TY - JOUR
T1 - Event-triggered mechanism for multiple frequency services of electric vehicles in smart grids
AU - Pham, Thanh Ngoc
AU - Maung Than Oo, Amanullah
AU - Trinh, Hieu
PY - 2022/3
Y1 - 2022/3
N2 - This paper considers an event-triggered mechanism (ETM) for multiple
frequency services of electric vehicles (EVs) in smart grids (SGs). A
new model of a SG with an ETM and multiple agents of EVs is introduced.
ETM is deployed to reduce the load on network bandwidth. EVs are
incorporated in both secondary and primary frequency services to
suppress frequency fluctuations in the system. The behaviours of EV
owners are also considered by using batteries SOC controls. Then, a
mathematical model of the system is derived which contains parametric
uncertainties due to the incorporation of SOC control, an ETM variable
arising from ETM control, and a time-varying delay in both the state and
control input vectors. We derive new Lyapunov stability and
stabilizability conditions to ensure robust
H∞
performance of the closed-loop system. The conditions are derived based
on various mathematical tools including relaxed Jensen inequality, free
weighting matrix technique, reciprocally convex approach, and matrix
inequality for uncertainties. An effective procedure is proposed based
on an approach using the state transformation and tractable linear
matrix inequalities to synthesis robust static output feedback
controller gains. Extensive simulations of a SG with three agents of EVs
are undertaken to validate of our proposed control scheme.
AB - This paper considers an event-triggered mechanism (ETM) for multiple
frequency services of electric vehicles (EVs) in smart grids (SGs). A
new model of a SG with an ETM and multiple agents of EVs is introduced.
ETM is deployed to reduce the load on network bandwidth. EVs are
incorporated in both secondary and primary frequency services to
suppress frequency fluctuations in the system. The behaviours of EV
owners are also considered by using batteries SOC controls. Then, a
mathematical model of the system is derived which contains parametric
uncertainties due to the incorporation of SOC control, an ETM variable
arising from ETM control, and a time-varying delay in both the state and
control input vectors. We derive new Lyapunov stability and
stabilizability conditions to ensure robust
H∞
performance of the closed-loop system. The conditions are derived based
on various mathematical tools including relaxed Jensen inequality, free
weighting matrix technique, reciprocally convex approach, and matrix
inequality for uncertainties. An effective procedure is proposed based
on an approach using the state transformation and tractable linear
matrix inequalities to synthesis robust static output feedback
controller gains. Extensive simulations of a SG with three agents of EVs
are undertaken to validate of our proposed control scheme.
UR - http://www.scopus.com/inward/record.url?scp=85112669044&partnerID=8YFLogxK
U2 - 10.1109/TPWRS.2021.3101281
DO - 10.1109/TPWRS.2021.3101281
M3 - Article
AN - SCOPUS:85112669044
SN - 0885-8950
VL - 37
SP - 967
EP - 981
JO - IEEE Transactions on Power Systems
JF - IEEE Transactions on Power Systems
IS - 2
ER -