Difference between revisions of "Program Examples:Robot tool calibration/zh-hans"
(Created page with "{{Languages}} here is an example of how to use tool calibration in case of non-existing deterministic world-frame-point. the procedure includes moving the tool to a certain po...") |
|||
| Line 1: | Line 1: | ||
| − | {{Languages}} | + | {{Languages|Program_Examples:Robot_tool_calibration}} |
| − | + | 以下是在不存在的确定性世界坐标系点的情况下如何使用工具校准的示例。该过程包括将工具移动到特定位置几次但具有不同的姿态,这种测量的结果是围绕工具尖端的球体。数学表达式如下: | |
| − | |||
| − | |||
point1 = {X1, Y1, Z1} | point1 = {X1, Y1, Z1} | ||
Latest revision as of 06:06, 17 July 2017
| 语言: | English • 中文(简体) |
|---|
以下是在不存在的确定性世界坐标系点的情况下如何使用工具校准的示例。该过程包括将工具移动到特定位置几次但具有不同的姿态,这种测量的结果是围绕工具尖端的球体。数学表达式如下:
point1 = {X1, Y1, Z1}
point2 = {X2, Y2, Z2}
point3 = {X3, Y3, Z3}
point4 = {X4, Y4, Z4}
shpere: Const = (X-Xc)^2 + (Y-Yc)^2 + (Z-Zc)^2
Const = (X1-Xc)^2 + (Y1-Yc)^2 + (Z1-Zc)^2
Const = (X2-Xc)^2 + (Y2-Yc)^2 + (Z2-Zc)^2
Const = (X3-Xc)^2 + (Y3-Yc)^2 + (Z3-Zc)^2
Const = (X4-Xc)^2 + (Y4-Yc)^2 + (Z4-Zc)^2
| 2(x2-x1) 2(y2-y1) 2 z2-z1) | |Xc| = | X2^2 - X1^2 + Y2^2 - Y1^2 + Z2^2 - Z1^2 |
| 2(x3-x1) 2(y3-y1) 2 z3-z1) |*|Yc| = | X3^2 - X1^2 + Y3^2 - Y1^2 + Z3^2 - Z1^2 |
| 2(x4-x1) 2(y4-y1) 2 z4-z1) | |Zc| = | X4^2 - X1^2 + Y4^2 - Y1^2 + Z4^2 - Z1^2 |
[MatA] * vecB = vecC
vecB = [MatA]^-1 * vecC
' in proto.pro import_c RBT_TOOL_CALIBRATION_SPHERE(byval as generic location, byval as generic location, byval as generic location, byval as generic location, as generic location) as long
common shared locArr[5] as generic location
program
locArr[1] = puma.setpoint
locArr[2] = puma.setpoint
locArr[3] = puma.setpoint
locArr[4] = puma.setpoint
locArr[5] = puma.setpoint
locArr[1] = #{0,0,20,0,0,0}
locArr[2] = #{0,10,10,0,0,0}
locArr[3] = #{10,0,10,0,0,0}
locArr[4] = #{0,-10,10,0,0,0}
locArr[5] = #{0,0,0,0,0,0}
?RBT_TOOL_CALIBRATION_SPHERE(locArr[1], locArr[2], locArr[3], locArr[4], locArr[5])
? "sphere center: " locArr[5]
end program