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1		-xwiki:XWiki.RB1
	1	+xwiki:XWiki.CBenson

Content

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42	42	Modified commands are command specific.
43	43	)))
44	44
45		-(((
46		-
47		-)))
48		-
49		-== Configuration Commands ==
50		-
51		-Configuration commands affect the servo's current session* but unlike action commands, configuration commands are written to EEPROM and are retained even if the servo loses power (therefore NOT session specific). Not all action commands have a corresponding configuration and vice versa. Certain configurations are retained for when the servo is used in RC model. More information can be found on the [[LSS - RC PWM page>>doc:Lynxmotion Smart Servos (LSS).LSS - RC PWM.WebHome]].
52		-
53		-1. Start with a number sign # (U+0023)
54		-1. Servo ID number as an integer
55		-1. Configuration command (two to three letters, no spaces, capital or lower case)
56		-1. Configuration value in the correct units with no decimal
57		-1. End with a control / carriage return '<cr>'
58		-
59		-Ex: #5CO-50<cr>
60		-
61		-Assigns an absolute origin offset of -5.0 degrees (with respect to factory origin) to servo #5 and changes the offset for that session to -5.0 degrees.
62		-
63		-Configuration commands are not cumulative, in that if two configurations are sent at any time, only the last configuration is used and stored.
64		-
65		-*Important Note: the one exception is the baud rate - the servo's current session retains the given baud rate. The new baud rate will only be in place when the servo is power cycled.
66		-
67	67	== Query Commands ==
68	68
69	69	Query commands are sent serially to the servo's Rx pin and must be set in the following format:
...	...	@@ -91,21 +91,25 @@
91	91	)))
92	92
93	93	Indicates that servo #5 is currently at 144.3 degrees.
	72	+)))
94	94
95		-**Session vs Configuration Query**
	74	+== Configuration Commands ==
96	96
97		-By default, the query command returns the sessions' value; should no action commands have been sent to change, it will return the value saved in EEPROM from the last configuration command.
	76	+Configuration commands affect the servo's current session* but unlike action commands, configuration commands are written to EEPROM and are retained even if the servo loses power (therefore NOT session specific). Not all action commands have a corresponding configuration and vice versa. Certain configurations are retained for when the servo is used in RC model. More information can be found on the [[LSS - RC PWM page>>doc:Lynxmotion Smart Servos (LSS).LSS - RC PWM.WebHome]].
98	98
99		-In order to query the value in EEPROM, add a '1' to the query command.
	78	+1. Start with a number sign # (U+0023)
	79	+1. Servo ID number as an integer
	80	+1. Configuration command (two to three letters, no spaces, capital or lower case)
	81	+1. Configuration value in the correct units with no decimal
	82	+1. End with a control / carriage return '<cr>'
100	100
101		-Ex: #5CSR20<cr> sets the maximum speed for servo #5 to 20rpm upon RESET (explained below).
	84	+Ex: #5CO-50<cr>
102	102
103		-After RESET: #5SR4<cr> sets the session's speed to 4rpm.
	86	+Assigns an absolute origin offset of -5.0 degrees (with respect to factory origin) to servo #5 and changes the offset for that session to -5.0 degrees.
104	104
105		-#5QSR<cr> would return *5QSR4<cr> which represents the value for that session.
	88	+Configuration commands are not cumulative, in that if two configurations are sent at any time, only the last configuration is used and stored.
106	106
107		-#5QSR1<cr> would return *5QSR20<cr> which represents the value in EEPROM
108		-)))
	90	+*Important Note: the one exception is the baud rate - the servo's current session retains the given baud rate. The new baud rate will only be in place when the servo is power cycled.
109	109
110	110	= Command List =
111	111
...	...	@@ -117,22 +117,20 @@
117	117	| 5|**M**ove in **D**egrees (relative)| MD| | | | ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
118	118	| 6|**O**rigin Offset| O| QO| CO| ✓| ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
119	119	| 7|**A**ngular **R**ange| AR| QAR| CAR| ✓| ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
120		-| 8|Position in **P**ulse| P| QP| | | ✓| microseconds|(((
121		-See details below.
122		-)))
	102	+| 8|Position in **P**ulse| P| QP| | | ✓| microseconds|
123	123	| 9|Position in **D**egrees| D| QD| | | ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
124	124	| 10|**W**heel mode in **D**egrees| WD| QWD| | | ✓| tenths of degrees per second (ex 248 = 24.8 degrees per second)|
125	125	| 11|**W**heel mode in **R**PM| WR| QWR| | | ✓| rpm|
126	126	| 12|**S**peed in **D**egrees| SD| QSD| CSD| ✓| ✓| tenths of degrees per second (ex 248 = 24.8 degrees per second)|
127	127	| 13|**S**peed in **R**PM| SR| QSR| CSR| ✓| ✓| rpm|
128		-| 14|**R**igidity| R| QR| CR| ✓| ✓|none|
129		-| 15|//N/A (removed)//| | | | | | |
	108	+| 14|**A**ngular **A**cceleration| AA| QAA| CAA| ✓| ✓| tenths of degrees per second squared|
	109	+| 15|**A**ngular **D**eceleration| AD| QAD| CAD| ✓| ✓| tenths of degrees per second squared|
130	130	| 16|**LED** Color| LED| QLED| CLED| ✓| ✓| none (integer from 1 to 8)|0=OFF 1=RED 2=GREEN 3= BLUE 4=YELLOW 5=CYAN 6= 7=MAGENTA, 8=WHITE
131		-| 17|**ID** #| ID| QID| CID| | ✓| none (integer from 0 to 250)|Note: ID 254 is a "broadcast" which all servos respond to.
	111	+| 17|**ID** #| ID| QID| CID| | ✓| none (integer from 0 to 254)|
132	132	| 18|**B**aud rate| B| QB| CB| | ✓| none (integer)|
133	133	| 19|**G**yre direction (**G**)| G| QG| CG| ✓| ✓| none | Gyre / rotation direction where 1= CW (clockwise) -1 = CCW (counter-clockwise)
134		-| 20|**F**irst Position (**P**ulse)| | QFP|CFP | ✓| ✓| none |
135		-| 21|**F**irst Position (**D**egrees)| | QFD|CFD| ✓| ✓| none |
	114	+| 20|**F**irst Position (**P**ulse)| | QFP|CFP | ✓| ✓| none |\\
	115	+| 21|**F**irst Position (**D**egrees)| | QFD|CFD| ✓| ✓| none |\\
136	136	| 22|**T**arget (**D**egree) **P**osition| | QDT| | | ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
137	137	| 23|**M**odel| | QM| | | | none (integer)|
138	138	| 24|Serial **N**umber| | QN| | | | none (integer)|
...	...	@@ -141,8 +141,8 @@
141	141	| 27|**V**oltage| | QV| | | ✓| tenths of volt (ex 113 = 11.3V; 92 = 9.2V)|
142	142	| 28|**T**emperature| | QT| | | ✓| degrees Celsius|
143	143	| 29|**C**urrent| | QC| | | ✓| tenths of Amps (ex 2 = 0.2A)|
144		-| | | | | | | | |
145		-| | | | | | | | |
	124	+|| | | | | || |
	125	+|| | | | | | | |
146	146
147	147	= Details =
148	148
...	...	@@ -228,14 +228,13 @@
228	228
229	229	Example: #5P2334<cr>
230	230
231		-The position in PWM pulses was retained in order to be backward compatible with the SSC-32 / 32U protocol. This relates the desired angle with an RC standard PWM pulse and is further explained in the SSC-32 and SSC-32U manuals found on Lynxmotion.com. Without any modifications to configuration considered, and a ±90.0 degrees standard range where 1500 microseconds is centered, a pulse of 2334 would set the servo to 165.1 degrees. Valid values for P are [500, 2500]. Values outside this range are corrected to end points.
	211	+The position in PWM pulses was retained in order to be backward compatible with the SSC-32 / 32U protocol. This relates the desired angle with an RC standard PWM pulse and is further explained in the SSC-32 and SSC-32U manuals found on Lynxmotion.com. Without any modifications to configuration considered, and a ±90.0 degrees standard range where 1500 microseconds is centered, a pulse of 2334 would set the servo to 165.1 degrees
232	232
233	233	Query Position in Pulse (**QP**)
234	234
235	235	Example: #5QP<cr> might return *5QP
236	236
237		-This command queries the current angular position in PWM "units". The user must take into consideration that the response includes any angular range and origin configurations in order to determine the actual angle.
238		-Valid values for QP are {-500, [500, 2500], -2500}. Values outside the [500, 2500] range are given a negative corresponding end point value to indicate they are out of bounds.
	217	+This command queries the current angular position in PWM "units". The user must take into consideration that the response includes any angular range and origin configurations in order to determine the actual angle.
239	239
240	240	__9. Position in Degrees (**D**)__
241	241
...	...	@@ -309,38 +309,46 @@
309	309
310	310	Using the CSD command sets the servo's maximum speed which is saved in EEPROM. In the example above, the servo's maximum speed will be set to 45rpm. When the servo is powered on (or after a reset), the CSD value is used. Note that CSD and CSR are effectively the same, but allow the user to specify the speed in either unit. The last command (either CSR or CSD) is what the servo uses for that session.
311	311
312		-__14. Rigidity (R)__
	291	+__14. Angular Acceleration (**AA**)__
313	313
314		-The servo's rigidity can be thought of as (though not identical to) a damped spring in which the rigidity value affects the stiffness and embodies how much, and how quickly the servo tried keep the requested position against changes.
	293	+{More information coming soon}
315	315
316		-A positive value of "rigidity":
	295	+Ex:
317	317
318		-* The more torque will be applied to try to keep the desired position against external input / changes
319		-* The faster the motor will reach its intended travel speed and the motor will decelerate faster and nearer to its target position
	297	+{Description coming soon}
320	320
321		-A negative value on the other hand:
	299	+Query Angular Acceleration (**QAA**)
322	322
323		-* Causes a slower acceleration to the travel speed, and a slower deceleration
324		-* Allows the target position to deviate more from its position before additional torque is applied to bring it back
	301	+Ex:
325	325
326		-The default value is zero and the effect becomes extreme by -4, +4. There are no units, only integers between -4 to 4. Greater values produce increasingly erratic behavior.
	303	+{Description coming soon}
327	327
328		-Ex: #5R-2<cr>
	305	+Configure Angular Acceleration (**CAA**)
329	329
330		-This reduces the rigidity to -2 for that session, allowing the servo to deviate more around the desired position. This can be beneficial in many situations such as impacts (legged robots) where more of a "spring" effect is desired. Upon reset, the servo will use the value stored in memory, based on the last configuration command.
	307	+Ex:
331	331
332		-Ex: #5QR<cr>
	309	+{Description coming soon}
333	333
334		-Queries the value being used.
	311	+__15. Angular Deceleration (**AD**)__
335	335
336		-Ex: #5CR<cr>
	313	+{More information coming soon}
337	337
338		-Writes the desired rigidity value to memory.
	315	+Ex:
339	339
340		-__15. N/A (removed)__
	317	+{Description coming soon}
341	341
342		-This command has been removed.
	319	+Query Angular Acceleration (**QAD**)
343	343
	321	+Ex:
	322	+
	323	+{Description coming soon}
	324	+
	325	+Configure Angular Acceleration (**CAD**)
	326	+
	327	+Ex:
	328	+
	329	+{Description coming soon}
	330	+
344	344	__16. RGB LED (**LED**)__
345	345
346	346	Ex: #5LED3<cr>
...	...	@@ -347,7 +347,7 @@
347	347
348	348	This action sets the servo's RGB LED color for that session.The LED can be used for aesthetics, or (based on user code) to provide visual status updates. Using timing can create patterns.
349	349
350		-0=OFF 1=RED 2=GREEN 3= BLUE 4=YELLOW 5=CYAN 6= 7=MAGENTA, 8=WHITE
	337	+0=OFF 1=RED 2=GREEN 3= BLUE 4=YELLOW 5=CYAN 6= 7=MAGENTA, 8=WHITE
351	351
352	352	Query LED Color (**QLED**)
353	353
...	...	@@ -361,7 +361,7 @@
361	361
362	362	__17. Identification Number__
363	363
364		-A servo's identification number cannot be set "on the fly" and must be configured via the CID command described below. The factory default ID number for all servos is 0. Since smart servos are intended to be daisy chained, in order to respond differently from one another, the user must set different identification numbers. Servos with the same ID and baud rate will all receive and react to the same commands.
	351	+A servo's identification number cannot be set "on the fly" and must be configured via the CID command described below. The factory default ID number for all servos is 1. Since smart servos are intended to be daisy chained, in order to respond differently from one another, the user must set different identification numbers. Servos with the same ID and baud rate will all receive and react to the same commands.
365	365
366	366	Query Identification (**QID**)
367	367
...	...	@@ -495,30 +495,23 @@
495	495
496	496	This command does a "soft reset" (no power cycle required) and reverts all commands to those stored in EEPROM (i.e. configuration commands).
497	497
498		-**__DEFAULT __**__& **CONFIRM**__
	485	+**__DEFAULT__**
499	499
500	500	Ex: #5DEFAULT<cr>
501	501
502		-This command sets in motion the reset all values to the default values included with the version of the firmware installed on that servo. The servo then waits for the CONFIRM command. Any other command received will cause the servo to exit the DEFAULT function.
	489	+This command sets all values to the default values included with the version of the firmware installed on that servo.
503	503
504		-EX: #5DEFAULT<cr> followed by #5CONFIRM<cr>
	491	+__**FIRMWARE** & **CONFIRM**__
505	505
506		-Since it it not common to have to restore all configurations, a confirmation command is needed after a firmware command is sent. Should any command other than CONFIRM be received by the servo after the firmware command has been received, it will leave the firmware action.
	493	+Ex: #5FIRMWARE<cr>
507	507
508		-Note that after the CONFIRM command is sent, the servo will automatically perform a RESET.
	495	+This command clears all user-input values in EEPROM and reverts back to factory defaults for the firmware installed. It does not overwrite any firmware updates. To revert to an older firmware version, please refer to the LSS - Firmware page. The firmware command alone does nothing other than have the servo wait for a confirmation.
509	509
510		-**__UPDATE __**__& **CONFIRM**__
	497	+EX: #5FIRMWARE<cr> followed by #5CONFIRM<cr>
511	511
512		-Ex: #5UPDATE<cr>
	499	+Since it it not common to have to restore all configurations, a confirmation command is needed after a firmware command is sent. Should any command other than CONFIRM be received by the servo after the firmware command has been received, it will leave the firmware action.
513	513
514		-This command sets in motion the equivalent of a long button press when the servo is not powered in order to enter firmware update mode. This is useful should the button be broken or inaccessible. The servo then waits for the CONFIRM command. Any other command received will cause the servo to exit the UPDATE function.
515	515
516		-EX: #5UPDATE<cr> followed by #5CONFIRM<cr>
517		-
518		-Since it it not common to have to update firmware, a confirmation command is needed after an UPDATE command is sent. Should any command other than CONFIRM be received by the servo after the firmware command has been received, it will leave the firmware action.
519		-
520		-Note that after the CONFIRM command is sent, the servo will automatically perform a RESET.
521		-
522	522	=== Virtual Angular Position ===
523	523
524	524	{In progress}