Internet Engineering Task Force IETF MSEC
Internet Draft Perrig, Canetti, Song, Tygar, Briscoe
draft-ietf-msec-tesla-intro-02.txt UC Berkeley / Digital Fountain / IBM / BT
May 2004
Expires: November 2004
TESLA: Multicast Source Authentication Transform Introduction
STATUS OF THIS MEMO
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Abstract
Data authentication is an important component for many applications,
for example audio and video Internet broadcasts, or data distribution
by satellite. This document introduces TESLA, a secure source
authentication mechanism for multicast or broadcast data streams. This
document provides an algorithmic description of the scheme for
informational purposes, and in particular, it is intended to assist
in writing standardizable and secure specifications for protocols
based on TESLA in different contexts.
The main deterrents so far for a data authentication mechanism for
multicast were the seemingly conflicting requirements: loss tolerance,
high efficiency, no per-receiver state at the sender. The problem
is particularly hard in settings with high packet loss rates and
where lost packets are not retransmitted, and where the receiver
wants to authenticate each packet it receives.
TESLA provides authentication of individual data packets, regardless
of the packet loss rate. In addition, TESLA features low overhead for
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both sender and receiver, and does not require per-receiver state at
the sender. TESLA is secure as long as the sender and receiver are
loosely time synchronized.
Table of Contents
1 Introduction . . . . . . . . . . . . . . . . . . . . . . 2
1.1 Notation . . . . . . . . . . . . . . . . . . . . . . . . 3
2 Functionality . . . . . . . . . . . . . . . . . . . . . . 4
2.1 Threat Model and Security Guarantee . . . . . . . . . . . 4
2.2 Assumptions . . . . . . . . . . . . . . . . . . . . . . . 5
3 The Basic TESLA Protocol . . . . . . . . . . . . . . . . 5
3.1 Sketch of protocol . . . . . . . . . . . . . . . . . . . 6
3.2 Sender Setup . . . . . . . . . . . . . . . . . . . . . . 7
3.3 Bootstrapping Receivers . . . . . . . . . . . . . . . . . 7
3.3.1 Time Synchronization. . . . . . . . . . . . . . . . . . . 8
3.4 Broadcasting Authenticated Messages . . . . . . . . . . . 8
3.5 Authentication at Receiver . . . . . . . . . . . . . . . 8
3.6 Determining the Key Disclosure Delay . . . . . . . . . . 9
3.7 An alternative delay description method . . . . . . . . . 10
3.8 Some extensions . . . . . . . . . . . . . . . . . . . . . 11
4 Layer placement . . . . . . . . . . . . . . . . . . . . . 11
5 Security considerations . . . . . . . . . . . . . . . . . 11
6 Acknowledgments . . . . . . . . . . . . . . . . . . . . . 12
7 Bibliography . . . . . . . . . . . . . . . . . . . . . . 12
A Author Contact Information . . . . . . . . . . . . . . . 13
B Full Copyright Statement . . . . . . . . . . . . . . . . 14
1 Introduction
The power of multicast is that one packet can reach millions of
receivers. This great property is unfortunately also a great danger:
an attacker that sends one malicious packet can also potentially
reach millions of receivers. Receivers need multicast source
authentication to ensure that a given packet originates from the correct
source.
In unicast communication, we can achieve data authentication through
a purely symmetric mechanism: the sender and the receiver share a
secret key to compute a message authentication code (MAC) of all
communicated data. When a message with a correct MAC arrives, the
receiver is assured that the sender generated that message. Standard
mechanisms achieve unicast authentication this way, for example TLS
or IPsec [1,2].
The symmetric MAC authentication is not secure in a broadcast
setting. Consider a sender that broadcasts authentic data to mutually
untrusting receivers. The symmetric MAC is not secure: every receiver
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knows the MAC key, and hence could impersonate the sender and forge
messages to other receivers. Intuitively, we need an asymmetric
mechanism to achieve authenticated broadcast, such that every receiver
can verify the authenticity of messages it receives, without being
able to generate authentic messages. Achieving this in an efficient
way is a challenging problem [3].
The standard approach to achieve such asymmetry for authentication is
to use asymmetric cryptography, for instance a digital signature.
Digital signatures have the required asymmetric property: the sender
generates the signature with its private key, and all receivers can
verify the signature with the sender's public key, but a receiver
with the public key alone cannot generate a digital signature for a
new message. A digital signature provides non-repudiation, which is a
stronger property than authentication. Unfortunately, digital
signatures have a high cost: they have a high computation overhead for
both the sender and the receiver, as well as a high communication
overhead. Since we assume broadcast settings where the sender does
not retransmit lost packets, and the receiver still wants to
immediately authenticate each packet it receives, we would need to
attach a digital signature to each message. Because of the high
overhead of asymmetric cryptography, this approach would restrict
us to low-rate streams, and to senders and receivers with powerful
workstations. To deal with the high overhead of asymmetric cryptography,
we can try to amortize one digital signature over multiple messages.
However, such an approach is still expensive in contrast to symmetric
cryptography, since symmetric cryptography is in general 3 to 5 orders
of magnitude more efficient than asymmetric cryptography. In addition,
the straight-forward amortization of one digital signature over multiple
packets requires reliability, as the receiver needs to receive all
packets to verify the signature. A number of schemes that follow this
approach are [4,5,6,7,8]. See [9] for more details.
This document presents the Timed Efficient Stream Loss-tolerant
Authentication protocol (TESLA). TESLA uses mainly symmetric
cryptography, and uses time delayed key disclosure to achieve the
required asymmetry property. However, TESLA requires loosely
synchronized clocks between the sender and the receivers. See more
details in Section 4. Other schemes that follow a similar approach
to TESLA are [10,11,12].
1.1 Notation
To denote the subscript or an index of a variable, we use the
underscore between the variable name and the index, e.g. the key K with
index i is K_i, the key K with index i+d is K_{i+d}. To write a
superscript we use the caret, e.g. the function F with the argument x
executed i times is F^i(x), executed j-1 times we write F^{j-1}(x).
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2 Functionality
TESLA provides delayed per-packet data authentication. The key idea
to providing both efficiency and security is a delayed disclosure of
keys. The delayed key disclosure results in an authentication delay.
In practice, the delay is on the order of one RTT (Round-trip-time).
TESLA has the following properties:
¸ Low computation overhead for generation and verification of
authentication information
¸ Low communication overhead
¸ Limited buffering required for the sender and the receiver, hence
timely authentication for each individual packet
¸ Strong robustness to packet loss
¸ Scales to a large number of receivers
¸ Security is guaranteed as long as the sender and recipients are
loosely time synchronized, where synchronization can take place
at session set-up.
TESLA can be used either in the network layer, or in the transport
layer, or in the application layer. The delayed authentication,
however, requires buffering of packets until authentication is completed.
2.1 Threat Model and Security Guarantee
We design TESLA to be secure against a powerful adversary with the
following capabilities:
¸ Full control over the network. The adversary can eavesdrop,
capture, drop, resend, delay, and alter packets.
¸ Access to a fast network with negligible delay.
¸ The adversary's computational resources may be very large, but
not unbounded. In particular, this means that the adversary can
perform efficient computations, such as computing a reasonable
number of pseudo-random function applications and MACs with
negligible delay. Nonetheless, the adversary cannot find the key
of a pseudorandom function (or distinguish it from a random
function) with non-negligible probability.
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The security property of TESLA guarantees that the receiver never
accepts M_i as an authentic message unless the sender really sent
M_i. A scheme that provides this guarantee is called a secure
broadcast authentication scheme.
Since TESLA requires the receiver to buffer packets before
authentication, the receiver needs to protect itself from a
potential denial-of-service (DOS) attack due to a flood of bogus packets.
2.2 Assumptions
TESLA makes the following assumptions in order to provide security:
1. The sender and the receiver must be be able to loosely
synchronize. Specifically, each receiver must be able to
compute an upper bound on the lag of the receiver clock
relative to the sender clock. We denote this quantity by D_t.
(That is, D_t = sender time - receiver time).
We note that an upper bound on D_t can be easily obtained via
a simple two-message exchange. (Such an exchange can be
piggybacked on any session initiation protocol. Alternatively,
standard protocols such as as NTP [16] can be used.
(The synchronization assumption of TESLA is considerably weaker
the synchronization requirements of authentication protocols based
on timestamps. In those protocols, the participants are
assumed to have the same global time a-priori.)
2. TESLA MUST be bootstrapped at session set-up through a regular
data authentication system. We recommend to use a digital
signature algorithm for this purpose, in which case the receiver
is REQUIRED to have an authentic copy of either the sender's
public key certificate or a root key certificate in case of a
PKI (public-key infrastructure).
3. TESLA uses cryptographic MAC and PRF (pseudo-random
functions). These MUST be cryptographically secure. Further
details on the instantiation of the MAC and PRF are in Section
4.2.
4. We would like to emphasize that the security of TESLA does NOT
rely on any assumptions on network propagation delay.
3 The Basic TESLA Protocol
TESLA is described in several academic publications: A book on
broadcast security [13], a journal paper [14], and two conference papers
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[8,15]. Please refer to these publications for an in-depth treatment.
3.1 Sketch of protocol
We first outline the main ideas behind TESLA.
As we argue in the introduction, broadcast authentication requires a
source of asymmetry. TESLA uses time for asymmetry. We first make sure
that the sender and receivers are loosely time synchronized as described
above. Next, the sender forms a one-way chain of keys, where each key in
chain is associated with a time interval (say, a second). Here is the
basic approach:
¸ The sender attaches a MAC to each packet. The MAC is computed
over the contents of the packet. For each packet, the sender uses
the current key from the one-way chain as a cryptographic key
to compute the MAC.
¸ The sender discloses a key from the one-way chain after some
pre-defined time delay. (e.g., the key used in time interval i
is disclosed at time interval i+3.)
¸ Each receiver receives the packet. Each receiver knows the
schedule for disclosing keys and, since it has an upper bound on
the local time at the sender, it can check that the key used to
compute the MAC was not yet disclosed by the sender. If so, then
the receiver buffers the packet. Otherwise the packet is dropped.
(Note that we do not know for sure whether a "late packet" is a
bogus one or simply a delayed packet. We drop the packet since we
are unable to authenticate it.)
¸ Each receiver checks that the disclosed key belongs to the hash-chain
(by checking against previously released keys in the chain) and then
checks the correctness of the MAC. If the MAC is correct, the
receiver accepts the packet.
Note that one-way chains have the property that if intermediate
values of the one-way chain are lost, they can be recomputed using
subsequent values in the chain . So, even if some key disclosures
are lost, a receiver can recover the corresponding keys and check
the correctness of earlier packets.
We now describe the stages of the basic TESLA protocol in this order:
sender setup, receiver bootstrap, sender transmission of
authenticated broadcast messages, and receiver authentication of
broadcast messages.
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3.2 Sender Setup
The sender divides the time into uniform intervals of duration T_int.
The sender assigns one key from the one-way chain to each time
interval in sequence.
The sender determines the length N of the one-way chain K_0, K_1,
..., K_N, and this length limits the maximum transmission duration
before a new one-way chain must be created. The sender picks a random
value for K_N. Using a pseudo-random function (PRF) f, the sender
constructs the one-way function F: F(k) = f_k(0). The rest of the
chain is computed recursively using K_i = F(K_{i+1}). Note that this
gives us K_i = F^{N-i}(K_N), so the receiver can compute any value in
the key chain from K_N even if is does not have intermediate values.
The key K_i will be used to authenticate packets sent in time
interval i.
3.3 Bootstrapping Receivers
Before a receiver can authenticate messages with TESLA, it needs to
have:
* An upper bound D_t on the lag of its own clock with respect to
the clock of the sender. (That is, if the local time reading is t,
the current time reading at the sender is at most t+D_t.).
* The disclosure schedule of keys. (Note that this information is not
essential. See details below.)
* One authenticated key of the one-way key chain. (Typically, this
will be the last key in the chain, i.e. K_0, this key will be
signed by the sender, and all receivers will verify the signature against
the public key of the signer.
The sender sends the key disclosure schedule by transmitting the
following information to the receivers over an authenticated channel
(either via a digitally signed broadcast message, or over an
authenticated unicast channel with each receiver):
¸ Time interval schedule: interval duration T_int, start time of
interval i and index of interval i, length of one-way key chain.
¸ Key disclosure delay d (number of intervals).
¸ A commitment to the key chain K_i (i < j - d + 1, where j is
the current interval index).
The receiver can perform the time synchronization and getting the
authenticated TESLA parameters in a two-round message exchange, which
we will describe in the technical TESLA document. Time synchronization
can be performed as part of the registration protocol between member
and sender.
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3.3.1 Time Synchronization
Various approaches exist for time synchronization [16,17,18,19].
TESLA, however, only requires the receiver to know an upper bound on
the delay of its local clock with respect to the receiver's clock,
so a simple algorithm is sufficient. TESLA can be used with direct,
indirect, and delayed synchronization as three default options.
The specific synchronization method will be part of each instantiation
of TESLA, and needs to be described in the appropriate standards-track
RFC.
For completeness we sketch a simple method for direct synchronization
between the sender and a receiver:
* The receiver sends a (sync t_r) message to the sender and records
its local time t_r.
* Upon receipt of the (sync t_r) message, the sender records its
local time t_s and sends (synch, t_r,t_s) to the receiver.
* Upon receiving (synch,t_r,t_s), the receiver sets D_t = t_s - t_r + S,
where S is an estimated bound on the clock drift throughout the
duration of the session.
Note:
* Assuming that the messages are authentic (i.e., the message received
the receiver was actually sent by the sender), and assuming that the
clock drift is at most S, then at any point throughout the session
we have that T_s < T_r + D_t, where T_s is the current time at the
sender and T_r is the current time at the receiver.
* The exchange of sync messages needs to be authenticated. This can be
done in a number of ways, for instance a secure NTP protocol, or in
conjunction with a session set-up protocol.
3.4 Broadcasting Authenticated Messages
Each key in the one-way key chain corresponds to a time interval.
Every time a sender broadcasts a message, it appends a MAC to the
message, using the key corresponding to the current time interval.
The key remains secret for the next d-1 intervals, so messages a
sender broadcasts in interval j effectively disclose key K_j-d. We
call d the key disclosure delay.
We do not want to use the same key multiple times in different
cryptographic operations, that is, to use key K_j to derive the previous
key of the one-way key chain K_{j-1}, and to use the same key K_j as
the key to compute the MACs in time interval j may potentially lead
to a cryptographic weakness. Using a pseudo-random function (PRF)
f', we construct the one-way function F': F'(k) = f'_k(1). We use F'
to derive the key to compute the MAC of messages in each interval.
The sender derives the MAC key as follows: K'_i = F'(K_i). Figure 1
depicts the one-way key chain construction and MAC key derivation. To
broadcast message M_j in interval i the sender constructs packet
P_j = {M_j || i || MAC(K'_i,M_j) || K_{i-d}}, where || denotes
concatenation.
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F(K_i) F(K_{i+1}) F(K_{i+2})
K_{i-1} <------- K_i <--------- Ki+1 <------- Ki+2
| | |
| F'(K_{i-1}) | F'(K_i) | F'(K_{i+1})
| | |
V V V
K'_{i-1} K'_i K'_{i+1}
Figure 1: At the top of the figure, we see the one-way key chain
(derived using the one-way function F), and the derived MAC keys
(derived using the one-way function F').
3.5 Authentication at Receiver
Once a sender discloses a key, we must assume that all parties might
have access to that key. An adversary could create a bogus message
and forge a MAC using the disclosed key. So whenever a packet
arrives, the receiver must verify that the MAC is based on a safe
key; a safe key is one that is still secret (only known by the
sender). We define a safe packet or safe message to be one with a MAC
that is computed with a safe key.
If the packet is not safe, the receiver must discard that packet,
because the authenticity is not assured any more.
We now explain the TESLA authentication in more detail. When the
receiver receives packet P_j sent in interval i, the receiver
computes an upper bound on the sender's clock: t_j. To test whether the
packet is safe, the receiver computes the highest interval x the
sender could possibly be in, namely x = floor((t_j - T_0) / T_int).
The receiver verifies that x < i + d (where i is the interval index),
which implies that the sender is not yet in the interval during which
it discloses the key K_i. If the condition fails then the receiver
drops the packet.
The receiver cannot yet verify the authenticity of packets sent in
interval i without key K_i. Instead, it adds the triplet ( i, M_j,
MAC( K'_i, M_j) ) to a buffer, and verifies the authenticity after it
learns K'_i.
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What does a receiver do when it receives the disclosed key K_i?
First, it checks whether it already knows K_i or a later key K_j
(j>i). If K_i is the latest key received to date, the receiver checks
the legitimacy of K_i by verifying, for some earlier key K_v (v<i)
that K_v = F^{i-v}(K_i). The receiver then computes K'_i = F'(K_i)
and verifies the authenticity of packets of interval i.
Using a disclosed key, we can calculate all previous disclosed keys,
so even if packets are lost, we will still be able to verify
buffered, safe packets from earlier time intervals. Thus, if i-v>1,
the receiver can also verify the authenticity of the stored packets
of intervals v+1 ... i-1.
Note that the security of TESLA does not rely on any assumptions on
network propagation delay.
3.6 Determining the Key Disclosure Delay
An important TESLA parameter is the key disclosure delay d. Although
the choice of the disclosure delay does not affect the security of
the system, it is an important performance factor. A short disclosure
delay will cause packets to lose their safety property, so receivers
will discard them; but a long disclosure delay leads to a long
authentication delay for receivers. We recommend choosing the
disclo¡ sure delay as follows: in direct time synchronization let
the RTT be a reasonable upper bound on the round trip time between the
sender and the receiver; then choose d = ceil( RTT / T_int) + 1. Note
that rounding up the quotient ensures that d >= 2. Also note that a
disclosure delay of one time interval (d=1) does not work. Consider
packets sent close to the boundary of the time interval: after the
network propagation delay and the receiver time synchronization
error, a receiver will need to discard the packet, because the sender
will already be in the next time interval, when it discloses the
corresponding key.
3.7 An alternative delay description method
The above description instructs the sender to include the time interval
i in each packet. The receiver then uses i to determine the time at which
the key authenticating the packet is disclosed. This method limits the
the sender to a pre-determined schedule of disclosing keys.
Alternatively, the sender may directly include in each packet the time t_p
at which it is going to disclose the key for this packet. This way, the
receiver does not need to know the duration of intervals or the delay
factor d. All the receiver needs to know is the bound D_t on the clock
skew and T_0, the sender's local time at the initiation of the session.
Then the receiver records the local time T when the packet has arrived,
and verifies that
T <= T_0 + D_t + t_p.
Else the packet is dropped.
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Another advantage of this method is that the sender is able to change
the duration of intervals and the key disclosure delay dynamically
throughout the session.
3.8 Some extensions
Let us mention two salient extensions of the basic TESLA scheme.
A first extension allows having multiple TESLA authentication chains
for a single stream, where each chain uses a different delay for
disclosing the keys. This extension is typically used to deal with
heterogeneous network delays within a single multicast transmission.
A second extension allows having most of the buffering of packets
at the sender side (rather than at the receiver side). Both
extensions are described in [15].
4 Layer placement
The TESLA authentication can be performed at any layer in the
networking stack. Three natural places are in the network, transport,
or the application layer. We list some considerations regarding the
choice of layer:
¸ Performing TESLA in the network layer has the advantage that the
transport or application layer only receives authenticated data,
potentially aiding a reliability protocol and preventing denial
of service attacks. (Indeed, reliable multicast tools based on
forward error correction are highly susceptible to denial of
service due to bogus packets.)
¸ Performing TESLA in either the transport or the application layer
has the advantage that the network layer remains unchanged; but it
has the drawback that packets are obtained by the application layer
only after being processed by the transport layer. Consequently,
if TCP is used then this may introduce additional and unpredictable
delays on top of the unavoidable network delays. (However, if UDP
is used then this is not a problem.)
5. Security Considerations
See the academic publications on TESLA [8,14,20] for several security
analyses. Regarding the security of implementations, by far the most
delicate point is the verification of the timing conditions. Care
should be taken to to make sure that:
(a) The value bound D_t on the clock skew is calculated according to the
spec at session set-up.
(b) The receiver records the arrival time of the packet as soon as possible
after the packet's arrival, and computes the safety condition correctly.
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6 Acknowledgments
We would like to thank Mike Luby for his feedback and support.
7 Bibliography
[1] T. Dierks and C. Allen, "The TLS protocol version 1.0." Internet
Request for Comments RFC 2246, January 1999. Proposed standard.
[2] Ipsec, "IP Security Protocol, IETF working group."
http://www.ietf.org/html.charters/ipsec-charter.html.
[3] D. Boneh, G. Durfee, and M. Franklin, "Lower bounds for multicast
message authentication," in Advances in Cryptology -- EUROCRYPT '2001
(B. Pfitzmann, ed.), vol. 2045 of Lecture Notes in Computer Science ,
(Innsbruck, Austria), pp. 434--450, Springer-Verlag, Berlin Germany,
2001.
[4] R. Gennaro and P. Rohatgi, "How to Sign Digital Streams," tech.
rep., IBM T.J.Watson Research Center, 1997.
[5] P. Rohatgi, "A compact and fast hybrid signature scheme for mul¡
ticast packet authentication," in 6th ACM Conference on Computer and
Communications Security , November 1999.
[6] P. Rohatgi, "A hybrid signature scheme for multicast source
authentication," Internet Draft, Internet Engineering Task Force,
June 1999. Work in progress.
[7] C. K. Wong and S. S. Lam, "Digital signatures for flows and mul¡
ticasts," in Proc. IEEE ICNP `98 , 1998.
[8] A. Perrig, R. Canetti, J. Tygar, and D. X. Song, "Efficient
authentication and signing of multicast streams over lossy channels,"
in IEEE Symposium on Security and Privacy , May 2000.
[9] R. Canetti, J. Garay, G. Itkis, D. Micciancio, M. Naor, and B.
Pinkas, "Multicast security: A taxonomy and some efficient construc¡
tions," in Infocom '99 , 1999.
[10] S. Cheung, "An efficient message authentication scheme for link
state routing," in 13th Annual Computer Security Applications Confer¡
ence , 1997.
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[11] F. Bergadano, D. Cavagnino, and B. Crispo, "Chained stream
authentication," in Selected Areas in Cryptography 2000 , (Waterloo,
Canada), August 2000. A talk describing this scheme was given at IBM
Watson in August 1998.
[12] F. Bergadano, D. Cavalino, and B. Crispo, "Individual single
source authentication on the mbone," in ICME 2000 , Aug 2000. A talk
containing this work was given at IBM Watson, August 1998.
[13] A. Perrig and J. D. Tygar, Secure Broadcast Communication in
Wired and Wireless Networks Kluwer Academic Publishers, Oct. 2002.
ISBN 0792376501.
[14] A. Perrig, R. Canetti, J. D. Tygar, and D. Song, "The tesla
broadcast authentication protocol," RSA CryptoBytes , vol. 5, no.
Summer, 2002.
[15] A. Perrig, R. Canetti, D. Song, and J. D. Tygar, "Efficient and
secure source authentication for multicast," in Network and Dis¡
tributed System Security Symposium, NDSS '01 , pp. 35--46, February
2001.
[16] D. L. Mills, "Network Time Protocol (Version 3) Specification,
Implementation and Analysis." Internet Request for Comments, March
1992. RFC 1305.
[17] B. Simons, J. Lundelius-Welch, and N. Lynch, "An overview of
clock synchronization," in Fault-Tolerant Distributed Computing (B.
Simons and A. Spector, eds.), no. 448 in LNCS, pp. 84--96, Springer-
Verlag, Berlin Germany, 1990.
[18] D. Mills, "Improved algorithms for synchronizing computer net¡
work clocks," in Proceedings of the conference on Communications
architectures, protocols and applications, SIGCOMM 94 , (London,
England), pp. 317--327, 1994.
[19] L. Lamport and P. Melliar-Smith, "Synchronizing clocks in the
presence of faults," J. ACM , vol. 32, no. 1, pp. 52--78, 1985.
[20] Philippa Broadfoot and Gavin Lowe, "Analysing a Stream
Authentication Protocol using Model Checking. In Proceedings of the
7th European Symposium on Research in Computer Security (ESORICS),
2002.
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A Author Contact Information
Adrian Perrig
ECE Department
Carnegie Mellon University
Pittsburgh, PA
US
perrig@ece.cmu.edu
Ran Canetti
IBM Research
30 Saw Mill River Rd
Hawthorne, NY 10532
US
canetti@watson.ibm.com
Dawn Song
CS Department
Carnegie Mellon University
Pittsburgh, PA
US
dawnsong@cmu.edu
Doug Tygar
UC Berkeley
102 South Hall, 4600
Berkeley, CA 94720-4600
US
tygar@cs.berkeley.edu
Bob Briscoe
BT Research
B54/74, BT Labs
Martlesham Heath
Ipswich, IP5 3RE
UK
bob.briscoe@bt.com
Perrig, Canetti, Song, Tygar, Briscoe [Page 12]
Internet Draft draft-msec-tesla-intro-02 May 2004
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Perrig, Canetti, Song, Tygar, Briscoe [Page 13]