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[* black] After detaching the headband and inner faceplate, we have a better view of the eye-tracking IR emitters. We note they're all wired in series, rather than individually controlled.
-[* black] And finally, at our fingertips, the heart of the Magic Leap: [https://en.wikipedia.org/wiki/Field-sequential_color_system|field-sequential color (FSC)|new_window=true] LCOS microdisplays project images through diffractive waveguides, which reflect those images back into the user's eyes. The lenses layer two sets of waveguides to create two distinct "focus planes."
- [* icon_note] This approach is similar in principle to Microsoft's [https://en.wikipedia.org/wiki/Microsoft_HoloLens|HoloLens|new_window=true]—with an additional set of stacked waveguides—and closely follows some of Magic Leap's [https://www.kguttag.com/2018/03/01/magic-leap-new-patent-applications/|recent patent applications|new_window=true].
+[* black] And finally, at our fingertips, the heart of the Magic Leap: a pair of [https://en.wikipedia.org/wiki/Field-sequential_color_system|field-sequential color (FSC)|new_window=true] LCOS microdisplays tasked with generating and projecting the images that the user eventually sees. The lenses layer two sets of waveguides to create two distinct "focus planes."
+[* icon_note] Overall, this approach is similar in principle to Microsoft's [https://en.wikipedia.org/wiki/Microsoft_HoloLens|HoloLens|new_window=true]—with an additional set of stacked waveguides—and closely follows some of Magic Leap's [https://www.kguttag.com/2018/03/01/magic-leap-new-patent-applications/|recent patent applications|new_window=true].