# Difference among Double.MIN_NORMAL and Double.MIN_VALUE

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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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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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

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

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

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