Testing cooperative autonomous systems for unwanted emergent behaviour and dangerous self-adaptations

Jörg Denzinger,
Department of Computer Science,
University of Calgary
denzinge@cpsc.ucalgary.ca

  Malik Atalla   Torsten Steiner
  Bernhard Bauer   Chris Thornton
  Karel Bergmann   Jan‐Philipp
  Michael Blackadar Steghöfer
  Jeﬀ Boyd
  Tom Flanagan
  Jonathan Hudson
  Holger Kasinger
  Jordan Kidney
Testing for unwanted emergent behavior and dangerous self‐adaptations J. Denzinger

  Awareness (www.aware‐project.eu/), a FET
coordination action funded by the European
Commission under FP7 which provides
support for researchers interested in “Self‐
Awareness in Autonomic Systems”
  Jennifer Willies
  Levent Gürgen, Klaus Moessner, Abdur
Rahim Biswas and Fano Ramparany


IoT aims at large number of autonomous
entities working together and manage
themselves to adapt to task and environment
and create emergent properties
  But what about


  Unwanted emergent behavior?


  Dangerous adaptations?


  Unwanted emergent behavior? SOS!



  How can we test for that and/or avoid it?


  General idea:
Use learning to create event sequences for
tested system that reveal examples for
unwanted emergent behavior and dangerous
adaptations.
  Use simulations (if necessary) to provide the
feedback necessary for learning


Ag tested,1 … Agtested,m

Ag byst,1

.
Env .
.

Ag byst,k

Ag event,1 … Ag event,n

Learner


  In theory, anything able to learn event
sequences could be used
  In practice, evaluating complete event
sequences is easier than trying to evaluate
potential of partial sequences or sequence
skeletons
 evolutionary methods advised
  But: use as much knowledge as possible
 targeted operators

  We need to evaluate how near the simulation
of a given event sequence came to creating a
specific (unwanted) behavior:
  We evaluate the simulation state after each
event ( step‐fitness) and sum up these
fitness values
  Step‐fitness depends on the application
(although we see some common patterns in
our applications)

  The main inﬂuence on the complexity are
  Number of event generators
  Length of event sequences
( search space of the learner)
  Size of the tested system only plays a role in
the simulations (so, hopefully, linear)


  Testing computer game AIs
  FIFA 99 (CEC‐04, CIG‐05)
  ORTS (CIG‐09)
  Starcraft (AIIDE‐11)
  Finding problems in student written MAS for
rescue simulator ARES (ECAI‐06, IAT‐06)
  Testing surveillance networks
  Harbor surveillance and interdiction (CISDA‐09)
  Patrolling robots with stationary sensor platforms


  Testing and evaluating self‐organizing, self‐
adapting transportation systems
(ADAPTIVE‐10, SASO‐12)
  Testing agriculture sensor networks (and
watering machinery) (on‐going work)


SASO‐08; Communications of SIWN 4, 2008;
EASe‐09; ADAPTIVE‐10
Scenario:
Group of agents for performing dynamic pickup
and delivery tasks
Objective:
Optimize performance (here: distance traveled)


  Self‐organizing system based on info‐
chemicals:
  tasks announce themselves by infochemicals that
are propagated
  Transport agents follow infochemicals trails while
sending out infochemicals themselves
  Picked‐up tasks announce this via infochem.,
again
  Test goal: How ineﬃcient can the tested
system be?

  Events: pickup and delivery coordinates +
time when event is announced to the tested
system
  Learner: GA learning a single event sequence
  Fitness: One simulation then comparing
emergent solution to optimal solution quality
normalized by optimal solution
(maximizing this diﬀerence)


  Test system consistently found event
sequences solved by tested system 4 times
worse than optimum (over varying event
numbers)


EASe 2010, EASe 2011, ADAPTIVE‐10
Scenario:
Group of agents for performing dynamic pickup
and delivery tasks,
quite a number of recurring tasks (every day)
Objective:
Optimize performance (here: distance traveled)



  Self‐organizing system based on info‐chemicals
with an advisor:
  Gets observations from all agents
  Determines recurring events
  Computes optimal (good) solution for these
  Determines what individual agents do wrong and
creates advice exception rules for them (several rule
variants)
  Test goal: how much damage to performance
can adaptations by advisor do (if exploited by
adversary)?


  Events as before
  Learner: GA learning two event sequences:
  Setup & break sequence
  targeted operators for “twining”

  Fitness:Simulation performs setup sequence often
enough to trigger adaptation then does break
sequence
  Comparing
(1) break sequence emergent solution before and after adaptation plus
(2) achieved adaptation plus
(3) nearness of break solution to optimum,
again normalized by optimal break solution (main focus on maximizing (1))


  Least intrusive advisor variant only made
things less than twice worse
  Test system allowed to compare the danger
potential of diﬀerent advisor variants
  Test system also found event sequences
showing oﬀ the advantages of the variants


CISDA‐09, CISDA‐11
Scenario:
Group of mobile and stationary sensor
platforms (with policies guiding movement of
mobile platforms)
  Harbors (simulated)
  Experimental robot setting (simulated and real)
Objective:
Protect a particular location

  Implementation of patrol and interception
policies (2) for harbor security in a GIS‐based
harbor simulation
 


  Events: high‐level waypoints for attack
agents together with speeds for traveling
between them
Use a standard path planner to navigate
between waypoints (creating low level
waypoints around obstacles)


  Learner: Particle swarm system
Particle represents an attack (i.e. waypoints
and speed)
  Fitness: Several evaluation functions for a
particle based on a simulation run combined
using goal ordering structures
              (<1, {<2, <3, <4},…<n)
  Nearness to target location
  Distance to defense agents

  A lot of the goal ordering structures are able
to find weaknesses for various policies and
various numbers of defenders and attackers
  Some ordering structures find more time‐
based attacks, others favor sacrifice attacks
  Some found attacks were not very intuitive
 would most probably be overlooked
  Simulation reflects real world well


  Look at advisor concept!
  Before giving advice, test it!
  Using Monte‐Carlo simulations (SASO‐11)
  In adversary situation: use testing described
before


  General guidelines for
  Fitness measure
  Targeted operators
  How can we tell approach to ﬁnd new
problem?
  For self‐awareness:
  Run‐times are an issue
  What if agents need more global view for using
exception rules?
”Distributed” trigger

Testing cooperative autonomous systems for unwanted emergent behaviour and dangerous self-adaptations

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