Analog keyboards have been the “next big thing” for ages now in the world of mechanical keyboards. These have sensors inside that can much more precisely differentiate between a slight and full keypress. They’ve long promised to revolutionize gaming and typing, being faster, more customizable, and more reliable (supposedly). But they’ve never quite been compelling enough for most people to adopt: Why sacrifice a proven track record for something new and experimental?
I think you can compare analog keyboards to electric vehicles. Sure, they’re better on paper in a variety of ways, but the entire infrastructure around us is designed for internal combustion engines, and we’re all used to the handling and performance characteristics of our gas guzzlers. Why make a change when it's hard to know if the benefits outweigh the risks?
Keychron’s new Hall effect (HE) keyboard, the Q1 HE, makes it easier to understand why. Combining the high-tech customizability of a Hall effect switch with the advanced construction of a premium mechanical keyboard brings out the best of both worlds. Plus having reliable and easy-to-understand customization makes the system a lot easier to understand.
What Are Hall Effect Switches?
Hall effect switches are a type of mechanical switch, similar to optical switches, which can have multiple different inputs across one keypress. While optical switches use a laser to identify inputs, an HE switch uses magnets to manipulate an electromagnetic field when a switch is pressed, which then returns different values at specific distances.
While these switches are new for consumer keyboards, the technology has been around for a while. One of the earliest manufacturers of Hall effect switches was Honeywell, who made these switches for the now-legendary Space Cadet keyboard. This version of the switch is incredibly different from modern iterations though—the only real similarity is that they both utilize magnets to create inputs.
The benefit of these multiple inputs is the ability to adjust the actuation point of your key switches—when the switch identifies that you have pressed a key. Moving the actuation point to the top of the keystroke can make typing more responsive while moving it toward the bottom can prevent accidental mis-inputs. To create a good middle ground, there are settings like “rapid-trigger” that allow multiple keypresses in a row without the switch needing to return to its resting position.