The message `m`

is 42, and blinding factor `r`

is 11, so the value provided to the authority is `m'`

calculated as:

m' = m * r^{e} mod N
m' = 42 * 11^{11} mod 85
m' = 62

The authority will sign this by calculating `s'`

using:

s' = m'^{d} mod N

Where `d`

is the private exponent.

We must therefore calculate the private exponent which we know to be a value that satisfies the relation:

e * d = 1 mod ɸ(N)

Where `ɸ`

is Euler's totient function. `N`

is the product of two primes `p`

and `q`

per the definition of the RSA algorithm, and since N is small we can easily factor it to determine `p = 5`

and `q = 17`

.

Thus by definition of `ɸ`

:

ɸ(N) = (p-1)(q-1)
ɸ(N) = (5-1)(17-1) = 64

Using the provided results, we can therefore determine:

e * d = 1 mod ɸ(N)
11 * d = 1 mod 64
d = 35

So, the authority should return to us the blinded signature `s'`

calculated as:

s' = m'^{d} mod N
s' = 62^{35} mod 85
s' = 73

To calculate the signature we need to calculate `s`

using:

s = s' * r^{-1} mod N

Here, `r`^{-1}

is the inverse of `r`

such that:

r * r^{-1} = 1 mod N

Again using the given results we can determine `r`^{-1}

as:

r * r^{-1} = 1 mod N
11 * r^{-1} = 1 mod 85
r^{-1} = 31

So the calculation for `s`

becomes:

s = s' * r^{-1} mod N
s = 73 * 31 mod 85
s = 53

Your question says to verify this using the private key, however signatures are verified using the public key, so that's what I shall do here:

To confirm that this is the correct signature, we verify that:

m = s^{e} mod N
m = 53^{11} mod 85
m = 42

We have thus shown that the signature is valid, since `m = 42`

- our original message.