Actually, higher speed makes it easier to pull up. You have more lift and more control authority. As long as you don't exceed the aircraft's structural limits, airspeed is your friend.
It's when you are low and slow and try to pull up with the elevator that you may stall the aircraft. You need to push the throttle to gain some airspeed.
I can see it being harder on a GA aeroplane (more airflow over control surfaces making them harder to deflect), but not sure the same applies on hydraulic controls.
Control surfaces work the same whether you are manipulating them with a direct mechanical connection or have hydraulic assistance.
It's not a question of whether you are strong enough to move the flight controls.
The only thing the hydraulics do for you is to reduce your effort in moving those controls.
Control surfaces don't magically make the plane go up or down, or left or right. The only way they work is by pushing against the air flowing over them.
If there is not enough airflow over the actual controls - ailerons, elevator, rudder - you won't be able to control the airplane.
And if there isn't enough airflow over the wings, they won't provide lift. That is when you stall and lose all control, until you find a way to increase your airspeed and get some air moving over the wings and flight controls, so they have something to push against.
Source: my basic pilot training where I practiced stalls and spins and all kinds of loss of control.
> It's not a question of whether you are strong enough to move the flight controls.
Anybody who flew a badly trimmed plane at high speed will disagree. Of course more airflow over the wings will mean your GA cessna 172 controls require more human strength to operate. They are also more effective as you say, but that's not what the previous poster meant.
It's when you are low and slow and try to pull up with the elevator that you may stall the aircraft. You need to push the throttle to gain some airspeed.