Age of information (AoI) is a key performance metric for the Internet of things (IoT). Timely status updates are essential for many IoT applications; however, they often suffer from harsh energy constraints and the unreliability of underlying information sources. To overcome these unpredictabilities, one can employ multiple sources that track the same process of interest, but with different energy costs and reliabilities. We consider an energy-harvesting (EH) monitoring node equipped with a finite-size battery and collecting status updates from multiple heterogeneous information sources. We investigate the policies that minimize the average AoI, formulating a Markov decision process (MDP) to choose the optimal actions of either updating fro...
A large body of applications that involve monitoring, decision making, and forecasting require timel...
In this work, we study age-optimal scheduling with stability constraints in a multiple access channe...
In this paper, we consider an information update system where a wireless sensor sends timely updates...
Age of information (AoI) is a key performance metric for the Internet of things (IoT). Timely status...
Data collected and transmitted by Internet of things (IoT) devices are typically used for control an...
Information freshness is crucial for time-critical IoT applications, e.g., monitoring and control. W...
Abstract Delivering timely status information of a random process has become increasingly important...
We examine the age of information (AoI) in a status update system that incorporates energy harvestin...
We consider an energy harvesting source equipped with a finite battery, which needs to send timely s...
The Age of Information (AoI) measures the freshness of information and is a critic performance metri...
Abstract We consider a resource-constrained IoT network, where multiple users make on-demand request...
We consider managing the freshness of status updates sent from a source (such as a sensor) to a moni...
Abstract Information freshness is crucial for time-critical IoT applications, e.g., monitoring and ...
Abstract We consider a resource-constrained IoT network, where users make on-demand requests to a ca...
In this article, we provide an accessible introduction to the emerging idea of Age of Information (A...
A large body of applications that involve monitoring, decision making, and forecasting require timel...
In this work, we study age-optimal scheduling with stability constraints in a multiple access channe...
In this paper, we consider an information update system where a wireless sensor sends timely updates...
Age of information (AoI) is a key performance metric for the Internet of things (IoT). Timely status...
Data collected and transmitted by Internet of things (IoT) devices are typically used for control an...
Information freshness is crucial for time-critical IoT applications, e.g., monitoring and control. W...
Abstract Delivering timely status information of a random process has become increasingly important...
We examine the age of information (AoI) in a status update system that incorporates energy harvestin...
We consider an energy harvesting source equipped with a finite battery, which needs to send timely s...
The Age of Information (AoI) measures the freshness of information and is a critic performance metri...
Abstract We consider a resource-constrained IoT network, where multiple users make on-demand request...
We consider managing the freshness of status updates sent from a source (such as a sensor) to a moni...
Abstract Information freshness is crucial for time-critical IoT applications, e.g., monitoring and ...
Abstract We consider a resource-constrained IoT network, where users make on-demand requests to a ca...
In this article, we provide an accessible introduction to the emerging idea of Age of Information (A...
A large body of applications that involve monitoring, decision making, and forecasting require timel...
In this work, we study age-optimal scheduling with stability constraints in a multiple access channe...
In this paper, we consider an information update system where a wireless sensor sends timely updates...