public void ResetTest()
        {
            Assert.AreEqual(0, filter.Average);

            //Initial population
            filter.Add(10);
            filter.Add(5);
            filter.Add(3);
            filter.Add(4);

            Assert.AreEqual(5.5, filter.Average);

            //Check reset removes all values
            filter.Reset();

            Assert.AreEqual(0, filter.Average);

            //Check we can still add elements
            filter.Add(4);

            Assert.AreEqual(1, filter.Average);
        }
Exemplo n.º 2
0
        // Update is called once per frame
        void Update()
        {
            if (!enabled)
            {
                return;
            }


            // in  [-1, 1] & inverted
            float steeringAngle = -player.GetAxis("SteeringAngle");
            // in [0,1]
            float left  = player.GetAxis("Backward");
            float right = player.GetAxis("Forward");
//#else
            var   joystick      = InputManager.Instance.GetControllerJoystick(true);
            float steeringAngle = joystick.x;
            // keeping "left"=backward and "right"=forward variables from the pedals implementation
            float left  = (joystick.y > 0) ? 0 : Mathf.Abs(joystick.y);
            float right = (joystick.y < 0) ? 0 : Mathf.Abs(joystick.y);

            leftWindow.Add(left);
            rightWindow.Add(right);

            // only change direction if pedals are in both deadzones
            if (Mathf.Max(left, right) <= Mathf.Max(forwardDeadzone, backwardDeadzone))
            {
                canChangeDir = true;
                leftWindow.Reset();
                rightWindow.Reset();
                //Debug.Log("reset");
            }
            //Debug.Log(leftWindow.IsFull + ", " + rightWindow.IsFull + "," + leftWindow.Buffer.Count + ", " + leftWindow.FilterSize);

            if (leftWindow.IsFull && rightWindow.IsFull)
            {
                if (canChangeDir)
                {
                    // go back if both pedals are pressed in more than the backward deadzone
                    if (leftWindow.Max() >= backwardDeadzone)
                    {
                        goingForward = false;
                        canChangeDir = false;
                    }
                    // go forward if one pedal is pressed more than the forward deadzone
                    else if (rightWindow.Max() >= forwardDeadzone)
                    {
                        goingForward = true;
                        canChangeDir = false;
                    }
                }
            }
            else
            {
                left  = 0;
                right = 0;
            }

            // moving average filter pedal values
            leftFilter.Add(left);
            rightFilter.Add(right);
            left  = leftFilter.GetFiltered();
            right = rightFilter.GetFiltered();

            // [-1, 1] -- non-linear -> [-1, 1]
            float mappedAngularVelocity = Mathf.Sign(steeringAngle) * Mathf.Clamp01(angularVelocityMap.Evaluate(Mathf.Abs(steeringAngle)));
            // [-1, 1] -- non-linear -> [-1, 1]
            float mappedVelocity;
            float vel = goingForward ? right : left;

            if (goingForward)
            {
                vel            = Mathf.Clamp01(vel - forwardDeadzone) / (1 - forwardDeadzone);
                mappedVelocity = Mathf.Clamp01(velocityMap.Evaluate(Mathf.Abs(vel)));
            }
            else
            {
                vel            = Mathf.Clamp01(vel - backwardDeadzone) / (1 - backwardDeadzone);
                mappedVelocity = -0.5f * Mathf.Clamp01(velocityMap.Evaluate(Mathf.Abs(vel)));
            }


            Vector2 direction = Vector2.Lerp(leftDrive.normalized,
                                             rightDrive.normalized,
                                             0.5f + 0.5f * mappedAngularVelocity);

            // publish read only values
            velocity        = mappedVelocity * maxVelocity;
            angularVelocity = direction.magnitude * maxAngularVelocity;

            _output = maxAngularVelocity * direction + velocity * forwardDrive.normalized;

            driveControl.V_L = output.x;
            driveControl.V_R = output.y;
        }