Here is how I understand it.
For induction motors, I agree with you. Induction motors need slip (difference in speed between synch speed ns and rotor speed n) to generate torque for the load. The more a rotor's speed n decreases away from synch speed ns, the more slip and thus the more torque produced. Real power P is directly proportional to torque.
Tm = 9.55 * Pr / ns = 9.55 * Pout / n (neglecting windage loss Pv)
Tm = 5252 * HP / rpm
For synchronous motors, I also agree with you. All synchronous machines (synch gens and synch motors) always run at synchronous speed ns, and the only way to change ns is by changing frequency f (a given synch machine's number of poles p is fixed/constant). The equation for real power for a synchronous machine (neglecting resistance) is:
P = (Ea * Vt / Xs) * sin(theta)
Usually theta = Angle of Ea - Angle of Vt. For a synch motor, Ea lags Vt, so theta would be negative... But I think you're just concerned with the magnitude of P. I guess for synch motor, maybe you can just use angle of Vt - angle of Ea for theta?
I think the terminal voltage Vt and synchronous reactance Xs are usually fixed/constant for a synchronous machine connected to an electrical system. So the only ways left to increase P is by increasing Ea (increasing the excitation) or by increasing theta (mainly by changing the angle of Ea, since I think the angle of Vt is usually fixed/constant).
