Jane Doe

Now, there's one little important fact, is that classifying the cones or generating maps of the cones is difficult. And nobody has ever mapped the cones right along the line of sight in an area called your fovea, because the cones are really densely packed there. So we, instead, we mapped the cones a little bit away from the fovea, about a half a millimeter away from the center of the fovea.

Now, there's one little important fact, is that classifying the cones or generating maps of the cones is difficult. And nobody has ever mapped the cones right along the line of sight in an area called your fovea, because the cones are really densely packed there. So we, instead, we mapped the cones a little bit away from the fovea, about a half a millimeter away from the center of the fovea.

Now, there's one little important fact, is that classifying the cones or generating maps of the cones is difficult. And nobody has ever mapped the cones right along the line of sight in an area called your fovea, because the cones are really densely packed there. So we, instead, we mapped the cones a little bit away from the fovea, about a half a millimeter away from the center of the fovea.

And initially, while everything's getting set up, things look green or just a regular green. Then once everything gets into place and you're carefully fixating, then you have this moment where it just turns this saturated teal. And I was aware at that moment that we had succeeded, that we had created and that we were able to stimulate only the M-cones.

And initially, while everything's getting set up, things look green or just a regular green. Then once everything gets into place and you're carefully fixating, then you have this moment where it just turns this saturated teal. And I was aware at that moment that we had succeeded, that we had created and that we were able to stimulate only the M-cones.

And initially, while everything's getting set up, things look green or just a regular green. Then once everything gets into place and you're carefully fixating, then you have this moment where it just turns this saturated teal. And I was aware at that moment that we had succeeded, that we had created and that we were able to stimulate only the M-cones.

And James Fong, the lead author on the paper, he invented the name OLO because it's a binary code for 010, which represent the stimulation of the L, M, and S cones. That's so smart.

And James Fong, the lead author on the paper, he invented the name OLO because it's a binary code for 010, which represent the stimulation of the L, M, and S cones. That's so smart.

And James Fong, the lead author on the paper, he invented the name OLO because it's a binary code for 010, which represent the stimulation of the L, M, and S cones. That's so smart.

That's right.

That's right.

That's right.

Now, there's one type of situation where you can get an impression of what Olo might be. And that is if you desensitize or if you're exposed to a bright red light for a period of time.

Now, there's one type of situation where you can get an impression of what Olo might be. And that is if you desensitize or if you're exposed to a bright red light for a period of time.

Now, there's one type of situation where you can get an impression of what Olo might be. And that is if you desensitize or if you're exposed to a bright red light for a period of time.

So if you look at red light and you kind of adapt to red light, by looking at red light too much for a long period of time, you may desensitize to it or adapt to it. And then immediately following the adaptation to red light, you show a green light.

So if you look at red light and you kind of adapt to red light, by looking at red light too much for a long period of time, you may desensitize to it or adapt to it. And then immediately following the adaptation to red light, you show a green light.

So if you look at red light and you kind of adapt to red light, by looking at red light too much for a long period of time, you may desensitize to it or adapt to it. And then immediately following the adaptation to red light, you show a green light.

And that approximates the condition that we generate with OLO, whereby the M-cones are preferentially stimulated more than what normal natural light would do. And so if you wanted to get a rough idea of what OLO looked like, you could do this adaptation trick. Now, the difference is that when we deliver OLO, we can make it last. It can persist.

And that approximates the condition that we generate with OLO, whereby the M-cones are preferentially stimulated more than what normal natural light would do. And so if you wanted to get a rough idea of what OLO looked like, you could do this adaptation trick. Now, the difference is that when we deliver OLO, we can make it last. It can persist.