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== Can Eve decrypt the message without finding the inverse of the secret matrix? == | == Can Eve decrypt the message without finding the inverse of the secret matrix? == | ||
| − | + | <math>\,B=B_1+B_2+B_3\,</math> and <math>\,C=C_1+C_2+C_3\,</math> | |
| − | <math>\,B=\ | + | |
| − | + | ||
| − | + | Thus,we can have: | |
| − | + | ||
| − | + | <math>\,B_1 = C_1*A^{-1}\,</math> | |
| − | <math>\,C_1 | + | |
| − | + | <math>\,B_2 = C_2*A^{-1}\,</math> | |
| − | <math>\, | + | <math>\,B_3 = C_3*A^{-1}\,</math> |
| − | <math>\, | + | if we can decompose <math>\,C_new=n*C_1+p*C_2+q*C_3\,</math> |
| + | we have: | ||
| − | <math>\, | + | <math>\,B_1new = n*C_1*A^{-1} = n*B_1\,</math> |
| − | + | <math>\,B_2new = p*C_2*A^{-1} = p*B_2\,</math> | |
| − | + | ||
| + | <math>\,B_3new = q*C_3*A^{-1} = q*B_3\,</math> | ||
| − | + | So we can get: | |
| − | <math>\, | + | <math>\,B_new = B_1new+B_2new+B_3new = n*B_1+p*B_2+q*B_3 \,</math> |
| − | + | so all Eve need to do is to express the encrypted message in terms of a*[2,0,0]+b*[0,1,0]+c*[0,0,3] | |
| − | + | then the original code is a*[1,0,4]+b*[0,1,0]+c*[1,0,1] | |
== What is the Decrypted Message? == | == What is the Decrypted Message? == | ||
Revision as of 17:11, 18 September 2008
How can Bob Decrypt the Message?
Let A be the 3x3 secret matrix message.
$ \,A=\left[ \begin{array}{ccc} a_{11} & a_{12} & a_{13} \\ a_{21} & a_{22} & a_{23} \\ a_{31} & a_{32} & a_{33} \end{array} \right] \, $
Let B be the 3x3 matrix for the original message.
$ \,B=\left[ \begin{array}{ccc} b_{11} & b_{12} & b_{13} \\ b_{21} & b_{22} & b_{23} \\ b_{31} & b_{32} & b_{33} \end{array} \right] \, $
Correspondingly, let C be the crypted message
From the poblem: $ \,C = B * A\, $
So $ \,C*A^{-1} = B * A * A^{-1} = B\, $, i.e. $ \,B = C*A^{-1} $
Thus Bob can decrypt the message by finding the inverse of the secret matrix.
Can Eve decrypt the message without finding the inverse of the secret matrix?
$ \,B=B_1+B_2+B_3\, $ and $ \,C=C_1+C_2+C_3\, $
Thus,we can have:
$ \,B_1 = C_1*A^{-1}\, $
$ \,B_2 = C_2*A^{-1}\, $
$ \,B_3 = C_3*A^{-1}\, $
if we can decompose $ \,C_new=n*C_1+p*C_2+q*C_3\, $ we have:
$ \,B_1new = n*C_1*A^{-1} = n*B_1\, $
$ \,B_2new = p*C_2*A^{-1} = p*B_2\, $
$ \,B_3new = q*C_3*A^{-1} = q*B_3\, $
So we can get:
$ \,B_new = B_1new+B_2new+B_3new = n*B_1+p*B_2+q*B_3 \, $
so all Eve need to do is to express the encrypted message in terms of a*[2,0,0]+b*[0,1,0]+c*[0,0,3]
then the original code is a*[1,0,4]+b*[0,1,0]+c*[1,0,1]
What is the Decrypted Message?
The given encrypted message is
$ \,e=(2,23,3)\, $
This can be rewritten as a linear combination of the given system result vectors
$ \,e=ae_1+be_2+ce_3\, $
$ \,e=(2,23,3)=1\cdot (2,0,0)+23\cdot (0,1,0)+1\cdot (0,0,3)\, $
Because the system s linear, we can write the input as
$ \,m=am_1+bm_2+cm_3\, $
$ \,m=1\cdot (1,0,4)+23\cdot (0,1,0)+1\cdot (1,0,1)=(2,23,5)\, $
Therefore, the unencrypted message is "BWE".
