The private key of the other curves are variable as well, but they are less likely to exhibit this variance when it comes to encoding to bytes.

The public key is encoded as two *statically sized* integers, prefixed with the uncompressed point indicator `04`

. The size is identical to the key size in bytes.

The private key doesn't really have an pre-established encoding. It is a single random value (or vector) within the range 1..N-1 where N is the order of the curve. Now if you encode this value as a *variable sized* unsigned number then *usually* it will be the same size as the key in bytes. However, it may by chance be one byte smaller, or two, or three or more. Of course, the chance that it is *much* smaller is pretty low.

Now the 521 bit key is a bit strange that the first, most significant byte of the order doesn't start with a bit set to 1; it only has the *least* significant bit set to 1. This means that there is a much higher chance that the most significant byte of the private value (usually called `s`

) is a byte shorter.

The exact chance of course depends on the full value of the order:

```
01FF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF
FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFA
51868783 BF2F966B 7FCC0148 F709A5D0
3BB5C9B8 899C47AE BB6FB71E 91386409
```

but as you may guess it is pretty close to 1 out of 2 because there are many bits set to 1 afterwards. The chance that two bytes are missing is of course 1 out of 512, and three bytes 1 out of 131072 (etc.).

Note that ECDSA signature sizes may fluctuate as well. The X9.42 signature scheme uses two DER encoded *signed* integers. The fact that they are signed may introduces a byte set all to zeros if the most significant bit of the most significant byte is set to 1, otherwise the value would be interpreted as being negative. The fact that it consists of two numbers, r and s, and that the size of DER encoding is also dependent of the size of the encoded integers makes the size of the full encoding rather hard to predict.

Another less common (flat) encoding of an ECDSA signature uses the same statically sized integers as the public key, in which case it is just twice the size of the order N in bytes.

ECDH doesn't have this issue. Commonly the shared secret is the statically encoded X coordinate of the point that is the result of the ECDH calculation - or at least a value that is derived from it using a Key Derivation Function (KDF).