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A European consortium dedicated to
A European consortium dedicated to food safety named SafeFoodEra conducted a collaborative RFID traceability pilot in 2010 with Swedish fisheries to test the efficacy of an EPCIS implementation for fish through the supply chain (Hild 2010). The research was part of eTrace, a project within the European Union food safety programme. The initial project scope was to track fish through the supply chain from vessel, through landing site, processor and wholesaler to final retailer to examine and evaluate traceability systems and product recall solutions (Hild 2010).
The pilot outlined a series of process transitions using unique product and location identifiers from catch to retailer over a four day period. The pilot demonstrated the use of chain of custody information of individual boxes of fish throughout the supply chain (Hild 2010). According to the Swedish Fishery Board, the pilot proved positive (Margeirsson and Gunlaugsson 2011) not only as a tool for traceability but because of enhanced levels of information sharing between supply chain stakeholders. The retailer stakeholders attested to significant increases in sales due to traceability assurances (Hild 2010). The report also outlined that RFID and the EPCIS worked well in harsh environments as a potential tool to meet the demands of the control regulation, (EG) nr 1224/2009 in EU (Hild 2010). EPCIS systems were shown to improve the speed and efficiency of traceability operations (Hild 2010).
New Zealand mandated the use of RFID technology for cattle in 2012 and deer in 2013 based on ISO standards, NZ/ISO 11784:2001 & 11785:2001.1 for transponders (low frequency RFID) and a numbering system to identify animals compliant with the International Committee on Animal Recording (ICAR) requirements. NAIT may assess and endorse devices containing transponders, which are not NZ/ISO 11784:2001 / NZ/ISO 11785:2001 compliant on a species by species basis.
The EPC Architectural Framework (formerly known as The EPCglobal Network) is a secure means to connect servers containing information related to items identified by using globally unique numbers known as Electronic Product Code (EPC) numbers. The servers, called EPC Information Services (EPCIS) are linked via a set of standards-based network services and the internet. EPC standards and The EPC Architectural Framework are being used around the world to provide supply chain visibility and traceability.
As with earlier Pathfinder research into the use of RFID technology within the context of livestock and meat identification and traceability, this research used Ultra High Frequency (UHF) RFID technologies (tags and readers) based on the EPC suite of Standards.
This research was conducted over a period of four weeks between April and May 2014. Using an eleven (11) stage Process Design Model1, stage one (1) involved the application of EPC Gen 2 UHF label tags encoded with EPC unique identification numbers (sGTIN) to 109 cartons of meat products (35 cartons of tails, 38 cartons of tripe and 36 cartons of lungs). The remaining ten (10) stages outline a process of loading cartons of frozen meat products into a shipping container, the transit of the container from the production facility to the export port (Port of Lyttleton, Christchurch, New Zealand), the transit by ocean freight of the container from the Port of Lyttleton, New Zealand to Port Klang, Malaysia and delivery of the container to a warehouse located in Kuala Lumpur. A ruggedised EPC tag encoded with a Global Individual Asset Identifier (GIAI) was attached to the shipping container on-site at the Kokiri processing plant. The unique identifier was captured and event details recorded at relevant read event nodes outlined in the process design model.
The project research team:
GS1 New Zealand and GS1 Malaysia – are member organisations in their respective countries of GS1, the international, not-for-profit standards development organisation with member organisations in over 100 countries. GS1 is dedicated to the design and implementation of global standards and solutions to improve the efficiency and visibility of supply and demand chains globally and across industry sectors. The GS1 system of standards is the most widely used supply chain standards system in the world.
The pilot outlined a series of process transitions using unique product and location identifiers from catch to retailer over a four day period. The pilot demonstrated the use of chain of custody information of individual boxes of fish throughout the supply chain (Hild 2010). According to the Swedish Fishery Board, the pilot proved positive (Margeirsson and Gunlaugsson 2011) not only as a tool for traceability but because of enhanced levels of information sharing between supply chain stakeholders. The retailer stakeholders attested to significant increases in sales due to traceability assurances (Hild 2010). The report also outlined that RFID and the EPCIS worked well in harsh environments as a potential tool to meet the demands of the control regulation, (EG) nr 1224/2009 in EU (Hild 2010). EPCIS systems were shown to improve the speed and efficiency of traceability operations (Hild 2010).
New Zealand mandated the use of RFID technology for cattle in 2012 and deer in 2013 based on ISO standards, NZ/ISO 11784:2001 & 11785:2001.1 for transponders (low frequency RFID) and a numbering system to identify animals compliant with the International Committee on Animal Recording (ICAR) requirements. NAIT may assess and endorse devices containing transponders, which are not NZ/ISO 11784:2001 / NZ/ISO 11785:2001 compliant on a species by species basis.
The EPC Architectural Framework (formerly known as The EPCglobal Network) is a secure means to connect servers containing information related to items identified by using globally unique numbers known as Electronic Product Code (EPC) numbers. The servers, called EPC Information Services (EPCIS) are linked via a set of standards-based network services and the internet. EPC standards and The EPC Architectural Framework are being used around the world to provide supply chain visibility and traceability.
As with earlier Pathfinder research into the use of RFID technology within the context of livestock and meat identification and traceability, this research used Ultra High Frequency (UHF) RFID technologies (tags and readers) based on the EPC suite of Standards.
This research was conducted over a period of four weeks between April and May 2014. Using an eleven (11) stage Process Design Model1, stage one (1) involved the application of EPC Gen 2 UHF label tags encoded with EPC unique identification numbers (sGTIN) to 109 cartons of meat products (35 cartons of tails, 38 cartons of tripe and 36 cartons of lungs). The remaining ten (10) stages outline a process of loading cartons of frozen meat products into a shipping container, the transit of the container from the production facility to the export port (Port of Lyttleton, Christchurch, New Zealand), the transit by ocean freight of the container from the Port of Lyttleton, New Zealand to Port Klang, Malaysia and delivery of the container to a warehouse located in Kuala Lumpur. A ruggedised EPC tag encoded with a Global Individual Asset Identifier (GIAI) was attached to the shipping container on-site at the Kokiri processing plant. The unique identifier was captured and event details recorded at relevant read event nodes outlined in the process design model.
The project research team:
GS1 New Zealand and GS1 Malaysia – are member organisations in their respective countries of GS1, the international, not-for-profit standards development organisation with member organisations in over 100 countries. GS1 is dedicated to the design and implementation of global standards and solutions to improve the efficiency and visibility of supply and demand chains globally and across industry sectors. The GS1 system of standards is the most widely used supply chain standards system in the world.
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A European consortium dedicated to food safety named SafeFoodEra conducted a collaborative RFID traceability pilot in 2010 with Swedish fisheries to test the efficacy of an EPCIS implementation for fish through the supply chain (Hild 2010). The research was part of eTrace, a project within the European Union food safety programme. The initial project scope was to track fish through the supply chain from vessel, through landing site, processor and wholesaler to final retailer to examine and evaluate traceability systems and product recall solutions (Hild 2010).The pilot outlined a series of process transitions using unique product and location identifiers from catch to retailer over a four day period. The pilot demonstrated the use of chain of custody information of individual boxes of fish throughout the supply chain (Hild 2010). According to the Swedish Fishery Board, the pilot proved positive (Margeirsson and Gunlaugsson 2011) not only as a tool for traceability but because of enhanced levels of information sharing between supply chain stakeholders. The retailer stakeholders attested to significant increases in sales due to traceability assurances (Hild 2010). The report also outlined that RFID and the EPCIS worked well in harsh environments as a potential tool to meet the demands of the control regulation, (EG) nr 1224/2009 in EU (Hild 2010). EPCIS systems were shown to improve the speed and efficiency of traceability operations (Hild 2010).New Zealand mandated the use of RFID technology for cattle in 2012 and deer in 2013 based on ISO standards, NZ/ISO 11784:2001 & 11785:2001.1 for transponders (low frequency RFID) and a numbering system to identify animals compliant with the International Committee on Animal Recording (ICAR) requirements. NAIT may assess and endorse devices containing transponders, which are not NZ/ISO 11784:2001 / NZ/ISO 11785:2001 compliant on a species by species basis.The EPC Architectural Framework (formerly known as The EPCglobal Network) is a secure means to connect servers containing information related to items identified by using globally unique numbers known as Electronic Product Code (EPC) numbers. The servers, called EPC Information Services (EPCIS) are linked via a set of standards-based network services and the internet. EPC standards and The EPC Architectural Framework are being used around the world to provide supply chain visibility and traceability.As with earlier Pathfinder research into the use of RFID technology within the context of livestock and meat identification and traceability, this research used Ultra High Frequency (UHF) RFID technologies (tags and readers) based on the EPC suite of Standards.This research was conducted over a period of four weeks between April and May 2014. Using an eleven (11) stage Process Design Model1, stage one (1) involved the application of EPC Gen 2 UHF label tags encoded with EPC unique identification numbers (sGTIN) to 109 cartons of meat products (35 cartons of tails, 38 cartons of tripe and 36 cartons of lungs). The remaining ten (10) stages outline a process of loading cartons of frozen meat products into a shipping container, the transit of the container from the production facility to the export port (Port of Lyttleton, Christchurch, New Zealand), the transit by ocean freight of the container from the Port of Lyttleton, New Zealand to Port Klang, Malaysia and delivery of the container to a warehouse located in Kuala Lumpur. A ruggedised EPC tag encoded with a Global Individual Asset Identifier (GIAI) was attached to the shipping container on-site at the Kokiri processing plant. The unique identifier was captured and event details recorded at relevant read event nodes outlined in the process design model.The project research team: GS1 Selandia Baru dan GS1 Malaysia-adalah organisasi-organisasi anggota di negara mereka masing-masing GS1, pengembangan standar internasional, tidak-untuk-laba organisasi dengan anggota organisasi di lebih dari 100 negara. GS1 didedikasikan untuk desain dan implementasi standar global dan solusi untuk meningkatkan efisiensi dan visibilitas rantai pasokan dan permintaan secara global dan di seluruh sektor industri. Sistem GS1 standar adalah sistem standar rantai pasokan yang paling banyak digunakan di dunia.
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Sebuah konsorsium Eropa yang didedikasikan untuk keamanan pangan bernama SafeFoodEra dilakukan pilot RFID traceability kolaboratif pada tahun 2010 dengan perikanan Swedia untuk menguji efektivitas implementasi EPCIS untuk ikan melalui rantai pasokan (Hild 2010). Penelitian ini merupakan bagian dari eTrace, proyek dalam program keamanan pangan Uni Eropa. Ruang lingkup proyek awal adalah untuk melacak ikan melalui rantai pasokan dari kapal, melalui situs pendaratan, prosesor dan grosir ke pengecer akhir untuk memeriksa dan mengevaluasi sistem traceability dan solusi produk recall (Hild 2010).
Pilot diuraikan serangkaian transisi proses menggunakan unik produk dan lokasi pengenal dari hasil tangkapan ke pengecer selama empat hari. Pilot menunjukkan penggunaan rantai informasi tahanan individu kotak ikan di seluruh rantai pasokan (Hild 2010). Menurut Perikanan Dewan Swedia, pilot terbukti positif (Margeirsson dan Gunlaugsson 2011) tidak hanya sebagai alat untuk ketertelusuran tetapi karena tingkat ditingkatkan berbagi antara pemangku kepentingan rantai pasokan informasi. Pengecer stakeholder dibuktikan peningkatan yang signifikan dalam penjualan karena jaminan ketertelusuran (Hild 2010). Laporan ini juga diuraikan bahwa RFID dan EPCIS bekerja dengan baik dalam lingkungan yang keras sebagai alat potensial untuk memenuhi tuntutan regulasi kontrol, (EG) nr 1224/2009 di Uni Eropa (Hild 2010). Sistem EPCIS ditunjukkan untuk meningkatkan kecepatan dan efisiensi operasi ketertelusuran (Hild 2010).
Selandia Baru diamanatkan penggunaan teknologi RFID untuk ternak pada tahun 2012 dan rusa pada tahun 2013 berdasarkan standar ISO, NZ / ISO 11784: 2001 & 11785: 2001.1 untuk transponder (frekuensi rendah RFID) dan sistem penomoran untuk mengidentifikasi hewan sesuai dengan Komite Internasional Recording Animal (ICAR) persyaratan. NAIT dapat menilai dan mendukung perangkat yang berisi transponder, yang tidak NZ / ISO 11784: 2001 / NZ / ISO 11785: 2001 compliant pada spesies dengan dasar spesies.
The EPC Kerangka Arsitektur (sebelumnya dikenal sebagai The EPCglobal Network) merupakan sarana yang aman untuk menghubungkan server yang berisi informasi yang berhubungan dengan item diidentifikasi dengan menggunakan nomor unik global dikenal sebagai Kode Produk Elektronik (EPC) nomor. Server, disebut Layanan Informasi EPC (EPCIS) yang terhubung melalui set layanan jaringan berbasis standar dan internet. Standar EPC dan EPC Kerangka Arsitektur yang digunakan di seluruh dunia untuk menyediakan rantai pasokan visibilitas dan mampu telusur.
Seperti penelitian Pathfinder sebelumnya ke dalam penggunaan teknologi RFID dalam konteks ternak dan daging identifikasi dan mampu telusur, penelitian ini menggunakan Ultra High Frequency ( UHF) teknologi RFID (tag dan pembaca) berdasarkan EPC suite Standar.
penelitian ini dilakukan selama empat minggu antara bulan April dan Mei 2014. menggunakan sebelas (11) Proses tahap Desain Model1, tahap satu (1) yang terlibat penerapan EPC Gen 2 UHF tag label dikodekan dengan nomor EPC yang unik identifikasi (sGTIN) ke 109 karton produk daging (35 karton ekor, 38 karton babat dan 36 karton dari paru-paru). Sisanya sepuluh (10) tahap menguraikan proses loading karton produk daging beku ke dalam wadah pengiriman, transit wadah dari fasilitas produksi ke pelabuhan ekspor (Port of Lyttleton, Christchurch, Selandia Baru), transit oleh laut barang dari kontainer dari Pelabuhan Lyttleton, Selandia Baru ke Port Klang, Malaysia dan pengiriman kontainer ke gudang yang terletak di Kuala Lumpur. Sebuah tag EPC ruggedised dikodekan dengan Global Individual Aset Identifier (Giai) melekat pada wadah pengiriman on-site di pabrik pengolahan Kokiri. Pengenal unik ditangkap dan detail acara yang direkam pada acara node membaca relevan digariskan dalam model desain proses.
Tim peneliti proyek:
GS1 Selandia Baru dan GS1 Malaysia - adalah organisasi anggota di negara masing-masing dari GS1, internasional, tidak-untuk standar -profit pengembangan organisasi dengan organisasi-organisasi anggota di lebih dari 100 negara. GS1 didedikasikan untuk desain dan implementasi standar global dan solusi untuk meningkatkan efisiensi dan visibilitas dari penawaran dan permintaan rantai global dan di seluruh sektor industri. Sistem GS1 standar yang paling banyak digunakan sistem standar rantai pasokan di dunia.
Pilot diuraikan serangkaian transisi proses menggunakan unik produk dan lokasi pengenal dari hasil tangkapan ke pengecer selama empat hari. Pilot menunjukkan penggunaan rantai informasi tahanan individu kotak ikan di seluruh rantai pasokan (Hild 2010). Menurut Perikanan Dewan Swedia, pilot terbukti positif (Margeirsson dan Gunlaugsson 2011) tidak hanya sebagai alat untuk ketertelusuran tetapi karena tingkat ditingkatkan berbagi antara pemangku kepentingan rantai pasokan informasi. Pengecer stakeholder dibuktikan peningkatan yang signifikan dalam penjualan karena jaminan ketertelusuran (Hild 2010). Laporan ini juga diuraikan bahwa RFID dan EPCIS bekerja dengan baik dalam lingkungan yang keras sebagai alat potensial untuk memenuhi tuntutan regulasi kontrol, (EG) nr 1224/2009 di Uni Eropa (Hild 2010). Sistem EPCIS ditunjukkan untuk meningkatkan kecepatan dan efisiensi operasi ketertelusuran (Hild 2010).
Selandia Baru diamanatkan penggunaan teknologi RFID untuk ternak pada tahun 2012 dan rusa pada tahun 2013 berdasarkan standar ISO, NZ / ISO 11784: 2001 & 11785: 2001.1 untuk transponder (frekuensi rendah RFID) dan sistem penomoran untuk mengidentifikasi hewan sesuai dengan Komite Internasional Recording Animal (ICAR) persyaratan. NAIT dapat menilai dan mendukung perangkat yang berisi transponder, yang tidak NZ / ISO 11784: 2001 / NZ / ISO 11785: 2001 compliant pada spesies dengan dasar spesies.
The EPC Kerangka Arsitektur (sebelumnya dikenal sebagai The EPCglobal Network) merupakan sarana yang aman untuk menghubungkan server yang berisi informasi yang berhubungan dengan item diidentifikasi dengan menggunakan nomor unik global dikenal sebagai Kode Produk Elektronik (EPC) nomor. Server, disebut Layanan Informasi EPC (EPCIS) yang terhubung melalui set layanan jaringan berbasis standar dan internet. Standar EPC dan EPC Kerangka Arsitektur yang digunakan di seluruh dunia untuk menyediakan rantai pasokan visibilitas dan mampu telusur.
Seperti penelitian Pathfinder sebelumnya ke dalam penggunaan teknologi RFID dalam konteks ternak dan daging identifikasi dan mampu telusur, penelitian ini menggunakan Ultra High Frequency ( UHF) teknologi RFID (tag dan pembaca) berdasarkan EPC suite Standar.
penelitian ini dilakukan selama empat minggu antara bulan April dan Mei 2014. menggunakan sebelas (11) Proses tahap Desain Model1, tahap satu (1) yang terlibat penerapan EPC Gen 2 UHF tag label dikodekan dengan nomor EPC yang unik identifikasi (sGTIN) ke 109 karton produk daging (35 karton ekor, 38 karton babat dan 36 karton dari paru-paru). Sisanya sepuluh (10) tahap menguraikan proses loading karton produk daging beku ke dalam wadah pengiriman, transit wadah dari fasilitas produksi ke pelabuhan ekspor (Port of Lyttleton, Christchurch, Selandia Baru), transit oleh laut barang dari kontainer dari Pelabuhan Lyttleton, Selandia Baru ke Port Klang, Malaysia dan pengiriman kontainer ke gudang yang terletak di Kuala Lumpur. Sebuah tag EPC ruggedised dikodekan dengan Global Individual Aset Identifier (Giai) melekat pada wadah pengiriman on-site di pabrik pengolahan Kokiri. Pengenal unik ditangkap dan detail acara yang direkam pada acara node membaca relevan digariskan dalam model desain proses.
Tim peneliti proyek:
GS1 Selandia Baru dan GS1 Malaysia - adalah organisasi anggota di negara masing-masing dari GS1, internasional, tidak-untuk standar -profit pengembangan organisasi dengan organisasi-organisasi anggota di lebih dari 100 negara. GS1 didedikasikan untuk desain dan implementasi standar global dan solusi untuk meningkatkan efisiensi dan visibilitas dari penawaran dan permintaan rantai global dan di seluruh sektor industri. Sistem GS1 standar yang paling banyak digunakan sistem standar rantai pasokan di dunia.
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