On the range of feasible power trajectories for a population of thermostatically controlled loads
D Paccagnan, M Kamgarpour… - 2015 54th IEEE …, 2015 - ieeexplore.ieee.org
2015 54th IEEE conference on decision and control (CDC), 2015•ieeexplore.ieee.org
We study the potential of a population of thermostatically controlled loads to track desired
power signals with provable guarantees. Based on connecting the temperature state of an
individual device with its internal energy, we derive necessary conditions that a given power
signal needs to satisfy in order for the aggregation of devices to track it using non-disruptive
probabilistic switching control. Our derivation takes into account hybrid individual dynamics,
an accurate continuous-time Markov chain model for the population dynamics and bounds …
power signals with provable guarantees. Based on connecting the temperature state of an
individual device with its internal energy, we derive necessary conditions that a given power
signal needs to satisfy in order for the aggregation of devices to track it using non-disruptive
probabilistic switching control. Our derivation takes into account hybrid individual dynamics,
an accurate continuous-time Markov chain model for the population dynamics and bounds …
We study the potential of a population of thermostatically controlled loads to track desired power signals with provable guarantees. Based on connecting the temperature state of an individual device with its internal energy, we derive necessary conditions that a given power signal needs to satisfy in order for the aggregation of devices to track it using non-disruptive probabilistic switching control. Our derivation takes into account hybrid individual dynamics, an accurate continuous-time Markov chain model for the population dynamics and bounds on switching rates of individual devices. We illustrate the approach with case studies.
ieeexplore.ieee.org
Showing the best result for this search. See all results