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Internet Engineering Task Force (IETF)                   N. Rozen-Schiff
Request for Comments: 9523                                      D. Dolev
Category: Informational                   Hebrew University of Jerusalem
ISSN: 2070-1721                                               T. Mizrahi
                                        Huawei Network.IO Innovation Lab
                                                             M. Schapira
                                          Hebrew University of Jerusalem
                                                           February 2024


A Secure Selection and Filtering Mechanism for the Network Time Protocol
                              with Khronos

Abstract

   The Network Time Protocol version 4 (NTPv4), as defined in RFC 5905,
   is the mechanism used by NTP clients to synchronize with NTP servers
   across the Internet.  This document describes a companion application
   to the NTPv4 client, named "Khronos", that is used as a "watchdog"
   alongside NTPv4 and that provides improved security against time-
   shifting attacks.  Khronos involves changes to the NTP client's
   system process only.  Since it does not affect the wire protocol, the
   Khronos mechanism is applicable to current and future time protocols.

Status of This Memo

   This document is not an Internet Standards Track specification; it is
   published for informational purposes.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Not all documents
   approved by the IESG are candidates for any level of Internet
   Standard; see Section 2 of RFC 7841.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   https://www.rfc-editor.org/info/rfc9523.

Copyright Notice

   Copyright (c) 2024 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (https://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.  Code Components extracted from this document must
   include Revised BSD License text as described in Section 4.e of the
   Trust Legal Provisions and are provided without warranty as described
   in the Revised BSD License.

Table of Contents

   1.  Introduction
   2.  Conventions Used in This Document
     2.1.  Terms and Abbreviations
     2.2.  Notations
   3.  Khronos Design
     3.1.  Khronos Calibration - Gathering the Khronos Pool
     3.2.  Khronos's Poll and System Processes
     3.3.  Khronos's Recommended Parameters
   4.  Operational Considerations
     4.1.  Load Considerations
   5.  Security Considerations
     5.1.  Threat Model
     5.2.  Attack Detection
     5.3.  Security Analysis Overview
   6.  Khronos Pseudocode
   7.  Precision vs. Security
   8.  IANA Considerations
   9.  References
     9.1.  Normative References
     9.2.  Informative References
   Acknowledgements
   Authors' Addresses

1.  Introduction

   NTPv4, as defined in [RFC5905], is vulnerable to time-shifting
   attacks in which the attacker changes (shifts) the clock of a network
   device.  Time-shifting attacks on NTP clients can be based on
   interfering with the communication between the NTP clients and
   servers or compromising the servers themselves.  Time-shifting
   attacks on NTP are possible even if NTP communication is encrypted
   and authenticated.  A weaker machine-in-the-middle (MITM) attacker
   can shift time simply by dropping or delaying packets, whereas a
   powerful attacker that has full control over an NTP server can do so
   by explicitly determining the NTP response content.  This document
   introduces a time-shifting mitigation mechanism called "Khronos".
   Khronos can be integrated as a background-monitoring application
   (watchdog) that guards against time-shifting attacks in any NTP
   client.  An NTP client that runs Khronos is interoperable with NTPv4
   servers that are compatible with [RFC5905].  The Khronos mechanism
   does not affect the wire mechanism; therefore, it is applicable to
   any current or future time protocol.

   Khronos is a mechanism that runs in the background, continuously
   monitoring the client clock (which is updated by NTPv4) and
   calculating an estimated offset (referred to as the "Khronos time
   offset").  When the offset exceeds a predefined threshold (specified
   in Section 5.2), this is interpreted as the client experiencing a
   time-shifting attack.  In this case, Khronos updates the client's
   clock.

   When the client is not under attack, Khronos is passive.  This allows
   NTPv4 to control the client's clock and provides the ordinary high
   precision and accuracy of NTPv4.  When under attack, Khronos takes
   control of the client's clock, mitigating the time shift while
   guaranteeing relatively high accuracy with respect to UTC and
   precision, as discussed in Section 7.

   By leveraging techniques from distributed computing theory for time
   synchronization, Khronos achieves accurate time even in the presence
   of powerful attackers who are in direct control of a large number of
   NTP servers.  Khronos will prevent shifting the clock when the ratio
   of compromised time samples is below 2/3.  In each polling interval,
   a Khronos client randomly selects and samples a few NTP servers out
   of a local pool of hundreds of servers.  Khronos is carefully
   engineered to minimize the load on NTP servers and the communication
   overhead.  In contrast, NTPv4 employs an algorithm that typically
   relies on a small subset of the NTP server pool (e.g., four servers)
   for time synchronization and is much more vulnerable to time-shifting
   attacks.  Configuring NTPv4 to use several hundreds of servers will
   increase its security, but will incur very high network and
   computational overhead compared to Khronos and will be bounded by a
   compromised ratio of half of the time samples.

   A Khronos client iteratively "crowdsources" time queries across NTP
   servers and applies a provably secure algorithm for eliminating
   "suspicious" responses and for averaging over the remaining
   responses.  In each Khronos poll interval, the Khronos client
   selects, uniformly at random, a small subset (e.g., 10-15 servers) of
   a large server pool (containing hundreds of servers).  While Khronos
   queries around three times more servers per polling interval than
   NTP, Khronos's polling interval can be longer (e.g., 10 times longer)
   than NTPv4, thereby minimizing the load on NTP servers and the
   communication overhead.  Moreover, Khronos's random server selection
   may even help to distribute queries across the whole pool.

   Khronos's security was evaluated both theoretically and
   experimentally with a prototype implementation.  According to this
   security analysis, if a local Khronos pool consists of, for example,
   500 servers, one-seventh of whom are controlled by an attacker and
   Khronos queries 15 servers in each Khronos poll interval (around 10
   times the NTPv4 poll interval), then over 20 years of effort are
   required (in expectation) to successfully shift time at a Khronos
   client by over 100 ms from UTC.  The full exposition of the formal
   analysis of this guarantee is available at [Khronos].

   Khronos maintains a time offset value (the Khronos time offset) and
   uses it as a reference for detecting attacks.  This time offset value
   computation differs from the current NTPv4 in two key aspects:

   *  First, in each Khronos poll interval, Khronos periodically
      communicates with only a few (tens) randomly selected servers out
      of a pool consisting of a large number (e.g., hundreds) of NTP
      servers.

   *  Second, Khronos computes the Khronos time offset based on an
      approximate agreement technique to remove outliers, thus limiting
      the attacker's ability to contaminate the time samples (offsets)
      derived from the queried NTP servers.

   These two aspects allow Khronos to minimize the load on the NTP
   servers and to provide provable security guarantees against both MITM
   attackers and attackers capable of compromising a large number of NTP
   servers.

   We note that, to some extent, Network Time Security (NTS) [RFC8915]
   could make it more challenging for attackers to perform MITM attacks,
   but is of little impact if the servers themselves are compromised.

2.  Conventions Used in This Document

2.1.  Terms and Abbreviations

   NTPv4:  Network Time Protocol version 4.  See [RFC5905].

   System process:  See the "Selection Algorithm" and the "Cluster
      Algorithm" sections of [RFC5905].

   Security Requirements:  See "Security Requirements of Time Protocols
      in Packet Switched Networks" [RFC7384].

   NTS:  Network Time Security.  See "Network Time Security for the
      Network Time Protocol" [RFC8915].

2.2.  Notations

   When describing the Khronos algorithm, the following notation is
   used:

     +==========+====================================================+
     | Notation | Meaning                                            |
     +==========+====================================================+
     |    n     | The number of candidate servers in a Khronos pool  |
     |          | (potentially hundreds).                            |
     +----------+----------------------------------------------------+
     |    m     | The number of servers that Khronos queries in each |
     |          | poll interval (up to tens).                        |
     +----------+----------------------------------------------------+
     |    w     | An upper bound on the distance between any         |
     |          | "truechimer" NTP server (as in [RFC5905]) and UTC. |
     +----------+----------------------------------------------------+
     |    B     | An upper bound on the client's clock error rate    |
     |          | (ms/sec).                                          |
     +----------+----------------------------------------------------+
     |   ERR    | An upper bound on the client's clock error between |
     |          | Khronos polls (ms).                                |
     +----------+----------------------------------------------------+
     |    K     | The number of Khronos pool resamplings until       |
     |          | reaching "panic mode".                             |
     +----------+----------------------------------------------------+
     |    H     | Predefined threshold for a Khronos time offset     |
     |          | triggering clock update by Khronos.                |
     +----------+----------------------------------------------------+

                         Table 1: Khronos Notation


   The recommended values are discussed in Section 3.3.

3.  Khronos Design

   Khronos periodically queries a set of m (tens) servers from a large
   (hundreds) server pool in each Khronos poll interval, where the m
   servers are selected from the server pool at random.  Based on
   empirical analyses, to minimize the load on NTP servers while
   providing high security, the Khronos poll interval should be around
   10 times the NTPv4 poll interval (i.e., a Khronos clock update occurs
   once every 10 NTPv4 clock updates).  In each Khronos poll interval,
   if the Khronos time offset exceeds a predetermined threshold (denoted
   as H), an attack is indicated.

   Unless an attack is indicated, Khronos uses only one sample from each
   server (avoiding the "Clock Filter Algorithm" as defined in
   Section 10 of [RFC5905]).  When under attack, Khronos uses several
   samples from each server and executes the "Clock Filter Algorithm"
   for choosing the best sample from each server with low jitter.  Then,
   given a sample from each server, Khronos discards outliers by
   executing the procedure described in Section 3.2.

   Between consecutive Khronos polls, Khronos keeps track of clock
   offsets, e.g., by catching clock discipline (as in [RFC5905]) calls.
   The sum of offsets is referred to as the "Khronos inter-poll offset"
   (denoted as tk), which is set to zero after each Khronos poll.

3.1.  Khronos Calibration - Gathering the Khronos Pool

   Calibration is performed the first time Khronos is executed and
   periodically thereafter (once every two weeks).  The calibration
   process generates a local Khronos pool of n (up to hundreds) NTP
   servers that the client can synchronize with.  To this end, Khronos
   makes multiple DNS queries to the NTP pools.  Each query returns a
   few NTP server IPs that Khronos combines into one set of IPs
   considered as the Khronos pool.  The servers in the Khronos pool
   should be scattered across different regions to make it harder for an
   attacker to compromise or gain MITM capabilities with respect to a
   large fraction of the Khronos pool.  Therefore, Khronos calibration
   queries general NTP server pools (e.g., pool.ntp.org) and not just
   the pool in the client's state or region.  In addition, servers can
   be selected to be part of the Khronos pool manually or by using other
   NTP pools (such as NIST Internet time servers).

   The first Khronos update requires m servers, which can be found in
   several minutes.  Moreover, it is possible to query several DNS pool
   names to vastly accelerate the calibration and the first update.

   The calibration is the only Khronos part where DNS traffic is
   generated.  Around 125 DNS queries are required by Khronos to obtain
   addresses of 500 NTP servers, which is higher than Khronos pool size
   (n).  Assuming the calibration period is two weeks, the expected DNS
   traffic generated by the Khronos client is less than 10 DNS queries
   per day, which is usually several orders of magnitude lower than the
   total daily number of DNS queries per machine.

3.2.  Khronos's Poll and System Processes

   In each Khronos poll interval, the Khronos system process randomly
   chooses a set of m (tens) servers out of the Khronos pool of n
   (hundreds) servers and samples them.  Note that the randomness of the
   server selection is crucial for the security of the scheme;
   therefore, any Khronos implementation must use a secure randomness
   implementation such as what is used for encryption key generation.

   Khronos's polling times of different servers may spread uniformly
   within its poll interval, which is similar to NTPv4.  Servers that do
   not respond during the Khronos poll interval are filtered out.  If
   less than one-third of the m servers are left, a new subset of
   servers is immediately sampled in the exact same manner (which is
   called the "resampling" process).

   Next, out of the time samples received from this chosen subset of
   servers, the lowest third of the samples' offset values and the
   highest third of the samples' offset values are discarded.

   Khronos checks that the following two conditions hold for the
   remaining sampled offsets (considering w and ERR defined in Table 1):

   *  The maximal distance between every two offsets does not exceed 2w
      (can be verified by considering just the minimum and the maximum
      offsets).

   *  The distance between the offset's average and the Khronos inter-
      poll offset is ERR+2w at most.

   In the event that both of these conditions are satisfied, the average
   of the offsets is set to be the Khronos time offset.  Otherwise,
   resampling is performed.  This process spreads the Khronos client's
   queries across servers, thereby improving security against powerful
   attackers (as discussed in Section 5.3) and mitigating the effect of
   a DoS attack on NTP servers that renders them non-responsive.  This
   resampling process continues in subsequent Khronos poll intervals
   until the two conditions are both satisfied or the number of times
   the servers are resampled exceeds a "panic trigger" (K in Table 1).
   In this case, Khronos enters panic mode.

   In panic mode, Khronos queries all the servers in its local Khronos
   pool, orders the collected time samples from lowest to highest, and
   eliminates the lowest third and the highest third of the samples.
   The client then calculates the average of the remaining samples and
   sets this average to be the new Khronos time offset.

   If the Khronos time offset exceeds a predetermined threshold (H), it
   is passed on to the clock discipline algorithm in order to steer the
   system time (as in [RFC5905]).  In this case, the user and/or admin
   of the client machine should be notified about the detected time-
   shifting attack, e.g., by a message written to a relevant event log
   or displayed on screen.

   Note that resampling immediately follows the previous sampling since
   waiting until the next polling interval may increase the time shift
   in face of an attack.  This shouldn't generate high overhead since
   the number of resamples is bounded by K (after K resamplings, panic
   mode is in place) and the chances of ending up with repeated
   resampling are low (see Section 5 for more details).  Moreover, in an
   interval following a panic mode, Khronos executes the same system
   process that starts by querying only m servers (regardless of
   previous panic).

3.3.  Khronos's Recommended Parameters

   According to empirical observations (presented in [Khronos]),
   querying 15 servers at each poll interval (i.e., m=15) out of 500
   servers (i.e., n=500) and setting w to be around 25 ms provides both
   high time accuracy and good security.  Specifically, when selecting
   w=25 ms, approximately 83% of the servers' clocks are, at most, w
   away from UTC and within 2w from each other, satisfying the first
   condition of Khronos's system process.  For a similar reason, the
   threshold for a Khronos time offset triggering a clock update by
   Khronos (H) should be between w and 2w; the default is 30 ms.  Note
   that in order to support scenarios with congested links, using a
   higher w value, such as 1 second, is recommended.

   Furthermore, according to Khronos security analysis, setting K to be
   3 (i.e., if the two conditions are not satisfied after three
   resamplings, then Khronos enters panic mode) is safe when facing
   time-shifting attacks.  In addition, the probability of an attacker
   forcing a panic mode on a client when K=3 is negligible (less than
   0.000002 for each polling interval).

   Khronos's effect on precision and accuracy are discussed in Sections
   5 and 7.

4.  Operational Considerations

   Khronos is designed to defend NTP clients from time-shifting attacks
   while using public NTP servers.  As such, Khronos is not applicable
   for data centers and enterprises that synchronize with local atomic
   clocks, GPS devices, or a dedicated NTP server (e.g., due to
   regulations).

   Khronos can be used for devices that require and depend upon
   timekeeping within a configurable constant distance from UTC.

4.1.  Load Considerations

   One requirement from Khronos is not to induce excessive load on NTP
   servers beyond that of NTPv4, even if it is widely integrated into
   NTP clients.  We discuss below the possible causes for a Khronos-
   induced load on servers and how this can be mitigated.

   Servers in pool.ntp.org are weighted differently by the NTP server
   pool when assigned to NTP clients.  Specifically, server owners
   define a "server weight" (the "netspeed" parameter) and servers are
   assigned to clients probabilistically according to their proportional
   weight.  Khronos's queries are equally distributed across a pool of
   servers.  To avoid overloading servers, Khronos queries servers less
   frequently than NTPv4, with the Khronos query interval set to 10
   times the default NTPv4 maxpoll (interval) parameter.  Hence, if
   Khronos queries are targeted at servers in pool.ntp.org, any target
   increase in server load (in terms of multiplicative increase in
   queries or number of bytes per second) is controlled by the poll
   interval configuration, which was analyzed in [Ananke].

   Consider the scenario where an attacker attempts to generate
   significant load on NTP servers by triggering multiple consecutive
   panic modes at multiple NTP clients.  We note that to accomplish
   this, the attacker must have MITM capabilities with respect to the
   communication between each and every client in a large group of
   clients and a large fraction of all NTP servers in the queried pool.
   This implies that the attacker must either be physically located at a
   central location (e.g., at the egress of a large ISP) or launch a
   wide-scale attack (e.g., on BGP or DNS); thereby, it is capable of
   carrying similar and even higher impact attacks regardless of Khronos
   clients.

5.  Security Considerations

5.1.  Threat Model

   The threat model encompasses a broad spectrum of attackers impacting
   a subset (e.g., one-third) of the servers in NTP pools.  These
   attackers can range from a fairly weak (yet dangerous) MITM attacker
   that is only capable of delaying and dropping packets (e.g., using
   the Bufferbloat attack [RFC8033]) to an extremely powerful attacker
   who is in control of (even authenticated) NTP servers and is capable
   of fully determining the values of the time samples returned by these
   NTP servers (see detailed attacker discussion in [RFC7384]).

   For example, the attackers covered by this model might be:

   1.  in direct control of a fraction of the NTP servers (e.g., by
       exploiting a software vulnerability),

   2.  an ISP (or other attacker at the Autonomous System level) on the
       default BGP paths from the NTP client to a fraction of the
       available servers,

   3.  a nation state with authority over the owners of NTP servers in
       its jurisdiction, or

   4.  an attacker capable of hijacking (e.g., through DNS cache
       poisoning or BGP prefix hijacking) traffic to some of the
       available NTP servers.

   The details of the specific attack scenario are abstracted by
   reasoning about attackers in terms of the fraction of servers with
   respect to which the attacker has adversarial capabilities.
   Attackers that can impact communications with (or control) a higher
   fraction of the servers (e.g., all servers) are out of scope.
   Considering the pool size across the world to be in the thousands,
   such attackers will most likely be capable of creating far worse
   damage than time-shifting attacks.

   Notably, Khronos provides protection from MITM and powerful attacks
   that cannot be achieved by cryptographic authentication protocols
   since, even with such measures in place, an attacker can still
   influence time by dropping/delaying packets.  However, adding an
   authentication layer (e.g., NTS [RFC8915]) to Khronos will enhance
   its security guarantees and enable the detection of various spoofing
   and modification attacks.

   Moreover, Khronos uses randomness to independently select the queried
   servers in each poll interval, preventing attackers from exploiting
   observations of past server selections.

5.2.  Attack Detection

   Khronos detects time-shifting attacks by constantly monitoring
   NTPv4's (or potentially any other current or future time protocol)
   clock and the offset computed by Khronos and checking whether the
   offset exceeds a predetermined threshold (H).  NTPv4 controls the
   client's clock unless an attack was detected.  Under attack, Khronos
   takes control over the client's clock in order to prevent its shift.

   Analytical results (in [Khronos]) indicate that if a local Khronos
   pool consists of 500 servers, one-seventh of whom are controlled by a
   MITM attacker, and 15 of those servers are queried in each Khronos
   poll interval, then success in shifting time of a Khronos client by
   even a small degree (100 ms) takes many years of effort (over 20
   years in expectation).  See a brief overview of Khronos's security
   analysis below.

5.3.  Security Analysis Overview

   Time samples that are at most w away from UTC are considered "good",
   whereas other samples are considered "malicious".  Two scenarios are
   considered:

   *  Scenario A: Less than two-thirds of the queried servers are under
      the attacker's control.

   *  Scenario B: The attacker controls more than two-thirds of the
      queried servers.

   Scenario A consists of two sub-cases:

   1.  There is at least one good sample in the set of samples not
       eliminated by Khronos (in the middle third of samples), and

   2.  there are no good samples in the remaining set of samples.

   In sub-case 1, the other remaining samples, including those provided
   by the attacker, must be close to a good sample (otherwise, the first
   condition of Khronos's system process in Section 3.2 is violated and
   a new set of servers is chosen).  This implies that the average of
   the remaining samples must be close to UTC.

   In sub-case 2, since more than a third of the initial samples were
   good, both the (discarded) third-lowest-value samples and the
   (discarded) third-highest-value samples must each contain a good
   sample.  Hence, all the remaining samples are bounded from both above
   and below by good samples, and so is their average value, implying
   that this value is close to UTC [RFC5905].

   In Scenario B, the worst possibility for the client is that all
   remaining samples are malicious (i.e., more than w away from UTC).
   However, as proved in [Khronos], the probability of this scenario is
   extremely low, even if the attacker controls a large fraction (e.g.,
   one-fourth) of the n servers in the local Khronos pool.  Therefore,
   the probability that the attacker repeatedly reaches this scenario
   decreases exponentially, rendering the probability of a significant
   time shift negligible.  We can express the improvement ratio of
   Khronos over NTPv4 by the ratios of their single-shift probabilities.
   Such ratios are provided in Table 2, where higher values indicate
   higher improvement of Khronos over NTPv4 and are also proportional to
   the expected time until a time-shift attack succeeds once.


     +========+==========+==========+==========+==========+==========+
     | Attack |    6     |    12    |    18    |    24    |    30    |
     | Ratio  | Samples  | Samples  | Samples  | Samples  | Samples  |
     +========+==========+==========+==========+==========+==========+
     |  1/3   | 1.93e+01 | 3.85e+02 | 7.66e+03 | 1.52e+05 | 3.03e+06 |
     +--------+----------+----------+----------+----------+----------+
     |  1/5   | 1.25e+01 | 1.59e+02 | 2.01e+03 | 2.54e+04 | 3.22e+05 |
     +--------+----------+----------+----------+----------+----------+
     |  1/7   | 1.13e+01 | 1.29e+02 | 1.47e+03 | 1.67e+04 | 1.90e+05 |
     +--------+----------+----------+----------+----------+----------+
     |  1/9   | 8.54e+00 | 7.32e+01 | 6.25e+02 | 5.32e+03 | 4.52e+04 |
     +--------+----------+----------+----------+----------+----------+
     |  1/10  | 5.83e+00 | 3.34e+01 | 1.89e+02 | 1.07e+03 | 6.04e+03 |
     +--------+----------+----------+----------+----------+----------+
     |  1/15  | 3.21e+00 | 9.57e+00 | 2.79e+01 | 8.05e+01 | 2.31e+02 |
     +--------+----------+----------+----------+----------+----------+

                        Table 2: Khronos Improvement


   In addition to evaluating the probability of an attacker successfully
   shifting time at the client's clock, we also evaluated the
   probability that the attacker succeeds in launching a DoS attack on
   the servers by causing many clients to enter panic mode (and querying
   all the servers in their local Khronos pools).  This probability
   (with the previous parameters of n=500, m=15, w=25, and K=3) is
   negligible even for an attacker who controls a large number of
   servers in clients' local Khronos pools, and it is expected to take
   decades to force a panic mode.

   Further details about Khronos's security guarantees can be found in
   [Khronos].

6.  Khronos Pseudocode

   The pseudocode for Khronos Time Sampling Scheme, which is invoked in
   each Khronos poll interval, is as follows:

   counter = 0
   S = []
   T = []
   While counter < K do
      S = sample(m) //get samples from (tens of) randomly chosen servers
      T = bi_side_trim(S,1/3) //trim lowest and highest thirds
      if (max(T) - min(T) <= 2w) and (|avg(T) - tk| < ERR + 2w), then
          return avg(T) // Normal case
      end
      counter ++
   end
   // panic mode
   S = sample(n)
   T = bi-sided-trim(S,1/3) //trim lowest and highest thirds
   return avg(T)

   Note that if clock disciplines can be called during this pseudocode's
   execution, then each time offset sample, as well as the final output
   (Khronos time offset), should be normalized with the sum of the clock
   disciplines offsets (tk) at the time of computing it.

7.  Precision vs. Security

   Since NTPv4 updates the clock at times when no time-shifting attacks
   are detected, the precision and accuracy of a Khronos client are the
   same as NTPv4 at these times.  Khronos is proved to maintain an
   accurate estimation of the UTC with high probability.  Therefore,
   when Khronos detects that client's clock error exceeds a threshold
   (H), it considers it to be an attack and takes control over the
   client's clock.  As a result, the time shift is mitigated and high
   accuracy is guaranteed (the error is bounded by H).

   Khronos is based on crowdsourcing across servers and regions, changes
   the set of queried servers more frequently than NTPv4 [Khronos], and
   avoids some of the filters in NTPv4's system process.  These factors
   can potentially harm its precision.  Therefore, a smoothing mechanism
   can be used where instead of a simple average of the remaining
   samples, the smallest (in absolute value) offset is used unless its
   distance from the average is higher than a predefined value.
   Preliminary experiments demonstrated promising results with precision
   similar to NTPv4.

   In applications such as multi-source media streaming, which are
   highly sensitive to time differences among hosts, note that it is
   advisable to use Khronos at all hosts in order to obtain high
   precision, even in the presence of attackers that try to shift each
   host in a different magnitude and/or direction.  Another approach
   that is more efficient for these cases may be to allow direct time
   synchronization between one host who runs Khronos to others.

8.  IANA Considerations

   This document has no IANA actions.

9.  References

9.1.  Normative References

   [RFC5905]  Mills, D., Martin, J., Ed., Burbank, J., and W. Kasch,
              "Network Time Protocol Version 4: Protocol and Algorithms
              Specification", RFC 5905, DOI 10.17487/RFC5905, June 2010,
              <https://www.rfc-editor.org/info/rfc5905>.

   [RFC7384]  Mizrahi, T., "Security Requirements of Time Protocols in
              Packet Switched Networks", RFC 7384, DOI 10.17487/RFC7384,
              October 2014, <https://www.rfc-editor.org/info/rfc7384>.

   [RFC8033]  Pan, R., Natarajan, P., Baker, F., and G. White,
              "Proportional Integral Controller Enhanced (PIE): A
              Lightweight Control Scheme to Address the Bufferbloat
              Problem", RFC 8033, DOI 10.17487/RFC8033, February 2017,
              <https://www.rfc-editor.org/info/rfc8033>.

   [RFC8915]  Franke, D., Sibold, D., Teichel, K., Dansarie, M., and R.
              Sundblad, "Network Time Security for the Network Time
              Protocol", RFC 8915, DOI 10.17487/RFC8915, September 2020,
              <https://www.rfc-editor.org/info/rfc8915>.

9.2.  Informative References

   [Ananke]   Perry, Y., Rozen-Schiff, N., and M. Schapira, "A Devil of
              a Time: How Vulnerable is NTP to Malicious Timeservers?",
              Network and Distributed Systems Security (NDSS) Symposium,
              Virtual, DOI 10.14722/ndss.2021.24302, February 2021,
              <https://www.ndss-symposium.org/wp-content/uploads/
              ndss2021_1A-2_24302_paper.pdf>.

   [Khronos]  Deutsch, O., Rozen-Schiff, N., Dolev, D., and M. Schapira,
              "Preventing (Network) Time Travel with Chronos", Network
              and Distributed Systems Security (NDSS) Symposium, San
              Diego, CA, USA, DOI 10.14722/ndss.2018.23231, February
              2018, <https://www.ndss-symposium.org/wp-
              content/uploads/2018/02/ndss2018_02A-2_Deutsch_paper.pdf>.

Acknowledgements

   The authors would like to thank Erik Kline, Miroslav Lichvar, Danny
   Mayer, Karen O'Donoghue, Dieter Sibold, Yaakov (J) Stein, Harlan
   Stenn, Hal Murray, Marcus Dansarie, Geoff Huston, Roni Even, Benjamin
   Schwartz, Tommy Pauly, Rob Sayre, Dave Hart, and Ask Bjorn Hansen for
   valuable contributions to this document and helpful discussions and
   comments.

Authors' Addresses

   Neta Rozen-Schiff
   Hebrew University of Jerusalem
   Jerusalem
   Israel
   Phone: +972 2 549 4599
   Email: neta.r.schiff@gmail.com


   Danny Dolev
   Hebrew University of Jerusalem
   Jerusalem
   Israel
   Phone: +972 2 549 4588
   Email: danny.dolev@mail.huji.ac.il


   Tal Mizrahi
   Huawei Network.IO Innovation Lab
   Israel
   Email: tal.mizrahi.phd@gmail.com


   Michael Schapira
   Hebrew University of Jerusalem
   Jerusalem
   Israel
   Phone: +972 2 549 4570
   Email: schapiram@huji.ac.il