Senior Capstone Project:Fast Tuning Synthesizer

Member: Nathan RothAdvisors: Dr. Huggins

Dr. ShastryMr. James Jensen

Date: December 9, 2003

Presentation Outline

• Project Summary

• Standards and Patents

• Functional Description

• Detailed Description

• Preliminary Laboratory Work/Results

• Preliminary Bill of Materials

• Preliminary Spring Semester Schedule

Project Summary

• Creation of a frequency synthesizer– Use of direct synthesis approach

• Design of synthesizer using indirect synthesis– Use of phase-locked loops

Project Summary

• Desired Characteristics– Output Frequency Range of 3.4 GHz to 4.6

GHz – Step Size of 50 MHz– Output Power of 0 dBm, ± 3 dB– Output Spurs < -45 dBc– Tuning Time < 500 ns, 200 ns if possible– Use of an External 100 MHz Reference Signal

Project Summary

• Actual Characteristics– Output Frequencies of 3650, 3700, 3850,

3900, 4450, 4500, 4650, and 4700 MHz– Output Power of 0 dBm, ± 3 dB– Output Spurs < -45 dBc– Tuning Time < 500 ns, 200 ns if possible– Use of an External 100 MHz Reference Signal

Standards

• Standards– Depends Upon Application– C, X, and KU Band Channels:

• MIL-STD-188-164

– Military Satellite Communications (MILSATCOM):

• MIL-STD-188-166: Interface Standard • MIL-STD-188-167: Message Format • MIL-STD-188-168: Interface for Satellite

Multiplexers and Demultiplexers

Patents

• Patent Number 5,166,629

• Grant Watkins and John Muhlbair of Westinghouse Electric Corporation on November 24, 1992

Functional Description

FastTuning

FrequencySynthesizer

3.6 – 4.6 GHz

100 MHz Reference

D2

D1

D0

Digital Input Command

Desired Output

Frequency

Detailed Description

Input Module

Resolution Modules

Basis Frequency Modules

Switch Selection Module

Output Module

Preliminary Laboratory Work

• Design and Simulation of Ideal Chebyshev Filters

• Currently Adding Parasitic Effects– Real Component Values– Real Inductor Responses– Microstrip Transmission Effects– Via Connections

Preliminary Laboratory Work

• Filter Design– Insertion Loss Method

Preliminary Laboratory Work

• Filter Design

Preliminary Laboratory Work

Preliminary Laboratory Work

Ideal S11 = Dark Blue

Ideal S21 = Aqua Blue

Actual S11 = Red

Actual S21 = Purple

Preliminary Laboratory Work

Preliminary Laboratory Work

Preliminary Bill of MaterialsPart Number Maker Description Qty Price Total

Price

HMC435MS8G Hittite SPDT, Hi Isolation, DC- 4 GHz

15 1.1 16.5

PE3512 Peregrine Divide By 4, DC - 1.5 2 2.75 5.5

MAX2671 Maxim IC 400 MHz To 2.5 GHz Upconverter Mixers

3 0.76 2.28

SYK-2R Mini-Circuits Frequency Doublers, 10-1000 MHz

1 29.95 29.95

HMC188MS8 Hittite Passive Frequency Doubler, 1.25 - 3.0 GHz

Input

1 2.94 2.94

HMC187MS8 Hittite Passive Frequency Doubler, 0.85 - 2.0 GHz

1 2.35 2.35

Preliminary Bill of MaterialsMSA-2743 Agilent Cascadable Silicon Bipolar

Gain Block MMIC Amplifier

1 0.94 0.94

ABA-53563 Agilent 3.5 GHz Broadband Silicon RFIC Amplifier

3 0.4 1.2

HMC315 Hittite GaAs InGaP HBT MMIC Darlington Amplifier,

DC - 7.0 GHz

3 0.97 2.91

AG604-89 WJ Ingap HBT Gain Block 2 1.48 2.96

TK10-KIT-ND Toko 250 Pcs - 10 Ea Of 25 Values

1 40.5 40.5

Substrate Rogers Corporation

RO4003, .020 Mil Thick, 1.4 Mil Foil

 2  32.25 64.5

        Total 172.53

Preliminary Spring Semester Schedule

Week TaskWinter Break Research and understand phase locked loop

(PLL) theory and circuitry

Begin design of PLL system

Finalize filter design and simulations

Begin implementing as parts arrive

Full scale simulation of direct synthesis (DS) system

Jan 19 – 25 Design of PLL system

DS system simulation

Jan 26 – Feb 1 Design PLL system

DS system simulation

Have all filters tested and built

Feb 2 – 8 Complete design of PLL system

DS system simulation

Feb 9 – 15 Simulation of PLL system

Complete DS system Simulation

Preliminary Spring Semester Schedule

Feb 9 – 15 Simulation of PLL system

Complete DS system Simulation

Feb 16 – 22 Simulation of PLL system

Feb 23 – 29 Complete simulation of PLL system

March 1 – 7 Components Arrive, Begin Soldering, Testing, and Biasing Components

March 8 – 14 Physical implementation of DS

March 15 – 21 Physical implementation of DS, Spring Break?

March 22 – 28 Begin DS full scale testing

March 29 – April 4 DS full scale testing

April 5 – 11 Complete DS full scale testing

April 12 – 18  

April 19 – 25 Student Expo

April 26 – May 2 Present successful findings

Fast Tuning Synthesizer

• Any questions?