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White Paper on Innovation Processes
Janet Rabin & Ben Turner
1. OverviewThe study of innovation is on the rise: all fields, from the public sector to big
business, from engineering to international development, are seeking to capture
innovation and weave it into their planning and operations. Innovation research was
originally confined to the sciences, but then progressed to spheres of the private
sector, especially in efficiency and product design. Recently it has also expanded to
the social sciences and the public sector; more and more organizations are seeking to
implement systems and processes into their management structure which will
consistently produce innovative solutions to problems in their field.
In order to come to a precise definition of innovation, we must distinguish between
the concepts of an innovation and the innovation process. It might help to explain
this distinction within the context of a cycle: invention, innovation, and diffusion.
Invention is the development of a new product or idea. Innovation is the successful
conversion of that product or idea into a process that adapts itself to multiple
contexts reliably and consistently. Diffusion is the commoditization of innovation as it
spreads and becomes a standard, accepted idea.
Our goal in this white paper is to examine and explain the processes that promote
this cycle and lead to the adoption of innovations -- that is, to identify reproducible,
transferable techniques that can be implemented across a variety of projects and
practices. First we will give a brief literature review covering fundamental works on
innovation from the sciences, the private sector, and international development. We
will then consider the commonalities and common principles that arise from these
different perspectives. Finally we will draw together theory and practice and forecast
future trends for increasing innovation and its diffusion within a development
consulting organization.
1.A. Academic Theories of Innovation1.A.i. SCHUMPETER'S CREATIVE DESTRUCTION
Joseph Schumpeter, father of "creative destruction" and oft-referenced scholar of
entrepreneurship, defines economic innovation in The Theory of Economic
Development:
1. The introduction of a new good — that is, one with which consumers are not
yet familiar — or of a new quality of a good.
2. The introduction of a new method of production, which need by no means be
founded upon a scientifically new discovery, and can also exist in a new way
of handling a commodity commercially.
3. The opening of a new market, that is a market into which the particular
branch of manufacture of the country in question has not previously entered,
whether or not this market has existed before.
4. The conquest of a new source of supply of raw materials or half-
manufactured goods, again irrespective of whether this source already exists
or whether it has first to be created.
5. The carrying out of the new organization of any industry, like the creation of
a monopoly position (for example through trustification) or the breaking up
of a monopoly position.1
Not a mathematician by practice, Schumpeter was an economist who used
behaviors to theorize about business and economies. This was in contrast to his
peers, who tended to rely on mathematical models. In particular, Schumpeter
envisioned a series of business cycles and circular flow in most firms, recycling the
same ideas and products within an enclosed circle. Only through entrepreneurship
were external inputs and outputs introduced into this cycle or flow. From
entrepreneurs, Schumpeter believed, came economic development.
One of Schumpeter's key insights was promoting "creative destruction," the
process of new ideas breaking down old ideas and replacing them continuously,
ensuring an innovative, generative path of development. He wrote at length about
capitalism and socialism, saying that capitalism eventually gives way to corporatism,
as entrenched old interests set an agenda to protect against entrepreneurs, whose
ideas are inherently targeted to destroy the entrenched interests. Schumpeter
sought to ensure that the ability to destructively create would continue to exist so
1 Wikipedia.org. "Innovation", Wikipedia.org. http://en.wikipedia.org/wiki/Innovation
that healthy capitalism and innovation could continue. This can be extended to a firm
level, where established ways of doing things dominate and those who execute those
ways well get promoted, making them biased against new or different upcoming
ideas. Thus, Schumpeter believed this continual process of replacing and upgrading
was normal, necessary, and, contrary to popular belief, far more stabilizing for the
internal health of a government or firm.
1.A.ii. TRIZ
TRIZ is named for its Russian acronym, Teoriya Resheniya Izobreatatelskikh
Zadatch, which roughly translates to “Theory of Inventive Problem Solving.” TRIZ
was created by Genrich Altshuller, (1926 – 1998), who used the Soviet Union’s open
patent database to compare over 200,000 inventions in his quest to find common
factors that lead to innovation. He was later sent to a prison camp in Siberia for
criticizing Stalin; however Altshuller used this time to interview the many scientists,
intellectuals, and artists who were also imprisoned there, and so continued his work
on the process of innovation.
TRIZ has multiple layers of analysis and can become
very technical; many of the examples used are drawn
from engineering. However the basic principle is one
that can be applied across numerous fields. TRIZ
defines an inventive problem as an unresolved contradiction. An innovation
transcends the limits that create the contradiction. A very simple illustration would
be a travel coffee mug: it solves the problem of needing coffee to be hot enough to
enjoy when drinking, but cool enough to hold in your hands. The insulated mug allows
the coffee to be simultaneously hot (inside) and cool (outside).
The TRIZ method maintains that if an analogous problem that has already been
solved can be identified, then an analogous solution can be applied. Altshuller created
various tools to facilitate the process of finding and overcoming contradictions. The
first is his 40 Principles of Invention, which are the principles Altshuller determined
to be the most frequently-employed in the creation the successful innovations he
studied. For example, the Principle of Segmentation calls for dividing an object or a
concept into multiple parts. This could be implemented by replacing a too-large truck
with a truck and trailer, or using a work breakdown structure to manage a
particularly unwieldy project. Ellen Domb, editor of the TRIZ Journal, provides this
and other examples for each of the 40 Principles in an article available on the
publication's website: http://www.triz-journal.com/archives/1997/07/b/index.html
Another tool is The Contradiction Matrix, which visually displays the most common
types of contradictions, matched up with the principles that are most suited to
resolving the contradiction. The rows of the matrix contain 39 characteristics a
would-be innovator wants to improve, such as strength, speed, or ease of repair; the
columns display the trade-offs that would normally have to be made to in order
achieve the improvement, such as loss of speed or decreased stability of an object. At
the intersection of the feature you want to improve and the feature you don't want to
worsen are numbers which represent which of the 40 Principles could be used to
achieve the improvement without the degradation. An Excel file of the entire matrix
can be downloaded free of charge from the TRIZ journal website: http://www.triz-
journal.com/archives/contradiction_matrix/
Altshuller’s work has been continued since his death, both in countries of the
former Soviet Union and more recently in the U.S. Some of his disciples have formed
branded versions of the TRIZ method, which they sell to companies. It has also been
incorporated into business innovation models, including Six Sigma. Some have
debated how far TRIZ principles can go in the social sciences; recent research in the
TRIZ journal has explored the application of TRIZ in subjects as far-reaching as
Public Health, Finance, and Education. Case studies range from Singapore’s
management of the SARS outbreak to a new type of mascara with a vibrating wand-
applicator.
1.A.iii. CLUSTERING
Michael Porter, of the Harvard Business School, has written extensively on clusters
as incubators of innovation. Porter defines clusters as a series of related industries, a
set of horizontally-connected co-dependent firms and institutions. A cluster may
contain private firms, academic institutions, and standard-setting bodies. The most
vivid example is Silicon Valley, the home of venture capital for technology,
bioscience, nanotechnology, and product design. Stanford University, geared
towards engineering, has given birth to both Yahoo! and Google, both of which were
founded later in nearby cities in the San Francisco/Palo Alto areas. Web-based
companies and start-ups have also swarmed to the area, and now San Francisco and
Silicon Valley have a cultural support system for the eccentricities of these
businesspeople, the capital to fund new business, and the relationship with Stanford,
Berkeley, and other schools to attract the brightest new minds to their operations.
One driver for innovation in a cluster is the competition inherent in so many similar
firms operating close together. The physical proximity also facilitates rapid diffusion
of best practices and encourages experimentation and new business formation.
Porter describes clusters as an "open" model of innovation, contrasting it with the
more traditional model, where only one part of the structure -- the R&D department
for example -- focuses on innovating.
1.A.iv. EXPERIMENTATION
Stefan Thomke, a Harvard MBA professor and former McKinsey employee, lists six
ways to inspire innovation in his book Experimentation Matters:
1. Anticipate and Exploit Early Information Through ‘Front-Loaded’ Innovation
Processes.
2. Experiment Frequently but Do Not Overload Your Organization.
3. Integrate New and Traditional Technologies to Unlock Performance.
4. Organize for Rapid Experimentation.
5. Fail Early and Often but Avoid ‘Mistakes’.
6. Manage Projects as Experiments.
Thomke emphasizes experimentation, implying a loose organization that allows for
failures and risk, especially early on. Innovative processes should change throughout
the development stages in order to adapt to information access, scalability, and
feedback from results.
1.B. Private Sector Approaches
1.B.i. TPS AND LEAN
The Toyota Production System was developed between the 1940's and the 1960's in
order to increase efficiency along the factory line through three reduction areas:
overburden (muri), inconsistency (mura) and eliminate waste (muda). Reducing
"muda" began to dominate the system because of the ease of understanding that
concept; a trip to the States by a Toyota delegation contrasted the massive inventory
held at Ford's production plants with the inventory held at a Piggly Wiggly
supermarket, and then returned home to apply principles we have come to associate
with Just-In-Time production. While reducing inventory and creating more of a
demand-based system where components were delivered only after known orders
were received, the TPS also required "autonomation," a way to reduce human
interference in production by requiring humans only if a machine reports a deficiency
on the line. As a result of this process of reducing inefficiencies, defects, and
stresses, as well as in ensuring continuity of production, Toyota has become famous
for its reliability and quality.
Lean manufacturing is focused on process flow and is heavily based on the TPS,
emphasizing that any component of a product that does not contribute to increased
value must be removed. This has implications not only in production but also within
design, for many problems that occur later on in a product cycle come through poor
planning and system engineering. In order to reduce later waste, it is therefore
important to nurture institutional capacity so that an organization's leaders and
employees share the Lean philosophy and are capable of understanding different
aspects of the product cycle; if they are cross-trained, they can anticipate errors later
on in the process. It is also important under Lean to challenge partners and suppliers
to share the same philosophy of reducing waste, and to involve all levels of the
organization in institutional learning processes.
While TPS and Lean seek to reduce waste, they also seek to accomplish this
through less specialization in institutional capacity, not more. Womack and Jones, the
authors of Lean Thinking contend that the Fordian model has been overused, and that
firms need to think beyond their role in the "value stream," to consider the entire
product and process the consumer wants to experience. When they describe people
as wanting "personal mobility," rather than cars, they almost sound as if they could
be discussing capabilities à la Amartya Sen, rather than consumables.
1.B.ii. SIX SIGMA
A business management philosophy developed by Motorola in 1986, its main task is
to remove defects in a process to an incredibly low level for the sake of reliability.
Its two methodologies (DMAIC and DMADV) emphasize quantitative measurement of
problems before seeking to improve them; DMAIC stands for Define, Measure,
Analyze, Improve, Control. DMADV stands for Define, Measure, Analyze, Design,
Verify.
DMAIC tends to be used for streamlining existing business processes, whereas
DMADV is used for creating completely new products or processes that require major
new design evaluation.
DMAIC, therefore, would be more significant to look at in the development
consultancy and project management context. Created by Edwards Deming to reduce
defects in processes, the process involves first identifying and defining a problem for
a development project and for the consultant's practice. Once that problem is
defined, it must be measured within its environment and then later analyzed to see
the full extent of the problem. At that point, with recommendations made to fix the
problem, the process can be improved to the desirable level, and then needs to be
maintained or controlled from that point forward.
Within the arena of controlling the process to maintain success, Six Sigma
endorses incentive and reward structures so that those who help to facilitate solving
the problem are recognized while others are not. By linking rewards to performance,
a company can ensure that its desired practices are advanced. Six Sigma also
endorses promoting local project champions to provide role models to other projects.
The implication of Six Sigma is that it introduces quality management into all levels
of an organization, so that all employees start to follow Six Sigma processes.
Negative complaints towards Six Sigma say that it stifles innovation (because of a
rigid, data-driven approach) instead of encouraging fresh, no-boundaries thinking.
Perhaps a more balanced view would emphasize Six Sigma's recommendation of
collaborative sharing as a sixth letter, "S", after DMAIC, the underlying concept of
which is described in depth below as a way to promote knowledge management for
Chemonics International projects and internal processes.
The "S" symbolizes synergy, emphasized because this sharing creates a learning
organization, said to be key in any innovative firm. It was determined in a recent
study that:
"Looking at data from 759 firms across 17 countries the researchers found that
location is not the determining factor in the degree to which any given firm is innovative;
but rather, the innovative firms themselves share key internal cultural traits. Innovation
appears to be a function of the degree to which a company fosters a supportive internal
structure headed by product champions and bolstered by incentives and the extent to
which that organization is able to change quickly, keeping an eye on the markets of the
future." (ScienceDaily, 2008)
1.B.iii. CONSTRUCTION CULTURE, INNOVATION, AND MANAGEMENT
(CCIM)
Much of the available literature on this topic comes out of three institutions: The
British University in Dubai, the Centre for Innovative and Collaborative Engineering
(CICE) at Loughborough University, and the International Council for Research and
Innovation in Building and Construction (CIB). In 2006 the three organized an
international conference in which research was presented on the topic of
“Sustainable Development through Culture and Innovation.” Recommendations for
increasing innovation within the construction field included nurturing relationships
with cutting-edge clients (Manley, 2005) and identifying how to best communicate
within a firm’s particular sub-culture (Harkink and Tijhuis, 2005).
One study, based on case studies of innovation in the Australian construction
industry, demonstrated that firms benefited not only from innovation within, but
also from "adoptive" or "incremental" innovation -i.e. adapting and using others'
innovations (Manley, Blase and McFallan, 2005). The study also found that
developing organizational skills within a firm was most important when supporting
incremental innovation, whereas developing technical skills was a key factor in
"radical" or original innovation.
Slaughter describes these two types of innovation, as well as three others
(modular, architectural and system innovation), in "Models of Construction
Innovation" (1998). Slaughter seeks to transpose models of innovation from the
manufacturing industry, where they originated, to the construction industry.
Slaughter places incremental innovation on the low end of the change spectrum
(small change), radical innovation on the high end (major change), and situates
modular, architectural, and system innovations in between.
A modular innovation is an improvement of one part or component of a system. It
may be a major change, but it does not directly affect neighboring components or the
way they are linked together. An architectural innovation may be small in scale, but
changes the way in which the parts of a whole interact. System innovation not only
affects more than one part of a given system, but requires that "multiple independent
innovations ...work together to perform new functions or improve the facility
performance as a whole" (Slaughter, 228). System innovation requires coordination
between each changed component for the innovation as a whole to work. Slaughter
gives industry-specific examples of each kind of innovation and calls attention to
where conditions specific to construction require adjusting the models.
The definitions of incremental and radical innovation Slaughter employs are based
on a 1969 article by Donald G. Marquis. Marquis argues that adaptive innovation,
sometimes called mere imitation, is vital to the growth of an industry, and should not
be downplayed. Likewise everyday "nuts and bolts" innovation -- small changes a firm
makes within its operations to maintain its competitiveness -- is championed as just as
important as radical technological breakthroughs. Marquis advises firms to focus
rather on how to use an innovation, whatever its source. His model of the process of
innovation includes six steps:
1. Recognition - identifying a new technical advance or a potential demand for
something new.
2. Idea Formulation - combining a recognized demand and a recognized
advance into a design or method.
3. Problem Solving - testing the design or method.
4. Solution - through invention or adoption.
5. Development - innovation is scaled up and introduced to the marketplace.
According to Marquis, this is when innovation is truly achieved.
6. Utilization and Diffusion
Marquis drew his recommendations from observing how existent successful
innovations were created and disseminated. He concludes that the training and
experience of a firm's staff are key: it is, after all, those who are working in the field
every day who are most likely to notice instances of and opportunities for innovation.
1.C. Innovation in International Development
1.C.i. "MACGYVER" INNOVATION
Ethan Zuckerman, a fellow at the Harvard Law School Berkman Center for Internet
and Society, a former Fulbright Scholar in Ghana as well as an Africa blogger, lists
seven developing world innovation rules:
Innovation (often) comes from constraint (If you’ve got very few resources,
you’re forced to be very creative in using and reusing them.)
Don’t fight culture (If people cook by stirring their stews, they’re not going to
use a solar oven, no matter what you do to market it. Make them a better
stove instead.)
Embrace market mechanisms (Giving stuff away rarely works as well as
selling it).
Innovate on existing platforms (We’ve got bicycles and mobile phones in
Africa, plus lots of metal to weld. Innovate using that stuff, rather than
bringing in completely new tech.)
Problems are not always obvious from afar (You really have to live for a while
in a society where no one has currency larger than a $1 bill to understand the
importance of money via mobile phones.)
What you have matters more than what you lack (If you’ve got a bicycle,
consider what you can build based on that, rather than worrying about not
having a car, a truck, a metal shop.)
Infrastructure can beget infrastructure (By building mobile phone
infrastructure, we may be building power infrastructure for Africa - see my
writings on incremental infrastructure.) (Zuckerman, 2008)
Zuckerman values less blue-sky thinking and more working with the resources
available. This is reminiscent of elements from Lean thinking, revising processes and
unlocking value constrained in existing models instead of creating entirely new
processes. Zuckerman's rules imply an innovative pressure that builds up within
projects; what's most important is to understand the project well and then be able to
recognize those pressures as they develop, then exploit them.
1.C.ii. "PROMOTING INNOVATION, PRODUCTIVITY, AND INDUSTRIAL
GROWTH AND REDUCING POVERTY”
"Promoting Innovation, Productivity and Industrial Growth and Reducing Poverty"
is a set of papers developed from presentations at an international workshop held at
the Open University in London’s Innovation, Knowledge, and Development Research
Centre in 2005. The papers and case studies emphasize the importance of promoting
and managing innovation in international development projects. Several authors
contend that innovation is needed not solely in the technical arena, but also in social
policy. A dramatic example is the case of pharmaceuticals in India: remarkable
innovation has been achieved in producing new drugs for worldwide export; however
over 50% of Indians do not have access to these drugs themselves (Chaudhuri, 2005).
An interesting case study of an innovative approach to poverty alleviation is the use
of value-chain lending in Mozambique. Value Chain Analysis is also attributed to
Michael Porter. His 1980s books Competitive Strategy and Competitive Advantage
describe how to analyze the discrete activities of a firm so as to identify where and
how much value is created.
This idea has been expanded to go beyond the boundaries of one single firm, to
include the entire supply chain of a product, or the whole process of a service, and is
used extensively in the Lean approach. It was also recently employed to reinvigorate
the cashew nut industry in Mozambique. GAPI, a Mozambican non-bank financial
institution, began the project by partnering with Technoserve to finance and improve
cashew nut processing plants. It quickly became apparent that the cashew nut
farmers needed to be supported as well to ensure a steady supply of input material.
GAPI and Technoserve then went on to work with firms in marketing and
international distribution to expand the market for the final product. By considering
the entire supply chain of the cashew industry, GAPI was able to correct coordination
failures that could have undermined the original venture.
1.C.iii. AGRICULTURAL INNOVATION SYSTEMS (AIS)
The AIS approach came out of a World Bank report released in 2006 called
"Enhancing Agricultural Innovation", and then was formalized during a presentation
at a World Bank conference in 2007 in Washington, DC.
Through consensus, the AIS findings agreed that research and development were
not the primary drivers of innovation, but only part of a larger system involving
stimulating innovation capacity. Said the report:
"Besides nurturing individuals who act as change agents within organizations, the
case studies highlight the power of: collective action within and among organizations;
flexibility (to allow self-organization); building self-confidence and trust; fostering
preparedness for change; stimulating creativity; and the enabling environment,
particularly the policy and funding incentives that permit these characteristics to
develop." (“Agricultural Innovation Systems”, World Bank, p. xxi)
AIS presents a large-scale, multi-lateral perspective of innovation management. In
particular, it sees the enabling environment as being free of as many barriers to
innovation as possible. For the World Bank, which now characterizes itself as a
learning organization, it is necessary to devote significant energy towards knowledge
management since it generates so much research and so many reports.
But it also recognizes that within a large organization, processes quickly become
circular, accepting no external inputs, rewarding those who reinforce the cycle
instead of breaking out of it, to use Schumpeter's metaphor. Therefore the World
Bank, through the AIS process, has emphasized enabling and championing "change
agents" and spurring individual initiative and rewarding flexibility. The World Bank
hopes to flash a green light within its organization and for agricultural projects on the
ground to seek solutions without worrying about boundaries.
The World Bank continues:
"The primary emphasis of extension should shift away from technology transfer and
toward creating connections to outlets, institutions, and people. Extension needs to
perform a wider range of services and provide a wider range of support to a diverse
clientele to improve their capacity to access, adapt, and use knowledge, inputs, and
services. Extension agents should see their main role as being intermediaries and
knowledge brokers. [...] Because the AIS approach is essentially multisectoral, it is
essential to promote the cooperation of different ministries, departments, and units and
cooperation among various stakeholders. A system to facilitate collaboration and
synergies among the agencies, ministries, and stakeholders is needed." (“Agricultural
innovation systems”, World Bank, p. xiv)
Thus the World Bank understands that innovation requires fresh ideas outside the
normal circle of information dissemination. The more departments and minds from
more diverse backgrounds, the better. This displays the innovation characteristic of
the "wisdom of crowds", later explained in reference to Jim Surowiecki's book of the
same name.
Key goals include:
Developing local capacities to innovate, experiment, access market
opportunities, and manage resources in a more sustainable manner.
Integrating Farmer Participatory Research and Participatory Market
Research approaches to build the agricultural assets of rural women and the
poor.
Integrating equity and gender considerations to improve the distribution of
benefits.
Applying the Resources-to-Consumption System: Forward and Backward
linkages between production, marketing and investment in NRM.
The description of this process emphasizes the importance in increasing the
number of links within organizations and their partner networks substantially
throughout all levels in order to allow for more collaboration and communication. It
also makes the organization more resilient to employee and project turnover, as
channels for communication will still continue even after personal friendship links are
cut off as people rotate out of the organization.
The World Bank describes a process approach to innovation as "capacity building":
"To enhance innovation capacity, it is necessary to invest in learning and capacity
building, provide incentives that allow actors to put new skills into use, and also nurture
new attitudes and practices. Programs that encourage greater openness in organizations
to collaborating with diverse formal and informal actors, introduce organizational and
managerial innovations within organizations, or strengthen individual and organizational
incentives to develop innovative capacity, should be considered. The organizational or
collective innovative capabilities, however, reside in individuals, in the information and
technology used by an organization, and in an organization’s structure, routines, and
coordination methods. Besides nurturing individuals who act as change agents within
organizations, the case studies highlight the power of: collective action within and
among organizations; flexibility (to allow self-organization); building self-confidence and
trust; fostering preparedness for change; stimulating creativity; and the enabling
environment, particularly the policy and funding incentives that permit these
characteristics to develop. Policy capacity thus needs to be strengthened to build
innovation capacity." (“Agricultural innovation systems”, World Bank, p. xii)
The World Bank's report emphasizes that there must be increased innovative
capacity within an organization, primarily gained through increasing incentives and
lowering barriers for communication across departments and divisions. What is
implied but not explicitly said is that networking tools could be implemented in order
to increase information flow whether it involves departments or different agricultural
projects on the ground sharing information quickly about what techniques will work
best or what is happening in the news. The report emphasizes funding an
infrastructure for clustering scientists and accommodating outside sources,
endorsing an amorphous cloud of knowledge to operate naturally and organically.
2. Synthesis2.A. Common Principles Among Different Innovation Processes
Within the context of applying innovation to organizations, we also identified some
common qualities of innovation processes:
Systematically test the parameters of a given situation and figure out which
constraints might be lifted through quantitative measurement and evaluation.
Reduce waste, inefficiency, and defects.
Link together different organizations so that they share knowledge more
creatively and willingly. (Zuckerman's rule: don't fight culture)
Tight relationship between governmental and educational research
organizations and businesses (DARPA & the Internet, Stanford and Yahoo
and Google).
Evaluate the value chain: look for abundances and low transaction costs that
can translate into large increases in productivity.
Split something big into smaller pieces (e.g. micro-enterprise development,
just-in-time supply chains).
Combine small insufficient parts to create a larger whole (e.g. micro-credit
and mobile-phone banking).
Use an abundant technology to improve a scarce or inaccessible one (mobile
phones building infrastructure (Zuckerman) or mobile-phone banking).
Encourage clustering and networks for innovation (Silicon Valley).
Organizational learning through documentation, diversity ("wisdom of
crowds" implying diversity, not homogeneity), and consensus-based decision-
making.
Tolerance for high-risk, high-reward research and experimentation.
Capable, cross-trained leadership able to adapt quickly to different
approaches and train their employees to do the same.
Different types of environments are required for different stages of
innovation: a) creative, free environment for generating new ideas; b)
methodical application of techniques to reduce waste and become more
efficient and effective.
2.B. Overarching Themes
After comparing the various innovation processes and looking at the substance
within the above commonalities, we found strong recurring traits.
2.B.i. Inside and Outside the Circle
The main trait behind innovation processes refers back to Schumpeter's model of
entrepreneurs being destructively creative inputs into an otherwise closed business
system; we can characterize certain innovation processes as being either inside or
outside of the "circle." Six Sigma DMAIC, CCIM, value chain analysis, and TPS/Lean
are examples of incremental improvements to an already-existing process. These
refine a process to be more productive by reducing defects and creating more
marketable products. But they are not innovative in the entrepreneurial sense.
Schumpeter lauded the entrepreneur for breaking the closed circle within firms to
introduce newer, more efficient and productive techniques for processes.
Processes such as TRIZ, Six Sigma DMADV, and Porter's clustering models are
specifically intended to introduce radical, new ideas and methods to within the
circle. They seek to break the assumptions of previous models and propose new ways
of developing a product. Thomke's emphasis on experimenting introduces the idea
that not all attempts at innovation will be successful, but allowing for failure and
freedom to experiment may yield unexpectedly beneficial results, and not necessarily
at a high cost. This is not unlike the intent behind Six Sigma's DMADV approach of
iterative improvement and testing.
2.B.ii. Productivity
Professor Porter talks at length about productivity, which he sees as the major
factor behind innovation.
"For Porter, the only meaningful concept of competitiveness at the national level is
the national productivity with which a nation's resources are employed. Sustained
productivity growth requires that an economy continually upgrade itself. A nation's firms
must relentlessly improve productivity in existing industries by raising product quality,
adding desirable features (differentiated products), improving product technology,
boosting production efficiency or improving the quality of factors of production through
technological progress. Firms musty also develop a capability to compete in even more
sophisticated and new industry segments, where productivity is generally higher. This
also absorbs human resources freed up in the process of improving productivity in
existing fields, say, with the introduction of automation." (Mahmood, 1998)
The same principle of "creative destruction" is prominent in Porter's thinking;
relentless improvement and using capital and labor more efficiently constitutes
innovation both inside and outside the circle: value chain enhancement and Six
Sigma DMAIC methods for within, and Six Sigma DMADV and TRIZ and clustering for
without. In these cases, seeking added value and increasing productivity are the core
goals of any innovative, competitive process.
2.B.iii. Knowledge Availability
A strong current running through the innovation processes, in particular with Six
Sigma as a whole and with the World Bank's AIS, is the idea that organizations need
to be flattened so that even the lowest worker on the organizational totem pole has as
easy access to the firm's knowledge as the executives at the top. Six Sigma explicitly
commands its senior "belts" to share their knowledge with others within their
organization, while the AIS method emphasizes that different stakeholders from
different backgrounds must be able to collaborate from different perspectives in
order to produce the ideal opinion.
We will argue that creating an innovation information commons within a company
promotes a culture of innovation. This culture can be introduced through advocacy,
incentive and reward systems (recommended in Six Sigma), and measurement and
evaluation (as in the AIMS assessments). Giving employees and stakeholders
knowledge management tools will allow them to organize and innovate in the way
that works best for them.
2.C. Gaps Identified for Further Research
While there is some crossover of innovation models, more systematic comparison is
needed. A review of the literature shows that there is much literature specific to an
industry: innovation in construction, innovation in technology, product innovation
etc., but not much unifying theory.
It is possible that organizations do not take advantage of the internal organic
networks created by employees. Company-wide standards for processes may conflict
with how employees actually obtain and disseminate information. Supporting
research to document this contradiction would help further the idea that adaptability
and analysis of actual work flow within an organization are highly desirable for
innovation, as there would be less internal conflict for the organization.
There is also more formal research to be done within the American start-up
culture, mainly clustered in Silicon Valley, San Francisco, and Boston. Heavily
borrowing from Michael Porter's theoretical work and intense creative destruction of
employees, ideas, and money within the web community, there are principles and
lessons learned emerging from this sector that must be constantly studied, with a
grain of salt, since it is evolving so quickly.
3. Conclusions: Freedom to Adapt a
Good Idea is Innovation
From our literature review and case studies we have seen that there are different
methods of innovation, with each method having its own particular stages. When
considered on a firm-wide scale, most organizations are employing multiple
innovation strategies, with different projects using different approaches at different
stages in their individual project cycles. How then could Chemonics capitalize on the
innovation processes its projects are already using? Increased use of knowledge-
sharing tools could increase in turn the rate and scale of the diffusion of good ideas.
Chemonics teams indicated that they arrived at most innovative solutions by adapting
ideas or techniques that had succeeded in the past experience of a team member or a
consultant. Going back to the literature on innovation processes, Marquis emphasizes
the key role played by employees' training and experience. He presents a study in
which he finds that most of his respondents cited co-workers and colleagues as their
main source of new ideas, rather than technical literature. Therefore, if what works at
the level of a project team – sharing of previously successful strategies, employment
of outside technical experts with transferrable experience –could be incorporated into
a knowledge-base that was accessible to all projects throughout the company, the
level of innovation could be expected to increase. The level of efficiency should
increase by learning from others’ relevant experiences, and the adoption of new ideas
should occur more quickly.
3.A. Using Knowledge-Sharing Tools as Accelerators and
Conductors of Innovation
3.A.i. News Feeds
Implementing knowledge-sharing tools into daily IT operations has the potential
for long-term positive effects at a low price, if properly integrated into peoples' daily
routines. A good example of how this might be done would be to look at Facebook's
front page that displays a feed of all the news of the user's friends and organizations.
Google offers iGoogle, and Yahoo! has My Yahoo!, both of which are customizable
web pages that include "panes" for e-mail, weather, and any other gadget the user
wants. Having a front page like this creates an opportunity for innovation in terms of
knowledge-sharing within the company. Passively viewing updates about other parts
of the company requires a negligible time investment, but it might spur more
awareness of what is going on throughout the organization and could lead to
surprisingly useful linkages between vastly different projects. One team interviewed
noted that the current shared databases at Chemonics are useful for learning about
what worked in previous projects; however there is no consistent way to for transfer
knowledge between projects that are going on simultaneously. A news feed or
lifestreaming application would allow employees to be kept abreast of current
innovations within the organization.
There are limits on the benefits of increased ability to communicate. But certainly
any organization that facilitates discussion between the highest levels, lowest levels,
and different departments will benefit from a flattened hierarchy and better
information dissemination. The best example of this has been Facebook's news feed.
At first the news feed was highly disputed because peoples' actions were now being
broadcast to all their friends' news feeds passively. The information was public
before, in that one could actively click on his friend's profile to read what he was up
to, but now it was being put on other peoples' news feeds as they logged in. They
didn't have to go looking for an update on their friend's page, it was delivered right to
them.
In a business context, the social content of a Facebook news feed-like system could
be replaced with relevant professional items of interest. For example, someone
working on an innovation and competitiveness project in Ghana might receive an
update on a similar project in Bolivia. Sarah in Ghana might log on to her SharePoint
homepage and see on her newsfeed, "Charles published a report on innovation in
Bolivia, keywords: Bolivia, innovation, agriculture, value chains". While the Ghana
project has no "interest" in Bolivia, this random update within the organization might
catch the Ghana project's interest because they are related projects. So a news feed
can be used to expand one's awareness of intra-organization projects. Tools could be
employed to allow for passive news feeds (randomized news updates) to active
updates (subscribing to keywords through RSS feeds so that any update involving the
keyword "innovation" would show up in your RSS feed).
3.A.ii. Lifestreaming
Lifestreaming, one of the rising trends in the web start-up community, is only
beginning to be extended to enterprise-level business tools. Booz Allen Hamilton, a
government contractor in the Washington, DC area, has added a social media team to
advocate for the usage of social media within corporate organizations. This runs
counter to the prevailing philosophy of firewalling intranets so that virtually only e-
mail can be used. The latest winner of the TechCrunch 50, an annual event which
invites 50 start-ups to pitch their ideas to a panel of seasoned entrepreneurs, was
Yammer, a Twitter-like (Twitter is a service that lets you send short messages or
"tweets" to anyone who chooses to "follow" your feed) network that segregates users
by e-mail address, so that, for example, anyone within the chemonics.com domain
would be able to communicate with each other after taking only a minute to sign up.
LinkedIn, the most common social networking site for business and professional
users, has adopted a Facebook-like news feed for business-related status updates.
The concept of lifestreaming is implemented in the Facebook news feed, RSS
updates, and Twitter tweets. Instead of active communications dialogues between
two parties, such as what happens through e-mail, now you can "tune in" to an
individual's updates so you see what they are doing without being obligated to
respond to them in order to receive more information. When you e-mail someone, it
implies a burden of them replying back, which can be overwhelming if a party is too
swamped to respond. The information flow stops there. (Thompson, 2008)
Now you can subscribe or "follow" someone on something like Twitter, and they
"tweet" on what they are working on or thinking about. When you log in to Twitter,
you see a list of all the short updates (each tweet can only be 140 characters long)
from the people you are following. This allows you to passively follow what everyone
you're interested in is doing. If something does catch your interest, you can respond
to the author of the tweet for more information.
Within an organization, this extends the idea of flattening the operational levels. You
might be involved in an Africa project but are interested in good governance issues
that certain people within your organization are working on. You can follow those
people to see if what they're doing might apply to your project.
This lifestreaming commonality is extremely easy to implement using a free, open-
source framework called laconi.ca (http://laconi.ca/). But it would benefit from some
degree of automation too; if a user were to upload a white paper to a knowledge base,
for example, that should be updated under the person's account. If a user is giving a
talk and has slides, those should be automatically shared and disseminated. Not only
should people’s work be automatically updated for the rest of the company to see, but
the process should be made as easy to participate in as possible and integrated into
employees’ e-mail clients so they see it when they read their e-mail.
Since this might not be easy to implement under Microsoft Outlook, a "homepage"
might be set as default which has internal company news feeds. What's most
important is that lifestreaming is implemented directly into peoples' existing
computer patterns. No one is going to go out of their way to view what's going on,
but if they see it alongside something they always do (like e-mail), they will be far
more aware of it and participatory in it. (Miller, 2008) It is important to visualize
employees' time as already filled up to the maximum, so anything "new" must either
be vastly more efficient than the prior process, or it must be incorporated into
existing cultural norms within the organization in order for it to be adopted.
3.A.iii. Crowdsourcing
In his book "The Wisdom of Crowds," James Surowiecki talks about how many
different people often produce a best solution better than an individual or even a
group of experts can. He argues that it is the heterogeneity of people that brings this
about, bringing different experiences and areas of expertise together (but not
necessarily values) to build consensus, which contradicts other theories that usually
posit that many experts together produce the superior solution. Surowiecki breaks
down the successful decisions into three areas: cognition (faster and more reliable
than experts, similar to market-based solutions), coordination (commonalities of
purpose and values), and cooperation (networks of trust). He lists the successful
traits that lead to those areas as: diversity of opinion, independence,
decentralization, and aggregation. In essence, Surowiecki is describing the traits of
entrepreneurial, innovative knowledge communities.
A colorful example of the "wisdom of crowds", or crowdsourcing, is based on a
Canadian gold mining company, Goldcorp (Wikipedia, “Crowdsourcing”). The
company was not succeeding in finding new gold deposits, so it decided to release its
highly-proprietary data onto the internet to allow people to compete for a cash
reward in order to locate potential new sources of gold. The result was that
crowdsourcing produced highly successful mining projects because amateur
geologists, mineral experts, geographers, and other random professions contributed
actively towards finding gold, and it worked!
In the context of a firm, crowdsourcing can serve as another method of facilitating
innovation through knowledge-sharing. An example would be a problem-solving
bulletin board/e-forum to discuss specific problems that anyone in the company might
have had experience working with. Dell utilizes this technique through IdeaStorm,
which allows customers to vote up their biggest gripes or problems with Dell's
products and customer relations with a system similar to Digg, a web site that lets
people post stories, vote them up or down, and comment on them. The end result is
that the most burning issues and priorities float to the top, and people are
empowered to discuss them.
3.A.iv. Create New Ways to Collaborate
Wikis and Working Groups are two activities that can increase the horizontal
transfer of information in an organization and encourage sharing of technical
knowledge. A wiki (from the Hawaiian word for "fast") is a collaborative web page
that allows all members of the community to add to and edit. The best-known
example is Wikipedia, a vast collection of encyclopedic wiki articles; however the
more general concept is gaining in popularity as a way for organizations to share
knowledge among its members. A drawback to this knowledge-sharing approach is
the considerable initial time investment and requirement of a critical mass of users; if
not enough people use the wiki, then it never gets updated, corrected, or added to.
The advantages include increased participation and a sense of ownership among staff
contributors.
Working groups were recommended both within Chemonics interviews and by
Professor Michael Nelson, a professor at Georgetown University and former director
of internet strategy at IBM, as well as former science advisor for, at first, Senator Al
Gore, and then Vice President Gore. Working groups could take people from different
areas of the business and have them evaluate all the other areas of the business to
see how they operate and then report back on the differences and potential
commonalities between them all. Working groups are widely used in business and
can be proposed for any specific problem or for general evaluation, being disbanded
when no longer applicable. This technique was used at IBM, according to Professor
Nelson, and helped to establish working groups into the company as a consistent
practice of innovation, not as an added chore or responsibility. Working groups can
become a rotating presence within an organization, pulling out employees
periodically and giving them a set time to conduct company-wide research and
assessments. Innovation is often the result of bringing together two separate ideas
and finding how they might improve each other, so pulling together as many different
parts of the organization as possible would be conducive to an innovating
environment.
Perhaps the main idea behind the working group concept is that a process be
indoctrinated into the company for the sake of its employee base's collaborative
energies and sharing of information, instead of treating innovation as an afterthought
or an extra task. In other words, it is an active step towards promoting and
facilitating a learning organization that values and rewards innovation while not
interfering with regular work responsibilities. Encouraging an organizational
philosophy that values learning as part of one's job goes a long way toward making an
organization more competitive, adaptive, and versatile for innovation.
3.A.v. Expand the Use of Private Sector Productivity and Marketing
Techniques
International development programs that use business and economic models - i.e.
financial services and private sector development projects - already make use of many
of the innovation processes discussed here as part of their technical work. They help
clients to examine the value chain, eliminate waste, improve productivity, and
increase competitiveness. Perhaps the expertise and experiences of the staff in these
practices could be better leveraged to help Chemonics as a whole.
How could more people within Chemonics - those who are working in an apparently
unrelated practice such as Agriculture or Health - learn about the private sector
techniques used by their colleagues? With the rise of social marketing and public-
private partnerships, tools like advertising and production incentives are no longer
consider anathema to the arena of public works. Transferring and adapting these
methods to different fields may prove to be the new frontier in development work.
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