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2024-04-15JST10:56:51 LoveLove
2024-04-15JST10:54:20 ShirakuraShirakura
2024-04-15JST10:52:34 Power-line-communication(PLC) systems use high-voltage cables in a frequency range up to 30 MHz. Since the cacles are not designed for this duty.there can be significant signal attenuation abd distortion.We have computed the propagation characteristics of a typical PLC signal along a sigle—core cable having two, 3-mm thicksemiconducting layers,using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity δ. With δ=10^-3S/m, attenuation is cause by radial charging and discharing of the semiconducting layers. Axial current propagation along the layers dominates losses at δ=10^3S/m.Power-line-communication(PLC) systems use high-voltage cables in a frequency range up to 30 MHz. Since the cacles are not designed for this duty.there can be significant signal attenuation abd distortion.We have computed the propagation characteristics of a typical PLC signal along a sigle—core cable having two, 3-mm thicksemiconducting layers,using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity δ. With δ=10^-3S/m, attenuation is cause by radial charging and discharing of the semiconducting layers. Axial current propagation along the layers dominates losses at δ=10^3S/m.
2024-04-15JST10:44:07 We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two, 3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method.We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two, 3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method.
2024-04-15JST10:37:40 AyunaAyuna
2024-04-15JST10:37:26 ayunaayuna
2024-04-15JST10:35:11 yorosikuyorosiku
2024-04-15JST10:34:07 Power-line-communication (PLC) systems use high-voltage cables in a frequency range up to 30 MHz Since the cables are not designed for this duty, there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a signal-core cable having two, 3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity σ. With σ=10^-3S/m. attenuation is caused by radial charging and discharging of the semiconducting layers. Axial current propagation along the layers dominates losses at σ=10^3S/m.Power-line-communication (PLC) systems use high-voltage cables in a frequency range up to 30 MHz Since the cables are not designed for this duty, there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a signal-core cable having two, 3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity σ. With σ=10^-3S/m. attenuation is caused by radial charging and discharging of the semiconducting layers. Axial current propagation along the layers dominates losses at σ=10^3S/m.
2024-04-15JST10:31:00 sakurasakura
2024-04-15JST10:30:56 this duty, there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two, 3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity o. With o=10-3 S/m, attenuation is caused by radial charging and discharging of the semiconducting layers. this duty, there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two, 3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity o. With o=10-3 S/m, attenuation is caused by radial charging and discharging of the semiconducting layers.
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2024-04-15JST10:30:00 forfor
2024-04-15JST10:29:16 Since the cables are not designed for this duty, there can be significant signal attenuation and distortion.Since the cables are not designed for this duty, there can be significant signal attenuation and distortion.
2024-04-15JST10:28:42 To PeaceTo Peace
2024-04-15JST10:28:37 NatuneNatune
2024-04-15JST10:28:23 Power line communication (PLC) systems use high-voltage cables in a frequency range up to 30 MHz . Since the cables are not designed for this duty , there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two,3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity . With σ=10^-3 S/m, attenuation is caused by radial charging and discharging of the semiconducting layers. Axial current propagation along the layers dominates losses at σ=30^3 S/m.Power line communication (PLC) systems use high-voltage cables in a frequency range up to 30 MHz . Since the cables are not designed for this duty , there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two,3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity . With σ=10^-3 S/m, attenuation is caused by radial charging and discharging of the semiconducting layers. Axial current propagation along the layers dominates losses at σ=30^3 S/m.
2024-04-15JST10:28:14 Power line communication (PLC) systems use high-voltage cables in a frequency range up to 30 MHz . Since the cables are not designed for this duty , there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two,3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity . With σ=10^-3 S/m, attenuation is caused by radial charging and discharging of the semiconducting layers. Axial current propagation along the layers dominates losses at σ=30^3 S/m.Power line communication (PLC) systems use high-voltage cables in a frequency range up to 30 MHz . Since the cables are not designed for this duty , there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two,3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity . With σ=10^-3 S/m, attenuation is caused by radial charging and discharging of the semiconducting layers. Axial current propagation along the layers dominates losses at σ=30^3 S/m.
2024-04-15JST10:27:51 To peaceTo peace
2024-04-15JST10:27:48 Power line communication (PLC) systems use high-voltage cables in a frequency range up to 30 MHz . Since the cables are not designed for this duty , there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two,3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity . With σ=10^-3 S/m, attenuation is caused by radial charging and discharging of the semiconducting layers. Axial current propagation along the layers dominates losses at σ=30^3 S/m.Power line communication (PLC) systems use high-voltage cables in a frequency range up to 30 MHz . Since the cables are not designed for this duty , there can be significant signal attenuation and distortion. We have computed the propagation characteristics of a typical PLC signal along a single-core cable having two,3-mm thick semiconducting layers, using the finite-difference time-domain (FDTD) method. The PLC signal suffers significant attenuation for two different values of layer conductivity . With σ=10^-3 S/m, attenuation is caused by radial charging and discharging of the semiconducting layers. Axial current propagation along the layers dominates losses at σ=30^3 S/m.
2024-04-15JST10:27:21 sincesince
2024-04-15JST10:26:48 sincesince
2024-04-15JST10:26:41 to peaceto peace
2024-04-15JST10:26:24 NatsuneNatsune
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2024-04-15JST10:24:04 MatumotoMatumoto
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2024-04-15JST10:02:37 Mitsuki KodaMitsuki Koda
2024-04-15JST09:59:13 InoriInori
2024-04-15JST09:50:39 KantaKanta
2024-04-15JST09:48:47 lovelove
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2024-04-15JST09:27:36 table tennistable tennis
2024-04-15JST09:26:29 Always Be Yourself!Always Be Yourself!
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2024-04-15JST09:11:48 AyakaAyaka
2024-04-15JST09:07:17 S.MatsukizonoS.Matsukizono

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