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Tektronix 80A00, Technical Reference

The Tektronix 80A00 Technical Reference Manual is a must-have resource for users of the Tektronix 80A00 product. Providing detailed insights and instructions, this manual is indispensable for optimizing performance and troubleshooting. Download your free copy of this invaluable resource from manualshive.com and unlock the full potential of your device.

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Optical Sampling Modules

Optical Sampling Modules

The following performance veri

fi

cation procedures for the optical sampling

modules check the characteristics that are shown as checked speci

fi

cations (

symbol) in the optical module tables of the

DSA8300 Digital Serial Analyzer

Speci

fi

cations

manual.

Prerequisites

Be sure you have performed the appropriate

Prerequisites

before doing any

procedures in this section. (See page 16,

Prerequisites

.)

NOTE.

The procedures throughout this chapter contain instructions based on the

menus and controls from the most updated instrument software available at the
time this document was released. These procedures will work for other versions of
software, but some control and menu names may vary slightly.

Dark Level and Vertical Equivalent Optical Noise

This procedure checks the dark level, which is the offset in the optical channel
caused by thermal variations or

fi

nite leakage current. This procedure also checks

the vertical equivalent optical noise. The checks are made with vertical offset
set to zero and no optical signal input to the optical sampling module (dustcap
installed on the OPTICAL INPUT).

Equipment required

(See Table 1.)

Terminator, 50

coaxial, SMA male; used with optical sampling

modules with clock recovery (CR) (item 30)

Prerequisites

(See page 16,

Prerequisites

.)

(See page 219,

Prerequisites

.)

Setup

Figure 28: Dark level and vertical equivalent optical noise test setup

DSA8300 Performance Veri

fi

cation

219

Summary of Contents for 80A00

Page 1: ...xx DSA8300 Digital Serial Analyzer 80C00 80E00 Sampling Modules 80A00 Accessory Modules Performance Verification ZZZ Technical Reference P077068203 077 0682 03 ...

Page 2: ......

Page 3: ...nce Verification ZZZ Technical Reference xx Warning The servicing instructions are for use by qualified personnel only To avoid personal injury do not perform any servicing unless you are qualified to do so Refer to all safety summaries prior to performing service www tektronix com 077 0682 03 ...

Page 4: ...d and pending Information in this publication supersedes that in all previously published material Specifications and price change privileges reserved TEKTRONIX and TEK are registered trademarks of Tektronix Inc Contacting Tektronix Tektronix Inc 14150 SW Karl Braun Drive P O Box 500 Beaverton OR 97077 USA For product information sales service and technical support In North America call 1 800 833 ...

Page 5: ...s taxes and any other charges for products returned to any other locations This warranty shall not apply to any defect failure or damage caused by improper use or improper or inadequate maintenance and care Tektronix shall not be obligated to furnish service under this warranty a to repair damage resulting from attempts by personnel other than Tektronix representatives to install repair or service...

Page 6: ......

Page 7: ...rd 23 80C00 Test Records 32 80A02 EOS ESD Protection Module Test Record 148 80A05 Electrical Clock Recovery Module Test Record 149 DSA8300 Performance Verification 151 Prerequisites 151 Time Interval Accuracy Direct and Clock Trigger 151 External Trigger Direct Level Accuracy 154 External Direct Trigger Sensitivity 156 External Trigger Direct Input Connector Delay Jitter 158 Trigger Delay Jitter U...

Page 8: ...ampling Modules 219 Prerequisites 219 Dark Level and Vertical Equivalent Optical Noise 219 Minimum Optical Bandwidth and Reference Receiver Frequency Response 222 Integrated Rise Time and Aberrations Check 235 Clock Recovery Optical Sensitivity Range and Recovered Clock Timing Jitter 241 80A02 EOS ESD Protection Module 250 Prerequisites 250 Logic Control Threshold 250 80A05 Electrical Clock Recove...

Page 9: ...ls setup 191 Figure 21 Setup to measure Power in 195 Figure 22 Power reference characterization setup 197 Figure 23 Adapter loss setup 199 Figure 24 HF response setup 201 Figure 25 TDR reflected rise time setup 204 Figure 26 TDR system step response aberrations setup 206 Figure 27 TDR system step response aberrations setup 211 Figure 28 Dark level and vertical equivalent optical noise test setup 2...

Page 10: ...Table of Contents Figure 40 Display example clock signal synchronized with the data rate input 257 Figure 41 Display example zoomed in at the crossing point 259 iv DSA8300 Performance Verification ...

Page 11: ...0E06 80E07B 1 189 Table 7 DUT device under test reference response 80E08B 80E09B 80E10B 1 190 Table 8 DUT device under test reference response 80E11 80E11X1 1 191 Table 9 Bandwidth response 55 GHz 65 GHz 203 Table 10 Minimum limits 239 Table 11 Aberrations 240 Table 12 Clock recovery settings 245 Table 13 Clock recovery settings and jitter limits 247 Table 14 Clock recovery settings 256 Table 15 C...

Page 12: ...cover for repair maintenance or adjustment Before use always check the product with a known source to be sure it is operating correctly This product is not intended for detection of hazardous voltages Use personal protective equipment to prevent shock and arc blast injury where hazardous live conductors are exposed While using this product you may need to access other parts of a larger system Read...

Page 13: ...e maximum rating of that terminal The measuring terminals on this product are not rated for mains or Category II III or IV circuits Do not operate without covers Do not operate this product with covers or panels removed or with the case open Hazardous voltage exposure is possible Avoid exposed circuitry Do not touch exposed connections and components when power is present Do not operate with suspe...

Page 14: ... is heavy To reduce the risk of personal injury or damage to the device get help when lifting or carrying the product Use only the Tektronix rackmount hardware specified for this product Service safety summary The Service safety summary section contains additional information required to safely perform service on the product Only qualified personnel should perform service procedures Read this Serv...

Page 15: ...y Symbols and terms on the product These terms may appear on the product DANGER indicates an injury hazard immediately accessible as you read the marking WARNING indicates an injury hazard not immediately accessible as you read the marking CAUTION indicates a hazard to property including the product When this symbol is marked on the product be sure to consult the manual to find out the nature of t...

Page 16: ...Important safety information x DSA8300 Performance Verification ...

Page 17: ...to read the introductions to all procedures These introductions provide important information needed to do the service correctly safely and efficiently Manual Conventions This manual uses certain conventions that you should become familiar with before attempting service Modules Throughout this manual the term module appears A module is composed of electrical and mechanical assemblies circuit cards...

Page 18: ...strument Help menu 80C00 and 80E00 Series Optical and Electrical Sampling Modules User Manual Tektronix part number 071 3059 XX 80A02 EOS ESD Protection Module Instructions Tektronix part number 071 1317 XX 80A03 TekConnect Probe Interface Module Instructions Tektronix part number 071 1298 XX 80A05 Electrical Clock Recovery Module User Manual Tektronix part number 071 1467 XX DSA8300 DSA8200 CSA82...

Page 19: ...unctionality first do the procedures just mentioned and then do the procedure Perform the Functional Tests See page 2 Functional Test Procedures Advantages These procedures require minimal additional time to perform require no additional equipment other than connection hardware and more completely test the internal hardware of the instrument They can be used to quickly determine if the instrument ...

Page 20: ...or no test equipment For information on when to use these procedures refer to Performance Verification Procedures See page 1 Performance Verification Procedures Instrument Diagnostics The following steps run the internal routines that confirm basic functionality and proper adjustment Equipment required None Prerequisites Install all sampling modules to be diagnosed see module user manual for insta...

Page 21: ...ass appears in the dialog box Status column when the diagnostics complete If an error number appears as Status rerun the diagnostics If Fail status continues after rerunning compensation and you have allowed warm up to occur the module or main instrument may need service c Click Close to exit End of Procedure Instrument and Module Compensation Performing a vertical compensation will maximize the a...

Page 22: ...ways store and transport modules in a static free container with their supplied terminations installed Do not transport or ship the instrument with the modules installed in the instrument compartments Always use a safely grounded wrist strap provided with your instrument when installing modules in the mainframe handling modules or making connections Discharge cables to ground before attaching them...

Page 23: ...rea and select All Modules 4 Click Execute to begin module compensation 5 Follow on screen instructions to disconnect inputs and install terminations while leaving trigger signals connected to the mainframe Follow static precautions see the user manual for your sampling module when connecting or disconnecting terminations and cables The compensation may take several minutes to complete CAUTION Fai...

Page 24: ...verify that they operate within limits therefore do not interpret any quantities cited such as about five horizontal divisions as limits NOTE DO NOT make changes to the front panel settings that are not called out in the procedures Each verification procedure will require you to set the instrument to default settings before verifying functions If you make changes to these settings other than those...

Page 25: ...et the DC CALIBRATOR OUTPUT a Push the front panel Vertical MENU button NOTE When an optical module is installed the optical setup dialog box displays by default Click the Basic button to display the basic dialog box b Set the DC CAL value to 200 mV c Push the front panel Vertical MENU button again to dismiss the Vert Setup dialog box 5 Push the channel button for the channel to test The button li...

Page 26: ...ly acquiring waveform on screen Note that there is a small amount of noise present on the DC level Average mode displays an actively acquiring waveform on screen with the noise reduced Envelope mode displays an actively acquiring waveform on screen with the upper and lower extremes of the noise displayed 8 Click the Sample acquisition mode 9 Confirm the DC accuracy compensation Do the following su...

Page 27: ...009 0 For the 80E07B 80E08B 80E09B and 80E10B Limits Vertical Scale mV div Vertical Offset mV DC CAL Output mV Minimum mV Maximum mV 100 600 0 600 0 605 4 594 6 100 0 0 450 461 0 439 0 100 0 0 0 2 0 2 0 100 0 0 450 439 0 461 0 100 600 0 600 0 594 6 605 4 10 Test all channels Repeat steps 3 through 9 until all input channels are verified 11 Remove the test setup Disconnect the SMA cable from the ch...

Page 28: ...ication toolbar select Free Run from the Trig menu 3 Select the channel to test Push the channel button for the channel to test The button lights and the screen shows the selected channel signal Figure 3 Channel button location 4 Verify that the channel is operational Confirm that the following statements are true A trace displays at about center screen The Waveform readout for the channel under t...

Page 29: ... acquisition modes and confirm that the following statements are true Sample mode displays an actively acquiring waveform on screen Note that there may be a small amount of noise present on the baseline level Average mode displays an actively acquiring waveform on screen with any noise present reduced Envelope mode displays an actively acquiring waveform on screen with the upper and lower extremes...

Page 30: ...Trigger dialog box d Push the Vertical channel button for the channel you connected to in step 2 e Turn the Vertical SCALE knob to set the vertical scale to 20 mV div The channel scale readout is displayed in the Control bar at the bottom of the graticule 4 Set the time base Set the Horizontal SCALE to 1 μs div The horizontal scale readout is displayed in the Control bar at the bottom of the grati...

Page 31: ...orizontal SCALE to 1 μs div The horizontal scale readout is in the Control bar at the bottom of the graticule and now shows the horizontal scale value of the Mag1 time base view 7 Verify that the Mag1 time base operates Confirm the following statements The Mag view brackets on the Main View waveform top graticule are a full screen width apart 10 divisions as shown in the following figure One perio...

Page 32: ...ead of the Mag1 NOTE The color of the Mag2 brackets in the main view are different than those of the Mag1 brackets Checking the Cooling Fan Operation Equipment required None Prerequisites The instrument must be powered on and running Power on the instrument and verify that you can feel airflow from all six cooling fans on the left side of the instrument End of Functional Test Procedures 14 DSA8300...

Page 33: ...nstalled modules To check a main instrument as an independent product Do the main instrument tests using a two channel 80E02 80E03 80E04 80E07B 80E08B 80E09B or 80E10B module that has passed the tests in 80E00 Electrical Sampling Modules See page 174 Electrical Sampling Modules When performing the time interval accuracy and external direct trigger delay jitter tests check one channel of each small...

Page 34: ...ors Prerequisites The tests in this section comprise an extensive valid confirmation of performance and functionality when the following requirements are met The cabinet must be installed on the instrument You must have performed and passed the procedure Perform the Diagnostics and the procedure Perform the Functional Tests See page 2 Instrument Diagnostics See page 6 Instrument Functional Tests A...

Page 35: ...ty 2 SMA female to BNC male connectors Tektronix part number 015 0572 00 4 Adapter Qty 2 BNC to dual banana plugs Tektronix part number 103 0090 00 5 Adapter SMA T 1 male to 2 SMA female Tektronix part number 015 1016 00 6 Attenuator 80E01 only 10 dB female to male SMA connectors HP8490D with option 10 7 Attenuator 2X attenuator 50 Ω SMA connectors Tektronix part number 015 1001 00 8 Attenuator op...

Page 36: ... 80E07B 80E08B 80E09B and 80E10B only Power meter Anritsu Wilton ML2437A 25 Power sensor 80E01 80E06 80E07B 80E08B 80E09B and 80E10B only Power sensor w attached cable Anritsu Wilton ML2425A 26 Power divider 50 Ω 3 SMA female connectors Tektronix part number 015 0565 00 27 Short coaxial Shorting 34 GHz precision 3 5 mm female Tektronix part number 011 0150 00 28 Terminator 50 Ω coaxial terminator ...

Page 37: ...nt 8487A Power Sensor 2002 07 31 47 RF Power Detector 80E06 80E07B 80E08B 80E09B and 80E10B only 10 MHz to 50 GHz Must use specified equipment Anritsu RF Detector 560 7VA50 48 Power sensor 80E06 and 80E09B only Waveguide Power Sensor Must use specified equipment Agilent V8486A 49 Open Short 80E06 80E07B 80E08B 80E09B and 80E10B only DC to 50 GHz Must use specified equipment Anritsu 22V50 Open and ...

Page 38: ...section contains test records that you can use to record the results of your performance verification checks DSA8300 Main Instrument includes 82A04 Phase Reference module 80E00 Electrical Sampling Modules 80C00 Optical Sampling Modules 80A02 EOS ESD Protection Module 80A05 Electrical Clock Recovery Module Do not enter values into the records contained in this manual rather make copies of the recor...

Page 39: ...e Trigger connector Eye mode Horizontal Position Set to 19 ns 1 0 991 ns 1 009 ns 100 ns 0 991 ns 1 009 ns 1 μs 0 991 ns 1 009 ns Time Interval Accuracy Clock Input Prescale Trigger connector Other mode Horizontal Position Set to 19 ns 1 0 991 ns 1 009 ns 100 ns 0 991 ns 1 009 ns 1 μs 0 991 ns 1 009 ns External Trigger Direct Input connector delay jitter Horizontal Position Set to 19 ns 1 none 1 5...

Page 40: ... 82A04 Performance Test Minimum Incoming Outgoing Maximum DC Calibration Output Set to 1 0 V 0 9988 V 1 0012 V 0 0 V 0 2 mV 0 2 mV 1 0 V 1 0012 V 0 9988 V 1 29 ns for 80E07B 80E08B 80E09B 80E10B 22 DSA8300 Performance Verification ...

Page 41: ...nstrument UI depending on the compartment slot in which the module is installed 80E00 Test Record Module Model Module Serial Number Cal Certificate Number Date of Calibration Technician 80E00 Performance test Minimum Incoming Outgoing Maximum Input Impedance C1 Impedance 49 5 Ω 50 5 Ω Baseline 80E04 only 1 mV 1 mV C2 Impedance 49 5 Ω 50 5 Ω 80E01 80E02 80E03 80E04 80E06 Baseline 80E04 only 1 mV 1 ...

Page 42: ...mV 11 mV 11 mV 650 mV 1100 mV 18 7 mV 18 7 mV 850 mV 1100 mV 14 7 mV 14 7 mV 1100 mV 1100 mV 9 7 mV 9 7 mV 1350 mV 1100 mV 14 7 mV 14 7 mV 1550 mV 1100 mV 18 7 mV 18 7 mV C2 100 mV div Input level Offset 1550 mV 1100 mV 18 7 mV 18 7 mV 1350 mV 1100 mV 14 7 mV 14 7 mV 1100 mV 1100 mV 9 7 mV 9 7 mV 850 mV 1100 mV 14 7 mV 14 7 mV 650 mV 1100 mV 18 7 mV 18 7 mV 450 mV 0 mV 11 mV 11 mV 250 mV 0 mV 7 mV...

Page 43: ...15 2 mV 15 2 mV 350 mV 600 mV 11 2 mV 11 2 mV 600 mV 600 mV 6 2 mV 6 2 mV 850 mV 600 mV 11 2 mV 11 2 mV 1050 mV 600 mV 15 2 mV 15 2 mV C2 100 mV div Input level Offset 1050 mV 600 mV 15 2 mV 15 2 mV 850 mV 600 mV 11 2 mV 11 2 mV 600 mV 600 mV 6 2 mV 6 2 mV 350 mV 600 mV 11 2 mV 11 2 mV 150 mV 600 mV 15 2 mV 15 2 mV 450 mV 0 mV 11 mV 11 mV 250 mV 0 mV 7 mV 7 mV 0 mV 0 mV 2 mV 2 mV 250 mV 0 mV 7 mV ...

Page 44: ...0 mV 350 mV 10 mV 10 mV 250 mV 10 mV 10 mV 150 mV 10 mV 10 mV 50 mV 10 mV 10 mV 50 mV 10 mV 10 mV 150 mV 10 mV 10 mV 250 mV 10 mV 10 mV 350 mV 10 mV 10 mV 450 mV 10 mV 10 mV Random Noise Displayed 80E01 C1 Vert scale 2 mV none 2 3 mV C1 Vert scale 1 mV none 800 μV 80E02 C2 Vert scale 1 mV none 800 μV C1 Vert scale 1 mV none 1 2 mV 80E03 80E04 C2 Vert scale 1 mV none 1 2 mV 80E06 C1 Vert scale 2 mV...

Page 45: ...e 480 μV C2 BW 40 GHz Vert scale 1 mV none 480 μV C1 BW 30 GHz Vert scale 1 mV none 410 μV 80E10B C2 BW 30 GHz Vert scale 1 mV none 410 μV Analog Bandwidth C1 to 50 GHz Max power 50 MHz ref none 3 dB 80E01 Min power 50 MHz ref 3 dB C1 to 65 GHz Max power 50 MHz ref none 3 dB 80E06 Min power 50 MHz ref 3 dB C1 to 30 GHz Max power 50 MHz ref none 3 dB Min power 50 MHz ref 3 dB C2 to 30 GHz Max power...

Page 46: ...ps 80E04 TDR Polarity set to none 35 ps C1 TDR Polarity set to none 22 ps TDR Polarity set to none 22 ps C2 TDR Polarity set to none 22 ps 80E08B TDR Polarity set to none 22 ps C1 TDR Polarity set to none 16 ps TDR Polarity set to none 16 ps C2 TDR Polarity set to none 16 ps 80E10B TDR Polarity set to none 16 ps TDR system step response aberrations 80E04 80E08B 80E10B models only 80E04 C1 positive...

Page 47: ...m 5 ns on 2 1 1 80E08B C1 positive polarity zone from 10 ns to 20 ps 1 1 1 zone from 14 ps to 150 ps 2 2 25 zone from 150 ps to 400 ps2 2 12 zone from 400 ps to 5 ns 2 2 2 zone from 5 ns to 100 ns 2 2 1 zone from 100 ns to end 2 1 1 C1 negative polarity zone from 10 ns to 20 ps 1 1 1 zone from 14 ps to 150 ps 2 2 25 zone from 150 ps to 400 ps2 2 12 zone from 400 ps to 5 ns 2 2 2 zone from 5 ns to ...

Page 48: ...e polarity zone from 10 ns to 20 ps 1 1 1 zone from 14 ps to 150 ps 2 2 25 zone from 150 ps to 400 ps2 2 12 zone from 400 ps to 5 ns 2 2 2 zone from 5 ns to 100 ns 2 2 1 zone from 100 ns to end 2 1 1 80E10B zone from 10 ns to 20 ps 1 1 1 zone from 14 ps to 150 ps 2 2 25 zone from 150 ps to 400 ps2 2 12 zone from 400 ps to 5 ns 2 2 2 zone from 5 ns to 100 ns 2 2 1 C1 positive polarity zone from 100...

Page 49: ... 10 ns to 20 ps 1 1 1 zone from 14 ps to 150 ps 2 2 25 zone from 150 ps to 400 ps2 2 12 zone from 400 ps to 5 ns 2 2 2 zone from 5 ns to 100 ns 2 2 1 C2 positive polarity zone from 100 ns to end 2 1 1 zone from 10 ns to 20 ps 1 1 1 zone from 14 ps to 150 ps 2 2 25 zone from 150 ps to 400 ps2 2 12 zone from 400 ps to 5 ns 2 2 2 zone from 5 ns to 100 ns 2 2 1 C2 negative polarity zone from 100 ns to...

Page 50: ...7B Test Record See page 54 80C08 Test Record See page 56 80C08B Test Record See page 60 80C08C Test Record See page 67 80C08D Test Record See page 75 80C09 Test Record See page 77 80C10 Test Record See page 79 80C10B Test Record See page 83 80C10C Test Record See page 88 80C11 Test Record See page 94 80C11B Test Record See page 100 80C12 Test Record See page 104 80C12 10G Test Record See page 109 ...

Page 51: ... none 12 μWRMS Clock Recovery none 15 μWRMS OC 192 STM 64 none 12 μWRMS Clock Recovery none 15 μWRMS 12 5 GHz none 12 μWRMS Clock Recovery none 15 μWRMS 20 GHz none 25 μWRMS Clock Recovery none 25 μWRMS Minimum optical bandwidth 12 5 GHz bandwidth setting 12 5 GHz none 20 GHz bandwidth setting 20 GHz none OC 12 STM 4 622 Mb s Reference Receiver setting frequency response dB Frequency MHz Nominal r...

Page 52: ...37 8 08 4 66 2986 0 8 54 10 74 6 35 3359 3 10 93 13 55 8 31 3732 6 13 41 16 41 10 41 OC192 STM 64 9 953 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 0 45 1 30 0 40 4478 8 1 02 1 87 0 17 5972 4 1 86 2 71 1 01 7465 0 3 00 3 86 2 16 8958 0 4 51 6 19 2 83 9953 28 5 71 7 87 3 55 10451 2 6 37 8 75 3 99 11944 0 8 ...

Page 53: ...WRMS 20 GHz none 15 μWRMS Clock Recovery none 20 μWRMS 30 GHz none 30 μWRMS Clock Recovery none 40 μWRMS Minimum optical bandwidth 12 5 GHz bandwidth setting 12 5 GHz none 20 GHz bandwidth setting 20 GHz none 30 GHz bandwidth setting 28 GHz none OC 192 STM 64 9 953 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986...

Page 54: ...Performance Tests 80C02 performance test Minimum Incoming Outgoing Maximum Recovered clock timing jitter 80C02 CR only Rate Horz scale OC 192 20 ps none 2 psRMS 36 DSA8300 Performance Verification ...

Page 55: ...M 16 none 1 5 μWRMS Clock Recovery none 1 5 μWRMS OC 48 STM 16 2 488 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 373 3 0 11 0 61 0 39 746 5 0 45 0 95 0 05 1119 7 1 02 1 52 0 52 1493 1 1 86 2 36 1 36 1866 3 3 00 3 50 2 50 2239 5 4 51 5 67 3 35 2488 3 5 71 7 25 4 17 2612 8 6 37 8 08 4 66 2986 0 8 54 10 74 6 35 3359 3 10 93 13 55 8 31 37...

Page 56: ... 05 562 5 1 02 1 52 0 52 750 1 86 2 36 1 36 937 5 3 00 3 50 2 50 1125 4 51 5 67 3 35 1250 5 71 7 25 4 17 1312 5 6 37 8 08 4 66 1500 8 54 10 74 6 35 1687 5 10 93 13 55 8 31 1875 13 41 16 41 10 41 FC1063 1 0625 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 159 5 0 11 0 61 0 39 318 9 0 45 0 95 0 05 478 4 1 02 1 52 0 52 637 9 1 86 2 36 1 36...

Page 57: ...est Minimum Incoming Outgoing Maximum Recovered clock timing jitter 80C03 CR only Rate Horz scale FC1063 200 ps none 8 psRMS GBE 200 ps none 8 psRMS OC 48 100 ps none 8 psRMS 2 5 Gb s 100 ps none 8 psRMS DSA8300 Performance Verification 39 ...

Page 58: ...Clock Recovery none 12 μWRMS 20 GHz none 15 μWRMS Clock Recovery none 20 μWRMS 30 GHz none 30 μWRMS Clock Recovery none 40 μWRMS Minimum optical bandwidth 20 GHz bandwidth setting 20 GHz none 30 GHz bandwidth setting 28 GHz none OC 192 STM 64 9 953 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 0 45 1 30 0 40...

Page 59: ... 0 85 1599 8 0 11 0 96 0 74 3199 2 0 45 1 30 0 40 4798 6 1 02 1 87 0 17 6398 9 1 86 2 71 1 01 7998 0 3 00 3 86 2 16 9597 7 4 51 6 19 2 83 10664 0 5 71 7 87 3 55 11197 5 6 37 8 75 3 99 12796 9 8 54 11 53 5 56 14396 7 10 93 14 45 7 41 15996 5 13 41 17 41 9 41 Recovered clock timing jitter 80C04 CR only Rate Horz scale OC 192 20 ps none 2 psRMS DSA8300 Performance Verification 41 ...

Page 60: ...WRMS 30 GHz none 35 μWRMS Clock Recovery none 35 μWRMS 40 GHz none 70 μWRMS Clock Recovery none 70 μWRMS Minimum optical bandwidth 20 GHz bandwidth setting 20 GHz none 30 GHz bandwidth setting 30 GHz none 40 GHz bandwidth setting 40 GHz none OC 192 STM 64 9 953 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 0...

Page 61: ...e Tests 80C05 performance test Minimum Incoming Outgoing Maximum Aberrations peak to peak OC 192 STM 64 none 5 20 GHz none 10 30 GHz none 10 Filter or Bandwidth 40 GHz none 15 DSA8300 Performance Verification 43 ...

Page 62: ...tificate Number RH Technician 80C06 performance test Minimum Incoming Outgoing Maximum Dark level C1 at 200 μW 50 GHz 25 μW 25 μW Vertical equivalent optical noise C1 at 200 μW 50 GHz none 192 μWRMS Clock Recovery none 192 μWRMS Aberrations peak to peak Bandwidth 50 GHz none 10 44 DSA8300 Performance Verification ...

Page 63: ... 5 μW OC 3 STM 1 500 nW 500 nW OC 12 STM 4 500 nW 500 nW OC 48 STM 16 500 nW 500 nW 2 GHz 500 nW 500 nW Vertical equivalent optical noise C1 at 5 μW OC 3 STM 1 none 1 0 μWRMS Clock Recovery none 1 0 μWRMS OC 12 STM 4 none 1 0 μWRMS Clock Recovery none 1 0 μWRMS OC 48 STM 16 none 1 5 μWRMS Clock Recovery none 1 5 μWRMS Minimum optical bandwidth 2 GHz bandwidth setting 2 3 GHz none DSA8300 Performan...

Page 64: ...Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 93 3 0 11 0 61 0 39 186 6 0 45 0 95 0 05 279 9 1 02 1 52 0 52 373 2 1 86 2 36 1 36 466 7 3 00 3 50 2 50 559 9 4 51 5 67 3 35 622 1 5 71 7 25 4 17 653 2 6 37 8 08 4 66 746 5 8 54 10 74 6 35 839 8 10 93 13 55 8 31 933 1 13 41 16 41 10 41 OC 48 STM 16 2 488 Gb s Reference Receiver setting frequency ...

Page 65: ...ximum 2612 8 6 37 8 08 4 66 2986 0 8 54 10 74 6 35 3359 3 10 93 13 55 8 31 3732 6 13 41 16 41 10 41 Recovered clock timing jitter 80C07 CR only Rate Horz scale OC 3 1 ns none 32 psRMS OC 12 500 ps none 8 psRMS OC 48 100 ps none 4 psRMS DSA8300 Performance Verification 47 ...

Page 66: ...500 nW 2 5 GHz 500 nW 500 nW Vertical equivalent optical noise OC 3 STM 1 none 1 0 μWRMS Clock Recovery none 1 0 μWRMS OC 12 STM 4 none 1 0 μWRMS Clock Recovery none 1 0 μWRMS OC 48 STM 16 none 1 5 μWRMS Clock Recovery none 1 5 μWRMS FC1063 none 1 0 μWRMS Clock Recovery none 1 0 μWRMS FC2125 none 1 5 μWRMS Clock Recovery none 1 5 μWRMS ENET1250 none 1 0 μWRMS Clock Recovery none 1 0 μWRMS ENET2500...

Page 67: ...BAND none 1 5 μWRMS Clock Recovery none 1 5 μWRMS 2 5 GHz none 1 5 μWRMS 1310 nm C1 at 5 μW Clock Recovery none 1 5 μWRMS OC 3 STM 1 none 1 6 μWRMS Clock Recovery none 1 6 μWRMS OC 12 STM 4 none 1 6 μWRMS Clock Recovery none 1 6 μWRMS OC 48 STM 16 none 2 4 μWRMS Clock Recovery none 2 4 μWRMS FC1063 none 1 6 μWRMS Clock Recovery none 1 6 μWRMS FC2125 none 2 4 μWRMS Clock Recovery none 2 4 μWRMS ENE...

Page 68: ...ecovery none 3 0 μWRMS 2 5 GHz none 3 0 μWRMS 780 nm C1 at 5 μW Clock Recovery none 3 0 μWRMS Minimum optical bandwidth 2 5 GHz bandwidth setting 2 3 GHz none OC 3 STM 1 155 Mb s Reference Receiver setting frequency response Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 23 3 0 11 0 61 0 39 46 65 0 45 0 95 0 05 69 98 1 02 1 52 0 52 93 3 1 86 2 36 1 36 116 7 3 00 3 50 2 50 140 0 4 51 5 67 3 ...

Page 69: ...0 11 0 61 0 39 746 5 0 45 0 95 0 05 1119 7 1 02 1 52 0 52 1493 1 1 86 2 36 1 36 1866 3 3 00 3 50 2 50 2239 5 4 51 5 67 3 35 2488 3 5 71 7 25 4 17 2612 8 6 37 8 08 4 66 2986 0 8 54 10 74 6 35 3359 3 10 93 13 55 8 31 3732 6 13 41 16 41 10 41 ENET2500 2 GBE 2 50 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 375 0 11 0 61 0 39 750 0 45 0 95...

Page 70: ...0625 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 159 5 0 11 0 61 0 39 318 9 0 45 0 95 0 05 478 4 1 02 1 52 0 52 637 9 1 86 2 36 1 36 797 4 3 00 3 50 2 50 956 8 4 51 5 67 3 35 1063 5 71 7 25 4 17 1116 6 37 8 08 4 66 1275 8 54 10 74 6 35 1435 10 93 13 55 8 31 1595 13 41 16 41 10 41 FC2125 2 125 Gb s Reference Receiver setting frequency ...

Page 71: ...5 1125 1 02 1 52 0 52 1500 1 86 2 36 1 36 1875 3 00 3 50 2 50 2250 4 51 5 67 3 35 2500 5 71 7 25 4 17 2625 6 37 8 08 4 66 3000 8 54 10 74 6 35 3375 10 93 13 55 8 31 3750 13 41 16 41 10 41 Recovered clock timing jitter 80C07B CR only Rate Horiz scale OC 3 STM 1 1 ns none 32 psRMS OC 12 STM 4 500 ps none 8 psRMS OC 48 STM 16 100 ps none 4 psRMS FC1063 200 ps none 8 psRMS FC2125 100 ps none 6 psRMS E...

Page 72: ... μW Clock Recovery none 3 5 μWRMS 10 GHz none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GBASE W none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GBASE R none 3 0 μWRMS 1310 nm C1 at 5 μW Clock Recovery none 3 5 μWRMS 10 GHz none 5 0 μWRMS Clock Recovery none 5 5 μWRMS 10GBASE W none 5 0 μWRMS Clock Recovery none 5 5 μWRMS 10GBASE R none 5 0 μWRMS 850 nm C1 at 5 μW Clock Recovery none 5 5 μWRMS 10 GH...

Page 73: ...6 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10BASE R 10 3125 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 ...

Page 74: ...S Clock Recovery none 3 5 μWRMS 10GBASE W none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GBASE R none 3 0 μWRMS Clock Recovery none 3 5 μWRMS OC 192 STM 64 none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GFC none 3 0 μWRMS 1550 nm C1 at 5 μW Clock Recovery none 3 5 μWRMS 10 GHz none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GBASE W none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GBASE R none 3 0 μWR...

Page 75: ...ery none 6 6 μWRMS 10GBASE R none 6 0 μWRMS Clock Recovery none 6 6 μWRMS OC 192 STM 64 none 6 0 μWRMS Clock Recovery none 6 6 μWRMS 10GFC none 6 0 μWRMS 780 nm C1 at 5 μW Clock Recovery none 6 6 μWRMS Minimum optical bandwidth 10 GHz bandwidth setting 9 5 GHz none 10BASE W 9 95328 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11...

Page 76: ...s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 0 45 1 30 0 40 4478 8 1 02 1 87 0 17 5972 4 1 86 2 71 1 01 7465 0 3 00 3 86 2 16 8958 0 4 51 6 19 2 83 9953 28 5 71 7 87 3 55 10451 2 6 37 8 75 3 99 11944 0 8 54 11 53 5 56 13437 2 10 93 14 45 7 41 14930 4 13 41 17 41 9 41 10GFC 10 51875 Gb s Reference Receiver sett...

Page 77: ...14 45 7 41 15000 13 41 17 41 9 41 Recovered clock timing jitter 80C08B CR1 only Rate Horiz scale OC 192 20 ps none 2 psRMS 10GBASE W 20 ps none 2 psRMS 10GBASE R 20 ps none 2 psRMS Recovered clock timing jitter 80C08B CR2 only Rate Horiz scale 10GBASE R 20 ps none 2 psRMS 10GFC 20 ps none 2 psRMS DSA8300 Performance Verification 59 ...

Page 78: ...μW 10 709 data filter 1 0 μW 1 0 μW Vertical equivalent optical noise 10 GHz none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GBASE W none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GBASE R none 3 0 μWRMS Clock Recovery none 3 5 μWRMS OC 192 STM 64 none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GFC none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GFC FEC none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10G...

Page 79: ... none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10 709 Gb s none 3 0 μWRMS 1310 nm C1 at 5 μW Clock Recovery none 3 5 μWRMS 10 GHz none 5 0 μWRMS Clock Recovery none 5 5 μWRMS 10GBASE W none 5 0 μWRMS Clock Recovery none 5 0 μWRMS 10GBASE R none 5 0 μWRMS Clock Recovery none 5 5 μWRMS OC 192 STM 64 none 5 5 μWRMS Clock Recovery none 5 5 μWRMS 10GFC none 5 0 μWRMS Clock Recovery none 5 5 μWRMS 10GFC ...

Page 80: ...MS 10 66 Gb s none 6 0 μWRMS Clock Recovery none 6 6 μWRMS 10 709 Gb s none 6 0 μWRMS 780 nm C1 at 5 μW Clock Recovery none 6 6 μWRMS Minimum optical bandwidth 10 GHz bandwidth setting 9 5 GHz none 10GBASE W 9 95328 Gb s Reference Receiver setting frequency response dB NOTE For 80C08C Serial numbers B030000 and up use the 80C08D table Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11...

Page 81: ...TM 64 9 953 Gb s Reference Receiver setting frequency response dB NOTE For 80C08C Serial numbers B030000 and up use the 80C08D table Note Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 0 45 1 30 0 40 4478 8 1 02 1 87 0 17 5972 4 1 86 2 71 1 01 7465 0 3 00 3 86 2 16 8958 0 4 51 6 19 2 83 9953 28 5 71 7 87 3 55 10451 2 6 37 8 75 3 99 11944 0 8 54 11 53 5 56 13437 2 10 93 14 45 ...

Page 82: ... 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GBE FEC 11 0957 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 1...

Page 83: ... Data Filter frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 Recovered clock timing jitter 80C08C CR1 only Rate Horiz scale OC 192 20 ps none ...

Page 84: ...iming jitter 80C08C CR4 only Rate Horiz scale OC 192 20 ps none 2 psRMS 10GBASE W 20 ps none 2 psRMS 10GBASE R 20 ps none 2 psRMS 10GFC 20 ps none 2 psRMS 10GBE 20 ps none 2 psRMS G 975 20 ps none 2 psRMS G 709 20 ps none 2 psRMS Super FEC 20 ps none 2 psRMS 66 DSA8300 Performance Verification ...

Page 85: ...lter 1 0 μW 1 0 μW 10 709 data filter 1 0 μW 1 0 μW Vertical equivalent optical noise 10GBASE W none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GBASE R none 3 0 μWRMS Clock Recovery none 3 5 μWRMS OC 192 STM 64 none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GFC none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GFC FEC none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10GBE FEC none 3 0 μWRMS Clock Recovery...

Page 86: ... none 3 0 μWRMS Clock Recovery none 3 5 μWRMS 10 709 Gb s none 3 0 μWRMS 1310 nm C1 at 5 μW Clock Recovery none 3 5 μWRMS 10GBASE W none 5 0 μWRMS Clock Recovery none 5 5 μWRMS 10GBASE R none 5 0 μWRMS Clock Recovery none 5 5 μWRMS OC 192 STM 64 none 5 0 μWRMS Clock Recovery none 5 5 μWRMS 10GFC none 5 0 μWRMS Clock Recovery none 5 5 μWRMS 10GFC FEC none 5 0 μWRMS Clock Recovery none 5 5 μWRMS 10G...

Page 87: ... 780 nm C1 at 5 μW Clock Recovery none 6 6 μWRMS Minimum optical bandwidth 10 GHz bandwidth setting 9 5 GHz none 10GBASE W 9 95328 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99...

Page 88: ...74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GFC FEC Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71...

Page 89: ...nce Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 45 1 30 0 40 4478 8 1 02 1 87 0 17 5972 4 1 86 2 71 1 01 7465 0 3 00 3 86 2 16 8958 4 51 6 19 2 83 9953 28 5 71 7 87 3 55 10451 2 6 37 8 75 3 99 11944 8 54 11 53 5 56 13437 2 10 93 14 45 7 41 14930 4 13 41 17 41 9 41 FEC 10 66Gb s Reference Receiver Setting Frequency Respon...

Page 90: ... 71 7 87 3 55 11245 0 6 37 8 75 3 99 12851 1 8 54 11 53 5 56 14457 7 10 93 14 45 7 41 16064 4 13 41 17 41 9 41 10 66 Gb s Data Filter frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 ...

Page 91: ... 1550 nm 13 dBm 50 μW none 1310 nm 13 dBm 50 μW none Clock Recovery Optical Sensitivity 80C08D CR4 Only Wavelength Data rate Sensitivity 9 8 to 11 25 G bs 13 dBm none 1550 nm 11 25 to 12 6 Gb s 11 5 dBm none 9 8 to 11 2 13 dBm none 1310 nm 11 25 to 12 6 Gb s 11 5 dBm none 9 8 to 11 25 10 dBm none 850 nm 11 25 to 12 6 Gb s 8 5 dBm none 9 8 to 11 25 10 dBm none 780 nm 11 25 to 12 6 Gb s 8 5 dBm none...

Page 92: ...oing Maximum Recovered clock timing jitter 80C08D CR4 only Rate OC 192 none 2 psRMS 10GBASE W none 2 psRMS 10GBASE R none 2 psRMS 10GFC none 2 psRMS 10GBE none 2 psRMS G 975 none 2 psRMS G 709 none 2 psRMS Super FEC none 2 psRMS 74 DSA8300 Performance Verification ...

Page 93: ...lock Recovery none 12 μWRMS 20 GHz none 15 μWRMS Clock Recovery none 20 μWRMS 30 GHz none 30 μWRMS Clock Recovery none 40 μWRMS Minimum optical bandwidth 20 GHz bandwidth setting 20 GHz none 30 GHz bandwidth setting 28 GHz none OC 192 STM 64 9 953 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 0 45 1 30 0 40 ...

Page 94: ... 11 0 96 0 74 3212 8 0 45 1 30 0 40 4819 0 1 02 1 87 0 17 6426 0 1 86 2 71 1 01 8032 0 3 00 3 86 2 16 9638 4 4 51 6 19 2 83 10709 2 5 71 7 87 3 55 11245 0 6 37 8 75 3 99 12851 1 8 54 11 53 5 56 14457 7 10 93 14 45 7 41 16064 4 13 41 17 41 9 41 Recovered clock timing jitter 80C09 CR1 only Rate Horz scale OC 192 20 ps none 2 psRMS FEC10 71 Gb s 20 ps none 2 psRMS 76 DSA8300 Performance Verification ...

Page 95: ...C 768 STM 256 none 60 μWRMS FEC 43 02 Gb s none 60 μWRMS 30 GHz none 50 μWRMS 1550 nm C1 at 50 μW 65 GHz none 120 μWRMS OC 768 STM 256 none 110 μWRMS 43 02 Gb s none 110 μWRMS 30 GHz none 90 μWRMS 1310 nm C1 at 50 μW 65 GHz none 220 μWRMS Minimum optical bandwidth 30 GHz bandwidth setting 30 GHz none 65 GHz bandwidth setting 60 GHz none OC 768 STM 256 39 813 Gb s Reference Receiver setting frequen...

Page 96: ...y GHz Nominal response dB 0 00 0 00 1 00 1 00 6 45 0 10 1 10 0 90 12 90 0 45 1 45 0 55 19 36 1 02 2 02 0 02 25 81 1 86 2 86 0 86 32 26 3 00 4 00 2 00 38 71 4 51 6 56 2 46 43 02 5 71 8 37 3 05 45 17 6 37 9 31 3 43 51 63 8 54 12 26 4 83 58 08 10 93 15 32 6 53 64 53 13 41 18 41 8 41 Aberrations peak to peak OC 768 none 5 FEC 43 02 Gb s none 5 30 GHz none 5 Filter or bandwidth 65 GHz none 10 78 DSA830...

Page 97: ...μW 65 GHz 25 μW 25 μW 1550 nm C1 at 50 μW 80 GHz 25 μW 25 μW OC 768 STM 256 35 μW 35 μW FEC 43 02 Gb s 35 μW 35 μW 40GBase FR 35 μW 35 μW 100GBase R4 35 μW 35 μW 100GBase R4 FEC 35 μW 35 μW 30 GHz 35 μW 35 μW 65 GHz 35 μW 35 μW 1310 nm C1 at 80 μW 80 GHz 35 μW 35 μW Vertical equivalent optical noise OC 768 STM 256 none 38 μWRMS FEC 43 02 Gb s none 38 μWRMS 40GBase FR none 38 μWRMS 100GBase R4 none...

Page 98: ...ver setting frequency response dB Frequency GHz Nominal response dB 0 00 0 00 1 00 1 00 5 97 0 10 1 10 0 90 11 94 0 45 1 45 0 55 17 92 1 02 2 02 0 02 23 89 1 86 2 86 0 86 29 86 3 00 4 00 2 00 35 83 4 51 6 56 2 46 39 81 5 71 8 37 3 05 41 80 6 37 9 31 3 43 47 78 8 54 12 26 4 83 53 75 10 93 15 32 6 53 59 72 13 41 18 41 8 41 FEC 43 02 Gb s G 709 FEC Reference Receiver setting frequency response dB Fre...

Page 99: ...0000 13 41 17 41 9 41 100GBase R4 25 781 Gb s ENET25781 Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 3750 0 11 0 96 0 74 7500 0 45 1 30 0 40 11250 1 02 1 87 0 17 15000 1 86 2 71 1 01 18750 3 00 3 86 2 16 22500 4 51 6 19 2 83 25000 5 71 7 87 3 55 26250 6 37 8 75 3 99 30000 8 54 11 53 5 56 33750 10 93 14 45 7 41 37500 13 41 17 41 9 41 100GBas...

Page 100: ...3 55 26250 6 37 8 75 3 99 30000 8 54 11 53 5 56 33750 10 93 14 45 7 41 37500 13 41 17 41 9 41 Aberrations peak to peak OC 768 none 5 FEC 43 02 Gb s none 5 40GBase FR none 5 100GBase R4 none 5 100GBase R4 FEC none 5 30 GHz none 5 65 GHz none 10 Filter or bandwidth 80 GHz none 12 82 DSA8300 Performance Verification ...

Page 101: ...nm C1 at 50 μW 80 GHz 25 μW 25 μW OC 768 STM 256 35 μW 35 μW FEC 43 02 Gb s 35 μW 35 μW 40GBase FR 35 μW 35 μW 100GBase R4 35 μW 35 μW 100GBase R4 FEC 35 μW 35 μW 30 GHz 35 μW 35 μW 65 GHz 35 μW 35 μW 1310 nm C1 at 80 μW 80 GHz 35 μW 35 μW Vertical equivalent optical noise 100GBase R4 none 18 μWRMS Infiniband EDR none 18 μWRMS OTU4 none 20 μWRMS 28 05 GHz none 20 μWRMS 32 GHz none 22 μWRMS OC768 S...

Page 102: ...RMS OC768 STM256 none 34 μWRMS 40GBase FR none 34 μWRMS 43 G FEC none 34 μWRMS 55 GHz none 46 μWRMS 70 GHz none 75 μWRMS Option CRTP 1550 nm C1 at 50 μW 80 GHz none 115 μWRMS 100GBase R4 none 27 μWRMS Infiniband EDR none 27 μWRMS OTU4 none 28 μWRMS 28 05 GHz none 28 μWRMS 32 GHz none 34 μWRMS OC768 STM256 none 44 μWRMS 40GBase FR none 44 μWRMS 43 G FEC none 44 μWRMS 55 GHz none 60 μWRMS 70 GHz non...

Page 103: ...4 s Reference Receiver setting frequency response dB OPTION F1 and OPTION F3 ONLY Frequency GHz Nominal response dB 0 00 0 00 0 85 0 85 6 45 0 11 0 96 0 74 12 90 0 45 1 30 0 40 19 32 1 02 1 87 0 17 25 81 1 86 2 71 1 01 32 26 3 00 3 86 2 16 38 73 4 51 6 19 2 83 43 02 5 71 7 87 3 55 45 17 6 37 8 75 3 99 51 63 8 54 11 53 5 56 58 08 10 93 14 45 7 41 64 52 13 41 17 41 9 41 32 GHz Reference Receiver Set...

Page 104: ...53 5 56 37868 10 93 14 45 7 41 42075 13 41 17 41 9 41 OTU4 OTU27952 Reference Receiver Setting Frequency Response for 27 952 Gb s OPTION F1 AND OPTION F2 ONLY Frequency GHz Nominal response dB 0 00 0 00 0 85 0 85 4193 0 11 0 96 0 74 8386 0 45 1 30 0 40 12579 1 02 1 87 0 17 16773 1 86 2 71 1 01 20966 3 00 3 86 2 16 25159 4 51 6 19 2 83 27952 5 71 7 87 3 55 29350 6 37 8 75 3 99 33542 8 54 11 53 5 56...

Page 105: ...LY Frequency GHz Nominal response dB 0 00 0 00 0 85 0 85 6188 0 11 0 96 0 74 12375 0 45 1 30 0 40 18563 1 02 1 87 0 17 24750 1 86 2 71 1 01 30938 3 00 3 86 2 16 37125 4 51 6 19 2 83 41250 5 71 7 87 3 55 43313 6 37 8 75 3 99 49500 8 54 11 53 5 56 55688 10 93 14 45 7 41 61875 13 41 17 41 9 41 Aberrations peak to peak Infiniband EDR setting none 5 100GBase R4 setting none 5 OTU4 none 5 28 05 GHz none...

Page 106: ...FC 10 μW 10 μW 20 GHz 10 μW 10 μW 30 GHz 10 μW 10 μW Vertical equivalent optical noise C1 at 100 μW OC 192 STM 64 none 8 0 μWRMS Clock Recovery none 9 0 μWRMS 10 66 Gb s none 8 0 μWRMS Clock Recovery none 9 0 μWRMS 10 71 Gb s none 8 0 μWRMS Clock Recovery none 9 0 μWRMS 10GBase W none 8 0 μWRMS Clock Recovery none 9 0 μWRMS 10GBase R none 8 0 μWRMS Clock Recovery none 9 0 μWRMS 10GBE FEC none 8 0 ...

Page 107: ...0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GBASE R 10 3125 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02...

Page 108: ... 10GFC 10 51875 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GFC FEC 11 317 Gb s Reference Receiver setti...

Page 109: ...8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10 66 Gb s Reference Receiver frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1599 8 0 11 0 96 0 74 3199 2 0 45 1 30 0 40 4798 6 1 02 1 87 0 17 6398 9 1 86 2 71 1 01 7998 0 3 00 3 86 2 16 9597 7 4 51 6 19 2 83 10664 0 5 71 7 87 3 55 11197 5 6 37 8 75 3 99 12796 9 8 54 11 53 5 56 14396 7 10 93 ...

Page 110: ...11 0 96 0 74 4208 0 45 1 30 0 40 6311 1 02 1 87 0 17 8415 1 86 2 71 1 01 10519 3 00 3 86 2 16 12623 4 51 6 19 2 83 14025 5 71 7 87 3 55 14726 6 37 8 75 3 99 16830 8 54 11 53 5 56 18934 10 93 14 45 7 41 21038 13 41 17 41 9 41 Recovered clock timing jitter 80C11 CR1 only Rate Horiz scale OC 192 20 ps none 2 psRMS Recovered clock timing jitter 80C11 CR2 only Rate Horiz scale OC 192 20 ps none 2 psRMS...

Page 111: ...iming jitter 80C11 CR4 only Rate Horiz scale OC 192 20 ps none 2 psRMS 10GBASE W 20 ps none 2 psRMS 10GBASE R 20 ps none 2 psRMS 10GFC 20 ps none 2 psRMS 10GBE 20 ps none 2 psRMS G 975 20 ps none 2 psRMS G 709 20 ps none 2 psRMS Super FEC 20 ps none 2 psRMS DSA8300 Performance Verification 93 ...

Page 112: ...W 10GBase R 10 μW 10 μW 10GBE FEC 10 μW 10 μW 10GFC 10 μW 10 μW 10GFC FEC 10 μW 10 μW 16GFC 10 μW 10 μW 20 GHz 10 μW 10 μW 30 GHz 10 μW 10 μW Vertical equivalent optical noise C1 at 100 μW OC192 8 0 μWRMS Clock 9 0 μWRMS 10 66Gb s 8 0 μWRMS Clock 9 0 μWRMS 10 71Gb s 8 0 μWRMS Clock 9 0 μWRMS 10Gbase_W 8 0 μWRMS Clock 9 0 μWRMS 10Gbase_R 8 0 μWRMS Clock 9 0 μWRMS 10GBE FEC 8 0 μWRMS Clock 9 0 μWRMS...

Page 113: ...500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GBASE R 10 3125 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 135...

Page 114: ...0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GFC FEC 11 317 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 ...

Page 115: ... Receiver frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1599 8 0 11 0 96 0 74 3199 2 0 45 1 30 0 40 4798 6 1 02 1 87 0 17 6398 9 1 86 2 71 1 01 7998 0 3 00 3 86 2 16 9597 7 4 51 6 19 2 83 10664 0 5 71 7 87 3 55 11197 5 6 37 8 75 3 99 12796 9 8 54 11 53 5 56 14396 7 10 93 14 45 7 41 15996 5 13 41 17 41 9 41 10 71 Gb s Reference Receiver frequency response dB Frequency ...

Page 116: ...5 7 41 14930 4 13 41 17 41 9 41 Clock Recovery Optical Sensitivity 80C11B CR1 ONLY Minimum Average Optical Input Power 7 5 dBm none Clock Recovery Optical Sensitivity 80C11B CR2 ONLY Minimum Average Optical Input Power 7 5 dBm none Clock Recovery Optical Sensitivity 80C11B CR3 ONLY Minimum Average Optical Input Power 7 5 dBm none Clock Recovery Optical Sensitivity 80C11B CR4 ONLY Data rate Sensiti...

Page 117: ...1B CR3 only Rate OC 192 none 2 psRMS G 709 FEC none 2 psRMS Recovered clock timing jitter 80C11B CR4 only Rate OC 192 none 2 psRMS 10GBASE W none 2 psRMS 10GBASE R none 2 psRMS 10GFC none 2 psRMS 10GBE none 2 psRMS G 975 none 2 psRMS G 709 none 2 psRMS Super FEC none 2 psRMS DSA8300 Performance Verification 99 ...

Page 118: ... X4 1 0 μW 1 0 μW VSR 5 3 318 Gb s 1 0 μW 1 0 μW 1550 nm C1 at 1 μW 9 GHz 1 0 μW 1 0 μW FC1063 1 0 μW 1 0 μW FC2125 1 0 μW 1 0 μW FC4250 1 0 μW 1 0 μW FC8500 1 0 μW 1 0 μW 10GBase X4 1 0 μW 1 0 μW 10GFC X4 1 0 μW 1 0 μW VSR 5 3 318 Gb s 1 0 μW 1 0 μW 1310 nm C1 at 1 μW 9 GHz 1 0 μW 1 0 μW FC1063 1 0 μW 1 0 μW FC2125 1 0 μW 1 0 μW FC4250 1 0 μW 1 0 μW FC8500 1 0 μW 1 0 μW 10GBase X4 1 0 μW 1 0 μW 1...

Page 119: ...none 2 5 μWRMS 1310 nm C1 at 5 μW 9 GHz none 5 0 μWRMS FC1063 none 4 0 μWRMS FC2125 none 4 0 μWRMS FC4250 none 4 0 μWRMS FC8500 none 4 0 μWRMS 10GBase X4 none 4 0 μWRMS 10GFC X4 none 4 0 μWRMS VSR 5 3 318 Gb s none 4 0 μWRMS 850 nm C1 at 5 μW 9 GHz none 8 0 μWRMS Minimum optical bandwidth Options F2 F3 F5 F6 FC 9 GHz bandwidth setting 8 5 GHz none FC1063 1 0625 Gb s Reference Receiver setting freq...

Page 120: ... 35 2869 10 93 13 55 8 31 3188 13 41 16 41 10 41 10GBASE X4 3 125 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 468 8 0 11 0 61 0 39 937 5 0 45 0 95 0 05 1406 1 02 1 52 0 52 1875 1 86 2 36 1 36 2344 3 00 3 50 2 50 2813 4 51 5 67 3 35 3125 5 71 7 25 4 17 3281 6 37 8 08 4 66 3750 8 54 10 74 6 35 4219 10 93 13 55 8 31 4688 13 41 16 41 10 4...

Page 121: ...5 0 05 1913 1 02 1 52 0 52 2550 1 86 2 36 1 36 3188 3 00 3 50 2 50 3826 4 51 5 67 3 35 4250 5 71 7 25 4 17 4462 6 37 8 08 4 66 5100 8 54 10 74 6 35 5738 10 93 13 55 8 31 6375 13 41 16 41 10 41 VSR 5 3 318 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 497 7 0 11 0 61 0 39 995 3 0 45 0 95 0 05 1493 1 02 1 52 0 52 1991 1 86 2 36 1 36 2488 ...

Page 122: ...0 μW 10GFC FEC 1 0 μW 1 0 μW 1550 nm C1 at 1 μW FC8500 1 0 μW 1 0 μW OC 192 STM 64 1 0 μW 1 0 μW 10 66 data filter 1 0 μW 1 0 μW 10 71 data filter 1 0 μW 1 0 μW 10GBase W 1 0 μW 1 0 μW 10GBase R 1 0 μW 1 0 μW 10GBE FEC 1 0 μW 1 0 μW 10GFC 1 0 μW 1 0 μW 10GFC FEC 1 0 μW 1 0 μW 1310 nm C1 at 1 μW FC8500 1 0 μW 1 0 μW OC 192 STM 64 1 0 μW 1 0 μW 10 66 data filter 1 0 μW 1 0 μW 10 71 data filter 1 0 μ...

Page 123: ... 5 0 μWRMS 10GBE FEC none 5 0 μWRMS 10GFC none 5 0 μWRMS 10GFC FEC none 5 0 μWRMS 1310 nm C1 at 5 μW FC8500 none 5 0 μWRMS OC 192 STM 64 none 8 0 μWRMS 10 66 data filter none 8 0 μWRMS 10 71 data filter none 8 0 μWRMS 10GBase W none 8 0 μWRMS 10GBase R none 8 0 μWRMS 10GBE FEC none 8 0 μWRMS 10GFC none 8 0 μWRMS 10GFC FEC none 8 0 μWRMS 850 nm C1 at 5 μW FC8500 none 8 0 μWRMS Minimum optical bandw...

Page 124: ...5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 OC 192 STM 64 9 953 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 0 45 1 30 0 40 4478 8 1 02 1 87 0 17 5972 4 1 86 2 71 1 01 7465 0 3 00 3 86 2 16 8958 0 4 51 6 19 2 83 9953 28 5 71 7 87 3 55 10451 2 6 37 ...

Page 125: ...0 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GBE FEC 11 0957 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 ...

Page 126: ...3 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10 71 Gb s Reference Receiver frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1606 6 0 11 0 96 0 74 3212 8 0 45 1 30 0 40 4819 0 1 02 1 87 0 17 6426 0 1 86 2 71 1 01 8032 0 3 00 3 86 2 16 9638 4 4 51 6 19 2 83 10709 2 5 71 7 87 3 55 11245 0 6 37 8 75 3 99 1285...

Page 127: ...bit Ethernet ENET1250 Opt F4 1 0 μW 1 0 μW FC2125 Opt F5 1 0 μW 1 0 μW OC 48 STM 16 Opt F6 1 0 μW 1 0 μW 2GBE Opt F6 1 0 μW 1 0 μW INF2500 Opt F6 1 0 μW 1 0 μW FEC2 666 Gb s FEC2666 Opt F7 1 0 μW 1 0 μW 10GBASE X4 Opt F8 1 0 μW 1 0 μW FC 3188 Opt F8 1 0 μW 1 0 μW FC4250 Opt F9 1 0 μW 1 0 μW INF5000 Opt F10 1 0 μW 1 0 μW OBSAI 6 144 Gb s Opt F11 1 0 μW 1 0 μW CPRI 7 373 Gb s Opt F12 1 0 μW 1 0 μW F...

Page 128: ...2 STM 4 Opt F2 1 0 μW 1 0 μW FC1063 Opt F3 1 0 μW 1 0 μW 1310 nm C1 at 3 μW div Gigabit Ethernet ENET1250 Opt F4 1 0 μW 1 0 μW FC2125 Opt F5 1 0 μW 1 0 μW OC 48 STM 16 Opt F6 1 0 μW 1 0 μW 2GBE Opt F6 1 0 μW 1 0 μW INF2500 Opt F6 1 0 μW 1 0 μW FEC2 666 Gb s FEC2666 Opt F7 1 0 μW 1 0 μW 10GBASE X4 Opt F8 1 0 μW 1 0 μW FC 3188 Opt F8 1 0 μW 1 0 μW FC4250 Opt F9 1 0 μW 1 0 μW INF5000 Opt F10 1 0 μW 1...

Page 129: ...2 STM 4 Opt F2 1 0 μW 1 0 μW FC1063 Opt F3 1 0 μW 1 0 μW 850 nm C1 at 3 μW div Gigabit Ethernet ENET1250 Opt F4 1 0 μW 1 0 μW FC2125 Opt F5 1 0 μW 1 0 μW OC 48 STM 16 Opt F6 1 0 μW 1 0 μW 2GBE Opt F6 1 0 μW 1 0 μW INF2500 Opt F6 1 0 μW 1 0 μW FEC2 666 Gb s FEC2666 Opt F7 1 0 μW 1 0 μW 10GBASE X4 Opt F8 1 0 μW 1 0 μW FC 3188 Opt F8 1 0 μW 1 0 μW FC4250 Opt F9 1 0 μW 1 0 μW INF5000 Opt F10 1 0 μW 1 ...

Page 130: ... μWRMS OC 12 STM 4 Opt F2 none 1 3 μWRMS FC1063 Opt F3 none 1 3 μWRMS 1550 nm C1 at 3 μW Gigabit Ethernet ENET1250 Opt F4 none 1 3 μWRMS FC2125 Opt F5 none 1 5 μWRMS OC 48 STM 16 Opt F6 none 1 5 μWRMS 2GBE Opt F6 none 1 5 μWRMS INF2500 Opt F6 none 1 5 μWRMS FEC2 666 Gb s FEC2666 Opt F7 none 1 5 μWRMS 10GBASE X4 Opt F8 none 1 5 μWRMS FC 3188 Opt F8 none 1 5 μWRMS FC4250 Opt F9 none 1 5 μWRMS INF500...

Page 131: ...M 4 Opt F2 none 1 3 μWRMS FC1063 Opt F3 none 1 3 μWRMS 1310 nm C1 at 3 μW div Gigabit Ethernet ENET1250 Opt F4 none 1 3 μWRMS FC2125 Opt F5 none 1 5 μWRMS OC 48 STM 16 Opt F6 none 1 5 μWRMS 2GBE Opt F6 none 1 5 μWRMS INF2500 Opt F6 none 1 5 μWRMS FEC2 666 Gb s FEC2666 Opt F7 none 1 5 μWRMS 10GBASE X4 Opt F8 none 1 5 μWRMS FC 3188 Opt F8 none 1 5 μWRMS FC4250 Opt F9 none 1 5 μWRMS INF5000 Opt F10 n...

Page 132: ... STM 4 Opt F2 none 2 1 μWRMS FC1063 Opt F3 none 2 1 μWRMS 850 nm C1 at 3 μW Gigabit Ethernet ENET1250 Opt F4 none 2 1 μWRMS FC2125 Opt F5 none 2 4 μWRMS OC 48 STM 16 Opt F6 none 2 4 μWRMS 2GBE Opt F6 none 2 4 μWRMS INF2500 Opt F6 none 2 4 μWRMS FEC2 666 Gb s FEC2666 Opt F7 none 2 4 μWRMS 10GBASE X4 Opt F8 none 2 4 μWRMS FC 3188 Opt F8 none 2 4 μWRMS FC4250 Opt F9 none 2 4 μWRMS INF5000 Opt F10 non...

Page 133: ...ormance test Minimum Incoming Outgoing Maximum OC 3 STM 1 155 Mb s Reference Receiver setting frequency response dB Opt F1 Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 23 3 0 11 0 61 0 39 46 65 0 45 0 95 0 05 69 98 1 02 1 52 0 52 93 3 1 86 2 36 1 36 116 7 3 00 3 50 2 50 140 0 4 51 5 67 3 35 155 5 5 71 7 25 4 17 163 3 6 37 8 08 4 66 186 6 8 54 10 74 6 35 209 9 10 93 13 55 8 31 233 3 13 41 ...

Page 134: ...3 35 1063 5 71 7 25 4 17 1116 6 37 8 08 4 66 1275 8 54 10 74 6 35 1435 10 93 13 55 8 31 1595 13 41 16 41 10 41 ENET1250 GBE 1 25 Gb s Reference Receiver setting frequency response dB Opt F4 Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 187 5 0 11 0 61 0 39 375 0 45 0 95 0 05 562 5 1 02 1 52 0 52 750 1 86 2 36 1 36 937 5 3 00 3 50 2 50 1125 4 51 5 67 3 35 1250 5 71 7 25 4 17 1312 5 6 37 8 0...

Page 135: ...0 61 0 39 746 5 0 45 0 95 0 05 1119 7 1 02 1 52 0 52 1493 1 1 86 2 36 1 36 1866 3 3 00 3 50 2 50 2239 5 4 51 5 67 3 35 2488 3 5 71 7 25 4 17 2612 8 6 37 8 08 4 66 2986 0 8 54 10 74 6 35 3359 3 10 93 13 55 8 31 3732 6 13 41 16 41 10 41 ENET2500 2 GBE 2 50 Gb s Reference Receiver setting frequency response dB Opt F6 Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 375 0 11 0 61 0 39 750 0 45 0 ...

Page 136: ...ceiver setting frequency response dB Opt F7 Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 400 0 11 0 61 0 39 799 8 0 45 0 95 0 05 1282 5 1 02 1 52 0 52 1599 8 1 86 2 36 1 36 1999 6 3 00 3 50 2 50 2399 5 4 51 5 67 3 35 2666 0 5 71 7 25 4 17 2799 4 6 37 8 08 4 66 3199 3 8 54 10 74 6 35 3528 7 10 93 13 55 8 31 3999 2 13 41 16 41 10 41 10GBASE X4 ENET3125 3 125 Gb s Reference Receiver setting ...

Page 137: ...8 08 4 65 3825 8 54 10 74 6 35 4303 10 93 13 55 8 31 4781 13 41 16 41 10 41 FC4250 4 250 Gb s Reference Receiver setting frequency response dB Opt F9 Frequency MHz Nominal response dB 0 00 0 00 0 50 0 50 637 5 0 11 0 61 0 39 1275 0 45 0 95 0 05 1913 1 02 1 52 0 52 2550 1 86 2 36 1 36 3188 3 00 3 50 2 50 3826 4 51 5 67 3 35 4250 5 71 7 25 4 17 4462 6 37 8 08 4 66 5100 8 54 10 74 6 35 5738 10 93 13 ...

Page 138: ...0 11 0 96 0 74 1843 0 45 1 30 0 40 2765 1 02 1 87 0 17 3686 1 86 2 71 1 01 4608 3 00 3 86 2 16 5530 4 51 6 19 2 83 6144 5 71 7 87 3 55 6451 6 37 8 75 3 99 7373 8 54 11 53 5 56 8234 10 93 14 45 7 41 9216 13 41 17 41 9 41 CPRI 7 373 GB s Reference Receiver setting frequency response dB Opt F12 0 00 0 00 0 85 0 85 1106 0 11 0 96 0 74 2212 0 45 1 30 0 40 3318 1 02 1 87 0 17 4423 1 86 2 71 1 01 5767 3 ...

Page 139: ...ence Receiver setting frequency response dB Opt 10GP Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 OC 192 STM 64 9 953 Gb s Reference Receiver setting frequency r...

Page 140: ...99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GBASE R 10 3125 Gb s Reference Receiver setting frequency response dB Opt 10GP Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 9...

Page 141: ...000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GFC 10 51875 Gb s Reference Receiver setting frequency response dB Opt 10GP Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17...

Page 142: ...eference Receiver frequency response dB Opt 10GP Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1606 6 0 11 0 96 0 74 3212 8 0 45 1 30 0 40 4819 0 1 02 1 87 0 17 6426 0 1 86 2 71 1 01 8032 0 3 00 3 86 2 16 9638 4 4 51 6 19 2 83 10709 2 5 71 7 87 3 55 11245 0 6 37 8 75 3 99 12851 1 8 54 11 53 5 56 14457 7 10 93 14 45 7 41 16064 4 13 41 17 41 9 41 FEC11 10 Gb s ENET11096 Reference Receiver se...

Page 143: ...b s Reference Receiver setting frequency response dB Opt 10GP Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 DSA8300 Performance Verification 125 ...

Page 144: ...1 0 μW 1 0 μW 40GBASE R4 1 0 μW 1 0 μW 100GBASE R10 1 0 μW 1 0 μW 10GFC 1 0 μW 1 0 μW FEC10 66 Gb s 1 0 μW 1 0 μW FEC10 17 Gb s 1 0 μW 1 0 μW FEC11 10 Gb s 1 0 μW 1 0 μW FC11317 1 0 μW 1 0 μW 1550 nm C1 at 3 μW div 12 GHz 1 0 μW 1 0 μW FC8500 1 0 μW 1 0 μW 8GFC 1 0 μW 1 0 μW OC 192 STM 64 1 0 μW 1 0 μW 10GBASE W 1 0 μW 1 0 μW 10GBASE R 1 0 μW 1 0 μW 40GBASE R4 1 0 μW 1 0 μW 100GBASE R10 1 0 μW 1 0...

Page 145: ... 0 μW FEC11 10 Gb s 1 0 μW 1 0 μW FC11317 1 0 μW 1 0 μW 850 nm C1 at 3 μW div 12 GHz 1 0 μW 1 0 μW Vertical equivalent optical noise FC8500 none 2 4 μWRMS 8GFC none 2 4 μWRMS OC 192 STM 64 none 2 4 μWRMS 10GBASE W none 2 4 μWRMS 10GBASE R none 2 4 μWRMS 40GBASE R4 none 2 4 μWRMS 100GBASE R10 none 2 4 μWRMS 10GFC none 2 4 μWRMS FEC10 66 Gb s none 2 4 μWRMS FEC10 17 Gb s none 2 4 μWRMS FEC11 10 Gb s...

Page 146: ...μWRMS OC 192 STM 64 none 4 0 μWRMS 10GBASE W none 4 0 μWRMS 10GBASE R none 4 0 μWRMS 40GBASE R4 none 4 0 μWRMS 100GBASE R10 none 4 0 μWRMS 10GFC none 4 0 μWRMS FEC10 66 Gb s none 4 0 μWRMS FEC10 17 Gb s none 4 0 μWRMS FEC11 10 Gb s none 4 0 μWRMS FC11317 none 4 0 μWRMS 850 nm C1 at 5 μW 12 GHz none 4 8 μWRMS Minimum optical bandwidth 12 GHz bandwidth setting 11 GHz none FC8500 8 5 Gb s Reference R...

Page 147: ... 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 OC 192 STM 64 9 953 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 0 45 1 30 0 40 4478 8 1 02 1 87 0 17 5972 4 1 86 2 71 1 01 7465 0 3 00 3 86 2 16 8958 0 4 51 6 19 2 83 9953 28 5 71 7 87 3 55 10451 2 6 37 8 75 3 99 11944 0 8 54 11 53 5 56 13437 2...

Page 148: ...0 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 40GBASE R4 10 3125 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1...

Page 149: ... 10 51875 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10 66 Gb s Reference Receiver frequency response dB ...

Page 150: ... 99 12851 1 8 54 11 53 5 56 14457 7 10 93 14 45 7 41 16064 4 13 41 17 41 9 41 FEC11 10 Gb s ENET11096 Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93...

Page 151: ...est Minimum Incoming Outgoing Maximum 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 DSA8300 Performance Verification 133 ...

Page 152: ...μW 8GFC 1 0 μW 1 0 μW OC 192 STM 64 1 0 μW 1 0 μW 10GBASE W 1 0 μW 1 0 μW 10GBASE R 1 0 μW 1 0 μW 40GBASE R4 1 0 μW 1 0 μW 100GBASE R10 1 0 μW 1 0 μW 10GFC 1 0 μW 1 0 μW FEC10 66 Gb s 1 0 μW 1 0 μW FEC10 17 Gb s 1 0 μW 1 0 μW FEC11 10 Gb s 1 0 μW 1 0 μW FC11317 1 0 μW 1 0 μW FEC12 5 Gb s 1 0 μW 1 0 μW 16GFC r6 1 1 0 μW 1 0 μW INF14063 1 0 μW 1 0 μW 1550 nm C1 at 3 μW div 14 GHz 1 0 μW 1 0 μW 134 D...

Page 153: ...W FEC12 5 Gb s 1 0 μW 1 0 μW 16GFC r6 1 1 0 μW 1 0 μW INF14063 1 0 μW 1 0 μW 1330 nm C1 at 3 μW div 14 GHz 1 0 μW 1 0 μW FC8500 1 0 μW 1 0 μW 8GFC 1 0 μW 1 0 μW OC 192 STM 64 1 0 μW 1 0 μW 10GBASE W 1 0 μW 1 0 μW 10GBASE R 1 0 μW 1 0 μW 40GBASE R4 1 0 μW 1 0 μW 100GBASE R10 1 0 μW 1 0 μW 10GFC 1 0 μW 1 0 μW FEC10 66 Gb s 1 0 μW 1 0 μW FEC10 17 Gb s 1 0 μW 1 0 μW FEC11 10 Gb s 1 0 μW 1 0 μW FC11317...

Page 154: ...one 2 4 μWRMS FEC12 5 Gb s none 2 9 μWRMS 16GFC r6 1 none 3 7 μWRMS INF14063 none 3 7 μWRMS 1550 nm C1 at 3 μW div 14 GHz none 3 7 μWRMS FC8500 none 2 4 μWRMS 8GFC none 2 4 μWRMS OC 192 STM 64 none 2 4 μWRMS 10GBASE W none 2 4 μWRMS 10GBASE R none 2 4 μWRMS 40GBASE R4 none 2 4 μWRMS 100GBASE R10 none 2 4 μWRMS 10GFC none 2 4 μWRMS FEC10 66 Gb s none 2 4 μWRMS FEC10 17 Gb s none 2 4 μWRMS FEC11 10 ...

Page 155: ... 8 μWRMS 16GFC r6 1 none 6 0 μWRMS INF14063 none 6 0 μWRMS 850 nm C1 at 5 μW 14 GHz none 6 0 μWRMS Minimum optical bandwidth 14 GHz bandwidth setting 13 GHz none 80C14 performance test Minimum Incoming Outgoing Maximum FC8500 8 5 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1275 0 11 0 96 0 74 2550 0 45 1 30 0 40 3825 1 02 1 87 0 17 51...

Page 156: ... Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1493 2 0 11 0 96 0 74 2986 0 0 45 1 30 0 40 4478 8 1 02 1 87 0 17 5972 4 1 86 2 71 1 01 7465 0 3 00 3 86 2 16 8958 0 4 51 6 19 2 83 9953 28 5 71 7 87 3 55 10451 2 6 37 8 75 3 99 11944 0 8 54 11 53 5 56 13437 2 10 93 14 45 7 41 14930 4 13 41 17 41 9 41 10GBASE W 9 95328 Gb s Reference Receiver se...

Page 157: ...9 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 40GBASE R4 10 3125 Gb s Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7...

Page 158: ...45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10 66 Gb s Reference Receiver frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1599 8 0 11 0 96 0 74 3199 2 0 45 1 30 0 40 4798 6 1 02 1 87 0 17 6398 9 1 86 2 71 1 01 799...

Page 159: ... ENET11096 Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 1500 0 11 0 96 0 74 3000 0 45 1 30 0 40 4500 1 02 1 87 0 17 6000 1 86 2 71 1 01 7500 3 00 3 86 2 16 9000 4 51 6 19 2 83 10000 5 71 7 87 3 55 10500 6 37 8 75 3 99 12000 8 54 11 53 5 56 13500 10 93 14 45 7 41 15000 13 41 17 41 9 41 10GFC FEC 11 317 Gb s FC11317 Reference Receiver setting...

Page 160: ...19 2 83 12500 5 71 7 87 3 55 13125 6 37 8 75 3 99 15000 8 54 11 53 5 56 16875 10 93 14 45 7 41 18750 13 41 17 41 9 41 16GFC r6 1 FC14025 Data Filter frequency response dB Frequency GHz Nominal response dB 0 00 0 00 0 85 0 85 1 845 0 085 0 935 0 765 3 690 0 344 1 194 0 506 5 535 0 783 1 633 0 067 7 380 1 416 2 266 0 566 9 225 2 267 3 117 1 417 10 519 3 00 4 68 1 66 11 070 3 368 5 357 1 821 12 915 4...

Page 161: ...85 1 850 0 085 0 935 0 765 3 700 0 344 1 194 0 506 5 550 0 783 1 633 0 067 7 400 1 416 2 266 0 566 9 250 2 267 3 117 1 417 10 547 3 00 4 68 1 66 11 100 3 368 5 357 1 821 12 950 4 746 7 698 2 610 14 065 5 71 9 18 3 26 14 800 6 402 10 189 3 756 16 650 8 299 12 281 5 203 18 500 10 366 15 546 6 867 20 350 12 527 18 303 8 664 21 095 13 41 19 41 9 41 DSA8300 Performance Verification 143 ...

Page 162: ... R4 10 8 μWRMS Infiniband EDR 10 8 μWRMS OTU4 11 1 μWRMS 22 0 GHz 18 6 μWRMS 28 05 GHz 11 5 μWRMS 1310 nm C1 at 50 μW 32 GHz 14 0 μWRMS 100GBase R4 13 8 μWRMS Infiniband EDR 13 8 μWRMS OTU4 15 5 μWRMS 22 0 GHz 23 5 μWRMS 28 05 GHz 15 2 μWRMS 850 nm C1 at 50 μW 32 GHz 20 0 μWRMS 25 781 GHz Filter Setting Frequency Response for 28 05 Gb s NRZ 100GBASE xR4 INF25781 Frequency GHz Nominal response dB 0...

Page 163: ...imum Incoming Outgoing Maximum 31 64 6 31 3 91 8 71 35 16 8 41 5 95 10 86 38 67 10 50 8 00 13 00 Aberrations peak to peak 22 GHz 9 100GBase R4 setting 12 OTU4 setting 13 5 Filter or bandwidth 32 GHz setting 17 DSA8300 Performance Verification 145 ...

Page 164: ...μWRMS 100GBase R4 none 28 μWRMS 1550 nm C1 at 50 μW 100GBase R4 FEC none 28 μWRMS 65 GHz none 75 μWRMS 100GBase R4 none 38 μWRMS 1310 nm C1 at 50 μW 100GBase R4 FEC none 38 μWRMS Minimum optical bandwidth 65 GHz bandwidth setting 60 GHz none 100GBase R4 25 781 Gb s ENET25781 Reference Receiver setting frequency response dB Frequency MHz Nominal response dB 0 00 0 00 0 85 0 85 3750 0 11 0 96 0 74 7...

Page 165: ... dB 0 00 0 00 0 85 0 85 3750 0 11 0 96 0 74 7500 0 45 1 30 0 40 11250 1 02 1 87 0 17 15000 1 86 2 71 1 01 18750 3 00 3 86 2 16 22500 4 51 6 19 2 83 25000 5 71 7 87 3 55 26250 6 37 8 75 3 99 30000 8 54 11 53 5 56 33750 10 93 14 45 7 41 37500 13 41 17 41 9 41 Aberrations peak to peak 65 GHz none 10 100GBase R4 none 5 Filter or bandwidth 100GBase R4 FEC none 5 DSA8300 Performance Verification 147 ...

Page 166: ... results for your 80A02 80A02 Test Record Module Serial Number Cal Certificate Number Temperature RH Date of Calibration Technician 80A02 Performance Test Minimum Incoming Outgoing Maximum Logic control threshold level Engaged LED lights 1 V 5 V Disengaged LED does not light 0 V 300 mV 148 DSA8300 Performance Verification ...

Page 167: ... 10 mV none Rate Infiniband Horz Scale 100 ps 10 mV none Rate PCI Express Horz Scale 100 ps 10 mV none Rate 2 5 G G 709 FEC Horz Scale 100 ps 10 mV none Rate Serial ATA 3 00 Gb s Horz Scale 100 ps 15 mV none Rate XAUI 3 125 Gb s Horz Scale 100 ps 15 mV none Rate FibreChannel Horz Scale 100 ps 15 mV none Rate VSR5 Horz Scale 100 ps 15 mV none Rate 4 Gigabit FibreChannel Horz Scale 100 ps 15 mV none...

Page 168: ...Horz Scale 100 ps none 4 ps Rate Serial ATA 3 00 Gb s Horz Scale 100 ps none 2 5 ps Rate XAUI 3 125 Gb s Horz Scale 100 ps none 2 5 ps Rate FibreChannel Horz Scale 100 ps none 2 5 ps Rate VSR5 Horz Scale 100 ps none 2 5 ps Rate 4 Gigabit FibreChannel Horz Scale 100 ps none 2 5 ps Rate Serial ATA 6 00 Gb s option 10G Horz Scale 50 ps none 2 ps Rate XAUI 6 25 Gb s option 10G Horz Scale 50 ps none 2 ...

Page 169: ...u bar at the top of the screen These procedures assume you will display and dismiss the setup dialog boxes as needed NOTE The procedures throughout this chapter contain instructions based on the menus and controls from the most updated instrument software available at the time this document was released These procedures will work for other versions of software but some control and menu names may v...

Page 170: ...ors 4 Connect one of the 0 5 meter cables to Channel 1 of the 80E0X module Connect the remaining 0 5 meter cable to the TRIGGER DIRECT INPUT 5 Set the synthesized signal generator frequency to 1 GHz 6 Set the Synthesized output to 800 mVp p 400 mV displayed 7 Set up the instrument as follows a Push the Default Setup front panel button and click Yes b Select C1 from the Waveform Selector menu on th...

Page 171: ...generator level until the amplitude measurement readout on the instrument screen is 400 mV 11 Verify that the period measurement readout value is 1 ns 9 ps Record the value in the Time Interval Accuracy Trigger Direct Input connector test record field 12 Click the HORZ tab set the Horizontal Position field to 100 ns and verify that the period measurement readout value is 1 ns 9 ps Record the value...

Page 172: ...y set the Position field to 19 ns 29 ns if using 80E07B 80E08B 80E09B or 80E10B 22 Repeat steps 11 through 13 Record the value in the Time Interval Accuracy Clock Input Prescale Trigger connector Other mode test record field End of Procedure External Trigger Direct Level Accuracy Equipment required See Table 1 0 5 meter precision SMA cable item 15 1 0 meter precision SMA cable item 16 Power divide...

Page 173: ... Selector menu left end of controls bar at bottom of the graticule c ClickSetup Mode Trigger and select Direct for Trigger Source d Click the Vert tab and set the following Scale to 100 mV div Offset to 0 e Click the Horz tab and set the following Scale to 5 ns division Position to the minimum possible value Horizontal Reference to 0 Test Follow this procedure to make the direct trigger level accu...

Page 174: ...d that the waveform position changes by 4 6 ns to 5 4 ns 9 Set the slope to Rising and close the Advanced Trigger Setup dialog box 10 In the Mode Trigger Setup dialog box adjust the Direct trigger Level field from 100 mV to 100 mV Verify the waveform position changes between 625 ps and 1 ns as the level is changed between 100 mV to 100 mV With positive slope the waveform shifts to the right End of...

Page 175: ...2 5 GHz 400 ps period Output to 400 mVp p 200 mV displayed 4 Set the DSA8300 as follows a Push the Default Setup front panel button and click Yes b Select C1 from the Waveform Selector menu left end of controls bar at bottom of the graticule c Select Setup Mode Trigger and select Direct for Trigger Source d Click the Vert tab and set the following Scale to 20 mV div Offset to 0 e Click the Horz ta...

Page 176: ...nerator frequency to 100 MHz 13 Adjust the Horizontal SCALE knob to display at least two full periods 14 Verify that the frequency readout value is within 10 of the true value 15 Set the signal generator frequency to each of the following values adjust the horizontal scale to the corresponding seconds div setting and repeat steps 13 and 14 800 MHz at 500 ps div 1 GHz at 500 ps div 2 GHz at 200 ps ...

Page 177: ...ut to 1 6 Vp p 800 mVp p displayed 4 Set the DSA8300 as follows a Push the Default Setup front panel button and click Yes b Select C1 from the Waveform Selector menu left end of controls bar at bottom of the graticule c Click Setup Mode Trigger and select Direct for the Trigger Source d Click the Vert tab and set the following Scale to 100 mV div Offset to 0 e Click the Horz tab and set the follow...

Page 178: ...he instrument will select whichever of the two databases that is not in use Turn on Display Database for the database that shows the current channel in the Source box Deselect Database On for the other database 14 Set the Horizontal Scale to 5 ps div and position the rising edge until it goes through the center of the display where the center horizontal and vertical graticules cross 15 Set the Ver...

Page 179: ...p After to Condition in the Acq tab 29 Push CLEAR DATA push RUN STOP and wait for the instrument to stop acquisition 30 Verify that the RMS Jitter measurement is less than 11 5 ps 31 Move the signal source cable to the next module under test Repeat from step for all 80E00 series modules installed Check one input per module for example channels 1 and 3 if two modules are installed 32 In Acq Setup d...

Page 180: ...ized signal generator as follows Frequency to 10 0 GHz Output to 1 6 Vp p 800 mVp p displayed 5 Set the DSA8300 as follows a Push the Default Setup front panel button and click Yes b Select the input channel of the module under test from the Waveform Selector menu left end of controls bar at bottom of the graticule c Select Setup Mode Trigger and set the Trigger Source to Free Run Untriggered Phas...

Page 181: ...ton 9 Make sure the channel under test is selected in the Source tab 10 Click the Pulse button Signal Type area 11 Click Select Meas Pulse Timing RMS Jitter Dismiss any database notification messages that are displayed 12 Verify that Use Wfm Database is selected in the Source tab area if not select it 13 Click the Wfm Database tab and select Display in the Database area NOTE The instrument will se...

Page 182: ...nt does not have a guaranteed specification 19 Move the signal source cable to the next module under test Repeat from setup step for each 80E00 series modules installed Check one input per module for example channels 1 and 3 if two modules are installed 20 Disconnect the test setup End of Procedure Trigger Delay Jitter External Triggered Phase Corrected Mode Clock Eye Equipment required See Table ...

Page 183: ...al generator as follows Frequency to 10 0 GHz Output to 1 6 Vp p 800 mVp p displayed 5 Set the DSA8300 as follows a Push the Default Setup front panel button and click Yes b Select the input channel of the module under test from the Waveform Selector menu left end of controls bar at bottom of the graticule c Click the Mode Trigger tab and set the following Trigger Source to Clock and clock type to...

Page 184: ...selected in the Source tab 5 Click the Pulse button Signal Type area 6 Click Select Meas Pulse Amplitude Amplitude 7 Select Meas 2 8 Click the Source1 button 9 Make sure the channel under test is selected in the Source tab 10 Click the Pulse button Signal Type area 11 Click Select Meas Pulse Timing RMS Jitter Dismiss any database notification messages that are displayed 12 Verify that Use Wfm Data...

Page 185: ...value on the Test Record for the module under test Typical values are 200 fs or less This measurement does not have a guaranteed specification 19 Move the signal source cable to the next module under test Repeat from setup step for each 80E00 series modules installed Check one input per module for example channels 1 and 3 if two modules are installed 20 Disconnect the test setup unless you are pro...

Page 186: ...signal generator as follows Frequency to 2 5 GHz Output to 1 6 Vp p 800 mVp p displayed 4 Set the DSA8300 as follows a Push the Default Setup front panel button and click Yes b Select the input channel of the module under test from the Waveform Selector menu left end of controls bar at bottom of the graticule c Select Setup Mode Trigger tab and set the following Trigger Source to Clock Click the E...

Page 187: ...e Amplitude 7 Verify that Use Wfm Database is selected in the Source tab area if not select it 8 Select Meas 2 9 Click the Source1 button 10 Make sure the channel under test is selected in the Source tab 11 Click the Pulse button Signal Type area 12 Click Select Meas Pulse Timing RMS Jitter Dismiss any database notification messages that are displayed 13 Verify that Use Wfm Database is selected in...

Page 188: ...is less than 500 fs 19 Click the Mode Trigger tab and set the Scope Mode to Other 20 Reposition the zero crossing rising edge to the middle of the screen 21 Verify that the RMS Jitter measurement readout value is less than 1 4 ps End of Procedure External Clock Prescale Trigger Sensitivity Equipment required See Table 1 0 5 meter precision SMA cable item 15 1 0 meter precision SMA cable item 16 Po...

Page 189: ... the graticule c Select Setup Mode Trigger and set the following Trigger Source to Clock Click the Eye button Scope Mode area d Click the Vert tab and set the following Scale to 50 mV div Offset to 0 e Click the Horz tab and set the following Scale to 200 ps div Horizontal Reference to 0 Position to 20 ns set to 29 ns for 80E07B 80E08B 80E09B and 80E10B Test Follow this procedure to make the Exter...

Page 190: ...sage 14 Adjust the Horizontal Scale knob to display two complete waveform periods on the screen 15 Verify that the DSA8300 Frequency readout value is within 10 of the true input signal value 16 Repeat steps 12 through 15 for each frequency and level setting 17 Disconnect the test setup End of Procedure DC Calibration Output Equipment required See Table 1 SMA female to BNC male connectors item 3 BN...

Page 191: ... box 4 Select Setup Mode Trigger and click Direct trigger mode 5 Set the multimeter to read DC volts Test Follow this procedure to make the DC calibration output check 1 Select Setup Vertical 2 Set the DC Cal parameter to each of the following settings and record the DMM readings in the test record 1 0 V 0 0 V 1 0 V 3 Check the readings against the limits in the test records 4 Disconnect the test ...

Page 192: ...nd channel 2 buttons and observe that the yellow indicator lights turn on Push them again and observe that the lights turn off Note that there are two push buttons per channel on the 80E07B 80E08B 80E09B and 80E10B one on the main module and one on the remote head Check both of these NOTE Use a calibrated torque wrench when connecting the terminators adapters attenuator and power sensor in this se...

Page 193: ... impedance test setup 1 Install the 80E0X module into the left most small module slot of the instrument 2 Connect the Digital multimeter to Channel 1 of the 80E0X module as shown in the figure 3 Set the DSA8300 as follows a Select C1 from the Waveform Selector menu on the controls bar at the bottom of the display left corner b In the Mode Trigger dialog box select TDR 200 kHz c In the Vert Setup d...

Page 194: ... and 49 Ω 5 80E04 Only Set the Digital multimeter to measure Volts at the minimum range 100 mV 6 80E04 Only Record reading on the Digital multimeter as baseline voltage 7 80E04 Only Check baseline voltage for 1 mV Enter value on test record 8 Make the following settings and then repeat steps 1 through 7 to check channel 2 a Select the next channel to test if any from the Waveform Selector menu on ...

Page 195: ...item 19 Prerequisites See page 16 Prerequisites See page 174 Prerequisites WARNING Improper operation of the DC Power Supply may create a shock hazard CAUTION To avoid damage to the electrical module do not exceed 2 volts input Setup Figure 16 Vertical DC accuracy test setup 1 Perform instrument and module compensation See page 3 Instrument and Module Compensation 2 Set the output of a DC power su...

Page 196: ...t Trigger Source to TDR c In the Acq Setup dialog box Set Acquisition Mode to Average and 32 samples Under Stop After select the Condition box and select Average Complete from the pull down menu d In the Horz Setup dialog box Set Scale to 2 ns div Set Position to 0 this will automatically change to a minimum non zero value Set Horizontal Reference to 0 e In the Meas Setup dialog box Select Meas 1 ...

Page 197: ...mV 0 mV 7 mV 450 mV 0 mV 11 mV 650 mV 1100 mV 18 7 mV 850 mV 1100 mV 14 7 mV 1100 mV 1100 mV 9 7 mV 1350 mV 1100 mV 14 7 mV 80E01 80E02 80E03 80E04 80E06 1550 mV 1100 mV 18 7 mV 1050 mV 600 mV 15 2 mV 850 mV 600 mV 11 2 mV 600 mV 600 mV 6 2 mV 350 mV 600 mV 11 2 mV 150 mV 600 mV 15 2 mV 450 mV 0 mV 11 mV 250 mV 0 mV 7 mV 0 mV 0 mV 2 mV 250 mV 0 mV 7 mV 450 mV 0 mV 11 mV 150 mV 600 mV 15 2 mV 350 m...

Page 198: ...record 8 Repeat steps 1 through 7 until all DC voltage and offset settings listed in the table are checked for the channel under test See Table 2 9 Change all settings in the setup to Channel 2 and then repeat steps 1 through 7 until all DC voltage settings and offset settings are checked See Table 2 End of Procedure Test Follow this procedure to make the DC vertical voltage accuracy single point ...

Page 199: ...wer supply Vin 450 mV 3 Record the DVM measurement in the Input Vin and the x columns as shown in the following table 4 Read mean measurement and record it in the Measured V mV and y columns as shown in the following table 5 Repeat steps 2 to 3 for all other Vin 6 Calculate Sx Sxx Sy and Sxy for each setting a Copy the Input Vin value to the x column b Copy the Measured V mV value to the y column ...

Page 200: ...11X1 and then repeat steps 1 through 9 until all DC vertical voltage accuracy single point compensated calculations listed in the table are checked See Table 3 11 Disconnect the test setup End of Procedure Random Noise Displayed These procedures check those characteristics that relate to the signal acquisition and are listed as checked in the DSA8300 Digital Serial Analyzer Specifications manual E...

Page 201: ...e minimum non zero value Set Horizontal Reference to 0 f In the Vert Setup dialog box Set Scale to 2 mV div if testing with an 80E01 or 80E06 module set to 1 mV div for all other modules Set Offset to 0 mV Set Bandwidth to the maximum setting module dependant Test Follow this procedure to make the Random noise checks 1 In the Wfm Database Setup dialog box click Display and set Source to C1 on Main...

Page 202: ...11 80E11X1 30 GHz 480 μV 10 Repeat steps 1 through 8 for each bandwidth setting 11 Repeat steps 1 through 8 for channel 2 End of Procedure Analog Bandwidth up to 50 GHz 80E01 80E06 80E07B 80E08B 80E09B 80E10B 80E11 80E11X1 These procedures check those characteristics that relate to the signal acquisition and are listed as checked in the DSA8300 Digital Serial Analyzer Specifications manual This ch...

Page 203: ...rence NOTE Use a torque wrench when connecting the terminators adapters attenuator and power sensor in this setup Use 8 0 3 inch pounds of torque 1 Connect the 10 dB attenuator to the Synthesized signal generator Connect the remaining end to the power sensor Connect the power sensor to the power meter Figure 17 Power reference setup Reference Characterization Measurements Follow this procedure to ...

Page 204: ...female adapter loss dB 50 MHz 4 GHz 8 GHz 12 GHz 16 GHz 20 GHz 24 GHz 28 GHz 30 GHz 32 GHz 36 GHz 40 GHz 44 GHz 48 GHz 50 GHz 3 Record the readings on the power meter in the Reference Level dBm column 1 You only need to characterize the frequency up to the maximum bandwidth of the module under test 186 DSA8300 Performance Verification ...

Page 205: ...ter Adapter Characterization Measurements Follow this procedure to characterize the reference level with the adapters 1 Set the signal frequency and the power meter frequency to each of the frequencies listed in the Frequency column of the table See Table 5 NOTE You only need to characterize the reference level up to the maximum bandwidth of the module under test 2 Record the readings on the power...

Page 206: ...the 10 dB attenuator 2 Connect the other end of the 10 dB attenuator to a 2 4 mm female to female adapter 3 Connect the other end of the 2 4 mm female to female adapter to the power sensor 4 Connect the power sensor to the power meter 5 Set the synthesized signal generator to 3 dBm 6 Set the signal frequency and the power meter frequency to each of the frequencies listed in the Frequency column of...

Page 207: ...he Rfrnce RF level in the following table for all frequencies listed as follows See Table 5 Rfrnce RF level Measured RF level 2 4mm female to female adapter loss dB Table 6 DUT device under test reference response 80E01 80E06 80E07B 1 Measured level 80E07B Frequency Rfrnce set level dBm Measured RF level dBm Rfrnce RF level 80E01 80E06 20 30 DUT resp 50 MHz 4 GHz 8 GHz 12 GHz 16 GHz 20 GHz 24 GHz ...

Page 208: ...09B 80E10B Frequency Rfrnce set level dBm Measured RF level dBm Rfrnce RF level 20 30 30 40 60 30 40 50 DUT resp 50 MHz 4 GHz 8 GHz 12 GHz 16 GHz 20 GHz 24 GHz 28 GHz 30 GHz 32 GHz 36 GHz 40 GHz 44 GHz 48 GHz 50 GHz 1 Only perform checks up to the maximum bandwidth of the module under test 190 DSA8300 Performance Verification ...

Page 209: ...z 16 GHz 20 GHz 24 GHz 28 GHz 30 GHz 32 GHz 36 GHz 40 GHz 44 GHz 48 GHz 50 GHz 1 Only perform checks up to the maximum bandwidth of the module under test Setup Figure 20 Reference signals setup 1 Install the module into the left most small module compartment of the main instrument 2 Connect one end of the cable to the Synthesized signal generator Connect the other end of the cable to the 10 dB att...

Page 210: ...n zero value Set Horizontal Reference to 0 f In the Vert Setup dialog box Set Scale to 35 mV div Set Offset to 0 Test Follow this procedure for the sampling module reference signals 1 In the Meas Setup dialog box a Select Meas 1 and make sure the Source1 button is selected b Make sure the channel under test is selected in the Source tab click the Pulse Signal Type button and then choose Select Mea...

Page 211: ...as Measured level Reference RF level Record the calculation results in the DUT Response column of the table See Table 8 12 Calculate all frequencies listed in the Frequency column of the table See Table 8 13 Find the maximum and minimum power points in the DUT Response column of the table See Table 8 14 The maximum power minus the power at 50 MHz should be less than 3 0 dB The minimum power minus ...

Page 212: ...14 Cable coaxial SMA item 15 Cable BNC item 17 Scalar network analyzer SNA item 42 Reflectometer with OML DC power cable to dual banana plug item 44 Power meter item 45 Waveguide power sensor item 46 Adapter Wave Guide to 1 85 mm male item 51 Adapter Wave Guide to 1 85 mm female item 52 Waveguide section item 53 80N01 or 80X02 Module Extender item 55 Prerequisites See page 16 Prerequisites See pag...

Page 213: ...Electrical Sampling Modules Figure 21 Setup to measure Power in DSA8300 Performance Verification 195 ...

Page 214: ...one end of a Waveguide section to the DUT port of the Reflectometer g Connect the Waveguide short directly to the remaining end of the Waveguide 2 Set the SNA as follows Output level 9 dBm Frequency Multiplier 4 Frequency Span 50 GHz to 65 GHz No of Averages 8 Leveling External Channel 1 Off Channel 2 Input B Channel 2 Meas Mode Return Loss 3 Push the Calibration key to start calibrating the SNA t...

Page 215: ...e above figure as you perform the following substeps a Start with the test setup as was left from step 6 b Remove the Waveguide short from the Waveguide section c Connect the Waveguide power sensor directly to the Waveguide section d Connect the attached cable of the Waveguide power sensor to the Ch B input of the Power meter 2 On the SNA recall the Setup Cal from Memory Location 2 3 Set the SNA F...

Page 216: ...apters 1 Refer to the following figure as you perform the following substeps a Start with the test setup as left from step 5 in the last procedure b Disconnect the Waveguide power sensor from the Waveguide section c Connect the 1 85 mm end of a Waveguide to 1 85 mm female adapter to the 1 85 mm end of a Waveguide to 1 85 mm male adapter d Install the set of combined adapters between the Waveguide ...

Page 217: ... a Set the signal frequency and the power meter frequency to each of the frequencies listed in the Frequency column of the table See Table 9 NOTE Only perform checks up to the maximum bandwidth of the module under test b Turn Trace Hold on the SNA to On DSA8300 Performance Verification 199 ...

Page 218: ...e wrench when connecting the terminators adapters attenuator and Waveguide power sensor in this setup Use 8 0 3 inch pounds of torque 1 Refer to the following figure as you perform the following substeps a Start with the remainder of the test setup from step 3 in the last procedure b If testing an 80E06 install the 80N01 or 80X01 Extender Cable in the leftmost slot of the main instrument and conne...

Page 219: ...Waveform Selector menu on the controls bar at the bottom of the display left corner c In the Mode Trigger dialog box set Source to TDR 200 kHz d In the Acq Setup dialog box Set Acquisition Mode to Envelope Under Stop After check Condition and select Number of Acquisitions from the pull down menu Set the Number of Acquisitions count to 64 DSA8300 Performance Verification 201 ...

Page 220: ... the SNA recall the Setup Cal from Memory Location 2 4 Set the SNA Frequency Span to 0 Hz to set the SNA to single frequency mode 5 Perform the following substeps a Set the SNA signal frequency to the first of the frequencies listed in the Frequency column of the table See Table 9 b Turn Trace Hold on the SNA to On c Push the CLEAR DATA front panel button on the main instrument d Push the RUN STOP...

Page 221: ...e following table 7 Find the maximum and minimum power points between the 50 MHz and 65 GHz points in the Response column as shown in the following table Table 9 Bandwidth response 55 GHz 65 GHz 80E09B response Frequency1 Reference level no adapters Reference level with adapters Adapter loss Measured level 80E06 response 30 40 60 55 GHz 60 GHz 65 GHz 1 Only perform checks up to the maximum bandwid...

Page 222: ... 49 Prerequisites See page 16 Prerequisites See page 174 Prerequisites Setup 1 Connect a coaxial short to the female connector of the airline as shown in the following figure 2 Connect the airline to channel 1 of the module Figure 25 TDR reflected rise time setup 3 Push the DEFAULT SETUP front panel button and click Yes 4 Set up the main instrument as follows a In the TDR Setup dialog box click Pr...

Page 223: ...lick the Pulse Signal Type button and then choose Select Meas Pulse Timing Fall Time Test Follow this procedure to make the fall time checks 1 Push the CLEAR DATA front panel button 2 Push the RUN STOP front panel button 3 Check that the measured fall time reflected rise time for the positive edge polarity is as follows 80E04 35 ps 80E08B 22 ps 80E10B 16 ps 4 In the TDR Setup dialog box change C1 ...

Page 224: ...aracteristics that relate to the TDR system and are listed as checked in the DSA8300 Digital Serial Analyzer Specifications manual Equipment required See Table 1 Terminator 50 Ω coaxial terminator K male item 28 Prerequisites See page 16 Prerequisites See page 174 Prerequisites Setup Figure 26 TDR system step response aberrations setup 1 Install the module into the left small module compartment of...

Page 225: ...ue in mr making sure to take down the proper sign This will be used as HiRef the high reference level for aberration measurements Test Follow this procedure to make the aberration checks 1 Check aberrations in the range of 10 ns to 20 ps before the edge aberrations within 3 a Set the Horizontal Position to 0 or to the minimum value possible b Change the Horizontal Scale to 50 ps div while adjustin...

Page 226: ...The Max and Min measurements are now set to include the region of 250 ps to 20 ps before the edge The aberration specification over this region is 3 which is 30 mρ for a 1 ρ step Since the reference is 1 ρ the Max and Min values should be within 1 030 to 0 970 ρ to meet the 3 specification i Calculate and take down for later use the peak aberrations in percent using the formulas with Max and Min i...

Page 227: ...ing data on the Test Record enter the largest positive or negative value 2 Check aberrations in the range of 400 ps to 5 ns after the edge aberrations within 3 a Change the Horizontal Scale to 50 ps div while adjusting Horizontal Position to keep the rising edge of the step waveform centered on the display b Push the front panel FINE button to turn it on c Adjust the Horizontal Position knob so th...

Page 228: ... Scale to 10 ns div b Adjust Horizontal Position so waveform rising edge is at the second vertical graticule assuming that first graticule is the left edge of display c In the Meas Setup dialog box for Meas2 set Gate G1 to 15 d In the Meas Setup dialog box for Meas1 set Gate G1 to 15 e The Max and Min measurements are now set to include the region of 5 ns to 90 ns after the edge The aberration spe...

Page 229: ...r channel 2 both polarities End of Procedure TDR System Step Response Aberrations 80E08B and 80E10B These procedures check those characteristics that relate to the TDR system and are listed as checked in the DSA8300 Digital Serial Analyzer Specifications manual Equipment required See Table 1 Terminator 50 Ω coaxial terminator K male 80E08B only item 28 Terminator 50 Ω coaxial terminator V male 80E...

Page 230: ...for later use the High reference and Low reference measurement values in mρ making sure to take down the proper sign This will be used as HiRef and LoRef the high and low reference levels for aberration measurements Test Follow this procedure to make the aberration checks 1 Check aberrations in the range of 10 ns to 20 ps before the edge aberrations within 1 a Set the Horizontal Position to its mi...

Page 231: ... the Meas Setup dialog box Select Meas 2 and make sure the Source1 button is selected Make sure the channel under test is selected in the Source tab click the Pulse Signal Type button and then choose Select Meas Pulse Amplitude Amplitude and then click the On box Select the Region tab Set Gate G1 to 0 Set Gate G2 to 46 Set Gates On select h Calculate and take down for later use the peak aberration...

Page 232: ...kHz using the drop down menu c Select the TDR tab in the menu dialog box In the Preset column select C1 or whichever channel your module is on d Select the Measurement tab Set up Meas1 Meas2 and Meas3 as follows Meas1 Choose Select Meas Pulse Amplitude Overshoot Meas2 Choose Select Meas Pulse Amplitude Pk Pk Meas3 Choose Select Meas Pulse Amplitude Amplitude e Click the MATH front panel button Cre...

Page 233: ...e division in from the left edge of the screen m Push the front panel FINE button to turn it off n In the Horizontal Setup dialog box set Horizontal Reference to 10 o Select the following measurements from the Setup dialog box menu and set them up as follows Meas1 Select the Region tab and set G1 to 10 approximately 50 edge crossing threshold G2 to 40 150 ps and select the Gates On box Meas2 Selec...

Page 234: ...Scale knob b Set Meas1 and Meas2 as follows Meas1 Select the Region tab and set G1 to 14 400 ps and G2 to 60 5 ns Meas2 Select the Region tab and set G1 to 14 400 ps and G2 to 60 5 ns c Check that the TDR incident edge aberrations in the range of 400 ps to 5 ns after the edge are within specification Aberration Upper Spec limit USL Meas1 Overshoot C1 2 Aberration Lower Spec limit LSL Meas4 Mean M1...

Page 235: ...pec limit LSL Meas4 Mean M1 2 6 Check aberrations in the range of 100 ns after the edge aberrations within 1 a Change the time div to 500 ns div using the Horizontal Scale knob b Set Meas1 and Meas2 as follows Meas1 Select the Region tab and set G1 to 2 100 ns and G2 to 100 5 μs Meas2 Select the Region tab and set G1 to 2 100 ns and G2 to 100 5 μs c Check that the TDR incident edge aberrations in ...

Page 236: ... after selecting TDR Preset in Setup step 4 a under TDR System Step Response Aberrations 80E04 No other changes to the procedures are needed since in rho ρ mode the display does not invert when the TDR edge polarity is changed 8 Repeat the Setup and Test procedures for channel 2 both polarities End of Procedure 218 DSA8300 Performance Verification ...

Page 237: ...ased These procedures will work for other versions of software but some control and menu names may vary slightly Dark Level and Vertical Equivalent Optical Noise This procedure checks the dark level which is the offset in the optical channel caused by thermal variations or finite leakage current This procedure also checks the vertical equivalent optical noise The checks are made with vertical offs...

Page 238: ...owing step click the Basic button in the lower left part of the Vert Setup dialog box 7 In the Vert Setup dialog box do the following a Set the Scale to one of the following values 100 μW div for 80C01 80C02 80C04 80C05 80C09 80C11 and 80C11B Optical Sampling Modules 5 μW div for 80C03 80C07 and 80C07B Optical Sampling Modules 200 μW div for 80C06 80C10 80C10B 80C10C 80C15 or 80C25GBE Optical Samp...

Page 239: ...click OK to the message box that appears 6 Wait until the compensation is completed hour glass cursor reverts back to arrow cursor It is recommended that you store this compensation result in the module as the Stored User values To store the compensation results in the module do the following procedure a In the Select Action section of the Compensation dialog box select Save b In the Storage secti...

Page 240: ...ck the Optical button if not already in the optical settings to access the filter and bandwidth settings for the optical sampling module you are testing End of Procedure Minimum Optical Bandwidth and Reference Receiver Frequency Response Before performing the checks for minimum optical bandwidth and reference receiver frequency response you need to have an understanding of what optical bandwidth i...

Page 241: ...ler already represents Optical Power in its linear form as opposed to having to square the voltage and divide by R For the optical sampling modules then the bandwidth where the displayed optical power is one half that approaching DC is The Vf in such a system is one half 0 5 the VDC as opposed to 0 707 The optical bandwidth therefore corresponds to the traditional electrical bandwidth at 6 dB Duri...

Page 242: ...tors item 8 Single mode fiber optic cable 2 m FC to FC connectors item 13 Cable coaxial 1 m male to male SMA connectors item 16 Variable optical attenuator Tektronix OA5002 item 21 Optical impulser Calmar FPL 01 item 22 Optical sampling module 80C01 80C09 80C11 80C11B 80C12 80C12B 80C14 and 80C15 Prerequisites See page 16 Prerequisites See page 219 Prerequisites Before performing this procedure be...

Page 243: ...Connect a 50 Ω coaxial cable from the rear trigger SYN on the optical impulse generator to the TRIGGER DIRECT input on the instrument 6 Start with about 30 dB of attenuation on the variable attenuator NOTE To avoid dispersing the narrow optical impulse signal keep all fiber lengths as short as possible Lengths that are 2 to 3 meters long are acceptable 7 Push the SELECT ON OFF button on the 80C0X ...

Page 244: ...do the following a Set the Style to Normal b Click Show Vectors 12 In the Vert Setup dialog box do the following NOTE If the Scale Position and Channel Offset control boxes are not displayed in the following step click the Basic button in the lower left part of the Vert Setup dialog box a Set the Scale to 500 0 μW div or a lower setting if 500 0 μW is not available b Set Position to 0 0 div c Set ...

Page 245: ...side of the display 13 Use the Horizontal POSITION knob to position the impulse at the first horizontal division as shown in the following figure This ensures that post impulse aberrations are included in the record 14 Adjust the attenuation of the variable optical attenuator as follows If you are testing an 80C01 80C02 80C04 80C09 or 80C11 or 80C11B Optical Sampling Module adjust it until it prod...

Page 246: ...u may experience signal jitter if you try to display a signal that is not the first impulse and is late in relation to time zero 2 Adjust the Horizontal SCALE knob so that the width of the impulse at its base is approximately 1 4 to 3 4 of a horizontal division on the display as shown in the following figure NOTE If the width of the impulse is much greater than 3 4 of a horizontal division the res...

Page 247: ...d 8 Repeat steps 1 through 7 for the remaining bandwidth settings for the optical module under test refer to the module test record 9 In the Vert Setup dialog box select a Filter see the test record for filters available for the optical sampling module under test 10 Do steps 1 through 6 11 Refer to the module test record and check that the optical sampling module meets the limits listed for the te...

Page 248: ... line width and high side mode suppression ratio 50 dB that result in single frequency emission The lasers must have an absolute wavelength accuracy of 1 pm where the wavelength of the sweep laser is measured during the sweep using a high precision optical wavelength meter 1 The sweep laser must be mode hop free over the sweep range The lasers must be matched to each other for polarization and pow...

Page 249: ... is repeatedly flexed over time 3 Connect a PM fiber optic cable between the OPTICAL output of the Laser 1 and the PM splitter Connect the input of the PM splitter to the OPTICAL output of laser 1 4 Connect the 5 output of the PM splitter to the wavelength meter connect the other output of the PM splitter to the PM coupler 5 Connect a PM fiber optic cable between the OPTICAL output of the Laser 2 ...

Page 250: ...module under test is 1 75 2 mW each this setting results in a modulation amplitude of 7 8 mW 8 Push the DEFAULT SETUP button on the instrument front panel Click Yes in the dialog box that appears 9 Select C1 for the waveform source use the waveform selector button in the lower left corner of the application display 10 In the Mode Trigger dialog box set the Trigger Source to TDR Use the default 200...

Page 251: ... point at 1550 nm a Adjust laser wavelengths to within 0 5 pm of each other by monitoring the beat note directly on the real time scope See Figure 31 b Adjust laser wavelengths until the beat frequency is 150 MHz and record the frequency fDC This is the DC reference point 2 For Vertical scale a Set the vertical position to 0 b Record the mean and peak to peak value from the histogram statistics c ...

Page 252: ...d deviation from the histogram statistics σi f Record the wavelength of the sweep laser λi 5 Record background standard deviation due to laser and sampling module noise a Set laser detuning to 750 GHz b Push Clear Data c Acquire a histogram with 250 000 hits d Record the standard deviation from the histogram statistics σb 6 Calculate the normalized frequency response curve a The frequency values a...

Page 253: ... filters available for the 80C10 80C10B or 80C10C module End of Procedure Integrated Rise Time and Aberrations Check This procedure checks the integrated rise time of an 80C06 Optical Sampling Module and the aberrations of an 80C05 80C06 80C10 80C10B 80C10C 80C15 or 80C25GBE Optical Sampling Module NOTE To optimize performance make sure that all connections are clean and secure and that all compon...

Page 254: ... to the TRIGGER DIRECT INPUT on the instrument 5 Start with about 30 dB of attenuation on the variable attenuator NOTE To avoid dispersing the narrow optical impulse signal keep all fiber lengths as short as possible Lengths that are 2 to 3 meters long are acceptable Figure 33 Integrated rise time and aberrations setup 6 Push the SELECT ON OFF button on the optical sampling module so that the adja...

Page 255: ...e Scale to 500 0 μW div b Set Position to 0 0 div c Set Channel Offset to 0 0 W d Click the Optical button in the lower left part of the Vert Setup dialog box e Set Wavelength to 1550 nm f Set the Bandwidth to 40 GHz for 80C05 50 GHz for 80C06 65 GHz for 80C10 80C10B F1 80C10C F1 or 80C25GBE 80 GHz for 80C10B 80C10C 32 GHz for 80C15 12 Use the Horizontal POSITION knob to position the impulse at th...

Page 256: ...80C10B 80C10C 80C15 or 80C25GBE module skip steps 22 and 23 22 Select the Meas Setup dialog box and make the following changes a Select Meas 2 and make sure the Source1 button is selected b In the Source tab area select M1 on Main click the Pulse button and then choose measurement Select Meas Pulse Timing Rise Time c Make sure the Meas 2 ON check box is selected 23 Set the bandwidth and note the r...

Page 257: ...0C15 or 80C25GBE increase G1 until it is 15 ps after the 50 point of the rising edge Move G2 until the time difference between G1 and G2 is 10 times the rise time from the rising edge See the following table for the time difference between G1 and G2 for the different bandwidth and filter settings Table 10 Minimum limits Optical sampling module Bandwidth filter setting Time difference 40 GHz G2 G1 ...

Page 258: ... 192 ps 10 x 19 2 ps 26 To calculate the Time Domain Vertical Response Aberrations divide Measurement 4 by Measurement 3 and multiply by 100 The aberration limits for the 80C05 80C06 80C10 80C10B 80C10C 80C15 and 80C25GBE modules are listed in the following table Table 11 Aberrations Optical sampling module Bandwidth filter setting Aberrations 40 GHz 15 30 GHz 10 20 GHz 10 80C05 OC192 5 80C06 50 G...

Page 259: ... attenuator Tektronix OA5002 item 21 Tektronix 80C02 Sampling Module item 32 Pattern Generator Advantest D3186 item 38 80C0X Optical sampling module that supports clock recovery Prerequisites See page 16 Prerequisites See page 219 Prerequisites Before performing this procedure be sure you have completed the Dark level Vertical Equivalent Optical Noise procedure See page 219 Dark Level and Vertical...

Page 260: ...the DIGITAL IN DC COUPLED input on the laser transmitter 6 Connect a single mode fiber optic cable between the OPTICAL output of the laser transmitter and the OPTICAL INPUT on the variable optical attenuator Figure 34 Clock recovery optical sensitivity range and recovered clock timing jitter setup 7 Connect a single mode fiber optic cable between the OPTICAL OUTPUT of the variable optical attenuat...

Page 261: ...e tested later in the procedure 11 Set the variable optical attenuator for minimum attenuation 12 Allow the instrument and its modules to warm up for at least 20 minutes in an environment that has had less than 1 C variation throughout the warm up cycle 13 Push the DEFAULT SETUP button on the instrument and click Yes 14 Push the SELECT ON OFF button on the 80C0X Optical Sampling Module so that the...

Page 262: ...cted b In the Source tab select C3 on Main and click the NRZ button c Choose measurement Select Meas NRZ Timing RMS Jitter d Make sure the Meas 2 ON check box is selected e Select Use Wfm Database Test Follow this procedure to make the clock recovery optical sensitivity range and recovered clock timing jitter checks 1 In the Mode Trigger dialog box select the clock recovery rate for C1 that you wa...

Page 263: ... 0 15552 Gb s 1 ns OC 12 0 62208 Gb s 500 ps div 80C07 CR OC 48 2 48832 Gb s 100 ps div OC 3 0 15552 Gb s 1 ns OC 12 0 62208 Gb s 500 ps div OC 48 2 48832 Gb s 100 ps div FC1063 1 0625 Gb s 200 ps div GBE 1 25 Gb s 200 ps div FC2125 2 125 Gb s 100 ps div 2GBE 2 5 Gb s 100 ps div 80C07B CR Infiniband 2 5 Gb s 100 ps div 10GBASE W 9 95328 Gb s 50 ps div 80C08 CR 10GBASE R 10 3125 Gb s 50 ps div 10GB...

Page 264: ...onous with the signal from the pulse pattern generator See Figure 36 If the signals are not synchronous as shown in the following figure check that the D3186 data rate is set to a data rate that matches the clock recovery rate set for the 80C0X CR Optical Sampling Module See Table 12 The following figure is an example of the display when the clock signal from the Optical Sampling Module is not syn...

Page 265: ...13 Clock recovery settings and jitter limits Module clock recovery rate Max optical power Min optical power Max RMS Jitter OC 12 80C01 CR OC 48 Not specified set to 9 0 dBm 125 μW Not specified set to 9 0 dBm 125 μW 8 ps 80C02 CR OC 192 Not specified set to 7 5 dBm 178 μW 7 5 dBm 178 μW 2 ps FC 1063 GBE OC 48 80C03 CR 2 5 Gb s 4 dBm 400 μW 16 0 dBm 100 μW 8 ps 80C04 CR1 OC 192 7 0 dBm 5 mW 10 0 dB...

Page 266: ...s to check recovered clock timing jitter a If you are checking an 80C01 or an 80C03 module set the Average Optical Power AOP to 125 μW 9 0 dBm otherwise leave the AOP set as it was set for step 5 d b Zoom into the 50 crossing point of the first rising edge on the C3 clock signal until the Horizontal SCALE is 10 ps div and the Vertical SCALE is 10 mV div See Figure 37 NOTE You can most easily zoom ...

Page 267: ...waveform Compare this to the previous figure in which the clock signal is not synchronized Figure 36 Display example clock signal synchronized with the data rate input The following figure is an example of the display zoomed in to 10 mV div and 10 ps div at the crossing point 50 on the recovered clock signal C3 Figure 37 Display example zoomed in at the crossing point End of Procedure DSA8300 Perf...

Page 268: ...ons of software but some control and menu names may vary slightly Prerequisites Be sure you have performed the following prerequisites and the Prerequisites under Performance Tests before doing any procedures in this section Install the 80A02 module in one of the small compartments in the main instrument NOTE Use a calibrated torque wrench when making connections to a module s connectors Use 8 0 3...

Page 269: ...ct the voltage source to the stereo mini phone plug as follows a Identify the connection of the phone plug that is the auto control portion of the phone plug b Set the voltage supply to 0 V and connect the plus supply to the auto control connection Connect the voltage supply ground to the ground portion of the phone plug DSA8300 Performance Verification 251 ...

Page 270: ...ule does not activate no click sound and that the ENGAGED LED does not light while adjusting the DC supply from 0 to 300 mV b Check that the relay in the 80A02 module activates click sound and that the ENGAGED LED lights while adjusting the DC supply from 500 mV 0 5 V to 5 V c Disconnect the voltage supply 2 Remove the mini phone plug End of Procedure 252 DSA8300 Performance Verification ...

Page 271: ...requisites and the Prerequisites under Performance Tests before doing any procedures in this section Install the 80A05 module in one of the small compartments in the main instrument NOTE Use a calibrated torque wrench when making connections to a module s connectors Use 8 0 3 inch pounds of torque Clock Recovery Sensitivity Range and Recovered Clock Timing Jitter This procedure checks the clock re...

Page 272: ... 3 Connect a less than 2 ns delay 50 Ω coaxial cable between the 1 32 CLK signal output of the pattern generator and the TRIGGER DIRECT INPUT connector on the instrument 4 Install 2 10X 20 dB SMA electrical attenuators in series creating 100X attenuation on the ELECTRICAL INPUT IN of the 80A05 Module 5 Connect a less than 2 ns delay 50 Ω coaxial cable between the DATA OUTPUT of the pattern generat...

Page 273: ...ument and click Yes 10 Push the SELECT ON OFF button on the 80E02 Sampling Module so that the adjacent indicator lights This turns on Channel 3 C3 which displays the TRIGGER CLOCK signal 11 Select Setup Mode Trigger from the instrument main menu Make the following changes a Set the Trigger Source to Direct b Click the Advanced Trigger Setup button c Click the Set to 50 button d Select positive edg...

Page 274: ...ecovery rate Rate setting Amplitude Horizontal Scale setting OC 3 0 15552 Gb s 1 0 V 1 ns div OC 12 0 62208 Gb s 1 0 V 500 ps div FC 1063 1 0625 Gb s 1 0 V 200 ps div GBE 1 25 Gb s 1 0 V 200 ps div Serial ATA 1 50 Gb s 1 0 V 200 ps div FC2125 2 125 Gb s 1 0 V 100 ps div OC 48 2 48832 Gb s 1 0 V 100 ps div 2GBE 2 5 Gb s 1 0 V 100 ps div Infiniband 2 5 Gb s 1 0 V 100 ps div PCI Express 2 5 Gb s 1 0 ...

Page 275: ...rom the pulse pattern generator as shown in the following figure If the signals are not synchronous check that the D3186 data rate is set to a data rate that matches the clock recovery rate set for the 80A05 Module See Table 14 Figure 40 Display example clock signal synchronized with the data rate input 4 Check that the Minimum amplitude measurement for C3 is greater than or equal to the value giv...

Page 276: ...red clock sensitivity and recovered clock timing jitter for each of the clock recovery rates Table 15 Clock recovery amplitude and jitter limits Clock recovery rate Minimum pk pk amplitude Max RMS jitter OC 3 200 mV 64 ps OC 12 200 mV 16 ps FC 1063 200 mV 9 4 ps GBE 200 mV 8 ps Serial ATA 1 50 Gb s 200 mV 6 7 ps FC2125 200 mV 4 7 ps OC 48 200 mV 4 ps 2GBE 200 mV 4 ps Infiniband 200 mV 4 ps PCI Exp...

Page 277: ...bE w FEC 1 200 mV 2 ps Super FEC 1 200 mV 2 ps 1 Only available with Option 10G 7 Move the test setup from the 80A05 ELECTRICAL INPUT IN connector to the IN connector and repeat this procedure from step 1 Figure 41 Display example zoomed in at the crossing point 8 Disconnect the test setup End of Procedure End of Document DSA8300 Performance Verification 259 ...

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