Widely used in jewelry management, chip management, production automation, personnel access control and other fields.
Used in intensive reading of large quantities of electronic tags, remote reading fields.
RD5212 is a read-write device with high sensitive read-write performance and fast anti-collision processing algorithm.
Integrates a variety of communication interfaces such as Ethernet,USB, RS232 andRS485.
Operating Frequency:13.56 MHz
Support Standard:ISO/IEC 15693 and ISO/IEC 18000-3M1
RF Power:1~8W(configurable, the system default setting is 4W)
Antenna Interface:SMA×12
Communication Interface:RS232, RS485, Ethernet, USB
Working Mode: host mode and auto read mode(configurable)
Supply Voltage:12V DC
Maximum Power Consumption:≤35W
Dimensions:200×168×33mm
Maximum Operating Temperature:50℃
High-frequency high-power RFID (Radio-Frequency Identification) reader is a specialized device used for reading and sometimes writing RFID tags that operate in the high-frequency (HF) range, typically around 13.56 MHz. These readers are characterized by their ability to generate a higher level of RF power, which allows for longer read ranges and more robust communication with HF RFID tags. Here are some key features and considerations for a high-frequency high-power RFID reader:
1. RF Power Output: High-frequency high-power RFID readers are known for their increased power output compared to standard HF readers. The higher power output enables these readers to communicate with HF RFID tags at greater distances, making them suitable for applications where extended read ranges are required.
2. Read Range: The increased power output of these readers translates into an extended read range. Depending on the specific reader and antenna configuration, the read range can vary but typically extends beyond the standard HF range of a few centimeters to several meters.
3. HF RFID Compatibility: Ensure that the high-frequency high-power reader is compatible with HF RFID standards, including ISO/IEC 14443 (used for contactless smart cards and NFC) and ISO/IEC 15693 (used for vicinity cards and tags). Compatibility with these standards ensures interoperability with a wide range of HF RFID tags and devices.
4. Antenna Options: The choice of antenna is crucial in maximizing the read range and coverage area. High-frequency high-power RFID readers often support various types of antennas, including circular polarized antennas and patch antennas. The antenna selection should align with the specific requirements of your application.
5. Multiple Tag Handling: Some high-power HF RFID readers are designed to handle multiple RFID tags simultaneously within their read range. This feature is useful for applications such as inventory management and asset tracking.
6. Data Writing Capability: In addition to reading RFID tags, these readers may have the capability to write data to rewritable HF RFID tags. This is essential for applications that require data updates or encoding tags for specific purposes.
7. Connectivity: High-frequency high-power RFID readers typically connect to a computer or network using standard interfaces such as USB, Ethernet, or RS-232. The choice of connectivity depends on your integration requirements.
8. Software Compatibility: Check if the reader is compatible with the operating systems and software applications you intend to use for RFID data collection and management. Some readers come with software development kits (SDKs) or APIs for custom integration.
9. Power Supply: Ensure that the reader's power requirements align with your available power sources. High-power readers may require dedicated power supplies or higher power consumption compared to standard HF readers.
10. Application-Specific Considerations: High-frequency high-power RFID readers are commonly used in various applications, including industrial automation, logistics, access control, and manufacturing. Consider the specific requirements of your application when selecting a reader.
When choosing a high-frequency high-power RFID reader, it's essential to understand your application's needs, including read range, tag compatibility, and the environment in which it will be used. Additionally, consider factors like antenna selection, connectivity options, and software compatibility to ensure seamless integration into your RFID system.