Electronic enthusiasts : Disease monitoring equipment is usually used to measure the patient's vital signs, such as blood pressure, heart rate and other parameters. The requirements for managing these important data far exceed the scope of simple inventory control, requiring equipment to provide equipment inspection, calibration and Self-test results with security upgrades while minimizing equipment downtime. Maintenance personnel often affix the label that records the repair data to the device. Since a large amount of data needs to be recorded and gradually deteriorated after a period of time, the label sticker is no longer a reasonable choice. As technology advances rapidly, disease surveillance devices often require software upgrades.
Unlike static label stickers, the dynamic dual-interface RFID EEPROM electronic label solution records measurement parameters for later reading and logs new data into the system, for example, calibration constants and inspection information, without the need for external externals. Connector. The dual interface electronic tag can be connected to the disease monitoring device through the I2C interface. When the device is executing, the device can read and write the electronic tag through the I2C interface. Even if the disease monitoring device is not working, the medical staff can read and write the electronic tag data through an ordinary electronic tag reader that conforms to the ISO 15693 13.56 MHz RFID standard, because it ensures the latest, safe and ready-to-read data, dual interface storage. Make the RFID technology chain perfect.
Target applications for dual-interface passive RFID systems include equipment maintenance conditions and records, authorized accessory verification, sensors, counterfeit goods identification, disposable product reuse control, and the addition of new licensed products. When the monitoring device is working or standby, the operator can read and write the data in the dual interface RFID through the monitoring device. When the device is turned off, the operator can use the electronic tag reader to manage the data in the dual interface RFID. Designers create more opportunities.
Disease surveillance system classification
Disease surveillance systems are generally divided into three categories: bedside monitors, portable handheld monitors, and body-worn monitors.
Bedside monitors play an important role in providing medical monitoring and diagnostic information. The amount of information provided by bedside monitors is increasing in the monitoring information required by healthcare professionals. Bedside monitoring equipment is often installed in critical intensive care areas, such as intensive care units, where most bedside monitoring devices are now connected to a central monitoring system via a hospital network to exchange data through the facility network.
The management of portable monitors is no small challenge, as such devices seem to be able to "get away from the group or even get lost." While viewing device locations is beyond the scope of this article, understanding what happens to a device can be a great help in ensuring that devices are continuously compliant and verifying device identities.
Although the human body wear monitor is not a new invention, as the product is updated, the measurement method and data volume are rapidly increasing, which is where a dual interface RFID solution comes into play. As a gateway to the internal workings of the system, the dual-interface RFID solution is connected to the monitoring device without the need for tangled connections, thus improving the usability and service life of the monitor.
The human body monitor can also be subdivided into the following categories :
• Mobile/Wearing Personal Monitor (MPM): A wearable personal monitoring device instantly monitors vital signs of patients with chronic conditions and stores and forwards measurements or alarms.
• Mobile aggregator: A smartphone-like device that can report patient status via mobile wireless technology with or without an external sensor.
• Wearable health care equipment: A health care device worn on the wrist/arm/chest or a sensor embedded in the fabric of the shoe and shirt to detect life activity characteristics such as heart rate, breathing, and pace.
• Remote Patient Management (RPM) equipment: Special monitoring equipment with built-in patient-specific sensors. These systems are equipped with hospital-specific sensors that are customizable for patients and can report all vital signs, such as heart rate, patient posture (standing or lying).
Whether it's a bedside monitor or a portable or wearable monitor, all disease monitoring devices face a common challenge: how to keep the equipment up-to-date with software, calibration data or maintenance records? How to find faulty equipment?
Benefits of managing system data
A simple device failure can have a major impact on the results of the disease detection report. Undoubtedly, in the problems that have plagued the industry for many years, the backup battery failure of monitoring equipment has always topped the list. The system self-test does not have an alarm at the time of the alarm, but alarms when it is not. For bedside monitoring equipment, the central monitoring function can report faults and dispatch maintenance personnel to troubleshoot, thus avoiding serious problems.
Portable and body-worn monitoring devices present designers with a range of more challenging problems. One of the problems is that these two devices are the fastest growing markets, and the standard of interoperability has only recently become the focus of attention. For example, the Continua Health Alliance recently specified four main interoperable interfaces: USB, Bluetooth, Bluetooth Low Energy (BTLE) and ZigBee. What these four interface technologies have in common is that the monitoring device must be powered on and executed (ie, perform monitoring functions) to report faults through these interfaces, indicating that the device is working properly. When these devices are turned off, the monitor is often disconnected from the error message, increasing the difficulty of reducing or even finding any problems.
Portable and body-worn surveillance devices have another emerging challenge that is waterproof and dust-proof, easy to clean, and does not damage electronic components. Today's portable and body-worn surveillance devices are designed with an integral seal. In this case, adding connectors or adding functionality to the connector tends to increase the size, cost, or system complexity of the sensor.
Reading and writing related materials
Mastering readable and reliable traceable product information and understanding all product information from the production line to the working state is very useful for managing the execution of these assets (monitoring equipment). For a long time, equipment manufacturers have succinctly described the product's date of manufacture, revision, production line/factory, serial number and other product information on the label sticker, and then pasted these labels on related products. This type of information is quality control and Basic information required for device information traceability.
Today's systems require options, multiple sensor calibration constants, maintenance intervals, and more. Some systems also provide user-programmable "hotkeys" that allow users to set and lock these functions. Only equipment maintenance management requires so much information, so there is no need to say "check engine status indicator" for real-time data. The ability to record and instantly read error events can significantly reduce equipment maintenance costs and reduce maintenance time.
By connecting an electronic tag to each device via the I2C interface, medical staff can record and instantly read error events.
Automotive Connectors,Automotive Connector,Cable Wire Connectors,Cable Wire Connector
YUEQING WEIMAI ELECTRONICS CO.,LTD , https://www.weimaicarconn.com