Character only moves sideways?

I have a problem.
In my Unity Project my character only moves sideways using the a and d keys. It does however not move forward and backwards using the w and s keys.

I’m using the Mouse Look, the FPSInputController, the Character Motor and the Character Controller which come with Unity.

Can anyone help me? Here is the code from FPSInputController:

private var motor : CharacterMotor;

// Use this for initialization
function Awake () {
	motor = GetComponent(CharacterMotor);
}

// Update is called once per frame
function Update () {
	// Get the input vector from keyboard or analog stick
	var directionVector = new Vector3(Input.GetAxis("Horizontal"), Input.GetAxis("Vertical"),0);
	print (directionVector);
	
	if (directionVector != Vector3.zero) {
		// Get the length of the directon vector and then normalize it
		// Dividing by the length is cheaper than normalizing when we already have the length anyway
		var directionLength = directionVector.magnitude;
		directionVector = directionVector / directionLength;
		
		// Make sure the length is no bigger than 1
		directionLength = Mathf.Min(1, directionLength);
		
		// Make the input vector more sensitive towards the extremes and less sensitive in the middle
		// This makes it easier to control slow speeds when using analog sticks
		directionLength = directionLength * directionLength;
		
		// Multiply the normalized direction vector by the modified length
		directionVector = directionVector * directionLength;
	}
	
	// Apply the direction to the CharacterMotor
	motor.inputMoveDirection = transform.rotation * directionVector;
	motor.inputJump = Input.GetButton("Jump");
}

// Require a character controller to be attached to the same game object
@script RequireComponent (CharacterMotor)
@script AddComponentMenu ("Character/FPS Input Controller")

Regards
Marc

I’m not sure what’s wrong with that script, but I have an idea nonetheless. Try my script, because it’s fully functional with my own character, so by logical extension should work for you.

CharacterMotor.js:

#pragma strict
#pragma implicit
#pragma downcast

// Does this script currently respond to input?
var canControl : boolean = true;

var useFixedUpdate : boolean = true;

// For the next variables, @System.NonSerialized tells Unity to not serialize the variable or show it in the inspector view.
// Very handy for organization!

// The current global direction we want the character to move in.
@System.NonSerialized
var inputMoveDirection : Vector3 = Vector3.zero;

// Is the jump button held down? We use this interface instead of checking
// for the jump button directly so this script can also be used by AIs.
@System.NonSerialized
var inputJump : boolean = false;

class CharacterMotorMovement {
	// The maximum horizontal speed when moving
	var maxForwardSpeed : float = 10.0;
	var maxSidewaysSpeed : float = 10.0;
	var maxBackwardsSpeed : float = 10.0;
	
	// Curve for multiplying speed based on slope (negative = downwards)
	var slopeSpeedMultiplier : AnimationCurve = AnimationCurve(Keyframe(-90, 1), Keyframe(0, 1), Keyframe(90, 0));
	
	// How fast does the character change speeds?  Higher is faster.
	var maxGroundAcceleration : float = 30.0;
	var maxAirAcceleration : float = 20.0;

	// The gravity for the character
	var gravity : float = 10.0;
	var maxFallSpeed : float = 20.0;
	
	// For the next variables, @System.NonSerialized tells Unity to not serialize the variable or show it in the inspector view.
	// Very handy for organization!

	// The last collision flags returned from controller.Move
	@System.NonSerialized
	var collisionFlags : CollisionFlags; 

	// We will keep track of the character's current velocity,
	@System.NonSerialized
	var velocity : Vector3;
	
	// This keeps track of our current velocity while we're not grounded
	@System.NonSerialized
	var frameVelocity : Vector3 = Vector3.zero;
	
	@System.NonSerialized
	var hitPoint : Vector3 = Vector3.zero;
	
	@System.NonSerialized
	var lastHitPoint : Vector3 = Vector3(Mathf.Infinity, 0, 0);
}

var movement : CharacterMotorMovement = CharacterMotorMovement();

enum MovementTransferOnJump {
	None, // The jump is not affected by velocity of floor at all.
	InitTransfer, // Jump gets its initial velocity from the floor, then gradualy comes to a stop.
	PermaTransfer, // Jump gets its initial velocity from the floor, and keeps that velocity until landing.
	PermaLocked // Jump is relative to the movement of the last touched floor and will move together with that floor.
}

// We will contain all the jumping related variables in one helper class for clarity.
class CharacterMotorJumping {
	// Can the character jump?
	var enabled : boolean = true;

	// How high do we jump when pressing jump and letting go immediately
	var baseHeight : float = 1.0;
	
	// We add extraHeight units (meters) on top when holding the button down longer while jumping
	var extraHeight : float = 4.1;
	
	// How much does the character jump out perpendicular to the surface on walkable surfaces?
	// 0 means a fully vertical jump and 1 means fully perpendicular.
	var perpAmount : float = 0.0;
	
	// How much does the character jump out perpendicular to the surface on too steep surfaces?
	// 0 means a fully vertical jump and 1 means fully perpendicular.
	var steepPerpAmount : float = 0.5;
	
	// For the next variables, @System.NonSerialized tells Unity to not serialize the variable or show it in the inspector view.
	// Very handy for organization!

	// Are we jumping? (Initiated with jump button and not grounded yet)
	// To see if we are just in the air (initiated by jumping OR falling) see the grounded variable.
	@System.NonSerialized
	var jumping : boolean = false;
	
	@System.NonSerialized
	var holdingJumpButton : boolean = false;

	// the time we jumped at (Used to determine for how long to apply extra jump power after jumping.)
	@System.NonSerialized
	var lastStartTime : float = 0.0;
	
	@System.NonSerialized
	var lastButtonDownTime : float = -100;
	
	@System.NonSerialized
	var jumpDir : Vector3 = Vector3.up;
}

var jumping : CharacterMotorJumping = CharacterMotorJumping();

class CharacterMotorMovingPlatform {
	var enabled : boolean = true;
	
	var movementTransfer : MovementTransferOnJump = MovementTransferOnJump.PermaTransfer;
	
	@System.NonSerialized
	var hitPlatform : Transform;
	
	@System.NonSerialized
	var activePlatform : Transform;
	
	@System.NonSerialized
	var activeLocalPoint : Vector3;
	
	@System.NonSerialized
	var activeGlobalPoint : Vector3;
	
	@System.NonSerialized
	var activeLocalRotation : Quaternion;
	
	@System.NonSerialized
	var activeGlobalRotation : Quaternion;
	
	@System.NonSerialized
	var lastMatrix : Matrix4x4;
	
	@System.NonSerialized
	var platformVelocity : Vector3;
	
	@System.NonSerialized
	var newPlatform : boolean;
}

var movingPlatform : CharacterMotorMovingPlatform = CharacterMotorMovingPlatform();

class CharacterMotorSliding {
	// Does the character slide on too steep surfaces?
	var enabled : boolean = true;
	
	// How fast does the character slide on steep surfaces?
	var slidingSpeed : float = 15;
	
	// How much can the player control the sliding direction?
	// If the value is 0.5 the player can slide sideways with half the speed of the downwards sliding speed.
	var sidewaysControl : float = 1.0;
	
	// How much can the player influence the sliding speed?
	// If the value is 0.5 the player can speed the sliding up to 150% or slow it down to 50%.
	var speedControl : float = 0.4;
}

var sliding : CharacterMotorSliding = CharacterMotorSliding();

@System.NonSerialized
var grounded : boolean = true;

@System.NonSerialized
var groundNormal : Vector3 = Vector3.zero;

private var lastGroundNormal : Vector3 = Vector3.zero;

private var tr : Transform;

private var controller : CharacterController;

function Awake () {
	controller = GetComponent (CharacterController);
	tr = transform;
}

private function UpdateFunction () {
	// We copy the actual velocity into a temporary variable that we can manipulate.
	var velocity : Vector3 = movement.velocity;
	
	// Update velocity based on input
	velocity = ApplyInputVelocityChange(velocity);
	
	// Apply gravity and jumping force
	velocity = ApplyGravityAndJumping (velocity);
	
	// Moving platform support
	var moveDistance : Vector3 = Vector3.zero;
	if (MoveWithPlatform()) {
		var newGlobalPoint : Vector3 = movingPlatform.activePlatform.TransformPoint(movingPlatform.activeLocalPoint);
		moveDistance = (newGlobalPoint - movingPlatform.activeGlobalPoint);
		if (moveDistance != Vector3.zero)
			controller.Move(moveDistance);
		
		// Support moving platform rotation as well:
        var newGlobalRotation : Quaternion = movingPlatform.activePlatform.rotation * movingPlatform.activeLocalRotation;
        var rotationDiff : Quaternion = newGlobalRotation * Quaternion.Inverse(movingPlatform.activeGlobalRotation);
        
        var yRotation = rotationDiff.eulerAngles.y;
        if (yRotation != 0) {
	        // Prevent rotation of the local up vector
	        tr.Rotate(0, yRotation, 0);
        }
	}
	
	// Save lastPosition for velocity calculation.
	var lastPosition : Vector3 = tr.position;
	
	// We always want the movement to be framerate independent.  Multiplying by Time.deltaTime does this.
	var currentMovementOffset : Vector3 = velocity * Time.deltaTime;
	
	// Find out how much we need to push towards the ground to avoid loosing grouning
	// when walking down a step or over a sharp change in slope.
	var pushDownOffset : float = Mathf.Max(controller.stepOffset, Vector3(currentMovementOffset.x, 0, currentMovementOffset.z).magnitude);
	if (grounded)
		currentMovementOffset -= pushDownOffset * Vector3.up;
	
	// Reset variables that will be set by collision function
	movingPlatform.hitPlatform = null;
	groundNormal = Vector3.zero;
	
   	// Move our character!
	movement.collisionFlags = controller.Move (currentMovementOffset);
	
	movement.lastHitPoint = movement.hitPoint;
	lastGroundNormal = groundNormal;
	
	if (movingPlatform.enabled && movingPlatform.activePlatform != movingPlatform.hitPlatform) {
		if (movingPlatform.hitPlatform != null) {
			movingPlatform.activePlatform = movingPlatform.hitPlatform;
			movingPlatform.lastMatrix = movingPlatform.hitPlatform.localToWorldMatrix;
			movingPlatform.newPlatform = true;
		}
	}
	
	// Calculate the velocity based on the current and previous position.  
	// This means our velocity will only be the amount the character actually moved as a result of collisions.
	var oldHVelocity : Vector3 = new Vector3(velocity.x, 0, velocity.z);
	movement.velocity = (tr.position - lastPosition) / Time.deltaTime;
	var newHVelocity : Vector3 = new Vector3(movement.velocity.x, 0, movement.velocity.z);
	
	// The CharacterController can be moved in unwanted directions when colliding with things.
	// We want to prevent this from influencing the recorded velocity.
	if (oldHVelocity == Vector3.zero) {
		movement.velocity = new Vector3(0, movement.velocity.y, 0);
	}
	else {
		var projectedNewVelocity : float = Vector3.Dot(newHVelocity, oldHVelocity) / oldHVelocity.sqrMagnitude;
		movement.velocity = oldHVelocity * Mathf.Clamp01(projectedNewVelocity) + movement.velocity.y * Vector3.up;
	}
	
	if (movement.velocity.y < velocity.y - 0.001) {
		if (movement.velocity.y < 0) {
			// Something is forcing the CharacterController down faster than it should.
			// Ignore this
			movement.velocity.y = velocity.y;
		}
		else {
			// The upwards movement of the CharacterController has been blocked.
			// This is treated like a ceiling collision - stop further jumping here.
			jumping.holdingJumpButton = false;
		}
	}
	
	// We were grounded but just loosed grounding
	if (grounded && !IsGroundedTest()) {
		grounded = false;
		
		// Apply inertia from platform
		if (movingPlatform.enabled &&
			(movingPlatform.movementTransfer == MovementTransferOnJump.InitTransfer ||
			movingPlatform.movementTransfer == MovementTransferOnJump.PermaTransfer)
		) {
			movement.frameVelocity = movingPlatform.platformVelocity;
			movement.velocity += movingPlatform.platformVelocity;
		}
		
		SendMessage("OnFall", SendMessageOptions.DontRequireReceiver);
		// We pushed the character down to ensure it would stay on the ground if there was any.
		// But there wasn't so now we cancel the downwards offset to make the fall smoother.
		tr.position += pushDownOffset * Vector3.up;
	}
	// We were not grounded but just landed on something
	else if (!grounded && IsGroundedTest()) {
		grounded = true;
		jumping.jumping = false;
		SubtractNewPlatformVelocity();
		
		SendMessage("OnLand", SendMessageOptions.DontRequireReceiver);
	}
	
	// Moving platforms support
	if (MoveWithPlatform()) {
		// Use the center of the lower half sphere of the capsule as reference point.
		// This works best when the character is standing on moving tilting platforms. 
		movingPlatform.activeGlobalPoint = tr.position + Vector3.up * (controller.center.y - controller.height*0.5 + controller.radius);
		movingPlatform.activeLocalPoint = movingPlatform.activePlatform.InverseTransformPoint(movingPlatform.activeGlobalPoint);
		
		// Support moving platform rotation as well:
        movingPlatform.activeGlobalRotation = tr.rotation;
        movingPlatform.activeLocalRotation = Quaternion.Inverse(movingPlatform.activePlatform.rotation) * movingPlatform.activeGlobalRotation; 
	}
}

function FixedUpdate () {
	if (movingPlatform.enabled) {
		if (movingPlatform.activePlatform != null) {
			if (!movingPlatform.newPlatform) {
				var lastVelocity : Vector3 = movingPlatform.platformVelocity;
				
				movingPlatform.platformVelocity = (
					movingPlatform.activePlatform.localToWorldMatrix.MultiplyPoint3x4(movingPlatform.activeLocalPoint)
					- movingPlatform.lastMatrix.MultiplyPoint3x4(movingPlatform.activeLocalPoint)
				) / Time.deltaTime;
			}
			movingPlatform.lastMatrix = movingPlatform.activePlatform.localToWorldMatrix;
			movingPlatform.newPlatform = false;
		}
		else {
			movingPlatform.platformVelocity = Vector3.zero;	
		}
	}
	
	if (useFixedUpdate)
		UpdateFunction();
}

function Update () {
	if (!useFixedUpdate)
		UpdateFunction();
}

private function ApplyInputVelocityChange (velocity : Vector3) {	
	if (!canControl)
		inputMoveDirection = Vector3.zero;
	
	// Find desired velocity
	var desiredVelocity : Vector3;
	if (grounded && TooSteep()) {
		// The direction we're sliding in
		desiredVelocity = Vector3(groundNormal.x, 0, groundNormal.z).normalized;
		// Find the input movement direction projected onto the sliding direction
		var projectedMoveDir = Vector3.Project(inputMoveDirection, desiredVelocity);
		// Add the sliding direction, the spped control, and the sideways control vectors
		desiredVelocity = desiredVelocity + projectedMoveDir * sliding.speedControl + (inputMoveDirection - projectedMoveDir) * sliding.sidewaysControl;
		// Multiply with the sliding speed
		desiredVelocity *= sliding.slidingSpeed;
	}
	else
		desiredVelocity = GetDesiredHorizontalVelocity();
	
	if (movingPlatform.enabled && movingPlatform.movementTransfer == MovementTransferOnJump.PermaTransfer) {
		desiredVelocity += movement.frameVelocity;
		desiredVelocity.y = 0;
	}
	
	if (grounded)
		desiredVelocity = AdjustGroundVelocityToNormal(desiredVelocity, groundNormal);
	else
		velocity.y = 0;
	
	// Enforce max velocity change
	var maxVelocityChange : float = GetMaxAcceleration(grounded) * Time.deltaTime;
	var velocityChangeVector : Vector3 = (desiredVelocity - velocity);
	if (velocityChangeVector.sqrMagnitude > maxVelocityChange * maxVelocityChange) {
		velocityChangeVector = velocityChangeVector.normalized * maxVelocityChange;
	}
	// If we're in the air and don't have control, don't apply any velocity change at all.
	// If we're on the ground and don't have control we do apply it - it will correspond to friction.
	if (grounded || canControl)
		velocity += velocityChangeVector;
	
	if (grounded) {
		// When going uphill, the CharacterController will automatically move up by the needed amount.
		// Not moving it upwards manually prevent risk of lifting off from the ground.
		// When going downhill, DO move down manually, as gravity is not enough on steep hills.
		velocity.y = Mathf.Min(velocity.y, 0);
	}
	
	return velocity;
}

private function ApplyGravityAndJumping (velocity : Vector3) {
	
	if (!inputJump || !canControl) {
		jumping.holdingJumpButton = false;
		jumping.lastButtonDownTime = -100;
	}
	
	if (inputJump && jumping.lastButtonDownTime < 0 && canControl)
		jumping.lastButtonDownTime = Time.time;
	
	if (grounded)
		velocity.y = Mathf.Min(0, velocity.y) - movement.gravity * Time.deltaTime;
	else {
		velocity.y = movement.velocity.y - movement.gravity * Time.deltaTime;
		
		// When jumping up we don't apply gravity for some time when the user is holding the jump button.
		// This gives more control over jump height by pressing the button longer.
		if (jumping.jumping && jumping.holdingJumpButton) {
			// Calculate the duration that the extra jump force should have effect.
			// If we're still less than that duration after the jumping time, apply the force.
			if (Time.time < jumping.lastStartTime + jumping.extraHeight / CalculateJumpVerticalSpeed(jumping.baseHeight)) {
				// Negate the gravity we just applied, except we push in jumpDir rather than jump upwards.
				velocity += jumping.jumpDir * movement.gravity * Time.deltaTime;
			}
		}
		
		// Make sure we don't fall any faster than maxFallSpeed. This gives our character a terminal velocity.
		velocity.y = Mathf.Max (velocity.y, -movement.maxFallSpeed);
	}
		
	if (grounded) {
		// Jump only if the jump button was pressed down in the last 0.2 seconds.
		// We use this check instead of checking if it's pressed down right now
		// because players will often try to jump in the exact moment when hitting the ground after a jump
		// and if they hit the button a fraction of a second too soon and no new jump happens as a consequence,
		// it's confusing and it feels like the game is buggy.
		if (jumping.enabled && canControl && (Time.time - jumping.lastButtonDownTime < 0.2)) {
			grounded = false;
			jumping.jumping = true;
			jumping.lastStartTime = Time.time;
			jumping.lastButtonDownTime = -100;
			jumping.holdingJumpButton = true;
			
			// Calculate the jumping direction
			if (TooSteep())
				jumping.jumpDir = Vector3.Slerp(Vector3.up, groundNormal, jumping.steepPerpAmount);
			else
				jumping.jumpDir = Vector3.Slerp(Vector3.up, groundNormal, jumping.perpAmount);
			
			// Apply the jumping force to the velocity. Cancel any vertical velocity first.
			velocity.y = 0;
			velocity += jumping.jumpDir * CalculateJumpVerticalSpeed (jumping.baseHeight);
			
			// Apply inertia from platform
			if (movingPlatform.enabled &&
				(movingPlatform.movementTransfer == MovementTransferOnJump.InitTransfer ||
				movingPlatform.movementTransfer == MovementTransferOnJump.PermaTransfer)
			) {
				movement.frameVelocity = movingPlatform.platformVelocity;
				velocity += movingPlatform.platformVelocity;
			}
			
			SendMessage("OnJump", SendMessageOptions.DontRequireReceiver);
		}
		else {
			jumping.holdingJumpButton = false;
		}
	}
	
	return velocity;
}

function OnControllerColliderHit (hit : ControllerColliderHit) {
	if (hit.normal.y > 0 && hit.normal.y > groundNormal.y && hit.moveDirection.y < 0) {
		if ((hit.point - movement.lastHitPoint).sqrMagnitude > 0.001 || lastGroundNormal == Vector3.zero)
			groundNormal = hit.normal;
		else
			groundNormal = lastGroundNormal;
		
		movingPlatform.hitPlatform = hit.collider.transform;
		movement.hitPoint = hit.point;
		movement.frameVelocity = Vector3.zero;
	}
}

private function SubtractNewPlatformVelocity () {
	// When landing, subtract the velocity of the new ground from the character's velocity
	// since movement in ground is relative to the movement of the ground.
	if (movingPlatform.enabled &&
		(movingPlatform.movementTransfer == MovementTransferOnJump.InitTransfer ||
		movingPlatform.movementTransfer == MovementTransferOnJump.PermaTransfer)
	) {
		// If we landed on a new platform, we have to wait for two FixedUpdates
		// before we know the velocity of the platform under the character
		if (movingPlatform.newPlatform) {
			var platform : Transform = movingPlatform.activePlatform;
			yield WaitForFixedUpdate();
			yield WaitForFixedUpdate();
			if (grounded && platform == movingPlatform.activePlatform)
				yield 1;
		}
		movement.velocity -= movingPlatform.platformVelocity;
	}
}

private function MoveWithPlatform () : boolean {
	return (
		movingPlatform.enabled
		&& (grounded || movingPlatform.movementTransfer == MovementTransferOnJump.PermaLocked)
		&& movingPlatform.activePlatform != null
	);
}

private function GetDesiredHorizontalVelocity () {
	// Find desired velocity
	var desiredLocalDirection : Vector3 = tr.InverseTransformDirection(inputMoveDirection);
	var maxSpeed : float = MaxSpeedInDirection(desiredLocalDirection);
	if (grounded) {
		// Modify max speed on slopes based on slope speed multiplier curve
		var movementSlopeAngle = Mathf.Asin(movement.velocity.normalized.y)  * Mathf.Rad2Deg;
		maxSpeed *= movement.slopeSpeedMultiplier.Evaluate(movementSlopeAngle);
	}
	return tr.TransformDirection(desiredLocalDirection * maxSpeed);
}

private function AdjustGroundVelocityToNormal (hVelocity : Vector3, groundNormal : Vector3) : Vector3 {
	var sideways : Vector3 = Vector3.Cross(Vector3.up, hVelocity);
	return Vector3.Cross(sideways, groundNormal).normalized * hVelocity.magnitude;
}

private function IsGroundedTest () {
	return (groundNormal.y > 0.01);
}

function GetMaxAcceleration (grounded : boolean) : float {
	// Maximum acceleration on ground and in air
	if (grounded)
		return movement.maxGroundAcceleration;
	else
		return movement.maxAirAcceleration;
}

function CalculateJumpVerticalSpeed (targetJumpHeight : float) {
	// From the jump height and gravity we deduce the upwards speed 
	// for the character to reach at the apex.
	return Mathf.Sqrt (2 * targetJumpHeight * movement.gravity);
}

function IsJumping () {
	return jumping.jumping;
}

function IsSliding () {
	return (grounded && sliding.enabled && TooSteep());
}

function IsTouchingCeiling () {
	return (movement.collisionFlags & CollisionFlags.CollidedAbove) != 0;
}

function IsGrounded () {
	return grounded;
}

function TooSteep () {
	return (groundNormal.y <= Mathf.Cos(controller.slopeLimit * Mathf.Deg2Rad));
}

function GetDirection () {
	return inputMoveDirection;
}

function SetControllable (controllable : boolean) {
	canControl = controllable;
}

// Project a direction onto elliptical quater segments based on forward, sideways, and backwards speed.
// The function returns the length of the resulting vector.
function MaxSpeedInDirection (desiredMovementDirection : Vector3) : float {
	if (desiredMovementDirection == Vector3.zero)
		return 0;
	else {
		var zAxisEllipseMultiplier : float = (desiredMovementDirection.z > 0 ? movement.maxForwardSpeed : movement.maxBackwardsSpeed) / movement.maxSidewaysSpeed;
		var temp : Vector3 = new Vector3(desiredMovementDirection.x, 0, desiredMovementDirection.z / zAxisEllipseMultiplier).normalized;
		var length : float = new Vector3(temp.x, 0, temp.z * zAxisEllipseMultiplier).magnitude * movement.maxSidewaysSpeed;
		return length;
	}
}

function SetVelocity (velocity : Vector3) {
	grounded = false;
	movement.velocity = velocity;
	movement.frameVelocity = Vector3.zero;
	SendMessage("OnExternalVelocity");
}

// Require a character controller to be attached to the same game object
@script RequireComponent (CharacterController)
@script AddComponentMenu ("Character/Character Motor")

FPSInputController.js:

private var motor : CharacterMotor;

// Use this for initialization
function Awake () {
	motor = GetComponent(CharacterMotor);
}

// Update is called once per frame
function Update () {
	// Get the input vector from kayboard or analog stick
	var directionVector = new Vector3(Input.GetAxis("Horizontal"), 0, Input.GetAxis("Vertical"));
	
	if (directionVector != Vector3.zero) {
		// Get the length of the directon vector and then normalize it
		// Dividing by the length is cheaper than normalizing when we already have the length anyway
		var directionLength = directionVector.magnitude;
		directionVector = directionVector / directionLength;
		
		// Make sure the length is no bigger than 1
		directionLength = Mathf.Min(1, directionLength);
		
		// Make the input vector more sensitive towards the extremes and less sensitive in the middle
		// This makes it easier to control slow speeds when using analog sticks
		directionLength = directionLength * directionLength;
		
		// Multiply the normalized direction vector by the modified length
		directionVector = directionVector * directionLength;
	}
	
	// Apply the direction to the CharacterMotor
	motor.inputMoveDirection = transform.rotation * directionVector;
	motor.inputJump = Input.GetButton("Jump");
}

// Require a character controller to be attached to the same game object
@script RequireComponent (CharacterMotor)
@script AddComponentMenu ("Character/FPS Input Controller")

MouseLook.cs

using UnityEngine;
using System.Collections;

/// MouseLook rotates the transform based on the mouse delta.
/// Minimum and Maximum values can be used to constrain the possible rotation

/// To make an FPS style character:
/// - Create a capsule.
/// - Add the MouseLook script to the capsule.
///   -> Set the mouse look to use LookX. (You want to only turn character but not tilt it)
/// - Add FPSInputController script to the capsule
///   -> A CharacterMotor and a CharacterController component will be automatically added.

/// - Create a camera. Make the camera a child of the capsule. Reset it's transform.
/// - Add a MouseLook script to the camera.
///   -> Set the mouse look to use LookY. (You want the camera to tilt up and down like a head. The character already turns.)
[AddComponentMenu("Camera-Control/Mouse Look")]
public class MouseLook : MonoBehaviour {

	public enum RotationAxes { MouseXAndY = 0, MouseX = 1, MouseY = 2 }
	public RotationAxes axes = RotationAxes.MouseXAndY;
	public float sensitivityX = 15F;
	public float sensitivityY = 15F;

	public float minimumX = -360F;
	public float maximumX = 360F;

	public float minimumY = -60F;
	public float maximumY = 60F;

	float rotationY = 0F;

	void Update ()
	{
		if (axes == RotationAxes.MouseXAndY)
		{
			float rotationX = transform.localEulerAngles.y + Input.GetAxis("Mouse X") * sensitivityX;
			
			rotationY += Input.GetAxis("Mouse Y") * sensitivityY;
			rotationY = Mathf.Clamp (rotationY, minimumY, maximumY);
			
			transform.localEulerAngles = new Vector3(-rotationY, rotationX, 0);
		}
		else if (axes == RotationAxes.MouseX)
		{
			transform.Rotate(0, Input.GetAxis("Mouse X") * sensitivityX, 0);
		}
		else
		{
			rotationY += Input.GetAxis("Mouse Y") * sensitivityY;
			rotationY = Mathf.Clamp (rotationY, minimumY, maximumY);
			
			transform.localEulerAngles = new Vector3(-rotationY, transform.localEulerAngles.y, 0);
		}
	}
	
	void Start ()
	{
		// Make the rigid body not change rotation
		if (rigidbody)
			rigidbody.freezeRotation = true;
	}
}

If you have any queries or concerns, tell me. If not, please accept the answer properly, because many users don’t.