Phase 1, Sensors and improvement of the current planned predictive maintenance by providing an increasing amount of data from the field. This data can be used as an alarm-rate maintenance operation right after the sensor data is gathered. The data is stored in the database. The estimated time for implementation is 1,5 – 2 years. Components can be recognized and the information can be used for ownership management.
Phase 2, An analytics platform is chosen and implemented. The analytical platform can recognize decay rates from the data gathered from the sensor. The decay information can be used for maintenance operations and the operations can be moved towards a preventive maintenance model.
Phase 3, The analytics platform starts to receive labels from the ERP-systems for self-learning algorithms. The self-learning algorithms will receive fault, effect, component and simulated data labels from ERP-systems which leads to the platform performing better with each new data point. Maintenance can be moved towards a predictive maintenance model.
Phase 4, AR-solutions can be implemented to operations to provide guidance for the field operators. While providing guidance the guiding person can label components from the pictures and train machine vision solutions for recognition of these components. After a sufficient amount of component labels, machine vision can be used for guiding robotics and maintenance the operations can be further automated in steps. The ultimate goal is set to automate maintenance operations fully.
As we see, AI-solutions will bring benefits to operations also in short-term.
A summary of the benefits to different stakeholders
Construction and maintenance operators
Recognizing the need for maintenance before additional cost occurs - moving to a Predictive maintenance model. This increases route capacity and decreases costs of maintenance operations by decreasing down-time of the track. In addition, component recognition can be used to maintain uptodate information for ownership management.
By adding measurement solutions to provide data for a BIM engineering software and providing real-time uptodate information, the right baseline information can be provided for designing operations. These measurement solutions will also remove the need for manual measurement of structures and gathering the measurement data into database can be automated.
In addition, an AR-platform can be used to increase efficiency and quality in the installation operations by providing guidance remote guidance during installation operations. At the same time, operators can label videodata and labels can be used for the training of machine vision solutions.
For traffic and transportation operators
Moving into a Predictive maintenance model decreases requirement for maintenance operations on the route and improves route capacity. Facial recognition system provides smooth passenger transportation and provides baseline for TaaS-solutions.
Smart city, citizens of the city, Institutes and companies operating in the city
Camera systems attached to transportation machinery can measure and recognize components from surrounding structures in its route meaning anything from the surveillance of street-lights to the condition of buildings. Changes in these structures can be surveilled and data can be used for the allocation of maintenance resources. The same data can then be used for building a uptodate digital model of the city. All this data can be used as a platform for new inventions resulting in a better quality of life for the citizens.
Emphasis on data-acquisition on an early stage
Implementing AI-solutions to most of the ecosystem requires a lot of data to work with. The data needs to be raw, clear and labeled to provide sufficient information for self-learning algorithms that aim to provide information for operations and finally make automation possible for the application.
When a system requires huge amount of clean raw-data from several sensors, the makes cost of a single measurement to work as major cost-driver. This means heavy and expensive sensors wont do the trick, instead by using multiple cheap sensors in the ecosystem most of the benefits can be achieved.
In addition, the know-how of the field operators needs to be digitalised and stored as data. Machine learning means that the machine needs to learn what to do, and so far humans are acting as teachers. This means personnel working in the ecosystem needs to use digital tools on their operations in order to provide sufficient information for machines to eventually operate automatically.
We recommend all operators to start collecting data by implementing cheap sensors to their ecosystems and storing the raw-data to databases for the future’s needs. Ungathered information can never be recovered.
Don’t wait FOR your data to arrive -
let’s get it for you.