I guess if that's the only thing that works... but bogging down the motor with inefficient gears and/or having to maintain a high speed seems like an poor way to run a railroad.
I wanted it that way. The bike had a job which was to get me somewhere in a convenient amount of time (i.e. speed is a benefit), and give me a workout, in a town that is laid out on cheap land with low traffic density, so everything is spread out, so its routine for lots of stores and whatnot to be miles away. Commuting for miles on flat ground on dead straight streets, I found the ideal setup was to set PAS to full blast, and then gear the bike so I could push past that top assisted speed via sets of rep intervals where I would push past the max speed to about 32 mph via muscle power, or relax and pedal and let the bike propel me at about 28. Wash, rinse and repeat over the course of the ride. The bike lanes were roads that oftentimes had speed limits of 50 mph, so an ebike going 32 attracted no attention whatsoever.
Usually.
This was my 2wd twin-hub commuter and this was another 50 mph road. I'm keeping up with traffic in part of the vid because the cars had slowed down for the cycling club on the single-lane segment (that road has been made into 6 lanes since this vid was made).
Doesn't the KT controller allow for cadence level settings like the Bafang BBS*?
Nope. Nothing like it unfortunately. You do have a setting that increases or decreases the power that is in between the 5 levels. Its C14 IIRC. So if you originally had default PAS that has 15% increases between levels (I just made that number up) instead you get a 20% increase between levels. The 'increase' version could deliver just a bit more acceleration power than you could get on throttle, in fact. Instead what KT controllers have is 'imitation torque control' which is entirely automated in its behavior.
Could you elaborate on the KT-based cadence-sensing scheme? What exactly does assist level control in this system?
As noted above, it is entirely automated. There is no documentation, either. Here's what happens: From a standing start, you engage the pedals and as soon as the sensor senses movement (you can adjust this with different magnet rings that range from 6, 8 or 12 magnets. I usually use 8 and get engagement after a pedal move of from say midnight to 2 o'clock). Once movement is sensed, the system will engage for a short time at very low power. Then as your speed goes to say 2 or 3 mph the power ramps up to peak after a few seconds. As your speed increases, the power tails off pretty quickly until eventually you are cruising on flat ground at 28 and your hub is only putting out as little as 20 or 30 watts. You can adjust this initial increase via a 'slow start' setting that has 3 levels, and essentially flattens and lengthens the power delivery curve. This keeps you from having very strong acceleration right off the bat but still rolls on the power fully. It just takes an extra 3 or 4 seconds or so to get there.
So thats starting from zero on flat ground and going up to cruise. Lets say you approach a hill. You maintain your cadence, but the bike is now climbing a hill and its slowing down, and so are your legs. The bike senses this change in speed and cadence and you can watch it slowly ramp the power back up until its pouring it on again to get you up the hill as best it can. As you crest the hill, your speed increments back up, maybe your cadence picks up some as well and you can watch the controller ramp the power right back down again as you get back to cruising speed.
Going downhill, as your speed gets up past a certain point the motor ramps power down to almost nothing and feeds just a minimum. Just enough to make the hub motor free-spinning like a normal hub.
