Protecting Your Health with Digital Medical Equipment

Driven by the rapid development of the network, equipment digitization has become a trend. The digitalization of medical equipment will benefit people's health more efficiently.

Ⅰ. Background of Medical Industry Networking Needs

The rise in the adoption of Internet of Things (IoT) applications within the medical industry has led to an increasing number of medical devices that share real-time data via the Internet, thereby enhancing device reliability. Nevertheless, within the intricate networks of healthcare facilities, manufacturers continue to encounter challenges related to secure remote maintenance and diagnosis. This situation underscores the need for specialized network solutions tailored to the unique requirements of the healthcare sector.

Ⅱ. Specific Requirements of Medical Industry Networking

Reliable and Continuous Internet Connectivity

• Medical devices necessitate a stable and uninterrupted network connection to facilitate the real-time transmission of substantial data volumes and maintain the reliability of remote operations.
• Employing redundant design, automatic switching, and other advanced technologies can help ensure high availability of these connections.
• Additionally, sufficient network bandwidth is essential to support the simultaneous transmission of large data volumes from multiple medical devices.

Robust Data Security Mechanism

• Given the sensitive nature of medical data, strict security measures are imperative.
• Implementing technologies such as end-to-end encryption, authentication, and access control is vital for securing data transmission and storage.
• Furthermore, a comprehensive security management strategy should be established, encompassing data backup protocols, log auditing, incident response planning, and more.

Streamlined Centralized Management

• Due to the extensive deployment of medical devices, it is essential for manufacturers to implement centralized management of remote devices.
• Utilizing a cloud management platform can facilitate centralized control over remote configurations, software upgrades, and fault diagnostics.
• The platform should also offer an intuitive management interface and tools designed to simplify the centralized administration of large-scale device networks.

Ⅲ. InHand Networks Solutions for Digital Medical Equipment

Convenient Cellular Access

Various medical devices within the hospital, such as ultrasound machines, ventilators, and electrocardiographs, are connected to the IR315 industrial router via LAN or Wi-Fi. The IR315 then establishes a data connection with the telemedicine center through a high-speed cellular network, facilitating real-time transmission of equipment status data.

Secure and Reliable Data Transmission

The IR315 creates a secure data transmission tunnel using firewalls and VPN encryption, ensuring the security and integrity of data while mitigating the risk of network attacks. This protocol guarantees that medical diagnostic information is transmitted safely and reliably to the hospital, enabling timely remote maintenance and fault resolution.

Remote Efficient Management

The Device Manager offers a user-friendly interface for the centralized management of numerous decentralized IR315 networked terminals, along with out-of-band management for medical terminal devices. The platform includes features for remote configuration and batch upgrades, effectively addressing the challenges associated with managing network devices and maintaining control over on-site networks.

Ⅳ.Benefits of InHand Network Solutions

Enhanced Web Experience

The IR315 is engineered to provide high-speed networking capabilities characterized by substantial bandwidth and low latency. It accommodates both Standalone (SA) and Non-Standalone (NSA) configurations, offering a variety of network access options. This versatility positions the IR315 as an excellent solution for Internet of Things (IoT) applications across diverse scales, enabling the swift establishment of effective networks.

SA and NSA Definition

SA and NSA are the two modes of 5G network architecture.

SA (Standalone) : This is a completely independent 5G network architecture that does not rely on the existing 4G infrastructure. It offers the full 5G capabilities, including higher speeds, low latency, and higher network efficiency.

NSA (Non-Standalone) : This architecture relies on the existing 4G network to provide some control functions, while 5G is used for data transmission. This model allows for faster 5G deployments as it leverage existing 4G infrastructure.

Currently, the deployment of 5G base stations in many countries is primarily characterized by Non-Standalone (NSA) networking. However, Standalone (SA) networking is progressively gaining traction. NSA leverages existing 4G core networks to facilitate 5G coverage, making it more common during the initial deployment phase. As 5G networks continue to evolve, numerous countries and operators are increasingly shifting towards SA, which offers enhanced 5G performance and lower latency.

Robust Security Policies

The IR315 is equipped with multi-layered security protocols, incorporating features such as Virtual Private Network (VPN) functionality, firewall protection, and device permission management. Collectively, these measures are designed to protect sensitive data and critical service networks from potential threats and attacks, thereby ensuring a secure networking environment.

Streamlined Cloud Management

The IR315 is compatible with the Device Manager cloud management platform, allowing users to access a centralized system for monitoring and managing the performance of devices across numerous distributed locations. This capability enhances management efficiency, simplifies operations, and provides cost-effective solutions.

Ⅴ. InHand Networks Device------IR315

If you are interested in Router IR315, please click the below image to learn more.

Ⅵ. Other Related Topics of Digital Medical Equipment

What Are Examples of Networked Medical Devices?

• Remote Patient Monitors: Devices designed to track vital signs, including heart rate, blood pressure, and oxygen levels, and transmit this data to healthcare providers.
• Infusion Pumps: Networked devices that ensure accurate medication delivery and facilitate remote monitoring and adjustments.
• Wearable Health Devices: Items such as smartwatches that monitor physical activity, sleep patterns, and heart rate.
• Connected Imaging Systems: MRI and CT scanners that enable the sharing of images with healthcare professionals for remote analysis.
• Smart Beds: Hospital beds equipped to monitor patient movement and adjust settings to enhance comfort and safety.

What Is the Dominant Protocol for Data Transfer Between Medical Devices?

The primary protocol for data transfer between medical devices is commonly HL7 (Health Level Seven). HL7 offers a comprehensive framework for the exchange, integration, sharing, and retrieval of electronic health information. It is extensively utilized in healthcare environments to enhance communication among diverse medical devices and healthcare information systems.

Conclusion

Networking is essential for the digital integration of medical equipment. InHand Networks provides the cost-effective and high-performance Router IR315 to facilitate the digital networking of devices within the medical industry. For further information, please visit our official website. Should you have any questions regarding the product, do not hesitate to reach out to us.

Phone: +1 (703) 348-2988 (US) 010-84170010 (CN)
Email: support@inhandgo.com
Website: https://inhandgo.com/