Why Your Eyes and Brain Strongly Prefer Games at 60fps

One of the Issues that Comes Up Frequently in Technical Discussions of Both Gaming and Video is What Frame Rate should be Considered “Good Enough”. On the One Hand, you Have People Who Argue for What I’ll Politely Call Tradition, Who Believe that 24fps for Film and 30fps for Gaming, Represents a Magic Figure that we Don’t Benefit from Exceeding. There’s actually a Great Deal of Objective Evidence suggesting this Isn’t True and a New Blog Post by Simon Cooke, from Microsoft’s XBox Advanced Technology Group, Delves into Why Humans Tend to Prefer Higher Frame Rates. Part of the Problem with Trying to Discuss this Topic is that, the Human Eye is a Fantastically Complicated Piece of Equipment that Performs its Own Image Processing before the Signal is Ever Relayed to the Brain.


We Tend to Think of What we See as a Cohesive Whole because, our Entire Visual System has Evolved to Allow us to do so. In Many Ways, however, this is an Illusion. The Eye’s Sensitivity to Color, Motion, Light and Acceleration / Deceleration are All Different. The Situation is Further Muddied by the Fact that, while we Often Think of the Eye as a Camera and Discuss Vision with the Same Terms we Use to Talk about Computer-Generated Graphics, Neither of these Analogies actually Capture How the Eye Receives or Processes Information. All of this Said, People do Tend to Prefer Higher Frame Rates for Gaming When Given the Opportunity to Try them. This Preference Holds Up Even Above 60fps (60Hz), for a Number of Potential Reasons depending on the Nature of the Game, its Graphics and How Fast-Paced the Action is. Simon Cooke’s Theory is that, this Preference has to do with One of the Interesting Mechanical Aspects of Human Vision — Even When you Fix your Eyes on a Single Fixed Point, the Retina is Never actually Still.


The Wobble — More Properly Known as Ocular Microtremor — Occurs at an Average Frequency of 83.68Hz, with a Jiggle Range of around 150-250nm, or about the Width of 1-3 Photoreceptors in the Retina. So, What’s the Point of this Wiggling Back and Forth ? Cooke Thinks he Knows. By Wiggling the Retina Back and Forth, you Sample the Same Scene from 2 Very Slightly Different Points. Meanwhile, Inside the Eye, you’ve Got 2 Different Types of Retinal Ganglion Cells — On-Center Cells that Respond When the Center of its Receptive Field is Exposed to Light and Off-Center Cells that Respond When the Center of the Field is Not Exposed to Light. When the Retina Wiggles Back and Forth, Incoming Light Strikes Both On-Center and Off-Center Cells, Stimulating Both. Cooke Thinks this May Boost our Ability to Detect the Edges of Objects. He also Argues that All of this Ties Back to the Uncanny Valley, though I’ll Leave that to him to Explain.