Phase calibration in prototype VLBI2010 systems

Similar documents
Phase Cal Basics Cable Delay measurement System & A short introduction to RF system testing using Spectrum Analyzer

VGOS Phase / Delay Calibra<on Systems

Results for 2009/049 polarization session 1: First look at amps, phase differences, and delays

RFI: Sources, Identification, Mitigation. Ganesh Rajagopalan & Mamoru Sekido & Brian Corey

MASSACHUSETTS INSTITUTE OF TECHNOLOGY

The WVR at Effelsberg. Thomas Krichbaum

The VLBI2010 Broadband System: First Geodetic Results

Dustin Johnson REU Program Summer 2012 MIT Haystack Observatory. 9 August

UVLBI MEMO #020 MASSACHUSETTS INSTITUTE OF TECHNOLOGY HAYSTACK OBSERVATORY

Keysight Technologies E8257D PSG Microwave Analog Signal Generator. Data Sheet

Reconfigurable 6 GHz Vector Signal Transceiver with I/Q Interface

Receivers for. FFRF Tutorial by Tom Clark, NASA/GSFC & NVI Wettzell, March 19, 2009

Data Sheet SC5317 & SC5318A. 6 GHz to 26.5 GHz RF Downconverter SignalCore, Inc. All Rights Reserved

LNS ultra low phase noise Synthesizer 8 MHz to 18 GHz

SC5407A/SC5408A 100 khz to 6 GHz RF Upconverter. Datasheet. Rev SignalCore, Inc.

VLBI2010: In search of Sub-mm Accuracy

MASSACHUSETTS INSTITUTE OF TECHNOLOGY HAYSTACK OBSERVATORY

HP 8901B Modulation Analyzer. HP 11722A Sensor Module. 150 khz MHz. 100 khz MHz. Technical Specifications. Four Instruments In One

Keysight Technologies

Very Long Baseline Interferometry

SC5307A/SC5308A 100 khz to 6 GHz RF Downconverter. Datasheet SignalCore, Inc.

MASSACHUSETTS INSTITUTE OF TECHNOLOGY HAYSTACK OBSERVATORY WESTFORD, MASSACHUSETTS

Model 855 RF / Microwave Signal Generator

(The basics of) VLBI Basics. Pedro Elosegui MIT Haystack Observatory. With big thanks to many of you, here and out there

Specification for Conducted Emission Test

MAKING TRANSIENT ANTENNA MEASUREMENTS

SX Observations using a Broadband Receiver and RDBE: Revised frequencies

Keysight Technologies E8257D PSG Microwave Analog Signal Generator

Model 745 Series. Berkeley Nucleonics Test, Measurement and Nuclear Instrumentation since Model 845-HP Datasheet BNC

Agilent 8901B Modulation Analyzer (150 khz 1300 MHz) and Agilent 11722A Sensor Module (100 khz 2600 MHz) Four Instruments In One

7. Transmitter Radiated Spurious Emissions and Conducted Spurious Emission

X-Band QTRM Product Capability QTRM - Quad Transmit Receive Module (4-Channel T/R Module)

Rev F. Nov 16, /16/2008 Rev F

MASSACHUSETTS INSTITUTE OF TECHNOLOGY HAYSTACK OBSERVATORY WESTFORD, MASSACHUSETTS

Agilent 8902A Measuring Receiver

Trees, vegetation, buildings etc.

The Phased Array Feed Receiver System : Linearity, Cross coupling and Image Rejection

Model 865 RF / Ultra Low Noise Microwave Signal Generator

HP 8901B Modulation Analyzer. HP 11722A Sensor Module. 150 khz MHz. 100 khz MHz. Technical Specifications. Four Instruments In One

Cu 0.37 Brass Cu 0.37 Brass

Agilent E4428C ESG Analog Signal Generator

An Overview of the Japanese GALA-V Wideband VLBI System

RF/IF Terminology and Specs

RF Signal Generators. SG380 Series DC to 2 GHz, 4 GHz and 6 GHz analog signal generators. SG380 Series RF Signal Generators

Contents. CALIBRATION PROCEDURE NI PXIe-5668R 14 GHz and 26.5 GHz Signal Analyzer

Critical Evaluation of the Motorola M12+ GPS Timing Receiver vs. the Master Clock at the United States Naval Observatory, Washington DC.

New Broadband VLBI System for High Precision Delay Measurement

Berkeley Nucleonics Test, Measurement and Nuclear Instrumentation since 1963

Agilent 8360B/8360L Series Synthesized Swept Signal/CW Generators 10 MHz to 110 GHz

On site RF troubleshooting for installation and maintenance

Wire spacing in wavelengths

Utilizzo del Time Domain per misure EMI

Jitter Measurements using Phase Noise Techniques

FISCHER CUSTOM COMMUNICATIONS, INC.

Antenna Measurements using Modulated Signals

ADI 2006 RF Seminar. Chapter II RF/IF Components and Specifications for Receivers

CHAPTER 6 EMI EMC MEASUREMENTS AND STANDARDS FOR TRACKED VEHICLES (MIL APPLICATION)

MASSACHUSETTS INSTITUTE OF TECHNOLOGY HAYSTACK OBSERVATORY WESTFORD, MASSACHUSETTS 01886

Broadband Delay Tutorial

Revisions: Initial jee Minor editorial changes jee Minor editorial changes suggested by J. Webber

SIGNAL GENERATORS. MG3633A 10 khz to 2700 MHz SYNTHESIZED SIGNAL GENERATOR GPIB

Agilent 8657A/8657B Signal Generators

Agilent 8560 EC Series Spectrum Analyzers Data Sheet

ULTRA BROADBAND RF over FIBER Transceiver OZ1606 Series Premium Grade 6 GHz

EVLA Front-End CDR. EVLA Ka-Band (26-40 GHz) Receiver

Agilent 83711B and 83712B Synthesized CW Generators

SC5306B 1 MHz to 3.9 GHz RF Downconverter Core Module. Datasheet SignalCore, Inc.

Chambers Accessories Equipment 1 Equipment 2 Amplifiers Antennas Emission

Accurate Phase Noise Measurements Made Cost Effective

MASSACHUSETTS INSTITUTE OF TECHNOLOGY HAYSTACK OBSERVATORY WESTFORD, MASSACHUSETTS

Cost-Effective Traceability for Oscilloscope Calibration. Author: Peter B. Crisp Head of Metrology Fluke Precision Instruments, Norwich, UK

GAO-SAU-105 Spectrum Analyzer with Wide Frequency Range

Debugging EMI Using a Digital Oscilloscope. Dave Rishavy Product Manager - Oscilloscopes

R&S FSWP Phase Noise Analyzer Specifications

PXIe Contents SPECIFICATIONS. 14 GHz and 26.5 GHz Vector Signal Analyzer

Signal Forge 2500M Frequency Expansion Module. 1.5 GHz to 2.6 GHz. User Manual

Using Frequency Diversity to Improve Measurement Speed Roger Dygert MI Technologies, 1125 Satellite Blvd., Suite 100 Suwanee, GA 30024

RF-LAMBDA LEADER OF RF BROADBAND SOLUTIONS

Keywords: GPS, receiver, GPS receiver, MAX2769, 2769, 1575MHz, Integrated GPS Receiver, Global Positioning System

DCNTS Phase Noise Analyzer 2 MHz to 1.8 / 26 / 50 / 140 GHz

FIBER OPTIC ANTENNA LINK OFW-5800/GPS. Compatible with a Wide Range of GPS Receivers Architectures. Logistically Supported with COTS Hardware

Beam Diagnostics, Low Level RF and Feedback for Room Temperature FELs. Josef Frisch Pohang, March 14, 2011

Increasing Automotive Safety with 77/79 GHz Radar Solutions for ADAS Applications

Agilent 8560 E-Series Spectrum Analyzers

Advanced Test Equipment Rentals ATEC (2832)

Femtosecond Synchronization of Laser Systems for the LCLS

MWA REVB LNA Measurements

VGOS MEMO #042 MASSACHUSETTS INSTITUTE OF TECHNOLOGY HAYSTACK OBSERVATORY WESTFORD, MASSACHUSETTS August 22, 2016

EDGES Group Alan E.E. Rogers and Judd D. Bowman Deployment of EDGES at Mileura Station, Western Australia

TETRA Tx Test Solution

Telecommunication Electronics

R-1550A TEMPEST WIDE RANGE RECEIVER. R-1550A TEMPEST Wide Range Receiver

Potential interference from spaceborne active sensors into radionavigation-satellite service receivers in the MHz band

Figure 1 Photo of an Upgraded Low Band Receiver

A Low Frequency Array Designed to Search for the 327 MHz line of Deuterium

Pulsed VNA Measurements:

American Microwave Corporation is a Solid State Switches Detector Log Video Amplifiers Solid State Variable Attenuators

Performance of the Prototype NLC RF Phase and Timing Distribution System *

Performance results based on the block diagram of figure 1 are as follows: Luff frequency range. Up conversion I.F. range

Receiver Architecture

Transcription:

Phase calibration in prototype VLBI2010 systems Brian Corey (MIT Haystack Observatory) With thanks for contributions by: Alan Rogers, Roger Cappallo, Mike Titus, Chris Beaudoin, Jason SooHoo (Haystack) Irv Diegel (HTSI) Katie Pazamickas (ITT Exelis) and everyone else in the NASA-supported Broadband Development group

Primary function: Measure instrumental variations over time. Digital back-ends have not made phase cal obsolete! Phase cal needed in VLBI2010 to measure LO phase drifts between bands Phase/delay drifts in RF/IF analog electronics and cables/fibers Increase pulse repetition rate from 1 to 5 or 10 MHz Reduces likelihood of saturation in broadband system Tones still strong enough to meet phase precision spec Broadband pcal generator deployed in NASA VLBI2010 test-bed receivers at GGAO and Westford Options for pcal injection point Phase calibration in VLBI2010 feed LNA 2012 October 22 International VLBI Technology Workshop 2

Specs on VLBI2010 phase cal performance Multiple (at least 5) pcal tones within each baseband channel (~32 MHz BW) Pcal phase 1-σ measurement precision <~ 1 in 1 second for each tone Peak pulse power / P1dB < -10 db Pulse temporal stability < 0.3 ps variations that depend on antenna orientation Allan std dev < 10-15 @ 50 minutes On other time scales, ASD scales with typical maser performance. Upper limits on time-varying spurious signals For spurs that do not vary with antenna orientation Sufficient condition: spurs < -40 db relative to pcal Necessary condition: delay error < 3 ps over 1 GHz and < 1 ps over 3 GHz For spurs that vary with antenna orientation Sufficient: spurs < -50 db relative to pcal Necessary: phase error < 0.004 radian & delay error < 0.3 ps over 3 GHz 2012 October 22 International VLBI Technology Workshop 3

Haystack digital phase calibrator High-speed logic devices can replace tunnel diodes in older pulse gen designs. Digital phase calibrator designed by Alan Rogers (Haystack) 5 or 10 MHz sinewave input; output pulse train at same frequency Output spectrum flatter than in tunnel diode design Pulse delay temperature sensitivity < 1 ps/ C with no external temp. control No support for cable measurement system Circuit diagram and details available at http://www.haystack.mit.edu/geo/vlbi_td/bbdev/023.pdf 5 or 10 MHz sinewave clipper comparator logic gate differentiator switch pulse gating signal 5 or 10 MHz pulse train 2012 October 22 International VLBI Technology Workshop 4

Digital phase calibrator output power spectrum 2012 October 22 International VLBI Technology Workshop 5

Broadband phase/noise calibration unit Cal box developed by Honeywell Technical Solutions Inc (HTSI) and Haystack Observatory for broadband front-ends Cal box includes digital phase calibrator noise source 0-31.5 db programmable attenuators on phase and noise outputs noise and phase cal gating RF-tight enclosure Peltier temperature controller (ΔT < 0.2 C for 20 C change in ambient T) monitoring of temperature, 5 MHz input level, attenuation, gating Two identical RF outputs with combined pcal+noise Equalizers for phase or noise cal signals can be added if necessary. 2012 October 22 International VLBI Technology Workshop 6

Broadband phase/noise cal box: RF connections 2012 October 22 International VLBI Technology Workshop 7

5 MHz Detector Board Phase cal generator, microwave switch, & 5 MHz detector Noise Source PCal Microwave Switch PCal Generator Board 2012 October 22 International VLBI Technology Workshop 8

Phase/noise calibrator assembly Signal Conditioning Board Digital Attenuators Phase Cal Generator Assembly 0.141 Dia. Super Flex Cable (Typical) Temperature Sensor Noise Source 2012 October 22 International VLBI Technology Workshop 9

Phase/noise calibrator in RF-tight inner enclosure RF Absorber Material Phase Cal Generator Assembly EMI Filters Signal Conditioning Board Grooves For RF Gasket Temperature Sensor Noise Source 2012 October 22 International VLBI Technology Workshop 10

[A box in [a box in [a box]]] Insulation RF Tight Enclosure RF Gasket 2012 October 22 International VLBI Technology Workshop 11

Complete cal box assembly with thermoelectric unit 5 MHz Input Monitor & Control Connector Phase Cal + Noise Outputs (2) (On Rear Side) Thermo-Electric Unit Fan 2012 October 22 International VLBI Technology Workshop 12

Applying pcal phases to visibility phases in VLBI2010 Traditional Haystack/WACO/Bonn processing uses 1 tone per channel. Throws away information (e.g., channel instrumental delay) and SNR Susceptible to severe phase corruption by a spurious signal Channel-dependent baseband tone frequencies when channel separation (e.g., 2 N MHz) is not integer multiple of pulse rep rate (e.g., 5 or 10 MHz) Multitone phase cal mode in HOPS fourfit Uses all, or a user-defined subset of, pcal tones in each channel Finds best-fit delay in each channel for each station Corrects channel visibility phase with pcal phase calculated at center freq Multitone usage options Adjustable time segmentation interval (1-9999 accumulation periods) User-specified fixed additive phase corrections by channel Pcal tone exclusion (e.g., to avoid known spurious signals) 2012 October 22 International VLBI Technology Workshop 13

Look for classic amplitude-vs.-phase sinusoids in each tone Compare amplitudes and phases in adjacent tones Fit linear phase-vs.-frequency model to phases for all tones in a band and look at variability of residual phase in each tone over time. Finding spurious signals 2012 October 22 International VLBI Technology Workshop 14

Westford intra-scan rms tone phase (deg) during May 16 session x H pol o V pol 1-second integrations 2012 October 22 International VLBI Technology Workshop 15

Westford intra-scan rms tone phase (deg) no Nx10 MHz tones x H pol o V pol 1-second integrations 2012 October 22 International VLBI Technology Workshop 16

H-pol phase cal delays (ns) during May 16 session Westford GGAO 2012 October 22 International VLBI Technology Workshop 17

Correcting GGAO pcal phase (turns) for delay to isolate LO phase - Φ pcal = τ RF ω RF + τ IF ω IF + Φ LO Before correction After correction 2012 October 22 International VLBI Technology Workshop 18

GGAO pcal-inferred LO phase variations and pcal delays (V pol) 22 21 up/down converter temperature temperature (degc) 20 19 18 17 16 15 10:00 11:00 12:00 13:00 14:00 15:00 2012 October 22 International VLBI Technology Workshop 19

GGAO 12m pcal delay vs. az/el during May 16 geodetic session 2012 October 22 International VLBI Technology Workshop 20

GGAO 12m phase cal delay during 4 azimuth scans (band C) 2012 October 22 International VLBI Technology Workshop 21

GGAO 12m phase cal delay vs. azimuth 2012 October 22 International VLBI Technology Workshop 22

GGAO 12m phase cal delay vs. elevation (band D) 2012 October 22 International VLBI Technology Workshop 23

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback