Английская Википедия:Digital object memory
Шаблон:Cleanup bare URLs A digital object memory (DOMe) is a digital storage space intended to keep permanently all related information about a concrete physical object instance that is collected during the lifespan of this object[1] and thus forms a basic building block for the Internet of Things (IoT)[2] by connecting digital information with physical objects.[3]
Such memories require each object instance to be uniquely identified and this ID to be attached to the physical object. The underlying techniques to create identification codes and to attach them to objects are manifold but machine-readable techniques are mandatory. Commonly used are barcodes with one or two dimensions (e.g. QRcode or DataMatrix) and radio based tags like RFID or NFC. Such codes or tags are a low cost solution but demand an underlying server infrastructure to host the memory data.
Active digital object memories
In contrast to the mentioned memories providing only a passive storage space, the more sophisticated active digital object memories (ADOMe) are based on embedded systems in terms of cyber-physical systems (CPS) and provide on the hardware side
- a microprocessor,
- memory,
- microsensor systems,
- positioning chips,
- radio modules for web connectivity,
- possibly actuators,
- its own energy supply or energy-harvesting unit
and on the software side there are
- memory management functions,
- sensor interpretation components,
- and possibly sensor fusion software modules,
- state transformation and processing logic components,
- communication interfaces,
- user interfaces,
- and security modules.
Such active memories allow for "on-object" processing of object-related tasks, such as condition monitoring, compilation of associated data, and memory clean-up. In addition to strictly passive memories (storage space is located in the web as mentioned above) and active memories (with "on-object" storage) hybrid forms are also available, that perform simple tasks "on-product", outsource more complex tasks to server-based infrastructures, and keep both representations in sync.
Digital product memory
Digital product memories (DPM) are a subclass of digital object memories, which include memories for all artifacts that were intentionally created such as containers and pieces of art or valuable and rare natural objects such as a marble plate or a lump of gold. Such objects don't have all the attributes of industrial products, but nevertheless a digital black box attached to them for lifelogging can make sense for specific applications.[4]
Semantic product memory
Semantic product memories (SemProM) go beyond that, since they provide a machine-understandable meaning description of their contents based on semantic web technologies. If a product memory has no explicit semantic markup, only propriety software can exploit the information stored in the memory. In contrast, semantic product memories can be interpreted by any software that has access to the semantic description of the epistemological primitives and the ontologies used for capturing memory contents.
Object memory model
In the context of the Object Memory Modeling Incubator Group,[5] part of the W3C Incubator Activity, an object memory format, which allows for modeling of events or other information about individual physical artifacts (ideally over their lifetime) and thus implements an object memory model (OMM), was created. The model consists of a block-based approach to partition the entire memory to groups each with associated object-related information. Each block consists of the data itself (the so-called payload) and a set of metadata attributes to describe the block content.
Related research projects
SemProM
Funded by the German Ministry of Education and Research, the project SemProM (Semantic Product Memory[6]) employs smart labels in order to give products a digital memory and thus support intelligent applications along the product's lifecycle. By the use of integrated sensors, relations in the production process become transparent and supply chains as well as environmental influences retraceable. The producer gets supported and the consumer better informed about the product.
RES-COM
Funded by the German Ministry of Education and Research, the project RES-COM (Resource Conservation by Context-Activated Machine-to-Machine Communication[7]) focuses on the development of technologies (containing interfaces, protocols and data models) for proactive resource conservation based on M2M-communication. With a defined interaction with active digital object memories the project tries to leverage the integration of distributed and active components to existing centralized structures in the field of industry and manufacturing.
Aletheia
The Aletheia project[8] is a leading innovation project, sponsored by the German Ministry of Education and Research that aims at obtaining comprehensive access to product information through the use of semantic technologies. The project follows an approach which does not only consult structured data from company-owned information sources, such as product databases, to respond to inquiries, it also looks at unstructured data from office documents and web 2.0 sources, such as wikis, blogs, and internet forums, as well as sensor and RFID data.
ADiWa
The ADiWa project (Alliance Digital Product Flow[9]), funded by the German Ministry of Education and Research, makes the huge potential of information from the Internet of Things accessible for business-relevant workflows that can be strategically planned and manipulated. For the data-level connection of objects from the real world, results from available solutions and from the SemProM project shall be used. ADiWa focuses on business processes, which can be controlled and manipulated based on evaluated information from the real world.
SmartProducts
The SmartProducts project,[10] funded by the European Union in the 7th Research Framework Programme (FP7), develops the scientific and technological basis for building "smart products" with embedded proactive knowledge. Smart products help customers, designers and workers to deal with the ever-increasing complexity and variety of modern products. Such smart products leverage proactive knowledge to communicate and co-operate with humans, other products and the environment. The project thereby also focuses on small devices with limited storage capabilities and thus also requires efficient storage mechanisms. Moreover, the project aims to apply the results achieved by the incubator group for optimizing the data exchange between different smart products.
ToTEM
Tales of Things and electronic Memory (TOTeM[11]) is a three-year collaborative project between five universities in the United Kingdom. A project aim is to explore the implications of Internet of Things technologies for the design of novel forms of augmented memory systems. While the potential implications of the Internet of Things for supply chain management and energy consumption have been acknowledged and discussed, its application for the engagement with personal and social memories has been rarely mentioned. More and more newly manufactured objects are often tagged at production and made traceable. Tales of Things provides a design space for exploring the value of a user-generated Internet of Old Things in which people's memories are linked to objects.
SmaProN
The project Smart Product Networks (SmaProN[12]), funded by the German Ministry of Education and Research, explores the dynamic linking of smart products to product bundles and product hierarchies, based on the developed Tip'n'Tell architecture (to integrate distributed product information) and the product description model SPDO (using semantic web-based representation languages).
RAN
The project RFID-Based Automotive Network (RAN[13]), founded by the German Ministry of Education and Research, focuses on the development of a RFID-based hybrid control architecture and valuation methods for value added chains. Using the example of automobile industry they develop a combined data management that exchanges product-related information in a decentralized way using RFID-tags. In addition order-related information are stored in centralized manufacturer databases. Such an architecture allows for transport of product-related data at the location of the physical object and process related data in real-time via backend systems.
References