Diffusion Of Innovations

THEORIES OF INNOVATION DIFFUSION

French Sociologist Gabriel Tarde originally claimed that sociology was based on small Psychological Interaction s among individuals, especially Imitation and Innovation .

A first ''theory of innovation diffusion'' was formalized by Everett Rogers in a 1962 book called ''Diffusion of Innovations''. Rogers stated that Adopters of any new innovation or idea could be categorized as innovators (2.5%), Early Adopter s (13.5%), early majority (34%), late majority (34%) and laggards (16%), based on a Bell Curve . Each adopter's willingness and ability to adopt an innovation would depend on their awareness, interest, evaluation, trial, and adoption. Some of the characteristics of each category of adopter include:

innovators - venturesome, educated, multiple info sources, greater propensity to take risk

early adopters - social leaders, popular, educated

early majority - deliberate, many informal social contacts

late majority - skeptical, traditional, lower socio-economic status

laggards - neighbours and friends are main info sources, fear of debt

Rogers also proposed a five stage model for the diffusion of innovation:

# ''Knowledge'' - learning about the existence and function of the innovation
# ''Persuasion'' - becoming convinced of the value of the innovation
# ''Decision'' - committing to the adoption of the innovation
# ''Implementation'' - putting it to use
# ''Confirmation'' - the ultimate acceptance (or rejection) of the innovation

THE S-CURVE AND TECHNOLOGY ADOPTION

Rogers theorized that innovations would spread through society in an S Curve , as the early adopters select the technology first, followed by the majority, until a technology or innovation is common.

The speed of technology adoption is determined by two characteristics ''p'', which is the speed at which adoption takes off, and ''q'', the speed at which later growth occurs. A cheaper technology might have a higher ''p'', for example, taking off more quickly, while a technology that has Network Effects (like a fax machine, where the value of the item increases as others get it) may have a higher ''q''.

Caveats and criticisms

Critics of this model have suggested that it is an overly simplified representation of a complex reality.

A number of other phenomena can influence innovation adoption rates, such as -

#Customers often adapt technology to their own needs, so the innovation may actually change in nature from the early adopters to the majority of users.
# Disruptive Technologies may radically change the diffusion patterns for established technology by starting a different competing S-curve.
#Lastly, Path Dependence may lock certain technologies in place, as in the QWERTY keyboard.

SEE ALSO

Bass Diffusion Model

Crossing The Chasm

Cultural Evolution

Development Communication

Disruptive Technology

Dual Inheritance Theory

Early Adopter

Logistic Function

Meme

Path Dependence

Percolation

Technology Acceptance Model

Technology Lifecycle

TRIZ

Two-step Flow Of Communication

REFERENCES

EXTERNAL LINKS

Historical look at the Technology Adoption Lifecycle

The Diffusion Simulation Game , about adopting an innovation in education

The Pencil Metaphor on diffusion of innovation particularly ICT in education

Modeling Market Adoption in Excel with a simplified s-curve

	CATEGORIES ABOUT DIFFUSION OF INNOVATIONS

	innovation

	diffusion

	marketing

	product management

	anthropology

	memetics

	books about public opinion

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Diffusion Of Innovations