Identification and Authentication
1
CHAPTER 9: User identification and  message authentication, Secret sharing and E-commerce
Most of today's applications of cryptography ask for authentic data rather than secret data. A
practically very important problem is therefore how  to protect data and communication against an
active attacker (and noise).
Main related problems to deal with are:
1. User identification (authentication): How can a person prove his (her) identity?
IV054
2. Message authentication: Can tools be provided to decide, for the recipient, that the message is
from the person who is supposed to send it?
3. Message integrity (authentication): Can tools be provided to decide for the recipient whether or
not the message was changed on the fly?
1.
Important  practical objectives are to find  identification schemes that are so simple  that it can
be implemented on  smart cards - they are essentially credit cards equipped with a chip that can
perform arithmetical operations and communications.
E-commerce: One of the main new application of the cryptographic techniques is to establish secure
and convenient manipulation with digital money (e-money), especially for e-commerce.

2
Identification and Authentication
USER IDENTIFICATION (AUTHENTICATION)
User identification (authentication) is a process at which one party (often referred to  as a
Prover  or Alice) convinces a second party often referred to as a Verifier or Bob) of Prover’s
identity.
(Namely, that the Prover has actually participated in the identication process. In other words that
the Prover has been active in the time the confirmative evidence of identity has been recquired).
The purpose of any identification (authentication) process is to preclude (vylucit) some
impersonation (zosobnenie) of one person (the Prover) by someone else.
Identication usually serves to control access to a resource (often a resource should be accessed
only by  privileged users).
IV054

>

3
Identification and Authentication
OBJECTIVES of IDENTICATIONS
User identification process has to satisfy the following objectives:
•The Verifier has to accept Prover’s identity if both parties are honest;
•
•The Verifier cannot later, after a successful identication, pose as the Prover and identicate
himself (as  the Prover) to another Verifier;
•
•A dishonest party that would claim to be the other party has only negligible chance to identicate
itself successfully;
•
•Each of the above conditions remains true even if an attacker has observed or has participated in
several identification protocols.
IV054

>

4
Identification and Authentication
USER IDENTIFICATION PROTOCOLS
Identification protocols  have to satisfy two security conditions:
1.If one party, say Bob (a verifier), gets a message from the other party, say Alice (a prover),
then Bob is able to verify that the sender was indeed  Alice.
2.
2.There is no way to pretend, for a third party, say Charles, when communicating with Bob, that he
is Alice without Bob having a large chance to find out that.
1.
IV054

>

5
Identification and Authentication
Identification system based on a PKC
• Alice chooses a random r and sends  e B (r) to Bob.
• Alice identifies a communicating person as Bob if he can send  her back r.
• Bob identifies a communicating person as Alice if she can send  him  r.
A misuse of the above system
We show  that (any non-honest)  Alice could misuse the above identification scheme.
Indeed, Alice  could intercept a communication of a Jane ( a new “player'') with Bob, and  get a
cryptotext e B (w), the one Jana has been sending to Bob,  and then Alice could send e B (w)  to
Bob.
Honest Bob, who follows fully the  protocol, would then return w to Alice and she would get this
way the plaintext w.
IV054

>

6
Identification and Authentication
ELEMENTARY AUTHENTICATION PROTOCOLS
USER IDENTIFICATION
Static means of identification: People can be identified by their attributes (fingerprints),
possessions (passports), or knowledge.
Dynamic means of identification: Challenge and respond protocols.
Both Alice and Bob share a key k and a one-way function f k.
1. Bob sends Alice a random number or string RAND.
2. Alice sends Bob PI = f k (RAND).
3. If Bob gets PI, then he verifies whether PI = f k (RAND).
4.
If yes, he starts to believe that the person he has communicated with is Alice.
The process can be repeated to increase  probability of a correct identification.
IV054
Message authentication – to be discussed later
MAC - method (Message Authentication Code) Alice and Bob share a key k and a encoding algorithm Ak
1. With a message m, Alice sends (m, A k (m))  -- MAC is here
2. If Bob gets (m', MAC), then he computes A k (m') and compares it with MAC.

7
Identification and Authentication
Three-way authentication and also key agreement
IV054
A PKC will be used with encryption/decryption algorithms (e, d) and
DSS with pairs (s, v). Alice and Bob will have their identity strings IA
and IB.
1. Alice chooses a random rA, sets t = (IB, rA), signs sigsA(t) and sends m1 = (t, sigsA(t)) to
Bob.
2. Bob verifies Alice’s signature, chooses random rB and a random session key k. He encrypts k with
Alice’s public key, EeA(k) = c, sets
t1 = (IA, rA, rB, c),
    signs it with sigsB(t1). Then he sends m2 = (t1, sigsB(t1)) to Alice.

>

8
Identification and Authentication
Three-way authentication and key agreement
IV054
3. Alice verifies Bob’s signature, and checks that the rA she just got matches the one she
generated in Step 1. Once verified, she is convinced that she is communicating with Bob. She gets k
via
DdA(c) = DdA(EeA(k)) = k,
     sets  t2= (IB, rB) and signs it with sigsA(t2). Then she sends m3 = (t2, sigsA(t2)) to Bob.
4. Bob verifies Alice’s signature and checks that rB he just got matches his choice in Step 2. If
both verifications pass, Alice and Bob have mutually authenticated each other identity and have
agreed upon a session key k.

>

9
Identification and Authentication
DATA AUTHENTICATION
The goal of data authentication schemes (protocols)  is to handle the case that data are sent
through insecure channels.
By creating so-called Message Authentication Code (MAC) a sending this MAC, together with a message
through an insecure channel, one can create possibility to verify  whether data were not changed in
the channel.
The price to pay is that communicating parties need to share a secret random key that need to be
transmitted through a very secure channel.l

>

10
Identification and Authentication
Schemes for Data Authentication
Basic difference between MACs and digital signatures is that MACs are symmetric in the following
sense: Anyone who is able to verify MAC of a message is also able to generate the same MAC, and
vice versa.
A scheme (M, T, K) for  data authentication is given by:
–M is a set of possible messages (data)
–T is a set of possible MACs
–K is a set of possible keys
Moreover, it is required that
–to each k from K there is a single and easy to compute authentication mapping
authk: {0,1}* x M ® T
–and a single easy to compute verification mapping
verk: M x T ® {true, false}
Two conditions should be satisfied for such a scheme:
Correctness: For each m from M and k from K it holds verk(m, c) = true, if there exists an r from
{0, 1}* such that c = autk(r, m)
Security: For any m from M and k from K it is computationally unfeasible, without a knowledge of k,
to find c from T such that verk(m, c) = true
IV054

>

11
Identification and Authentication
FROM BLOCK CIPHERS to MAC – CBC-MAC
Let C be an encryption algorithm that maps kbit strings into kbit strings.
If a message
m = m1m2...ml
    is divided into blocks of length k, then socalled CBCmode of encryption assumes a choice
(random) of a special block y0 of length k, and performs the following computations for i = 1, . .
. ,l
yi = C(yi-1 Å mi)
and then
y1||y2 || . . . ||yl
is the encryption of m and
yl is MAC for m.
A modification of this method is to use another cryptoalgoritm to encrypt the last block ml.
IV054

>

12
Identification and Authentication
WEAKNESS of the CBS-MAC  METHOD
Let us have three pairs and in each: a message and its MAC
(m1, c1), (m2, c2), (m3, c3)
Where m1 and m3   have the same length k and
m2 = m1||B||m’2.
and let the length of B be also k. The encryption of the block B within m2 is C(B Å c1).
If we now define
B’ = B Å c1 Å c3 , m4 = m3||B’||m’2 ,
then, during the encryption of m4, we get
C(B’ Å c3) = C(B Å c1),
This implies that MAC's for m4 and m2 are the same.
One can therefore forge a new valid pair
(m4, c2).
IV054

>

13
Identification and Authentication
ANALYSIS of CBCMAC – a view
Theorem Given are two independent random permutations C1 and C2 on the set of message blocks M of
cardinality n. Let us define
MAC(m1, m2, . . . , ml) = C2(C1(...C1(C1(m1) Å m2) Å... Å ml-1  Å ml).
Let us assume that the MAC function be implemented by an oracle, and consider an adversary who can
send queries to the oracle with a limited total length of q. If m1, ..., md denote the finite block
sequences on M which are sent by the adversary to the oracle and let the total number of blocks be
less than q. Let the purpose of the adversary be to output a message m which is different from all
mi together with its MAC value c. Then the probability of success of the adversary (i.e. the
probability that his MAC value is correct) is smaller than
When q = qn1/2, this is approximately a = q2/2 (which is greater than 1 – e-a )
Implication: if the total length of all authenticated messages is negligible against   # n, then
there is no better way than the brute force attack to get collisions on the CBCMAC.
IV054

>

14
Identification and Authentication
FROM HASH FUNCTIONS TO MAC
So called HMAC was published as the internet standard RFC2104.
Let a hash function h processes messages by blocks of b bytes and produces a digest of l bytes and
let t be the size of MAC, in bytes. HMAC of a message m with a key k is computed as follows:
•If k has more than b bytes replace k with h(k).
•Append zero bytes to k to have exactly b bytes.
•Compute (using strings opad and ipad defined later)
h(k Å opad||h(k Å ipad||m)).
and truncate the results to its t leftmost bytes to get
HMAXk(m).
In HMAX ipad (opad) consists of b bytes equal to 0x36 (0x5c) hexadecimal.
IV054

>

15
Identification and Authentication
SECURITY of HMAC
It can be shown that if
•h(k Å ipad||m) defines a secure MAC on fixed length messages, and
•h is collision free,
then HMAC is a secure MAC on variable length messages
with two independent keys. More precisely:
Theorem Let h be a hash function which hashes into l bits. Given k1, k2 from {0, 1}l consider the
following MAC algorithm
MACk1,k2(m) = h(k2||h(k1||m))
If h is collision free and m ® h(k2||m) is a secure MAC algorithm for messages m of the fixed
length l, then the MAC is a secure MAC algorithm for messages of arbitrary length.
IV054

>

16
Identification and Authentication
Disadvantage of static user identification schemes
Everybody who knows your password or PIN can impersonate you.
Using so called zero-knowledge identification schemes, discussed in  the next chapter, you can
identify yourself without giving to the identificator the ability to impersonate you.
IV054

>

17
Identification and Authentication
Simplified Fiat-Shamir identification scheme
A trusted authority (TA) chooses: large random primes p,q , computes  n = pq;
and chooses a quadratic residue v Î QR n, and s such that  s 2 = v (mod n).
public-key: v
private-key: s (that Alice knows, but not Bob)
Challenge-reponse Identification protocol
(1) Alice chooses a random r < n, computes x = r 2 mod n and sends x to Bob.
(2) Bob sends to Alice a random bit (a challenge) b.
(3) Alice sends Bob (a response) y = rs b mod n
(4) Bob identifies the sender as Alice  if and only if y 2 = xv b mod n, what is taken as a proof
that the sender knows  square roots of x and of  v.
IV054
This protocol is a so-called single accreditation protocol
Alice proves her identity by convincing Bob that she knows square root s of  v (without revealing s
to Bob).
If protocol is repeated t times, Alice has a chance 2 -t to fool Bob if she does not known s.

18
Identification and Authentication
Analysis of Fiat-Shamir identification I
public-key: v
private-key: s (of Alice) such that s 2 = v.
Protocol
(1)Alice chooses a random r < n, computes x = r 2 mod n and sends x (her commitment) to Bob.
(2)
IV054
(2) Bob sends to Alice a random bit b (a challenge).
(3) Alice sends to Bob (a response) y = rs b.
(4) Bob verifies if and only if  y 2 = xv b mod n, proving that Alice knows a square root of x.

19
Identification and Authentication
Analysis of Fiat-Shamir identification II
Analysis
1. The first message is a commitment by Alice that she knows square root of x.
2. The second message is a challenge by Bob.
3.
• If Bob sends b = 0, then Alice has to open her commitment and reveals r.
• If Bob sends b = 1, the Alice has to show her secret s in an “encrypted form''.
•
3. The third message is Alice's response to the challenge of Bob.
IV054
Completeness If Alice knows s, and both Alice and Bob follow the protocol, then the response rs
b is the square root of xv b.
It can be shown that Eve can cheat with probability of success ½ as follows:
• Eve chooses random r Î Zn*, random b 1 Î {0,1} and sends x = r 2 v -b1, to Bob.
• Bob chooses b Î {0,1} at random and sends it to Alice.
• Alice sends r to Bob.

20
Identification and Authentication
HOW CAN A BAD EVE CHEAT?
Eve can send, to fool Bob, as her commitment, either         for a random r or
In the first case Eve can respond correctly to the Bob’s challenge b=0, by sending r; but cannot
respond correctly to the challenge b = 1.
In the second case Eve can respond correctly to Bob’s challenge
 b = 1, by sending r again; but cannot respond correctly to the challenge  b = 0.
Eve has therefore a 50% chance to cheat.

>

21
Identification and Authentication
Fiat-Shamir identification scheme parallel version
In the following parallel version of Fiat-Shamir idenitification scheme the probability of false
identification is decreased.
Choose primes p,q, compute n = pq.
Choose quadratic residues v 1,…,v k Î QR n.
Compute s 1,…,s k  such that
public-key: v 1,…,v k
secret-key: s 1,…,s k of Alice
(1) Alice chooses a random r < n, computes a = r 2 mod n and sends a to Bob.
(2) Bob sends Alice a random k-bit string b 1… b k.
(3) Alice sends to Bob
(4) Bob accepts if and only if
Alice and Bob repeat this protocol t times, until Bob is convinced that Alice knows s1,…,sk .
The chance that Alice fools Bob is 2 -kt, a decrease comparing with the chance 1/2 of the previous
version of the identification scheme.
IV054

22
Identification and Authentication
The Schnorr identification scheme - setting
This is a practically attractive and  computationally efficient (in time, space + communication)
scheme which minimizes storage + computations performed by Alice (to be a smart card).
Scheme requires also a trusted authority (TA) which
(1) chooses: a large prime p < 2 512,
     a large prime q dividing p -1  and q Ł 2 140,
     an a Î Z p* of order q,
     a security parameter t such that 2 t < q,
     p, q, a, t are made public.
(2) establishes: a secure digital signature scheme with a secret signing algorithm sig TA and a
public verification algorithm ver TA.
IV054
Protocol for issuing a certificate to Alice
1. TA establishes Alice's identity by conventional means and forms a string ID(Alice) which
contains identification information.
•
2. Alice chooses a secret random 0 Ł a Ł q -1 and computes
v = a -a mod p
and sends v to the TA.
3. TA generates signature
s = sig TA (ID(Alice), v)
and sends to Alice the certificate   C (Alice) = (ID(Alice), v ,s)

23
Identification and Authentication
Schnorr identification scheme
1. Alice chooses a random 0 Ł k < q and computes
g =  a k mod p.
IV054
2. Alice sends her certificate C (Alice) = (ID(Alice), v, s) and g to Bob.
3. Bob verifies the signature of the TA by checking that
ver TA (ID(Alice), v, s) = true.
4. Bob chooses a random 1Ł r Ł 2 t, where t < lg q is a security parameter and sends it to Alice
(often t Ł 40).
5. Alice computes and sends to Bob
y = (k + ar) mod q.
6. Bob verifies that
This way Alice shows her identity to Bob. Indeed,
Total storage: 512 bits for ID(Alice), 512 bits for v, 320 bits for s (if DSS is used), total -
1344 bits.
Total communication: Alice ® Bob 1996 bits,
 Bob ® Alice 40 bits.

24
Identification and Authentication
Okamoto identification scheme
The disadvantage of the Schnorr identification scheme is that there is no proof of its security.
For the  modification of the Schnorr identification scheme presented below, for Okamoto
identification scheme, a proof of security exists.
Basic setting: To set up the scheme the TA chooses:
• a large prime p Ł 2 512,
• a large prime q ł 2 140 dividing p -1;
• two elements a 1, a 2 Î  Z p* of order q.
•
TA makes public p, q, a 1, a 2 and keeps secret (also before Alice and Bob)
c = lga1 a 2.
Finally, TA chooses a signature scheme and a hash function.
IV054
Issuing a certificate to Alice
• TA establishes Alice's identity and issues an identification string ID(Alice).
• Alice secretly and randomly chooses 0 Ł a 1, a 2 Ł q -1 and sends to TA
v = a1 -a1a 2 -a2 mod p.
• TA generates a signature s = sig TA(ID(Alice), v) and sends to Alice the certificate
C (Alice) = (ID(Alice), v, s).

25
Identification and Authentication
Okamoto identification scheme – basics once more
Basic setting
TA chooses: a large prime p Ł 2 512,large prime q ł 2 140 dividing p -1; two elements a 1, a 2 Î  Z
p* of order q. TA keep secret (also from Alice and Bob)
c = lga1 a 2.
Issuing a certificate to Alice
• TA establishes Alice's identity and issues an identification string ID(Alice).
• Alice  randomly chooses 0 Ł a 1, a 2 Ł q -1 and sends to  TA.
v = a1 -a1a 2 -a2 mod p.
• TA generates a signature s = sig TA(ID(Alice), v) and sends to Alice the certificate
C (Alice) = (ID(Alice), v, s).
IV054

>

26
Identification and Authentication
Okamoto identification scheme
Okamoto identification scheme
• Alice chooses random 0 Ł k1, k2 Ł q -1 and computes
g = a1 k1a 2 k2 mod p.
IV054
• Alice sends to Bob her certificate (ID(Alice), v, s) and g.
• Bob verifies the signature of TA  by checking that
verTA (ID(Alice), v, s) = true.
• Bob chooses a random 1Ł r Ł 2 t and sends it to Alice.
• Alice sends to Bob
y1 = (k1 + a1r)  mod q; y2 = (k2 + a2 r)  mod q.
• Bob verifies
g º a1 y1a 2 y2  v r  (mod p)

27
Identification and Authentication
Authentication codes
They provide methods of ensuring integrity of messages - that a message has not been
tampered/changed, and that message originated with the presumed sender.
The goal is to achieve authentication even in the presence of Mallot, a man in the middle, who can
observe transmitted messages and replace them by messages of his own choise.
Formally, an authentication code consists:
• A set M of possible messages.
• A set T of possible authentication tags.
• A set K of possible keys.
• A set  R of authentication algorithms a k: M ® T, one for each k Î K
IV054
Transmission process
• Alice and Bob jointly choose a secret key k.
• If Alice wants to send a message w to Bob, she sends (w, t), where t = a k (w).
• If Bob receives (w, t) he computes t‘ = a k (w) and if t = t' Bob accepts the message as
authentic.

28
Identification and Authentication
Attacks and deception probabilities
There are two basic types of attacks Mallot, the man in the middle,can do.
Impersonation. Mallot introduces a message (w, t) into the channel expecting that  message will be
received as being sent by Alice.
Substitution. Mallot replaces a message (w, t) in the channel by a new one, (w', t'), expecting
that message will be accepted as being sent by Alice.
With any impersonation (substitution) attack a probability P i (P s) is associated that Mallot will
deceive Bob, if Mallot follows an optimal strategy.
In order to determine such probabilities we need to know  probability distributions p m on messages
and p k on keys.
In the following so called  |K| ´ |M| authentication matrice will tabulate all authenticated tags.
The item in a row corresponding to a key k and in a column corresponding to a message w will
contain the authentication tag  t k (w).
The goal of authentication codes, to be discussed next, is to decrease probabilities that Mallot
performs successfully impersonation or substitution.
IV054

>

29
Identification and Authentication
Example
Let M = T = Z3, K = Z3 ´ Z3.
For (i, j) Î K and w Î M, let tij(w) = (iw + j) mod 3.
The matrix key x message of  authentication tags has the form
IV054
Key
0
1
2
(0,0)
0
0
0
(0,1)
1
1
1
(0,2)
2
2
2
(1,0)
0
1
2
(1,1)
1
2
0
(1,2)
2
0
1
(2,0)
0
2
1
(2,1)
1
0
2
(2,2)
2
1
0
Impersonation attack: Mallot picks a message w and tries to guess the correct authentication tag.
However, for each message w and each tag a there are exactly three keys k such that
t k (w) = a. Hence P i = 1/3.
Substitution attack: By checking the table one can see that if Mallot observes an authenticated
messages (w, t), then there are only three possibilities for the key that was used.
Moreover, for each choice (w', t'), w ¹ w', there is exactly one of the three possible keys for
(w,t) that can be used. Therefore P s = 1/3.

30
Identification and Authentication
Computation of deception probabilities I
Probability of impersonation: For w Î M, t Î T, let us define payoff(w, t) to be the probability
that Bob accepts the  message (w, t) as authentic. Then
(4)
(5)
In other words, payoff(w, t) is computed by selecting the rows of the authentication matrix that
have entry t in column w and summing probabilities of the corresponding keys.
Therefore       P I = max {payoff (w, t), | w  Î M, t Î A}.
IV054
Probability of substitution: Define, for w, w‘Î M, w ¹ w' and t,t‘Î A, payoff(w',t‘,w,t) to be  the
probability that a substitution of (w, t) with (w', t') will succeed to deceive Bob. Hence
(6)
(7)
(8)
Observe that the numerator in the last fraction is found by selecting rows of the authentication
matrix with value t in column w and t' in column w'.

31
Identification and Authentication
Computation of deception probabilities II
Since Mallot wants to maximize his chance of deceiving Bob, he needs to compute
p w,t = max {payoff(w', t', w, t) | w‘Î M, w ¹ w', t' Î A}.
p w,t therefore denotes the probability that Mallot can deceive Bob with a substitution in the case
(w, t) is the message observed.
If PrMa(w, t) is the probability of observing a message (w, t) in the channel, then
and
The next problem is to show how to construct an authentication code such that the deception
probabilities are as low as possible.
The concept of orthogonal arrays, introduced next, serves well such a purpose.
IV054

32
Identification and Authentication
Orthogonal arrays
Definition An orthogonal array OA(n, k, l) is a ln 2 ´ k array of n symbols, such that in any two
columns of the array every one of the possible n 2 pairs of symbols occurs in exactly l rows.
Example OA(3,3,1) obtained from the authentication matrix presented before;
IV054
orthogonal array
authentication code
row
authentication rule
column
message
symbol
authentication tag
Theorem Suppose we have an orthogonal array OA(n, k, l).Then there is an authentication code with
|M| = k, |A| = n, |K|= ln 2 and P I = P s = 1/n.
Proof Use each row of the orthogonal array as an authentication rule (key) with equal probability.
Therefore we have the following correspondence:

33
Identification and Authentication
Construction and bounds for OAs
In an orthogonal array OA(n, k, l)
• n determines the number of authenticators (security of the code);
• k is the number of messages the code can accommodate;
• l relates to the number of keys - ln 2.
•
The following holds for orthogonal arrays.
• If p is prime, then OA(p, p, 1) exits.
• Suppose there exists an OA(n, k, l). Then
•
• Suppose that p is a prime and d Ł 2 an integer. Then there is an orthogonal array OA(p, (p
d -1)/(p -1), p d-2).
• Let us have an authentication code with |A| = n and P i = P s = 1/n.Then      |K| ł n 2.
Moreover, |K| = n 2 if and only if there is an orthogonal array       OA(n, k,1), where |M| = k and
P K (k) = 1/n 2 for every key k Î K.
•
The last claim shows that there are no much better approaches to authentication codes with
deception probabilities as small as possible than orthogonal arrays.
IV054

34
Identification and Authentication
Secret sharing between two parties
IV054
A moderator distributes a binary-string secret s, between two parties
P1 and P2 by choosing a random binary string b, of the same length
as s, and
  • by sending b to P1 and
  • by sending s Å b to P2.
This way, none of the parties P1 and P2 alone has a slightest idea
about s, but both together easily recover s by computing
b Å (s Å b) = s.

>

35
Identification and Authentication
Threshold secret sharing schemes
Secret sharing schemes distribute  a “secret'' among several users in such a way that only
predefined sets of users can “assemble'' the secret.
For example, a vault in the bank can be opened only if at least two out of three responsible
employees use their knowledge and tools to open the vault.
An important special simple case of secret sharing schemes are threshold secret sharing schemes at
which a certain threshold of participant is needed and sufficient to assemble the secret.
IV054
Definition Let t Ł n be positive integers. A (n, t)-threshold scheme is a method of sharing a
secret S among a set P of n participants, P = { P i | 1 Ł i Ł n}, in such away that  any t, or
more, participants can compute the value S, but no group of     t -1, or less, participants can
compute S.
Secret S is chosen by a “dealer'' D Ď P.
It is assumed that the dealer “distributes'' the secret to participants secretly and in such a way
that no participant knows shares of other participants.

36
Identification and Authentication
Shamir's (n,t)-threshold scheme
Initial phase:
Dealer D chooses a prime p,  n distinct x i, 1 Ł i Ł n and D gives  randomly chosen values x i to
the user P i.
The values  x i are then public.
IV054
Share distribution: Suppose D wants to share a secret S Î Z p among the users. D randomly chooses t
-1 elements of Z p, a 1,…,a t-1.
For 1 Ł i Ł n, D computes the “shares'' y i = a(x i),
where
For 1 Ł i Ł n , D sends the share yi to the participant P i.
Secret cumulation: Let participants P i1,…, P it want to determine secret S. Since a(x) has degree
t-1, a(x) has the form
a(x) = a 0 + a 1x + … + a t-1x t-1,
and coefficients a i can be determined from t equations a (x ij) = y ij, where all arithmetic is
done modulo p.
It can be easily shown that equations obtained this way are linearly independent and the system has
a unique solution.
In such a case S = a 0.

37
Identification and Authentication
Shamir's scheme - technicalities
Shamir's scheme uses the following result concerning polynomials over fields Zp, where p is prime.
Theorem Let         be a polynomial of degree t -1 and let
S be a  set {(x i, f(x i)) | x i Î Zp, i =1,…,t, x i ą x J if i ą j }.  For any Q Í S,
let                           P Q = { g Î Z p [x] |  deg(g) = t -1, g(x) = y for all (x,y) Î Q}.
Then it holds:
• PS = {f(x)}, i.e. f is the only polynomial of degree t -1, whose graph contains all t points in
P.
•
• If Q  is a proper subset of S and x ą 0 for all (x, y) Î Q, then each a Î Z p appears with the
same frequency as the constant coefficient of  polynomials in PQ.
IV054
Corollary (Lagrange formula) Let   be a
polynomial and let P = {(x I, f(x i)) | i = 1,…,t, x i ą x J, i ą j }. Then

38
Identification and Authentication
Shamir's (n,t)-threshold scheme - summary
To distributes n shares of a secret S among users P 1,…, P n a trusted authority TA proceeds as
follows:
• TA chooses a prime p > max{S, n} and sets a 0 = S.
• TA selects randomly a 1,…, a  t-1 Î Z p and creates polynomial
• TA computes s i = f (i), i = 1,…, n and transfers each (i, s i) to the user P i in a secure way.
•
Any group J of t or more users can compute the secret. Indeed, from the previous corollary we have
In case |J| < t, then each a0 € Z p is equally likely to be the secret.
IV054

39
Identification and Authentication
SECRET SHARING – GENERAL CASE
A serious limitation of the threshold secret sharing schemes is that all groups of users with the
same number of users have the same access to secret. Practical situations usually require that some
(sets of) users are more important than others.
Let P be a set of users. To deal with above situation such concepts as authorized set of user and
access structure are used.
An authorized set of users            is a set of users who can together construct the secret.
An unauthorized set of users                is a set of users who alone cannot learn anything about
the secret.
Let P be a set of users. The access structure             is a set such
that                            for all authorized sets A and                   for all
unauthorized sets U.
Theorem: For any access structure there exists a secret sharing scheme realizing this access
structure.
IV054

>

40
Identification and Authentication
Secret Sharing Schemes with Verification
•Secret sharing protocols increase security of a secret information by sharing it between several
subjects.
•
•Some secret sharing scheme are such that they work even in case some participants behave
incorrectly.
•
•A secret sharing scheme with verification is such a secret sharing scheme that:
–Each Pi is capable to verify correctness of his/her
    share si
–No participant Pi  is able to provide incorrect information and to convince others about its
correctness
1.
IV054

>

41
Identification and Authentication
Feldman’s (n,k)-Protocol
Feldman’s protocol is an example  of the secret sharing scheme with verification. The protocol  is
a generalization of Shamir's protocol. It is assumed that all n participants can broadcast messages
to all others and each of them  can determine all senders..
Given are large primes p, q, q|(p - 1), q > n and h < p  a generator of Z*p . All these numbers,
and also the number g = h(p-1)/q mod p, are public.
As in Shamir's scheme, the dealer assigns to each participant Pi a specific xi from {1, . . , q –
1}  and generates a random polynomial
                            f(x) =
(1)
such that f(0) = s and sends to each Pi value yi = f(xi). In addition,
using a broadcasting scheme, the dealer sends to each Pi all values
vj = gaj mod p.
IV054

>

42
Identification and Authentication
Feldman’s (n,k)-Protocol (cont.)
Each Pi verifies that
If (1) does not hold, Pi asks, using the broadcasting scheme, the dealer to broadcast correct value
of yi. If there are at least k such requests, or some of the new values of yi does not satisfies
(1), the dealer is considered as not reliable.
One can easily verify that if the dealer works correctly, then all relations (1) hold
IV054

>

43
Identification and Authentication
E-COMMERCE
Very important is to ensure security of e-money transactions needed                    for
e-commerce.
In addition to providing security and privacy, the task  is also to prevent alterations of purchase
orders and forgery of credit card information.
IV054
Basic requirements for e-commerce system:
Authenticity: Participants in transactions cannot be impersonated and signatures cannot be forged.
Integrity: Documents (purchase orders, payment instructions,...) cannot be forged.
Privacy: Details of transaction should be kept secret.
Security: Sensitive information (as credit card numbers) must be protected.
Anonymity: Anonymity of  money senders should be guaranteed.
Additional requirement: In order to allow an efficient fighting of the organized crime a system for
processing e-money has to be such that under well defined conditions it has to be possible to
revoke customer's identity and flow of e-money.
(Secure Electronic Transaction) protocol was created to standardize the exchange of credit card
information. Development os SET initiated in 1996 the credit card companies MasterCard and Visa.

44
Identification and Authentication
DUAL SIGNATURE PROTOCOL
We present  a protocol to solve the following security and privacy problem  in e-commerce:
shoppers banks should not know what cardholders are ordering and shops should not learn  credit
cards numbers.
Participants of our e-commerce  protocol: a bank, a cardholder, a shop
The cardholder uses the following information:
• GSO - Goods and Service Order (cardholder's name, shop's name, items being ordered, their
quantity,...)
• PI - Payment instructions (shop's name, card number, total price,...)
Protocol uses a public hash function h.
RSA cryptosystem is used and
• e C, e S and e B are public keys of cardholder, shop, bank and
• d C, d S and d B are  their secret keys.
IV054

>

45
Identification and Authentication
CARDHOLDER and SHOP ACTIONS
A cardholder performs the following procedure--GSO-goods and service order
1.Computes HEGSO = h (e S(GSO)) - hash value of the encryption of GSO.
2.Computes HEPI = h (e B(PI)) - hash value of the encryption of the payment
instructions.
3.Computes HPO = h (HEPI || HEGSO) - Hash values of the Payment Order.
4.Signs HPO by computing “Dual Signature'' DS = d C(HPO).
5.Sends e S(GSO), DS, HEPI, and e B(PI) to shop.
IV054
Shop does the following: (payment instructions)
•Calculates h (e S(GSO)) = HEGSO;
•Calculates h (HEPI || HEGSO) and e C(DS). If they are equal, shop has verified by that the
cardholder signature;
•Computes d S(e S(GSO)) to get GSO.
•Sends HEGSO, HEPI, e B(PI), and DS to the bank.

46
Identification and Authentication
BANK and SHOP ACTIONS
Bank has received  HEPI, HEGSO, e B(PI), and DS and performs the following actions.
1. Computes h (e B(PI)) - what should be equal to HEPI.
2.
2. Computes h (h (e B(PI)) || HEGSO) what should be equal to e C(DS) = HPO.
3.
3. Computes d B(e B(PI)) to obtain PI;
4.
4. Returns an encrypted (with e S) digitally signed authorization to shop, guaranteeing the
payment.
Shop completes the procedure by encrypting, with e C, the receipt to  the cardholder, indicating
that transaction has been completed.
It is easy to verify that the above protocol fulfils basic requirements concerning security,
privacy and integrity.
IV054

>

47
Identification and Authentication
DIGITAL MONEY
Is it possible to have electronic (digital) money?
It seems that not, because copies of digital information are indistinguishable from their origin
and one could therefore hardly prevent double spending,....
T. Okamoto and K. Ohia formulated six properties digital money systems should have.
1. One should be able to send e-money  through e-networks.
2. It should not be possible to copy and reuse e-money.
3. Transactions using e-money should be done off-line - that is no communication with central bank
should  be needed during translation.
4. One should be able to sent e-money  to anybody.
5. An e-coin could be divided into e-coins of smaller values.
Several system of e-money have been created that satisfy all or at least some of the above
requirements.
IV054

>

48
Identification and Authentication
BLIND SIGNATURES - applications
Blind digital signatures allow the signer (bank) to sign a message without seeing its content.
Scenario: Customer Bob would like to give e-money to Shop. E-money have to be signed by a Bank.
Shop must be able to verify Bank's signature. Later, when Shop sends e-money to Bank, Bank should
not be able to recognize that it signed these e-money for Bob. Bank has therefore to sign money
blindly.
Bob can obtain a blind signature for a message m from Bank by executing the Shnorr blind signature
protocol described on the next slide.
IV054
Basic setting
Bank chooses large primes p, q | (p -1) and an g Î Z p of order q.
Let h: {0,1}* ® Z p be a collision-free hash function.
Bank's secret will be a randomly chosen x Î {0,…, p -1}.
Public information: (p, q, g, y = g x ).

49
Identification and Authentication
BLIND SIGNATURES - protocols
1. Shnorr's simplified identification protocol in which Bank proves its identity by proving that it
knows x.
• Bank chooses a random r Î {0,…,q -1}  and send a = g  r to Bob. {By that Bank ``commits’’ itself
to r}.
• Bob sends to Bank a random c Î {0,…,q -1} {a challenge}.
• Bank sends to Bob b = r – cx {a response}.
• Bob accepts the proof that bank knows x if a = g b y c .  {because y=gx
IV054
2. Transfer of the identification scheme to a signature scheme:
Bob chooses as c = h (m || a), where m is message to sign.
Signature: (c, b); Verification rule: a = g b y c; Transcript: (a, c, b).
3. Shnorr's blind signature scheme
• Bank sends to Bob a’ = g r’ with random r’ Î {0,…,q -1}.
• Bob chooses random u,v,w Î {0,…,q -1}, u ą 0, computes a = a’ u g v y w,                c = h
(m||a), c’ = (c - w)u -1 and sends c’ to Bank.
• Bank sends to Bob b’ = r’ - c’x.
Bob verifies whether a’ = g b’y c’, computes b = ub’ + v and gets blind signature s(m) = (c, b) of
m.
Verification condition for the blind signature: c = h (m || g b y c).
Both (a,c,b) and (a’,c’,b’) are valid transcripts.