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Parent

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1		-Lynxmotion Smart Servo (LSS).WebHome
	1	+lynxmotion:LSS - Overview (DEV).WebHome

Author

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

Tags

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1		-LSS|communication|protocol|programming|firmware|control|LSS-Ref
	1	+LSS|communication|protocol|programming|firmware|control

Content

...	...	@@ -1,9 +4,6 @@
1		-(% class="wikigeneratedid" id="HTableofContents" %)
2		-**Table of Contents**
3		-
4	4	{{toc depth="3"/}}
5	5
6		-= Protocol Concepts =
	3	+= Protocol concepts =
7	7
8	8	The Lynxmotion Smart Servo (LSS) protocol was created in order to be as simple and straightforward as possible from a user perspective, while at the same time trying to stay compact and robust yet highly versatile. Almost everything one might expect to be able to configure for a smart servo motor is available.
9	9
...	...	@@ -30,7 +30,7 @@
30	30
31	31	Action commands are session-specific, therefore once a servo is power cycled, it will not have any "memory" of previous actions or virtual positions (as described at the bottom of this page).
32	32
33		-== Action Modifiers ==
	30	+=== Action Modifiers ===
34	34
35	35	Two commands can be used as action modifiers only: Timed Move and Speed. The format is:
36	36
...	...	@@ -51,7 +51,7 @@
51	51
52	52	== Configuration Commands ==
53	53
54		-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 Servo (LSS).LSS - RC PWM.WebHome]].
	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:LSS - Overview (DEV).LSS - RC PWM.WebHome]].
55	55
56	56	1. Start with a number sign # (U+0023)
57	57	1. Servo ID number as an integer
...	...	@@ -109,7 +109,7 @@
109	109
110	110	#5QSR1<cr> would return *5QSR20<cr> which represents the value in EEPROM
111	111
112		-== Virtual Angular Position ==
	109	+=== Virtual Angular Position ===
113	113
114	114	{In progress}
115	115
...	...	@@ -136,62 +136,51 @@
136	136
137	137	= Command List =
138	138
139		-|= #|=Description|= Action|= Query|= Config|= RC|= Serial|= Units|= Notes|=(% style="width: 50px;" %)Default
140		-| 1|[[**L**imp>>||anchor="H1.Limp28L29"]]| L| | | | ✓|none| |(% style="text-align:center" %)
141		-| 2|[[**H**alt & Hold>>||anchor="H2.Halt26Hold28H29"]]| H| | | | ✓|none| |(% style="text-align:center" %)
142		-| 3|[[**T**imed move>>||anchor="H3.Timedmove28T29"]]| T| | | | ✓|milliseconds| Modifier only (P, D, MD)|(% style="text-align:center" %)
143		-| 4|[[**S**peed>>||anchor="H4.Speed28S29"]]| S| | | | ✓|microseconds / second| Modifier only (P)|(% style="text-align:center" %)
144		-| 5|[[**M**ove in **D**egrees (relative)>>||anchor="H5.28Relative29MoveinDegrees28MD29"]]| MD| | | | ✓|tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)| |(% style="text-align:center" %)
145		-| 6|[[**O**rigin Offset>>||anchor="H6.OriginOffsetAction28O29"]]| O| QO| CO| ✓| ✓|tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)| |(% style="text-align:center" %)(((
146		-00
147		-
148		-0.0 degrees
149		-)))
150		-| 7|[[**A**ngular **R**ange>>||anchor="H7.AngularRange28AR29"]]| AR| QAR| CAR| ✓| ✓|tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)| |(% style="text-align:center" %)(((
151		-1800
152		-
153		-180.0 degrees
154		-)))
155		-| 8|[[Position in **P**ulse>>||anchor="H8.PositioninPulse28P29"]]| P| QP| | | ✓|microseconds|(((
	136	+|= #|=Description|= Action|= Query|= Config|= RC|= Serial|= Units|= Notes
	137	+| 1|**L**imp| L| | | | ✓| none|
	138	+| 2|**H**alt & Hold| H| | | | ✓| none|
	139	+| 3|**T**imed move| T| | | | ✓| milliseconds| Modifier only
	140	+| 4|**S**peed| S| | | | ✓| microseconds / second| Modifier only
	141	+| 5|**M**ove in **D**egrees (relative)| MD| | | | ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
	142	+| 6|**O**rigin Offset| O| QO| CO| ✓| ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
	143	+| 7|**A**ngular **R**ange| AR| QAR| CAR| ✓| ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
	144	+| 8|Position in **P**ulse| P| QP| | | ✓| microseconds|(((
156	156	See details below
157		-)))|(% style="text-align:center" %)
158		-| 9|[[Position in **D**egrees>>||anchor="H9.PositioninDegrees28D29"]]| D| QD| | | ✓|tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)| |(% style="text-align:center" %)
159		-| 10|[[**W**heel mode in **D**egrees>>||anchor="H10.WheelModeinDegrees28WD29"]]| WD| QWD| | | ✓|tenths of degrees per second (ex 248 = 24.8 degrees per second)|A.K.A. "Speed mode" or "Continuous rotation"|(% style="text-align:center" %)
160		-| 11|[[**W**heel mode in **R**PM>>||anchor="H11.WheelModeinRPM28WR29"]]| WR| QWR| | | ✓| rpm|A.K.A. "Speed mode" or "Continuous rotation"|(% style="text-align:center" %)
161		-| 12|[[Max **S**peed in **D**egrees>>||anchor="H12.SpeedinDegrees28SD29"]]| SD| QSD| CSD| ✓| ✓|tenths of degrees per second (ex 248 = 24.8 degrees per second)|QSD: Add modifier "2" for instantaneous speed|(% style="text-align:center" %)
162		-| 13|[[Max **S**peed in **R**PM>>||anchor="H13.SpeedinRPM28SR29"]]| SR| QSR| CSR| ✓| ✓|rpm|QSR: Add modifier "2" for instantaneous speed|(% style="text-align:center" %)
163		-| 14|[[**A**ngular **S**tiffness>>||anchor="H14.AngularStiffness28AS29"]]| AS| QAS| CAS| ✓| ✓|none|-4 to +4, but suggested values are between 0 to +4|(% style="text-align:center" %)0
164		-| 15|[[**A**ngular **H**olding Stiffness>>||anchor="H15.AngularHoldStiffness28AH29"]]|AH|QAH|CAH| | ✓|none|-10 to +10, with default as 0. |(% style="text-align:center" %)
165		-|15b|[[**A**ngular **A**cceleration>>||anchor="H15b:AngularAcceleration28AA29"]]|AA|QAA|CAA| | ✓|degrees per second squared|Increments of 10 degrees per second squared|(% style="text-align:center" %)
166		-|15c|[[**A**ngular **D**eceleration>>||anchor="H15c:AngularDeceleration28AD29"]]|AD|QAD|CAD| | ✓|degrees per second squared|Increments of 10 degrees per second squared|(% style="text-align:center" %)
167		-|15d|[[**E**nable **M**otion control>>||anchor="H15d:MotionControl28MC29"]]|EM|QEM| | | ✓|none|EM0 to disable motion control, EM1 to enable. Session specific / does not survive power cycles|(% style="text-align:center" %)
168		-| 16|[[**LED** Color>>||anchor="H16.RGBLED28LED29"]]| LED| QLED| CLED| ✓| ✓|none (integer from 0 to 8)|0=Off (black); 1=Red 2=Green; 3=Blue; 4=Yellow; 5=Cyan; 6=Magenta; 7=White;|(% style="text-align:center" %)7
169		-| 16b|[[**C**onfigure **L**ED **B**linking>>||anchor="H16b.ConfigureLEDBlinking28CLB29"]]| | | CLB| ✓| |none (integer from 0 to 63)|0=No blinking, ; 63=Always blink; Blink while: 1=Limp; 2=Holding 4=Accel; 8=Decel; 16=Free 32=Travel;|(% style="text-align:center" %)
170		-| 17|[[**ID** #>>||anchor="H17.IdentificationNumber"]]| | QID| CID| | ✓|none (integer from 0 to 250)|Note: ID 254 is a "broadcast" which all servos respond to|(% style="text-align:center" %)0
171		-| 18|[[**B**aud rate>>||anchor="H18.BaudRate"]]| B| QB| CB| | ✓|none (integer)| |(% style="text-align:center" %)9600
172		-| 19|[[**G**yre direction (**G**)>>||anchor="H19.GyreRotationDirection"]]| G| QG| CG| ✓| ✓|none | Gyre / rotation direction where 1= CW (clockwise) -1 = CCW (counter-clockwise)|(% style="text-align:center" %)1 Clowckwise
173		-| 20|[[**F**irst Position (**P**ulse)>>||anchor="H20.First2InitialPosition28pulse29"]]| | QFP|CFP | ✓| ✓|none | |(% style="text-align:center" %)(((
174		-Limp
175	175	)))
176		-| 21|[[**F**irst Position (**D**egrees)>>||anchor="H21.First2InitialPosition28Degrees29"]]| | QFD|CFD| ✓| ✓|none | |(% style="text-align:center" %)Limp
177		-| 22|[[**T**arget (**D**egree) **P**osition>>||anchor="H22.QueryTargetPositioninDegrees28QDT29"]]| | QDT| | | ✓|tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)| |(% style="text-align:center" %)
178		-| 23|[[**M**odel **S**tring>>||anchor="H23.QueryModelString28QMS29"]]| | QMS| | | |none (string)| Recommended to determine the model|(% style="text-align:center" %) |
179		-| 23b|[[**M**odel>>||anchor="H23b.QueryModel28QM29"]]| | QM| | | |none (integer)| Returns a raw value representing the three model inputs (36 bit)|(% style="text-align:center" %) |
180		-| 24|[[Serial **N**umber>>||anchor="H24.QuerySerialNumber28QN29"]]| | QN| | | |none (integer)| |(% style="text-align:center" %)
181		-| 25|[[**F**irmware version>>||anchor="H25.QueryFirmware28QF29"]]| | QF| | | |none (integer)| |(% style="text-align:center" %)
182		-| 26|[[**Q**uery (general status)>>||anchor="H26.QueryStatus28Q29"]]| | Q| | | ✓|none (integer from 1 to 8)| See command description for details|(% style="text-align:center" %)
183		-| 27|[[**V**oltage>>||anchor="H27.QueryVoltage28QV29"]]| | QV| | | ✓|millivolts (ex 5936 = 5936mV = 5.936V)| |(% style="text-align:center" %)
184		-| 28|[[**T**emperature>>||anchor="H28.QueryTemperature28QT29"]]| | QT| | | ✓|tenths of degrees Celsius|Max temp before error: 85°C (servo goes limp)|(% style="text-align:center" %)
185		-| 29|[[**C**urrent>>||anchor="H29.QueryCurrent28QC29"]]| | QC| | | ✓|milliamps (ex 200 = 0.2A)| |(% style="text-align:center" %)
186		-| 30|[[**RC** Mode>>||anchor="H30.RCMode28CRC29"]]| | |CRC| |✓|none|(((
	147	+| 9|Position in **D**egrees| D| QD| | | ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
	148	+| 10|**W**heel mode in **D**egrees| WD| QWD| | | ✓| tenths of degrees per second (ex 248 = 24.8 degrees per second)|
	149	+| 11|**W**heel mode in **R**PM| WR| QWR| | | ✓| rpm|
	150	+| 12|Max **S**peed in **D**egrees| SD| QSD| CSD| ✓| ✓| tenths of degrees per second (ex 248 = 24.8 degrees per second)|QSD: Add modifier "2" for instantaneous speed
	151	+| 13|Max **S**peed in **R**PM| SR| QSR| CSR| ✓| ✓| rpm|QSR: Add modifier "2" for instantaneous speed
	152	+| 14|**A**ngular **S**tiffness| AS| QAS| CAS| ✓| ✓|none|-4 to +4, but suggested values are between 0 to +4
	153	+| 15|**A**ngular **H**olding Stiffness|AH|QAH|CAH| | ✓|none|-10 to +10, with default as 0.
	154	+|15b|**A**ngular **A**cceleration|AA|QAA|CAA| | ✓|degrees per second squared|Increments of 10 degrees per second squared
	155	+|15c|**A**ngular **D**eceleration|AD|QAD|CAD| | ✓|degrees per second squared|Increments of 10 degrees per second squared
	156	+|15d|**M**otion **C**ontrol|MC|QMC| | | ✓|none|MC0 to disable motion control, MC1 to enable. Session specific
	157	+| 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=MAGENTA, 7=WHITE
	158	+| 17|**ID** #| | QID| CID| | ✓| none (integer from 0 to 250)|Note: ID 254 is a "broadcast" which all servos respond to
	159	+| 18|**B**aud rate| B| QB| CB| | ✓| none (integer)|
	160	+| 19|**G**yre direction (**G**)| G| QG| CG| ✓| ✓| none | Gyre / rotation direction where 1= CW (clockwise) -1 = CCW (counter-clockwise)
	161	+| 20|**F**irst Position (**P**ulse)| | QFP|CFP | ✓| ✓| none |
	162	+| 21|**F**irst Position (**D**egrees)| | QFD|CFD| ✓| ✓| none |
	163	+| 22|**T**arget (**D**egree) **P**osition| | QDT| | | ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
	164	+| 23|**M**odel **String**| | QMS| | | | none (string)| Recommended to determine the model|
	165	+| 23b|**M**odel| | QM| | | | none (integer)| Returns a raw value representing the three model inputs (36 bit)|
	166	+| 24|Serial **N**umber| | QN| | | | none (integer)|
	167	+| 25|**F**irmware version| | QF| | | | none (integer)|
	168	+| 26|**Q**uery (general status)| | Q| | | ✓| none (integer from 1 to 8)| See command description for details
	169	+| 27|**V**oltage| | QV| | | ✓| millivolts (ex 5936 = 5936mV = 5.936V)|
	170	+| 28|**T**emperature| | QT| | | ✓| tenths of degrees Celsius|Max temp before error: 85°C (servo goes limp)
	171	+| 29|**C**urrent| | QC| | | ✓| milliamps (ex 200 = 0.2A)|
	172	+| 30|**RC** Mode| | |CRC| |✓|none|(((
187	187	CRC: Add modifier "1" for RC-position mode.
188	188	CRC: Add modifier "2" for RC-wheel mode.
189	189	Any other value for the modifier results in staying in smart mode.
190	190	Puts the servo into RC mode. To revert to smart mode, use the button menu.
191		-)))|(% style="text-align:center" %)Serial
192		-|31|[[**RESET**>>||anchor="H31.RESET"]]| | | | | ✓|none|Soft reset. See command for details.|(% style="text-align:center" %)
193		-|32|[[**DEFAULT**>>||anchor="H32.DEFAULTA026CONFIRM"]]| | | | |✓|none|Revert to firmware default values. See command for details|(% style="text-align:center" %)
194		-|33|[[**UPDATE**>>||anchor="H33.UPDATEA026CONFIRM"]]| | | | |✓|none|Update firmware. See command for details.|(% style="text-align:center" %)
	177	+)))
	178	+|31|**RESET**| | | | | ✓|none|Soft reset. See command for details.
	179	+|32|**DEFAULT**| | | | |✓|none|Revert to firmware default values. See command for details
	180	+|33|**UPDATE**| | | | |✓|none|Update firmware. See command for details.
195	195
196	196	== Details ==
197	197
...	...	@@ -201,33 +201,31 @@
201	201
202	202	This action causes the servo to go "limp". The microcontroller will still be powered, but the motor will not. As an emergency safety feature, should the robot not be doing what it is supposed to or risks damage, use the broadcast ID to set all servos limp #254L<cr>.
203	203
204		-====== __2. Halt & Hold (**H**)__ ======
	190	+__2. Halt & Hold (**H**)__
205	205
206	206	Example: #5H<cr>
207	207
208	208	This action overrides whatever the servo might be doing at the time the command is received (accelerating, moving continuously etc.) and causes it to stop immediately and hold that position.
209	209
210		-====== __3. Timed move (**T**)__ ======
	196	+__3. Timed move (**T**)__
211	211
212	212	Example: #5P1500T2500<cr>
213	213
214	214	Timed move can be used only as a modifier for a position (P) action. The units are in milliseconds, so a timed move of 2500 milliseconds would cause the servo to rotate from its current position to the desired position in 2.5 seconds. This command is in place to ensure backwards compatibility with the SSC-32 / 32U protocol.
215	215
216		-Note: If the calculated speed at which a servo must rotate for a timed move is greater than its maximum speed (which depends on voltage and load), then it will move at its maximum speed, and the time of the move may be longer than requested.
	202	+__4. Speed (**S**)__
217	217
218		-====== __4. Speed (**S**)__ ======
219		-
220	220	Example: #5P1500S750<cr>
221	221
222	222	This command is a modifier only for a position (P) action and determines the speed of the move in microseconds per second. A speed of 750 microseconds would cause the servo to rotate from its current position to the desired position at a speed of 750 microseconds per second. This command is in place to ensure backwards compatibility with the SSC-32 / 32U protocol.
223	223
224		-====== __5. (Relative) Move in Degrees (**MD**)__ ======
	208	+__5. (Relative) Move in Degrees (**MD**)__
225	225
226	226	Example: #5MD123<cr>
227	227
228	228	The relative move command causes the servo to read its current position and move the specified number of tenths of degrees in the corresponding position. For example if the servo is set to rotate CW (default) and an MD command of 123 is sent to the servo, it will cause the servo to rotate clockwise by 12.3 degrees. Negative commands would cause the servo to rotate in the opposite configured direction.
229	229
230		-====== __6. Origin Offset Action (**O**)__ ======
	214	+__6. Origin Offset Action (**O**)__
231	231
232	232	Example: #5O2400<cr>
233	233
...	...	@@ -251,7 +251,7 @@
251	251
252	252	This command allows you to change the origin of the servo in relation to the factory zero position in EEPROM. The setting will be saved upon servo reset / power cycle. Origin offset configuration commands are not cumulative and always relate to factory zero. The new origin is also used in RC mode.
253	253
254		-====== __7. Angular Range (**AR**)__ ======
	238	+__7. Angular Range (**AR**)__
255	255
256	256	Example: #5AR1800<cr>
257	257
...	...	@@ -275,7 +275,7 @@
275	275
276	276	This command allows you to change the total angular range of the servo in tenths of degrees in EEPROM. The setting will be saved upon servo reset / power cycle.
277	277
278		-====== __8. Position in Pulse (**P**)__ ======
	262	+__8. Position in Pulse (**P**)__
279	279
280	280	Example: #5P2334<cr>
281	281
...	...	@@ -288,7 +288,7 @@
288	288	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.
289	289	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 (note that if the servo is physically located at one of the endpoints, it may return a negative number if it is a fraction of a degree beyond the position).
290	290
291		-====== __9. Position in Degrees (**D**)__ ======
	275	+__9. Position in Degrees (**D**)__
292	292
293	293	Example: #5PD1456<cr>
294	294
...	...	@@ -302,7 +302,7 @@
302	302
303	303	This means the servo is located at 13.2 degrees.
304	304
305		-====== __10. Wheel Mode in Degrees (**WD**)__ ======
	289	+__10. Wheel Mode in Degrees (**WD**)__
306	306
307	307	Ex: #5WD900<cr>
308	308
...	...	@@ -314,7 +314,7 @@
314	314
315	315	The servo replies with the angular speed in tenths of degrees per second. A negative sign would indicate the opposite direction (for factory default a negative value would be counter clockwise).
316	316
317		-====== __11. Wheel Mode in RPM (**WR**)__ ======
	301	+__11. Wheel Mode in RPM (**WR**)__
318	318
319	319	Ex: #5WR40<cr>
320	320
...	...	@@ -326,7 +326,7 @@
326	326
327	327	The servo replies with the angular speed in rpm. A negative sign would indicate the opposite direction (for factory default a negative value would be counter clockwise).
328	328
329		-====== __12. Speed in Degrees (**SD**)__ ======
	313	+__12. Speed in Degrees (**SD**)__
330	330
331	331	Ex: #5SD1800<cr>
332	332
...	...	@@ -351,7 +351,7 @@
351	351
352	352	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 180.0 degrees per second. When the servo is powered on (or after a reset), the CSD value is used. Note that CSD and CSR (described below) 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.
353	353
354		-====== __13. Speed in RPM (**SR**)__ ======
	338	+__13. Speed in RPM (**SR**)__
355	355
356	356	Ex: #5SD45<cr>
357	357
...	...	@@ -376,7 +376,7 @@
376	376
377	377	Using the CSR 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 CSR 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.
378	378
379		-====== __14. Angular Stiffness (**AS**)__ ======
	363	+__14. Angular Stiffness (**AS**)__
380	380
381	381	The servo's rigidity / angular stiffness can be thought of as (though not identical to) a damped spring in which the value affects the stiffness and embodies how much, and how quickly the servo tried keep the requested position against changes.
382	382
...	...	@@ -404,7 +404,7 @@
404	404
405	405	Writes the desired angular stiffness value to memory.
406	406
407		-====== __15. Angular Hold Stiffness (**AH**)__ ======
	391	+__15. Angular Hold Stiffness (**AH**)__
408	408
409	409	The angular holding stiffness determines the servo's ability to hold a desired position under load. Values can be from -10 to 10, with the default being 0. Note that negative values mean the final position can be easily deflected.
410	410
...	...	@@ -424,19 +424,19 @@
424	424
425	425	This writes the angular holding stiffness of servo #5 to 2 to EEPROM
426	426
427		-====== __15b: Angular Acceleration (**AA**)__ ======
	411	+__15b: Angular Acceleration (**AA**)__
428	428
429	429	{More details to come}
430	430
431		-====== __15c: Angular Deceleration (**AD**)__ ======
	415	+__15c: Angular Deceleration (**AD**)__
432	432
433	433	{More details to come}
434	434
435		-====== __15d: Motion Control (**EM**)__ ======
	419	+__15d: Motion Control (**MC**)__
436	436
437	437	{More details to come}
438	438
439		-====== __16. RGB LED (**LED**)__ ======
	423	+__16. RGB LED (**LED**)__
440	440
441	441	Ex: #5LED3<cr>
442	442
...	...	@@ -454,22 +454,8 @@
454	454
455	455	Configuring the LED color via the CLED command sets the startup color of the servo after a reset or power cycle. Note that it also changes the session's LED color immediately as well.
456	456
457		-====== __16b. Configure LED Blinking (**CLB**)__ ======
	441	+__17. Identification Number__
458	458
459		-This command allows you to control when the RGB LED will blink the user set color (see [[16. RGB LED>>||anchor="H16.RGBLED28LED29"]] for details).
460		-You can turn on or off blinking for various LSS status. Here is the list and their associated value: 0=No blinking, ; 63=Always blink; Blink while: 1=Limp; 2=Holding 4=Accel; 8=Decel; 16=Free 32=Travel;
461		-
462		-To set blinking, use CLB with the value of your choosing. To activate blinking in multiple status, simply add together the values of the corresponding status. See examples below:
463		-
464		-Ex: #5CLB0<cr> to turn off all blinking (LED always solid)
465		-Ex: #5CLB1<cr> only blink when limp
466		-Ex: #5CLB2<cr> only blink when holding
467		-Ex: #5CLB12<cr> only blink when accel or decel
468		-Ex: #5CLB48<cr> only blink when free or travel
469		-Ex: #5CLB63<cr> blink in all status
470		-
471		-====== __17. Identification Number__ ======
472		-
473	473	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.
474	474
475	475	Query Identification (**QID**)
...	...	@@ -484,7 +484,7 @@
484	484
485	485	Setting a servo's ID in EEPROM is done via the CID command. All servos connected to the same serial bus will be assigned that ID. In most situations each servo must be set a unique ID, which means each servo must be connected individually to the serial bus and receive a unique CID number. It is best to do this before the servos are added to an assembly. Numbered stickers are provided to distinguish each servo after their ID is set, though you are free to use whatever alternative method you like.
486	486
487		-====== __18. Baud Rate__ ======
	457	+__18. Baud Rate__
488	488
489	489	A servo's baud rate cannot be set "on the fly" and must be configured via the CB command described below. The factory default baud rate for all servos is 9600. Since smart servos are intended to be daisy chained, in order to respond to the same serial bus, all servos in that project should ideally be set to the same baud rate. Setting different baud rates will have the servos respond differently and may create issues. Available baud rates are: 9.6 kbps, 19.2 kbps, 38.4 kbps, 57.6 kbps, 115.2 kbps, 230.4 kbps, 250.0 kbps, 460.8 kbps, 500.0 kbps, 750.0 kbps*, 921.6 kbps*. Servos are shipped with a baud rate set to 9600. The baud rates are currently restricted to those above.
490	490	\*: Current tests reveal baud rates above 500 kbps are unstable and can cause timeouts. Please keep this in mind if using those / testing them out.
...	...	@@ -501,7 +501,7 @@
501	501
502	502	Sending this command will change the baud rate associated with servo ID 5 to 9600 bits per second.
503	503
504		-====== __19. Gyre Rotation Direction__ ======
	474	+__19. Gyre Rotation Direction__
505	505
506	506	"Gyre" is defined as a circular course or motion. The effect of changing the gyre direction is as if you were to use a mirror image of a circle. CW = 1; CCW = -1. The factory default is clockwise (CW).
507	507
...	...	@@ -519,7 +519,7 @@
519	519
520	520	This changes the gyre direction as described above and also writes to EEPROM.
521	521
522		-====== __20. First / Initial Position (pulse)__ ======
	492	+__20. First / Initial Position (pulse)__
523	523
524	524	In certain cases, a user might want to have the servo move to a specific angle upon power up. We refer to this as "first position". The factory default has no first position value stored in EEPROM and therefore upon power up, the servo remains limp until a position (or hold command) is assigned. FP and FD are different in that FP is used for RC mode only, whereas FD is used for smart mode only.
525	525
...	...	@@ -535,7 +535,7 @@
535	535
536	536	This configuration command means the servo, when set to RC mode, will immediately move to an angle equivalent to having received an RC pulse of 1550 microseconds upon power up. Sending a CFP command without a number results in the servo remaining limp upon power up (i.e. disabled).
537	537
538		-====== __21. First / Initial Position (Degrees)__ ======
	508	+__21. First / Initial Position (Degrees)__
539	539
540	540	In certain cases, a user might want to have the servo move to a specific angle upon power up. We refer to this as "first position". The factory default has no first position value stored in EEPROM and therefore upon power up, the servo remains limp until a position (or hold command) is assigned. FP and FD are different in that FP is used for RC mode only, whereas FD is used for smart mode only.
541	541
...	...	@@ -551,37 +551,37 @@
551	551
552	552	This configuration command means the servo, when set to smart mode, will immediately move to 6.4 degrees upon power up. Sending a CFD command without a number results in the servo remaining limp upon power up.
553	553
554		-====== __22. Query Target Position in Degrees (**QDT**)__ ======
	524	+__22. Query Target Position in Degrees (**QDT**)__
555	555
556	556	Ex: #5QDT<cr> might return *5QDT6783<cr>
557	557
558	558	The query target position command returns the target angle during and after an action which results in a rotation of the servo horn. In the example above, the servo is rotating to a virtual position of 678.3 degrees. Should the servo not have a target position or be in wheel mode, it will respond without a number (Ex: *5QDT<cr>).
559	559
560		-====== __23. Query Model String (**QMS**)__ ======
	530	+__23. Query Model String (**QMS**)__
561	561
562	562	Ex: #5QMS<cr> might return *5QMSLSS-HS1cr>
563	563
564	564	This reply means the servo model is LSS-HS1, meaning a high speed servo, first revision.
565	565
566		-====== __23b. Query Model (**QM**)__ ======
	536	+__23b. Query Model (**QM**)__
567	567
568	568	Ex: #5QM<cr> might return *5QM68702699520cr>
569	569
570	570	This reply means the servo model is 0xFFF000000 or 100, meaning a high speed servo, first revision.
571	571
572		-====== __24. Query Serial Number (**QN**)__ ======
	542	+__24. Query Serial Number (**QN**)__
573	573
574	574	Ex: #5QN<cr> might return *5QN~_~_<cr>
575	575
576	576	The number in the response is the servo's serial number which is set and cannot be changed.
577	577
578		-====== __25. Query Firmware (**QF**)__ ======
	548	+__25. Query Firmware (**QF**)__
579	579
580	580	Ex: #5QF<cr> might return *5QF11<cr>
581	581
582	582	The integer in the reply represents the firmware version with one decimal, in this example being 1.1
583	583
584		-====== __26. Query Status (**Q**)__ ======
	554	+__26. Query Status (**Q**)__
585	585
586	586	Ex: #5Q<cr> might return *5Q6<cr>, which indicates the motor is holding a position.
587	587
...	...	@@ -591,32 +591,32 @@
591	591	|ex: *5Q2<cr>|Free moving|Motor driving circuit is not powered and horn can be moved freely
592	592	|ex: *5Q3<cr>|Accelerating|Increasing speed from rest (or previous speeD) towards travel speed
593	593	|ex: *5Q4<cr>|Traveling|Moving at a stable speed
594		-|ex: *5Q5<cr>|Decelerating|Decreasing from travel speed towards final position.
	564	+|ex: *5Q5<cr>|Deccelerating|Decreasing speed towards travel speed towards rest
595	595	|ex: *5Q6<cr>|Holding|Keeping current position
596	596	|ex: *5Q7<cr>|Stepping|Special low speed mode to maintain torque
597		-|ex: *5Q8<cr>|Outside limits|{More details coming soon}
	567	+|ex: *5Q8<cr>|Outside limits|More details coming soon
598	598	|ex: *5Q9<cr>|Stuck|Motor cannot perform request movement at current speed setting
599		-|ex: *5Q10<cr>|Blocked|Similar to stuck, but the motor is at maximum duty and still cannot move (i.e.: stalled)
	569	+|ex: *5Q10<cr>|Blocked|Similar to stuck, but the motor is at maxiumum duty and still cannot move (i.e.: stalled)
600	600
601		-====== __27. Query Voltage (**QV**)__ ======
	571	+__27. Query Voltage (**QV**)__
602	602
603	603	Ex: #5QV<cr> might return *5QV11200<cr>
604	604
605	605	The number returned has one decimal, so in the case above, servo with ID 5 has an input voltage of 11.2V (perhaps a three cell LiPo battery).
606	606
607		-====== __28. Query Temperature (**QT**)__ ======
	577	+__28. Query Temperature (**QT**)__
608	608
609	609	Ex: #5QT<cr> might return *5QT564<cr>
610	610
611	611	The units are in tenths of degrees Celcius, so in the example above, the servo's internal temperature is 56.4 degrees C. To convert from degrees Celcius to degrees Farenheit, multiply by 1.8 and add 32. Therefore 56.4C = 133.52F.
612	612
613		-====== __29. Query Current (**QC**)__ ======
	583	+__29. Query Current (**QC**)__
614	614
615	615	Ex: #5QC<cr> might return *5QC140<cr>
616	616
617	617	The units are in milliamps, so in the example above, the servo is consuming 140mA, or 0.14A.
618	618
619		-====== __30. RC Mode (**CRC**)__ ======
	589	+__30. RC Mode (**CRC**)__
620	620
621	621	This command puts the servo into RC mode (position or continuous), where it will only respond to RC pulses. Note that because this is the case, the servo will no longer accept serial commands. The servo can be placed back into smart mode by using the button menu.
622	622
...	...	@@ -628,13 +628,13 @@
628	628
629	629	EX: #5CRC<cr>
630	630
631		-====== __31. RESET__ ======
	601	+__31. RESET__
632	632
633	633	Ex: #5RESET<cr> or #5RS<cr>
634	634
635	635	This command does a "soft reset" (no power cycle required) and reverts all commands to those stored in EEPROM (i.e. configuration commands).
636	636
637		-====== __32. DEFAULT & CONFIRM__ ======
	607	+__32. DEFAULT & CONFIRM__
638	638
639	639	Ex: #5DEFAULT<cr>
640	640
...	...	@@ -646,7 +646,7 @@
646	646
647	647	Note that after the CONFIRM command is sent, the servo will automatically perform a RESET.
648	648
649		-====== __33. UPDATE & CONFIRM__ ======
	619	+__33. UPDATE & CONFIRM__
650	650
651	651	Ex: #5UPDATE<cr>
652	652

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