# Calculate n-dimensional arc path

I'm implementing a driver for a CNC mill, and I'm having trouble implementing the G-code arc commands.

I have found several implementations of the midpoint circle algorithm, but it is not really usable as-is.

The problem with the midpoint circle algo as I found it, is that it is 2D and draws all the octants at the same time, while I need sequential steps through a 3D path, given by the start, end and center points.

I found a nice multidimensional equivalent of Bresenham’s line drawing algo using floating point operations. Maybe a similar thing exists for drawing an arc?

I might be able to bend this algo to my will using a lot of thinking and experimenting, but since drawing an arc is not an unsolved problem, and CNC machines have been made before, I wonder if an elegant solution already exists?

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Are you trying to find a path along a 1D curve in 3D space, or a path that covers a 2D curved surface in 3D space? –  Beta Apr 17 '12 at 13:19

My dxftools python package used for processing DXF files for a not very smart 2D cutter has a function to split an arc into line segments in 2D. You could use this code and then use 3D coordinate tranformations to arbitrarily place this in 3D space. Examples of coordinate transforms can be found in my py-stl package.

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In LinuxCNC, position generation is separated from step generation. In the position generating loop, the system tracks the distance it has already moved along the current primitive (line or helix) and uses a simple formula to get the location that is distance D along that primitive. (Typically, this is done once per millisecond). This position can be used in different ways depending on whether you have servos, hardware step generation, or software step generation.

In a software step generation system, the difference between the old commanded position and the new commanded position is determined along each axis, and this is used to update the rates of a digital waveform generator using the direct digital synthesis method (DDS). Then, at a higher rate (typically every 20-50µs), the DDS determines for each axis whether a step should be generated at that time.

This is a different design than you are describing, but it is a more flexible one. For instance, by separating position generation from step generation, you can revise the blending algorithm in your position generation code without revising step generation; and you can replace software step generation with hardware step generation or servo control with algorithms like PID.

In your design, you can approximate the method I describe above by simply dicing your helical arc into line segments as described by Roland, and using those as inputs into your step generation code which understands only lines. In a sense, this is not too different from what LinuxCNC does, except that the curve primitive becomes sampled according to distance instead of according to time.

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