| Dimension (depth) | 480 mm |
| Application weight | 4 g |
| Housing material (primary) | PA |
RFID transponders
61 - 80 / 344
| Dimension (width) | 25 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 65 mm |
| Dimension (depth) | 480 mm |
| Application weight | 205 g |
| Housing material (primary) | Epoxy resin fiberglass |
| Dimension (depth) | 480 mm |
| Application weight | 16 g |
| Housing material (primary) | Steel |
| Dimension (depth) | 480 mm |
| Application weight | 101 g |
| Housing material (primary) | POM |
| Dimension (width) | 34 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 34 mm |
| Max. memory size (writing) | 192 Byte |
| Memory type | EEPROM |
| Type data medium | Special design |
| Dimension (depth) | 480 mm |
| Dimension (height) | 25 mm |
| Dimension (width) | 25 mm |
| Dimension (depth) | 480 mm |
| Application weight | 20 g |
| Housing material (primary) | Steel |
| Dimension (depth) | 480 mm |
| Application weight | 3 g |
| Housing material (primary) | Steel |
| Dimension (depth) | 480 mm |
| Dimension (height) | 22 mm |
| Dimension (width) | 22 mm |
| Dimension (depth) | 480 mm |
| Application weight | 1 g |
| Housing material (primary) | Epoxy resin fiberglass |
| Dimension (depth) | 480 mm |
| Application weight | 74 g |
| Housing material (primary) | PBT |
| Dimension (depth) | 480 mm |
| Application weight | 18 g |
| Housing material (primary) | Steel |
| Dimension (depth) | 480 mm |
| Application weight | 3 g |
| Housing material (primary) | Steel |
| Dimension (depth) | 480 mm |
| Dimension (height) | 130.2 mm |
| Dimension (width) | 37.4 mm |
| Dimension (depth) | 480 mm |
| Application weight | 131 g |
| Housing material (primary) | PEEK |
| Dimension (depth) | 480 mm |
| Application weight | 9 g |
| Housing material (primary) | POM |
| Dimension (width) | 32 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 52 mm |
| Dimension (width) | 32 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 52 mm |
RFID transponder - The invisible technology that changes our everyday life
RFID transponders are tiny electronic devices that allow objects to be identified and tracked wirelessly. The abbreviation RFID stands for Radio-Frequency Identification. This technology has become increasingly important in recent years and already influences many aspects of our daily lives.
The RFID transponder consists of a microchip and an antenna. The microchip stores information about the object it represents, while the antenna enables communication with an RFID reader. When the transponder is within range of a reader, it is activated and sends its stored information to the reader via radio waves. This process happens in a fraction of a second and requires no physical connection between the transponder and the reader.
The applications of RFID transponders are diverse. In the logistics industry, they are used to track goods. RFID transponders enable companies to determine the exact location of their products in real time, improving the efficiency of their supply chains. In supermarkets, RFID transponders are embedded in products such as clothing or electronics to prevent theft. When a customer tries to leave the store with an unpaid item, the RFID transponder triggers an alarm.
But RFID transponders are not only used in business. In healthcare, they are used to identify patients and track medical devices. This allows physicians and nurses to quickly access patient data and ensure that the right medications and treatments are administered.
RFID transponders also have their uses in the animal world. Pets can be equipped with an RFID transponder that allows them to be identified and returned to their owners if lost. In agriculture, RFID transponders are used to track livestock to monitor their health and origin.
Despite their many uses, there are also concerns about the privacy and security of RFID transponders. Since they operate wirelessly, unauthorized persons could theoretically intercept and misuse the information sent. It is therefore important to take appropriate security measures to prevent the misuse of RFID transponders.
Overall, however, RFID transponders offer a variety of benefits and have the potential to make our everyday lives easier and more efficient. The technology is constantly evolving and is being used in more and more areas. We can look forward to seeing what new and innovative applications await us in the future.
RFID transponders are tiny electronic devices that allow objects to be identified and tracked wirelessly. The abbreviation RFID stands for Radio-Frequency Identification. This technology has become increasingly important in recent years and already influences many aspects of our daily lives.
The RFID transponder consists of a microchip and an antenna. The microchip stores information about the object it represents, while the antenna enables communication with an RFID reader. When the transponder is within range of a reader, it is activated and sends its stored information to the reader via radio waves. This process happens in a fraction of a second and requires no physical connection between the transponder and the reader.
The applications of RFID transponders are diverse. In the logistics industry, they are used to track goods. RFID transponders enable companies to determine the exact location of their products in real time, improving the efficiency of their supply chains. In supermarkets, RFID transponders are embedded in products such as clothing or electronics to prevent theft. When a customer tries to leave the store with an unpaid item, the RFID transponder triggers an alarm.
But RFID transponders are not only used in business. In healthcare, they are used to identify patients and track medical devices. This allows physicians and nurses to quickly access patient data and ensure that the right medications and treatments are administered.
RFID transponders also have their uses in the animal world. Pets can be equipped with an RFID transponder that allows them to be identified and returned to their owners if lost. In agriculture, RFID transponders are used to track livestock to monitor their health and origin.
Despite their many uses, there are also concerns about the privacy and security of RFID transponders. Since they operate wirelessly, unauthorized persons could theoretically intercept and misuse the information sent. It is therefore important to take appropriate security measures to prevent the misuse of RFID transponders.
Overall, however, RFID transponders offer a variety of benefits and have the potential to make our everyday lives easier and more efficient. The technology is constantly evolving and is being used in more and more areas. We can look forward to seeing what new and innovative applications await us in the future.
What is an RFID transponder and how does it work?
An RFID transponder is an electronic device that can send and receive information wirelessly via radio waves. RFID stands for Radio Frequency Identification.
The transponder consists of a microchip and an antenna. The microchip contains the stored information to be transmitted, while the antenna enables communication with an RFID reader.
Radio communication between the RFID transponder and the reader is based on the principle of inductive coupling. When the RFID transponder comes within range of the reader, the reader emits a radio signal. This signal is picked up by the transponder's antenna and generates energy that activates the microchip.
As soon as the microchip is activated, it sends the stored information back to the reader. This information can be, for example, the transponder's unique identifier or other data stored on the chip.
Communication between the transponder and the reader is usually very fast and does not require a direct line of sight. This enables the automatic identification and capture of large quantities of transponders in a short time, which is useful in various applications such as logistics, retail, public transportation and access systems.
The transponder consists of a microchip and an antenna. The microchip contains the stored information to be transmitted, while the antenna enables communication with an RFID reader.
Radio communication between the RFID transponder and the reader is based on the principle of inductive coupling. When the RFID transponder comes within range of the reader, the reader emits a radio signal. This signal is picked up by the transponder's antenna and generates energy that activates the microchip.
As soon as the microchip is activated, it sends the stored information back to the reader. This information can be, for example, the transponder's unique identifier or other data stored on the chip.
Communication between the transponder and the reader is usually very fast and does not require a direct line of sight. This enables the automatic identification and capture of large quantities of transponders in a short time, which is useful in various applications such as logistics, retail, public transportation and access systems.
What different types of RFID transponders are there?
There are different types of RFID transponders, which have different attributes depending on the application and communication protocol. Here are some examples:
1. Active RFID transponders: These transponders have their own energy source and can actively send and receive information. They have a greater range than passive transponders and are suitable for applications where real-time communication is required.
2. Passive RFID transponders: These transponders have no energy source of their own and are activated by the electromagnetic field of an RFID reader. They have a limited range and are mostly used for applications where only small amounts of data need to be transmitted, such as barcode replacement, access control or inventory.
3. Semi-passive RFID transponder: These transponders have their own power source to run their internal circuits, but they use the RFID reader's field to transmit data. They offer a greater range than passive transponders and have a longer battery life than active transponders.
4. UHF RFID transponder: These transponders use the ultra-high frequency range (UHF) and enable a greater range and higher data throughput rates. They are often used for applications in logistics, retail and warehousing.
5. HF RFID transponders: These transponders use the high frequency (HF) range and have a shorter range than UHF transponders. They are often used for applications such as near field communication (NFC), contactless payments and access control.
6. LF RFID transponders: These transponders use the low frequency (LF) range and have the shortest range. They are often used for applications such as animal identification, vehicle identification and access control.
These are just a few examples of the different types of RFID transponders. Depending on the specific application, other variations and protocols can also be used.
1. Active RFID transponders: These transponders have their own energy source and can actively send and receive information. They have a greater range than passive transponders and are suitable for applications where real-time communication is required.
2. Passive RFID transponders: These transponders have no energy source of their own and are activated by the electromagnetic field of an RFID reader. They have a limited range and are mostly used for applications where only small amounts of data need to be transmitted, such as barcode replacement, access control or inventory.
3. Semi-passive RFID transponder: These transponders have their own power source to run their internal circuits, but they use the RFID reader's field to transmit data. They offer a greater range than passive transponders and have a longer battery life than active transponders.
4. UHF RFID transponder: These transponders use the ultra-high frequency range (UHF) and enable a greater range and higher data throughput rates. They are often used for applications in logistics, retail and warehousing.
5. HF RFID transponders: These transponders use the high frequency (HF) range and have a shorter range than UHF transponders. They are often used for applications such as near field communication (NFC), contactless payments and access control.
6. LF RFID transponders: These transponders use the low frequency (LF) range and have the shortest range. They are often used for applications such as animal identification, vehicle identification and access control.
These are just a few examples of the different types of RFID transponders. Depending on the specific application, other variations and protocols can also be used.
Where are RFID transponders used and what advantages do they offer?
RFID transponders are used in various areas, including:
1. Logistics and supply chain management: RFID transponders are used to track and identify goods and products to monitor inventory status in real time and improve efficiency in the supply chain.
2. Retail trade: RFID transponders are used in the retail industry to track inventory, prevent theft and provide a seamless shopping experience. They can also be used to personalize customer experiences.
3. Access control and security: RFID transponders are used for access control in buildings, parking garages, events and public transportation. They enable people and vehicles to be identified quickly and efficiently.
4. Healthcare: RFID transponders are used in hospitals and care facilities to identify patients, track medical equipment and monitor medication stocks.
5. Animal identification: RFID transponders are used to identify and track pets and farm animals. They can also be used in wildlife research.
The advantages of RFID transponders are:
1. Automation: RFID transponders enable automatic identification and data capture without direct contact or line of sight, speeding up the process and reducing human error.
2. Real-time tracking: RFID transponders enable real-time tracking of goods, products or people, ensuring accurate inventory control and improved security.
3. Increased efficiency: RFID transponders enable fast inventory, inventory management and process optimization, resulting in improved efficiency and productivity.
4. Theft prevention: RFID transponders can be used to prevent theft by triggering alarms when goods leave the store without authorization.
5. Personalization: RFID transponders enable personalized customer interaction by storing information about preferences or past purchases and providing personalized offers or recommendations.
6. Longevity: RFID transponders are usually durable and can be used in various environments, including adverse weather conditions or transportation by different hands.
1. Logistics and supply chain management: RFID transponders are used to track and identify goods and products to monitor inventory status in real time and improve efficiency in the supply chain.
2. Retail trade: RFID transponders are used in the retail industry to track inventory, prevent theft and provide a seamless shopping experience. They can also be used to personalize customer experiences.
3. Access control and security: RFID transponders are used for access control in buildings, parking garages, events and public transportation. They enable people and vehicles to be identified quickly and efficiently.
4. Healthcare: RFID transponders are used in hospitals and care facilities to identify patients, track medical equipment and monitor medication stocks.
5. Animal identification: RFID transponders are used to identify and track pets and farm animals. They can also be used in wildlife research.
The advantages of RFID transponders are:
1. Automation: RFID transponders enable automatic identification and data capture without direct contact or line of sight, speeding up the process and reducing human error.
2. Real-time tracking: RFID transponders enable real-time tracking of goods, products or people, ensuring accurate inventory control and improved security.
3. Increased efficiency: RFID transponders enable fast inventory, inventory management and process optimization, resulting in improved efficiency and productivity.
4. Theft prevention: RFID transponders can be used to prevent theft by triggering alarms when goods leave the store without authorization.
5. Personalization: RFID transponders enable personalized customer interaction by storing information about preferences or past purchases and providing personalized offers or recommendations.
6. Longevity: RFID transponders are usually durable and can be used in various environments, including adverse weather conditions or transportation by different hands.
What security risks are associated with RFID transponders and how can they be minimized?
RFID (Radio-Frequency Identification) transponders are associated with various security risks. Some of them are:
1. Data theft: RFID transponders can transmit data that can be intercepted and stolen by attackers. This could put personal information or company data at risk.
2. Cloning of transponders: RFID transponders can be cloned, allowing attackers to impersonate legitimate users and gain access to protected areas or information.
3. Unauthorized tracking: The reading of RFID tags can lead to unauthorized tracking of people or objects, which endangers privacy.
4. Manipulation of transponders: Attackers could manipulate RFID transponders to transmit false information or disrupt the system.
The following measures can be taken to minimize these security risks:
1. Encryption: Communication between the RFID transponder and reader should be encrypted to protect the data from theft.
2. Access control: Access control should be implemented to ensure that only authorized persons have access to the RFID tags and the associated information.
3. Authentication: A strong authentication method, such as passwords or biometric features, should be used to ensure that only legitimate transponders are recognized.
4. Data protection: Measures should be taken to protect privacy, for example by regularly changing RFID IDs or adding jamming signals to make tracking more difficult.
5. Monitoring: The RFID system should be monitored to detect and respond to suspicious activity.
By implementing these measures, the security risks associated with RFID transponders can be minimized.
1. Data theft: RFID transponders can transmit data that can be intercepted and stolen by attackers. This could put personal information or company data at risk.
2. Cloning of transponders: RFID transponders can be cloned, allowing attackers to impersonate legitimate users and gain access to protected areas or information.
3. Unauthorized tracking: The reading of RFID tags can lead to unauthorized tracking of people or objects, which endangers privacy.
4. Manipulation of transponders: Attackers could manipulate RFID transponders to transmit false information or disrupt the system.
The following measures can be taken to minimize these security risks:
1. Encryption: Communication between the RFID transponder and reader should be encrypted to protect the data from theft.
2. Access control: Access control should be implemented to ensure that only authorized persons have access to the RFID tags and the associated information.
3. Authentication: A strong authentication method, such as passwords or biometric features, should be used to ensure that only legitimate transponders are recognized.
4. Data protection: Measures should be taken to protect privacy, for example by regularly changing RFID IDs or adding jamming signals to make tracking more difficult.
5. Monitoring: The RFID system should be monitored to detect and respond to suspicious activity.
By implementing these measures, the security risks associated with RFID transponders can be minimized.
What is the range of an RFID transponder?
The range of an RFID transponder depends on various factors, such as the frequency of the transponder, the transmission power of the reader and the environmental conditions.
At low frequencies, such as 125 kHz, the typical range of a passive RFID transponder is around 1 to 2 meters. At higher frequencies, such as 13.56 MHz, the range can be up to 1 meter.
However, there are also active RFID transponders that have their own battery and can therefore have a greater range. With active transponders, ranges of several meters to several kilometers can be achieved.
It is important to note that the range may also depend on other factors such as the material the transponder is made of and the positioning of the reader.
At low frequencies, such as 125 kHz, the typical range of a passive RFID transponder is around 1 to 2 meters. At higher frequencies, such as 13.56 MHz, the range can be up to 1 meter.
However, there are also active RFID transponders that have their own battery and can therefore have a greater range. With active transponders, ranges of several meters to several kilometers can be achieved.
It is important to note that the range may also depend on other factors such as the material the transponder is made of and the positioning of the reader.
What costs are associated with the implementation of RFID transponders?
The cost of implementing RFID transponders can vary depending on the scope and complexity of the project. Possible cost items include:
1. RFID transponder: The cost of purchasing RFID transponders depends on the type and quantity of transponders required. Prices may vary depending on the size, storage capacity and functionality of the transponders.
2. RFID readers: The readers are required to read the RFID transponders. The cost of purchasing readers varies depending on the manufacturer, performance and functionality.
3. RFID infrastructure: An RFID infrastructure usually includes antennas, cabling, network devices and software. The costs for the infrastructure depend on the size of the area to be monitored and the specific requirements of the project.
4. Implementation costs: The implementation of RFID transponders usually requires the involvement of specialist personnel such as RFID experts or IT specialists. The costs for implementation vary depending on the scope of the project and the resources required.
5. Training costs: It may be necessary to train employees so that they can use the RFID system effectively. The training costs vary depending on the number of employees to be trained and the type of training (e.g. on-site training or online training).
6. Maintenance costs: RFID systems require regular maintenance to ensure smooth operation. The maintenance costs may vary depending on the provider and the scope of the maintenance services.
It is important to note that these costs are only general guidelines and may vary depending on individual requirements and circumstances. It is recommended to obtain quotes from various providers and to carry out a comprehensive cost analysis in order to obtain an accurate estimate of the implementation costs.
1. RFID transponder: The cost of purchasing RFID transponders depends on the type and quantity of transponders required. Prices may vary depending on the size, storage capacity and functionality of the transponders.
2. RFID readers: The readers are required to read the RFID transponders. The cost of purchasing readers varies depending on the manufacturer, performance and functionality.
3. RFID infrastructure: An RFID infrastructure usually includes antennas, cabling, network devices and software. The costs for the infrastructure depend on the size of the area to be monitored and the specific requirements of the project.
4. Implementation costs: The implementation of RFID transponders usually requires the involvement of specialist personnel such as RFID experts or IT specialists. The costs for implementation vary depending on the scope of the project and the resources required.
5. Training costs: It may be necessary to train employees so that they can use the RFID system effectively. The training costs vary depending on the number of employees to be trained and the type of training (e.g. on-site training or online training).
6. Maintenance costs: RFID systems require regular maintenance to ensure smooth operation. The maintenance costs may vary depending on the provider and the scope of the maintenance services.
It is important to note that these costs are only general guidelines and may vary depending on individual requirements and circumstances. It is recommended to obtain quotes from various providers and to carry out a comprehensive cost analysis in order to obtain an accurate estimate of the implementation costs.
How can RFID transponders be used to improve logistics processes?
RFID transponders can be used in logistics in various ways to improve processes:
1. Inventory management: RFID tags can be attached to goods, pallets or containers to track and identify inventory. This enables real-time monitoring of the flow of goods and precise inventory management.
2. Tracking of shipments: RFID tags can be attached to individual shipments to track their location and movements in real time. This facilitates shipment tracking and enables faster delivery.
3. Automatic data acquisition: RFID tags can automatically record information about goods, such as weight, size, origin or expiry date. This reduces manual data entry and the susceptibility to errors.
4. Optimization of warehouse processes: RFID tags can be attached to warehouse shelves or containers to track the location of goods in the warehouse. This makes it easier to search for specific products, optimizes storage capacity and increases efficiency.
5. Theft protection: RFID tags can be used as theft protection by attaching them to expensive or sensitive products. This can trigger an alarm if a product leaves the warehouse or salesroom without authorization.
6. Quality control: RFID tags can contain information about the manufacturing process or the quality of a product. This enables fast and precise quality control and traceability in the event of problems or recalls.
Logistics processes can be made more efficient through the use of RFID transponders, as they enable goods to be automatically recorded and monitored. This reduces errors, improves accuracy and shortens process times.
1. Inventory management: RFID tags can be attached to goods, pallets or containers to track and identify inventory. This enables real-time monitoring of the flow of goods and precise inventory management.
2. Tracking of shipments: RFID tags can be attached to individual shipments to track their location and movements in real time. This facilitates shipment tracking and enables faster delivery.
3. Automatic data acquisition: RFID tags can automatically record information about goods, such as weight, size, origin or expiry date. This reduces manual data entry and the susceptibility to errors.
4. Optimization of warehouse processes: RFID tags can be attached to warehouse shelves or containers to track the location of goods in the warehouse. This makes it easier to search for specific products, optimizes storage capacity and increases efficiency.
5. Theft protection: RFID tags can be used as theft protection by attaching them to expensive or sensitive products. This can trigger an alarm if a product leaves the warehouse or salesroom without authorization.
6. Quality control: RFID tags can contain information about the manufacturing process or the quality of a product. This enables fast and precise quality control and traceability in the event of problems or recalls.
Logistics processes can be made more efficient through the use of RFID transponders, as they enable goods to be automatically recorded and monitored. This reduces errors, improves accuracy and shortens process times.