Let n be given.

Assume Hn.

We will prove eps_ n ≤ 1.

rewrite the current goal using mul_SNo_oneR (eps_ n) (SNo_eps_ n Hn) (from right to left).

We will prove eps_ n * 1 ≤ 1.

rewrite the current goal using mul_SNo_eps_power_2 n (omega_nat_p n Hn) (from right to left) at position 2.

We will prove eps_ n * 1 ≤ eps_ n * 2 ^ n.

Apply nonneg_mul_SNo_Le (eps_ n) 1 (2 ^ n) (SNo_eps_ n Hn) to the current goal.

We will prove 0 ≤ eps_ n.

Apply SNoLtLe to the current goal.

An exact proof term for the current goal is SNo_eps_pos n Hn.

An exact proof term for the current goal is SNo_1.

We will prove SNo (2 ^ n).

Apply SNo_exp_SNo_nat to the current goal.

An exact proof term for the current goal is SNo_2.

We will prove nat_p n.

An exact proof term for the current goal is omega_nat_p n Hn.

We will prove 1 ≤ 2 ^ n.

Apply exp_SNo_1_bd 2 SNo_2 to the current goal.

We will prove 1 ≤ 2.

Apply SNoLtLe to the current goal.

An exact proof term for the current goal is SNoLt_1_2.

We will prove nat_p n.

An exact proof term for the current goal is omega_nat_p n Hn.

∎