name	mpc-horizon-tuning
description	Selecting MPC prediction horizon and cost matrices for web handling.

MPC Tuning for Tension Control

Horizon N affects performance and computation:

For R2R systems with dt=0.01s: N = 5-15 typical

State cost Q: Emphasize tension tracking

Q_tension = 100 / T_ref²  # High weight on tensions
Q_velocity = 0.1 / v_ref²  # Lower weight on velocities
Q = diag([Q_tension × 6, Q_velocity × 6])

Control cost R: Penalize actuator effort

R = 0.01-0.1 × eye(n_u)  # Smaller = more aggressive

Higher Q	Effect
Faster tracking	More control effort
Lower steady-state error	More aggressive transients

Higher R	Effect
Smoother control	Slower response
Less actuator wear	Higher tracking error

Use LQR solution for terminal cost to guarantee stability:

P = solve_continuous_are(A, B, Q, R)

name	mpc-horizon-tuning
description	Selecting MPC prediction horizon and cost matrices for web handling.

Horizon N affects performance and computation:

For R2R systems with dt=0.01s: N = 5-15 typical

State cost Q: Emphasize tension tracking

Q_tension = 100 / T_ref²  # High weight on tensions
Q_velocity = 0.1 / v_ref²  # Lower weight on velocities
Q = diag([Q_tension × 6, Q_velocity × 6])

Control cost R: Penalize actuator effort

R = 0.01-0.1 × eye(n_u)  # Smaller = more aggressive

Higher Q	Effect
Faster tracking	More control effort
Lower steady-state error	More aggressive transients

Higher R	Effect
Smoother control	Slower response
Less actuator wear	Higher tracking error

Use LQR solution for terminal cost to guarantee stability:

P = solve_continuous_are(A, B, Q, R)

mpc-horizon-tuning