Knowledge Management as a Service
When Big Data Meets Knowledge Management
Thomas Ochs
1
and Ute Riemann
2
1
Villeroy & Boch, P.O.Box 11 20, 66688 Mettlach, Germany
2
SAP Deutschland SE & Co. KG, Hasso Plattner Ring 7, 69190 Walldorf, Germany
Keywords: Big Data, Big Data Analytics, Knowledge Management, Cloud Services, KMaaS.
Abstract: Purpose – Nowadays the world is getting more technological savvy. The collection of data is becoming a hype
which is a phenomenon is called “big data”. Companies seeking for these data collections and data analytics
assuming valuable insights. As for now, these valuable insights are perishable to a high degree - perishable
because the insights are only valuable if you can detect and act on them (The Forrester Wave, Q3 2014, p2).
In our article, we propose to take advantage of big data analytics while introducing a service-oriented
knowledge management discipline that will allow gaining the full value of big data. Herein, we focus on the
benefit aspect of big data linked to the service approach of knowledge management, which may increase the
value of big data.
Findings –In fact, big data analytics offer value and the use of big data has the potential to transform business
in itself. However, there are greater opportunities beyond big data analytics once we turn data from
information into a knowledge linked to business strategy, easy accessible and consume. With the introduction
of knowledge management-as-a-service to the concept of big data, we provide justification for bringing
proven knowledge management strategies and tools into the cloud sphere to bear on big data and business
analytics. With the introduction of pre-defined service to knowledge management, we open the ability for
increased competitiveness as a final consequence (Thuraisingham and Parikh, 2008) and the value of any
company (Bertino et al., 2006).
Originality/Value – Our article outlines the previously underestimated strong link of big data and knowledge
management and how the delivery of data-driven intelligence is supported with the appliance of a cloud-based
service model. When big data and cloud-based knowledge management are combined are able to not only
uncover a new revenue stream but also create a true competitive advantage.
1 INTRODUCTION
With the success of big data and the remarkably
collection, storage, processing and analysis of data
volumes never seen before (Bughin et al, 2010) an
increasing volume, velocity, and variety at nearly
exponential rates available goes alongside and are
mined for useful information (Rajpathak and
Narsingpurkat, 2013). The excitement of big data is
has arguably been generated primarily from the
technical possibilities in doing so but the question is
if it is it appropriate to purely have a focus greater
data volume, faster and ease to capture data? In our
article, we would like to propose to take the next step
and focus on the generation and management of
knowledge that big data generates while using the
paradigm of cloud-based services.
Knowledge Management in general emerged
some decades ago (Drucker, 1969) and goes beyond
a mere collection of data or information, including
expertise based on some degree of reflection. It
focuses on knowledge as a valuable intellectual
capital that needs to be managed adequately
(Erickson and Rothberg, 2011). As of today, nobody
argues about the importance of managing knowledge
for continuous business success. The success rely on
non-value precursors like data and information that
needs to be turned into valuable knowledge assets. In
establishing the conceptual foundation of big data as
an additional valuable knowledge asset (or at least a
valuable asset closely related to knowledge due to big
data analytics), we can begin to make a case for
applying knowledge management services to data
assets.
Ochs, T. and Riemann, U.
Knowledge Management as a Service - When Big Data Meets Knowledge Management.
DOI: 10.5220/0005851703150323
In Proceedings of the International Conference on Internet of Things and Big Data (IoTBD 2016), pages 315-323
ISBN: 978-989-758-183-0
Copyright
c
2016 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
315
This will help us to bring big data and big data
analytics into the knowledge management field,
creating a new and easy accessible “knowledge
experience”. Here, we can cite Yogesh Malhotra: “In
knowledge management <…> the most limited
resource is no longer information. It has become
human attention – the ability to deal effectively with
the growing volume and speed of information.” In our
opinion, the pure provisioning of data and
information with the advantage of big data
technologies is not enough. Therefore, we have to
think of a new knowledge experience, to create a
consistent and easy to handle experience. With the
foundation of a cloud-based service approach in
mind, a paradigm such as knowledge management-
as-a-service can be discussed to increase the value of
knowledge even further.
2 KNOWLEDGE MANAGEMENT
Before taking a deeper look into our proposed
approach, we need to first understand the core
elements of knowledge management and the
distinction between data, information and knowledge.
2.1 Data, Information and Knowledge
Data: is a set of discrete and objective facts about
events. Information is a message, usually in the
form of a document or audio-visual
communication. As with any message, it has a
sender and a receiver.
Information: changes the way the receiver
perceives something, and to affect their judgment
and behaviour.
Knowledge: is broader, deeper, and richer than
data or information. Within managerial theories
formulated by e.g. Schumpeter (1934), Drucker
(1991) and Nelson and Winter (1982), knowledge
has been defined as a source of competitive
advantage in managerial theory. Knowledge can
be categorized in the two types of knowledge:
Tacit knowledge is highly personal and
subjective and focuses on learning and
experiences (Beijerse, 2000).
Explicit knowledge which is formal,
systematic and system-bound (Beijerse, 2000)
and can be further divided into “know what”,
which is knowledge about facts and “know
why” which refers to scientific knowledge of
rules.
If we try to categorize knowledge based on the
dimension of usage, we differentiate between.
Organization knowledge deals with management
in the organization such as policy, culture,
personnel, career planning, internal processes, cut
backs, alliances and teamwork.
Marketing knowledge is about the external
environment such as competition, suppliers,
customers, markets, target groups, consumers,
clients, users, interested parties, trade and
distribution and relation management.
Technological knowledge is knowledge of
products, research and development, core
competencies, technological development,
information and communication technology and
product development (Beijerse, 2000).
To sum up, data are a set of facts about events,
information is a processed set of facts that are
meaningful and knowledge is broader, deeper and
richer as both data and information. (Hota et al,
2015). Having stated that, knowledge management
can be considered as a process that comprises the
creation, organization, sharing and usage of tactic and
explicit knowledge (Wong and Aspinwall, 2004). In
this regard, knowledge management systems are IT
based systems developed to support the knowledge
management processes (Alavi and Leidner, 2001) and
based on the (big) data generated from big data
(analytic) tools within a dynamic process from the
perspective of business and technology (Khoshnevis
and Rabeifar, 2012).
3 BIG DATA
For companies real-time business insights that big
data technologies are offering becomes the main
source of information on top of which companies
decide and build their strategy. The value that
companies aiming to get out of big data is
tremendous, and becomes a necessary asset to survive
in a highly competitive world. Real-time insights
allow organizations, for example, to build better
products, predict what future business outcomes
might be, detect early data signals or better manage
their inventory.
3.1 Key Characteristics of Big Data
All definitions towards big data make at least one of
the following assertions (Ward and Barker, 2013):
Size: the volume of the datasets is a critical factor.
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316
Complexity: the structure, behaviour and
permutations of the datasets is a critical factor.
Technologies: the tools and techniques which are
used to process a sizable or complex dataset is a
critical factor.
Manyika et al., (2011) considers that big data refers
to datasets whose size goes beyond typical databases
that can be created, stored, managed and analysed by
existing tools; they also consider the need of the use
of new technologies for managing big data. However,
Fisher et al., (2012) considered that most often big
data refer to the conception that the volume of data
cannot be treated, processed and analysed in a
simplified way, requiring much more robust
technologies, techniques and people with new skills
for managing these large data sets.
Overall, big data refers to the idea that a vast
amount of data cannot be treated, processed and
analysed in a simplified way. One of the most cited
definitions is included in the Gartner report from 2001
they proposed a definition encompassing the “three
Vs”. Volume, Velocity, Variety. (This idea is
supported the NIST definition which states that big
data is data which: “exceed(s) the capacity or
capability of current or conventional methods and
systems”, see Intel Peer Research, 2013)
Volume: Refers to the amount of data, which is
higher. Gartner first described it back in 2001: the
Big Data volume definition will continue to
remain a moving target and it is a matter of fact
that Big Data sizes were ranging from a few dozen
terabytes to many petabytes of data in a single
dataset.
Velocity: Refers to the speed of data collection.
This means how frequently the data is generated.
Typically, we can identify three main categories:
occasional, frequent, and real-time (Zaslavsky et
al., 2013) and often time-sensitive (Lévai, 2013).
Variety: Refers to the range of data types, sources,
and languages. In addition, difference sources will
produce big data such as sensors, devices, social
networks, the web, mobile phones, etc. For
example, data could be web logs, RFID sensor
readings, unstructured social networking data,
streamed video and audio (Zaslavsky et al., 2013).
These 3Vs allow a perfect context-independent
definition of the key characteristics of big data. What
is missing here is the “V” that answers the question
why to deal with big data. Reducing big data to the
3Vs we merely focus on no more than collection,
simple analytics, and reporting for purposes of
understanding and optimizing on process or decision
and assessing the improvement of the existing
effectiveness of one’s company. So address even
more value from these data we need to consider a “4th
V – the value” as the context-sensitive dimension to
overcome the “flashlight in the dark” where the
companies are today. Therefore, we have to consider
mainly three issues:
High Complexity – getting data out of various
platforms is different and the data we get is
different – if they are available at all.
Low Insight – because there is no apples to apples
data comparison, measuring processes across the
company or even beyond becomes virtually
impossible.
Low Business Support Value – essentially a result
of the first two, means it is hard to measure the
success of the company and with a lack of
knowledge curve to improve even faster.
4 SENSING KNOWLEDGE
MANAGEMENT AS A BIG
DATA SUPPORTED SERVICE
MODEL
Cloud computing consists of a wide array of new
business models, the most prominent of which are
Software as a Service (SaaS), Platform as a Service
(PaaS), and Infrastructure as a Service (IaaS).
According to various documentations (e.g. TBR
Cloud Program, 2013).
4.1 Cloud Services
Infrastructure as a Service (IaaS): IaaS is the basis
of the cloud architecture; and constitutes the
dynamic provisioning of computing, storage, and
network resources. IaaS users, in particular
system administrators, IT architects, and
developers (the latter for testing purposes), can
access these infrastructure resources as required.
IaaS provides linkage between different types of
services which in turn leads to efficiency
improvement and time reduction in business
processes (Chang, 2013). With IaaS, the cloud
offers platform virtualization to the customer.
Instead of buying servers and other network
equipment, users just rent these resources. In
addition, whereas public cloud services are
dominated by SaaS, “outsourced Private Cloud”
services (managed/ hosted) are dominated by
IaaS. For knowledge management it is necessary
using a cloud infrastructure as a service for the
Knowledge Management as a Service - When Big Data Meets Knowledge Management
317
storage of aggregated data and knowledge to have
the required computational capacity and the
processing power.
Platform as a Service (PaaS): PaaS is on top of the
IaaS architecture and comprises the middleware
and/or development platform, that enables PaaS
users, in particular application developers and IT
designs, to develop applications within the Cloud
and/or operate them. PaaS is the offering of a
computing platform as a service. Users are able to
deploy their applications on such a platform. The
platform offers auxiliary functionality such as a
web server, databases, load balancing and more.
For knowledge management this reflects to the
ability to design own applications based on the
provided infrastructure.
Software as a Service (SaaS): SaaS contains the
uppermost layer of the Cloud architecture, the
actual business application: e.g. CRM, ERP,
collaboration, etc. SaaS users are generally
“traditional” end-users within business units.
SaaS is the basic cloud service models are well
known (Chandramouli and Mell, 2010). It is a
model in which software is offered as a service to
the user. The software is hosted on a server and
users access the software by using a web browser.
For knowledge management it is important to
have the ability to gather knowledge from
different – structured and non-structured sources.
Providing everything as a service is model that
emerged with cloud computing. Garter defines cloud
computing as a style of computing in which
massively scalable IT-related capabilities are
provided “as a service” using Internet technologies to
multiple external customers (Patidar et al., 2012).
Cloud computing realizes the idea of everything is a
service (XaaS) (Riemann, 2015) and can be
differentiated in three basic categories: Software-as-
a-service (SaaS), Platform-as-a-Service (PaaS),
Infrastructure-as-a-service (IaaS) (Villegas et al.,
2012).
Overall, cloud services have the following key
characteristics that are relevant for this article as there
are self-service on demand and network access to
cover the ability of accessing a broad range of data
sources. Cloud services as a paradigm for convenient,
on-demand access to a shared pool of configurable
resources. As guidance toward the cloud market two
dimensions shall be used to define the cloud service
market segments (Forrester, 2010): “What resources
are shared?” and “With whom resources are shared?”
For this article, we will use the slightly simplifying
assumption that clouds are commonly classified into
Public Clouds, Private Clouds and Hybrid Clouds
(Chang et al., 2014).
Private Clouds: The cloud infrastructure is
provisioned for exclusive use by a single
organization comprising multiple consumers
(e.g., business units). It may be owned, managed,
and operated by the organization, a third party, or
some combination of them, and it may exist on or
off premises (Mell and Grance, 2011).
Public Clouds: The cloud infrastructure is
provisioned for open use by the general public. It
may be owned, managed, and operated by a
business, academic, or government organization,
or some combination of them. It exists on the
premises of the cloud provider (Mell and Grance,
2011).
Hybrid Clouds: The cloud infrastructure is a
composition of two or more distinct cloud
infrastructures (private, community, or public)
that remain unique entities, but are bound together
by standardized or proprietary technology that
enables data and application portability (e.g.
cloud bursting for load balancing between clouds)
(Mell and Grance, 2011).
5 KNOWLEDGE MANAGEMENT
AS A SERVICE (KMaaS)
Considering the need of companies of having more
valuable, data-driven insights and having already
understood that knowledge management has to do
with identifying and managing knowledge assets
effectively in order to gain this competitive advantage
and about effectively managing these assets, through
combination, sharing, and other methods leading to
their growth (Zack, 1999a; Grant, 1996) we propose
to shift the available concept to the paradigm of
cloud-based services to capture knowledge (Nonaka
and Takeuchi, 1996; Polanyi, 1967), lower
complexity, and stickiness (McEvily and
Chakravarthy, 2002; Zander and Kogut, 1995; Kogut
and Zander, 1992) and to employ a tool and to even
better manage the knowledge (Choi and Lee, 2003;
Schulz and Jobe, 2001; Boisot, 1995).
We believe in the two following main statements:
With the use of big data and the benefit of cloud
computing we have the ability to provide a major
shift in how to create knowledge leading to a new
reality of knowledge management
With the shift from a centralized knowledge
management information solution and asset to a
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flexible and based on pre-defined services-based
solution
If we emerge from the basic types of cloud service
models, Knowledge Management-as-a-Service adds
a context-sensitive layer to the service models
available aiming to provide the most valuable
knowledge, in the appropriate context and the easiest
way possible. Therefore and according to our
understanding Knowledge Management-as-a-Service
is a layer on top of the basic service types that
consumes the already available and aggregated data
from the big data tools and its aggregation by big data
analytics.
Knowledge management-as-a-service is a service
model based on analytic data and consisting of
aggregate data such as lessons learned, studies to
leverage knowledge from anywhere, anything, and
anyone in a distributed computing model. With the
introduction of the cloud-based paradigm to
knowledge management, any knowledge will be
easier to access and even more important we can
address on already mentioned issue – the will created
a unique and easy-to-access knowledge experience.
To embark the new service model we have to
understand three main things:
The technology fit to allow the data capturing
The analytic fit to aggregate the data to
information and the low the first step from data
gathering to knowledge generation
The fit of access of knowledge
With the concept of Knowledge Management-as-a-
Service we will be able to move forward from purely
data collection to knowledge generation that delivers
the desired knowledge asset and competitive
advantage. Knowledge Management-as-a-Service
lets us access knowledge and experience structured in
a way that we can find it, understand it and use it
instantly.
Let us assume that Knowledge Management-as-a-
Service is a productized and cloud-based service
model offering a set of pre-defined knowledge assets
that allows the execution data analytics, information
aggregation and knowledge provisioning. Although
such a service harbours an economic potential and
proposes value towards data and information,
questions that need to be answered are: can an
individual and company-specific need for knowledge
supported by a service? Additionally we need to
understand how to manage the way from operational
data, information towards valuable knowledge.
5.1 Big Data Impact towards
Knowledge
Management-as-a-Service
Big data and big data analytics can be seen as the first
step in our journey of more meaningful analytics,
from quantitative to substantial qualitative analysis.
Gradually it is necessary to combine quantitative as
well as qualitative analytical methods within the big
data approach to enable more and more actionable
insight-driven decisions. This will be one mail pillar
to support. The identification of the right data and
definition of right aggregation of data plays a
fundamental role when thinking about a meaningful
integrated experience for information leading to
knowledge. To gain this competitive advantage we
have to make sure that the workflow that distils low-
value data, transforming them into high-value data
reaches the level of knowledge to support the
business adequately. The ability to generate
knowledge from a large amount of data with different
structures is part of what can determine big data
management. It is a common understanding, that big
data as a technology is a key enabler to success. Even
though we have already seen the clear distinction
between data, information and knowledge there is a
strong relationship since the potential for data and
information to turn into knowledge (Rothberg and
Erickson, 2014). Once we look beyond big data and
its enabling technology, Brynjolfsson and McAfee
(2012) suggest that organizations have to consider on
knowledge management, as the era of big data means
not just more data.
It seems that big data has its main effect on
explicit knowledge since the generation of any
analysis is inherent in big data analytics but provides
the ability to have a broader set of raw data for these
analytics to increase the quality of explicit
knowledge. However, the effect of big data on tacit
knowledge shall not be underestimated: due to the
ability to analyses masses of data and simulate
scenarios the support on an individualized learning
experience can be significant.
5.2 Cloud Services Impact towards
Knowledge
Management-as-a-Service
Since we have already proposed an answer how to
provide a new knowledge experience with the benefit
of cloud services. However, the question cannot be
divorced from a thorough understanding of the access
of data and information. For explicit knowledge
private clouds has the most limited the access to any
Knowledge Management as a Service - When Big Data Meets Knowledge Management
319
knowledge as it ends at the companies’ boundaries.
This access to knowledge increases in other types of
clouds and has its maximum in public clouds. On the
contrary, for tacit knowledge, the type of cloud has
only little effects or it is more likely to assume, that
the private cloud has a positive influence towards
tacit knowledge since it relies more on the users itself,
their personal minds.
Therefore, access to tacit and explicit knowledge
is neither as limited as in private clouds, nor is it as
open as in public clouds, however, tacit knowledge is
more accessible in private clouds compared to the
explicit knowledge, because of the mentioned reason
stated for public clouds.
Table 1: Benefit for knowledge types in different cloud
deployment models.
Explicit Knowledge Tacit Knowledge
Private cloud Low High
Public cloud High Low
Hybrid cloud High – medium Medium – low
If we now add the context of usage, we will also
find highly differentiated benefits due to the cloud
deployment models. The organisational knowledge is
driven by mainly company internal driven knowledge
that is ti a certain degree focused on the tacit
knowledge type since e.g. career planning and
personnel data are certainly more focused on a
personnel view , learning behaviour and subjective.
Having this in mind the benefit of a private cloud is
somewhat higher compared to marketing and
technology drive knowledge aspects. Especially the
marketing knowledge dimension relies on the benefit
of a public accessible knowledge. While being mainly
explicit driven the benefit of a broad knowledge base
and network is very high – much higher compared to
the technological dimension. Even though technology
has a strong benefit from information and
communication a lot of knowledge lies within the
company and in personal experiences.
Table 2: Benefit for knowledge dimensions in different
cloud deployment models.
Organizational
Knowl.
Marketing
Knowl.
Technological
Knowl.
Private
cloud
High Low High-Medium
Public
cloud
Low High Medium
Hybrid
cloud
Low-Medium High – Medium Medium
6 CONCLUSION
Knowledge and knowledge management are largely
connected to the idea of an IT-based infrastructure.
For a successful knowledge management it is
therefore essential to handle many aspects through
and with technology: data gathering, data analytics
that ultimately leads to a better enablement of
decision-making.
While decision-making, reflects the need to
maximize cross-functional cooperation between
people who manage the data and the people who use
them we have to consider knowledge as a
fundamental object to improve competitive
advantage and decision-making. In the information
era, and more precisely in the era of digital
information, this smart asset becomes increasingly
necessary for business survival.
It is obvious that big data are much more than just
a hype as this allows us to collect and crawl almost
every data, which gives us more knowledge transfers
opportunities. On the other side cloud services have
the potential to transform the business and with the
promise of a rapid scalability, the adoption cloud
services will increase. Briefly, cloud services deliver
the dynamic and flexible infrastructure that is needed
for today’s business requirements that are mainly
driven by the factor of knowledge and the competitive
advantage that is generated out of it. Therefore,
knowledge management is in the focus of many
companies. With big data, we have now a technology
in place that is described by the 3 Vs and that provides
opportunities for data generation and data analytics
that mainly has a positive impact on explicit
knowledge. Considering the 4
th
V – the value of big
data it becomes obvious that it is important for
companies not to stick solely in the big data
technology nor in the big data analytics but invest
time upfront to carefully identify what is the
knowledge you would like to generate out of these
data and make this accessible to the desired audience.
Here the application of cloud services to knowledge
management allows benefiting from a flexible
infrastructure provided in different dimensions
depending on the cloud service model. The degree of
benefit often results from the type of cloud that is
used. Therefore, it is necessary to analyse the
knowledge types and dimensions prior to the alliance
of big data in a dedicated cloud environment.
The key to success lays in the definition of
knowledge management service. The idea is to define
services.
That allow an easy adoption of (new) knowledge.
Having the knowledge is unfortunately not enough.
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Therefore, the service concept will allow the
distribution of on-demand knowledge improving
knowledge sharing and business connectivity.
Knowledge Management-as-a-service (KMaaS)
is actually digital knowledge and experience
packages accessible at any time, any place and any
device. With the big data technology, it is of course
much easier to get the right data – even in real time
within a broad network of data sources that are
accessible using digital sources of knowledge,
independent of if the person that is providing the
knowledge is available or not.
Knowledge Management-as-a-service depends on
the type and dimension of knowledge. It is a context-
sensitive layer in addition to the already existing
service types. The emergence of KMaaS and the
delivery of knowledge on demand will enable new
knowledge generating and sharing models especially
within explicit knowledge and in the dimension of
marketing and technological knowledge.
Organizations can more or less immediately benefit
from reduced upfront costs and obtain increased reach
based on a scalable and dynamic platform with the
use of an agile big data technology.
These “knowledge-based-services” prioritize and
guide of what data are needed and how these data
need to be presented to be aggregated to information
and experienced as valuable knowledge. Establishing
knowledge services is therefore a continuous task. It
helps reducing information overload within times of
delivering big data at high volume, quality, and
accuracy in a timely fashion is not possible without a
streamlined approach towards managing the data to
become information.
With the idea to introduce big data and big data
analytics to the context of knowledge management.
With the provisioning of a comprehensive set of
already analysed data, enhanced these already
available meaningful and comparable data with
cloud-service-based knowledge management tools to
we are able to “turnonthelight”andletusaddress
thepainpoints:
Lower the complexity by having introduced big
data analytics for getting data and doing the
operational analytics
Greater insight through consistent, comparable
data, e.g.
Insight into customer buying behaviour can
drive key improvements in the sales channel,
as is already happening
Analysis quality issues within manufacturing
across the entire supply chain may improve the
entire production process
Closed loop transparency – being able to
measure the success and drive greater
efficiencies
Aligned with big data and with the cloud paradigm of
a service oriented architecture might shift the
knowledge management, but the impact big data has
will affect knowledge management significantly in
dedicated areas. With KMaaS based on big data
technology and analytics, knowledge management
will be shifted while providing a way to quickly
address target group focused. At the same time, much
of what we call knowledge today will be automated
like physical labour and transactional tasks have been
widely automated over the last three decades.
Knowledge management is the cross discipline that
will help to accomplish this task of an increased
competitiveness by providing knowledge to strategy
and clarity to content. Since KMaaS is context-
sensitive we will have the ability that contextual
connect the data sources versus just focusing on one
thing at a time. It is about the ability to connect
process, people and technology in a way that
analysing a business problem, defining a solution and
realizing success can happen seamlessly and in an
integrated fashion. Knowledge Management is
nothing overly complicated or esoteric. Companies
are complex, human beings are as well, and
sometimes even technology still is. As such
knowledge management as a discipline aiming at
connecting and integrating all of the above often
failed to deliver what was promised in the first place.
However, knowledge management is simply about
finding simple, but nevertheless reliable and
sustainable solutions for concrete business problems.
For the same reason, knowledge management is never
a goal in itself, if it is done right is always about
enabling and bettering concrete business decisions
Of course only people create competitive
advantages, not hard- or software alone. But in times
of big data and cloud services it is not only impossible
but not necessary to do it without carefully designed,
integrated Knowledge Management that link
corporate strategy to a structured yet people-focused
approach to knowledge. We believe that the success
of knowledge management depends on putting all the
parts together: the right data, bid data and adequate
analytics, and a flexible service-based platform to
enable and valuing knowledge a culture to create a
real “knowledge experience leading to a sustainable
competitive advantage.
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