Presentation is loading. Please wait.

Presentation is loading. Please wait.

Digital Microfluidics Control System II P15610. Previous state - The previous control system is not self contained and uses a class AB amplifier which.

Published byEzra Short Modified over 8 years ago

Similar presentations

Presentation on theme: "Digital Microfluidics Control System II P15610. Previous state - The previous control system is not self contained and uses a class AB amplifier which."— Presentation transcript:

1 Digital Microfluidics Control System II P15610

2 Previous state - The previous control system is not self contained and uses a class AB amplifier which makes the system large and nonmodular. Desired state - A fully enclosed control system that efficiently operates the DMF chip while providing accurate feedback. Project Goals - Make key improvements to functionality of control system, and complete all assigned deliverables. ● Repeatable, consistent droplet motion. ● Durable, lightweight, modular design. Constraints - Use provided DMF chip, control fluid droplets using electrowetting, use DI water as test fluid, ensure compatibility with peripheral hardware and GUI. Phase One: Problem Definition Problem Statement

3 Phase One: Problem Definition Engineering Requirements

4 Phase One: Problem Definition DropBot

5 Phase One: Problem Definition Functional Decomposition

6 Phase Two: Subsystem Identification System Layout

7 Phase One: Problem Definition Morphological Chart

8 Phase Two: Subsystem Identification Original CAD Models

9 Phase Two: Subsystem Identification Original External Design Components: 3 Enclosures and Lid 1 Fan and Fan Guard Electrical Ports: USB, BNC, 40 pin connector, Power Vent Grommets

10 Phase Three: Design and Testing Output Board: PCB layout

11 Phase Three: Design and Testing Output Board: PCB layout

12 ● Takes amplified signal from amplifier chooses which pin on DMF chip to apply high voltage ● Consists of: o HV Solid State Relays o Shift Registers (Load pin positions to apply voltage to) o Control Mechanism (ATMEGA) Phase Three: Design and Testing Output Board: Functionality

13 Phase Three: Design and Testing Output Board: Functionality ATMEGA Shift Register Off Board 40 HV Relays DMF Chip

14 Phase Three: Design and Testing Input Board: Functionality

15 Phase Three: Design and Testing Input Board: Functionality 1pF: steady state voltage of 29mV 200pF: steady state voltage of 5.00V Rise time: <10ms

16 Phase Three: Design and Testing Input Board: Functionality 60pF: steady state voltage of 1.693V 61pF: steady state voltage of 1.720V Granularity: 27mV/pF or: 5.5 q- level/pF

17 -Total simulated current draw: <25mA -Noise: input filter to buffer limits frequency generator noise -Large capacitive loading: Zener diode limits output (below) -Output noise: two-stage low-pass filter Phase Three: Design and Testing Input Board: Functionality

18 -Absolute values of measured capacitances ranged from 30pF to 170pF -Capacitance changes over time in the minutes -Capacitance differences sub-1pF Phase Three: Design and Testing Input Board: Previous Data Graphs from Dr. Michael Schertzer “Automated detection of particle concentration and chemical reactions in EWOD devices”

19 Phase Three: Design and Testing Input Board: PCB Layout

20 -Input Board was tested using the designed circuit and outputted the following waveform before full- wave rectification -This demonstrates that the signal is voltage-varying and can demonstrate changes in magnitude -Phase detection remains untested, however the preliminary circuit was promising Phase Three: Design and Testing Input Board: Experimental Output

21 Phase Three: Design and Testing Signal Generator: PCB Layout

22 Phase Three: Design and Testing Signal Generator: PCB Layout

23 - (+)9 V p-p from signal generator amplified to 120 V p-p between ~100 - 100kHz Phase Three: Design and Testing Amplifier Functionality

24 - Simulated with a 600uH Resonant Converter Transformer Phase Three: Design and Testing Amplifier Functionality

25 - Breadboarded setup of amplifier design Phase Three: Design and Testing Amplifier: Preliminary Design

26 -Output waveforms at 10kHz and 100kHz respectively Phase Three: Design and Testing Amplifier: Preliminary Results

27 Phase Three: Design and Testing Amplifier: PCB Layout

28 Phase Three: Design and Testing Fault Detector: PCB Layout

29 Phase Three: Design and Testing Indicator: PCB Layout

30 -Cosel +/- 15 V DC @ 1.7A -Cosel +5 V DC @ 2A Phase Three: Design and Testing Power Supplies

31 Phase Three: Integration

32 Machining of Enclosures

33 Phase Four: Final Design

34

35

36

37 Performance vs. Requirements

38 Housing ● 10 pin ribbon cable connector ● Protective paint coating Input Board ● Purchase DropBot input board or modify existing software to work with current board Amplifier ● Modify design to use BNC connector instead of SMA Power Supply ● Switch to using power supply from P15611 Opportunities for Future Work

Download ppt "Digital Microfluidics Control System II P15610. Previous state - The previous control system is not self contained and uses a class AB amplifier which."

Similar presentations

Controller Tests Stephen Kaye 2013-5-08. Controller Test Motivation Testing the controller before the next generation helps to shake out any remaining.

Controller Tests Stephen Kaye Controller Test Motivation Testing the controller before the next generation helps to shake out any remaining.
USB Controlled IO Module Jon Knoll Dave Wolowicz Sponsored by: Dr. Kin Li A 499a Project.

USB Controlled IO Module Jon Knoll Dave Wolowicz Sponsored by: Dr. Kin Li A 499a Project.
Agenda Review Problem Statement Customer Requirements

Agenda Review Problem Statement Customer Requirements
1 Series Resonant Converter with Series-Parallel Transformers for High Input Voltage Applications C-H Chien 1,B-R Lin 2,and Y-H Wang 1 1 Institute of Microelectronics,

1 Series Resonant Converter with Series-Parallel Transformers for High Input Voltage Applications C-H Chien 1,B-R Lin 2,and Y-H Wang 1 1 Institute of Microelectronics,
CHAPTER 3: SPECIAL PURPOSE OP-AMP CIRCUITS

CHAPTER 3: SPECIAL PURPOSE OP-AMP CIRCUITS
Analog Electronics Workshop (AEW) Apr 3, 2013 1. Contents Intro to Tools Input Offset Input and Output Limits Bandwidth Slew Rate Noise EMIRR Filtering.

Analog Electronics Workshop (AEW) Apr 3, Contents Intro to Tools Input Offset Input and Output Limits Bandwidth Slew Rate Noise EMIRR Filtering.
Experiment 17 A Differentiator Circuit

Experiment 17 A Differentiator Circuit
Chapter 10 Analog Integrated Circuits The 741 OP-AMP Introduction.

Chapter 10 Analog Integrated Circuits The 741 OP-AMP Introduction.
COMMUNICATION SYSTEM EEEB453 Chapter 3 (III) ANGLE MODULATION

COMMUNICATION SYSTEM EEEB453 Chapter 3 (III) ANGLE MODULATION
Oscillators with LC Feedback Circuits

Oscillators with LC Feedback Circuits
1 DIFFERENTIAL POLARIZATION DELAY LINE Controller FINAL REPORT D0215 Supervisor : Mony Orbach Performed by: Maria Terushkin Guy Ovadia Technion – Israel.

1 DIFFERENTIAL POLARIZATION DELAY LINE Controller FINAL REPORT D0215 Supervisor : Mony Orbach Performed by: Maria Terushkin Guy Ovadia Technion – Israel.
Project Improvement Ideas Brian Drost Bangda Yang.

Project Improvement Ideas Brian Drost Bangda Yang.
Design of a Control Workstation for Controller Algorithm Testing Aaron Mahaffey Dave Tastsides Dr. Dempsey.

Design of a Control Workstation for Controller Algorithm Testing Aaron Mahaffey Dave Tastsides Dr. Dempsey.
OSCILLATORS.

OSCILLATORS.
POWER SUPPILES LECTURE 20.

POWER SUPPILES LECTURE 20.
 Distortion – the alteration of the original shape of a waveform.  Function of distortion analyzer: measuring the extent of distortion (the o/p differs.

 Distortion – the alteration of the original shape of a waveform.  Function of distortion analyzer: measuring the extent of distortion (the o/p differs.
Content Op-amp Application Introduction Inverting Amplifier

Content Op-amp Application Introduction Inverting Amplifier
Digital Microfluidics Control System II P15610 Complete Detailed Design.

Digital Microfluidics Control System II P15610 Complete Detailed Design.
Control System (2 min) HOQ - highlighting specs and metrics Potential Concepts Feasibility.

Control System (2 min) HOQ - highlighting specs and metrics Potential Concepts Feasibility.
Microwave Amplifier Design Blog by Ben (Uram) Han and Nemuel Magno Group 14 ENEL 434 – Electronics 2 Assignment 2012 1.

Microwave Amplifier Design Blog by Ben (Uram) Han and Nemuel Magno Group 14 ENEL 434 – Electronics 2 Assignment

Similar presentations

Ads by Google