Difference between revisions of "Searching for Stability"
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====3D Design and Printing==== | ====3D Design and Printing==== | ||
| − | When you compare our first design | + | When you compare our first design (below, far left) to our last design (below, far right) of the stabilization platform/gimbal many of the differences are very obvious. However to get from our first design to the final design there were many small steps and changes that each occurred with their own purpose often to solve a specific issue discovered after analyzing the print of the previous prototype. |
| − | + | The first design (below, far left) was simply a starting point. It lacked balance, did not even have a mounting bracket for the phone case and was never printer. It did, however, help us realize that we needed a place to place the vibration dampening pads that would smooth out the video. | |
| − | [[File:Assembly1.png|200px | + | Our second design (below, second to the left), included space for the vibration dampening pads as well as a place to mount the phone, however, with this design, we realized that mounting the phone with such a high center of gravity would be detrimental to the stability of the platform. |
| − | [[File:Balanced1.JPG|200px|alt=Our final prototype that a counterbalance mounted on the back of the paddle.|Our final design]] | + | Our third design (below, second to the right), was actually the first model that we actually printed. It did not take us long to realize that we still needed to think through clearances more due to the fact that when we rotated both the paddle and the phone at the same time the phone ran into one of the upright supports. Since this was the first model that we physically printed, it was the first time we were able to assemble the entire prototype, including the motors and the phone. Upon doing this, we learned that both the paddle and the phone mount were unbalanced and thus the motors could not produce enough torque to rotate them. |
| + | The process of balancing the paddle and the phone mount took place before printing our fourth and final prototype (below, far right) and is described in more depth below. The final prototype (below, far right), utilized the bike mounting device and the vibration dampening base developed with the third design and once some final balancing was done on the paddle, worked great. Both the paddle and the phone could turn freely within the uprights and we had even added a housing for the encoder that would provide feedback on the rotated position of the paddle. | ||
| + | [[File:Assembly1.png|200px|alt=Our very first prototype that even lacks a physical mount for the phone.|Our very first design]] | ||
| + | [[File:Design2_2.jpg|200px|alt=Our second prototype with phone mount, as well as battery storage space in the back along with the arduino.|Our second design]] | ||
| + | [[File:Design3.jpg|200px|alt=Our third prototype that displays a significant change in design that approaches the look of our final design.|Our third design]] | ||
| + | [[File:Balanced1.JPG|200px|alt=Our final prototype that includes a counterbalance mounted on the back of the paddle.|Our final design]] | ||
How-To Detect and Eliminate Internal Edges in 3D Files Before Printing | How-To Detect and Eliminate Internal Edges in 3D Files Before Printing | ||
Revision as of 05:37, 2 May 2016
Contents
Proposal
Project Description
Overview
Our project is to create a bike-mounted stabilizing platform for iPhone cinematography. We will use the readings from two magnetic encoders to control two motors responsible for stabilizing the platform. Vibration dampening pads in the mounting device itself will provide additional stability. If successful, applications of an inexpensive, compact stabilizing device could be innumerable, from handheld usage to RC and aerial filming and photography.
The mounting device of the gimbal is an original design drafted in SketchUp and produced in AutoCAD.
By the end of the semester we will be able to present iPhone footage from our device to illustrate its stabilizing capabilities.
Team Members
- Natalie Ng
- Nathan Schmetter
- Deko Ricketts (TA)
Objectives
- Program an Arduino module to receive data from magnetic rotary encoders to consistently level the iPhone while in use
- Design and construct a practical and functional mounting device for an iPhone on a bike
- Design and embed the gimbal and additional stability elements either onto or within the mounting platform itself
- Successfully stabilize the iPhone while recording a video from a moving bike
Challenges
- Perfecting the programming of the Arduino module in order to analyze the input from the two magnetic rotary encoders and communicate with the two brushless motors to re-level the iPhone
- Ensuring that input from the encoders is readable to the Arduino
- Identifying appropriate motors to carry out the stabilization of the platform
- Designing the mounting device and modifying gimbal design using 3D printer
- Finding the most effective dampening cushions considering size and weight of platform
- Compacting all elements of the design to create an unobtrusive stabilizing device
Budget
Arduino
- Parts Ordered Online
- Hardware
- 4 9V batteries ($21.99)
- 4 Screws to secure dampening pads
- 3 9V Battery Snap Connectors
- Wire
Total: $90.99
Gantt Chart
Design & Solutions
Modules
Motor Circuit
Check the functionality of both MOSFET Transistors and Diodes
3D Design and Printing
When you compare our first design (below, far left) to our last design (below, far right) of the stabilization platform/gimbal many of the differences are very obvious. However to get from our first design to the final design there were many small steps and changes that each occurred with their own purpose often to solve a specific issue discovered after analyzing the print of the previous prototype.
The first design (below, far left) was simply a starting point. It lacked balance, did not even have a mounting bracket for the phone case and was never printer. It did, however, help us realize that we needed a place to place the vibration dampening pads that would smooth out the video.
Our second design (below, second to the left), included space for the vibration dampening pads as well as a place to mount the phone, however, with this design, we realized that mounting the phone with such a high center of gravity would be detrimental to the stability of the platform.
Our third design (below, second to the right), was actually the first model that we actually printed. It did not take us long to realize that we still needed to think through clearances more due to the fact that when we rotated both the paddle and the phone at the same time the phone ran into one of the upright supports. Since this was the first model that we physically printed, it was the first time we were able to assemble the entire prototype, including the motors and the phone. Upon doing this, we learned that both the paddle and the phone mount were unbalanced and thus the motors could not produce enough torque to rotate them.
The process of balancing the paddle and the phone mount took place before printing our fourth and final prototype (below, far right) and is described in more depth below. The final prototype (below, far right), utilized the bike mounting device and the vibration dampening base developed with the third design and once some final balancing was done on the paddle, worked great. Both the paddle and the phone could turn freely within the uprights and we had even added a housing for the encoder that would provide feedback on the rotated position of the paddle.
How-To Detect and Eliminate Internal Edges in 3D Files Before Printing
Coding
Interrupts on Arduino
