Traffic engineering and path planning
Through traffic engineering and path planning, deterministic networks can avoid network congestion and ensure that the transmission path of data in the network is optimal. Traffic engineering technology ensures optimal allocation of network resources through intelligent traffic control and routing selection, thereby improving network performance. Path planning is responsible for finding the shortest and most reliable data transmission path.
The shortest path still causes congestion
As shown in the above figure, initially based on the Shortest Path First (SPF) protocol, the traffic selects the shortest path (A-C-E) for data transmission. However, when multiple traffic flows choose the same path, congestion may occur, and when the shortest path is congested, the longer path A-B-D-E may be the better route. That's why sometimes we need to deviate from the SPF principle and adopt more complex traffic engineering strategies. Through methods such as traffic shaping, traffic supervision, and routing control, we can optimize the path selection of network traffic, avoid or reduce congestion, and improve the reliability and performance of the network. Simply put, the goal of traffic engineering is to ensure that network traffic can be reasonably allocated to different paths based on its characteristics (such as priority, QoS requirements, etc.), thereby avoiding network congestion and improving network resource utilization.
Hard real-time communication mechanism
Hard real-time communication mechanism is an important technology for achieving key data transmission in deterministic networks. For some applications that require precise control of latency, it ensures that data transmission is completed within the predetermined time. This requires implementing real-time scheduling mechanisms in the network to ensure timely transmission of real-time data packets.
Time aware shaper (IEEE 802.1Qbv) is a technology used to implement hard real-time communication mechanisms. Its main function is to identify priorities on Ethernet frames and assign them to priority based VLAN Tags. It controls queue traffic by defining a schedule, where each queue has a time period that defines the sending window for data frames in the queue. When a data frame reaches the queue, the time aware shaper schedules it based on its priority and schedule to ensure that key data frames are sent within the predetermined time.