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Coordination of European Research on Industrial Safety towards Smart and Sustainable Growth

Indoor localizatIon and building maintenance using radio frequency identification and inertial navigation

2015-05 to 2016-06

  • For improving personnel safety in the working environment in standard  and/or emergency operating conditions, several technologies have been  introduced in the last few years. Some ofthe proposed solutions combine  and integrate existing technologies by using them into different  application domains to enhance the synergy of interaction between  operators and the technology itself.
    This approach is adopted in the  RISING project, which addresses workers’ safety and situational  awareness using Radio Frequency IDentification (RFID) devices. RFID is a  low-cost, new emerging technology that uses communication via radio  waves to identify and track objects. An active receiver (the reader)  sends an RF signal to a transponder (the tag) which backscatters a  message.
    The RISING project aims to exploit RFID technology to  improve the safety into the working environment, with a specific focus  on emergency scenarios. Preinstalled into the environment, RFID tags can  be used to store useful information that emergency operators equipped  with RFID readers can easily retrieve automatically. Typical information  stored into RFID tag scan include: location info about the tag  (latitude, longitude, altitude, floor, etc.), the position of possible  resources (e.g., emergency exits), potential risks and/or hazardous  materials (e.g., biological hazard, toxic or flammable gases) in the  surroundings. In emergency scenarios, first responders can use such  information to be early warned about hazards, to select evacuation  paths, to endorse navigation to useful resources (plant equipment or  machinery to shutdown/open, emergency exits) and to support their  localization in indoor and deep indoor environments. In emergencies,  localization and planning information are crucial for personnel safety.  In this context, RFID system can be used in combination with inertial  navigation as viable solution for supporting hybrid Indoor Positioning  Systems (IPSs). To this end, in the RISING framework emergency  responders are supposed to be equipped with RFID readers (for retrieving  info about surroundings and their position) Inertial Measurements Units  (IMUs, for indoor localization) and smart devices (i.e., tablets,  smartphones) for displaying useful data in real time (their absolute  position, available resources and point of interests in the environment,  etc.).

  • The project will investigate the feasibility of using RFID technology to improve the activities of first responders during emergency missions in indoor/deep indoor environments. Pre-installed RFID devices embedded in  emergency lights will be used for providing crucial information to  first aid staff (such as, the actual presence of hazardous materials and  resources or in support of personnel localization and navigation system). A clear awareness about the position of specific resources  (e.g. pipelines with flammable gas, fire hoses, etc.) can considerably  reduce and prevent dangerous situations for personnel, such as  exposition to toxic materials or specific plants. In addition, an IPS  supporting first responders can really increase the efficiency of rescue  missions by reducing their operating time: when emergency commander and  rescuers know their exact positions in the environment, the mission’s  planning and management results surely more effective. In order to  guarantee the constant alignment between information stored in RFID tags  and the actual environment status, specific studies about the use of  the RISING solution for building/facilities maintenance will be also  performed.

  • The RISING framework is a flexible and scalable cutting-edge solution that allows increasing workers safety, both in emergencies and normal operating conditions, with a minimum investment. The RISING solution can bring benefits in several application fields, as illustrated in the following.

    • Technology. From a technological point of view, the RISING framework represents an innovative and scalable solution for IPSs in both emergency management and maintenance fields. The hybrid IPS combining inertial sensors and RFID (PTs, SPATs) beacons represents a turning-point system able to track user’s position without any restriction and overcoming limitations of current approaches that usually use inertial sensors and local beacons separately. Thus, operators using smart device can be constantly informed about their current positions and/or the position of local resources/hazmats.

    • User safety. The possibility to display on smart devices pseudo maps about the environment and/or info on the position of peculiar resources/hazmats contribute to increase the sense of awareness of first aid staff in emergencies, as well as contribute to support the activity of specialists during maintenance operations. The constant updating of data stored into the database/tags, according to procedures defined in WP7, will also contribute to improve the
      overall workers safety.

    • Economic. Based on the use of inertial sensors, RFID tags and smart devices (tablets, smartphones), the RISING tool is an economic solution that does not require any specific and/or dedicated infrastructures or facilities, which could be expensive to buy, install and maintain. Inertial sensors and smart devices are economic, widely available and are usually already part of the current workers’ equipment. At the same time, PTs and SPATs are inexpensive, easy to find and to use. Being embedded into emergency lights, tags do not require any specific procedure for installation and power supplying.

    • Flexibility. The RISING framework does not require any specific prior knowledge or practice. It can be used also by personnel with no experience with RFID technologies.

  • The RISING project will last 12 months. The overall activities will be arranged into Work Packages (WP), as described in the following.

    • WP1 [TECNUN] (M1-M4): definition of the scenario. Identification of the information to be stored in the RFID tags; definition of the information codification. The stored data usually include: tags physical coordinates (for personnel and objects localization), localization of possible resources (such as emergency exits), POIs, hazmats and/or service plants in the surroundings of the tag itself, local/general pseudo map of the environment (in case of SPATs).

    • WP2 [TECNUN] (M2 – M6): design and implementation of a database to collect all the information identified in WP1 within their codification. The database will include all the information related to the RFID tags and their deployment (geographical location) on the real scenario. The prototype of the database will be implemented using MySQL open source software.

    • WP3 [UNIROMA3] (M1 – M6): implementation of the hybrid IPS using an IMU that assembles off-the-shelf sensors with customised electronics. Design and implementation of a SW interface to support communication between IMU and smart devices (i.e., tablet, smartphone).

    • WP4 [UCBM] (M1 – M6): development and implementation of a software to write/read information from RFID tags using codified data stored in the database defined in WP2. Development and implementation of the communication interface between the RFID reader and smart devices.

    • WP5 [UNIROMA3 & UCBM] (M2 – M9): design and implementation of a localization algorithm able to perform data fusion from IMU and RFID tags, in order to estimate user’s position using a PDR algorithm.

    • WP6 [UCBM] (M2 – M9): design and implementation of a user-interface on the smart device able to provide a pseudo map to emergency operators’ with information about their current position, local resources, hazmats, etc.

    • WP7 [TECNUN] (M6 – M10): design of maintenance policies and update procedures needed to guarantee an adequate level of confidence on the information stored into RFID tags. Reliability of the RISING system depends on the accuracy of the stored information and the proper performance of the implemented equipment.

    • WP8 [UCBM, with the support of all partners] (M7 – M12): validation of the feasibility of the RISING solution through a pilot test in a real user case scenario.

  • Design and implementation of the RISING Hybrid Indoor Positioning System

    Publication date:

    30/08/17

    License:

    CC BY-SA

    Type:

    Project overview

    The RISING project will investigate the feasibility of using RFID  technology combined with inertial sensors embedded in smart devices to  improve the activities of first responders during emergency missions in  indoor/deep indoor environments. This document describes the design and  the implementation of a computing unit that provides the displacement of the user during the time of a mission.

    Maintenance policies and update procedures of the Rising installations

    Publication date:

    30/08/17

    License:

    CC BY-SA

    Type:

    Intermediate report

    The RISING project investigates the feasibility of using RFID technology  to improve the activities of first responders during emergency missions  in indoor/deep indoor environments. This document defines the  maintenance policies and update procedures needed to guarantee an  adequate level of confidence on the information stored into RFID tags.  The reason for this is that the reliability of the RISING system depends  on the accuracy of the stored information.

    Definition of the scenario and identification of the information

    Publication date:

    30/08/17

    License:

    CC BY-SA

    Type:

    Intermediate report

    The RISING project will investigate the feasibility of using RFID  technology to improve the activities of first responders during  emergency missions in indoor/deep indoor environments. This document  defines the scenario where the RISING solution is going to be tested and  the information to be stored in the RFID tags to provide crucial  information to first aid staff such as, the actual presence of hazardous  materials and resources.

  • Ingrid Raben

    TNO

    The Netherlands

    Anne Jansen

    TNO

    The Netherlands

    Steijn Wouter

    TNO

    The Netherlands

    Dolf Van der Beek

    TNO

    The Netherlands

    Gabriele Oliva

    Complex systems and security lab, University Campus Bio-Medico of Rome

    Italy

    Roberto Setola

    Complex systems and security lab, University Campus Bio-Medico of Rome

    Italy

    Alessandro Tugnoli

    Università di Bologna

    Italy

    Ernesto Salzano

    Università di Bologna

    Italy

    Minna Nissilä

    VTT, Technical Research Center of Finland

    Finland

    Jouko Heikkilä

    VTT, Technical Research Center of Finland

    Finland

    Nadezhda Gotcheva

    VTT, Technical Research Center of Finland

    Finland

    Marja Ylönen

    VTT, Technical Research Center of Finland

    Finland

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