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You're reading from Unity 5.x Game AI Programming Cookbook

Product type Book

Published in Mar 2016

Publisher Packt

ISBN-13 9781783553570

Pages 278 pages

Edition 1st Edition

Languages

Concepts

Game Artificial Intelligence

Author (1):

Jorge Palacios

Table of Contents (15) Chapters

Unity 5.x Game AI Programming Cookbook

Credits

About the Author

About the Reviewers

www.PacktPub.com

Preface

1. Behaviors – Intelligent Movement

2. Navigation

3. Decision Making

4. Coordination and Tactics

5. Agent Awareness

6. Board Games AI

7. Learning Techniques

8. Miscellaneous

Index

Facing objects

Real-world aiming, just like in combat simulators, works a little differently from the widely-used automatic aiming in almost every game. Imagine that you need to implement an agent controlling a tank turret or a humanized sniper; that's when this recipe comes in handy.

Getting ready

We need to make some modifications to our AgentBehaviour class:

Add new member values to limit some of the existing ones:

public float maxSpeed;
public float maxAccel;
public float maxRotation;
public float maxAngularAccel;

Add a function called MapToRange. This function helps in finding the actual direction of rotation after two orientation values are subtracted:

public float MapToRange (float rotation) {
    rotation %= 360.0f;
    if (Mathf.Abs(rotation) > 180.0f) {
        if (rotation < 0.0f)
            rotation += 360.0f;
        else
            rotation -= 360.0f;
    }
    return rotation;
}

Also, we need to create a basic behavior called Align that is the stepping stone for the facing algorithm. It uses the same principle as Arrive, but only in terms of rotation:

using UnityEngine;
using System.Collections;

public class Align : AgentBehaviour
{
    public float targetRadius;
    public float slowRadius;
    public float timeToTarget = 0.1f;

    public override Steering GetSteering()
    {
        Steering steering = new Steering();
        float targetOrientation = target.GetComponent<Agent>().orientation;
        float rotation = targetOrientation - agent.orientation;
        rotation = MapToRange(rotation);
        float rotationSize = Mathf.Abs(rotation);
        if (rotationSize < targetRadius)
            return steering;
        float targetRotation;
        if (rotationSize > slowRadius)
            targetRotation = agent.maxRotation;
        else
            targetRotation = agent.maxRotation * rotationSize / slowRadius;
        targetRotation *= rotation / rotationSize;
        steering.angular = targetRotation - agent.rotation;
        steering.angular /= timeToTarget;
        float angularAccel = Mathf.Abs(steering.angular);
        if (angularAccel > agent.maxAngularAccel)
        {
            steering.angular /= angularAccel;
            steering.angular *= agent.maxAngularAccel;
        }
        return steering;
    }
}

How to do it...

We now proceed to implement our facing algorithm that derives from Align:

Create the Face class along with a private auxiliary target member variable:

using UnityEngine;
using System.Collections;

public class Face : Align
{
    protected GameObject targetAux;
}

Override the Awake function to set up everything and swap references:

public override void Awake()
{
    base.Awake();
    targetAux = target;
    target = new GameObject();
    target.AddComponent<Agent>();
}

Also, implement the OnDestroy function to handle references and avoid memory issues:
```
void OnDestroy ()
{
    Destroy(target);
}
```

Finally, define the GetSteering function:

public override Steering GetSteering()
{
    Vector3 direction = targetAux.transform.position - transform.position;
    if (direction.magnitude > 0.0f)
    {
        float targetOrientation = Mathf.Atan2(direction.x, direction.z);
        targetOrientation *= Mathf.Rad2Deg;
        target.GetComponent<Agent>().orientation = targetOrientation;
    }
    return base.GetSteering();
}

How it works...

The algorithm computes the internal target orientation according to the vector between the agent and the real target. Then, it just delegates the work to its parent class.