CogBPMN: Representing Human-computer Symbiosis
in the Cognitive Era
Juliana Jansen Ferreira, Viviane Torres da Silva, Raphael Melo Thiago, Leonardo Guerreiro Azevedo
and Renato F. de G. Cerqueira
IBM Research Brazil, Brazil
Keywords:
Cognitive Computing, Cognitive Systems, Business Process Notation, BPMN, Cognitive BPMN,
Human-computer Symbiosis.
Abstract:
The human-computer symbiosis is a core principle of Cognitive Computing where humans and computers are
coupled very tightly, and the resulting partnership presents new ways for the human brain to think and com-
puters to process data. Business Process Management (BPM) provides methods and tools to represent, review,
and discuss business domains, considering their knowledge, context, people, computer systems, and so on.
Such methods and tools will be affected by advances in Cognitive Computing. Business Process Modeling
notations need to support discussion and representation of human-computer symbiosis in any given organi-
zational context. We propose CogBPMN, a set of cognitive recommendation subprocesses types that can be
used to represent human-computer symbiosis in business process models. With CogBPMN, business stake-
holders and Cognitive Computing specialists can understand how business processes can thrive by considering
cognitive empowerment in organizations’ core processes. We discuss the proposed cognitive subprocesses in
a medical domain use case.
1 INTRODUCTION
In the past, Cognitive Computing aimed to develop
a coherent, unified, universal mechanism inspired
by the mind’s capabilities (Modha et al., 2011). It
focused on investigating the development of self-
learning systems, which naturally interact with hu-
mans in complex environments, and are capable of
adapting themselves to context. More recently, the
idea of a human-computer symbiosis is gaining mo-
mentum in the Cognitive Computing research (Kelly,
2015) where humans and computers collaborate, us-
ing their unique and powerful capabilities, to build an
environment where knowledge is created and evolves
considering environment events. Computers bring
their capability to deal, in different ways, with large
sets of data, which is impractical for the human brain.
On the other hand, humans provide their capability to
judge and make decisions, to assess situations consid-
ering their intuition and all kinds of knowledge (struc-
tured, unstructured, subjective, etc.), and their abil-
ity to innovate in a given domain. Understanding this
human-computer symbiosis is the key to the applica-
tion of proper Cognitive Computing resources in any
business domain.
The relationship between humans and comput-
ers is intricately established in any business and so-
ciety. However, to understand and discuss it, con-
sidering the advantages of Cognitive Computing re-
sources to the modeled business, we need to rep-
resent that relationship. Business Process Manage-
ment (BPM) practices already present process mod-
eling notations to represent business domains. BPM
also investigates the bridge between business context
and software systems, considering business process
models as a source of early software system’s re-
quirements (Alotaibi and Liu, 2017). Therefore, busi-
ness process models are a representation that can be
used to express the human-computer symbiosis nec-
essary to define artifacts for the development of cog-
nitive systems. However, BPM still requires a “cog-
nitive layer” above its practices to address the evolu-
tion and adaptation to the Cognitive Era. Cognitive
BPM, coined in (Nezhad and Akkiraju, 2014), refers
to a new paradigm in BPM, which encompasses all
BPM contexts and aspects of its ecosystem that are
impacted and enabled by Cognitive Computing tech-
nologies (Hull and Nezhad, 2016).
Any business process, from transaction-intensive
to knowledge-intensive (Di Ciccio et al., 2015),
850
Ferreira, J., Torres da Silva, V., Thiago, R., Azevedo, L. and Cerqueira, R.
CogBPMN: Representing Human-computer Symbiosis in the Cognitive Era.
DOI: 10.5220/0009787408500858
In Proceedings of the 22nd International Conference on Enterprise Information Systems (ICEIS 2020) - Volume 2, pages 850-858
ISBN: 978-989-758-423-7
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
has the potential for cognitive empowerment through
human-computer symbiosis. Several organizations
have their business processes designed with Business
Process Model and Notation (BPMN) - the de-facto
standard for business process modeling (Chinosi and
Trombetta, 2012). BPMN already deals with human-
computer relation, e.g., the user representation sup-
ported by system task characterizes a human per-
forming a task with the assistance of a software sys-
tem (OMG, 2011). However, we believe that BPMN
needs resources to support the discussion, representa-
tion, and specification of human-computer symbiosis
necessary to develop cognitive systems.
The relation between humans and computers deals
with other aspects of Cognitive Computing. For ex-
ample, machine learning techniques support various
human tasks involved in interpretative-intensive ac-
tivities (Kelly, 2015). Some of those tasks, as de-
picted in (KPMG, 2015), are the identification of con-
cepts in massive data, ranking web searches, pattern
recognition, trend finding, and sentiment analysis on
social media. With the immediate dissemination of
such technologies, the relationship between humans
and AI algorithms in daily tasks is undoubtedly be-
coming more transparent. The relationship between
humans and computers in these cognitive scenarios
is symbiotic: the quality of such cognitive systems
increases because of the interaction itself. In this
paper, we propose CogBPMN – four recommenda-
tion cognitive subprocesses types to represent human-
computer symbiosis in business process models. The
subprocesses indicate activities to represent actions
for recommendation, creating evidence from the rea-
soning used to reach recommendations, and getting
user feedback. Besides, the subprocesses suggest rep-
resentations for the involved data and knowledge. We
exemplify the use of CogBPMN, designing a business
process of the medical domain scenario.
Our main motivations to propose CogBPMN are:
(i) explore the representation of processes focusing on
the modeling of Cognitive Computing activities; and,
(ii) use BPMN to allow the analysis and (re)design of
organization models containing such processes. Rep-
resent human-computer symbiosis in a business pro-
cess that can be used by stakeholders and Cognitive
Computing specialists to (re)analyze and (re)think
processes and decide where the Cognitive Computing
resources can make a strategical difference for busi-
nesses. In the current version of CogBPMN presented
in this paper, we have chosen to focus on the model-
ing of recommendation processes (Rich, 1979), which
is a classic standard process coming from experts and
recommendation systems.
The remainder of this work is divided as follows.
Section 2 presents the background. Section 3 presents
our proposal. Section 4 presents an example of the
use of the proposal. Finally, Section 5 concludes and
presents future work.
2 BACKGROUND
Cognitive Computing refers to software (cognitive)
systems that learn at scale from their interaction with
humans and the environment. One of the defining
characteristics of cognitive systems is that they are
capable of improving their performance over time by
leveraging its understanding of their users and ap-
plication domain. Some requirements are: (i) inter-
actions should be (at least partially) recorded; and,
(ii) models should learn from previous interactions.
The research and development of cognitive systems
involve multiple computer science areas of exper-
tise. There must be a constant technical collabora-
tion from different professionals to tackle the chal-
lenges of building a cognitive system. The areas in-
volved depend on the problems that the cognitive sys-
tem aims to solve. At least HCI (Human-Computer
Interaction) experts (UX designers and HCI profes-
sionals) and developers need to work closely together
to build a cognitive system. Designers and HCI pro-
fessionals, working together with industry experts,
place the new system in real scenarios; and developers
and machine learning experts define the algorithmic
strategy and datasets for solving the scenario prob-
lems. This multidisciplinary technical approach ap-
plied to Cognitive Computing differs from other cur-
rent approaches of Artificial Intelligence (AI) that fo-
cus on algorithmic accuracy and not on the people that
work with the system (Kelly, 2015). Cognitive sys-
tems allow humans and computers to collaborate and
produce better results, each one bringing their supe-
rior skills to the partnership: computers with rational
and analytics and people with intuition, empathy, and
judgment. That is why this is such a multidisciplinary
approach (Kelly III and Hamm, 2013). HCI (Human-
Computer Interaction) is an important research area to
investigate and explore human-computer symbiosis.
HCI and AI expertise have been combined for some
time (Grudin, 2009). The combination of HCI and
AI research has been a concern of major tech com-
panies like Google
1
, which launched an initiative to
study and redesign the ways people interact with AI
systems (Holbrook, 2017).
We argue that a cognitive system learns when-
ever the output of a given model evolves due to
1
https://ai.google/pair/
CogBPMN: Representing Human-computer Symbiosis in the Cognitive Era
851
changes in the knowledge base. Therefore, one re-
quirement is that models, in principle, should use the
acquired knowledge in their predictions. This defini-
tion of learning is loosely based on (Mitchell and et al,
1997). In particular, we relax the performance mea-
surement requirement, since evaluating “how good is
the human-computer symbiosis” is a non-trivial task:
A computer program is said to learn from experience
E with respect to some class of tasks T and perfor-
mance measure P, if its performance at tasks in T, as
measured by P, improves with experience E.
Recommendation and Expert systems are refer-
ences in AI for Cognitive Computing approaches.
Recommendation, or recommender systems, are soft-
ware tools and techniques that provide suggestions to
support users’ decisions (Adomavicius and Tuzhilin,
2005). Recommendation systems deal with the prob-
lem of estimating ratings for current items, usually
based on the ratings given by the user to other items
and/or by other users to the same items. Expert
systems reconstruct the expertise and reasoning ca-
pabilities of qualified specialists within limited do-
mains. The underlying assumption is that experts con-
struct their solutions from single pieces of knowledge,
which they select and apply in a proper sequence.
Hence, expert systems require detailed information
about the domain and the strategies for applying this
knowledge to problem-solving. Those systems simu-
late problem-solving tasks over static representations
of some knowledge domain (Kidd, 2012).
Although recommender systems include concepts
of cognitive science (Rich, 1979), they handle rec-
ommendation problems that explicitly rely on rat-
ing structures. On the other hand, Cognitive Com-
puting enables “knowledge acquisition at scale”, i.e.,
deeper than ratings of items, using emerging meth-
ods in natural language understanding and machine
learning techniques (Hull and Nezhad, 2016). Expert
systems, different from cognitive systems, do not aim
for human-computer symbiosis, but to emulate human
thinking and problem-solving abilities (Kidd, 2012).
The discussion, mapping, modeling, and represen-
tation of business scenarios are rich topics to be devel-
oped by the BPM research area. Those topics are re-
lated to the research of Cognitively-enable BPM (Hull
and Nezhad, 2016), and referenced in our work as
Cognitive BPM. Particularly those scenarios where
people need to harvest insights from vast quantities
of data to understand complex situations, make accu-
rate predictions, and anticipate the unintended con-
sequences of actions and other human-centered pro-
cesses.
There are also important concepts and key
abstractions for Cognitive BPM and Knowledge-
intensive Processes (KiP’s) research (Di Ciccio et al.,
2015)(Hull and Nezhad, 2016)(Netto et al., 2013).
Cognitive Computing presents the possibility of
“knowledge at scale” (Hull and Nezhad, 2016). KiP’s
process representation deals with the life-cycle of
knowledge in business processes. In that way, large
amounts of knowledge relevant to a process instance
can be considered as input for new process’ instances
and the model itself. Moreover, cognitive potential
can be present in structured workflow processes to
unstructured and knowledge-intensive ones (Hull and
Nezhad, 2016). Also, the practice of software sys-
tems early requirement derivation from business pro-
cess models (Alotaibi and Liu, 2017) can be applied
for cognitive systems’ specifications.
BPM has been used in different industries for over
a decade (Van der Aalst, 2013). Hence, there is a large
amount of pre-existing knowledge legacy of business
processes models in organizations. The knowledge
presented in those business models and their instances
is a crucial asset for each organization that wants to
advance to the Cognitive Era. Questions like “What
and how can we learn through discussing and revising
old business processes in the light of Cognitive Com-
puting technologies?” and “What can happen to trans-
actional processes once there is a technology to han-
dle more volume of data and unstructured data?” are
going to guide the Cognitive BPM research agenda.
BPM activities, like mapping, modeling, and analy-
sis of processes, can gain with Cognitive Computing
technology abilities to explore and get insights from
large amounts of business process data.
3 CogBPMN
This section describes CogBPMN, our proposal for
representing cognitive subprocesses using BPMN.
We focus on subprocess types that include recom-
mendations, evidence that support those recommen-
dations, and the handling of user feedback. The rec-
ommendation subprocesses are a guide since they
contain activities that should be used when model-
ing a system that provides recommendations. We
also present an abstract view about how to perform
those activities, although it is not the focus of this
work. Our current proposal of CogBPMN comprises
four subprocesses types: (i) Recommendation sub-
process; (ii) Recommendation with evidence subpro-
cess; (iii) Recommendation with feedback subpro-
cess; and, (iv) Recommendation with feedback and
evidence subprocess.
Section 4 presents an example of the proposal for
a cognitive application in the medical domain. In the
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following, we present the proposed BPMN four sub-
processes types, and their abstract representation us-
ing BPMN subprocesses.
We decide to explore BPMN specification (OMG,
2011), which is the de-facto standard modeling lan-
guage for business process modeling (Chinosi and
Trombetta, 2012), to identify definitions and visual
representations that could support our proposal for
CogBPMN. Table 1 presents the elements and corre-
sponding icons we are using in this work.
Table 1: BPMN elements used in this work.
Element Icon
Service task
User task
Data store
Data object
We selected service and user tasks to represent advi-
sor and user’s tasks, respectively. A service task is
a task that uses some sort of service ((OMG, 2011),
pp.158). Its definition already covers our need to
represent a task performed by an algorithm or ser-
vice. We choose the user task element to represent
tasks where humans execute an activity with the ad-
visor’s aid. A user task is a typical workflow task
where a human performs the task with the assistance
of a software application ((OMG, 2011), pp.163). In
CogBPMN, the software application is the advisor for
the represented subprocess.
We used the data store element to represent a
generic knowledge base in the main process and also
the specific data stores in the cognitive subprocesses.
A data store provides mechanisms to retrieve or up-
date stored information that will persist beyond the
scope of the process ((OMG, 2011), pp.208). We
created a specific data store called process instances’
data store, which represents the data of the previously
executed process’ instances. The cognitive subpro-
cess has the potential capacity to learn from its exe-
cution and the main process execution. We used the
data object element ((OMG, 2011), pp.205-206) to
represent specific instances data, and collection of in-
stances data. Those elements are present in the main
process model and the subprocesses.
BPMN is a flexible notation that allows its users
to add more semantics to its elements, like addressing
different meanings to the same element represented
in different colors. For CogBPMN, there are specific
demands that the notation specification needs to ad-
dress. For example, the data store for process’ in-
stances usually needs to be handled on cognitive sub-
process’ new instances. Data stores remain generic
and central for cognitive processes, representing data
and knowledge generated and consumed throughout
the process’ instances. We argue that CogBPMN
specification is a conservative extension (Turski and
Maibaum, 1987) of BPMN to represent specific activ-
ities that define a pattern, as a specialized type of sub-
process like Transaction, Ad-Hoc and Event Subpro-
cesses ((OMG, 2011), pp.173-183). We are propos-
ing a visual representation that does not interfere with
the model notation specification but makes explicit
and enriches the representation for identifying and
discussing when the human-computer symbiosis hap-
pens in business processes.
3.1 Cognitive Recommendation
Subprocesses
We present in this section, the four Cognitive Recom-
mendation subprocesses. They are abstract represen-
tations, corresponding to suggestions of activities to
be modeled in each case, i.e., the process modeler de-
signs those activities according to the scenario being
modeled.
3.1.1 Recommendation Subprocess
Figure 1 illustrates an abstract representation of the
Recommendation subprocess. This subprocess is ex-
tended by the other three by defining new activities
and other elements. It is the simplest proposed sub-
process.
Figure 1: Recommendation subprocess abstract representa-
tion.
The first activity represents the advisor analyzing the
knowledge base (KB) of the application to create hy-
potheses. The second activity represents the advisor
generating the recommendations and storing such rec-
ommendations in (another) KB. These two activities
can be merged into one activity if necessary, repre-
senting the analysis and the generation of recommen-
dations. The third activity represents the actions of
the user monitored by the advisor. This action could
CogBPMN: Representing Human-computer Symbiosis in the Cognitive Era
853
represent, for instance, the selection of an option from
the list of options recommended by the advisor. They
do not need to be executed immediately after the first
two actions.
To provide recommendations to a user, the cogni-
tive advisor analyzes available knowledge related to
the application domain, the process being executed,
and the process’ instances already executed. Besides,
the advisor can learn about the recommendations pro-
vided and the actions carried out by the user. For ex-
ample, the advisor evaluates if the user has followed
or not the recommendations and uses such informa-
tion when making new recommendations. This ex-
ample is a kind of implicit feedback produced by the
user for the recommendations provided by the advi-
sor. Some examples are:
• Using the history of actions executed by the user
and his peers, the advisor recommends the next
actions to be executed;
• Using previous recommendations and the most se-
lected options in a specific context, the advisor
suggests the ones the user may choose.
In both cases above, the advisor monitors the actions
performed by the user to learn about its recommenda-
tions.
3.1.2 Recommendation with Evidence
Subprocess
Figure 2 presents an abstract representation of Recom-
mendation with evidence subprocess. It extends the
Recommendation subprocess by making available to
the user the evidence that supported each generated
recommendation. Such evidence is relevant to the
user to understand why the advisor has provided the
recommendations. Recommendations and evidence
are stored along with the actions taken by the user.
The advisor can use these data to learn and make more
precise recommendations. Examples of this type of
process are:
• Besides recommending the next action, the advi-
sor shows the user evidence like the history of pre-
vious interactions executed by him and by others;
• Besides suggesting options to the user, the advisor
shows evidence like recommended and selected
options in past similar contexts.
3.1.3 Recommendation with Feedback
Subprocess
Figure 3 presents an abstract representation of Rec-
ommendation with feedback subprocess. It extends
the Recommendation subprocess by allowing the user
Figure 2: Recommendation with evidence subprocess ab-
stract representation.
to provide feedback about the advisor’s recommenda-
tions. This kind of feedback is explicit, different from
the implicit feedback already present in the Recom-
mendation subprocess. When given explicit feedback,
the user informs if she/he likes or dislikes a recom-
mendation. The advisor stores the recommendations,
actions executed by the user, and the explicit feed-
back. It uses such knowledge to learn and to make
improved recommendations. Examples of this type of
process are:
• The user likes the recommended action and fol-
lows the recommendation;
• The user likes some of the recommended options
and dislikes others;
• The user does not follow any of the recommended
options.
Figure 3: Recommendation with feedback subprocess ab-
stract representation.
3.1.4 Recommendation with Feedback and
Evidence Subprocess
Figure 4 presents an abstract representation of Recom-
mendation with feedback and evidence subprocess. It
combines the Recommendation with evidence and the
Recommendation with feedback subprocesses by al-
lowing the user to provide feedback not only about the
recommendations made by the advisor but also about
the evidence used to support them.
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Figure 4: Recommendation with feedback and evidence
subprocess abstract representation.
The advisor should store the recommendations, evi-
dence, actions executed by the user, and also the feed-
back to provide a more precise recommendation. The
feedback about evidence is essential, e.g., to guide the
advisor on the sources (knowledge-based, documents,
etc.) it uses in its analyses. Some examples of Rec-
ommendation with feedback and evidence subprocess
are:
• The user likes the recommended actions and also
agrees that the previous actions executed in simi-
lar contexts are the correct evidence to be used;
• The user wants the recommended options but does
not agree with the evidence. The user explains the
context considered by the advisor is not similar to
the context of the execution.
The Recommendation with feedback and evidence
subprocess is the most complete proposed cognitive
recommendation subprocess. The other subprocesses
are simplifications of this one. The first and sec-
ond activities (Analyze Knowledge Base and Generate
Recommendation) are present in all recommendation
subprocesses. To provide recommendations to a user,
the cognitive advisor analyzes available knowledge
bases (KBs) of the application domain and the pro-
cess’ instances already executed. Besides, the advisor
can learn from previous recommendations and the ac-
tions carried out by the user stored in the process’ in-
stances KB. The advisor evaluates if the user has fol-
lowed or not the recommendations and uses such in-
formation when making new recommendations. The
information about the user’s decisions for the recom-
mendations is a kind of implicit feedback used by the
advisor.
In the feedback, the user informs if she/he likes or
dislikes the recommendation, and if she/he agrees or
disagrees with the evidence used to support the rec-
ommendation. In both cases, the user should also
be able to include comments (e.g., expressed in nat-
ural language) about the recommendations and evi-
dence. For instance, on the one hand, the user may
like the recommendations but understands that the ev-
idence supporting the recommendations are not ade-
quate. In such a case, the advisor has provided the
right recommendations based on the wrong evidence.
On the other hand, the user may dislike the recom-
mendations, but agree with the evidence. In this case,
the advisor has provided the wrong recommendation
based on accurate evidence.
The advisor should store the recommendations,
evidence, actions executed by the user, and the feed-
back to provide a more precise recommendation. The
feedback about evidence is essential, e.g., to guide
the advisor about the sources (knowledge-based, doc-
uments, etc.) it uses in its analyses.
4 EXAMPLE OF MODEL USING
CogBPMN
This section presents an example using our pro-
posal of cognitive subprocesses types (CogBPMN) to
model the business process that represents the Doc-
tor Oncology scenario (Figure 5). This scenario il-
lustrates the use of IBM Watson for Oncology
2
, the
AI technology from IBM, which helps physicians
quickly identify critical information in a patient”’s
medical record, surface relevant articles and explore
treatment options to reduce the unwanted variation of
care and give time back to their patients.
The process Perform Clinical Assessment for On-
cology treatment (Figure 5) starts the cognitive doctor
advisor, which helps a doctor (i.e., the user) to ana-
lyze patient’s medical records and previous exams by
highlighting the potentially significant aspects for a
given patient disease. The advisor monitors the user’s
interactions to learn and provide recommendations.
The activity Analyze Patient’s Medical Records
is detailed following the CogBPMN’s Recommenda-
tion subprocess type (Figure 1) through the subpro-
cess presented in Figure 7. The advisor analyses the
aspects visualized by the user about the patient cur-
rent medical status (activity Analyze Patient Current
Medical Status). The advisor learns from this (activity
Analyze Medical Knowledge), and provides recom-
mendations for future actions information. The user
makes decisions about the provided recommendations
(activity Decide about Relevant Medical Recommen-
dations).
The next cognitive activity of the oncology pro-
cess, Analyze Analogue Cases (Figure 5), is detailed
2
https://www.ibm.com/products/clinical-decision-
support-oncology
CogBPMN: Representing Human-computer Symbiosis in the Cognitive Era
855
Figure 5: Perform Clinical Assessment for Oncology treatment process - main process.
following the CogBPMN’s Recommendation with
feedback and evidence subprocess (Figure 4) through
the subprocess presented in Figure 6. The advisor an-
alyzes characteristics of other patients’ analog cases
by taking into account: (i) the feedback about recom-
mendations provided to such analog cases; (ii) the evi-
dence used to support such recommendations and the
feedback they received; and, (iii) the patient current
medical record (activity Analyze Analogue Cases).
Afterward, in the activity Analyze Related Domain
Data Sources, the advisor uses the r
´
esum
´
e about ana-
log cases generated in the previous activity to pro-
vide recommendations about the current patient case
and the evidence, such as books, papers or medical
records of other patients, to support the recommen-
dations. Then, the user provides feedback about the
recommendations (activity Provide Feedback about
Recommendation) and the evidence (activity Provide
Feedback about Evidence). Back to the main process
(Figure 5), the doctor decides if the patient should do
complementary exams.
The next oncology process’ cognitive activity
Identify Potential Treatment Options (Figure 5) is de-
tailed following the CogBPMN’s Recommendation
with evidence subprocess (Figure 2) through the sub-
process presented in Figure 8. The advisor analyzes
the case information and identifies a prioritized list of
treatment options by associating then with a set of ev-
idence that supports such a list (activity Generating
Treatment Options). The advisor monitors the treat-
ment chosen by the doctor and uses such informa-
tion when making new recommendations about treat-
ments. Then, the doctor explores the recommenda-
tions and evidence (activity Explore Treatment Op-
tions and Evidence).
Finally, the doctor discusses potential treatments
with the patient (activity Discuss Potential Treatment
Options), and, if a decision about the treatment rises,
the doctor updates the patient’s medical record (activ-
ity Update Current Medical Record).
5 FINAL REMARKS AND
FUTURE WORK
Several works have evaluated the cognitive load
to understand process models in specific BPM no-
tations (Gruhn and Laue, 2006)(Gruhn and Laue,
2009)(Holschke et al., 2009). More recently, some
authors have presented the impact of cognitive sys-
tems in BPM systems. Two major theoretical contri-
butions on that subject are (Rich, 1979): 1. a frame-
work of how cognitive systems will impact BPM; and,
2. a meta-model called Plan-Act-Learn for Cogni-
tive-Enabled processes.
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Figure 6: Recommendation with feedback and evidence subprocess of doctor advisor process.
Figure 7: Recommendation subprocess of doctor advisor
process.
Figure 8: Recommendation with evidence subprocess of
doctor advisor process.
However, to the best of our knowledge, no work pro-
posed the extension of BPMN or other BPM notation
to model cognitive related activities
3
, which is the
3
Research conducted using Google Scholar (http://
scholar.google.com). It consisted of finding extensions for
goal of this paper. Therefore, this paper introduces an
innovative approach to model cognitive activities as
BPMN subprocesses. The proposed approach encom-
passes four complementary recommendation subpro-
cesses. The use of the approach to model the Doctor
Oncology scenario makes clear those subprocesses
should be used to model different kinds of recommen-
dations.
Our proposal points out which parts of a process
could be modeled as a cognitive subprocess along
with which kinds of cognitive activities should be
modeled if the process includes recommendations,
evidence, or feedback. The proposal is in the abstract
conceptual level presenting some directions on what
should be considered by the subprocesses’ activities.
Hence it does not present how advisors should be
combined nor which algorithmic approaches should
be used to keep the knowledge base evolving, which
is leveraged to the implementation phase.
We intend to extend CogBPMN to model other
kinds of cognitive subprocesses, such as the learn-
ing process itself. In this work, the learning process
is presented as an intrinsic characteristic of the rec-
ommendations subprocesses. However, the modeler
should be able to represent which classes of learn-
ing algorithms (or models) that are more suitable for
each type of subprocesses. Some goals are better or
only achievable with particular algorithms. For ex-
ample, if the subprocess requires that evidence should
support the recommendations, neural networks
4
can-
not be used (Adomavicius and Tuzhilin, 2005). The
proposed subprocesses learn in the sense that previ-
Business Process Models; several were found: for SOA
(Service-Oriented Architecture), aspects, and model-driven
BPM, among others.
4
Weights in Artificial Neural Networks are not easily in-
terpretable.
CogBPMN: Representing Human-computer Symbiosis in the Cognitive Era
857
ously acquired knowledge are (or should be) lever-
aged by models in their predictions. Learning could
be achieved by retraining the models.
Moreover, we are in the process of defining visual
elements in BPMN to represent the four recommenda-
tions cognitive subprocesses. For example, we could
use a specific icon (like the one depicted in Figure 9)
for an activity expanded by a cognitive subprocess.
Figure 9: Icon for CogBPMN activity.
In the following, we intend to evaluate the proposed
notation by surveying experts in BPM and BPMN,
and domain experts to discuss real business processes
exploring opportunities to take advantage of cogni-
tive technology to empower human-computer inter-
action. We also intend to evaluate the proposal in
modeling other kinds of processes like transactional
and knowledge-intensive processes in the oil and gas
domain. As another future work, we plan to evolve
CogBPMN with other cognitive subprocesses types
than the proposed four in the current approach, e.g.,
conversation subprocess where the advisor identifies
the willingness of the user by understanding the user’s
questions through tracking questions and the provided
answers and the feedback of the user to which ques-
tions were correctly answered.
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