The way to do this is by using an additional (helper) SCNNode. You'll use the fact that it adds its own coordinate system and that all of its Child Nodes will move together with that (helper) coordinate system. The child nodes that are off-centre will effectively be orbiting if you view them from the world coordinate system.

You add the **HelperNode** at the **centre** of your FixedPlanetNode (orbited planet), perhaps as its child, but definitely at the same position

You add your OrbitingPlanetNode as a **child** to the **HelperNode**, but with an **offset** on one of the axes, e.g. 10 points on the X axis

You start the **HelperNode** rotating (together with its coordinate system) around a **different** axis, e.g. the Y axis

This will result in the OrbitingPlanetNode orbiting around the Y axis of HelperNode with an orbit radius of 10 points.

EXAMPLE

`earthNode`

- fixed orbited planet

`moonNode`

- orbiting planet

`helperNode`

- helper node added to provide coordinate system

```
// assuming all planet geometry is at the centre of corresponding nodes
// also helperNode.position is set to (0, 0, 0)
[earthNode addChildNode:helperNode];
moonNode.position = SCNVector3Make(10, 0, 0);
[helperNode addChildNode:moonNode];
// set helperNode to rotate forever
SCNAction * rotation = [SCNAction rotateByX:0 y:3 z:0];
SCNAction * infiniteRotation = [SCNAction repeatActionForever:rotation];
[helperNode runAction:infiniteRotation];
```

I used actions and objective-c as this is what I am familiar with, but should be perfectly doable in Swift and with animations.