– Internalized knowledge : problem representations and/or task-relevant knowledge held by individual team members – Externalized knowledge : problem representations and/or task-relevant knowledge explicitly shared & acknowledged by multiple team members 3 Macrocognition: the process of transforming internalized knowledge into externalized team knowledge through individual and team knowledge building processes (Fiore et al., 2010)
B OIDS, D ROIDS, & N OIDS : D ESCRIPTION AND I MPLICATIONS
OF AN I NTEGRATIVE R ESEARCH P ARADIGM ON M ACROCOGNITION Steve
W.J. Kozlowski Georgia T. Chao 27 th Annual Conference of the
Society for Industrial & Organizational Psychology April 28,
2012 James A. Grand Michael T. Braun Goran Kuljanin The views,
opinions, and/or findings contained in this presentation are solely
those of the authors and should not be construed as an official
Department of the Navy or Department of Defense position, policy,
or decision, unless so designated by other documentation.
Background Defining and modeling the dynamics of macrocognition
Theory integration and development Macrocognitive process model
Research paradigm & results Computational simulation CRONUS
Implications & future directions Boids, Droids, & Noids:
Description and Implications of an Integrative Research Paradigm on
Macrocognition 2 Internalized knowledge : problem representations
and/or task-relevant knowledge held by individual team members
Externalized knowledge : problem representations and/or
task-relevant knowledge explicitly shared & acknowledged by
multiple team members 3 Macrocognition: the process of transforming
internalized knowledge into externalized team knowledge through
individual and team knowledge building processes (Fiore et al.,
2010) Individual knowledge building processes : intra-individual
activities related to information gathering, synthesizing, and
interpretation (i.e., learning ) Team knowledge building processes
: inter-individual activities related to information sharing,
explanation, and consensus-building (i.e., sharing ) 4
Macrocognition: the process of transforming internalized knowledge
into externalized team knowledge through individual and team
knowledge building processes (Fiore et al., 2010) Complex
macrocognitive outcomes and patterns (i.e., internalized and
externalized knowledge) emerge as a result of these distinctive
intra-individual and inter-individual processes (e.g., Kozlowski
& Klein, 2000) 5 Team members learn certain information with
varying levels of effectiveness and efficiency thus impacting the
speed & quality of team planning and decision-making leading to
within-team variance in knowledge acquisition rates... Relevant
Knowledge Pool Decision Point Use of agent-based models to
conceptualize emergent behavior Simple, ruled-based interactions
among constituent units produces higher- level/collective behavior
(Reynolds, 1986) 6 Da BOIDS (Reynolds, 1986) Separation Move to
avoid collisions with flockmates Alignment Steer towards average
heading of flockmates Cohesion Move towards average position of
flockmates 123 Flocking Behavior in BOIDS Macrocognitive process
model describes how fundamental learning and sharing mechanisms
lead to emergence of macrocognitive outcomes 7 Select Data to Learn
Learning Rate: Acquisition Knowledge Internalized: Non-overlap
Internalized: Partial overlap Internalized: Full overlap Knowledge
Pool Learning Rate: Sharing Acknowledge Externalized: Partial
overlap Externalized: Full overlap Sharing Inter-Individual
Intra-Individual Select Data to Learn Knowledge Pool Shared
information directs/focuses subsequent learning 1 2 New information
from sharing 8 Computational simulation based on macrocognitive
process model Experimental task to test macrocognitive process
model Simulated agents ( DROIDS ) Like the BOIDS, our DROIDS follow
simple rules to determine: What & when to learn What & when
to share/communicate Simulation details 3000 three-person teams
Varied three parameters: Member learning rates Member sharing
frequency Proportion of common & unique information 9
Computational simulation based on macrocognitive process model
Boids, Droids, & Noids: Description and Implications of an
Integrative Research Paradigm on Macrocognition Real teams ( NOIDS
) CRONUS Crisis Relief Operation: Naval Unit Simulation Ad hoc
teams with distributed expertise (Fiore et al., 2010) Goal is to
learn & share all relevant information in order to make optimal
decision Pilot study ~10 three-person teams participated in nine
trials varying from 8-12 minutes in length Explore diagnostic value
of TKT metrics Compare to results of computational simulation 10
Experimental task to test macrocognitive process model Boids,
Droids, & Noids: Description and Implications of an Integrative
Research Paradigm on Macrocognition 11...as a result, when a team
member reaches their individual learning potential before other
members......they are stuck and must remain idle for a longer
period of time as they wait for the slower teammates to acquire
knowledge and begin sharing. Team members acquire information at
different rates... Simulated Team (DROIDS) 12 A similar pattern
emerges with real human actors! Variation in learning
rates......which leads to longer periods of idleness for faster
learners....means people reach their maximum individual learning
potential at different points... Simulated Team (DROIDS) Human Team
(NOIDS) 13 As individuals acquire and share information, different
distribution patterns emerge that are reflective of individual and
team learning strategies Simulated Team (DROIDS) An effective team
is one that can quickly distribute information across all team
members Thus, the manner by which the non- and partially
overlapping curves fluctuate is indicative of how teams are sharing
& distributing information 14 Each team member learns their own
unique expertise quickly, thus producing a sharp increase in non-
overlapping information. Members then share their information with
others, though in no particular order. As a result, each member can
essentially pick when and which information to learn randomly,
which produces a bell-shaped pattern of partially-overlapping
information. Fast Learning, Random Sharing Human Team (NOIDS)
Simulated Team (DROIDS) Emergence of macrocognitive outcomes
conceptually and analytically modeled utilizing principles of
agent-based modeling (i.e., BOIDS) Comparable results from
computational simulation (DROIDS) and CRONUS (NOIDS) lend support
to foundations of macrocognitive process model Current and future
directions within research paradigm Development of embedded
interventions to improve macrocognitive processes Examination of
information uncertainty using DROIDS and NOIDS Improving team
decision-making based on macrocognitive outcomes 15 B OIDS, D
ROIDS, & N OIDS : D ESCRIPTION AND I MPLICATIONS OF AN I
NTEGRATIVE R ESEARCH P ARADIGM ON M ACROCOGNITION Steve W.J.
Kozlowski Georgia T. Chao 27 th Annual Conference of the Society
for Industrial & Organizational Psychology April 28, 2012 James
A. Grand Michael T. Braun Goran Kuljanin The views, opinions,
and/or findings contained in this presentation are solely those of
the authors and should not be construed as an official Department
of the Navy or Department of Defense position, policy, or decision,
unless so designated by other documentation.
