Wiki source code of SES-PRO Robotic Arm UI

Version 52.1 by Eric Nantel on 2024/10/16 12:40
Show last authors
1 {{lightbox image="https://wiki.lynxmotion.com/info/wiki/lynxmotion/download/ses-pro/ses-pro-software/ses-pro-arm-ui/WebHome/SES-PRO-Robotic-Arm-UI.png" width="350"/}}
2
3 [[[[image:[email protected]]]>>https://lynxmotion.com/tools/ses-pro-app/lynxmotion_ses_pro_robotic_arm_ui_stable.exe]]
4
5 **Table of Contents**
6
7 {{toc/}}
8
9 = Description =
10
11 The Lynxmotion Servo Erector Set Professional (SES PRO) Robotic Arm User Interface (UI) is a simple software which allows a user to control any of the Lynxmotion Professional Modular robotic arms in their default configuration. The two compatible gripper kits which are compatible with the SES PRO system (based on the DH Robotics PGE-50-40 and CGE-10-10 DC grillers) can also be controlled via this interface in each of their possible configurations. The included manual jog feature can be used to either position each joint angle, or move to specific cartesian coordinates. Arm (and gripper) positions can then be recorded as part of the built-in sequencer. A 3D display of the arm shows the position of the arm, and a graph can be used to show various information to the user. In order to get a better understanding of the protocol, commands sent to the arm are shown in the interface, and a user input field are standard.
12
13 = Features =
14
15 * Angular and cartesian positioning of the end effector
16 * 3D graphical display of the appropriate robotic arm and end effector
17 * Sequencer to record and play back frames (single, looped or infinite)
18 * Error checking (speed, temperature etc.)
19 * Command output and user input
20 * Safety (Software E-Stop, Halt&Hold & Limp)
21
22 __Compatibility: Windows 7 Operating System or above__
23
24
25 |(% colspan="3" %)(((
26 = User Guide =
27 )))
28 |(% style="width:25px" %) |(% colspan="2" rowspan="1" style="width:100px" %)(((
29 Before proceeding with the guide, it is important to note the following:
30
31 * Neither the servos nor the arm are meant to be operated in proximity of humans as they do not have "collaborative" (COBOT) features and do not detect collision
32 * The servos use stepper motors and do NOT include mechanical brakes. If the stepper motor is unable to retain or move to a desired angle (insufficient torque), the motor will rotate freely as opposed to hold the last position
33 )))
34 | |(% style="text-align:center; vertical-align:middle; width:125px" %)[[image:ses-pro-robotic-arm-ui-info.png]]|Pressing the i "Information" icon in the software will bring you to this page.
35 | |(% colspan="2" rowspan="1" %)(((
36 == IMPORTANT ==
37 )))
38 | |(% colspan="2" rowspan="1" %)(((
39 === Payload Considerations ===
40 )))
41 | |(% colspan="2" rowspan="1" %)(((
42 1. The rated payload for each arm does NOT include an end effector, nor any added distance between the center of mass of the payload and the output of the final joint. Each of the two compatible Lynxmotion PRO grippers reduce the maximum payload of each arm, and it is up to the user to known and understand the concept of "torque" and center of mass before adding an end effector and payload.
43 1. The rated maximum payload for each arm (at full reach) is at the rated speed for each motor. Moving any joint at a higher speed will decrease the payload capacity of the robot.
44 1. Although each servo can provide significantly more torque than is needed for the rated payload (and therefore means the arm can support much higher loads at lower speeds, the mechanical and modular structure of the arms may fail. We strongly suggest testing and using each arm in a highly controlled and safe setting where, if a failure should occur with one or more joints, that nothing will break should the arm fall.
45 1. The stepper motors provide the highest torque at low speeds, and lower torque at high speeds. Note that the maxium torque is not at the lowest speed as the torque to rpm curve for each servo resembles a "mountain".
46 )))
47 | |(% colspan="2" rowspan="1" %)(((
48 === Emergency ===
49 )))
50 | |(% colspan="2" rowspan="1" %)Before using the arm, it is important that a user know what to do when an issue or emergency arises where the arm must be stopped quickly. 
51 The following emergency options are available based on severity:
52 | |(% style="text-align:center; vertical-align:middle" %)[[image:ses-pro-robotic-arm-ui-halt.png]]|(((
53 **Halt (and hold)**
54
55 This will stop every joints and hold them in their last recorded angular positions. The corresponding command is #254H<cr>.
56 )))
57 | |(% style="text-align:center; vertical-align:middle" %)[[image:ses-pro-robotic-arm-ui-limp.png]]|(((
58 **Limp**
59
60 All joints will go limp which mean there will be nothing avoiding them to turn freely (potentially causing the arm to fall). The high gear ratio of the strain wave gearing does mean there is some (low) level of resistant to rotation, but the gears and motor are nto "locked" and as such, the arm may fall. The corresponding command is #254L<cr>.
61 )))
62 | |(% style="text-align:center; vertical-align:middle" %)[[image:ses-pro-robotic-arm-ui-arm-emergency.png]]|(((
63 **Software E-Stop**
64
65 The E-stop button within the software sets all joints to limp, this can possibly cause the arm to fall.
66 )))
67 | |(% style="text-align:center; vertical-align:middle" %) |(((
68 **Power Supply E-Stop**
69
70 A hardware E-stop (push to cut power) button is located on the power supply which will cut electricity to all actuators. Similar to a limp command, this can possibly cause the arm to fall. To reset this button, rotate the red "mushroom" in the direction indicated by the white arrows and it will spring out.
71 )))
72 | |(% colspan="2" rowspan="1" %)(((
73 == Arm Connection ==
74 )))
75 | |(% style="text-align:center; vertical-align:middle" %)[[image:ses-pro-robotic-arm-ui-arm-version.png]]|(((
76 **Model**
77
78 The software currently supports the following Lynxmotion PRO Arms:
79
80 * 550mm 5DoF
81 * 550mm 6DoF
82 * 900mm 5DoF
83 * 900mm 6DoF
84
85 In practice, each 5DoF arm has joint 4 at a fixed angle, otherwise the arms are identical to the 6DoF. Users can always purchase the missing actuator to upgrade to a 6DoF.
86 )))
87 | |(% style="text-align:center; vertical-align:middle" %)[[image:ses-pro-robotic-arm-ui-com.png]]|(((
88 **COM Port**
89
90 The first joint at the base (J1) must be connected via USB to a computer running the sofware. No other joints should have a USB connection. A USB 3.0 port or higher on the computer is suggested, as the lower communication speeds fo USB 2.0 or 1.0 may impede communication and cause unecessary delay or issues.
91 )))
92 | |(% style="text-align:center; vertical-align:middle" %)(((
93 [[image:ses-pro-robotic-arm-ui-connect.png]]
94
95 [[image:ses-pro-robotic-arm-ui-disconnect.png]]
96 )))|(((
97 **Connect / Disconnect**
98
99 Once the COM port has been selection, the CONNECT button can be pressed, and once a servo has been found, the light next to it will go from red to green.
100 )))
101 | |(% colspan="2" rowspan="1" %)(((
102 == Gripper Controls ==
103 )))
104 | |(% style="text-align:center; vertical-align:middle" %) |
105 | |(% style="text-align:center; vertical-align:middle" %) |
106 | |(% style="text-align:center; vertical-align:middle" %) |
107 | |(% style="text-align:center; vertical-align:middle" %) |
108 | |(% style="text-align:center; vertical-align:middle" %) |
109 | |(% style="text-align:center; vertical-align:middle" %) |
110 | |(% style="text-align:center; vertical-align:middle" %) |
111 | |(% style="text-align:center; vertical-align:middle" %) |
112 | |(% style="text-align:center; vertical-align:middle" %) |
113 | |(% style="text-align:center; vertical-align:middle" %) |
114 | |(% style="text-align:center; vertical-align:middle" %) |
115 | |(% style="text-align:center; vertical-align:middle" %) |
116 | |(% style="text-align:center; vertical-align:middle" %) |
117 | |(% style="text-align:center; vertical-align:middle" %) |
118 | |(% style="text-align:center; vertical-align:middle" %) |
119 | |(% style="text-align:center; vertical-align:middle" %) |
120 | |(% style="text-align:center; vertical-align:middle" %) |
121 | |(% style="text-align:center; vertical-align:middle" %) |
122 | |(% style="text-align:center; vertical-align:middle" %) |
123 | |(% style="text-align:center; vertical-align:middle" %) |
124 | |(% style="text-align:center; vertical-align:middle" %) |
125 | |(% style="text-align:center; vertical-align:middle" %) |
126 | |(% style="text-align:center; vertical-align:middle" %) |
127 | |(% style="text-align:center; vertical-align:middle" %) |
128 | |(% style="text-align:center; vertical-align:middle" %) |
129 | |(% style="text-align:center; vertical-align:middle" %) |
130 | |(% style="text-align:center; vertical-align:middle" %) |
131 | |(% style="text-align:center; vertical-align:middle" %) |
132 | |(% style="text-align:center; vertical-align:middle" %) |
133 | |(% style="text-align:center; vertical-align:middle" %) |
134 | |(% style="text-align:center; vertical-align:middle" %) |
135 | |(% style="text-align:center; vertical-align:middle" %) |
136 | |(% style="text-align:center; vertical-align:middle" %) |
137 | |(% style="text-align:center; vertical-align:middle" %) |
138
139 |(% colspan="2" %)(((
140 = User Guide =
141 )))
142 |(% style="width:26px" %) |(% style="width:1452px" %)(((
143 Before proceeding with the guide, it is important to note the following:
144
145 * Neither the servos nor the arm are meant to be operated in proximity of humans as they do not have "collaborative" (COBOT) features and do not detect collision
146 * The servos use stepper motors and do NOT include mechanical brakes. If the stepper motor is unable to retain or move to a desired angle (insufficient torque), the motor will rotate freely as opposed to hold the last position
147
148 Pressing the i "Information" icon in the software will bring you to this page.
149
150 [[image:ses-pro-robotic-arm-ui-info.png]]
151 )))
152 |(% colspan="2" %)(((
153 == IMPORTANT ==
154 )))
155 |(% style="width:26px" %) |(% style="width:1452px" %)(((
156 === Payload Considerations ===
157
158 1. The rated payload for each arm does NOT include an end effector, nor any added distance between the center of mass of the payload and the output of the final joint. Each of the two compatible Lynxmotion PRO grippers reduce the maximum payload of each arm, and it is up to the user to known and understand the concept of "torque" and center of mass before adding an end effector and payload.
159 1. The rated maximum payload for each arm (at full reach) is at the rated speed for each motor. Moving any joint at a higher speed will decrease the payload capacity of the robot.
160 1. Although each servo can provide significantly more torque than is needed for the rated payload (and therefore means the arm can support much higher loads at lower speeds, the mechanical and modular structure of the arms may fail. We strongly suggest testing and using each arm in a highly controlled and safe setting where, if a failure should occur with one or more joints, that nothing will break should the arm fall.
161 1. The stepper motors provide the highest torque at low speeds, and lower torque at high speeds. Note that the maxium torque is not at the lowest speed as the torque to rpm curve for each servo resembles a "mountain".
162 )))
163 |(% style="width:26px" %) |(% style="width:1452px" %)(((
164 === Emergency ===
165
166 Before using the arm, it is important that a user know what to do when an issue or emergency arises where the arm must be stopped quickly. The following emergency options are available based on severity:
167
168 **Halt (and hold)**
169
170 **[[image:ses-pro-robotic-arm-ui-halt.png]]**
171
172 This will stop every joints and hold them in their last recorded angular positions. The corresponding command is #254H<cr>.
173
174 **Limp**
175
176 **[[image:ses-pro-robotic-arm-ui-limp.png]]**
177
178 All joints will go limp which mean there will be nothing avoiding them to turn freely (potentially causing the arm to fall). The high gear ratio of the strain wave gearing does mean there is some (low) level of resistant to rotation, but the gears and motor are nto "locked" and as such, the arm may fall. The corresponding command is #254L<cr>.
179
180 **Software E-Stop**
181
182 **[[image:ses-pro-robotic-arm-ui-arm-emergency.png]]**
183
184 The E-stop button within the software sets all joints to limp, this can possibly cause the arm to fall.
185
186 **Power Supply E-Stop**
187 A hardware E-stop (push to cut power) button is located on the power supply which will cut electricity to all actuators. Similar to a limp command, this can possibly cause the arm to fall. To reset this button, rotate the red "mushroom" in the direction indicated by the white arrows and it will spring out.
188 )))
189 |(% colspan="2" %)(((
190 == Arm Connection ==
191 )))
192 |(% style="width:26px" %) |(% style="width:1452px" %)(((
193 **Model**
194
195 **[[image:ses-pro-robotic-arm-ui-arm-version.png]]**
196
197 The software currently supports the following Lynxmotion PRO Arms:
198
199 * 550mm 5DoF
200 * 550mm 6DoF
201 * 900mm 5DoF
202 * 900mm 6DoF
203
204 In practice, each 5DoF arm has joint 4 at a fixed angle, otherwise the arms are identical to the 6DoF. Users can always purchase the missing actuator to upgrade to a 6DoF.
205
206 **COM Port**
207
208 **[[image:ses-pro-robotic-arm-ui-com.png]]**
209
210 The first joint at the base (J1) must be connected via USB to a computer running the sofware. No other joints should have a USB connection. A USB 3.0 port or higher on the computer is suggested, as the lower communication speeds fo USB 2.0 or 1.0 may impede communication and cause unecessary delay or issues. 
211
212 **Connect / Disconnect**
213
214 [[image:ses-pro-robotic-arm-ui-connect.png]]
215
216 [[image:ses-pro-robotic-arm-ui-disconnect.png]]
217
218 Once the COM port has been selection, the CONNECT button can be pressed, and once a servo has been found, the light next to it will go from red to green.
219 )))
220 |(% colspan="2" %)(((
221 == Gripper Controls ==
222 )))
223 |(% style="width:26px" %) |(% style="width:1452px" %)(((
224 **Model**
225
226 The software currently supports two models of Lynxmotion PRO compatible grippers based on DH Robots' PGE-50-40 and CGE-10-10 electric grippers. The Lynxmotion kits include hardware to mount the fingers in multiple different offsets for smaller or larger objects. In the sequencer, the position of the fingers for each gripper are included in the sequencer as J7.
227
228 * PGE-50-40 (40mm default configuration)
229 * PGE-50-40 (60mm configuration)
230 * PGE-50-40 (80mm configuration)
231 * CGE-10-10 (20mm configuration)
232 * CGE-10-10 (40mm configuration)
233 * CGE-10-10 (60mm configuration)
234
235 **COM Port**
236
237 Choose the appropriate COM port to which the gripper is connected (via its own USB cable). If you are not certain, you can check Windows -> Device Manager
238
239 **Baudrate**
240
241 The DH Robotics grippers provide the option to change the baud rate, though the default is 115200. If the gripper is configured by the user to a different baud rate, it is important to select the corresponding baud rate in the software.
242
243 **Initialize**
244
245 Initializing the gripper opens it fully. This is available should the user encounter issues with positioning and need to re-zero the fingers.
246
247 **Connect**
248
249 Pressing CONNECT establishes a connection to the gripper and goes through the initilization process once, opening the gripper fully. Once connection has been established, the light next to the button will go from red to green.
250
251 **Speed**
252
253 The speed of motion can be adjusted either via the plus or minus buttons or entering a value between 0 and 100 and pressing enter.
254
255 **Force**
256
257 The maximum force exerted by the gripper can be adjusted either via the plus or minus buttons or entering a value between 0 and 100 and pressing enter.
258
259 **Open / Close**
260
261 These are shortcut buttons to either fully open or fully close the gripper.
262
263 **Sequencer**
264
265 The sequencer displays the gripper position as joint 7 (J7).
266
267 HINT: If you want the gripper to open or close on an object only at the end of a motion, create a separate frame where only J7 moves.
268 )))
269 |(% colspan="2" %)(((
270 == 3D Model ==
271 )))
272 |(% style="width:26px" %) |(% style="width:1452px" %)(((
273 The 3D model of the arm is shown as reference at all times. The display also includes a virtual plane to denote  the X-Y plane. The model updates based on the selection of the arm, gripper and finger configuration.
274
275 **View Controls**
276
277 Zoom: Shift + Middle Scroll
278
279 Rotate: Shift + Middle Mouse
280
281 Pan: None
282 )))
283 |(% colspan="2" %)(((
284 == Manual Move ==
285 )))
286 |(% style="width:26px" %) |(% style="width:1452px" %)(((
287 **Angular Control**
288
289 In angular mode, the user can control the angle of each joint
290
291 **Coordinates Control**
292
293 In coordinate control the user can control the cartesian position of the end effector
294
295 **End Effector Lock**
296
297 The orientation of the end effector can be locked.
298 )))
299 |(% colspan="2" %)(((
300 == Direct Command ==
301 )))
302 |(% style="width:26px" %) |(% style="width:1452px" %)(((
303 This section allow the user to send commands using the [[LSS-PRO Communication Protocol>>path:/info/wiki/lynxmotion/view/ses-pro/lss-pro/lss-p-communication-protocol/]] directly if required.
304
305 A few things to keep in mind when using this:
306
307 * Make sure you know what you are doing as you can make the arm move in __dangerous__ ways.
308 * Sending commands does not require ‘#’ and ‘\r’ chars.
309 ** example for #2\r you should enter 2Q and press the "SEND" button
310 * The commands are validated, and it shows a notification in case of error.
311 * The replies of queries are shown in the text field below.
312 )))
313 |(% colspan="2" %)(((
314 == Command Output ==
315 )))
316 |(% style="width:26px" %) |(% style="width:1452px" %)(((
317 //{Coming Soon}//
318 )))
319 |(% colspan="2" %)(((
320 == Telemetry ==
321 )))
322 |(% style="width:26px" %) |(% style="width:1452px" %)(((
323 **Data to Display**
324
325 Various telemetry data can be retrieved from each actuators / joints, here is what the software support:
326
327 * Position
328 * Current
329 * Linear Accel X
330 * Linear Accel Y
331 * Linear Accel Z
332 * Angular Accel α
333 * Angular Accel β
334 * Angular Accel γ
335 * MCU Temperature
336 * PCB Temperature
337 * Probe Temperature
338
339 **Display / Hide **
340
341 At the bottom of the graphics you will find squares to activate / deactivate the desired actuator / joint to be displayed in the graph.
342 )))
343 |(% colspan="2" style="width:26px" %)(((
344 == Sequencer ==
345 )))
346 |(% style="width:26px" %) |(% style="width:1452px" %)(((
347 **Sequence**
348
349 Add
350
351 Substract
352
353 Copy
354
355 Save
356
357 Open
358
359 Delete
360
361 //{Coming Soon}//
362
363 **Frames**
364
365 Add
366
367 Sequence Selector
368
369 Record
370
371 Delete
372
373 Copy
374
375 Paste
376
377 Swap
378
379 Manual Edit
380
381 Time, angles, gripper
382
383 Moving Frames
384
385 //Alt + Left Click = Drag time//
386
387 //{Coming Soon}//
388
389 **Errors**
390
391 //{Coming Soon}//
392 )))
393 |(% style="width:26px" %) |(% style="width:1452px" %)
394 |(% style="width:26px" %) |(% style="width:1452px" %)
395 |(% style="width:26px" %) |(% style="width:1452px" %)
396 |(% style="width:26px" %) |(% style="width:1452px" %)
397 |(% style="width:26px" %) |(% style="width:1452px" %)
398 |(% style="width:26px" %) |(% style="width:1452px" %)
399 |(% style="width:26px" %) |(% style="width:1452px" %)
400 |(% style="width:26px" %) |(% style="width:1452px" %)
401 |(% style="width:26px" %) |(% style="width:1452px" %)
402 |(% style="width:26px" %) |(% style="width:1452px" %)
403 |(% style="width:26px" %) |(% style="width:1452px" %)
404 |(% style="width:26px" %) |(% style="width:1452px" %)
405 |(% style="width:26px" %) |(% style="width:1452px" %)
406 |(% style="width:26px" %) |(% style="width:1452px" %)
407 |(% style="width:26px" %) |(% style="width:1452px" %)
408 |(% style="width:26px" %) |(% style="width:1452px" %)
409 |(% style="width:26px" %) |(% style="width:1452px" %)
410 |(% style="width:26px" %) |(% style="width:1452px" %)
411 |(% style="width:26px" %) |(% style="width:1452px" %)
412 |(% style="width:26px" %) |(% style="width:1452px" %)
413 |(% style="width:26px" %) |(% style="width:1452px" %)
414 |(% style="width:26px" %) |(% style="width:1452px" %)
415 |(% style="width:26px" %) |(% style="width:1452px" %)
416 |(% style="width:26px" %) |(% style="width:1452px" %)
417 |(% style="width:26px" %) |(% style="width:1452px" %)
418 |(% style="width:26px" %) |(% style="width:1452px" %)
419 |(% style="width:26px" %) |(% style="width:1452px" %)
420 |(% style="width:26px" %) |(% style="width:1452px" %)
421 |(% style="width:26px" %) |(% style="width:1452px" %)
422 |(% style="width:26px" %) |(% style="width:1452px" %)
423 |(% style="width:26px" %) |(% style="width:1452px" %)
424 |(% style="width:26px" %) |(% style="width:1452px" %)
425 |(% style="width:26px" %) |(% style="width:1452px" %)
426 |(% style="width:26px" %) |(% style="width:1452px" %)
427 |(% style="width:26px" %) |(% style="width:1452px" %)
428 |(% style="width:26px" %) |(% style="width:1452px" %)
429 |(% style="width:26px" %) |(% style="width:1452px" %)
430 |(% style="width:26px" %) |(% style="width:1452px" %)
431 |(% style="width:26px" %) |(% style="width:1452px" %)
432 |(% style="width:26px" %) |(% style="width:1452px" %)
433 |(% style="width:26px" %) |(% style="width:1452px" %)
434 |(% style="width:26px" %) |(% style="width:1452px" %)
435 |(% style="width:26px" %) |(% style="width:1452px" %)
436 |(% style="width:26px" %) |(% style="width:1452px" %)
437 |(% style="width:26px" %) |(% style="width:1452px" %)
438 |(% style="width:26px" %) |(% style="width:1452px" %)
439 |(% style="width:26px" %) |(% style="width:1452px" %)
440 |(% style="width:26px" %) |(% style="width:1452px" %)
441 |(% style="width:26px" %) |(% style="width:1452px" %)
442 |(% style="width:26px" %) |(% style="width:1452px" %)
443 |(% style="width:26px" %) |(% style="width:1452px" %)
444 |(% style="width:26px" %) |(% style="width:1452px" %)
445 |(% style="width:26px" %) |(% style="width:1452px" %)
446 |(% style="width:26px" %) |(% style="width:1452px" %)
447
448 {{comment}}
449 = =
450
451 = User Guide =
452
453 Pressing the i "Information" icon in the software will bring you to this page. Before proceeding with the guide, it is important to note the following:
454
455 * Neither the servos nor the arm are meant to be operated in proximity of humans as they do not have "collaborative" (COBOT) features and do not detect collision
456 * The servos use stepper motors and do NOT include mechanical brakes. If the stepper motor is unable to retain or move to a desired angle (insufficient torque), the motor will rotate freely as opposed to hold the last position
457
458 == IMPORTANT: Payload Considerations ==
459
460 1. The rated payload for each arm does NOT include an end effector, nor any added distance between the center of mass of the payload and the output of the final joint. Each of the two compatible Lynxmotion PRO grippers reduce the maximum payload of each arm, and it is up to the user to known and understand the concept of "torque" and center of mass before adding an end effector and payload.
461 1. The rated maximum payload for each arm (at full reach) is at the rated speed for each motor. Moving any joint at a higher speed will decrease the payload capacity of the robot.
462 1. Although each servo can provide significantly more torque than is needed for the rated payload (and therefore means the arm can support much higher loads at lower speeds, the mechanical and modular structure of the arms may fail. We strongly suggest testing and using each arm in a highly controlled and safe setting where, if a failure should occur with one or more joints, that nothing will break should the arm fall.
463 1. The stepper motors provide the highest torque at low speeds, and lower torque at high speeds. Note that the maxium torque is not at the lowest speed as the torque to rpm curve for each servo resembles a "mountain".
464
465 == IMPORTANT: Emergency ==
466
467 Before using the arm, it is important that a user know what to do when an issue or emergency arises where the arm must be stopped quickly. The following emergency options are available based on severity:
468
469 **Halt & Hold**
470
471 This will stop every joints and hold them in their last recorded angular positions. The corresponding command is #254H<cr>.
472
473 **Limp**
474
475 All joints will go limp which mean there will be nothing avoiding them to turn freely (potentially causing the arm to fall). The high gear ratio of the strain wave gearing does mean there is some (low) level of resistant to rotation, but the gears and motor are nto "locked" and as such, the arm may fall. The corresponding command is #254L<cr>.
476
477 **Software Stop**
478
479 The E-stop button within the software sets all joints to limp.
480
481 **Hardware E-Stop**
482 A hardware E-stop (push to cut power) button is located on the power supply which will cut electricity to all actuators. Similar to a limp command, this can possibly cause the arm to fall. To reset this button, rotate the red "mushroom" in the direction indicated by the white arrows and it will spring out.
483
484 == Arm Connection ==
485
486 **Model**
487
488 The software currently supports the following Lynxmotion PRO Arms:
489
490 * 550mm 5DoF
491 * 550mm 6DoF
492 * 900mm 5DoF
493 * 900mm 6DoF
494
495 In practice, each 5DoF arm has joint 4 at a fixed angle, otherwise the arms are identical to the 6DoF. Users can always purchase the missing actuator to upgrade to a 6DoF.
496
497 **COM Port**
498
499 The first joint at the base (J1) must be connected via USB to a computer running the sofware. No other joints should have a USB connection. A USB 3.0 port or higher on the computer is suggested, as the lower communication speeds fo USB 2.0 or 1.0 may impede communication and cause unecessary delay or issues. 
500
501 **Connect**
502
503 Once the COM port has been selection, the CONNECT button can be pressed, and once a servo has been found, the light next to it will go from red to green.
504
505 == Gripper Controls ==
506
507 **Model**
508
509 The software currently supports two models of Lynxmotion PRO compatible grippers based on DH Robots' PGE-50-40 and CGE-10-10 electric grippers. The Lynxmotion kits include hardware to mount the fingers in multiple different offsets for smaller or larger objects. In the sequencer, the position of the fingers for each gripper are included in the sequencer as J7.
510
511 * PGE-50-40 (40mm default configuration)
512 * PGE-50-40 (60mm configuration)
513 * PGE-50-40 (80mm configuration)
514 * CGE-10-10 (20mm configuration)
515 * CGE-10-10 (40mm configuration)
516 * CGE-10-10 (60mm configuration)
517
518 **COM Port**
519
520 Choose the appropriate COM port to which the gripper is connected (via its own USB cable). If you are not certain, you can check Windows -> Device Manager
521
522 **Baudrate**
523
524 The DH Robotics grippers provide the option to change the baud rate, though the default is 115200. If the gripper is configured by the user to a different baud rate, it is important to select the corresponding baud rate in teh software.
525
526 **Initialize**
527
528 Initializing the gripper opens it fully. This is available should the user encounter issues with positioning and need to re-zero the fingers.
529
530 **Connect**
531
532 Pressing CONNECT establishes a connection to the gripper and goes through the initilization process once, opening the gripper fully. Once connection has been established, the light next to the button will go from red to green.
533
534 **Speed**
535
536 The speed of motion can be adjusted either via the plus or minus buttons or entering a value between 0 and 100 and pressing enter.
537
538 **Force**
539
540 The maximum force exerted by the gripper can be adjusted either via the plus or minus buttons or entering a value between 0 and 100 and pressing enter.
541
542 **Open / Close**
543
544 These are shortcut buttons to either fully open or fully close the gripper.
545
546 **Sequencer**
547
548 The sequencer displays the gripper position as joint 7 (J7).
549
550 HINT: If you want the gripper to open or close on an object only at the end of a motion, create a separate frame where only J7 moves.
551
552 == 3D Model ==
553
554 The 3D model of the arm is shown as reference at all times. The display also includes a virtual plane to denote  the X-Y plane. The model updates based on the selection of the arm, gripper and finger configuration.
555
556 **View Controls**
557
558 Zoom: Shift + Middle Scroll
559
560 Rotate: Shift + Middle Mouse
561
562 Pan: None
563
564 == Manual Move ==
565
566 **Angular Control**
567
568 In angular mode, the user can control the angle of each joint
569
570 **Coordinates Control**
571
572 In coordinate control the user can control the cartesian position of the end effector
573
574 **End Effector Lock**
575
576 The orientation of the end effector can be locked.
577
578 == Direct Command ==
579
580 This section allow the user to send commands using the [[doc:ses-pro.lss-pro.lss-p-communication-protocol.WebHome]] directly if required.
581
582 A few things to keep in mind when using this:
583
584 * Make sure you know what you are doing as you can make the arm move in __dangerous__ ways.
585 * Sending commands does not require ‘#’ and ‘\r’ chars.
586 ** example for #2\r you should enter 2Q and press the "SEND" button
587 * The commands are validated, and it shows a notification in case of error.
588 * The replies of queries are shown in the text field below.
589
590 == Command Output ==
591
592 //{Coming Soon}//
593
594 == Telemetry ==
595
596 **Data to Display**
597
598 //{Coming Soon}//
599
600 **Display / Hide Actuator**
601
602 //{Coming Soon}//
603
604 == Sequencer ==
605
606 **Frames**
607
608 //{Coming Soon}//
609
610 **Record **
611
612 //{Coming Soon}//
613
614 **Edit **
615
616 Time, angles, gripper
617
618 //Alt + Left Click = Drag time//
619
620 **Reorder**
621
622 //{Coming Soon}//
623
624 **Play**
625
626 //{Coming Soon}//
627
628 **Errors**
629
630 //{Coming Soon}//
631 {{/comment}}

Navigation

Recently Visited

Copyright RobotShop 2018