It has become very important to study the lightning surges that flow into telecommunications equipment because of the increased use of circuits susceptible to excess voltage. This paper reports for the first time simultaneous measurements of distributed lightning current at many positions in a mountain-top radio relay station caused by natural direct lightning strikes. More than 90% of the direct lightning current flowed from the lightning rod to the ground through building structural components such as antenna tower legs, waveguides, and so on, with the high frequency components of the lightning current tending to flow into the outside parts of those structural components. And then, 25 to 43 % of the lightning current flowed out again to outside telecommunications cables and power lines because the lightning current raised the station's ground potential. Based on these measurements, to help predict lightning current which is dangerous to telecommunications equipment, lightning current occurrence probabilities at the waveguide and cables were estimated by analyzing the distribution ratios between the current in those components.

Lightning surge protection semiconductor devices have been developed for subscriber telecommunication equipment that utilize transient thermal and low energy dissipation designs to improve surge-handling capability. A fabricated eight-cell device based on transient thermal design and a four-cell device with a thin substrate based on low energy dissipation design have a 1.83 and 1.80 times higher surge-handling capability, respectively, than a conventional device for lightning surge current waveforms of (1.5/30) µs.

It has become very important to study the lightning surges that were induced in subscriber telecommunication equipment because of the increase of susceptible circuits to the over voltage. The test generator is desire to be developed evaluating the resistibility of equipments against lightning surges. This paper proposes a new lightning-test method for subscriber telecommunication equipment. The waveform of the test generator simulates that of the induced lightning surge voltage caused by a nearby return stroke. The output impedance of the surge generator is determined to match the common-mode impedance of telecommunication lines. The damaged condition of circuit parts and the trouble occurrence rate estimated by using this method agree well with actual observations.