Team Watts in the Box Presents…

TeslaBoxStephen BennettDevin Callahan

Ben KaslonSushia Rahimizadeh

Connor Shapiro

Sushia Rahimizadeh

Overview Project Proposal and Purpose Hardware Design and Implementation

o Level 1 and 2 Block Diagrams Software Design and Implementation

o Use Case, System Context Diagram Division of Labor for Major Tasks Feasibility and Risks Economic Viability, Environmental Aspects,

Sustainability, Manufacturability, Safety, & Impact Schedule for the First Semester of Work Budget

Sushia Rahimizadeh

Proposal This project will consist of a scalable box or

drawer in which small hand-held devices or toys can be placed and wirelessly charged.

The box will require only an external source of power in order to be able to charge the devices.

The devices will perform all RF harvesting and charging automatically without user input.

The user simply opens the lid, places the devices inside, and shuts the lid. The devices do the rest.

Sushia Rahimizadeh

Purpose The purpose of this project is to demonstrate the

feasibility of scalable, commercially viable wireless charging.

It will be shown that any device is capable of being integrated with this technology and can be charged wirelessly in any station.o These stations can be placed in any household,

business, hotel room, etc. and can be of varying size.

Sushia Rahimizadeh

State of the Arto Heinrich Hertz – Directional, relatively high power free-

space power transmissiono Nikola Tesla – High power, omnidirectional power

transmissiono Jet Propulsion Laboratory and Raytheon (1973) -- 30 kW

transferred over 1.6 kmo Topic of “Wireless Power” has been of interest since

early 1900’s

Number of books that include the keyword “wireless power” since 1800, found by using Google Ngrams.

Sushia Rahimizadeh

Setup

Sushia Rahimizadeh

Background “Power Transmission”

o DC electrical power into RF powero RF power transmitted through space to some electrically

far pointo Power is collected and converted into DC power at this

point Multi-mode cavity

No field nulls

Field uniformity desired

Harvest power at any point within the cavity

Sushia Rahimizadeh

Expo Deliverables Hinged box

o Disables power transmission when openo Enclosed by conductive mesho Can mount all Tx antennas and display

RF Energy Transfero Uses antennas, not coupled inductorso High overall efficiency

• High conversion efficiency (DC RF, RF DC , DC DC)• Aperture-to-Aperture efficiency

Power Management Circuitso Supports Li-Ion and Ni-MH

Sushia Rahimizadeh

Expo Deliverables Externally-mounted display

o Unique device identificationo Power receivedo Remaining charge time

Hardware Design and

Implementation

Ben Kaslon

Overall System Block Diagram

Ben Kaslon

Overall System Block Diagram

Ben Kaslon

Power Transmit Circuit

Responsibility: o Converts supply power into a 1W 2.2 GHz RF

modulated signal

Ben KaslonVoltage-Controlled Oscillator

Responsibility: o Convert supply power to a 2.2 GHz signal

Design Goals: o This signal will be modulated tens of MHz around

2.2GHz in order to improve power density uniformity in the box.

o During development, input power is supplied from lab bench DC supply, but final design will be supplied from standard wall outlet.

Voltage Controlled Oscillator: Crystek

CVCO55BE

Frequency Allocation

Application Range (kHz) Min MaxVerizon and (at&T) 850 850Unused By Consumer Devices 850 1227.6L2 (Military GPS) 1227.6 1227.6L1 (Commercial GPS) 1575.4 1575.43G/4G 1700 1700Personal Communications Service 1900 1900Advanced Wireless Service 1915 1920Advanced Wireless Service 1995 2000Broadband Personal Communication 1850 1915Broadband Personal Communication 1930 19953G/4G 2100 2100Unused By Consumer Devices 2100 2400Wifi 2400 2400Bluetooth 2400 2480

2.2GHz was choseno Unallocated in

commercial spaceo No consumer wireless

devices will be harmed by this frequency coupling onto the devices

o Reduced component size

o Large availability of components operate at this frequency

Ben Kaslon

Power Amplifier Responsibility:

o Amplify 2.2GHz signal from the VCO to 1W Design Goal:

o Must be designed to make the transmitter circuit as efficient as possible.

Example Power Amplifier

Ben Kaslon

Transmit Antenna Responsibility:

o Transmits the amplified and modulated 2.2GHz signal Design Goal:

o Match Simulationso Display low loss to circuito Well matched to the operating frequencyo Widest bandwidth possible.

Ben Kaslon

Transmit Antenna Patch antenna will be used.

o Relatively easy to designo Small sizeo Low costo Can be etched directly into PCBo Lots of research available on design

Example Patch Antenna

Ben Kaslon

Ben KaslonPower Transmit Circuit Risks

Efficiency of the designed power amplifier too lowo If we are unable to design a sufficiently efficient

amplifier, a COTS amplifier will have to be usedo Ideally want 90% but will accept 50%

Design of the antenna does not match the simulations.o New simulations will have to be done with

different, more predictable substrates

Non-uniform field distribution in the cavityo Need to try a new modulation scheme

Ben Kaslon

Overall System Block Diagram

Ben Kaslon

Receiver Circuit

Receiving arbitrarily polarized radiation within the cavity

Rectifying received microwave power to DC power

Maintain optimal power transfer throughout

Ben Kaslon

Receive Antenna Responsibility:

o Receive microwave power

Design Goals:o Polarization diversityo Harmonic rejectiono Low reflections at fundamental frequency

Ben Kaslon

Matching Circuit Rectifier input impedance is a function of:

o Frequencyo Powero DC Loado Harmonic terminations

Responsibilities:o Ensuring optimal power transfer between antenna and

rectifier Design Goals:

o Achieve a low reflection coefficiento Low insertion losso A precise, common impedance

Ben Kaslon

Rectifier

Responsibilities:o Rectify microwave power to DC power

Design Goals:o Maximize rectification efficiencyo Low insertion losso High switching speedo Smaller devices (smaller junction capacitance).

Ben Kaslon

Receiver Circuit Risks Sub-Operational Efficiencies

o Increasing power transmitted into cavityo Antenna matching circuit redesign

Interference from deviceo Isolation will have to be introduced

Connor Shapiro

Overall System Block Diagram

Connor ShapiroPower Management Circuit

Design Goals:o Maximize boost converter efficiencyo Minimize microcontroller power consumption

Responsibilities: o Charge

controlling• Ni-MH• Li-Ion

o Battery monitoring• Generation of

UI/display data

Connor Shapiro

Power Management Circuit Risks

Battery over-chargingo Prioritize cell protection

No power to turn on microcontroller – total system failureo Specialized cold-start circuit

Connor Shapiro

Battery Charging

Ni-MH Charge Cycleo Constant-Current

End-of-charge based on following peak V

Li-Ion Charge Cycleo Constant-Current &

Constant-Voltage End-of-charge based

end of current-draw

Connor Shapiro

Overall System Block Diagram

Connor Shapiro

Display Circuit

Antenna receives device status information

Microcontroller routine to translate data to generic display instructions

Connor Shapiro

Example LCD Displays Small compact LCD Display Designed to interface easily

with any MCU Can be used to display any

generic shapes Cycle through displaying data

for each device

Software Design and

Implementation

Stephen BennettSystem Context Diagram

Microcontroller Tasks

Power Manager Rectified power detection Power management

o Control boost converter to produce correct battery charging profile

Monitor voltage and current going to chargeable device

Packetize power data and device ID for transmission to display circuit

Display Manager Decode power data

packets Convert received data

to appropriate display format

Stephen Bennett

Stephen Bennett

Display Responsibilities:

o Transceivers• Sending/receiving data at appropriate frequency• Outputting clean signal to microcontroller

o Microcontroller• Translating data to display instructions

o Display• Outputting data to user

Design Goals:o Display instructions are independent of received data

formato Displayed data is readable and user friendly

Microcontroller and Transceiver

MSP430 familyo Low costo Low powero Integrates well with CC1110o Prior experience

CC1110 Transceivero 315-915 MHzo Easy integration with

MSP430

CC430 familyo MSP430 with integrated

CC1110

CC1110 Transceiver

MSP430 EVM

Stephen Bennett

Stephen Bennett

Software Risks Code rewrites due to changes in underlying

hardwareo Careful code design that is as hardware-independent as

possible

Code size exceeds space on microcontrollero Choose a microcontroller with more onboard memoryo Worst case – add external memory

Regressions or bugs created by new codeo Use a version control system (Git) in order to keep an

immutable code history

Administration

Devin Callahan

Division of Labor Sushia Rahimizadeh

o Research in energy harvesting, communications systems, and embedded systems

Ben Kaslono Antenna design with

a background in RF theory (Space Grant)

o Experience with VNA’s, SA’s and RF design software (NIST)

Devin Callahano Analog circuit

design, implementation, and control (LSI)

Stephen Bennetto Software background in embedded wireless

communications platform (Qualcomm)o Power management background (Space Grant)

Connor Shapiroo Power management background (TI & coursework)

Task SushiaStephe

n Ben Connor Devin

Project Management PrimarySeconda

rySeconda

ry   

Construction of Box Secondary

Tertiary Tertiary Tertiary Primary

Design of Tx Antenna Secondary

  Primary    

Modulation of Signal    Seconda

ry  Primary

Design of Power Amplifier

Primary  Seconda

ry   

Design of Rectenna Secondary   Primary    

Design of Power Converter

Tertiary Secondary   Primary Tertiary

Design of Microcontroller Circuit

  Primary  Seconda

rySeconda

ry

Display Circuit  Seconda

ry  Secondary Primary

Software Design Primary Tertiary TertiarySeconda

ryDevice Integration with System

 Seconda

ryTertiary Primary  

Devin Callahan

Feasibility Academic Resources

o Zoya Popovic – Faculty Advisor• Provide guidance in power amplifier and antenna design

o Steve Dunbar – Ph.D. Student• TI Analog/RF applications engineer willing to assist in

component selection and applications

o Sean Korhummel – Ph.D. Student• Provide guidance in converter design

Outside research already exists

Devin Callahan

Feasibility Most required components can be purchased

directly from electronics suppliers, including:o Voltage-controlled oscillatorso Microcontrollerso Power transistorso Converter inductors, diodes & capacitors

Devin Callahan

Economic Viability A household or business can purchase one of the

boxes

Any device outfitted with the charging hardware will be able to be charged in any box

Low cost to produce a unito Most cost found in the containero Relatively small cost for manufacturing of electronics

Devin Callahan

Sustainability Most parts are available commercially

o Voltage controlled oscillatoro Microcontrollero Peripheral parts

Parts that are not available commercially will designedo Need to be designed for efficiency

• Power amplifier• Rectifier• Antennas

o Cheap to produce Low maintenance expectations

o Unexpected component malfunction exempting

Devin Callahan

Manufacturability Main concern of the system is to ensure minimum

leak of RF power in compliance with FCC regulations

It will be easy to see if this project is working or not. Either the battery on the device will be charged or it will not

Component tolerances will not affect the design, apart from negligible detractions from system efficiency

Devin CallahanEnvironmental Considerations

Leaked power is chief concern o The system must abide by FCC regulations by emitting

no stray powero Also relates to overall efficiency

No other environmental concerns

Devin Callahan

Safety This system exhibits zero risk to the environment

or the population so long as all RF energy is kept within the box

A standard 120VAC outlet plug will eventually be used

Devin Callahan

Impact on Society Convenience

RF energy transfer proof-of-concept

Devin Callahan

Schedule

Budget

Component Cost

Power Transmit Circuitry $300

Receive Circuitry $50

Power Management Circuitry

$220

Display Circuitry $225

Software Debugger $100

Box Construction $100

Batteries $160

Miscellaneous $100

Total $1255

Devin Callahan

Devin Callahan

Reach Goals

Additional battery chemistries

More advanced GUI

USB Charging

Thank you!

Questions?