Difference between revisions of "Denavit-Hartenberg parameters"

Revision as of 12:30, 16 November 2015

Overview: Denavit-Hartenberg Convention

When the coordinate frames are assigned to a manipulator, the transformation between each two consecutive frames has to be described. As before for the assignment of the coordinate frames, the manipulator has to be in its zero position as well for the determination of the parameters. The figure on the right shows the two coordinate frames $K_{n-1}$ and $K_n$ in their zero position and the corresponding common normal represented by a dashed red line. To describe the transformation of $K_n$ with respect to $K_{n-1}$ , the 4 Denavit-Hartenberg parameters $\theta_n$ , $d_n$ , $l_n$ and $\alpha_n$ are used. These parameters describe the static transformation within link $L_n$ , but as well include the dynamic influence of the joint parameter of $J_n$ , that could change over time. The figure illustrates the parameters, that are defined as follows:

\theta_n

The angle $\theta_n$ is defined as the angle about the $z_{n-1}$ -axis to align $x_{n-1}$ with the new $x_{n}$ -axis.

In case of a revolute joint: The Denavit-Hartenberg parameters should include the dynamic influence of the joints. So as a revolute joint $J_n$ located in the coordinate frame $K_{n-1}$ allows for a rotation about the $z_{n-1}$ -axis, the joint parameter (here $\theta_J$ ) has to be included in the Denavit-Hartenberg parameter $\theta_n$ .

The figure on the right shows a link

L_n

in dark grey with the two coordinate frames

K_{n-1}

at its beginning and

K_{n}

at the distal joint. The coordinate frames are shown in their zero position. The angle

\theta_L

describes the rotation about the

z_{n-1}

-axis to align the two

x

-axes.

So in case of a revolute joint, there is not only the static rotation by

\theta_L

, but as well the dynamic rotation angle

\theta_J

caused by the joint itself. Thus the parameter

\theta_n

is the sum of the static and the dynamic rotation:

\theta_n = \theta_L + \theta_J

Hint: In the Robotics course at the University of Paderborn, cases with a static rotation

\theta_L

for a revolute joint are usually avoided. So for revolute joints, there is only the actual joint parameter as

\theta_n

and the

x

-axes are aligned in their zero position.

d_n

$d$ is the offset or translation, respectively, along the $z_{n-1}$ -axis from the origin of $K_{n-1}$ to the intersection with the common normal.

l_n

The parameter $l$ corresponds to the length of the common normal which is equivalent to the translation along it.

If the related joint $J_n$ is a revolute joint, $l$ can also be regarded as the radius of the rotation about the $z_{n-1}$ -axis

\alpha_n

The angle $\alpha$ corresponds to the angle about the common normal to align the $z_{n-1}$ -axis with the new $z_{n}$ -axis

Special case: It can occur that there is an offset ...

The 4 parameters can rather be determined by just regarding the two coordinate frames, their axes and the common normal like visualized above. To completely understand the parameters and their meaning, the figure below illustrates what the parameters actually describe. $\theta$ , $d$ , $l$ and $\alpha$ define 4 transformations that are applied consecutively to transform the coordinate frame $K_{n-1}$ to $K_n$ . First a rotation about the $x_{n-1}$ -axis by $\alpha$ is applied followed by a translation along it by $l$ . Then the coordinate frame is rotated about the $z_{n-1}$ -axis by $\theta$ . Finally a translation along the $z_{n-1}$ -axis leads to the next coordinate frame $K_n$ . Some further aspects about the meaning and the use of the 4 parameters are described in the following article about the A-matrices.

The video at the end of this page explains the assignment of the coordinate frames and the determination of the 4 parameters very vividly and comprehensibly.

Hint: Notation of the Denavit-Hartenberg parameters
The Denavit-Hartenberg parameters are usually noted in a table with columns for the parameters and a row for each link or transformation, respectively.

T	$\theta$	$d$	$l$	$\alpha$
1	$\theta_1$	$d_1$	$l_1$	$\alpha_1$
...

Example: Determination of the Denavit-Hartenberg parameters

The table below contains the Denavit-Hartenberg parameters for the manipulator shown in the figure on the right. For further information about the already assigned coordinate frames, have a look on the examples of the previous articles. The necessary lengths of certain parts of the manipulator are indicated by the variables $k_1$ to $k_7$ .

T	$\theta$	$d$	$l$	$\alpha$
1	$\theta_1$	$k_1$	$-k_2$	$-90^\circ$
2	$\theta_2$	$k_3$	$0$	$0^\circ$
3	$0^\circ$	$k_4$	$0$	$-90^\circ$
4	$-90^\circ+\theta_4$	$k_5$	$k_6$	$180^\circ$
5	$\theta_5$	$0$	$k_7$	$0^\circ$

Multimedial educational material

https://www.youtube.com/watch?v=qZB3_gKBwf8 Video: Assignment of coordinate frames and determination of the parameters (in German)

@@ Line 18: / Line 18: @@
 :So in case of a revolute joint, there is not only the static rotation by <math>\theta_L</math>, but as well the dynamic rotation angle <math>\theta_J</math> caused by the joint itself. Thus the parameter <math>\theta_n</math> is the sum of the static and the dynamic rotation:
-:<math>
+::<math>
 \theta_n = \theta_L + \theta_J
 </math>

Difference between revisions of "Denavit-Hartenberg parameters"

Revision as of 12:30, 16 November 2015

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