DWDM Wavelengths Chart
Introduction:
DWDM, which stands for Dense Wavelength Division Multiplexing, is a technology used in optical communication networks to increase the transmission capacity over a single optical fiber. It achieves this by simultaneously transmitting multiple optical signals of different wavelengths on the same fiber. To effectively use DWDM technology, it is important to understand the wavelengths used and their corresponding applications. This article provides a comprehensive DWDM wavelengths chart to facilitate a better understanding of this technology.
DWDM Wavelengths Chart:
Level 1: C-Band (Conventional Band)
– Wavelength Range: 1530nm to 1565nm
– Channel Spacing: 100GHz
– Applications: Long-haul transmission, backbone networks, metro networks
Level 2: L-Band (Extended Band)
– Wavelength Range: 1570nm to 1610nm
– Channel Spacing: 50GHz
– Applications: Dense urban areas, metropolitan networks
Level 3: S-Band (Short Band)
– Wavelength Range: 1460nm to 1530nm
– Channel Spacing: 100GHz
– Applications: Amplified CATV, local access networks
Level 4: U-Band (Ultra-Band)
– Wavelength Range: 1625nm to 1675nm
– Channel Spacing: 50GHz
– Applications: Long-haul DWDM spans
Level 5: E-Band (Extended Band)
– Wavelength Range: 1360nm to 1460nm
– Channel Spacing: 100GHz
– Applications: Amplified CATV, ultra-long-haul transmission
Level 6: Lx-Band (L-extended Band)
– Wavelength Range: 1270nm to 1360nm
– Channel Spacing: 100GHz
– Applications: Access networks, PON (Passive Optical Network)
Level 7: Ux-Band (U-extended Band)
– Wavelength Range: 1675nm to 1850nm
– Channel Spacing: 50GHz
– Applications: Long-haul, ultra-long-haul transmission, submarine networks
Conclusion:
Understanding the different levels and corresponding wavelengths used in DWDM technology is crucial for the successful deployment and operation of optical communication networks. This article presented a comprehensive DWDM wavelengths chart, outlining the wavelength ranges, channel spacing, and applications for each level. By utilizing the appropriate wavelengths, network operators can maximize the transmission capacity and efficiency of their optical fiber networks.
