Summary

• Page properties (1 modified, 0 added, 0 removed)

Details

Page properties

Content

...	...	@@ -90,15 +90,15 @@
90	90	The v1.1 includes the SSC-32 is an easy to use dedicated 32 servo controller. It can be connected to a computer via the DB9 connector or to the Serial to XBee breakout board. The SSC-32 can also be connected to another microcontroller via the Tx and Rx pins. The SSC-32 is not "programmable" as such - you simply send it position commands. The V1.1 does not include this part.
91	91	|[[image:SSC-32U.jpg]]|[[SSC-32U User Guide>>attach:servo-erector-set-system.ses-electronics.ses-modules.ssc-32u.WebHome@lynxmotion_ssc-32u_usb_user_guide.pdf]]
92	92	The newer S.E.S V1.2 includes the SSC-32U, which is an updated USB version of the dedicated SSC-32 servo controller. It can be connected to a computer via USB or Bluetooth Bee module. The SSC-32 can also be connected to another microcontroller via the Tx and Rx pins. The SSC-32 is not "programmable" as such - you simply send it position commands. The V1.1 does not include this part.
93		-|[[image:servo-erector-set-system.ses-electronics.ses-modules.botboarduino.WebHome@BBU-01.PNG]]|DFRobot Bluetooth Module User Guide (PDF)
	93	+| |DFRobot Bluetooth Module User Guide (PDF)
94	94	The DFRobot Bluetooth module operates at 9600 baud (so be sure to change the jumpers on the SSC-32) and the default pairing code is 1234. The module uses the standard XBee format. Once the module has paired with the computer, the green LED located in the lower right side of the board will light up and stay solid.
95		-|[[image:servo-erector-set-system.ses-electronics.ses-modules.botboarduino.WebHome@BBU-01.PNG]]| Serial to XBee Breakout Board Datasheet (PDF)
	95	+| | Serial to XBee Breakout Board Datasheet (PDF)
96	96	The Serial to XBee breakout board is only included with the V1.1 and allows the DFRobot Bluetooth module to be connected directly to the SSC-32 board. Note that the board needs to be powered by running a pair of standard wires from the underside of the board to the SSC-32's pins (as described in the user guides).
97	97	The S.E.S. V1.2 does not include this part since the SSC-32U is already XBee compatible.
98	98	|(% colspan="2" %)(((
99	99	== **Assembly Guides** ==
100	100	)))
101		-|[[image:[email protected]||alt="BBU-01.PNG"]]|(((
	101	+|(% style="vertical-align:middle" %)[[image:[email protected]||alt="BBU-01.PNG"]]|(((
102	102	**A2WD1 (2WD) Rover**
103	103
104	104	The rover assembly guide shows how to assemble the robot using just the SSC-32 controller (for FlowBotics Studio) or using the BotBoarduino (Arduino). We suggest building and programming this robot first.
...	...	@@ -105,7 +105,7 @@
105	105
106	106	* [[doc:wheeled-tracked.2wd-rover-assembly-v1\.1.WebHome]]
107	107	)))
108		-|[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-arms.al5d.WebHome@al5d.jpg||alt="BBU-01.PNG"]]|(((
	108	+|(% style="vertical-align:middle" %)[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-arms.al5d.WebHome@al5d.jpg||alt="BBU-01.PNG"]]|(((
109	109	**AL5D Robotic Arm**
110	110
111	111	The AL5D arm can be assembled using either the BotBoarduino or the SSC-32 controller. We suggest building this robot second. Note that you will need to disassemble the 2WD rover to assemble the arm.
...	...	@@ -113,7 +113,7 @@
113	113	* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-arms.arm-base-v-2-1.WebHome]]
114	114	* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-arms.al5d-arm-rev-2-1.WebHome]]
115	115	)))
116		-|[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-bipeds.brat.WebHome@brat.jpg||alt="BBU-01.PNG"]]|(((
	116	+|(% style="vertical-align:middle" %)[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-bipeds.brat.WebHome@brat.jpg||alt="BBU-01.PNG"]]|(((
117	117	**BRAT Biped Robot**
118	118
119	119	The BRAT can be assembled using either the SSC-32 controller or the BotBoarduino. The BRAT uses only three servos per leg which allows for basic motion. If you are comfortable with either the Arduino code or the FlowBotics Studio code, you can try to add an additional degree of freedom to each leg. Please refer to the Arduino sample code to know which pins are connected to which servos.
...	...	@@ -120,7 +120,7 @@
120	120
121	121	* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-bipeds.brat-biped.WebHome]]
122	122	)))
123		-|[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-2dof-hexapods.mh2.WebHome@mh2u.jpg||alt="BBU-01.PNG"]]|(((
	123	+|(% style="vertical-align:middle" %)[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-2dof-hexapods.mh2.WebHome@mh2u.jpg||alt="BBU-01.PNG"]]|(((
124	124	**MH2 Hexapod Robot**
125	125
126	126	The MH2 robot assembly differs slightly from the guide shown because the SES V1.1 includes 4x HS-422 servos and 8x HS-645MG servos, therefore you will need to replace two HS-422 servos with 2x HS-645MG servos.
...	...	@@ -128,7 +128,7 @@
128	128	* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-2dof-hexapods.simple-2-dof-leg.WebHome]]
129	129	* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-2dof-hexapods.mini-inline-hexapod-body.WebHome]]
130	130	)))
131		-|[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-quadrapods.sq3-symmetric-quad.WebHome@SQ3U.jpg||alt="BBU-01.PNG"]]|(((
	131	+|(% style="vertical-align:middle" %)[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-quadrapods.sq3-symmetric-quad.WebHome@SQ3U.jpg||alt="BBU-01.PNG"]]|(((
132	132	**SQ3 Quadruped Robot**
133	133
134	134	The SQ3 quadruped is the most complex robot which can be built with the kit and is for users who feel comfortable with the electronics and software.
...	...	@@ -136,5 +136,3 @@
136	136	* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-3-4-dof-hexapods.3-dof-leg-v2.WebHome]]
137	137	* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-quadrapods.quadrapod-qbk-02.WebHome]]
138	138	)))
139		-
140		-