I am still struggling with this problem and have additional question.

How exactly are toolpaths generated in this Steep and shallow strategy and if this is different for other strategies? Are they generated directly on the 3D surface with offset curves, or are they generated on the XY-plane and then projected onto the 3D surface?

Thanks.

Thank you very much for your answer; you provided a very good explanation! I have been trying all sorts of parameters and did additional tests after your video, and the results are better. However, in some cases, there are still very sharp declines, as in my original post (Figure 2) when we zoom in. 
I noticed that if I use the tool diameter the same as stepover distance, the results also improve.
As you mentioned, the part itself can have an impact on the machining path. Here, originally, I had the .stl part, but I converted it into a solid body in Fusion; maybe it will be better to do machining directly on the original .stl part with a more dense triangulation?

Hi, it's me again. After more testing, unfortunately, I have to un-accept your answer @a.laasW8M6T.
At the time, it seemed like it was working, but more detailed analysis showed there were still deviations. Please see the attached file, where the machining path from Fusion is compared to other software, where surface normals can deviate up to 8 degrees alongside the uneven toolpath in my original post.

I am attaching another workpiece; please take a look if somebody can. I can't find the strategy or parameters to create straight machining toolpaths in Fusion 360 CAM software, and I think it's probably impossible.

Conditions for machining path:

- 5-axis machining with tool normal to the surface (Lead and lean option)

- the strategy must offer arbitrary machining direction selection

Currently, I am only able to create those paths with Steep and Shallow strategy but if there is another option that can create straight machining toolpaths under those conditions, I will gladly use it.

I want to get confirmation on why that happens. Mainly, I want to eliminate if I am doing something in the design that results in bad toolpaths or if this is because of the underlying Fusion path planning algorithm.

Ok thank you again for all your time and help. I hope somebody from Autodesk can take a look.

Here's an explanation as to what is happening with Steep and Shallow and some methods which might help you to get a superior result

It might also be worth stating that both BLEND and FLOW both support Lead/Lean toolaxis control. However, they will not maintain a constant Y value or Parallel passes when viewing down Z.

Thank you very much for your time and help. I don't know how I didn't see this option before, but changing the smooth angle to 0 deg improved the machining for Workpiece 1 ("Fusion_example.f3d") along the 0.005 tolerance. The normal deviation has now improved (Fig. wp1_tolerance), but the downside is that there is a significant increase in points, but I can handle this. 

Applying the same tactics to Workpiece 2 (Fusion_example_WP2 v4.f3d), which is also attached in previous posts, did not yield such good results. When the tolerance is low (0.005), the path drifts out from the surface, and additional turns at the end appear (Fig. wp2_low_tolerance_dev); those turns are still visible when changing the tolerance to 0.1 (Fig. wp2_tolerance_increase).

Would you happen to have any suggestions for this workpiece? Based on the video, it seems that tool diameter can impact the machining since you can not pick a tool diameter smaller than the stepover distance in Fusion. Theoretically, if we set the tool diameter smaller, the contact point would be closer to the tooltip, and the path deviation may improve?

Dear Craig,

that's exactly what I was looking for; the paths are ideal now! Perfect!

Thank you for taking the time to investigate that problem. You have saved me a lot of time because I was already looking at some other software, but I like the simplicity and versatility of Fusion and I am very glad I can continue using it.

Yes, my demands for this machining are odd, and because all the strategies are based on milling, it was hard for me to achieve the right results. To simplify what we are doing: We are working on a robot hammer peening application, which is basically surface finishing, and there is no material removal like in the milling. Here, the hard metal ball is hammering the surface of the workpiece to improve hardness, smoothness, etc. (https://www.youtube.com/watch?v=E4zfizO65xo). We are calculating the optimal direction and robot machining speed to minimize the machining time, so the catch is that the calculated (designed) optimal directions are straight, and the robot should follow them very closely. Then we pick those optimal machining directions in Fusion, but if there are deviations from the designed directions, as initially, the machining task is not successful. That's why I need nice, smooth, and straight paths without deviations. If interested, I can send our paper, which better explains it.

Thank you again. I would also like to thank @seth.madore to forward this problem to you and of course @a.laasW8M6T who is always willing to help and was also a big part in answering my other questions.

Best regards.

Yes, this is meant for the toolmaking industry, but we are still in the research phase. We can exchange some more data in private messages.

Thanks.