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1		-lynxmotion:LSS - Overview (DEV).WebHome
	1	+Main.WebHome

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

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

Content

...	...	@@ -39,31 +39,9 @@
39	39
40	40	Results in the servo rotating from the current angular position to a pulse position of 1456 in 1263 milliseconds.
41	41
42		-Action modifiers can only be used with certain commands.
	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:LSS - Overview (DEV).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:
...	...	@@ -91,46 +91,26 @@
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
	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.
108	108
109		-=== Virtual Angular Position ===
110		-
111		-{In progress}
112		-
113		-A "virtual position" is one which allows for multiple rotations of the output horn, moving the center position and more. The "absolute position" would be the angle of the output shaft with respect to 360.0 degrees.
114		-
115		-[[image:LSS-servo-positions.jpg]]
116		-
117		-Example: Gyre direction / rotation is positive (clockwise), and origin offset has not been modified. Each square represents 30 degrees.
118		-
119		-#1D-300<cr> The servo is sent a command to move to -30.0 degrees (green arrow)
120		-
121		-#1D2100<cr> This second position command is sent to the servo, which moves it to 210.0 degrees (orange arrow)
122		-
123		-#1D-4200<cr> This next command rotates the servo counterclockwise to a position of -420 degrees (red arrow), which means one full rotation of 360 degrees,  stopping at an absolute position of 60.0 degrees (420.0-360.0), with a virtual position of -420.0 degrees.
124		-
125		-Although the final physical position would be the same as if the servo were commanded to move to -60.0 degrees, the servo is in fact at -420.0 degrees.
126		-
127		-#1D4800<cr> This new command is sent which would then cause the servo to rotate from -420.0 degrees to 480.0 degrees (blue arrow), which would be a total of 900 degrees of clockwise rotation, or 2.5 complete rotations.
128		-
129		-#1D3300<cr> would cause the servo to rotate from 480.0 degrees to 330.0 degrees (yellow arrow).
130		-
131		-If / once the servo loses power or is power cycled, it also loses the virtual position associated with that session. For example, if the virtual position was 480.0 degrees before power is cycled, upon power up the servo's position will be read as +120.0 degrees from zero (assuming center position has not been modified).
132		-)))
133		-
134	134	= Command List =
135	135
136	136	|= #|=Description|= Action|= Query|= Config|= RC|= Serial|= Units|= Notes
...	...	@@ -141,39 +141,30 @@
141	141	| 5|**M**ove in **D**egrees (relative)| MD| | | | ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
142	142	| 6|**O**rigin Offset| O| QO| CO| ✓| ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
143	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|(((
145		-See details below
146		-)))
	102	+| 8|Position in **P**ulse| P| QP| | | ✓| microseconds|
147	147	| 9|Position in **D**egrees| D| QD| | | ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
148	148	| 10|**W**heel mode in **D**egrees| WD| QWD| | | ✓| tenths of degrees per second (ex 248 = 24.8 degrees per second)|
149	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|//N/A (removed)//| | | | | | |
154		-| 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
155		-| 17|**ID** #| | QID| CID| | ✓| none (integer from 0 to 250)|Note: ID 254 is a "broadcast" which all servos respond to
	106	+| 12|**S**peed in **D**egrees| SD| QSD| CSD| ✓| ✓| tenths of degrees per second (ex 248 = 24.8 degrees per second)|
	107	+| 13|**S**peed in **R**PM| SR| QSR| CSR| ✓| ✓| rpm|
	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|
	110	+| 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
	111	+| 17|**ID** #| ID| QID| CID| | ✓| none (integer from 0 to 254)|
156	156	| 18|**B**aud rate| B| QB| CB| | ✓| none (integer)|
157	157	| 19|**G**yre direction (**G**)| G| QG| CG| ✓| ✓| none | Gyre / rotation direction where 1= CW (clockwise) -1 = CCW (counter-clockwise)
158		-| 20|**F**irst Position (**P**ulse)| | QFP|CFP | ✓| ✓| none |
159		-| 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 |\\
160	160	| 22|**T**arget (**D**egree) **P**osition| | QDT| | | ✓| tenths of degrees (ex 325 = 32.5 degrees; 91 = 9.1 degrees)|
161	161	| 23|**M**odel| | QM| | | | none (integer)|
162	162	| 24|Serial **N**umber| | QN| | | | none (integer)|
163	163	| 25|**F**irmware version| | QF| | | | none (integer)|
164		-| 26|**Q**uery (general status)| | Q| | | ✓| none (integer from 1 to 8)| See command description for details
	120	+| 26|**Q**uery (general status)| | Q| | | ✓| none (integer from 1 to 8)|
165	165	| 27|**V**oltage| | QV| | | ✓| tenths of volt (ex 113 = 11.3V; 92 = 9.2V)|
166		-| 28|**T**emperature| | QT| | | ✓| degrees Celsius|Max temp before error: 85°C (servo goes limp)
	122	+| 28|**T**emperature| | QT| | | ✓| degrees Celsius|
167	167	| 29|**C**urrent| | QC| | | ✓| tenths of Amps (ex 2 = 0.2A)|
168		-| 30|**RC** Mode| | |CRC| |✓| |(((
169		-CRC: Add modifier "1" for RC-position mode.
170		-CRC: Add modifier "2" for RC-wheel mode.
171		-Any other value for the modifier results in staying in smart mode.
172		-Puts the servo into RC mode. To revert to smart mode, use the button menu.
173		-)))
174		-|31|**RESET**| | | | | ✓|none|Soft reset. See command for details.
175		-|32|**DEFAULT**| | | | |✓|none|Revert to firmware defaults. See command for details
176		-|33|**UPDATE**| | | | |✓|none|Update firmware. See command for details.
	124	+|| | | | | || |
	125	+|| | | | | | | |
177	177
178	178	= Details =
179	179
...	...	@@ -259,14 +259,13 @@
259	259
260	260	Example: #5P2334<cr>
261	261
262		-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
263	263
264	264	Query Position in Pulse (**QP**)
265	265
266		-Example: #5QP<cr> might return *5QP2334
	215	+Example: #5QP<cr> might return *5QP
267	267
268		-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.
269		-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).
	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.
270	270
271	271	__9. Position in Degrees (**D**)__
272	272
...	...	@@ -278,10 +278,8 @@
278	278
279	279	Query Position in Degrees (**QD**)
280	280
281		-Example: #5QD<cr> might return *5QD132<cr>
	229	+Example: #5QD<cr> might return *5QD0<cr>
282	282
283		-This means the servo is located at 13.2 degrees.
284		-
285	285	__10. Wheel Mode in Degrees (**WD**)__
286	286
287	287	Ex: #5WD900<cr>
...	...	@@ -316,15 +316,8 @@
316	316
317	317	Ex: #5QSD<cr> might return *5QSD1800<cr>
318	318
319		-By default QSD will return the current session value, which is set to the value of CSD as reset/power cycle and changed whenever a SD/SR command is processed.
320		-If #5QSD1<cr> is sent, the configured maximum speed (CSD value) will be returned instead. You can also query the current speed using "2" and the current target travel speed using "3". See the table below for an example:
	265	+Note that the QSD query will return the current servo speed. Querying the last maximum speed value set using SD or CSD is not possible.
321	321
322		-|**Command sent**|**Returned value (1/10 °)**
323		-|ex: #5QSD<cr>|Session value for maximum speed (set by latest SD/SR command)
324		-|ex: #5QSD1<cr>|Configured maximum speed  (set by CSD/CSR)
325		-|ex: #5QSD2<cr>|Instantaneous speed (same as QWD)
326		-|ex: #5QSD3<cr>|Target travel speed
327		-
328	328	Configure Speed in Degrees (**CSD**)
329	329
330	330	Ex: #5CSD1800<cr>
...	...	@@ -341,53 +341,54 @@
341	341
342	342	Ex: #5QSR<cr> might return *5QSR45<cr>
343	343
344		-By default QSR will return the current session value, which is set to the value of CSR as reset/power cycle and changed whenever a SD/SR command is processed.
345		-If #5QSR1<cr> is sent, the configured maximum speed (CSR value) will be returned instead. You can also query the current speed using "2" and the current target travel speed using "3". See the table below for an example:
	283	+Note that the QSD query will return the current servo speed. Querying the last maximum speed value set using SR or CSR is not possible.
346	346
347		-|**Command sent**|**Returned value (1/10 °)**
348		-|ex: #5QSR<cr>|Session value for maximum speed (set by latest SD/SR command)
349		-|ex: #5QSR1<cr>|Configured maximum speed  (set by CSD/CSR)
350		-|ex: #5QSR2<cr>|Instantaneous speed (same as QWR)
351		-|ex: #5QSR3<cr>|Target travel speed
	285	+Configure Speed in Degrees (**CSR**)
352	352
353		-Configure Speed in RPM (**CSR**)
354		-
355	355	Ex: #5CSR45<cr>
356	356
357		-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.
	289	+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.
358	358
359		-__14. Angular Stiffness (AS)__
	291	+__14. Angular Acceleration (**AA**)__
360	360
361		-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.
	293	+{More information coming soon}
362	362
363		-A positive value of "angular stiffness":
	295	+Ex:
364	364
365		-* The more torque will be applied to try to keep the desired position against external input / changes
366		-* 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}
367	367
368		-A negative value on the other hand:
	299	+Query Angular Acceleration (**QAA**)
369	369
370		-* Causes a slower acceleration to the travel speed, and a slower deceleration
371		-* Allows the target position to deviate more from its position before additional torque is applied to bring it back
	301	+Ex:
372	372
373		-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}
374	374
375		-Ex: #5AS-2<cr>
	305	+Configure Angular Acceleration (**CAA**)
376	376
377		-This reduces the angular stiffness 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:
378	378
379		-Ex: #5QAS<cr>
	309	+{Description coming soon}
380	380
381		-Queries the value being used.
	311	+__15. Angular Deceleration (**AD**)__
382	382
383		-Ex: #5CAS<cr>
	313	+{More information coming soon}
384	384
385		-Writes the desired angular stiffness value to memory.
	315	+Ex:
386	386
387		-__15. N/A (removed)__
	317	+{Description coming soon}
388	388
389		-This command has been removed.
	319	+Query Angular Acceleration (**QAD**)
390	390
	321	+Ex:
	322	+
	323	+{Description coming soon}
	324	+
	325	+Configure Angular Acceleration (**CAD**)
	326	+
	327	+Ex:
	328	+
	329	+{Description coming soon}
	330	+
391	391	__16. RGB LED (**LED**)__
392	392
393	393	Ex: #5LED3<cr>
...	...	@@ -394,7 +394,7 @@
394	394
395	395	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.
396	396
397		-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
398	398
399	399	Query LED Color (**QLED**)
400	400
...	...	@@ -404,28 +404,27 @@
404	404
405	405	Configure LED Color (**CLED**)
406	406
407		-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.
	347	+Configuring the LED color via the CLED command sets the startup color of the servo after a reset or power cycle.
408	408
409	409	__17. Identification Number__
410	410
411		-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.
412	412
413	413	Query Identification (**QID**)
414	414
415		-EX: #254QID<cr> might return *QID5<cr>
	355	+EX: #QID<cr> might return *QID5<cr>
416	416
417		-When using the query ID command, it is best to only have one servo connected and thus receive only one reply using the broadcast command (ID 254). Alternatively, pushing the button upon startup and temporarily setting the servo ID to 255 will still result in the servo responding with its "real" ID.
	357	+When using the query ID command, it is best to only have one servo connected and thus receive only one reply.
418	418
419	419	Configure ID (**CID**)
420	420
421		-Ex: #4CID5<cr>
	361	+Ex: #CID5<cr>
422	422
423	423	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.
424	424
425	425	__18. Baud Rate__
426	426
427		-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.
428		-\*: 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.
	367	+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. Standard / suggested baud rates are: 4800; 9600; 14400; 19200; 38400; 57600; 115200; 128000; 256000, 512000 bits per second. Servos are shipped with a baud rate set to 9600. The baud rates are currently restricted to those above
429	429
430	430	Query Baud Rate (**QB**)
431	431
...	...	@@ -459,23 +459,23 @@
459	459
460	460	__20. First / Initial Position (pulse)__
461	461
462		-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.
	401	+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 serial mode only.
463	463
464	464	Query First Position in Pulses (**QFP**)
465	465
466	466	Ex: #5QFP<cr> might return *5QFP1550<cr>
467	467
468		-The reply above indicates that servo with ID 5 has a first position pulse of 1550 microseconds. If no first position has been set, servo will respond with DIS ("disabled").
	407	+The reply above indicates that servo with ID 5 has a first position pulse of 1550 microseconds.
469	469
470		-Configure First Position in Pulses (**CFP**)
	409	+Configure First Position in Pulses (CFP)
471	471
472	472	Ex: #5CP1550<cr>
473	473
474		-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).
	413	+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.
475	475
476	476	__21. First / Initial Position (Degrees)__
477	477
478		-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.
	417	+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 serial mode only.
479	479
480	480	Query First Position in Degrees (**QFD**)
481	481
...	...	@@ -487,7 +487,7 @@
487	487
488	488	Ex: #5CD64<cr>
489	489
490		-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.
	429	+This configuration command means the servo, when set to serial 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.
491	491
492	492	__22. Query Target Position in Degrees (**QDT**)__
493	493
...	...	@@ -515,20 +515,9 @@
515	515
516	516	__26. Query Status (**Q**)__
517	517
518		-Ex: #5Q<cr> might return *5Q6<cr>, which indicates the motor is holding a position.
	457	+Ex: #5Q<cr> might return *5Q_<cr>
519	519
520		-|*Value returned|**Status**|**Detailed description**
521		-|ex: *5Q0<cr>|Unknown|LSS is unsure
522		-|ex: *5Q1<cr>|Limp|Motor driving circuit is not powered and horn can be moved freely
523		-|ex: *5Q2<cr>|Free moving|Motor driving circuit is not powered and horn can be moved freely
524		-|ex: *5Q3<cr>|Accelerating|Increasing speed from rest (or previous speeD) towards travel speed
525		-|ex: *5Q4<cr>|Traveling|Moving at a stable speed
526		-|ex: *5Q5<cr>|Deccelerating|Decreasing speed towards travel speed towards rest
527		-|ex: *5Q6<cr>|Holding|Keeping current position
528		-|ex: *5Q7<cr>|Stepping|Special low speed mode to maintain torque
529		-|ex: *5Q8<cr>|Outside limits|More details coming soon
530		-|ex: *5Q9<cr>|Stuck|Motor cannot perform request movement at current speed setting
531		-|ex: *5Q10<cr>|Blocked|Similar to stuck, but the motor is at maxiumum duty and still cannot move (i.e.: stalled)
	459	+{Description coming soon}
532	532
533	533	__27. Query Voltage (**QV**)__
534	534
...	...	@@ -542,52 +542,51 @@
542	542
543	543	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.
544	544
545		-__29. Query Current (**QC**)__
	473	+__29. Query Current (QC)__
546	546
547	547	Ex: #5QC<cr> might return *5QC140<cr>
548	548
549	549	The units are in milliamps, so in the example above, the servo is consuming 140mA, or 0.14A.
550	550
551		-__30. RC Mode (**CRC**)__
	479	+__**RESET**__
552	552
553		-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.
554		-
555		-|**Command sent**|**Note**
556		-|ex: #5CRC<cr>|Stay in smart mode.
557		-|ex: #5CRC1<cr>|Change to RC position mode.
558		-|ex: #5CRC2<cr>|Change to RC continuous (wheel) mode.
559		-|ex: #5CRC*<cr>|Where * is any number or value. Stay in smart mode.
560		-
561		-EX: #5CRC<cr>
562		-
563		-__31. RESET__
564		-
565	565	Ex: #5RESET<cr> or #5RS<cr>
566	566
567	567	This command does a "soft reset" (no power cycle required) and reverts all commands to those stored in EEPROM (i.e. configuration commands).
568	568
569		-__32. DEFAULT & CONFIRM__
	485	+**__DEFAULT__**
570	570
571	571	Ex: #5DEFAULT<cr>
572	572
573		-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.
574	574
575		-EX: #5DEFAULT<cr> followed by #5CONFIRM<cr>
	491	+__**FIRMWARE** & **CONFIRM**__
576	576
	493	+Ex: #5FIRMWARE<cr>
	494	+
	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.
	496	+
	497	+EX: #5FIRMWARE<cr> followed by #5CONFIRM<cr>
	498	+
577	577	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.
578	578
579		-Note that after the CONFIRM command is sent, the servo will automatically perform a RESET.
580	580
581		-__33. UPDATE & CONFIRM__
	502	+=== Virtual Angular Position ===
582	582
583		-Ex: #5UPDATE<cr>
	504	+{In progress}
584	584
585		-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.
	506	+A "virtual position" is one which allows for multiple rotations of the output horn, moving the center position and more. The "absolute position" would be the angle of the output shaft with respect to 360.0 degrees.
586	586
587		-EX: #5UPDATE<cr> followed by #5CONFIRM<cr>
	508	+[[image:LSS-servo-positions.jpg]]
588	588
589		-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.
	510	+Example: Gyre direction / rotation is positive (clockwise), and origin offset has not been modified.
590	590
591		-Note that after the CONFIRM command is sent, the servo will automatically perform a RESET.
	512	+#1D-300<cr> The servo is commander to move to -30.0 degrees (green arrow)
592	592
593		-=== ===
	514	+#1D2100<cr> This second position command is sent to the servo, which moves it to 210.0 degrees (orange arrow)
	515	+
	516	+#1D-4200<cr> The servo rotates counterclockwise to a position of -420 degrees (red arrow), which means one full rotation of 360 degrees and (420.0-360.0) stopping at an absolute position of 60.0 degrees, but virtual position of -420.0.
	517	+
	518	+Although the final position would be the same as if the servo were commanded to move to -60.0 degrees, it is in fact at -420.0 degrees.
	519	+
	520	+#1D4800<cr> This new command is sent which would then cause the servo to rotate from -420.0 degrees to 480.0 degrees, which would be a total of 900 degrees of clockwise rotation, or 2.5 complete rotations.