access icon free Time-domain resonant characteristics between the disturbances and the RS422 communication signals in Tesla pulse driver, and analysis on the caused RS422 communication interference

The communication circuit network is widely employed for signal transmission in high-voltage pulse driver system, for commanding, controlling, measurement & communication. The electromagnetic compatibility of the communication circuit network mainly decides the stability and reliability of the high-voltage pulse driver system. Aiming at the electromagnetic interference (EMI) problems of the RS422 communication circuit in the Tesla pulse driver, the generated disturbance sources and characteristics from the Tesla pulse driver itself are analysed in five divided work stages, and two typical simplified EMI coupling modes for the communication circuit are also presented in this Letter. In the RS422 communication cable circuits between the subsystems of the pulse driver, the time-domain resonant characteristics of the communication signal and the conducting disturbances are analysed. The error and failure modes of the RS422 communication data caused by the full time-domain conducting interference are also revealed. Evaluation and calculation method for the time-domain resonant probability and the interference probability of the RS422 communication signals is also put forward. The communication interference probability is also calculated under different repetition work modes of the Tesla pulse driver. In view of the time-domain resonance phenomenon, some effective ways for time-domain resonance elimination and interference compression are put forward.

Inspec keywords: electromagnetic compatibility; electromagnetic interference; driver circuits; telecommunication cables; pulse circuits

Other keywords: electromagnetic interference problems; signal transmission; Tesla pulse driver; communication circuit network; interference compression; time-domain conducting interference; RS422 communication cable circuits; communication interference probability; communication circuit; EMI coupling modes; time-domain resonance phenomenon; RS422 communication signals; time-domain resonance elimination; RS422 communication data; time-domain resonant probability; time-domain resonant characteristics; communication signal; conducting disturbances; electromagnetic compatibility; high-voltage pulse driver system

Subjects: Signal processing and detection; Power electronics, supply and supervisory circuits; Pulse circuits; Transmission line links and equipment; Electromagnetic compatibility and interference

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