Difference between revisions of "Rainbow"
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== Meeting Notes == | == Meeting Notes == | ||
| − | [[Media:2013-7-16_-_Processing_Update_2_1micron.pptx]] | + | * [[Media:2013_06-26_Stanton_Rainbow_2.1um_Directional_Coupler.pptx]] |
| + | * [[Media:2013_07-02_Stanton_Rainbow_Material_Losses_and_Waveguide_Proposals.pptx]] | ||
| + | * [[Media:2013_07-16_Stanton_Rainbow_Waveguide_Designs.pptx]] | ||
| + | * [[Media:2013-7-16_-_Processing_Update_2_1micron.pptx]] | ||
== Processing == | == Processing == | ||
Latest revision as of 11:21, 16 July 2013
Overview[edit]
Rainbow aims to produce a compact single chip with no free-space optics that emits very high power into a near-diffraction-limited beam covering all spectral bands of interest. The goal within three years is to develop a hybrid silicon chip that emits > 12 W into a high-quality beam (defined here as M2 < 3) that combines three bands: the near infrared (NIR), shortwave infrared (SWIR), and midwave infrared (MWIR, both Band II and Band IVB). We will further develop a roadmap and design the architecture for a single chip that combines all 6 bands, i.e., those specified above plus ultraviolet (UV), visible (VIS), MWIR Band IVA, and longwave infrared (LWIR). This 6-band chip is ultimately projected to emit more than 100 W of total power into a high-quality beam. Each diode will be controlled independently, and coupled into a low-loss waveguide that combines the 3 spectral bands.
Simulations[edit]
Meeting Notes[edit]
- Media:2013_06-26_Stanton_Rainbow_2.1um_Directional_Coupler.pptx
- Media:2013_07-02_Stanton_Rainbow_Material_Losses_and_Waveguide_Proposals.pptx
- Media:2013_07-16_Stanton_Rainbow_Waveguide_Designs.pptx
- Media:2013-7-16_-_Processing_Update_2_1micron.pptx
