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May I know what is the difference among Double.MIN_NORMAL (introduced in 1.6) and Double.MIN_VALUE?

JavaDoc of Double.MIN_NORMAL:

A constant holding the smallest positive normal value of type double, 2-1022

JavaDoc of Double.MIN_VALUE:

A constant holding the smallest positive nonzero value of type double, 2-1074

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3 Answers 3

up vote 17 down vote accepted

The answer can be found in the IEEE specification of floating point representation:

For the single format, the difference between a normal number and a subnormal number is that the leading bit of the significand (the bit to left of the binary point) of a normal number is 1, whereas the leading bit of the significand of a subnormal number is 0. Single-format subnormal numbers were called single-format denormalized numbers in IEEE Standard 754.

That is, (if I interpret it correctly) Double.MIN_NORMAL is the smallest possible number you can represent, provided that you have a 1 in front of the binary point (what is referred to as decimal point in a decimal system). While Double.MIN_VALUE is basically the smallest number you can represent without this constraint.

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No offense, but this answer is misleading/incomplete. As such, I've added an answer below. –  Pacerier yesterday

For simplicity, the explanation will consider just the positive numbers.

The maximum spacing between two adjacent normalized floating point numbers 'x1' and 'x2' is 2 * epsilon * x1 (the normalized floating point numbers are not evenly spaced, they are logarithmically spaced). That means, that when a real number (i.e. the "mathematical" number) is rounded to a floating point number, the maximum relative error is epsilon, which is a constant called machine epsilon or unit roundoff, and for double precision it has the value 2^-52 (approximate value 2.22e-16).

The floating point numbers smaller than Double.MIN_NORMAL are called subnormals, and they are evenly filling the gap between 0 and Double.MIN_NORMAL. That means that the computations involving subnormals can lead to less accurate results. Using subnormals allows a calculation to lose precision more slowly when the result is small.

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Bosonix's answer is on the right track. To understand why these numbers are what they are and what's the difference between them, we'll have to look deeper.

The Myth

Consider the 64-bit representation (IEEE 754 binary64 format):

s-eee-eeee-eeee-mmmm-mmmm-mmmm-mmmm-mmmm-mmmm-mmmm-mmmm-mmmm-mmmm-mmmm-mmmm-mmmm

The widely-held myth is that the values of these bit representations are equal to (-1)s × 2e-1023 × (1 + m × 2-52) regardless of the values of s, e, and m. This is demonstrably false.

The Truth

IEEE 754 binary64 values are derived as such:

  • If e > 0 && e < 2047 (0b111-1111-1111), then value is equal to (-1)s × 2e-1023 × (1 + m × 2-52). These values are called "normal numbers", also known as "normalized numbers".

  • If e == 0, then value is equal to (-1)s × 2(e+1)-1023 × (0 + m × 2-52). These values are called "subnormal numbers", also known as "denormalized numbers" or "denormal number".

  • If e == 2047 && m == 0, then value is equal to (-1)s × infinity.

  • If e == 2047 && m != 0, then value is equal to NaN. In other words, there is 21 + 52 - 1 different bit representations for NaN (cf. doubleToRawLongBits).

With that Info,

We can see that Double.MIN_NORMAL is equal to the smallest positive binary64 "normal number",

      = (-1)0 × 21-1023 × (1 + 0 × 2-52)

      = 2-1022

      = ~2.225 × 10-308.

On the other hand, Double.MIN_VALUE is equal to the smallest positive binary64 "subnormal number",

      = (-1)0 × 2(0+1)-1023 × (0 + 1 × 2-52)

      = 2-1022 × 2-52

      = 2-1074

      = ~4.94 × 10-324.

Also, .NET's equivalent of Java's Double.MIN_VALUE is Double.Epsilon.

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