# KINS

NAME
SYNOPSIS
DESCRIPTION

## NAME

 kins − kinematics definitions for emc2

## DESCRIPTION

 Rather than exporting HAL pins and functions, these components provide the forward and inverse kinematics definitions for emc2.
 trivkins − Trivial Kinematics
 There is a 1:1 correspondence between joints and axes. Most standard milling machines and lathes use the trivial kinematics module.
 rotatekins − Rotated Kinematics
 The X and Y axes are rotated 45 degrees compared to the joints 0 and 1.
 tripodkins − Tripod Kinematics
 The joints represent the distance of the controlled point from three predefined locations (the motors), giving three degrees of freedom in position (XYZ)
 tripodkins.Bx
 tripodkins.Cx
 tripodkins.Cy
 The location of the three motors is (0,0), (Bx,0), and (Cx,Cy)
 genhexkins − Hexapod Kinematics
 Gives six degrees of freedom in position and orientation (XYZABC). The location of the motors is defined at compile time.
 maxkins − 5-axis kinematics example
 Kinematics for Chris Radek’s tabletop 5 axis mill named ’max’ with tilting head (B axis) and horizintal rotary mounted to the table (C axis). Provides UVW motion in the rotated coordinate system. The source file, maxkins.c, may be a useful starting point for other 5-axis systems.
 genserkins − generalized serial kinematics
 Kinematics that can model a general serial-link manipulator with up to 6 angular joints. The kinematics use Denavit-Hartenberg definition for the joint and links. The DH definitions are the ones used by John J Craig in "Introduction to Robotics: Mechanics and Control" The parameters for the manipulator are defined by hal pins.
 genserkins.A-N
 genserkins.ALPHA-N
 genserkins.D-N
 Parameters describing the Nth joint’s geometry.
 pumakins − kinematics for puma typed robots
 Kinematics for a puma-style robot with 6 joints
 pumakins.A2
 pumakins.A3
 pumakins.D3
 pumakins.D4
 Describe the geometry of the robot
 scarakins − kinematics for SCARA-type robots
 scarakins.D1
 Vertical distance from the ground plane to the center of the inner arm.
 scarakins.D2
 Horizontal distance between joint[0] axis and joint[1] axis, ie. the length of the inner arm.
 scarakins.D3
 Vertical distance from the center of the inner arm to the center of the outer arm. May be positive or negative depending on the structure of the robot.
 scarakins.D4
 Horizontal distance between joint[1] axis and joint[2] axis, ie. the length of the outer arm.
 scarakins.D5
 Vertical distance from the end effector to the tooltip. Positive means the tooltip is lower than the end effector, and is the normal case.
 scarakins.D6
 Horizontal distance from the centerline of the end effector (and the joints 2 and 3 axis) and the tooltip. Zero means the tooltip is on the centerline. Non-zero values should be positive, if negative they introduce a 180 degree offset on the value of joint[3].