The formula to solve for centripetal acceleration is f = (mv)^2 /r Where "m" is the mass of the object experiencing centripetal acceleration, "v" is its rotational velocity, "r" is the radius of the circle it travels as it rotates, and "f" is the force acting on the object expressed in Newtons. Since we're dealing with the interior of a spinning asteroid, we can assume "r" is the radius of a given point on the interior hollow surface. We can also alter the equation; a "g" is a unit of gravitational force, equivalent to one Newton/kilogram (g = f/m). With a little bit of high school algebra, we can eliminate "m" from the above equation: r(g) = v^2 Plug in the radius of your asteroid and how much apparent gravity you want inhabitants to experience at the rim, and you'll get your velocity. The radius of your asteroid will depend on how much "vertical" space you want there to be inside. As for the precise dimensions, you already have an idea how many people you want on it. Figure out how much surface area you need for 5,000 people to live, work and occasionally have some time to themselves, and then abstract the interior of your asteroid as a cylinder. The formula for calculating the surface area of a cylinder is 2(pi)rh+2(pi)r However, the end caps of your cylinder are not usable area so we don't care about them, which leaves us with: A = 2(pi)rh You'll have an idea what A is, but you'll have to pull either r or h out of your hat; you can calculate r given h, or h given r, but you're going to have to make up one number or the other. The good news is asteroids come in all shapes and sizes so you can get away with it.