[wpimath] Make SimpleMotorFeedforward only support discrete feedforward (#6647)

Co-authored-by: Tyler Veness <calcmogul@gmail.com>

wpimath/src/main/java/edu/wpi/first/math/controller/SimpleMotorFeedforward.java

@@ -4,9 +4,12 @@
 
 package edu.wpi.first.math.controller;
 
-import edu.wpi.first.math.MatBuilder;
-import edu.wpi.first.math.Nat;
-import edu.wpi.first.math.system.plant.LinearSystemId;
+import static edu.wpi.first.units.Units.Volts;
+
+import edu.wpi.first.units.Measure;
+import edu.wpi.first.units.Unit;
+import edu.wpi.first.units.Velocity;
+import edu.wpi.first.units.Voltage;
 
 /** A helper class that computes feedforward outputs for a simple permanent-magnet DC motor. */
 public class SimpleMotorFeedforward {
@@ -19,17 +22,22 @@ public class SimpleMotorFeedforward {
   /** The acceleration gain. */
   public final double ka;
 
+  /** The period. */
+  private double m_dt;
+
   /**
-   * Creates a new SimpleMotorFeedforward with the specified gains. Units of the gain values will
-   * dictate units of the computed feedforward.
+   * Creates a new SimpleMotorFeedforward with the specified gains and period. Units of the gain
+   * values will dictate units of the computed feedforward.
    *
    * @param ks The static gain.
    * @param kv The velocity gain.
    * @param ka The acceleration gain.
+   * @param dtSeconds The period in seconds.
    * @throws IllegalArgumentException for kv < zero.
    * @throws IllegalArgumentException for ka < zero.
+   * @throws IllegalArgumentException for period ≤ zero.
    */
-  public SimpleMotorFeedforward(double ks, double kv, double ka) {
+  public SimpleMotorFeedforward(double ks, double kv, double ka, double dtSeconds) {
     this.ks = ks;
     this.kv = kv;
     this.ka = ka;
@@ -39,17 +47,37 @@ public class SimpleMotorFeedforward {
     if (ka < 0.0) {
       throw new IllegalArgumentException("ka must be a non-negative number, got " + ka + "!");
     }
+    if (dtSeconds <= 0.0) {
+      throw new IllegalArgumentException(
+          "period must be a positive number, got " + dtSeconds + "!");
+    }
+    m_dt = dtSeconds;
+  }
+
+  /**
+   * Creates a new SimpleMotorFeedforward with the specified gains and period. The period is
+   * defaulted to 20 ms. Units of the gain values will dictate units of the computed feedforward.
+   *
+   * @param ks The static gain.
+   * @param kv The velocity gain.
+   * @param ka The acceleration gain.
+   * @throws IllegalArgumentException for kv &lt; zero.
+   * @throws IllegalArgumentException for ka &lt; zero.
+   */
+  public SimpleMotorFeedforward(double ks, double kv, double ka) {
+    this(ks, kv, ka, 0.020);
   }
 
   /**
    * Creates a new SimpleMotorFeedforward with the specified gains. Acceleration gain is defaulted
-   * to zero. Units of the gain values will dictate units of the computed feedforward.
+   * to zero. The period is defaulted to 20 ms. Units of the gain values will dictate units of the
+   * computed feedforward.
    *
    * @param ks The static gain.
    * @param kv The velocity gain.
    */
   public SimpleMotorFeedforward(double ks, double kv) {
-    this(ks, kv, 0);
+    this(ks, kv, 0, 0.020);
   }
 
   /**
@@ -58,43 +86,114 @@ public class SimpleMotorFeedforward {
    * @param velocity The velocity setpoint.
    * @param acceleration The acceleration setpoint.
    * @return The computed feedforward.
+   * @deprecated Use the current/next velocity overload instead.
    */
+  @SuppressWarnings("removal")
+  @Deprecated(forRemoval = true, since = "2025")
   public double calculate(double velocity, double acceleration) {
     return ks * Math.signum(velocity) + kv * velocity + ka * acceleration;
   }
 
-  /**
-   * Calculates the feedforward from the gains and setpoints.
-   *
-   * @param currentVelocity The current velocity setpoint.
-   * @param nextVelocity The next velocity setpoint.
-   * @param dtSeconds Time between velocity setpoints in seconds.
-   * @return The computed feedforward.
-   */
-  public double calculate(double currentVelocity, double nextVelocity, double dtSeconds) {
-    var plant = LinearSystemId.identifyVelocitySystem(this.kv, this.ka);
-    var feedforward = new LinearPlantInversionFeedforward<>(plant, dtSeconds);
-
-    var r = MatBuilder.fill(Nat.N1(), Nat.N1(), currentVelocity);
-    var nextR = MatBuilder.fill(Nat.N1(), Nat.N1(), nextVelocity);
-
-    return ks * Math.signum(currentVelocity) + feedforward.calculate(r, nextR).get(0, 0);
-  }
-
-  // Rearranging the main equation from the calculate() method yields the
-  // formulas for the methods below:
-
   /**
    * Calculates the feedforward from the gains and velocity setpoint (acceleration is assumed to be
    * zero).
    *
    * @param velocity The velocity setpoint.
    * @return The computed feedforward.
+   * @deprecated Use the current/next velocity overload instead.
    */
+  @SuppressWarnings("removal")
+  @Deprecated(forRemoval = true, since = "2025")
   public double calculate(double velocity) {
     return calculate(velocity, 0);
   }
 
+  /**
+   * Calculates the feedforward from the gains and setpoints assuming discrete control when the
+   * setpoint does not change.
+   *
+   * @param <U> The velocity parameter either as distance or angle.
+   * @param setpoint The velocity setpoint.
+   * @return The computed feedforward.
+   */
+  public <U extends Unit<U>> Measure<Voltage> calculate(Measure<Velocity<U>> setpoint) {
+    return calculate(setpoint, setpoint);
+  }
+
+  /**
+   * Calculates the feedforward from the gains and setpoints assuming discrete control.
+   *
+   * @param <U> The velocity parameter either as distance or angle.
+   * @param currentVelocity The current velocity setpoint.
+   * @param nextVelocity The next velocity setpoint.
+   * @return The computed feedforward.
+   */
+  public <U extends Unit<U>> Measure<Voltage> calculate(
+      Measure<Velocity<U>> currentVelocity, Measure<Velocity<U>> nextVelocity) {
+    if (ka == 0.0) {
+      // Given the following discrete feedforward model
+      //
+      //   uₖ = B_d⁺(rₖ₊₁ − A_d rₖ)
+      //
+      // where
+      //
+      //   A_d = eᴬᵀ
+      //   B_d = A⁻¹(eᴬᵀ - I)B
+      //   A = −kᵥ/kₐ
+      //   B = 1/kₐ
+      //
+      // We want the feedforward model when kₐ = 0.
+      //
+      // Simplify A.
+      //
+      //   A = −kᵥ/kₐ
+      //
+      // As kₐ approaches zero, A approaches -∞.
+      //
+      //   A = −∞
+      //
+      // Simplify A_d.
+      //
+      //   A_d = eᴬᵀ
+      //   A_d = exp(−∞)
+      //   A_d = 0
+      //
+      // Simplify B_d.
+      //
+      //   B_d = A⁻¹(eᴬᵀ - I)B
+      //   B_d = A⁻¹((0) - I)B
+      //   B_d = A⁻¹(-I)B
+      //   B_d = -A⁻¹B
+      //   B_d = -(−kᵥ/kₐ)⁻¹(1/kₐ)
+      //   B_d = (kᵥ/kₐ)⁻¹(1/kₐ)
+      //   B_d = kₐ/kᵥ(1/kₐ)
+      //   B_d = 1/kᵥ
+      //
+      // Substitute these into the feedforward equation.
+      //
+      //   uₖ = B_d⁺(rₖ₊₁ − A_d rₖ)
+      //   uₖ = (1/kᵥ)⁺(rₖ₊₁ − (0) rₖ)
+      //   uₖ = kᵥrₖ₊₁
+      return Volts.of(ks * Math.signum(nextVelocity.magnitude()) + kv * nextVelocity.magnitude());
+    } else {
+      //   uₖ = B_d⁺(rₖ₊₁ − A_d rₖ)
+      //
+      // where
+      //
+      //   A_d = eᴬᵀ
+      //   B_d = A⁻¹(eᴬᵀ - I)B
+      //   A = −kᵥ/kₐ
+      //   B = 1/kₐ
+      double A = -kv / ka;
+      double B = 1.0 / ka;
+      double A_d = Math.exp(A * m_dt);
+      double B_d = 1.0 / A * (A_d - 1.0) * B;
+      return Volts.of(
+          ks * Math.signum(currentVelocity.magnitude())
+              + 1.0 / B_d * (nextVelocity.magnitude() - A_d * currentVelocity.magnitude()));
+    }
+  }
+
   /**
    * Calculates the maximum achievable velocity given a maximum voltage supply and an acceleration.
    * Useful for ensuring that velocity and acceleration constraints for a trapezoidal profile are