List of coating design exapmles

Antireflection

• Broadband Antireflection Graded-Index Coating
• Growing an Antireflection Coating
• Broadband AR for a Cone of Light

Beamsplitter

• New Thin Film Polarizing Beamsplitter
• Immersed Wide-Angle Polarizer
• Immersed Wideband Nonpolarizing Beamsplitter
• Symmetric Immersed Beamsplitter
• Nonpolarizing Beamsplitter for OIC Contest

Reflector

• Extreme Ultraviolet Mirrors
• Dielectric Omnidirectional Reflector
• Broadband High-Reflection Coating at 50 Degrees
• Cold Mirror

Bandpass

• Wide Infrared Bandpass Filter
• Metal-Dielectric Dual Bandpass Filter
• Metal-Dielectric Bandpass Filter
• Family of WDM and DWDM Filters
• 8-Skip-0 WDM Filters
• Four-Wavelength Bandpass Filter
• Triple Bandpass Filter for OIC Contest

Miscellaneous

• Transparent Metal Coatings
• Fabry-Perot Interferometer Coating
• Dielectric Sunglasses
• Photopic Filter

A Family of WDM and DWDM Filters

Note: this page was written in 2000, when tools for designing WDM filters were limited. Now the TFCalc 3.5 and TFCalc/WDM software enable the user to design a wide variety of WDM and DWDM filters.

A number of people have asked for a sample WDM filter. This type of bandpass coating is used in the telecommunications industry to control the transmission of multiple laser lines (i.e., channels) through fiberoptic cables. WDM is the abbreviation for Wavelength Division Multiplexing. DWDM means Dense WDM; that is, the spacing between laser wavelengths is denser, allowing the fiber to transmit more information. These filters are usually designed for wavelengths near 1550 nm.

We will consider the following four generations of WDM filters

Spacing (GHz)   Spacing (nm)    Channels    Bandwidth (nm)
  400             3.2              8            0.8
  200             1.6             16            0.5
  100             0.8             32            0.2
   50             0.4             64            0.1

which shows the center-to-center spacing of the channels in frequency units and wavelength units. As you can see, the denser spacing allows many more channels. The table also shows that these filters must have an extremely narrow bandwidth. (For this type of filter, bandwidth is measured at 1 dB, which is approximately the 79.4% transmittance level.) To minimize the interference between channels, there is also a requirement to block the transmission of adjacent channels. This is typically 30 dB (i.e., 0.1%) at the position of the next channel.

We introduce the following family of designs:

  GLASS
  (HL)^N H          reflector
  2L                cavity
  (HL)^(2N+1) H     reflector
  2L                cavity
  (HL)^(2N+1) H     reflector
  2L                cavity
  (HL)^N H          reflector
  GLASS

where L is a low-index (1.434) material, H is a high-index (2.1) material, GLASS (index 1.52) is the incident and exit medium, and N is an integer parameter that we vary to obtain a series of designs. The designs work for other indices, but we use these indices in this example. All thicknesses are in quarter waves measured at 1550 nm. To the right of the design, we indicate how parts of the design operate as either reflectors or cavities. The interesting cases for WDM filters are N = 7, 8, 9, and 10, which yield designs having 95, 107, 119, and 131 layers.

The plot below shows the performance of the four designs. Note, interestingly, that for each coating in the series, the bandwidth is approximately halved — exactly what each new WDM generation requires.

This example illustrates one design family for WDM filters. There are many other possibilities. For instance, the bandwidth, the passband ripple, the slope, and the angular performance of filters can be changed by

• increasing the thickness of the cavities (e.g., to 4L, 6L, etc.),
• changing the powers N and 2N+1,
• changing some H and/or L layers in the reflectors to 3H and 3L,
• changing the indices of H and L, and
• using an intermediate index in addition to H and L.