loss (and in any case there are good algorithms for correctly rounded summation); it's the log calls. Not surprisingly, a function that maps the entire positive floating-point range into the interval (0.0, 710.0) introduces significant loss of information. @njuffa: Any chance of an answer encapsulating your comment? Commented Jun 9, 2016 at 8:08
  • Similarly, the nth root operation is going to lose significant information for large n; I agree with @njuffa that (2) is going to be significantly more accurate. Commented Jun 9, 2016 at 8:11
  • 1
    The risk of overflow in method 2 can be avoided by accumulating the floating-point exponents separately.
    – user1196549
    Commented Jun 9, 2016 at 19:54

2 Answers 2


In general, in a sequence of floating-point operations that also involves contracting operations such as square root or cube root, it is advantageous from an accuracy perspective to perform the contracting operations last. For example, sqrt(1.0/x) is more accurate than 1.0/sqrt(x), sqrt(a*b) is more accurate than sqrt(a)*sqrt(b), and cbrt(a*b*c) is more accurate than cbrt(a)*cbrt(b)*cbrt(c).

As a consequence, unless there is a danger of overflowing or underflowing the chosen floating-point format, such as IEEE-754 binary64 (e.g. double in C/C++), in intermediate computation, method [2] should be chosen. Additional aspect relevant to accuracy: if n-th root is computed by exponentiation, such as pow() in C/C++, additional error will be introduced with every computed root, as explained in case of cube root in my answer to this question. Finally, the computation of the n-th root will be slower than a multiplication, so doing only multiplies with a final root computation at the end will also be a superior approach performancewise.

Very accurate results can be achieved with method [2] by using a compensated product (akin to the compensated addition provided by Kahan summation). See the following paper for details:

Stef Graillat, "Accurate Floating-Point Product and Exponentiation", IEEE Transactions on Computers, Vol. 58, No. 7, July 2009, pp. 994-1000 (online)

This compensated product can be computed particularly efficient on systems that provide the FMA (fused multiply-add) operation in hardware. This is the case for all the common modern processor architectures, both CPUs and GPUs. C/C++ provide convenient access to this via the standard math functions fma(), fmaf().

Update: Asker clarified in comment that the risk of underflow is imminent since there are on the order of 108 factors in [10-6, 10-1]. One possible workaround mentioned by @Yves Daoust in a comment is to separate the factors into mantissa and exponent and accumulate them separately. Whether this is practical will depend on the floating-point environment. While C and C++ provide the standard function frexp() for performing this splitting, this function may not be very fast.


Here's what I would do:

  1. The logarithm of the product over a_i is the same as the sum of the logarithms of multiple values of a_i.

  2. The exponent of a logarithm of some value returns the original value.

  3. The n^th root of an exponential function is given by the same exponential function, where the exponent is divided by n.

Putting this all together, the geometric mean of a_i is given by taking the sum of the logarithms of a_i, dividing by n, and taking the exponent.

In short, geom_mean(A) = e^(sum(ln(a_i)) / n), or e^mean(ln(a_i)).

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.