Paden–Kahan subproblems

Paden–Kahan subproblems are a set of solved geometric problems which occur frequently in inverse kinematics of common robotic manipulators.^[1] Although the set of problems is not exhaustive, it may be used to simplify inverse kinematic analysis for many industrial robots.^[2] Beyond the three classical subproblems several others have been proposed.^[3]^[4]

Simplification strategies[edit]

For a structure equation defined by the product of exponentials method, Paden–Kahan subproblems may be used to simplify and solve the inverse kinematics problem. Notably, the matrix exponentials are non-commutative.

Generally, subproblems are applied to solve for particular points in the inverse kinematics problem (e.g., the intersection of joint axes) in order to solve for joint angles.

Eliminating revolute joints[edit]

Simplification is accomplished by the principle that a rotation has no effect on a point lying on its axis. For example, if the point ${\textstyle p}$ is on the axis of a revolute twist ${\textstyle \xi }$ , its position is unaffected by the actuation of the twist. To wit:

e^{{\widehat {\xi }}\theta }p=p

Thus, for a structure equation

e^{{\widehat {\xi }}_{1}\theta _{1}}e^{{\widehat {\xi }}_{2}\theta _{2}}e^{{\widehat {\xi }}_{3}\theta _{3}}=g

where

{\textstyle \xi _{1}}

,

{\textstyle \xi _{2}}

and

{\textstyle \xi _{3}}

are all zero-pitch twists, applying both sides of the equation to a point

{\textstyle p}

which is on the axis of

{\textstyle \xi _{3}}

(but not on the axes of

{\textstyle \xi _{1}}

or

{\textstyle \xi _{2}}

) yields

e^{{\widehat {\xi }}_{1}\theta _{1}}e^{{\widehat {\xi }}_{2}\theta _{2}}e^{{\widehat {\xi }}_{3}\theta _{3}}p=gp

By the cancellation of

{\textstyle \xi _{3}}

, this yields

e^{{\widehat {\xi }}_{1}\theta _{1}}e^{{\widehat {\xi }}_{2}\theta _{2}}p=gp

which, if

{\textstyle \xi _{1}}

and

{\textstyle \xi _{2}}

intersect, may be solved by Subproblem 2.

Norm[edit]

In some cases, the problem may also be simplified by subtracting a point from both sides of the equation and taking the norm of the result.

For example, to solve

e^{{\widehat {\xi }}_{1}\theta _{1}}e^{{\widehat {\xi }}_{2}\theta _{2}}e^{{\widehat {\xi }}_{3}\theta _{3}}=g

for

{\textstyle \xi _{3}}

, where

{\textstyle \xi _{1}}

and

{\textstyle \xi _{2}}

intersect at the point

{\textstyle q}

, both sides of the equation may be applied to a point

{\textstyle p}

that is not on the axis of

{\textstyle \xi _{3}}

. Subtracting

{\textstyle q}

and taking the norm of both sides yields

{\begin{aligned}\delta _{i}=\|gp-q\|=\|e^{{\widehat {\xi }}_{1}\theta _{1}}e^{{\widehat {\xi }}_{2}\theta _{2}}e^{{\widehat {\xi }}_{3}\theta _{3}}p-q\|=\|e^{{\widehat {\xi }}_{1}\theta _{1}}e^{{\widehat {\xi }}_{2}\theta _{2}}(e^{{\widehat {\xi }}_{3}\theta _{3}}p-q)\|=\|e^{{\widehat {\xi }}_{3}\theta _{3}}p-q\|\end{aligned}}

This may be solved using Subproblem 3.

List of subproblems[edit]

Each subproblem is presented as an algorithm based on a geometric proof. Code to solve a given subproblem, which should be written to account for cases with multiple solutions or no solution, may be integrated into inverse kinematics algorithms for a wide range of robots.

Subproblem 1: Rotation about a single axis[edit]

Let ${\textstyle \xi }$ be a zero-pitch twist with unit magnitude and ${\textstyle p,q\in \mathbb {R} ^{3}}$ be two points. Find ${\textstyle \theta }$ such that

e^{{\widehat {\xi }}\theta }p=q.

In this subproblem, a point ${\textstyle p}$ is rotated around a given axis ${\textstyle \xi }$ such that it coincides with a second point ${\textstyle q}$ .

Solution[edit]

Let ${\textstyle r}$ be a point on the axis of ${\textstyle \xi }$ . Define the vectors ${\textstyle u=(p-r)}$ and ${\textstyle v=(q-r)}$ . Since ${\textstyle r}$ is on the axis of ${\textstyle \xi }$ , ${\textstyle e^{{\widehat {\xi }}\theta }r=r.}$ Therefore, ${\textstyle e^{{\widehat {\omega }}\theta }u=v.}$

Next, the vectors ${\textstyle u'}$ and ${\textstyle v'}$ are defined to be the projections of ${\textstyle u}$ and ${\textstyle v}$ onto the plane perpendicular to the axis of ${\textstyle \xi }$ . For a vector ${\textstyle \omega \in \mathbb {R} }$ in the direction of the axis of ${\textstyle \xi }$ ,

u'=u-\omega \omega ^{T}u

and

v'=v-\omega \omega ^{T}v.

In the event that

{\textstyle u'=0}

,

{\textstyle p=q}

and both points lie on the axis of rotation. The subproblem therefore yields an infinite number of possible solutions in that case.

In order for the problem to have a solution, it is necessary that the projections of ${\textstyle u}$ and ${\textstyle v}$ onto the ${\textstyle \omega }$ axis and onto the plane perpendicular to ${\textstyle \omega }$ have equal lengths. It is necessary to check, to wit, that:

\omega ^{T}u=\omega ^{T}v

and that

\|u'\|=\|v'\|

If these equations are satisfied, the value of the joint angle ${\textstyle \theta }$ may be found using the atan2 function:

\theta =\mathrm {atan2} (\omega ^{T}(u'\times v'),u'^{T}v').

Provided that

{\textstyle u'\neq 0}

, this subproblem should yield one solution for

{\textstyle \theta }

.

Subproblem 2: Rotation about two subsequent axes[edit]

Let ${\textstyle \xi _{1}}$ and ${\textstyle \xi _{2}}$ be two zero-pitch twists with unit magnitude and intersecting axes. Let ${\textstyle p,q\in \mathbb {R} ^{3}}$ be two points. Find ${\textstyle \theta _{1}}$ and ${\textstyle \theta _{2}}$ such that $e^{{\widehat {\xi }}_{1}\theta _{1}}e^{{\widehat {\xi }}_{2}\theta _{2}}p=q.$

This problem corresponds to rotating ${\textstyle p}$ around the axis of ${\textstyle \xi _{2}}$ by ${\textstyle \theta _{2}}$ , then rotating it around the axis of ${\textstyle \xi _{1}}$ by ${\textstyle \theta _{1}}$ , so that the final location of ${\textstyle p}$ is coincident with ${\textstyle q}$ . (If the axes of ${\textstyle \xi _{1}}$ and ${\textstyle \xi _{2}}$ are coincident, then this problem reduces to Subproblem 1, admitting all solutions such that ${\textstyle \theta _{1}+\theta _{2}=\theta }$ .)

Solution[edit]

Provided that the two axes are not parallel (i.e., ${\textstyle \omega _{1}\neq \omega _{2}}$ ), let ${\textstyle c}$ be a point such that

e^{{\widehat {\xi }}_{2}\theta _{2}}p=c=e^{-{\widehat {\xi }}_{1}\theta _{1}}q.

In other words,

{\textstyle c}

represents the point to which

{\textstyle p}

is rotated around one axis before it is rotated around the other axis to be coincident with

{\textstyle q}

. Each individual rotation is equivalent to Subproblem 1, but it's necessary to identify one or more valid solutions for

{\textstyle c}

in order to solve for the rotations.

Let ${\textstyle r}$ be the point of intersection of the two axes:

e^{{\widehat {\xi }}_{2}\theta _{2}}(p-r)=c-r=e^{-{\widehat {\xi }}_{1}\theta _{1}}(q-r).

Define the vectors ${\textstyle u=(p-r)}$ , ${\textstyle v=(q-r)}$ and ${\textstyle z=(c-r)}$ . Therefore,

e^{{\widehat {\xi }}_{2}\theta _{2}}u=z=e^{-{\widehat {\xi }}_{1}\theta _{1}}v.

This implies that ${\textstyle \omega _{2}^{T}u=\omega _{2}^{T}z}$ , ${\textstyle \omega _{1}^{T}v=\omega _{1}^{T}z}$ , and ${\textstyle \|u\|^{2}=\|z\|^{2}=\|v\|^{2}}$ . Since ${\textstyle \omega _{1}}$ , ${\textstyle \omega _{2}}$ and ${\textstyle \omega _{1}\times \omega _{2}}$ are linearly independent, ${\textstyle z}$ can be written as

z=\alpha \omega _{1}+\beta \omega _{2}+\gamma (\omega _{1}\times \omega _{2}).

The values of the coefficients may be solved thus:

\alpha ={\frac {(\omega _{1}^{T}\omega _{2})\omega _{2}^{T}u-\omega _{1}^{T}v}{(\omega _{1}^{T}\omega _{2})^{2}-1}}

\beta ={\frac {(\omega _{1}^{T}\omega _{2})\omega _{1}^{T}v-\omega _{2}^{T}u}{(\omega _{1}^{T}\omega _{2})^{2}-1}}

, and

\gamma ^{2}={\frac {\|u\|^{2}-\alpha ^{2}-\beta ^{2}-2\alpha \beta \omega _{1}^{T}\omega _{2}}{\|\omega _{1}\times \omega _{2}\|^{2}.}}

The subproblem yields two solutions in the event that the circles intersect at two points; one solution if the circles are tangential; and no solution if the circles fail to intersect.

Subproblem 3: Rotation to a given distance[edit]

Let ${\textstyle \xi }$ be a zero-pitch twist with unit magnitude; let ${\textstyle p,q\in \mathbb {R} ^{3}}$ be two points; and let ${\textstyle \delta }$ be a real number greater than 0. Find ${\textstyle \theta }$ such that $\|q-e^{{\widehat {\xi }}\theta }p\|=\delta .$

In this problem, a point ${\textstyle p}$ is rotated about an axis ${\textstyle \xi }$ until the point is a distance ${\textstyle \delta }$ from a point ${\textstyle q}$ . In order for a solution to exist, the circle defined by rotating ${\textstyle p}$ around ${\textstyle \xi }$ must intersect a sphere of radius ${\textstyle \delta }$ centered at ${\textstyle q}$ .

Solution[edit]

Let ${\textstyle r}$ be a point on the axis of ${\textstyle \xi }$ . The vectors ${\textstyle u=(p-r)}$ and ${\textstyle v=(q-r)}$ are defined so that

\|v-e^{{\widehat {\xi }}\theta }u\|^{2}=\delta ^{2}.

The projections of ${\textstyle u}$ and ${\textstyle v}$ are ${\textstyle u'=u-\omega \omega ^{T}u}$ and ${\textstyle v'=v-\omega \omega ^{T}v.}$ The “projection” of the line segment defined by ${\textstyle \delta }$ is found by subtracting the component of ${\textstyle p-q}$ in the ${\textstyle \omega }$ direction:

\delta '^{2}=\delta ^{2}-|\omega ^{T}(p-q)|^{2}.

The angle

{\textstyle \theta _{0}}

between the vectors

{\textstyle u'}

and

{\textstyle v'}

is found using the atan2 function:

\theta _{0}=atan2(\omega ^{T}(u'\times v'),u'^{T}v').

The joint angle

{\textstyle \theta }

is found by the formula

\theta =\theta _{0}\pm \cos ^{-1}\left({\frac {\|u'\|^{2}+\|v'\|^{2}-\delta '^{2}}{2\|u'\|\|v'\|}}\right).

This subproblem may yield zero, one, or two solutions, depending on the number of points at which the circle of radius

{\textstyle \|u'\|}

intersects the circle of radius

{\textstyle \delta '}

.

Subproblem 4: Rotation about two axes to a given distance[edit]

Let ${\textstyle \xi _{1}}$ and ${\textstyle \xi _{2}}$ be two zero-pitch twists with unit magnitude and intersecting axes. Let ${\textstyle p,q_{1},q_{2}\in \mathbb {R} ^{3}}$ be points. Find ${\textstyle \theta _{1}}$ and ${\textstyle \theta _{2}}$ such that $\|e^{{\widehat {\xi }}_{1}\theta _{1}}e^{{\widehat {\xi }}_{2}\theta _{2}}p-q_{1}\|=\delta _{1}$ and

\|e^{{\widehat {\xi }}_{1}\theta _{1}}e^{{\widehat {\xi }}_{2}\theta _{2}}p-q_{2}\|=\delta _{2}.

This problem is analogous to Subproblem 2, except that the final point is constrained by distances to two known points.

Subproblem 5: Translation to a given distance[edit]

Let ${\textstyle \xi }$ be an infinite-pitch unit magnitude twist; ${\textstyle p,q\in \mathbb {R} ^{3}}$ two points; and ${\textstyle \delta }$ a real number greater than 0. Find ${\textstyle \theta }$ such that $\|q-e^{{\widehat {\xi }}\theta }p\|=\delta .$

References[edit]

^ Paden, Bradley Evan (1985). "Kinematics and Control of Robot Manipulators". Ph.D. Thesis. Bibcode:1985PhDT........94P.
^ Sastry, Richard M. Murray; Zexiang Li; S. Shankar (1994). A mathematical introduction to robotic manipulation (PDF) (1. [Dr.] ed.). Boca Raton, Fla.: CRC Press. ISBN 9780849379819.{{cite book}}: CS1 maint: multiple names: authors list (link)
^ Pardos-Gotor, Jose (2021). Screw Theory in Robotics: An Illustrated and Practicable Introduction to Modern Mechanics. doi:10.1201/9781003216858. ISBN 9781003216858. S2CID 239896825.
^ Elias, Alexander J.; Wen, John T. (2022-11-10). "Canonical Subproblems for Robot Inverse Kinematics". arXiv:2211.05737 [cs.RO].

[1] Paden, Bradley Evan (1985). "Kinematics and Control of Robot Manipulators". Ph.D. Thesis. Bibcode:1985PhDT........94P.

[2] Sastry, Richard M. Murray; Zexiang Li; S. Shankar (1994). A mathematical introduction to robotic manipulation (PDF) (1. [Dr.] ed.). Boca Raton, Fla.: CRC Press. ISBN 9780849379819.{{cite book}}: CS1 maint: multiple names: authors list (link)

[3] Pardos-Gotor, Jose (2021). Screw Theory in Robotics: An Illustrated and Practicable Introduction to Modern Mechanics. doi:10.1201/9781003216858. ISBN 9781003216858. S2CID 239896825.

[4] Elias, Alexander J.; Wen, John T. (2022-11-10). "Canonical Subproblems for Robot Inverse Kinematics". arXiv:2211.05737 [cs.RO].

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