Raysync, a leading provider of high-performance file transfer solutions, has announced a strategic partnership with Red Hat, the world-renowned open-source software and solutions provider. This collaboration aims to revolutionize data management solutions and empower businesses with efficient, secure, and scalable file transfer capabilities. The certification from Red Hat is a testament to Raysync's dedication to maintaining the highest standards of compatibility and performance within the Red Hat Enterprise Linux ecosystem. It signifies that Raysync's Transfer Acceleration Software for Container meets the stringent criteria set by Red Hat, ensuring seamless integration and optimal performance for users. Background Unstructured data such as business documents, emails, images, research reports, legal regulations, various reports, and audio/video information have become the predominant form of enterprise data. As the volume of data grows exponentially, with IDC projecting global data to reach 175ZB by 2025, of which 80% will be unstructured, effective management and utilization of data assets become a paramount task for enterprises.  In response to this challenge, Raysync has developed the Raysync Transfer Acceleration Software for Container, a cutting-edge solution designed to address the limitations of traditional data transfer methods and provide a secure, efficient, and reliable file transfer platform for enterprises. Core Capabilities Proprietary High-Speed Transfer Protocol Raysync has developed its own high-speed Transfer protocol that automatically adjusts the Transfer speed to the optimal state regardless of network latency or packet loss conditions. Compared to TCP-based FTP and HTTP Transfer methods, this protocol can achieve speed improvements ranging from tens to hundreds of times. Disk I/O Read/Write Optimization The RayFile file processing engine, developed by Raysync, optimizes the reading and writing of data to achieve optimal Transfer speeds with minimal software overhead. This technology is effective in transferring both large and small files efficiently. Cluster Transfer Technology  Through distributed cluster technology, multiple servers can be combined into a logical Transfer service. This technology supports file synchronization while retaining metadata information such as file permissions and user groups. Security and Reliability The platform supports TLS encryption protocol, enabling users to encrypt files using self-signed or CA-issued certificates to ensure file security. It also includes features like data filtering and text-sensitive word monitoring. High Reliability and Modularity The platform is designed using a highly modular architecture with distributed and loosely-coupled components, ensuring high availability in case of hardware or software failures. Raysync Architecture Business Value The Raysync Transfer Acceleration Software for Container platform offers several key business advantages: Stability and Reliability Built on the Red Hat Enterprise Linux operating system, the platform provides quick, stable, and reliable file transfer services. Enhanced Data Management The solution offers efficient system support, including automated deployment and testing, to improve data management capabilities and utilization value. Security and Compliance Leveraging the security features of the Red Hat Enterprise Linux OS and implementing multiple encryption techniques, Raysync ensures secure and reliable file transfers. User Experience By utilizing Red Hat technology, Raysync offers robust technical support and services, enhancing user experience and satisfaction. Conclusion This partnership is poised to redefine how businesses handle data across the globe. As industries continue to generate and exchange vast amounts of data, the Raysync and Red Hat collaboration will play a pivotal role in ensuring that data can be moved efficiently, securely, and at the speed of business. Through this partnership, Raysync and Red Hat will jointly develop solutions tailored to meet the evolving needs of enterprises across various industries. By leveraging Red Hat's extensive network and Raysync's technical expertise, the partnership will introduce innovative products that enable businesses to securely transfer, synchronize, and manage their data in real-time. About Raysync Raysync specializes in providing high-performance data transfer solutions for enterprises, offering software that optimizes transfer efficiency, secures data, and enhances data management capabilities. With a focus on innovation and reliability, Raysync empowers businesses to overcome data transfer challenges and achieve seamless connectivity. Leveraging its proprietary Raysync Transfer engine, Raysync addresses cross-border, long-distance, and large file transfer challenges, significantly enhancing bandwidth efficiency, work efficiency, and user satisfaction. About Red Hat Red Hat is a world-leading enterprise open-source software solutions provider, offering stable, reliable, and high-performance Linux, hybrid cloud, container, and Kubernetes technologies. With strong community support, Red Hat assists clients in integrating existing and new IT applications, developing cloud-native applications, implementing standardized operations on leading operating systems, and achieving automation, security, and management in complex environments. Renowned for its top-notch support, training, and consulting services, Red Hat serves as a trusted advisor to Fortune 500 companies. As a collaborative partner of various cloud service providers, system integrators, application vendors, customers, and open-source communities, Red Hat is committed to preparing businesses to embrace a digital future.  

With the continuous development and popularization of the Internet, businesses and organizations are accumulating a vast amount and variety of data, stored across different servers, data centers, or cloud platforms, making it difficult to manage and sync effectively. In such a scenario, there is a need for a reliable, automated, and visually controllable solution that can provide real-time monitoring, management, and comprehensive analysis of data from different platforms. The technology solution of unified data synchronization has emerged in this context. Raysync high-speed large transfer solution provides a one-click distribution and transfer task for servers, offering an integrated data management and transfer solution. By syncing data from different platforms, building data sharing and exchange links, and managing data storage, it achieves unified syncing, control, management, and transmission of data. This effectively addresses the pain points and challenges faced by businesses and organizations in data management, enabling them to quickly, efficiently, and securely distribute and pull data, thereby improving data transfer efficiency and stability and ultimately enhancing business productivity.  1. Efficient Sync Task With Raysync Transfer Solutions, data packets or files can be distributed and synced to different data nodes. By utilizing an efficient wide area network distributed architecture, data is distributed to different nodes, ensuring efficient and stable task distribution. Additionally, Raysync employs precise intelligent task allocation algorithms that consider the nature of the task and server load conditions, allowing tasks to be assigned to the optimal nodes for efficient completion. 2. Rule-based Sync Task  Users can set task syncing rules based on the characteristics of the transfer tasks and their own requirements. By setting various types of tasks and syncing rules such as timed tasks and periodic tasks, users can achieve automated distribution and syncing of tasks. This allows users to focus more on core business issues in a centralized manner. 3. Real-time Transfer Status Monitoring Raysync Transfer provides real-time transfer status monitoring, allowing users to stay informed about the progress and status of their transfers. Through the management platform, users can view the latest status and progress of tasks, enabling them to make timely adjustments and effectively manage the entire data transfer process, reducing potential issues during transmission. 4. High-standard Data Security Guarantee Data security and stability are among the top concerns for enterprises during the data transfer process. Raysync adopts bank-grade AES-256 encryption technology, employs TLS encryption for secure transmission, supports national encryption standards, and implements features like breakpoint resumes, error retransfer, and multiple file checksums . These measures ensure the security and stability of data during transmission, alleviating concerns for enterprise managers. 5. Diversified Application Scenarios Raysync task distribution and synchronization can be widely applied in various scenarios, including internet IT, film and television production, genomics, semiconductor, finance, online gaming, and many other fields. It facilitates data collection and analysis in different regions, helping enterprises efficiently transmit and distribute data, saving time, effort, and costs, and enhancing data analysis efficiency. Let's go through the steps as follows to create a sync task together: - Go to the admin panel of Raysync and navigate to "Transfer Task" and then "Tasks List". - Click on 'Add' to create a new task. - Set the 'Task name' and select the transfer direction . - Select the 'Source path' and the specific Client nodes. - Set the 'Target Path' for the task. - Choose the 'Task frequency'. - Once you have filled in all the necessary details, click on "Save" to create the syncing task. - Now you have successfully created the sync task.   If you would like to learn more or need any assistance, please feel free to contact us. We also welcome you to apply for Raysync testing program. Thank you for your interest and support. We look forward to working together to further advance this tool.

In the film and television industry, the transfer and sharing of video files are essential tasks, especially during the production and post-production stages. Generally, a typical film workflow includes the following steps: Shooting Stage -> Data Compilation -> Editing Stage -> Color Grading Stage -> Visual Effects Stage -> Compositing Stage -> Distribution Stage 1. Shooting Stage: The production crew captures video footage, which is usually stored in intermediary storage devices like TF cards or hard drives. 2. Data Compilation: Various videos, audio, subtitles, and materials are compiled into a single data package for easier editing and production in later stages. 3. Editing Stage: Editors trim and combine the captured footage to create storylines and scenes. 4. Color Grading Stage: Colorists adjust the color and brightness parameters of the edited videos to achieve the desired visual aesthetics. 5. Visual Effects Stage: After color grading, the visual effects team adds effects to specific scenes to enhance and beautify the film. 6. Compositing Stage: Compositors merge the edited and enhanced scenes together to create the final complete film. 7. Distribution Stage: Once the film production is finished, it needs to be exported into a playable format and distributed for viewing and dissemination. Throughout the entire workflow mentioned above, the transfer and sharing of video files are essential in different stages. For example, during the editing and visual effects stages, it is necessary to share the captured footage and edited videos with the color grading and visual effects teams. In the compositing and distribution stages, the completed tasks from various teams need to be transferred for integration and release. In this process, slow transfer speeds or data leaks can cause delays in film production progress and even result in significant financial losses. Therefore, efficient and secure methods for video file transfer and sharing are crucial in the film and television industry workflow. Raysync Transfer provides a fast, stable, and secure file transfer and sharing solution that meets these requirements, improving the efficiency of film production and ensuring its security. Let's take a closer look together! 1. Online preview of video, image, and other design files By uploading the media files, users can directly preview the files online on the web page without the need to download them. This allows users to preview and select video files directly through Raysync, avoiding unnecessary time-consuming operations and improving efficiency.   2. File sharing File sharing is a method that allows others to access and download shared files through a shared link. In the Raysync system, users can upload video files to Raysync storage and generate a sharing link to share with the recipient. The recipient can simply access the link through a web browser or downloader to obtain the video file without downloading it to their local device. This method makes it easy to transfer video files to others without the need for local downloads. It is especially useful for transferring large video files as it only requires sharing the link. In terms of file sharing, multiple sharing options are supported. Users can choose the appropriate sharing method based on their specific needs, such as sharing public links or encrypted links. Additionally, the Raysync protocols provide the capability to set an expiration period for the file, ensuring greater security and control over the shared files.   3. High-speed transfer using the Raysync client The Raysync client enables high-speed transfer using the self-developed Raysync protocol, which is 100 times faster than FTP/HTTP. It can handle concurrent transfers of thousands of small files, achieving a bandwidth utilization rate of up to 96%. Even for team members located in different regions, it effectively reduces network latency, packet loss, and other performance issues, enabling efficient file collaboration. The client also supports AES-256 encryption for secure data transmission and multiple file verification mechanisms to prevent data leakage and ensure data integrity.   By employing these three methods, users can effortlessly transfer video files to others without wasting significant time and effort on file transfers. Therefore, utilizing Raysync for video file transfer is an incredibly efficient approach that caters to users' daily file transfer needs.

With the rapid development of cloud computing and artificial intelligence technologies, the application scope of cloud XR applications is becoming increasingly wide. However, during the promotion and popularization of cloud XR applications, the issue of large file transfer has gradually emerged. Due to the large size of high-definition images, models, videos, and other files, the transfer speed is slow, often requiring a long time to complete, which negatively affects the user experience. Solving this bottleneck problem is not only an important issue in the development of cloud XR applications but also a challenging problem that is not easily achievable in traditional scenarios. Therefore, large file transfer acceleration solutions have emerged to achieve low-latency, high-speed transfer, and file sharing. This article will introduce the role and significance of large file transfer acceleration solutions in empowering the development of cloud XR applications. Let us explore together. Challenges of Cloud XR Applications 1. Cloud XR applications require low-latency, high-bandwidth, and efficient large file transfer. 2. Cloud XR applications need to ensure transfer quality and stability in unstable network environments. 3. Cloud XR applications require high-speed file transfer and sharing between different devices and operating systems. Large File Transfer Acceleration Solutions 1. UDP-based optimization for high-speed transfer greatly improves file transfer speed and efficiency. Raysync is a software-based large file transfer solution provider, dedicated to meeting the needs of high-speed large data transfers with high security regardless of file size, distance or network conditions, providing enterprises with fast, safe, stable, cost-efficient, and convenient large file transfer services. 2. Support for functions such as breakpoint resume, instant transfer, and folder transfer, providing a more convenient user experience. 3. Automatic adaptive optimization of the network environment to achieve efficiency and stability while saving bandwidth and costs. 4. Provide data encryption and secure data transfer authentication to ensure data security. Roles of Large File Transfer Acceleration Solutions in Cloud XR Applications 1. Enhancing image and model transfer efficiency In the context of cloud XR applications, efficient file transfer can greatly enhance the user experience, allowing users to better enjoy the immersion brought by 3D scenes. The large file transfer acceleration solutions enable quick transfer of large images, models, and other data files, reducing transfer time and significantly improving the user experience. Especially in business scenarios such as VR exhibition halls, providing customers with a good network quality experience can encourage them to explore and discover their needs more deeply, bringing more effective marketing opportunities for enterprises. 2. Enhancing user interactive experience The interactive experience of cloud XR applications plays a crucial role in user experience. Interactive experiences mainly involve users' gestures, voice, visual perception, and body movements. Users interact with the application through gestures, voice, and other means, and the application responds to the user's actions explicitly or implicitly, providing a more realistic and immersive experience. Therefore, higher requirements are placed on network latency and bandwidth. By using large file transfer acceleration solutions, transfer speed can be improved, latency can be reduced, and a smoother and higher-quality user experience can be achieved. 3. Enabling fast deployment and promotion of cloud XR applications Large file transfer acceleration solutions enable fast and convenient deployment and promotion, providing strong support for business expansion. With this technology solution, the rapid construction and deployment of cloud XR applications such as VR exhibition halls and AR applications allow enterprises to quickly obtain critical information and data. Especially for the transfer of high-quality data with insufficient network bandwidth, large file transfer acceleration solutions can successfully upload data, solving the problem of transferring files on a large scale. 4. Supporting file sharing among multiple devices and systems In the face of the challenges brought by the diversity of devices and systems to cloud XR applications, large file transfer acceleration solutions provide comprehensive support, enabling timely recognition of various compatibility issues and offering multi-platform support. Particularly in collaborative scenarios, only one client software is needed to share files among different devices and systems, greatly facilitating data transfer within the enterprise and across multiple parties. Large file transfer acceleration solutions play an extremely important role in empowering the development of cloud XR applications. By optimizing data transfer, they greatly enhance user experience, improve the efficiency and quality of file transfer, and enable fast construction and deployment, further increasing enterprise productivity and business marketing capabilities, providing strong technical support for the popularization and promotion of cloud XR applications. With the advent of the big data era, the application of large file transfer acceleration solutions will become more extensive and profound, bringing more added value to enterprises and contributing to the further development and growth of the industry.

In today's digital age, data transfer is an inevitable task in various industries. The speed of data transfer can determine the efficiency and cost of data processing. Accelerating data transfer has become a focal point for many businesses and organizations. This article will introduce some technologies used to accelerate data transfer to help enterprises address this challenge. 1. Network Acceleration Technologies Network acceleration technologies primarily improve transfer speed by optimizing network protocols and improving transfer methods. TCP acceleration and UDP acceleration are common ways to optimize network protocols. TCP, or transfer Control Protocol, has complex mechanisms and includes some important instructions. When transmitting files or data, since the files are divided into multiple packets, and each packet carries important instructions, complete recovery and assembly are required, along with retransmitting data packets that the other party has not received. This process often results in slow transfer speeds. To optimize transfer efficiency, TCP acceleration technologies such as window size and flow control can be used. UDP, or User Datagram Protocol, achieves better transfer speeds compared to TCP by sending data packets to the destination as soon as possible. Additionally, network load balancing can also achieve network acceleration by distributing the load across multiple servers, thereby improving data transfer speed. Raysync is a software-based large file transfer solution provider, dedicated to meeting the needs of high-speed large data transfers with high security regardless of file size, distance or network conditions, providing enterprises with fast, safe, stable, cost-efficient, and convenient large file transfer services. 2. Storage Acceleration Technologies Storage acceleration technologies improve storage transfer speeds through optimization of data read/write, data compression, data caching, etc. SSD, RAID, and hardware acceleration are three commonly used storage acceleration technologies. SSD, or Solid State Drive, offers higher read/write speeds, lower latency, and longer lifespan compared to traditional hard drives. Therefore, using SSD can improve file transfer speed in handling large files. RAID, or Redundant Array of Independent Disks, is a disk array technology that combines multiple disks into a single logical disk for data backup and quick access. RAID technology can combine multiple hard disks into a logical disk, thus achieving data redundancy and improving data transfer speed and reliability. Hardware acceleration provides acceleration features at the hardware level, such as using GPUs to accelerate data processing or improving data transfer speed through techniques like high-speed caching and data prefetching. 3. Striping Technologies Striping technology involves storing file data in blocks and then transferring them between multiple devices, thereby quickly improving transfer speed. Implementation methods include cluster striping and cross-device striping. These techniques essentially divide files into blocks and simultaneously transmit them through multiple devices, thereby enhancing data transfer speed and efficiency. In cluster striping, the size of data blocks varies to adapt to different application scenarios. Cross-device striping involves dividing file data into multiple stripes and assigning them to different devices for storage, thus improving data access speed and efficiency. 4. Aggregation Linking Technology Aggregation linking technology combines multiple network links to improve transfer speed. Link aggregation technology can aggregate multiple network links and different network protocols to achieve multi-link concurrent transfer. Additionally, aggregation linking can optimize transfer protocols, compress data, reduce retransfer, etc., to improve transfer speed and optimize data transfer efficiency. 5. Compression Technology Compression technology aims to improve data transfer speed and efficiency by reducing data size. Common compression techniques include Gzip and LZ4. Gzip is a streaming compression technique known for its high compression ratio and small data volume during transfer. It also enables encryption during transfer to ensure data security. LZ4 is a real-time compression technique suitable for compressing infinite data streams, such as network transfers or disk files. Using compression technology reduces data transfer time and space consumption, thereby improving data transfer speed and efficiency. 6. Encryption Technology While encryption technology does not have the goal of improving transfer speed, it can enhance data security during transfer and, in some cases, even improve transfer speed. For example, when using SSL/TLS protocols for data transfer, encryption algorithms and public-private key encryption protect data security. This encryption method can also reduce network interception, decrease data transfer latency, and improve data transfer efficiency. 7. Distributed Transfer Technology Distributed transfer technology improves transfer speed and reliability by dispersing data transfer among multiple nodes. For example, the BitTorrent protocol is a distributed file transfer protocol that divides files into multiple small pieces and distributes them among multiple nodes for block-by-block transfer, thereby accelerating file transfer speed. Distributed transfer technology can also enhance data transfer efficiency through optimization of data caching, data backup, etc. 8. Content Delivery Network  Technology CDN technology utilizes multiple distributed servers to store and transmit data, selecting appropriate servers based on the principle of proximity to users, thereby improving data transfer speed and reliability. CDN technology typically includes acceleration nodes, response nodes, CNAME, DNS load balancing, and other technologies. Servers can be placed in different geographic locations to cache and distribute common resources, improving data transfer efficiency. Using these technologies in the data transfer process can significantly improve transfer speed and quality, avoid issues such as data transfer delays and network congestion, and help reduce network bandwidth and CPU consumption. In today's era of the Internet and cloud computing services, data transfer speed is increasingly important, and technologies such as accelerating data transfer have become indispensable.

What is UDP protocol? UDP, User Datagram Protocol, is a connectionless transport layer protocol and part of the TCP/IP protocol suite. UDP is known for its high transfer efficiency and is suitable for data transfer scenarios with high real-time requirements. Let's see what the UDP protocol is in terms of how it works, advantages, use cases, and pros and cons. How does UDP work? UDP is a connectionless protocol, so it does not require establishing a connection like TCP. UDP datagrams do not undergo serialization, packaging, and unpackaging processes like TCP packets, and it does not provide data guarantee mechanisms during data transfer. UDP's main responsibility is to deliver data to the destination endpoint without confirming whether it has been received correctly. Therefore, UDP can be used for fast data transfer with high real-time requirements. The main features of UDP 1. Simple and Fast: As UDP does not require connection establishment and maintenance, data transfer speed is very fast. 2. Small Header Overhead: UDP headers are only 8 bytes compared to TCP's 20 bytes, saving bandwidth. 3. Multicast and Broadcast: UDP supports multicasting and broadcasting, making it more efficient to broadcast to multiple nodes. 4. No Congestion Control: UDP does not provide guarantees for data packet integrity and does not support flow control, congestion control, and similar mechanisms. Therefore, in situations where network quality is less than ideal, UDP transfer may result in data loss or duplication. In summary, UDP is suitable for applications that prioritize fast transfer and real-time requirements over guaranteed delivery and reliability of data. Use cases of UDP 1. Audio and Video Communication: UDP protocol is suitable for real-time audio and video communication applications such as IP telephony and video conferencing. 2. Multiplayer Games: UDP protocol is also suitable for data transfer in multiplayer online gaming, such as Dota 2 and League of Legends. 3. DNS Protocol: Domain Name System uses UDP protocol for domain name resolution, allowing for quick response when multiple clients access the DNS server simultaneously. 4. Broadcasting: UDP protocol is suitable for transmitting data to multiple nodes through broadcasting. Pros: 1. Low Latency: UDP protocol is more suitable for scenarios that require fast data transfer compared to TCP protocol. For example, video conferencing and real-time monitoring applications require minimal data transfer latency to prevent video stuttering and excessive delays. UDP protocol effectively minimizes latency. 2. Support for Broadcasting and Multicasting: UDP protocol supports broadcasting and multicasting, making it widely applicable for data transfer among multiple devices or clients. 3. Low Overhead: UDP protocol has a small header of only 8 bytes and does not require establishing a connection. Therefore, it has minimal overhead during data transfer, leading to more efficient data transfer. 4. Ease of Implementation: Compared to TCP protocol, UDP protocol generates significantly less overhead. As a result, it is easier to implement compared to TCP protocol. Cons: 1. Unreliable: UDP protocol does not provide guaranteed packet integrity and does not support mechanisms such as flow control and congestion control. Therefore, in cases with poor network quality, data transmitted through UDP protocol may be lost or duplicated. 2. Poor Security: UDP protocol lacks encryption and authentication mechanisms, making it vulnerable to attacks by hackers. What is UDP-based data transfer protocol? The Raysync high-speed file transfer protocol is a core technology created by Raysync based on the UDP data transfer protocol. To address the limitations of UDP protocol, Raysync Protocol optimizes upon UDP to enhance the reliability, stability, and overall user experience during data transfer. 1. Congestion Detection and Handling: Raysync Protocol's congestion detection algorithm collects background transfer information along the path. It accurately determines the congestion situation based on the transfer speed, neither overly conservative nor overly aggressive, effectively utilizing path bandwidth. 2. Packet Loss Detection and Recovery Mechanism: Raysync Protocol introduces a new ACK data algorithm that accurately detects packet loss and initiates data retransfer promptly, without relying on cumulative acknowledgments or ACK timeout timers. This greatly improves transfer speed and real-time data transfer. 3. Packet Fragmentation and Reassembly: Raysync Protocol efficiently handles packet fragmentation and reassembly, supporting data stream optimization and protocol conversion. 4. transfer Encryption and Authentication: Raysync Protocol employs bank-level AES-256 encryption and TLS encryption during transfer, supports national cryptographic standards, and implements multiple file verification methods . Additionally, Raysync Protocol utilizes login 2FA authentication and permission settings, ensuring stricter access control. How does Raysync Protocol automatically switch between UDP and TCP in transfer? Raysync Protocol can dynamically and intelligently switch between UDP and TCP protocols based on the network conditions for data transfer. When the network quality is good, Raysync automatically selects TCP protocol for transfer to guarantee data stability and reliability. When the network quality is poor, Raysync automatically switches to UDP protocol to achieve lower latency and higher transfer speed. Through this dynamic and intelligent protocol-switching mechanism, Raysync Protocol can adapt to the actual network conditions, automatically selecting the optimal data transfer method to enhance user experience and data transfer efficiency. Moreover, due to the distinct characteristics of TCP and UDP protocols, Raysync's intelligent switching allows it to adapt to different business scenarios and requirements, improving its flexibility and applicability.

Remote data storage on cloud-based systems has become increasingly significant in recent years with the growth of cloud computing. Cloud storage is a type of cloud computing system that prioritizes data storage and management, providing a new model for storing data and information. However, the same data can be accessed and retrieved from anywhere in the world, which also means that there are potential security risks associated with cloud storage. In the event of a security breach in cloud storage, stored data may be leaked, posing a significant challenge to protecting the security of cloud storage data. To ensure the security of cloud storage data and prevent potential issues like data leakage, cracking, and eavesdropping, Raysync's Secure File Transfer Service has implemented a series of security control measures that enhance data communication when connecting to cloud resources and calling APIs. These measures include: 1. Implementing AES-256 encryption technology at the net banking level. 2. Utilizing SSL encryption during the transfer process. 3. Applying access rights and OS rights settings to achieve stricter access control over cloud resources. To experience the free version, you can apply for a free trial of Raysync SMB or Raysync Enterprise. For server installation and deployment, please refer to our Support Center or contact us.  After successfully deploying the Raysync system, access the admin portal and select your cloud object storage. Enter your cloud storage bucket, access the private key, and key information, and the Raysync service will automatically encrypt the cloud storage key information using AES-256. Utilizing SSL encryption during the transfer process. Control users' access and permissions for reading and writing cloud storage data. After configuration, the system ensures that data transfer is encrypted, thereby guaranteeing the security and privacy of any data transferred to the cloud storage bucket.

Currently, most large file transfer systems only support single storage, which cannot meet the diverse needs of businesses as storage types become more varied and complex, and business requirements become more complicated. To achieve high flexibility in placing different types of storage on the same server, Raysync adopts virtual path method to uniformly manage different object storage, paths, and network disks, allowing for the addition and deletion of storage and the upload or download of files from storage at any time. Let's take a closer look at how this is achieved. In the server backend, you can add the storage information you want to access, including the storage ID, actual path, account name, and password. With this storage information, the server can connect to the storage and perform operations on its files. Raysync supports local storage, Alibaba Cloud, Amazon, Google Cloud, Azure Blob, and other S3-compatible object storage. Set the logical root path of the server to "/". In the server backend, add a virtual directory for the users, starting with the server's logical root path "/" and then adding the desired path, for example, "/aws". At the same time, bind a storage ID to this virtual path. To uniformly manage various object storages, paths, and cloud drives, it is necessary to create multiple virtual directories. When a user client accesses a virtual directory, the server returns all the virtual paths under the logical root path. For example, it returns "/aws". When the user client continues browsing "/aws", the server receives the request and looks up "/aws" in the virtual path list to get the bound storage ID. Then, it retrieves the storage information by using the storage ID and connects to the storage to traverse the actual path of the storage and obtain the file information under the actual path, such as "/aws/a". At the same time, it looks up all virtual paths under "/aws" in the virtual path list, such as "/aws/virtual path". Finally, it returns the obtained file information and virtual paths to the client. After receiving the browsing results, the user client can begin to manage, add, and delete files, as well as upload and download files between different storage locations.