Comparison of Vector Network Analyzer and TDA Systems IConnect Generated S-Parameters



Similar documents
HPM-5 Performance Testing

High Speed Characterization Report

Recommendations for TDR configuration for channel characterization by S-parameters. Pavel Zivny IEEE GCU Singapore, 2011/03 V1.

Twinax Intra Pair Skew Comparison Report Various Lengths and Competitors Tested

ELECTRICAL CHARACTERISATION OF SEMI-RIGID COAXIAL CABLES WITH SMA AND K CONNECTORS. Carmen Diez Rafael García Juan Daniel Gallego.

Agilent De-embedding and Embedding S-Parameter Networks Using a Vector Network Analyzer. Application Note

Agilent Measuring Noninsertable Devices

Category 8 Cable Transmission Measurements Comparative Study between 4-port single wire measurements and 2-port balun measurements

Impedance 50 (75 connectors via adapters)

ECE 435 INTRODUCTION TO THE MICROWAVE NETWORK ANALYZER

Utilizing Time Domain (TDR) Test Methods For Maximizing Microwave Board Performance

A Comparison of Measurement Uncertainty in Vector Network Analyzers and Time Domain Reflectometers. White Paper

Eye Doctor II Advanced Signal Integrity Tools

R3765/67 CG Network Analyzer

Calibration Procedure for Measuring S-Parameters in Balun Applications on 150-Ω High-Speed Cables

spinner Measurement & Calibration equipment for network analyzers

Agilent AN In-Fixture Measurements Using Vector Network Analyzers

Agilent Stripline TRL Calibration Fixtures for 10-Gigabit Interconnect Analysis. White Paper

Experiment 7: Familiarization with the Network Analyzer

Agilent Electronic Calibration (ECal) Modules for Vector Network Analyzers

Tuning a Monopole Antenna Using a Network Analyzer

Designing the NEWCARD Connector Interface to Extend PCI Express Serial Architecture to the PC Card Modular Form Factor

Agilent Test Solutions for Multiport and Balanced Devices

The Design & Test of Broadband Launches up to 50 GHz on Thin & Thick Substrates

S-PARAMETER MEASUREMENTS OF MEMS SWITCHES

AMERICAN NATIONAL STANDARD

Vector Network Analyzer Techniques to Measure WR340 Waveguide Windows

USB 3.0 INTERNAL CONNECTOR AND CABLE SPECIFICATION

Engineering Sciences 151. Electromagnetic Communication Laboratory Assignment 3 Fall Term

Applying Error Correction to Network Analyzer Measurements. Application Note Table of Contents. Page

Successfully negotiating the PCI EXPRESS 2.0 Super Highway Towards Full Compliance

2. The Vector Network Analyzer

Agilent Improved Method for Characterizing and Modeling Gigabit Flex-Circuit Based Interconnects. White Paper

Revision 1.10 April 7, 2015 Method of Implementation (MOI) for 100BASE-TX Ethernet Cable Tests Using Keysight E5071C ENA Option TDR

One Port Network Analyzer

75 Ω Transmission System

Agilent E5063A ENA Series Network Analyzer. 100 khz to 4.5/ 8.5/18 GHz

The Application of Vector Network Analyzers in Balanced Transmission Line Signal Integrity Measurements

Agilent Ultra-Low Impedance Measurements Using 2-Port Measurements. Application Note

Probes and Setup for Measuring Power-Plane Impedances with Vector Network Analyzer

Advanced Calibration Techniques for Vector Network Analyzers

Vector Network Analyzer (VNA) Calibration: The Basics

Techniques for precise cable and antenna measurements in the field

MEASUREMENT OF CRYOGENIC PERFORMANCE OF 4-8 GHz PAMTECH ISOLATORS S/N Juan Daniel Gallego Isaac López Fernández Carmen Diez González

Basic of Load Pull Measurements Active and Passive load pull & Harmonic load pull testbench

Selecting Microwave/RF Cable Assemblies for Reliable Performance Over Time. White Paper

RF Network Analyzer Basics

LOW LOSS CABLE PAG. 1

Application Guide to RF Coaxial Connectors and Cables

DEPARTMENT OF DEFENSE TEST METHOD STANDARD METHOD OF INSERTION LOSS MEASUREMENT

Agilent Time Domain Analysis Using a Network Analyzer

MAURY. VNA Calibration Kits, Microwave Components & Adapters. Calibrate With Confidence IN THIS CATALOG:

Agilent 8720 Family Microwave Vector Network Analyzers

Comprehensive Analysis of Flexible Circuit Materials Performance in Frequency and Time Domains

Agilent 8753ET/8753ES Network Analyzers

When designing. Inductors at UHF: EM Simulation Guides Vector Network Analyzer. measurement. EM SIMULATION. There are times when it is

Shielding Effectiveness Test Method. Harbour s LL, SB, and SS Coaxial Cables. Designs for Improved Shielding Effectiveness

Annex 113A Description of cable clamp and test setup. (informative) 113A.1 Overview

Cable Impedance and Structural Return Loss Measurement Methodologies

Subject: Glenair MIL-PRF Conduit Surface Transfer Impedance Test

Agilent 10 Hints for Making Better Network Analyzer Measurements. Application Note B

Solving Difficult Cable Measurements

Michael Hiebel. Fundamentals of Vector Network Analysis

Keysight Vector Network Analyzer Calibration and Connector Care. Timothy Lee Keysight Technologies Australia Pty Ltd Application Engineer

HEWLETT PACKARD. HP 8510C Network Analyzer 45 MHz to 110 GHz. Unmatched excellence in microwave network analysis

E5092A Configurable Multiport Test Set

Measuring RF Parameters of Networks Bill Leonard NØCU

MEASUREMENT UNCERTAINTY IN VECTOR NETWORK ANALYZER

EM Noise Mitigation in Circuit Boards and Cavities

Current Probes. User Manual

SPARQ Signal Integrity Network Analyzer. High-bandwidth, Multi-port S-parameters

Introduction. Description of Measurement Techniques

Managing Connector and Cable Assembly Performance for USB SuperSpeed

Connector Launch Design Guide

Techniques for Precise Cable and Antenna Measurements in the Field

Spectrum Analyzers And Network Analyzers. The Whats, Whys and Hows...

Agilent PN In-fixture Microstrip Device Measurements Using TRL* Calibration. Product Note

Ultra640 SCSI Measured Data from Cables & Backplanes

Network Analysis. Specifying calibration standards for the HP 8510 network analyzer Product Note A

Measurements in 75 Ω Coaxial Transmission Lines

TRU RoHS Products Test Report

Application Note. PCIEC-85 PCI Express Jumper. High Speed Designs in PCI Express Applications Generation GT/s

Automotive Electronics Council Component Technical Committee

R&S ZVA Vector Network Analyzer High performance up to 110 GHz with up to four test ports

R&S ZVA Vector Network Analyzer High performance up to 67 GHz with up to four test ports

Keysight E5063A ENA Series PCB Analyzer

Agilent 8757D Scalar Network Analyzer 10 MHz to 110 GHz

TETRIS High Impedance Active Probe. Features:

Sensor and Simulation Notes. Note 479. October A Dual-Polarity Impulse Radiating Antenna

Cable Analysis and Fault Detection using the Bode 100

Minimizing crosstalk in a high-speed cable-connector assembly.

1. The Slotted Line. ECE 584 Microwave Engineering Laboratory Experiments. Introduction:

Keysight Technologies Understanding the Fundamental Principles of Vector Network Analysis. Application Note

High-Definition Multimedia Interface (HDMI) Source/Sink Impedance Compliance Test Test Solution Overview Using the E5071C ENA Option TDR

"FP", "FR", "FQ" Series Bandpass Filters

TETRIS 1000 / High Impedance Active Probe Order-No: Features:

R&S ZVA Vector Network Analyzer Specifications

Technical Datasheet Scalar Network Analyzer Model MHz to 40 GHz

A New Concept of PTP Vector Network Analyzer

1000BASE-T1: 3-Port Conversion/Balance Measurement for Cables and Components

Transcription:

Comparison of Vector Network Analyzer and TDA Systems IConnect Generated S-Parameters Purpose: This technical note presents single-ended insertion loss ( SE IL) and return loss ( SE RL) data generated from two different methods: 1) vector network analyzer (VNA), and 2) TDA Systems IConnect. The purpose of this note is to validate the use of the IConnect software in generating these parameters as an alternative to the more widely accepted VNA generated data. Introduction: It is well-known that the VNA is the accepted standard frequency domain instrument used to determine the IL and RL of various devices. Its calibration techniques lend itself well to the measurement of insert able devices. De-embedding techniques can be used to determine the insertion loss of non-insert able devices. Measuring RL on non-insert able devices remains problematic. With selection of the proper reference measurements, IConnect can theoretically gate out, or de-embed, fixturing contributions. This issue along with the high cost of a VNA, especially for differential measurements, has lead to investigating TDA Systems IConnect as a viable option for obtaining frequency domain data. The IConnect software operates on time domain measurements acquired from an oscilloscope with time domain reflectometry (TDR) and time domain transmission (TDT) capability. Once the necessary measurements are made, the IConnect calculates the IL and RL from these measurements. Near and far end crosstalk can also be similarly measured in the time domain and calculated in the frequency domain, but is beyond the scope of this document. Only single-ended measurements were performed. The processing of differential data is as simple as the single-ended data in IConnect, except that four channels are necessary. The same theory applies. At the time of this writing, a differential VNA was not available for comparative data. In this comparison, the device under test (DUT) consisted of two Samtec EQCD Series cable assemblies of 6 inches and 1 meter in length. Refer to Figure 1 on page 4. Cable assemblies were chosen because of the combined effects of reflective connectors separated by lossy cable. One measurement of each type was made on the same line of each cable assembly. A more descriptive test procedure is found in the test procedure section on page 4. samtec Page 1 6/17/24

Results: Insertion loss Plots 1 and 2 show the insertion loss measured by each method on the 6 inch and 1 meter cable assemblies, respectively. The results show the two methods are highly comparable. Pay particular attention to the alignment of the peaks and valleys caused by reflections of the connectors at low frequencies and resonances at high frequencies. For example, observation of the magnitude in Plot 1 at 1.27GHz shows a magnitude difference of.16db. This is within the expected accuracy of the VNA. At the time of this writing, IConnect accuracies were not known. Differences in the resonance magnitudes can be caused by the VNA IF bandwidth or data point location. SE IL 6in EQCD VNA - IConnect Comparison -2-4 IL (db) -6-8 -1-12.E+ 1.E+9 2.E+9 3.E+9 4.E+9 5.E+9 6.E+9 7.E+9 8.E+9 9.E+9 1.E+9 VNA IConnect Plot 1: VNA and IConnect generated Single Ended IL for 6in EQCD Cable Assembly. samtec Page 2 6/17/24

SE IL 1m EQCD VNA - IConnect Comparison -5-1 IL (db) -15-2 -25.E+ 1.E+9 2.E+9 3.E+9 4.E+9 5.E+9 6.E+9 7.E+9 8.E+9 9.E+9 1.E+9 VNA IConnect Plot 2: VNA and IConnect generated Single Ended IL for 1m EQCD Cable Assembly. Return Loss The return loss also matched well. Slight differences were expected due to the inability of the VNA to achieve a precise calibration or reference measurement at the DUT insertion point. It can be argued that the TDA method is a more accurate method in this case due to the fact that a better reference can be obtained. Although the use of timedomain gating option in a VNA would be a better comparison, this option was not available. samtec Page 3 6/17/24

SE RL 6in EQCD VNA - IConnect Comparison -5-1 RL (db) -15-2 -25-3 -35-4.E + 1.E+9 2.E+9 3.E+9 4.E+9 5.E+9 6.E+9 7.E+9 8.E+9 9.E+9 1.E+ 9 VNA IConnect Plot 3: VNA and IConnect generated Single Ended RL for 6in EQCD Cable Assembly. SE RL 1m EQCD VNA - IConnect Comparison -5-1 RL (db) -15-2 -25-3 -35-4.E+ 1.E+9 2.E+9 3.E+9 4.E+9 5.E+9 6.E+9 7.E+9 8.E+9 9.E+9 1.E+9 VNA IConnect Plot 4: VNA and IConnect generated Single Ended RL for 1m EQCD Cable Assembly. samtec Page 4 6/17/24

Test Procedures: Figure 1: Reference and fixtured 6 in EQCD cable assemblies. VNA 1) The VNA was set up with the following parameters: f start = 5MHz Number of Points = 41 f stop = 1GHz IF Bandwidth = 3KHz 2) A full 2-port 3.5mm calibration was performed on the VNA at the end of two 3.5mm test cables using an HP 8552B calibration kit. 3) The insertion loss of a.32 semi-rigid cable assembly terminated with SMA s was then measured and stored. Refer to the top of Figure 1 above (note: at this point, a thru reference measurement was taken and stored on the same semi-rigid cable assembly in the time domain). 4) The semi-rigid cable assembly was cut in half. On each end of the cut cable assembly probes were made by removing 1mm of the outer conductor and dielectric. This resulted in two probes with 1mm probe tips. (Note: At this point, an open reference measurement in the time domain was made on one probe and stored). 5) Small copper plates were machined which grounded the center blade and two connector pins adjacent to a signal pin on the connectors that will mate to each end of the cable assembly. The probes were then soldered to complete the fixturing. Refer to Figure 1 above. samtec Page 5 6/17/24

6) The fixtured connectors were mated with the cable assembly and the SMA probes were attached to the reference plane at the end of the 3.5mm test cables. 7) Return loss (S 11 ) was measured across the sweep band and stored. Note that the far end was terminated at 5Ω into port 2 of the VNA. 8) Insertion loss (S 21 ) of the SMA probes, fixturing, and DUT was measured and stored. 9) The insertion loss of the DUT was taken by scalar subtraction of the magnitude obtained in Procedure 3 from the magnitude obtained in Procedure 8. TDA IConnect 1) The Tektronix CSA 8 was set up with the following parameters: Record Length = 4 t base = 3ns/division These settings allowed for 31 points from Hz to 1GHz with a frequency step of 3.33MHz. 2) The.32 semi-rigid cable assembly terminated with SMA s was attached to channel 1 and 4 of the TDR. 3) With the pulser of channel 1 on a thru reference was measured through the semirigid cable assembly was measured and stored as a thru reference via the IConnect software. (Note: at this point, a thru reference was also made on the VNA in the frequency domain). 4) The semi-rigid cable assembly was cut in half. On each end of the cut cable assembly probes were made by removing 1mm of the outer conductor and dielectric. This resulted in two probes with 1mm probe tips. 5) One of the probes was attached to channel 1 of the oscilloscope. 6) With the pulser of channel 1 on the open reflection was measured at the probe tip and stored via the IConnect software. 7) Small copper plates were machined which grounded the center blade and two connector pins adjacent to a signal pin on the connectors that will mate to each end of the cable assembly. The probes were then soldered to complete the fixturing. Refer to Figure 1 on the previous page. 8) The fixtured connectors were mated with the cable assembly and the SMA probes were attached to channels 1 and 4 of the oscilloscope. 9) The pulser of channel 1 was turned on. 1) A terminated reflection of the of the SMA probes, fixturing, and DUT was measured and stored via the IConnect software. The termination was provided from channel 4. 11) A transmission measurement was made thru the SMA probes, fixturing, and DUT on channel 4 and stored via the IConnect software. 12) Return loss was calculated in IConnect with the open reflection measurement (Procedure 6) used as the Step and the terminated reflection measurement (Procedure 1) as the DUT. 13) Insertion loss was calculated in IConnect with the thru reference measurement (Procedure 3) as the Step and the thru transmission measurement (Procedure 11) as the DUT. samtec Page 6 6/17/24

Equipment: References: 1-Hewlett-Packard 872ES Vector Network Analyzer 1-Tektronix CSA 8 Communications Signal Analyzer 2-Tektronix 8E4 Sampling Modules 1-Agilent 8552B 3.5mm Calibration Kit 1-TDA Systems IConnect Software, Revision 3..2 MX. TDA Systems IConnect TDR Software User Manual, Version 3.. Agilent 872ES Users Guide, Version July 2. samtec Page 7 6/17/24

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information