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} × 2^{e-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} × 2^{e-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 **2**^{1 + 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} × 2^{1-1023} × (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`

.