Title: Its a Small Wireless World'
1Its a Small Wireless World.
- Engineering 1202
- TEAM E0108
- Adam Harris
- Patrice Harrington
- Chris Sides
- Joshua Huff
- Kile Blair
- Peter Rached
- Brendan Oldham
2Agenda
- Problem Statement and Constraints
- Research
- Wavelength Calculations
- Antenna Design
- Conductor Comparison/ Decision
- Cost Analysis
- Global, Societal and Contemporary Issues
- The Fabrication Process
- Clean Room Safety and Attire
- Dealing with a Silicon wafer
- Photolithography
- Finished Product
- Proposed Alternative Solutions
- Questions Answers
3Problem Statement
We were required, as a freshman engineering
team, to research and design a planar antenna for
use inside a miniature communications device that
is the size of a modern day watch. The design
made is to fit specific and well defined criteria
such as size range (size ranging from 5mm 5mm
to 20mm 20mm), and unique frequency band
(2400-2497 MHz), which is specific for the
Bluetooth/Wi-Fi model.
4Design Constraints
- Design area must be larger than 5mm x 5mm but
smaller than 20mm x 20mm - Antenna must be set for frequencies
- 824-894 MHz (cellular), 1850-1990 MHz (pcs),
or 2400-2497 MHz (Bluetooth/Wifi) - Cost, Reliability, and Manufacturability should
also be taken into account
5Research
Wireless systems were researched as part of the
Project to further the teams understanding of
the subject matter. The research revealed that
cell phones are nothing more than complex two way
radios sending and receiving on separate
bandwidths Bluetooth and Wi-Fi are on the
unlicensed bandwidth (2400-2497 MHz) and are used
for wireless data communications. Bluetooth
transmits with a 10 m range, while Wi-Fi
transmits within a 100 m range.
6Antenna Type Decision
- We have chosen the Bluetooth
- and Wi-Fi model because
- - It is a newer technology
- - It has a higher frequency
- (higher frequency ? smaller antenna)
- - More money is to be made (hopefully)
- in a more recent technology.
7Calculations
- c speed of light in meters/second.
- W Wavelength in meters.
- P time or period is seconds.
- f frequency in Hertz.
- c W/P, f 1/P ? c Wf ? W c/f
- W c/f (3.0108) / (2448106) .120144 m 12
cm - Since we have decided to use a quarter
wavelength instead of a full wavelength for the
length of the antenna, our design would have the
length of - Length ¼ Wavelength ¼ 12 cm 3.0 cm.
8Design Alternatives
As part of the design process the team had to
decide on not only the antenna shape and size but
also the type of conductor to be used.
The two major designs for the antenna were the
Square Nautilus design and the Octagonal design.
The Square Nautilus design was chosen due to its
simplicity and compact size
9Design Decided
The final design made using AutoCad.
All measurements are in millimeters.
10Conductor Decision Matrix
Copper was our choice for conductor material.
Scale 1 (poor) 10 (excellent)
11Cost Analysis Sheet
12Global, Societal and Contemporary issues
- Maintenance and Security
- Changing the workplace
- Saving money
13FabricationThe Microelectronics Clean Room
Kile getting gowned up for the clean room.
14The Attire
- Shoe covers
- Face mask
- Hood (hair cover)
- Tyvek Coveralls
- Gloves
Josh wearing his coveralls, putting on a facemask.
15The Silicon (Si) Wafer
- Started with an Si wafer
- 4 inches in diameter
- Cleaned the wafer using
H2SO4, H2O2, and HF
Visual of the silicon wafer.
Chris (left) and Adam (right) cleaning the Si
wafer.
16Oxidizing the Silicon
- Silicon is a semiconductor
- SiO2 was formed on the Silicon wafer in
the Oxidation/Diffusion furnace
Si wafer with the layer of SiO2 surrounding
17Applying the conductor
The chosen conductor (Cu) was added using the
Varian vacuum thin film system
Copper applied to silicon dioxide layer.
Adam (left) and Kile (right) operating the Varian
system.
18Photo-litho-WHAT!?
Definition from ECE lab website Photolithography
The transfer of a pattern or image from one
medium (mask) to another (wafer) using light. It
is considered microphotolithography if the images
have features in the micrometer range.
Basically it is the process the team used to put
the design on the antenna.
19PhotolithographySpin coating
- Place wafer in high speed spin processor
- Apply Photoresist to the wafer.
- Spin at 4000 RPM for 1 minute.
- Soft bake on hotplate for 1 minute.
Operating the spin processor.
20PhotolithographyExposure
Place the wafer in the mask printer, cover with
the mask, and expose to UV light for 10
seconds. The photo resist reacts with the UV
light and the exposed portions of Photoresist
become a soluble acid.
WARNING NEVER LOOK INTO UV LIGHT DIRECTLY! The
wafer being exposed to UV light.
21Exposure (contd)
Before being exposed the Photoresist is insoluble.
Once exposed the Photoresist becomes a soluble
acid.
22PhotolithographyDevelopment
- Place the wafer into the spray developer
- Make sure the vacuum on the wafer is good before
starting the process
The soluble gets washed away during development.
23Etching
Photolithography etch is a method of etching away
the conductor unprotected by the Photoresist.
(see below)
Brendan etching a wafer.
24Dicing
The wafer is placed on the MicroAutomation Wafer
dicing saw. The saw has a small diamond blade
that cuts the antennas out. The saw can be
operated manually or can be set to cut
measurements on a wafer.
Kile dicing a wafer, and monitoring the cut on
the screen.
25The Finished Product
Adams Reflection in the diced wafer.
26Proposed Alternative Solutions
- Use professional mask for better dimensions and
quality. - Redesign and test different antenna designs to
achieve optimal performance and capacity. - Use a clean room that allows us to process
better, bigger wafers with lower contamination
and at a faster pace.
27QAThank You For Your Time.Any Questions?
Team E0108 and TA