Detail publikace

Few issues when measuring a high-g-shock

KUNZ, J.

Originální název

Few issues when measuring a high-g-shock

Anglický název

Few issues when measuring a high-g-shock

Jazyk

en

Originální abstrakt

This paper deals with effects which cause differences between real and measured mechanical shock, namely a high-pass filtering caused by a piezoelectric sensor and a charge amplifier and a resonance ripple caused by a piezoelectric sensor. The first effect can be suppressed by properly selected filtration which fits the application's requirements. To suppress the second effect the sensor's model needs to be found. In previous work this was done by two-sensor method, now the frequencies are estimated from the electrical parameters of the sensor. A 2-DOF model is used as it suits better for high-g-shocks. The method is able to suppress some ripple effects in the shock shape.

Anglický abstrakt

This paper deals with effects which cause differences between real and measured mechanical shock, namely a high-pass filtering caused by a piezoelectric sensor and a charge amplifier and a resonance ripple caused by a piezoelectric sensor. The first effect can be suppressed by properly selected filtration which fits the application's requirements. To suppress the second effect the sensor's model needs to be found. In previous work this was done by two-sensor method, now the frequencies are estimated from the electrical parameters of the sensor. A 2-DOF model is used as it suits better for high-g-shocks. The method is able to suppress some ripple effects in the shock shape.

Dokumenty

BibTex


@inproceedings{BUT157045,
  author="Jan {Kunz}",
  title="Few issues when measuring a high-g-shock",
  annote="This paper deals with effects which cause differences between real and measured mechanical shock, namely a high-pass filtering caused by a piezoelectric sensor and a charge amplifier and a resonance ripple caused by a piezoelectric sensor. The first effect can be suppressed by properly selected filtration which fits the application's requirements. To suppress the second effect the sensor's model needs to be found. In previous work this was done by two-sensor method, now the frequencies are estimated from the electrical parameters of the sensor. A 2-DOF model is used as it suits better for high-g-shocks. The method is able to suppress some ripple effects in the shock shape.",
  booktitle="Proceedings of the 25 th  Conference STUDENT EEICT 2019",
  chapter="157045",
  howpublished="electronic, physical medium",
  year="2019",
  month="april",
  pages="601--605",
  type="conference paper"
}