Department of Electrical & Systems Engineering Lisa Fleming Rafi Hasib Easwaran Subbaraman Advisors...
-
date post
22-Dec-2015 -
Category
Documents
-
view
217 -
download
2
Transcript of Department of Electrical & Systems Engineering Lisa Fleming Rafi Hasib Easwaran Subbaraman Advisors...
Department of Electrical &Systems Engineering
Lisa FlemingRafi HasibEaswaran
Subbaraman
AdvisorsDr. Jorge SantiagoDr. Dwight Jaggard
Special ThanksPhilip FarnumSid Deliwala
Sansern Somboonsong
Demo Times
Thursday, April 24, 2008
10:30 am – 12 noon
2:00 pm – 3:00 pm
Group 4
INKLESS COLOR BLACKBOARD WITH MEMORYNANOMATERIAL COIL DESIGN
PIXEL HARDWARE
MICROCONTROLLER & COMPUTER
Each display pixel requires its own magnetic field. By passing direct current through loops of magnet wire, one can create an electromagnet to generate such a field only when powered. Using the Law of Biot-Savart, one can determine the field, B, at a particular distance from the loop of wire z, based on its current I, radius r, and number of turns N.
2/322
2
)(2
0
zr
NIrB
Furthermore, by use of a ferrite core within the loops of wire, one can scale the field by a constant factor μrod, based on the length-to-diameter ratio and the rod material’s characteristics.
The values for B, r, z, and I constrain the design to a particular N but allow for freedom to choose wire diameter d. A longer rod allows for a greater μrod but increases the thickness of the board. Determining the right d presents a tradeoff between pixel size and increase in resistance per rod (and thus, power dissipation). All of these factors must be considered in design.
ABSTRACT
The blackboard continues to remain a classroom standard, allowing lecturers to visually communicate information and erase it as necessary for reusability. As society continues through the digital age, the convenience of storing notes electronically has become a more attractive means for preserving information.
Several products have been developed that attempt to integrate these two ideas, often incorporating a mounted projector with a computer to send and receive information. However, the implicit requirement of an overhead projector makes this a very costly alternative to the traditional blackboard. Furthermore, any extra embedded features offered, in an effort to justify cost, detract from the primary purpose of loading and storing written data.
In the chosen approach, a potentially cost-effective alternative is explored, making use of electromagnets within a self-contained device. Based on the superparamagnetic, luminescent properties of an iron oxide based nanomaterial, an array of electromagnetic coils generates magnetic fields that alter the color of the compound.
The hardware supporting each pixel is able to accomplish two main goals: detecting when the stylus has passed over a pixel, and then setting the current through the electromagnet to produce the correct magnetic field. A microcontroller, responsible for activating the coils, also stores the state of the array that can then be exported to an image file or redisplayed on the board.
The proof-of-concept prototype that has been developed allows the user to draw using one of three colors, and erase as well. The size of the screen is three pixels by five pixels so that single digit numbers and most letters can be displayed.
Prototype coil(3.5” length, 0.125” diameter, 31 AWG wire)
SYSTEM OVERVIEW
Process Flowchart
The microcontroller serves as the central processing core for the blackboard, coordinating detection of stylus swipes and the corresponding setting of pixel color, saving the array state to memory, and clearing the board when the user wishes to do so. The microcontroller’s logic for these basic tasks is illustrated in the process flowchart above.
Detection of stylus swipes is interrupt-driven, thus minimizing microprocessor usage while maximizing the response time to user input. Each interrupt updates the affected pixel’s color by polling the color buttons and then outputting two bits to the decoder. These two bits represent what color the pixel should be set to – three colors plus “erase”. The pixel hardware then sets the coil voltage to the appropriate value. Finally the microcontroller updates its color value in the array that stores the color values for all of the pixels in the blackboard. The save feature allows a user to save a copy of the
blackboard’s current state to the microprocessor’s memory. These saved images can then be redisplayed by typing the save position into the computer after specifying that a load is desired.
Initialize all pixel voltages to 0 V
Change in Pixel Current
Save Button Pressed
Get ‘Color’ register value
Set pixel current
Update ‘Color’ Register
Allocate space in memory for
array
Wait for user action
System Startup
Update memory
Initialize memory array for pixel
currents with zeros
Color Button Pressed
Change in Pixel Current
Copy pixel array
HC11 Microcontroller Board
This nanomaterial served as the inspiration behind the project. Given its ability to change color when exposed to magnetic fields, it provides an ideal material to use for a multicolor display with color resolution defined largely by the preciseness of magnetic field biasing points.
The material itself consists of "superparamagnetic colloidal nanocrystal clusters" of iron oxide that form "ordered structures when exposed to external magneticfields"
The diffraction wavelength (color) of the material can be altered by modulating the strength of the applied magnetic field. A broad spectrum (red to violet) can be created by varying the magnetic field strength from 50 gauss (red) to 500 gauss (violet), while the material when not exposed to any magnetic field is brown in color.
(1) All quotes and images taken from:Ge et al. “Self-Assembly and Field-Responsive Optical Diffractions
of Superparamagnetic Colloids”, American Chemical Society, 02/13/2008
Illustration of the structure of iron oxide colloids that have self assembled when exposed to a magnetic field (1)
Images of the nanomaterial when exposed increasing magnetic fields
Optical microscope images showing the assembly of
CNC’s in a film between two glass slides. The field strength
increases from (a to b) (1)
The hardware, which is identical for each pixel, was designed to simultaneously detect when the stylus passes over its respective pixel as well as tokeep the pixel’s electromagnet generating the field needed to maintain color on the board.
When the stylus passes over the electromagnet, the induced current in the coil creates a voltage spike at the top of the coil with an amplitude of approximately 30 mV. This node is the input to a differentiator, which produces a voltage outputproportional to the change of the input voltage. This voltage spike is amplified to register as a “high” input signal to the microcontroller, as shown in the image on the right.
Once the pixel is detected as active, the coil’s color is set. The two bits that the microcontroller outputs are the control bits for a decoder. The decoder ensures that out of the four outputs present (one for each color state), only one is active at a time.
Stylus
Electromagnet Coil Array Microcontroller
Image Formatter
NanomaterialDisplay
Save & Color Buttons
Computer Display
ComputerInterface
Decoder
Differentiator
Pixel Hardware
Switch
To obtain different voltages for the different colors, a voltage divider is used. Each voltage is connected an analog switch, all of whose ends are shorted together. The control logic for the switches is the decoder output, which ensures that two different voltages will not be shorted together. This voltage is connected to the base node of a transistor, which isolates the biasing voltages from the electromagnet. The resulting current that flows through the electromagnet produces the correct magnetic field.
Image of voltage spike:
differentiator output
Pixel Hardware Circuit Diagram