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Team LIT. Scott Butler Kristin Haeusler Michael Hatt Brock Smith. Presentation Outline. Project Proposal Project Block Diagrams Subsystems Schedule Risk and Contingency plan. LED Light Show.
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Team LIT Scott Butler Kristin Haeusler Michael Hatt Brock Smith
Presentation Outline • Project Proposal • Project Block Diagrams • Subsystems • Schedule • Risk and Contingency plan
LED Light Show • Tom Churchill has a 40 ft wall of composite material that he wants to display color light patterns using LEDs. • He has developed 6 inch boards, with 48 LEDs per board. The entire wall will require 80 boards for a total of 3840 LEDs. • He has developed a PIC controller to send information to these boards, but this does run fast enough for the entire wall. • He would like to use an FPGA controller for faster and more flexibility in displaying patterns
Our goals • We plan to design a prototype that will control 4 of the LED boards in a manner that can be easily adapted to more boards. Because the design of the current boards (using shift registers) makes them easily scalable, we can add code for all 3840 LEDs and the extra data will be shifted out and discarded. • These LEDs will display patterns determined by one of three inputs. (Manual, VGA, and Real Time) • There will be an LCD display that will display the current mode • There will a touch pad for user control.
The LED boards • Each board contains 48 LEDs with 6 shift registers. • Subsequent boards are daisy chained together. • In order to change one specific LED, we must shift in entirely new string of data.
LED boards continued… • 5 VDC @ 1A to each board to the shift registers • There are two clock signals. One clock signal shifts the data through the storage registers and the other sends the information to the outputs • There is a serial input which is the data input line.
System Overview • FPGA • Receives all data from external devices • Determines pattern for output LEDs • Sends appropriate data to boards to display the pattern • Displays information on LCD • Acts as a state machine to control each mode
System Overview continued… • Inputs : • VGA • Microphone • Keypad – Allows user to change modes • Outputs : • LCD Display – Displays current mode and options • LED boards – Displays LED color patterns
Block Diagram VGA LCD Display FPGA VGA controller LCD Display Controller Microphone A/D Converter LED Board Controller A/D Controller State Machine LED Boards Touch pad
Manual Mode • Allows user to choose between pre-programmed patterns to be displayed on the wall via buttons and LCD. • User options • Choose a color • Test pattern • Light show • Random color pattern
Real Time Mode • This mode generates patterns based on an analog input (voice) and converts it to digital data that we will assign some interesting colors to based on frequency or amplitude
VGA Mode • We are going to use 3 bit/8 color VGA port. This will display a pattern based on the VGA input. • The lowest bit number used by computer monitors is 8 bits. • The FPGA will determine a pattern based on a VGA input.
Risks • LED boards will not run fast enough • Built in VGA will not work for our needs • Spartan 3 starter kit will not be large enough our needs
Contingency Plans • These foreseen difficulties will have extra time allowed in the schedule. • We will be able to move to a larger FPGA board if needed.