Building energy management systems (BEMS) provide real-time remote monitoring and integrated control of a wide range of connected systems, allowing modes of operation, energy use, and environmental conditions to be monitored and modified based on hours of operation, occupancy, or other variables to optimise efficiency and comfort. Building energy management systems can also trigger alarms, in some cases predicting problems and informing maintenance programmes. They maintain records of historical performance to enable benchmarking of performance against other buildings or across time and may help automate report writing. BEMS are often integrated with building automation and control (BAC) systems, which have a broaded scope of operations.

Intelligent Urban Water Supply Management uses IoT gateways to securely connect the water supply asset (e.g. pressurizing pumps) to the cloud service platform where advanced analytics are applied to the operational data communicated from the assets. The operational insight obtained from the analytics are used to drive the water supply domain applications to monitor and provide advanced maintenance capability, monitor water quality, detect water leakages, reduce energy consumption of pressurizing pumps and ensure equitable water distributions to the points of consumption during water peak usage hours and water supply shortages.

Real Time Locating Systems (RTLS) provide knowledge by delivering precise visibility of critical assets, supply chain, manufacturing, and human, in real-time. For transportation and logistics enterprises, this knowledge means having end-to-end visibility and traceability of all containers, pallets, and packages. For manufacturers, it enables intelligent management and flow of all critical assets, whether in the facility or at a sprawling storage yard. Under security and safety operations, it means controlling employee access and ensuring they do not linger in hazardous areas beyond safety requirements.RTLS or indoor positioning systems (IPS) can be simply described as GPS on steroids but used indoors for the purpose of tracking, locating and monitoring the activity of people and things. It is used in healthcare, manufacturing, smart warehouses, hospitality, education, and other industries for the purpose of maximizing workflow efficiency, safety, wayfinding, and inventory and asset control and has been proven to deliver significant return on investment (ROI).

Smart city operations include the range of solutions required to enable smart city concepts by integrating information and communication technology with senors and connected devices to optimize the efficiency of city operations and services. Smart city technology allows city officials to interact with both community members and city infrastructure and to monitor situation in the city in real time. Benefits for city managers include tracking events in the city in real time, managing congestion, improving operational efficiency, reducing emergency response times, and enabling remote management. Modern solutions will aim to integrate all city data into a single dashboard. Both historical and current KPIs are measured to conduct performance reviews and gap analysis, and to plan future infrastucture and service investments.

Structural health monitoring solutions ensure the safety and soundness of engineering structures such as a buildings and bridges. Structural health monitoring uses an assortment of sensors to collect and analyze data pertaining to any damage or deterioration that a structure may receive over the course of its life. The data that structural health monitoring systems acquire can help its users avoid structural failures and changes to the material and/or geometric properties of a structural system, including changes to the boundary conditions and system connectivity, which adversely affect the system's performance. The structural health monitoring process involves the observation of a system over time using periodically sampled response measurements from an array of sensors (often inertial accelerometers), the extraction of damage-sensitive features from these measurements, and the statistical analysis of these features to determine the current state of system health. For long term solutions, the output of this process is periodically updated information regarding the ability of the structure to perform its intended function in light of the inevitable aging and degradation resulting from operational environments. After extreme events, such as earthquakes or blast loading, health monitoring is used for rapid condition screening and aims to provide, in near real time, reliable information regarding the integrity of the structure.

Track and trace systems provide real-time or periodic updates for the current and historical locations of containers, vehicles, or other property. Solutions can apply reckoning and reporting of the position of vehicles and containers that store the tracked property of concern. For example, if it is known the one thousand objects are stored in a container, it is more cost effective to track the container than each individual object. However, high value individual objects can also be monitored directly. Wireless tags can be attached to objects with fixed reference points receiving wireless signals from tags to determine their location, as when a pallet is loaded onto a truck. Alternatively, GPS or another technology can track the object using satellite or cellular networks. Examples of real-time locating systems include tracking products through an assembly line, locating pallets of merchandise in a warehouse, and tracking containers as they move across warehouses. The physical layer is usually some form of radio frequency communication, but some systems use optical or acoustic technology.