Title :
Transient Bimodality and Catastrophic Jumps in Innovation Diffusion
Author :
Karmeshu ; Goswami, Debasree
Author_Institution :
Jawaharlal Nehru Univ., New Delhi
fDate :
5/1/2008 12:00:00 AM
Abstract :
A new phenomenon in innovation diffusion that exhibits a transient bimodality familiar in physical sciences is predicted in this paper for the first time on the basis of an extended Bass model. This accounts for the population heterogeneity, with the parameters characterizing the ldquoword of mouthrdquo and ldquomass mediardquo processes as random. A theoretical framework based on a nonlinear random differential equation is thus introduced to develop a stochastic model for new product diffusion with parametric uncertainty. The analytical investigation of the model establishes the existence of transient bimodality, which manifests through a cusp catastrophe. Illustrations based on analytical and simulation studies are presented. Empirical validation of the proposed model based on well-known data sets where the Bass model is known to fit very well has been carried out.
Keywords :
nonlinear differential equations; random processes; social sciences; stochastic processes; uncertain systems; catastrophic jumps; extended Bass model; innovation diffusion; mass media process; nonlinear random differential equation; parametric uncertainty; population heterogeneity; product diffusion; social group; stochastic model; transient bimodality; word-of-mouth process; Differential equations; Diffusion processes; Economic forecasting; Nonlinear equations; Predictive models; Probability distribution; Stochastic processes; Technological innovation; Transient analysis; Uncertainty; Bimodal probability distribution; catastrophic jump; empirical validation; innovation diffusion; population heterogeneity; transient bimodality;
Journal_Title :
Systems, Man and Cybernetics, Part A: Systems and Humans, IEEE Transactions on
DOI :
10.1109/TSMCA.2008.918621
