Abstract
The designs of highly scalable intelligent sensory application—Ethernet-based communication architectures—are moving toward the integration of a fault recovery and fault-detection algorithm on the automotive industry. In particular, each port on the same network interface card design is required to provide highly scalable and low-latency communication. In this article, we present a study of intelligent sensory application for the Ethernet-based communication architecture and performance of multi-port configuration which is mainly used in safety-enhanced application such as automotive, military, finance, and aerospace, in other words, safety-critical applications. Our contributions and observations on the highly scalable intelligent behavior: (1) proposed network interface card board design scheme and architecture with multi-port configuration are a stable network configuration; (2) timing matrix is defined for fault detection and recovery time; (3) experimental and related verification methods by cyclic redundancy check between client–server and testing platform provide comparable results to each port configurations; and (4) application program interface–level algorithm is defined to make network interface card ready for fault detection.
Highlights
Intelligent sensory application for fault-tolerant system guarantees availability and reliability in the network connections
We present a technical aspect of data flow with port configuration which will be available in various platforms, such as supercomputers and cloud computing system
We present that a design of highly scalable intelligent sensory application which included Ethernet-based communication architectures, moving toward safety-critical application
Summary
Intelligent sensory application for fault-tolerant system guarantees availability and reliability in the network connections. Section ‘‘Algorithm’’ presents that hardware requirements for developing a dual-port fault-tolerant network interface card (DP-FT-NIC) for data speed up to 1 Gbps. The average time of fault time (i.e. the delay time for disconnect network) was 30 ms, and the time of recovery from detection error was 16 ms This system can provide higher reliable service in runtime with required less 50 ms at once fault. High-performance analog-to-digital converter (A/D) and digital-toanalog converter (D/A) are needed to detect the cable faults using the TDR This diagram is a specific knowledge required to multi-port configuration and large-scale data ingestion for intelligent sensory system.
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