Effect of Driving Frequency on Reduction of Radar Cross Section Due to Dielectric-Barrier-Discharge Plasma in Ku-Band

“…Assuming 684 GHz of collision frequency at 0.3 atm [8], the extracted plasma frequency is 240 Grad/s, which gives the best match between the measured and simulated RCS results. This corresponds to an electron density of 1.81 × 10 13 cm −3 .…”

“…The plasma characteristics generated from the DBD generator considerably vary depending on the frequency and voltage of the bias signal as well as the surrounding gas In the case of the proposed generator, the gap between the electrode and ground (target) was 4.572 mm, which is maintained by the dielectric rim between the two; thus, the breakdown voltage of the proposed plasma generator was approximately 8 kV peak-topeak at 0.3 atm according to Paschen's law [8,12]. Therefore, plasma was stably generated when a higher voltage was applied.…”

“…Assuming 684 GHz of collision frequency at 0.3 atm [8], the extracted plasma fre- Figure 7 shows the measured RCS of the 200 × 200 mm 2 copper plate and when the proposed DBD generator is attached to this plate. The figure also shows the changes in the RCS when the plasma is generated, with and without the dielectric rim.…”

“…For comparison, Figure 7 also shows the full-wave simulated results obtained thru CST [11]. Simulations are performed based on the Drude model in Equation ( 3), which is a popular model that describes its interaction between plasma and electromagnetic waves [8,9,12,15,16]. For comparison, Figure 7 also shows the full-wave simulated results obtained thru CST [11].…”

“…The real part of the plasma dielectric constant is 1 or less, and the imaginary part has a relatively large value such that the loss is higher than that of other materials. Therefore, extensive research has been conducted based on the suitability of plasma in detection technology [5][6][7][8][9].…”

Plasma Generator with Dielectric Rim and FSS Electrode for Enhanced RCS Reduction Effect

“…Assuming 684 GHz of collision frequency at 0.3 atm [8], the extracted plasma frequency is 240 Grad/s, which gives the best match between the measured and simulated RCS results. This corresponds to an electron density of 1.81 × 10 13 cm −3 .…”

“…The plasma characteristics generated from the DBD generator considerably vary depending on the frequency and voltage of the bias signal as well as the surrounding gas In the case of the proposed generator, the gap between the electrode and ground (target) was 4.572 mm, which is maintained by the dielectric rim between the two; thus, the breakdown voltage of the proposed plasma generator was approximately 8 kV peak-topeak at 0.3 atm according to Paschen's law [8,12]. Therefore, plasma was stably generated when a higher voltage was applied.…”

“…Assuming 684 GHz of collision frequency at 0.3 atm [8], the extracted plasma fre- Figure 7 shows the measured RCS of the 200 × 200 mm 2 copper plate and when the proposed DBD generator is attached to this plate. The figure also shows the changes in the RCS when the plasma is generated, with and without the dielectric rim.…”

“…For comparison, Figure 7 also shows the full-wave simulated results obtained thru CST [11]. Simulations are performed based on the Drude model in Equation ( 3), which is a popular model that describes its interaction between plasma and electromagnetic waves [8,9,12,15,16]. For comparison, Figure 7 also shows the full-wave simulated results obtained thru CST [11].…”

“…The real part of the plasma dielectric constant is 1 or less, and the imaginary part has a relatively large value such that the loss is higher than that of other materials. Therefore, extensive research has been conducted based on the suitability of plasma in detection technology [5][6][7][8][9].…”

Plasma Generator with Dielectric Rim and FSS Electrode for Enhanced RCS Reduction Effect

Measurement of re-entry plasma density using microwave reflectometer in laboratory

Design of a wideband and tunable radar absorber