Mid review presentation

Autonomous Robotic Manipulator
Team ARM - University of Massachusetts Lowell

Philip Colangelo, ZiChang Ruan, Allen Antony

Outline
● The Problem
● The Solution – Our Goal Design
● Current Progress
● Key Features
● Performance Measures
● Timeline/Budget
● Next Steps

Problem
● Our focus
– People who rely on a feeding staff
● In home, school, hospital, etc.
● Need
– Inhibiting situations
● Illness, cognitive challenges, paralysis, gross motor
control, etc.
– “785 million people have a physical and or mental
disability” [1].

Solution
● A feeding device that can be controlled by
someone who cannot feed themselves.
– Robotic Feeding Arm
● Benefits from solution
– Independence for users to feed themselves.
– Improved quality of life
– Frees up staff

Outline
● The Problem
● The Solution – Our Goal Design
● Current Progress – what we have done.
● Key Features
● Performance Measures
● Timeline/Budget
● Next Steps

Current Progress – Robot Arm
● Schematic
– Links
– Joint angles
– Joint positions
– 4 DOF
– |λθθθ|

Initial Robot Arm Schematic

Solid Works Prototype

● Link Lengths
– Ratios:
● L1: 1
● L2: 1/1.618
● L3: 1/3.236
– Desired Length
● With L1 = 13” ARM can reach up to 18.88”

● Motors
– 5 DC Servo Motors
● λ1+θ1: SPG785A and Top Mount (7:1)
● θ2: HS-805BB Mega Power Servo
● θ3: HS-322HD Standard Deluxe Servo
● Bowl: HS-1425CR (Continuous Rotation) Servo

SPG785A Top Mount [2] HS-805BB [3]

Current Progress - Sensors
● Proximity Infrared Sensors
– Obstacle avoidance
– Sharp GP2D120XJ00F
● Range: 3cm to 30cm
Sharp Proximity Sensor [4].
● Analog output

Current Progress - Control
● Microprocessor
– 5 ADC pins for proximity sensors
– 5 16-bit Timer registers for PWM output
● PWM 16 bit resolution
– DIP package
● PIC32MX series
● PIC24FJ series

Microprocessor 40-DIP package [5].

Current Progress – Prototype

Current Progress – Program Flow

Key Features – Safety
● RFID
– Device will only work when in range
– Safety shut off when no tag is read
● Panic Button
– In case of an emergency user can override device
to shut down and call for help.

Key Features – Kinematics
● Inverse Kinematics (IK)
– Location
● Pin point desired location
● Feedback from camera will
update end effector to meet
user
● IK's allows for remapping

Key Features – User Interface
● Push Button
– For users with gross motor skills
– 2 buttons
● Bowl motor
● Food present and return
● Facial Recognition
- Various facial movements to trigger device
- Arm can meet user position

Key Features – User Interface
● Open Source Computer Vision
– Facial recognition [6]

– Head movement

What Sets our Design Apart
● Cost Effective
– Manufacturing could make affordable for in home
use.
● Smart Design
– Small learning curve
– Simple design keeps costs low
● Easy maintenance
● Small footprint
● Grand potential

Performance Measures
Category Measurement Description
User Interaction
Push Buttons for arm control Human interaction The push button interface will be a success if the robot can be
triggered by different types of users.

Head Movement Human interaction The head movement interface will be a success if the robot can
be triggered by sideways head movement of different users.

Facial Features Human interaction The facial features interface will be a success if the robot can
be triggered by facial expressions of different users.

Movement Efficiency
Obstacle Avoidance Path of Motion Observation of arms behavior given an obstacle in test
environment.

Food Spillage Waste Performance of the arms ability to provide a smooth path for
the food to travel, any spillage from spoon will be unsuccessful.

Repeatability Number of Completions 10 successful food deliveries will be a success.

Timeline - Milestones

Milestone Range
Design December – January
Prototype January – February
Debug/Redesign February
Build March
Debug March
Finalize April

Timeline - Detailed

Pick out RFID system Jan 28 Place bulk order

continue developing openCV software Feb. 4
Build prototype ARM Feb. 11 Code IKS, PIR sensors
Debug ARM mechanics and sensors Feb. 18 continue developing openCV software
Research for new ways to improve the design Feb 25 Design Electronic Schematic
Design PCB Mar. 4 Mar. 7th 1hr online info sessions for finalist begins
Optimize/Redesign PCB – Order Mar. 11 Test Open CV software
Solder PCB Mar. 18 Implement Open CV software with ARM
Test ARM Mar. 25 Test with RFID
Build housing unit Apr. 1
Test and Debug ARM Apr. 8
Apr. 15 Apr. 22nd Final Report Due
Continue test and debug Apr. 22 Apr. 25th 1hr online info sessions ends
Finalize Apr. 29
May 1 Flight to Disney World !!!

Budget
● Given $2500 for project development and travel
– Our current design is high-averaging around $1000
for parts.

Next Steps
● Code
– Inverse kinematics
– Computer Vision
● Electronics
– Finalize schematic
– Design PCB for control circuit
● Base
– Design housing (pending on Atom)

References
[1] Report: 15 percent of world population is disabled. [Online]. Available:
http://www.washingtonpost.com/national/report-15-percent-of-world-population-is-
disabled/2011/06/09/AGZcqBNH_story.html
[2] SPG785A Top Mount. [Online] Available:
http://www.servocity.com/html/spg785a_top_mount.html

[3] HS-805BB Giant Scale Servo Motor. [Online] Available:
http://www.robotshop.com/hitec-hs805BB-servo-motor.html
[4] Infrared Proximity Sensor Short Range - Sharp GP2D120XJ00F. [Online]. Available:
https://www.sparkfun.com/products/8959
[5] PIC Microcontroller. [Online]. Available:
http://media.digikey.com/Photos/Microchip%20Tech%20Photos/PIC18LF44K22-
I%5EP.jpg
[6] OpenCV. [Online]. Available: http://opencv.org/wp-
content/themes/opencv/images/logo.png

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