Smart Buildings and IFC and BIM and Smart Cities and Ontology/AI

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Smart Buildings, IFC and Ontology

Smart building is an initiative to improve energy efficiency, security, and convenience through the use of building automation technologies, including Internet of Things (IoT) devices, artificial intelligence, big data, cloud computing, and automation systems. By combining technologies such as IoT (Internet of Things) devices, artificial intelligence, big data, cloud computing, and automation systems, the goal is to streamline building management and operations, reduce costs, and improve comfort.

Specific examples of smart building include the following

  • Automation of air conditioning, lighting, power, etc.: IoT sensors are used to acquire environmental data from inside and outside the building and automatically adjust air conditioning, lighting, power, etc. to reduce energy waste.
  • Improved security: IoT sensors will be used to automatically control surveillance cameras, doors, windows, etc., and automatically issue alarms when suspicious activity is detected, thereby improving security.
  • Improved efficiency of management and operation: Using big data and artificial intelligence, building data can be analyzed to detect predictive signs of problems and automatically schedule maintenance and inspections.

An ontology is a systematized body of knowledge about a particular domain, and will define concepts, attributes, and relationships in that domain.

In a smart building, the objective is to analyze data obtained from sensors installed in the building to optimize the operation and management of the building. This requires various types of sensor data, and an ontology will be used to integrate this data. The ontology will define what type of data is obtained from sensors, what relationships exist, what information they represent, etc. This will allow data obtained from multiple sensors to be integrated and useful information to be extracted.

Ontologies will also be useful for sharing data among different systems and standardizing data in smart buildings. Different terms and concepts used in different systems make it difficult to share and integrate data, but an ontology allows them to be handled in a unified manner.

This section describes this smart pilding and ontology based on Chapter 2, “Ontology Analysis and Ontology Ring Standards: an Initial Study of the IFC,” in Ontology Modeling in Physical Asset Management.

This paper discusses building smart and Industry Foundation Classes (IFC). buildingSMART defines specifications for the systematic representation of all objects that make up a building (e.g., elements such as doors, windows, walls, etc.). The Industry Foundation Classes (IFC) are a collection of these specifications.While smart city is an application that deals with the entire city from the user’s point of view, smart building is an application that deals with the building side by sharing building data such as BIM and sharing building materials through building smart.

For example, a “door” as defined in IFC is not just a simple set of line segments representing a “door”, but has properties that make it recognizable as a “door”. For example, a door defined in IFC is not simply a set of line segments that represent a door, but rather has properties that allow it to be recognized as a door. In the case of various types of doors used in a project, one door may be 900mm wide, another may be 1200mm wide, and so on, both doors can be recognized and have the common properties of doors defined in the IFC specification. In this case, the “class” is the one that defines the common characteristics, and the one that corresponds to each entity is called an “object”.

This “object” on the IFC can be shared as a project model among various industries in the construction industry. A “door” designed by an architect can be treated as the same “door” by personnel in other industries, allowing for greater efficiency in estimating, facility design, construction, and facility management.

In addition, IFC-compliant applications allow the sharing of electronic information data (such as drawings, reports, and specifications).

For these IFCs, this document discusses the IFC ontology after describing the upper ontology DOLCE, which is often used with BFO. The table of contents is shown below.

2.1 Introduction
       
2.2 Ontology and Ontology Analysis
    
2.2.1 The DOLCE Foundation Ontology
     
2.3 Industry Foundation Class
      
2.4 Ontology IFC
    
2.4.1 State of the Art
     
2.4.2 From EXPRESS to OWL
           
2.5 Types and Occurrences in IFC:An Ontological Analysis 
   
2.6 Properties in IFC Ontologies
   
2.7 Conclusion and Further Discussion References
building smart

<Overviews>

buildingSMART is an international non-profit organization that promotes information sharing and data exchange in the building and construction industry. Its objectives are to increase efficiency throughout the building process, ensure consistency of information, and improve interoperability between different systems.

buildingSMART is engaged in standardization activities to establish a common language and data standards across the industry, the core deliverable of which is the Industry Foundation Classes (IFC), an open file format for representing building and facility information in a comprehensive and interoperable format. The core deliverable is an open file format (data model) for representing building and facility information in a comprehensive and interoperable format called Industry Foundation Classes (IFC).

buildingSMART activities are applied across all phases of a building project, and specifically aim to facilitate data sharing and collaboration across the entire building lifecycle, including design, construction, operation, and maintenance.

The main activities of buildingSMART will include the following

  • Promoting standardization: buildingSMART is developing and promoting common data standards in the building industry. This will improve data compatibility among different software and tools and facilitate information sharing.
  • Dissemination of best practices: buildingSMART is also working to develop and disseminate best practices and guidelines in the building industry. In this way, we disseminate efficient project implementation and data management practices.
  • Providing education and training: buildingSMART offers education and training programs for building professionals and stakeholders. This helps to improve digitization and information sharing skills in the building industry.
  • Innovation and Research: buildingSMART also promotes innovation and research in the building industry. It aims to promote the development of the industry by developing new technologies and methods, supporting demonstration projects, and working to improve data quality.

<buildingSMART and AI Technologies>

AI technology is a powerful tool for achieving buildingSMART’s goals, utilizing techniques such as machine learning, deep learning, and natural language processing to extract patterns and acquire knowledge from large amounts of data.

The use of AI technology in the building industry will materialize in the following ways

  • Design assistance: AI will be used to assist the design process, such as analyzing design patterns and suggesting optimal solutions and efficient plans for building design.
  • Energy efficiency optimization: AI can be used to optimize building energy usage, such as analyzing sensor and weather data, predicting energy consumption patterns, and implementing appropriate control actions.
  • Building Construction Efficiency: AI can contribute to the efficiency of the construction process by monitoring the progress of work on a building site, providing real-time information, and can also be used to optimize the placement of building materials and schedule resources.
  • Maintenance and facility management: AI will be used to improve the efficiency of building maintenance and facility management by analyzing sensor data and maintenance history to help optimize maintenance planning and preventive maintenance activities, and will also be used for early detection of problems and diagnosis of faults.
Industry Foundation Classes (IFC)

<Overview>

Industry Foundation Classes (IFC) is an open file format for information sharing and data exchange in the building and construction industry. Specifically, IFC is defined as a data model for comprehensively representing information across the entire building lifecycle, including design, construction, operation, and maintenance.

IFC will also define elements (walls, floors, windows, etc.) and attributes (sizes, materials, colors, etc.) of buildings and other infrastructure, expressing the relationships and hierarchical structure of these elements, and covering various aspects of buildings, such as their location, structure, equipment, and energy efficiency.

In addition, IFC is also used as a central element of Building Information Modeling (BIM), which creates a digital model of a building or project on which the design and construction process is managed. model information is exported in a standardized format and used to exchange data with other software and systems.

The advantages of IFC include the following

  • Open standard: IFC is an open format and has been widely adopted as an industry standard. This improves data compatibility among different software and tools and facilitates information sharing and collaboration.
  • Comprehensive information representation: IFC can comprehensively represent a wide range of aspects of a building or facility, allowing for integrated management of information for the entire building project. This makes it easier for each party involved to access necessary information and make decisions.
  • Improved project efficiency: IFC improves data consistency and accuracy, reducing inconsistencies and missing information between models. This will increase project efficiency, reduce costs, and allow for schedule adherence.

<IFC and AI Technology>

IFC and AI technologies play complementary roles in the building and construction industry. Examples of these are as follows

  • AI analysis and prediction of IFC data: While IFC serves as a data model for comprehensive representation of building and facility information, the data can be analyzed using AI technology to provide a variety of insights and predictions. This could be, for example, a use case where AI and IFC are used to predict energy consumption patterns of a building and propose measures to improve energy efficiency.
  • Design Support and Optimization with AI: AI can also be used to support the design process by learning architectural design patterns and automatically generating new or improved designs, or by analyzing data contained in IFC to suggest optimal solutions or efficient plans for building design. The data contained in IFC can be analyzed and used to propose optimal solutions and efficient plans for architectural design.
  • AI can be used to streamline the construction process: AI can also be used in the construction field. AI can be used to monitor the progress and quality control of construction work by analyzing sensor data and video data, and AI can be used to streamline the construction process, such as optimizing the placement of building materials and scheduling resources.
  • AI for Maintenance and Facility Management: AI is also being used in the area of building maintenance and facility management. For example, it can analyze sensor data and maintenance history to help optimize maintenance planning and preventive maintenance activities, as well as detect abnormalities and troubles at an early stage.
BIM(Building Information Modeling)

<Overview>

BIM is a framework for digital technologies and processes in the building and construction industry, characterized by the representation of information about buildings and facilities as three-dimensional models and the integration and management of information related to those models.

The purpose of BIM is to increase efficiency and promote information sharing throughout the building project. BIM allows for consistency of information during the design, construction, and operation phases, and smooth communication and cooperation among different stakeholders.

Some of the key features and benefits of BIM are listed below.

  • 3D modeling: BIM begins with the creation of a 3D model of a building or facility. This allows designers and stakeholders to visually understand the exterior and interior structure of a building and to conduct detailed design studies and clash detection.
  • Information Integration: BIM integrates and manages information related to the 3D model. For example, it can correlate and manage information such as building material specifications, construction procedures, cost data, and maintenance plans, thereby ensuring consistency and accuracy of information throughout the project.
  • Collaboration: BIM facilitates cooperation and communication between different parties and departments. Each party can access the BIM model, share information, and track changes, making it easier to make decisions quickly and keep up with design changes.
  • Simulation and Analysis: BIM provides tools to simulate and analyze the behavior and performance of buildings and facilities. These can perform a variety of analyses, including energy efficiency evaluation, collision detection, and construction simulation.
  • Life Cycle Management: BIM helps manage buildings and facilities throughout their life cycle. This allows for centralized management of information from the design and construction phases through operations, maintenance, and renovation to achieve building sustainability and efficient facility management.

BIM is expected to bring efficiency, quality improvement, cost reduction, and other benefits to the building and construction industry, and various software platforms are supporting BIM and increasing its popularity throughout the industry.

<BIM and AI Technology>

BIM and AI technologies are expected to play complementary roles in the building and construction industry as follows

  • Data Analysis and Prediction: BIM integrates a great deal of information about buildings and facilities, and AI technology can be used to analyze BIM data to predict building energy efficiency, optimize construction schedules, improve design quality, and much more.
  • Design assistance and optimization: AI technology can provide architectural design assistance and optimization based on the analysis of BIM data; AI can learn architectural design patterns and automatically generate new or improved designs; AI can also take into account building design constraints and regulatory requirements while recommending optimal AI can also propose optimal solutions, taking into account architectural design constraints and regulatory requirements.
  • Improved efficiency of the construction process: AI technology can also be used to improve the efficiency of the construction process. For example, AI can assist in monitoring construction site progress and quality control through vision sensing and sensor data analysis, and can also help optimize the construction process, including optimal placement of building materials and resource scheduling.
  • Maintenance and Facilities Management: AI technology is also being used in the area of building maintenance and facilities management. It analyzes sensor data and maintenance history to help optimize maintenance planning and preventive maintenance activities. AI can also help detect abnormalities and troubles at an early stage.

In these ways, the combination of BIM and AI technologies will help the building and construction industry derive additional benefits in terms of efficiency, quality improvement, and sustainability.

Smart Cities

<Overview>.

A smart city is a concept that uses information technology to improve the sustainability, efficiency, and comfort of a city. Smart cities use information and communication technology (ICT) and sensor technology to integrate and manage various areas of a city, such as infrastructure, transportation, energy, environment, and administration, with the aim of improving the quality of life of its citizens.

Some of the characteristic elements and initiatives of a smart city include the following

  • Smart infrastructure: In a smart city, a city’s infrastructure (roads, bridges, water and sewage systems, power grids, etc.) are linked by sensors and networks for real-time monitoring and control. This will enable efficient energy use, optimized traffic flow, and early warning in case of disasters.
  • Data utilization: In a smart city, data collected by various sensors and devices will be analyzed and used for decision-making and efficiency. This includes analyzing traffic data to guide routes to avoid congestion and to coordinate public transportation services.
  • Energy efficiency and environmental protection: Smart cities emphasize energy efficiency and the use of renewable energy. Building energy management systems, automatic control of lighting, and integration of renewable energy sources will be implemented to achieve a sustainable urban environment.
  • Digitization of administrative services: In smart cities, administrative services are being digitized. E-government, online services, and digital and mobile technologies will be used to communicate with citizens and streamline administrative procedures.
  • Citizen participation and community building: Smart cities emphasize citizen participation and community building. This will provide a mechanism for citizens to share information, submit opinions, and participate in the management of the city.

There are many challenges to realize smart cities, including the development of ICT, data security and privacy protection, and the development of policies and regulations. However, efforts to realize smart cities are underway around the world and have the potential to contribute to the sustainability of cities and the quality of life of their citizens.

<Smart Cities and Ontologies>

Smart cities and ontologies are different concepts, but can play important roles in data management and information sharing.

An ontology is a formalized body of knowledge for expressing the meaning and relationships of information, which helps improve data integration, interoperability, and semantic interpretation. In smart cities, ontologies are used to integrate and utilize large amounts of data collected from various sensors and devices, and are used to support data integration and interpretation by clarifying the meaning and relationships of the data.

Specific roles and benefits of ontologies in smart cities include

  • Data integration and interoperability: Smart cities need to integrate data collected from different data sources. Ontologies serve to convert different data formats and data models into a unified format and enhance data interoperability.
  • Semantic Interpretation and Knowledge Sharing: In smart cities, an accurate understanding of the meaning and relationships of data is critical. Ontologies support data interpretation and knowledge sharing by clearly defining the meaning and relationships of data elements. This facilitates common understanding among different stakeholders and systems.
  • Improve data quality and reliability: Ontologies provide criteria for assessing data consistency and quality. When data is ontology compliant, data quality and reliability are improved, enabling accurate decision making and effective service delivery.
  • Data Retrieval and Analysis: Ontologies support data retrieval and analysis. Specifically, ontology-based queries and inference mechanisms can be used to efficiently extract specific information and discover relationships and patterns among data.

In smart cities, ontologies may be used to integrate and effectively utilize data from various data sources and sensors. The use of ontologies is expected to have the effect of clarifying the meaning and relationships among data and improving the efficiency of data management and information sharing in a smart city.

<Smart Cities and AI>

Smart cities and AI technology are closely related, and AI technology plays an important role in the realization of smart cities. The relationship between smart cities and AI technology is described below.

  • Data analysis and prediction: Smart cities use large amounts of data collected from various sensors and devices; AI technology can analyze these data and extract patterns and trends, and data analysis by AI can predict traffic flow, optimize energy consumption, predict disaster risk AI data analysis can contribute to improving the efficiency and sustainability of smart cities, such as predicting traffic flow, optimizing energy consumption, and predicting disaster risk.
  • Automatic control and optimization: Smart cities use AI technology for automatic control and optimization. This includes things like AI in transportation systems to control signals and optimize traffic flow to reduce congestion and improve traffic efficiency, and AI in energy systems to help optimize power supply and improve energy efficiency.
  • Predictive Maintenance and Maintenance: AI technology is also being used for predictive maintenance and maintenance of facilities and infrastructure in smart cities. Sensor data analysis and machine learning can be used to predict equipment failures and optimize maintenance schedules to improve maintenance efficiency and system reliability.
  • System self-learning and optimization: AI technology can also be applied to self-learning and optimization of smart city systems and services: AI can learn from data and use past experience to improve and optimize systems, such as a garbage collection system where AI can predict the amount of garbage and demand and optimize the collection schedule. This can be achieved.
  • Citizen service and engagement: AI technology can also help smart cities improve citizen service and engagement. This could include AI chatbots and virtual assistants to support citizen interactions and provide information and respond to inquiries.

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