let a, b, k be Real; :: thesis: ( k > 0 implies ( (abs (a + b)) to_power k <= ((abs a) + (abs b)) to_power k & ((abs a) + (abs b)) to_power k <= (2 * (max (abs a),(abs b))) to_power k & (abs (a + b)) to_power k <= (2 * (max (abs a),(abs b))) to_power k ) )
assume A0: k > 0 ; :: thesis: ( (abs (a + b)) to_power k <= ((abs a) + (abs b)) to_power k & ((abs a) + (abs b)) to_power k <= (2 * (max (abs a),(abs b))) to_power k & (abs (a + b)) to_power k <= (2 * (max (abs a),(abs b))) to_power k )
A3: abs (a + b) <= (abs a) + (abs b) by ABSVALUE:21;
( abs a <= max (abs a),(abs b) & abs b <= max (abs a),(abs b) ) by XXREAL_0:25;
then A5: (abs a) + (abs b) <= (max (abs a),(abs b)) + (max (abs a),(abs b)) by XREAL_1:9;
then A6: abs (a + b) <= 2 * (max (abs a),(abs b)) by A3, XXREAL_0:2;
0 <= abs (a + b) by COMPLEX1:132;
hence ( (abs (a + b)) to_power k <= ((abs a) + (abs b)) to_power k & ((abs a) + (abs b)) to_power k <= (2 * (max (abs a),(abs b))) to_power k & (abs (a + b)) to_power k <= (2 * (max (abs a),(abs b))) to_power k ) by A0, A3, A5, A6, HOLDER_1:3; :: thesis: verum