The simplest (though not scientifically accurate) thing to do would to use Math.cos/sin paired with an updating angle value. Something like this in the frame update:

```
earthOrbitAngle += earthOrbitSpeed; //advance angle in degrees
var orbitAngleInRadians = earthOrbitAngle * Math.PI / 180; //convert to radians
//update position of earth...
earth.position.x = Math.cos(orbitAngleInRadians) * earthOrbitRadius;
earth.position.z = Math.sin(orbitAngleInRadians) * earthOrbitRadius;
```

You could elongate either the x or z value to make the orbit elliptical by multiplying earthOrbitRadius by some factor.

You could tilt the earth just by setting it's rotation.z. However, if you want to have the Moon and have it orbit around the tilted axis, then easiest thing to do is create an empty Object3D container to hold the two, with the moon running its own orbiting script. Then you animate that container around the Sun. So the set up would look something like this:

```
theSun = new THREE.Mesh(new THREE.SphereGeometry(30, 16, 15), new THREE.MeshBasicMaterial({
color: 'yellow'
}));
scene.add(theSun);
theEarthAndMoon = new THREE.Object3D();
theEarthAndMoon.rotation.z = 23.439281 * Math.PI / 180; //tilt of earth in radians;
scene.add(theEarthAndMoon);
theEarth = new THREE.Mesh(new THREE.SphereGeometry(5, 16, 15), new THREE.MeshLambertMaterial({
color:"blue"
}));
theEarthAndMoon.add(theEarth);
theMoon = new THREE.Mesh(new THREE.SphereGeometry(1, 16, 15), new THREE.MeshLambertMaterial({
color:"white"
}));
theEarthAndMoon.add(theMoon);
```

And in the frame update:

```
//run the earth's orbit around the Sun
earthOrbitAngle += earthOrbitSpeed;
var radians = earthOrbitAngle * Math.PI / 180;
theEarthAndMoon.position.x = Math.cos(radians) * earthOrbitRadius;
theEarthAndMoon.position.z = Math.sin(radians) * earthOrbitRadius;
//run the Moon's orbit around the Earth
moonOrbitAngle += moonOrbitSpeed;
var moonRadians = moonOrbitAngle * Math.PI / 180;
theMoon.position.x = Math.cos(moonRadians) * moonOrbitRadius;
theMoon.position.z = Math.sin(moonRadians) * moonOrbitRadius;
```

You can see it running here: Simple Sun, Earth, and Moon at JSFiddle

Now, if you want to go deep down the rabbit hole of accurate orbiting mechanics, I would suggest starting with looking under the hood of this incredible Three.js simulation of all the planets and 600,000 asteroids: Asterank project

"I think I only need to edit the position of x axis, right?"I don't think that will work. At some point, the Earth's position will lie on top of the x axis, at which point subtracting 1 and normalizing won't change its position at all. You should consider coming up with a different strategy. – Kevin Jan 14 '14 at 18:19