Abstract
This study compares differential model to delay differential model in terms of their qualitative behaviour with respect to equilibrium price changes using roots of characteristic equation techniques. The equilibrium states of both price adjustment models were simulated using inputs from same source. The study found that irrespective of initial prices set for the system, the current price of the differential model would always move monotonically towards the equilibrium price defined for the system. However, the current price of the delay- differential model will fluctuate and move away from the initial prices due to the delay parameter associated with the supply, then gradually decrease and turn towards the defined system equilibrium price.
 
 Results from the study also showed that current prices in the delay-differential model are not predictable at the initial stage due to the time delay parameter in the supply function of price. On the other hand, current prices in their counterpart models without delay are predictable, as they always converge to the equilibrium price points defined in the system. Since most economic and physical systems are time delay inherent, it is recommended that such systems are modeled using delay-differential equations to reflect realities of the phenomena.
Highlights
The behaviour of oscillation of delay differential equations and the associated differential equations without delay are not always the same in terms of their solutions (Grace and Lalli, 1985)
This paper presents the dynamics of stability conditions of both differential and delay-differential equations applied as price adjustment functions
This paper studies the dynamics of stability states of price adjustment differential equations with and without delay parameter using characteristic equation techniques
Summary
The behaviour of oscillation of delay differential equations and the associated differential equations without delay are not always the same in terms of their solutions (Grace and Lalli, 1985). Due to the understanding that most processes involve after effect phenomena in their inner dynamics, interest related to the theory of delay differential equations has been increasing. These models are supposed to be applied in a wide variety of physical, chemical, engineering, economic, weapons fire-control from moving platforms and biological systems (Bodnar and Piotrowska, 2010; Adomian and Rach, 1983; Ligang et al, 2015)
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