Electronic Product Code Information Services (EPCIS) is a global GS1 Standard for creating and sharing visibility event data, both within and across enterprises, to enable users to gain a shared view of physical or digital objects within a relevant business context. [1] "Objects" in the context of EPCIS typically refers to physical objects that are handled in physical steps of an overall business process involving one or more organizations. Examples of such physical objects include trade items (products), logistic units, returnable assets, fixed assets, physical documents, etc. “Objects” may also refer to digital objects which participate in comparable business process steps. Examples of such digital objects include digital trade items (music downloads, electronic books, etc.), digital documents (electronic coupons, etc.), and so forth.
The EPCIS standard was originally conceived as part of a broader effort to enhance collaboration between trading partners by sharing of detailed information about physical or digital objects. The name EPCIS reflects the origins of this effort in the development of the Electronic Product Code (EPC). However, EPCIS does not require the use of Electronic Product Codes, nor of Radio-frequency identification (RFID) data carriers, and as of EPCIS 1.1 does not even require instance-level identification (for which the Electronic Product Code was originally designed). The EPCIS standard applies to all situations in which visibility event data is to be captured and shared, and the presence of “EPC” within the name is of historical significance only. [1]
EPCIS 1.0 was first ratified in April 2007. [2] At the time of ratification, over 30 companies had used the draft EPCIS standard to exchange data and collaborate with trading partners [3] As of 2014, 24 commercial products had received certificates of compliance to the EPCIS standard from GS1. [4] EPCIS 1.1 was ratified by GS1 in May, 2014. [5] EPCIS 1.2 was ratified by GS1 (in conjunction with CBV 1.2) in September 2016.
The GS1 US Rx EPCIS Conformance Testing Program is administered by Drummond Group, LLC. [6]
In 2001, the MIT Auto-ID Center published a paper proposing the Physical markup language (PML), intended as "a common 'language' for describing physical objects, processes and environments". [7] PML was one of four components of an "intelligent infrastructure" envisioned by the Auto-ID Center, the other three components being RFID tags, the Electronic Product Code, and the Object Naming Service. As the work of the MIT Auto-ID Center was taken up by EPCglobal in 2004, the PML concept was renamed Electronic Product Code Information Services (EPCIS), and efforts began to create a global standard. In 2005, the first version of the EPCglobal Architecture Framework was published, which introduced EPCIS as a standard under development and showed how it related to other components of an envisioned architecture for RFID-based tracking of physical objects within supply chains. [8]
EPCIS 1.0 was first ratified in April 2007. [2] A companion standard, the EPC Core Business Vocabulary 1.0, was ratified by EPCglobal in October, 2010. [9] Despite the RFID-oriented origins of EPCIS, it came to be used in applications that used bar codes exclusively or bar codes in combination with RFID tags. [10]
EPCIS 1.1 and CBV 1.1 were ratified in May 2014. [5] New features in EPCIS 1.1 include support for class-level identification (needed especially in bar code applications), a new event type to describe processes where inputs are transformed into outputs, and additional event data to describe business transfers and instance- or lot-level master data. [11]
EPCIS 1.2 and CBV 1.2 were ratified in September 2016. New features include a mechanism to declare a previous event as being erroneous, and a mechanism for including master data into the EPCIS document header. [12]
GS1 EPCIS Rx Conformance tests are administered by their testing partner Drummond Group, LLC. [13]
Radio-frequency identification (RFID) uses electromagnetic fields to automatically identify and track tags attached to objects. An RFID system consists of a tiny radio transponder called a tag, a radio receiver, and a transmitter. When triggered by an electromagnetic interrogation pulse from a nearby RFID reader device, the tag transmits digital data, usually an identifying inventory number, back to the reader. This number can be used to track inventory goods.
Traceability is the capability to trace something. In some cases, it is interpreted as the ability to verify the history, location, or application of an item by means of documented recorded identification.
The Electronic Product Code (EPC) is designed as a universal identifier that provides a unique identity for every physical object anywhere in the world, for all time. The EPC structure is defined in the EPCglobal Tag Data Standard, which is a freely available standard. The canonical representation of an EPC is a URI, namely the 'pure-identity URI' representation that is intended for use when referring to a specific physical object in communications about EPCs among information systems and business application software.
The Auto-ID Labs network is a research group in the field of networked radio-frequency identification (RFID) and emerging sensing technologies. The labs consist of seven research universities located on four different continents. These institutions were chosen by the former Auto-ID Center to design the architecture for the Internet of Things together with EPCglobal. The federation was established in 1999; the network they have developed is at the heart of a proposal sponsored by EPCglobal and supported by GS1, GS1 US, Wal-Mart, Hewlett-Packard, and others to use RFID and the Electronic Product Code (EPC) in the identification of items in the supply chain for companies. The areas of expertise range from hardware to software to business research related to RFID.
Automatic identification and data capture (AIDC) refers to the methods of automatically identifying objects, collecting data about them, and entering them directly into computer systems, without human involvement. Technologies typically considered as part of AIDC include QR codes, bar codes, radio frequency identification (RFID), biometrics, magnetic stripes, optical character recognition (OCR), smart cards, and voice recognition. AIDC is also commonly referred to as "Automatic Identification", "Auto-ID" and "Automatic Data Capture".
GS1 is a not-for-profit, international organization developing and maintaining its own standards for barcodes and the corresponding issue company prefixes. The best known of these standards is the barcode, a symbol printed on products that can be scanned electronically.
A unique identifier (UID) is an identifier that is guaranteed to be unique among all identifiers used for those objects and for a specific purpose. The concept was formalized early in the development of computer science and information systems. In general, it was associated with an atomic data type.
In the distribution and logistics of many types of products, track and trace or tracking and tracing concerns a process of determining the current and past locations of a unique item or property. Mass serialization is the process that manufacturers go through to assign and mark each of their products with a unique identifier such as an Electronic Product Code (EPC) for track and trace purposes. The marking or "tagging" of products is usually completed within the manufacturing process through the use of various combinations of human readable or machine readable technologies such as DataMatrix barcodes or RFID.
Sanjay E. Sarma currently serves as CEO, President, and Dean at the Asia School of Business. Additionally, he holds esteemed titles as the Fred Fort Flowers (1941) and Daniel Fort Flowers (1941) Professor of Mechanical Engineering, as well as vice president for Open Learning at the Massachusetts Institute of Technology.
ISBT 128 is a global standard for the identification, labeling, and information transfer of medical products of human origin (MPHO) across international borders and disparate health care systems. MPHO includes blood, cells, tissues, human milk, and organ products among others. The Standard is managed by the International Council for Commonality in Blood Banking Automation (ICCBBA).
An epedigree is an electronic document which provides data on the history of a particular batch of a drug. It satisfies the requirement for a drug pedigree while using a convenient electronic form.
Mobile tagging is the process of providing data read from tags for display on mobile devices, commonly encoded in a two-dimensional barcode, using the camera of a camera phone as the reader device. The contents of the tag code is usually a URL for information addressed and accessible through Internet.
Application Level Events (ALE) is a standard created by EPCglobal, an organization of industry leaders devoted to the development of standards for the Electronic Product Code (EPC) and Radio-frequency identification (RFID) technologies and standards. The ALE specification is a software specification indicating required functionality and behavior, as well as a common API expressed through XML Schema Definition (XSD) and Web Services Description Language (WSDL).
The IBM RFID Information Center (RFIDIC) software solution is based on EPCglobal's Electronic Product Code Information Services (EPCIS) standard specification. RFID Information Center enables tracking of uniquely identifiable (serialized) product throughout the supply chain. Despite the name, the RFID Information Center is sensor agnostic, meaning it recognizes product serialized with RFID, barcode and/or 2D barcode. This IBM WebSphere middleware offering is a software product that falls within IBM's broader IBM Information Management Software line.
The Global Location Number (GLN) is part of the GS1 systems of standards. It is a simple tool used to identify a location and can identify locations uniquely where required. This identifier is compliant with norm ISO/IEC 6523.
Josef Preishuber-Pflügl is an Austrian technology leader.
CISC Semiconductor GmbH defines itself as “a design and consulting service company for industries developing embedded microelectronic systems with extremely short Time-To-Market cycles.” The company started in 1999, working in the semiconductor industry, but soon expanded its field towards the automotive branch and further extended business towards the radio frequency technology (RFID) sector in 2003. Since then, CISC gained significant experience and expertise in RFID, developing an own business segment and highly sensitive measurement equipment to test and verify RFID systems for different industries. Representatives of CISC Semiconductor are actively working on and contributing to worldwide standardization of future technologies like RFID, in different standardization organizations. This effort brings CISC into the position of being a leader in research and development, and thus being able to be “one step ahead of innovation”. As of 2011 CISC Semiconductor was in a globally leading standardization position for RFID testing by providing the convener of ISO/IEC JTC1 WG4/SG6 on “RFID performance and conformance test methods“, as well as GS1 EPCglobal co-chairs for performance and conformance tests.
Item-level tagging is the tagging of individual products, as opposed to case-level and pallet-level tagging. Item-level tagging is used to track individual items in order to better control inventory, by providing retailers with the ability to tag individual items on the retail floor. Previously, RFID tags were used to track pallets of merchandise, rather than individual items, through the supply chain. With the use of printed RFID tags, retailers are now able to track inventory at the item level, scan the tag, and know the location.
The ucode system is an identification number system that can be used to identify things in the real world uniquely. Digital information can be associated with objects and places, and the associated information can be retrieved by using ucode.
Dynamic Intelligent Currency Encryption (DICE) is a technological concept proposed to enhance the security of paper currency. It aims to track and monitor banknotes in circulation by utilizing identifiable characteristics, allowing for the remote devaluation of banknotes implicated in fraudulent activities or criminal transactions. Developed in 2014 by the British-Austrian technology company EDAQS, DICE introduces a security system wherein banknotes are equipped with Machine Readable Codes (MRC) or Radio-Frequency Identification (RFID) tags. These banknotes are then registered to a centralized system, purportedly rendering them secure and resistant to forgery.