Agent-Based Faults Monitoring in Automatic Teller Machines

Automated Teller Machine (ATM) has gained widespread acceptance as a convenient medium to facilitate financialtransaction without need for human agent. However, ATM deployers are facing challenges in maximizing the uptime of theirATMs as a result of wide gap in fault detection, notification and correction of the ATMs. One way to ameliorate thissituation is through intelligent monitoring of ATM by resident software agents that monitor the device real time and reportfaulty components real time to facilitate quick response. We proposed an architecture for rule-based, intelligent agent basedmonitoring and management of ATMs. Agents are used to perform remote monitoring on the ATMs and control functionsuch software maintenance. Such agents can detect basic events or correlate existing events that are stored in a database todetect faults. A system administrator can securely modify the monitoring policies and control functions of agents. Theframework presented here includes software fault monitor, hardware fault monitor and transaction monitor. A set of utilitysupport agents: caller agent and log agent are used to alert network operator and log error and transaction information in adatabase respectively. at-1, stuck-at-0 faults in digital circuits validate the point that faulty circuits dissipates more andhence draw more power.Key words: Automated Teller Machine (ATM), Intelligent Agents, Mobile Agents, Event Monitoring

Structural, mechanical, electronic and optical properties of N-decorated single-walled silicon carbide nanotube photocatalyst for hydrogen evolution via water splitting: a DFT study

ABSTRACTThis work investigates the fundamental photocatalytic properties of nitrogen-doped single-walled silicon carbide nanotubes (N-doped SWSiCNTs) for hydrogen evolution for the first time. Investigations of the structural, mechanical, electronic, and optical properties of the studied systems were carried out using popular density functional theory implemented in quantum ESPRESSO and Yambo codes. Analysis of the structural properties revealed high mechanical stability with the 3.6% and 7.4% N-doped SWSiCNT. The calculated band gap of the N-doped SWSiCNT with 3.6% demonstrated a value of 2.56 eV which is within the photocatalytic range of 2.3 eV−2.8 eV. The hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) potentials of the 3.6% N-doped SWSiCNT also showed good agreement with previous theoretical data. The studied material showed the best photocatalytic performance in both parallel and perpendicular directions by absorbing photons in the visible region. Therefore, the observed structural, mechanical, electronic and optical behaviors demonstrated by the 3.6% N-doped SWSiCNT exposed it as a better photocatalyst for hydrogen production under visible light