Changes for page SES-V1 Servo Erector Set V1.1
Last modified by Eric Nantel on 2024/07/03 11:22
Change comment: Upload new image "bratcbu.jpg", version 1.1
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... ... @@ -1,1 +1,1 @@ 1 -S ES-V1 - Servo Erector Set V1.11 +Servo Erector Set (SES) V1.1 - Hidden
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... ... @@ -1,4 +1,4 @@ 1 -[[image: SES-V1.1-01.jpg||queryString="width=350" width="350"]]1 +[[image:ah203kt.jpg||queryString="width=350" width="350"]] 2 2 3 3 [[[[image:[email protected]]]>>https://www.robotshop.com/products/lynxmotion-servo-erector-set-v1-1]] 4 4 ... ... @@ -7,7 +7,7 @@ 7 7 {{toc/}} 8 8 9 9 |((( 10 -= Description=10 += About the Servo Erector Set V1.1 = 11 11 ))) 12 12 |((( 13 13 (% class="wikigeneratedid" id="HAbouttheServoErectorSetV1.1" %) ... ... @@ -29,13 +29,10 @@ 29 29 = Software = 30 30 )))|(% style="text-align:center; vertical-align:middle; width:200px" %) 31 31 |((( 32 -**FlowBotics Studio V2** 33 - 34 -* Included with the SES kit is the new FlowBotics Studio V2 (which itself includes the complete FlowStone programming language!). FlowBotics Studio is an easy to use graphical and text-based, Windows -compatible software for programming and controlling anything you build without the need to create lines of code. FlowBotics Studio interacts directly with the SSC-32 servo controller via Bluetooth (no need for the BotBoarduino), off-loading all of the higher level mathematics to the computer. There is also a visual representation of each of the five sample robots which you can manipulate on screen to make it easier to position the servos for each sequence. All the tools and tutorials are available to help you build upon these samples or create your own from scratch. Sample code is available for each of the five robots outlined below.More about FlowBotics Studio can be found here. 35 - 36 -**Arduino** 37 - 38 -* The BotBoarduino is based on the Arduino Duemilanove microcontroller, which means it can be programmed in Arduino (one of the most popular and easy to use programming languages around)!. There is code available to control each of the five sample robots using the PS2 transmitter / receiver, and once you get used to programming in Arduino, you can explore the code further, and add to it, optimize it and share it with others. Robots which use only a small number of servos such as the BRAT, 2WD Rover and AL5D arm only need the BotBoarduino. Sample code is available in order to control each of the five robots below using the PS2 controller. Download Arduino here. 32 +* **FlowBotics Studio V2** 33 +** Included with the SES kit is the new FlowBotics Studio V2 (which itself includes the complete FlowStone programming language!). FlowBotics Studio is an easy to use graphical and text-based, Windows -compatible software for programming and controlling anything you build without the need to create lines of code. FlowBotics Studio interacts directly with the SSC-32 servo controller via Bluetooth (no need for the BotBoarduino), off-loading all of the higher level mathematics to the computer. There is also a visual representation of each of the five sample robots which you can manipulate on screen to make it easier to position the servos for each sequence. All the tools and tutorials are available to help you build upon these samples or create your own from scratch. Sample code is available for each of the five robots outlined below.More about FlowBotics Studio can be found here. 34 +* **Arduino** 35 +** The BotBoarduino is based on the Arduino Duemilanove microcontroller, which means it can be programmed in Arduino (one of the most popular and easy to use programming languages around)!. There is code available to control each of the five sample robots using the PS2 transmitter / receiver, and once you get used to programming in Arduino, you can explore the code further, and add to it, optimize it and share it with others. Robots which use only a small number of servos such as the BRAT, 2WD Rover and AL5D arm only need the BotBoarduino. Sample code is available in order to control each of the five robots below using the PS2 controller. Download Arduino here. 39 39 )))|(% style="text-align:center; vertical-align:middle; width:300px" %)[[image:flowbotics-studio-arduino.jpg]] 40 40 41 41 |(% colspan="2" style="width:200px" %)((( ... ... @@ -50,96 +50,13 @@ 50 50 |[[image:rc-01 v2.jpg]]|(% style="vertical-align:middle" %)**Lynxmotion PS2 Controller** 51 51 This 2.4ghz wireless Play Station 2 style controller has a range of 10 meters when used outdoors. The controller can be connected directly to the BotBoarduino, Two analog joysticks and 16 buttons available for robot control. Dual vibration motors provide tactile feedback for robots programmed with obstacle sensors (Version 2). We are also including a USB to PS2 receiver so the PS2 remote can communicate with the computer, allowing you to control the robots virtually. 52 52 53 -|(% style="vertical-align:middle" %)((( 54 -**AL5D Robotic Arm** 50 +| |(% style="width:300px" %) |(% style="width:300px" %) 51 +| | | 52 +| | | 53 +| | | 54 +| | | 55 55 56 -The AL5D robotic arm delivers fast, accurate, and repeatable movement. The robot features: base rotation, single plane shoulder, elbow, wrist motion, a functional gripper, and optional wrist rotate. The AL5D robotic arm is an affordable system with a time tested rock solid design that will last and last. Everything needed to assemble and operate the robot is included in the kit and accessories such as a rotating wrist or vacuum gripper are sold separately. 57 -The assembly guide, specifications and more for the AL5D can be found here. 58 -)))|(% style="vertical-align:middle; width:300px" %){{lightbox image="flowbotics-studio-armcontrol.jpg"/}}|(% style="width:300px" %){{lightbox image="al5dcu.jpg"/}} 59 -|(% style="vertical-align:middle" %)((( 60 -**SQ3 Symmetric Quadruped Robot** 56 += Specifications = 61 61 62 -The SQ3 is a 3DoF per leg quadruped robot with a symmetric body design. The robot's symmetry makes this a very unique quadruped walker. The three DOF (degree of freedom) leg design provides the flexibility required to walk in any direction as well as body roll! The robot uses eight HS-645MG servos along with four HS-422 servos. The SES kit includes everything you need to make a functional robot. 63 -The assembly guide, specifications and more for the SQ3 can be found here. 64 -)))|(% style="vertical-align:middle" %){{lightbox image="flowbotics-studio-quadruped.jpg"/}}|{{lightbox image="sq3u.jpg"/}} 65 -|(% style="vertical-align:middle" %)((( 66 -**MH2 Hexapod Robot** 67 67 68 -The MH2 hexapod robot is designed around a simple mechanical leg design with all metal brackets. This leg design minimizes the number of parts required to make a two DOF (degree of freedom) leg and allows this robot to be steered like a tank. Forward, reverse and in place turning is supported. The robot uses standard sized Hitec servos for the legs. The combo kit includes everything you need to make a functional robot. More information about the MH2 can be found here. 69 -)))|(% style="vertical-align:middle" %){{lightbox image="flowbotics-studio-hexapod.jpg"/}}|{{lightbox image="mh2u.jpg"/}} 70 -|(% style="vertical-align:middle" %)((( 71 -**2WD1 Rover** 72 - 73 -The Lynxmotion Aluminum 2WD Servo Robot Kit is a robust, modifiable, and expandable chassis for your RC or autonomous robot experimentation. By utilizing plastic wheels with rubber rim, robot has excellent traction. Using our small 6V NiMH battery pack and the BotBoarduino means there is plenty of room for additional sensors and electronics. Add the IR distance sensor to the front of rear of the robot to perform basic obstacle detection. More information about the 2WD Rover can be found here. 74 -)))|(% style="vertical-align:middle" %){{lightbox image="flowbotics-studio-rover.jpg"/}}|{{lightbox image="2wdu.jpg"/}} 75 -|(% style="vertical-align:middle" %)((( 76 -**BRAT Walking Robot** 77 - 78 -BRAT stands for Bipedal Robotic Articulating Transport. The robot is a 6 servo biped walker featuring three degrees of freedom (DOF) per leg. The robot can walk forward or backwards and turn in place left or right with variable speed. It can even do lots of Robo-One style acrobatic moves. Our combo kits include everything needed to make an operational robot. The electronics are mounted as a "backpack". Once you understand the principles, you can modify the legs to include additional degrees of freedom (such as hip rotation) or more complex motion. 79 -Complete details about the BRAT, including assembly instructions, can be found here. 80 -)))|(% style="vertical-align:middle" %){{lightbox image="flowbotics-studio-brat.jpg"/}}|(% style="vertical-align:middle" %){{lightbox image="bratcbu.jpg"/}} 81 - 82 82 = User Guide = 83 - 84 -|(% colspan="2" %)((( 85 -== **Electronics Guides** == 86 -))) 87 -|(% style="width:150px" %)[[image:BBU-01.jpg]]|[[BotBoarduino User Guide>>doc:servo-erector-set-system.ses-electronics.ses-modules.botboarduino.botboarduino-manual.WebHome]] 88 -The BotBoarduino is intended to be used only if you plan to create code in Arduino / if you want the robot to be fully autonomous. The BotBoarduino is compatible with a variety of third party "shields". 89 -|[[image:ssc32.jpg]]|[[SSC-32 User Guide>>doc:servo-erector-set-system.ses-electronics.ses-modules.ssc-32.ssc-32-manual.WebHome]] 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 -|[[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 -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:dfrobot-bluetooth-bee.jpg||alt="SSC-32U.jpg"]]|DFRobot Bluetooth Module User Guide (PDF) 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:RB-Tys-01.jpg]]|((( 96 -Bluetooth Bee (CSRÂ BC417143) 97 - 98 -The Bluetooth Bee is a complete Bluetooth 2.0 module (complete with onboard antenna) whose pinout is compatible with that of an XBEE module. This module is intended to be used with the SSC-32U servo controller for wireless servo control 99 - 100 -* [[attach:servo-erector-set-system.ses-electronics.ses-modules.WebHome@Bluetooth Bee manual.pdf]] 101 -* [[attach:servo-erector-set-system.ses-electronics.ses-modules.WebHome@TEL0026_Datasheet.pdf]] 102 - 103 - 104 -))) 105 -|(% colspan="2" %)((( 106 -== **Assembly Guides** == 107 -))) 108 -|(% style="vertical-align:middle" %)[[image:[email protected]||alt="BBU-01.PNG"]]|((( 109 -**A2WD1 (2WD) Rover** 110 - 111 -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. 112 - 113 -* [[doc:wheeled-tracked.2wd-rover-assembly-v1\.1.WebHome]] 114 -))) 115 -|(% style="vertical-align:middle" %)[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-arms.al5d.WebHome@al5d.jpg||alt="BBU-01.PNG"]]|((( 116 -**AL5D Robotic Arm** 117 - 118 -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. 119 - 120 -* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-arms.arm-base-v-2-1.WebHome]] 121 -* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-arms.al5d-arm-rev-2-1.WebHome]] 122 -))) 123 -|(% style="vertical-align:middle" %)[[image:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-bipeds.brat.WebHome@brat.jpg||alt="BBU-01.PNG"]]|((( 124 -**BRAT Biped Robot** 125 - 126 -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. 127 - 128 -* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-bipeds.brat-biped.WebHome]] 129 -))) 130 -|(% 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"]]|((( 131 -**MH2 Hexapod Robot** 132 - 133 -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. 134 - 135 -* [[doc:ses-v1.ses-v1-robots.ses-v1-2dof-hexapods.simple-2-dof-leg.WebHome]] 136 -* [[doc:ses-v1.ses-v1-robots.ses-v1-2dof-hexapods.mini-inline-hexapod-body.WebHome]] 137 -))) 138 -|(% 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"]]|((( 139 -**SQ3 Quadruped Robot** 140 - 141 -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. 142 - 143 -* [[doc:ses-v1.ses-v1-robots.ses-v1-3-4-dof-hexapods.3-dof-leg-v2.WebHome]] 144 -* [[doc:servo-erector-set-robots-kits.ses-v1-robots.ses-v1-quadrapods.quadrapod-qbk-02.WebHome]] 145 -)))
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