Keysight Technologies 1130B Series User Manual Download

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182

1130B-Series Probes User’s Guide

1134B Performance Data Plots

Figure 188

Graph of Vin and Vout of probe with a 25

source and Vout/Vin frequency

response.

Figure 189

Graph of Vout/Vin frequency response when inputs driven in common (common

mode rejection).

-12

-9

-6

-3

Frequency (Hz)

Vout/Vin

Vin

Vout

-60

-50

-40

-30

-20

-10

Frequency (Hz)

Summary of Contents for 1130B Series

Page 1: ...Keysight 1130B Series Differential and Single Ended Probes User s Guide ...

Page 2: ...cial license which is embodied in its End User License Agreement EULA a copy of which can be found at http www key sight com find sweula The license set forth in the EULA represents the exclusive author ity by which the U S government may use modify distribute or disclose the Software The EULA and the license set forth therein does not require or permit among other things that Keysight 1 Furnish t...

Page 3: ...r In Head 64 8 E2676B Single Ended Browser 65 9 E2677B Differential Solder In Head with Medium BW Resistors 67 10 E2679B Single Ended Solder In Head with Long Wire 69 11 E2678B Differential Socketed Head with Damped Wire Accessory 71 12 E2678B Differential Socketed Head with Header Adapter 73 Replacing Resistors on E2677B 9B Solder In Probe Heads 74 3 Calibrating Probes Calibration for Solder In a...

Page 4: ... 150 7 1132B Performance Data Plots E2675B Differential Browser 152 E2676B Single Ended Browser 155 E2677B Differential Solder in Probe Head Full BW 158 E2677B Differential Solder in Probe Head Medium BW 161 E2678A B Differential Socketed Probe Head Full BW 164 E2678A B Differential Socketed Probe Head with Damped Wire Accessory 167 E2679B Single Ended Solder in Probe Head Full BW 170 E2679B Singl...

Page 5: ...for Single Ended Probe Heads 218 SPICE Deck and Measured Modeled Data Matching 219 11 Replacement Parts E2675B Differential Browser Probe Head 230 E2677B Differential Solder In Probe Head 230 E2678A B Differential Socketed Probe Head 231 E2679B Single Ended Solder in Probe Head 231 Other Accessories 232 Index ...

Page 6: ...6 1130B Series Probes User s Guide ...

Page 7: ...2880A InfiniiMax In Line Attenuator Kit 24 N2881A InfiniiMax DC Blocking Caps 28 MX0102A Soldering Toolkit 29 Safety Information 31 Troubleshooting 33 The 1130 1 2 4B InfiniiMax active probes are designed for probing differential and single ended high frequency signals The probes are compatible with the Infiniium AutoProbe Interface which completely configures the Infiniium series of oscilloscopes...

Page 8: ... 4B probe amplifiers The E2669B and E2668B connectivity kits described on page 21 and page 20 conveniently package multiple probe heads and their accessories Differential probe heads offer easy measurement of differential signals and greatly improve the measurement of single ended signals Single ended probe heads offer extremely small size for probing single ended signals in confined spaces Compat...

Page 9: ...bes User s Guide 9 Figure 2 Available Probe Heads and Accessories NOTE N2849A QuickTips are also compatible with the N2848A InfiniiMode probe heads which are designed for N2830 1 2A InfiniiMax III and N2800 1 2 3A InfiniiMax III probes ...

Page 10: ...of order Any head shown in Figure 2 on page 9 can be ordered at any time for any 1130 1 2 4B probes Inspect the shipping container for damage Keep the damaged shipping container or cushioning material until the contents of the shipment have been checked for completeness and the probe has been checked mechanically and electrically Check the accessories Table 1 Compatible Oscilloscopes Oscilloscope ...

Page 11: ...ow signs of stress notify the carrier as well as your Keysight Technologies Sales Office Keep the shipping materials for the carrier s inspection The Keysight Technologies office will arrange for repair or replacement at Keysight Technologies option without waiting for claim settlement Figure 3 Accessories Supplied With the Probe Amplifier Cleaning the probe If the probe requires cleaning disconne...

Page 12: ...be in a shock resistant case such as the foam lined shipping case which came with the probe Connecting and Disconnecting Probe Heads When disconnecting a probe head from an amplifier pull the probe head connectors straight out of the sockets as shown in Figure 4 When connecting a probe head to an amplifier push straight in Always grasp the indentations located on the sides of the amplifier as show...

Page 13: ...able around your thumb as shown in Figure 6 Then continue to circle your thumb but provide a slight twist with each rotation This allows the cable rotations to lie flat against each other and will eliminate the net twisting of the cable in the end Figure 6 Recommended Coil for Storage CAUTION Avoid degrading the probe s performance Do not twist kink or tightly bend the probe s cable CAUTION When t...

Page 14: ...sitive ESD devices so standard precautions need to be used to not ruin the probe from the build up of static charges Securing Probe Heads and Amplifiers to Your DUTs When soldering a probe head to a circuit first provide strain relief by using low temperature hot glue use as little as possible or non conductive double sided tape Do not use super glue and do not get the low temperature hot glue on ...

Page 15: ...is Placed on the Probe Head Tip The velcro dots can be used to secure the probe amplifier to a circuit board removing the weight of the probe from the circuit connection Attach a Velcro dots to both the probe amplifier and the circuit board as shown in Figure 9 on page 15 Figure 9 Using the Velcro Dots ...

Page 16: ...ws the offset voltage to be subtracted from the input signal before the signal gets to the differential amplifier Since this subtraction is done before any active circuits the offset range is large 12V for the 113X amplifiers and 25 kW probe heads Note that the minus probe tip is not present when using a single ended probe head which means nothing is plugged into the input of the probe amp This is...

Page 17: ... 17 The channel offset allows the waveform seen on screen to be moved as desired The allowable dc component in the plus and minus signals is determined by the common mode range of the probe which for the 113x probe amps and 25 kW probe heads is 6 75 V ...

Page 18: ...ingle Ended Slew Rate V ns Max Differential Slew Rate V ns Driver Min Edge Rate 20 80 ps Max Transmitter Level Diff V PCI Express 3GIO YES 9 6 19 2 50 1 6 RapidIO Serial 3 125Gb YES 8 0 16 0 60 1 6 10GbE XAUI 4x3 125Gb YES 8 0 16 0 60 1 6 1394b YES 8 0 16 0 60 1 6 Fibre Channel 2125 YES 8 0 16 0 75 1 Gigabit Ethernet 1000Base CX YES 7 8 15 5 85 2 2 RapidIO 8 16 2Gb YES 7 2 14 4 50 1 2 Infiniband 2...

Page 19: ...dge Slew Rates V nS Differential Slew Rates Maximum Probe Differential Slew Rate 30 V nS Slew Rates of Popular Technologies Compared to Maximum Probe Slew Rates 0 0 2 0 4 0 6 0 8 0 10 0 12 0 14 0 16 0 18 0 20 0 P C I E x p r e s s 3 G I O R a p i d I O S e r i a l 3 1 2 5 G b 1 0 G b E X A U I 4 x 3 1 2 5 G b 1 3 9 4 b F i b r e C h a n n e l 2 1 2 5 G i g a b i t E t h e r n e t 1 0 0 0 B a s e C...

Page 20: ...me time as 1130 1 2 4B probe amplifiers Figure 11 E2668B Single Ended Connectivity Kit not to scale Table 3 Supplied Accessories Sheet 1 of 2 Description Qty Supplied Used With Part Number E2679B E2678B E2676B E2679B Single Ended Solder In Head 1 E2678B Differential Socketed Head 1 E2676B Single Ended Browser 1 91W resistor for full bandwidth 16 1NC3 1091 150W resistor for medium bandwidth 8 1NC3 ...

Page 21: ...ifiers Figure 12 E2669B Differential Connectivity Kit not to scale 25 mil female socket w 20 mil round male pin on other end 4 01131 85202 Heat shrink tubing for square pin socket accessory 4 01130 41101 Header adapter 91W 2 01130 63201 82W resistor template 1 01131 94309 Resistive tip blue 91W 10 01131 62107 Ergonomic handle 1 01130 43202 Ground collar assembly for single ended browser 2 01130 60...

Page 22: ...er end 8 01131 85202 Heat shrink socket accessory 8 01130 41101 Header adapter 91W 4 01130 63201 82W resistor template 1 01131 94309 91W resistor for full bandwidth 80 1NC3 1091 150W resistor for medium bandwidth 40 1NC3 1150 91W resistor template 1 01131 94311 150W resistor template 1 01131 94308 Resistive tip blue 91W 20 01131 62107 Ergonomic handle 1 01131 43201 Not orderable NOTE Resistor perf...

Page 23: ... positioned anywhere along the length of the cable and can withstand the temperature ranges specified Table 5 Probing Temperature Ranges Probe Head Configuration Operating Temperature Range o C Expected Lifetime of the Probe Head cycles E2677B 25 to 80 1000 E2678A B 25 to 80 1000 N5425B N5426A 40 to 85 500 N5451A 25 to 80 1000 MX0100A 55 C dwell 1000 hours minimum 150 C dwell 1000 hours minimum 55...

Page 24: ...r has a serial number The pair of matching attenuators in each set will have the same four digit numeric prefix and will differ by the last letter one attenuator in the matched pair will be labeled A and the other will be labeled B Figure 13 Placement of Attenuators Between Probe Amplifier and Head CAUTION Prevent abrasion and tears in the cable s jacket do not rest the extension cables on any met...

Page 25: ...talled If you want to scale readings and settings on the oscilloscope so they are correct with the attenuators installed refer to the procedures below for your specific oscilloscope series Configuring Attenuators on a Infiniium Scope Table 6 N2880A With 1130B Series Probe Amplifiers Added Attenuator MaximumInput Range mains isolated circuits only Offset Range Typical Noise Referred to Maximum Allo...

Page 26: ...InfiniiVision software release 5 25 or newer installed on your oscilloscope 1 Plug your InfiniiMax probe amplifier probe head into one of the oscilloscope channels with the attenuators attached 2 Press the Channel on off key to turn the channel on if the channel is off 3 Press the Probe softkey in the Channel menu A series of probe related softkeys will appear 4 Repeatedly press the second softkey...

Page 27: ...s Probes User s Guide 27 Red dB Vout Vin 10 8 dB of probe Black dB Vout Vin 6dB attenuator 10 8 dB Blue dB Vout Vin 12 dB attenuator 10 8 dB of probe Green dB Vout Vin 20 dB attenuator 10 8 dB of probe Figure 14 Frequency Response ...

Page 28: ... DC Blocking Caps block out the DC component of the input signal up to 30 Vdc The N2881A InfiniiMax DC Blocking Caps can be used with the N2880A In Line Attenuators The order of the two products in the probing system i e which one is closest to the probe amplifier does not matter Figure 15 Placement of DC Blocking Caps Between Probe Amplifier and Head Figure 16 on page 28 shows the frequency respo...

Page 29: ...ers Cutting Tweezers Double sided Foam Tape Low Temperature Solder Wire Regular Solder Wire Probe Tip Wire Kapton Tape Description Qty Supplied Part Number Straight Tweezers Anti magnetic straight pointed tip 120mm For general purpose manipulation movement of com ponents such as probe tip wires and probe head 1 8710 2837 Cutting Tweezers Narrow oblique head 115mm To cut a probe tip wire to a desir...

Page 30: ...elts at 217 o C 1 MX0102 21302 Low Temperature Solder Wire Lead free 010 diameter 2 feet long To attach the probe tip wires to a DUT using a low tem perature setting on your soldering iron NOTE This alloy melts at 138 o C 1 MX0102 21303 Probe Tip Wire 004 diameter 2 feet long To add ground wires to your probe tip if InfiniiMode mea surements differential single ended and common mode signals with a...

Page 31: ... to a potential other than earth ground Always make sure the probe and the oscilloscope are grounded properly WARNING Connect and Disconnect Properly Connect the probe to the oscilloscope and connect the ground lead to earth ground before connecting the probe to the circuit under test Disconnect the probe input and the probe ground lead from the circuit under test before disconnecting the probe fr...

Page 32: ... excessive bending or pulling Avoid any mechanical shocks to this product in order to guarantee accurate performance and protection WARNING Whenever it is likely that the ground protection is impaired you must make the instrument inoperative and secure it against any unintended operation WARNING If you energize the instrument by an auto transformer for voltage reduction or mains isolation the grou...

Page 33: ...tness If the probe s pulse response shows a top that is not flat check for the following Output of probe must be terminated into a proper 50W termination If you are using the probe with an Infiniium oscilloscope this should not be a problem If you are using the probe with other test gear ensure the probe is terminated into a low reflectivity 50W load 2 If the coax or coaxes of the probe head in us...

Page 34: ...Name and address of owner Product model number for example 1130B Product Serial Number for example MYXXXXXXXX Description of failure or service required 3 Protect the probe by wrapping in plastic or heavy paper 4 Pack the probe in the original carrying case or if not available use bubble wrap or packing peanuts 5 Place securely in sealed shipping container and mark container as FRAGILE Contacting ...

Page 35: ... Damped Wire Accessory 71 12 E2678B Differential Socketed Head with Header Adapter 73 Replacing Resistors on E2677B 9B Solder In Probe Heads 74 This chapter describes the various probe heads The probe configurations are listed in the order of the best performance to the least performance The recommended configurations are designed to give the best probe performance for different probing situations...

Page 36: ... 51 3 1134B 7 1132B 5 1131B 3 5 1130B 1 5 0 34 0 56 Differential and Single ended signals Removable connection using solder in resistor pins Hard to reach targets E2675B Differential Browser Refer to page 54 4 1134B 6 1132B 5 1131B 3 5 1130B 1 5 0 32 0 57 Differential and Single ended signals Hand held browsing Probe holders General purpose troubleshooting Ergonomic handle available N5380B Differe...

Page 37: ...older In with Long Wire Refer to page 69 10 1134B 2 2 1132B 2 2 1131B 2 2 1130B 1 5 N A 0 58 Single ended signals only Solder in hands free connection when physical size is critical Larger span and reach than 4 Hard to reach targets Very small fine pitch targets E2678B Differential Socketed with Damped Wire Accessory Refer to page 71 11 1134B 1 2 1132B 1 2 1131B 1 2 1130B 1 2 0 63 0 95 Differentia...

Page 38: ...d configuration supports the highest bandwidth and provides the full bandwidth signals 1134B 7 GHz 1132B 5 GHz 1131B 3 5 GHz and 1130B 1 5 GHz and the lowest capacitive loading for measuring both single ended and differential signals This probe head connects easily to an InfiniiMax probe amplifier using the bullet adapter shipped with the probe head For connection to a DUT it has pre wired probe t...

Page 39: ...s specified frequency response and bandwidth over the operating temperature range 55 C to 150 C without any need for compensation or correction NOTE When probing differential signals the and connection of the MX0100A probe head can be determined when the probe head is plugged into the probe amplifier The and indicators on the probe amplifier represent the and inputs on MX0100A probe head When prob...

Page 40: ...mmodate small fine pitch targets The available bandwidth is the full bandwidth of the probe amplifier being used 1134B 7 GHz 1132B 5 GHz 1131B 3 5 GHz and 1130B 1 5 GHz Table 9 MX0100A Probe Head Kit Components Component Quantity Part Number Option 001 Option 002 Option 003 Micro Probe Heads with pre wired probe tips 5 25 50 MX0100A Probe Tip Wire 004 diameter To make ground connections 1 wire spo...

Page 41: ...ing the cutting tweezers trim the lead wires even with the trim lines Soldering an MX0100A Probe Head to DUT To solder the probe tip lead wires to DUT 1 Trim the length of the MX0100A probe head lead wires to match your DUT s geometry see page 40 You may use the cutting tweezers Keysight part number 8710 2838 included in the Soldering toolkit NOTE You can spread the probe head s lead wires within ...

Page 42: ...hese wires on DUT and then reflowing joint while heating momentarily 5 Provide strain relief to the probe head by taping its mid portion to a flat surface such as a tabletop using the double sided foam tape such as Keysight part NOTE Keep the temperature as low as possible while still reflowing the solder at the joint of concern The following are some of the useful tips to maintain low temperature...

Page 43: ...housings by using a double sided foam tape Keysight part number 0460 3122 included in the MX0102A Soldering Toolkit MX0100A Probe Head Handling Precautions One of the advantages of the MX0100A probe head is its reusability feature This section describes some of the cautions and tips on how to properly handle the MX0100A probe head to prevent damage and maintain high performance and reusability of ...

Page 44: ...ate connections Strain relief is recommended at the probe head and amplifier housings as well as at the probe head cable Figure 19 Example of a properly strain relieved MX0100A probe head setup While moving a soldered MX0100A probe head always ensure that you do not twist pull tightly bend or apply force near the probe head s cable housing Figure 20 Example of correct movement of MX0100A probe hea...

Page 45: ...Using a low temperature solder alloy such as SAC Tin Silver Copper with 220 o C melting point or tin bismuth solder with 138 o C melting point Do not apply heat on the probe tip leads for a time period longer than two seconds Use a small solder iron tip 1mm is recommended No clean non conductive and less acidic flux is recommended While disconnecting the probe head from the MX0103A bullet adapter ...

Page 46: ...or of the MX0100A is displayed as Infinite Figure 23 Resistance measurement for a damaged MX0100A probe head Replacing an MX0100A Probe Tip Lead Wire Use the following procedure to install or replace the lead wires on the MX0100A probe head in the event of damage or break off due to use Depending on your probing application you can order either 9 mil or 10 mil wire as listed in the following table...

Page 47: ...ntly Touch the soldering iron to the solder joint just long enough for the lead wire to come free of the probe head tip 3 Position the end of the new lead wire Keysight part number MX0102 21302 or MX0102 21303 included in the MX0102A Soldering Toolkit over the via hole Touch the soldering iron to the side of the hole When the solder in the hole Low Temperature Solder Wire lead free Requires a low ...

Page 48: ... the tip of the soldering iron Touch the solder tip with the solder on it to the solder joint Do not dwell on the joint with the solder iron any longer than needed The solder should flow off the soldering iron tip into the joint If it does not flow then sufficient flux may not have been used 5 Cut the extra wire off using a cutting tweezer Keysight part number 8710 2838 included in the MX0102A Sol...

Page 49: ...nection to very small fine pitch targets Figure 24 E2677B The probe head resistors must be soldered to the circuit that you are measuring Because of the small size of the resistor leads it is easy to solder them to very small geometry circuits Table 11 Bandwidth Probe Amplifier BW GHz Probe Amplifier BW GHz 1130B 1 5 1132B 5 1131B 3 5 1134B 7 NOTE To install or repair resistor leads Refer to Repla...

Page 50: ...thout having to use an excessive amount of solder CAUTION Strain relieve the micro coax leading away from the solder in tips using hook and loop fasteners or adhesive tape to protect delicate connections NOTE Before using the resistors the resistor wires must be cut to the correct dimensions For the correct dimensions see Replacing Resistors on E2677B 9B Solder In Probe Heads on page 74 Table 12 S...

Page 51: ... for mounting the lead resistors Figure 25 E2678B The 82Ω axial lead resistors are soldered to the circuit that you are measuring The socketed differential probe head is plugged onto the resistors This makes it easier to move the probe from one location to another Because of the larger size of the resistor leads the target for soldering must be larger than the solder in probe heads NOTE The E2678B...

Page 52: ... 762 mm is recommended Shaping the Resistors Before installing the 82W resistors 01130 81506 onto your device under test the resistor wires must be trimmed using diagonal cutters and bent to the correct dimensions as shown in Figure 26 Use tweezers to place the resistor body inside the rectangle of the supplied trim guage Use diagonal cutters to trim the leads even with the trim lines Figure 26 Re...

Page 53: ... 82W resistor for full bandwidth 48 01130 81506 not orderable Socket for 25 mil 25 1000 inch square pins female on both ends 4 01131 85201 not orderable 25 mil female socket w 20 mil round male pin on other end 4 01131 85202 not orderable Heats hrink socket accessory 4 01130 41101 not orderable Header adapter 91W 2 01130 63201 82W resistor template 1 01131 94309 ...

Page 54: ...be tips to be adjusted for different circuit geometries Figure 27 Differential Browser Table 15 Bandwidth Probe Amplifier BW GHz Probe Amplifier BW GHz 1130B 1 5 1132B 5 1131B 3 5 1134B 6 NOTE Performance plots Refer to Chapter 5 1130B Performance Data Plots Chapter 6 1131B Performance Data Plots Chapter 7 1132B Performance Data Plots and Chapter 8 1134B Performance Data Plots CAUTION Do not use t...

Page 55: ... Orientation of the Blue Tips When holding the E2675B for extended periods of time use the supplied ergonomic handle Figure 29 on page 55 and Figure 30 on page 55 show how to attach and remove the handle from the probe head Figure 29 Inserting the Probe Figure 30 Removing the Probe ...

Page 56: ...56 1130B Series Probes User s Guide 2 Using Probe Heads Table 16 Supplied Accessories Description Qty Supplied Part Number Resistive tip blue 91W 20 01131 62107 Ergonomic handle 1 01131 43201 ...

Page 57: ...from the N5380B SMA probe head grasp the probe amplifier as shown in Figure 31 on page 57 and pull it straight away from the SMA probe head without any rocking either side to side or up and down Figure 31 Disconnecting the N5380B NOTE The E2695A 8 GHz SMA head for InifiniiMax I probe amplifiers was discontinued in December 2013 and replaced by the N5380B 12 GHz SMA head Table 17 Bandwidth Probe Am...

Page 58: ...head support already attached For older N5380A heads the head support can be ordered As shown in Figure 32 the current design of the N5380 64701 has been changed from the original design The original design is no longer offered Both the original and new design provide the same level of protection for the probe amplifier and can be attached to both N5380B and N5380A heads Figure 32 Original and New...

Page 59: ...Using Probe Heads 2 1130B Series Probes User s Guide 59 Figure 33 N5380B Schematic ...

Page 60: ...shown in Figure 35 on page 61 Because the probe head is magnetically connected instead of mechanically connected to the QuickTip you can effortlessly connect and disconnect to each QuickTip For best performance position the QuickTip vertically on the DUT The N2849A QuickTip has two signal leads and two ground leads The ground leads have minimal effect on your differential measurements However if y...

Page 61: ...2848A QuickTip InfiniiMode Probe Heads which are designed for N2800 1 2 3A N2830 1 2A and N7000 1 2 3A probes CAUTION Do not replace or repair the N2849A QuickTip s resistor or ground leads Attempting to do so will damage the ability of the tip to mate with the N2851A probe head NOTE The N2851A does not include any N2849A QuickTips The N2849A must be ordered separately ...

Page 62: ...probe head or the N2787A 3D probe positioner for securing the probe amplifier to a rigid body near the DUT CAUTION Always mechanically strain relieve the QuickTip head before using to protect both your probe accessories and DUT from damage NOTE Resistor and wire leads on the QuickTip are factory trimmed to the proper length for use Adding wire length to the tip of the mini axial lead resistors or ...

Page 63: ...ions in the head become dirty clean the connections using the following steps 1 Use compressed air or a cloth to remove any loose dirt 2 Gently rub a small piece of tack putty supplied with the probe against the magnetic connections to clean off any remaining surface grime Figure 36 N2851A Head Before and After Cleaning ...

Page 64: ...the small size of the resistor leads it is easy to solder them to very small geometry circuits Figure 37 E2679B Table 19 Bandwidth Probe Amplifier BW GHz Probe Amplifier BW GHz 1130B 1 5 1132B 5 1131B 3 5 1134B 5 2 NOTE To install or repair resistor leads Refer to Replacing Resistors on E2677B 9B Solder In Probe Heads on page 74 NOTE Performance plots Refer to Chapter 5 1130B Performance Data Plot...

Page 65: ...in tight areas For wider span non performance critical browsing rise times greater than 0 5 ns the E2676 21301socketed ground lead can be used in place of the 01130 60012 ground collar Figure 38 E2676B When holding the E2676B for extended periods of time use the supplied ergonomic handle Figure 39 and Figure 40 show how to attach and remove the handle from the probe head Figure 39 Inserting the Pr...

Page 66: ...66 1130B Series Probes User s Guide 2 Using Probe Heads Figure 40 Removing the Probe from the Handle ...

Page 67: ...onnection to widely spaced points or points in tight areas The probe head resistors must be soldered to the circuit that you are measuring Because of the small size of the resistor leads it is easy to solder them to very small geometry circuits This configuration can probe circuit points that are farther apart than the full bandwidth configurations Table 21 Bandwidth Probe Amplifier BW GHz Probe A...

Page 68: ...User s Guide 2 Using Probe Heads NOTE Performance plots Refer to Chapter 5 1130B Performance Data Plots Chapter 6 1131B Performance Data Plots Chapter 7 1132B Performance Data Plots and Chapter 8 1134B Performance Data Plots ...

Page 69: ...B Medium Bandwidth The probe head resistors must be soldered to the circuit that you are measuring Because of the small size of the resistor leads it is easy to solder them to very small geometry circuits This configuration can probe circuit points that are farther apart than the full bandwidth configurations Table 22 Bandwidth Probe Amplifier BW GHz Probe Amplifier BW GHz 1130B 1 5 1132B 2 9 1131...

Page 70: ...essories Description Qty Supplied Part Number Not orderable 91W resistor for full bandwidth 16 1NC3 1091 150W resistor for medium bandwidth 8 1NC3 1150 0W resistor for full and medium bandwidth 24 1NC3 1000 91W resistor template 2 01131 94311 150W resistor template 2 01131 94308 ...

Page 71: ...es must be soldered to the circuit that you are measuring This configuration can probe circuit points that are farther apart than other configurations This probe head come with a damped wire accessory that includes two 160W resistors Table 24 Bandwidth Probe Amplifier BW GHz Probe Amplifier BW GHz 1130B 1 2 1132B 1 2 1131B 1 2 1134B 1 2 NOTE The E2678B is a direct replacement for the E2678A that p...

Page 72: ...User s Guide 2 Using Probe Heads NOTE Performance plots Refer to Chapter 5 1130B Performance Data Plots Chapter 6 1131B Performance Data Plots Chapter 7 1132B Performance Data Plots and Chapter 8 1134B Performance Data Plots ...

Page 73: ...t and heat the heat shrink tubing with a heat gun This allows the damped wire accessories to be used to plug onto 25 mil square pins Figure 44 01130 63201 Header Adapter Dimensions NOTE If the header adapter is used with higher bandwidth probe amplifiers such as the 1132B 5 GHz or the 1134B 7GHz the rise time of the input signal should be slower than 150 ps 10 to 90 to limit the effects of resonan...

Page 74: ...stors were changed from 100Ω to 91Ω for slightly better performance Either value produces a response that is well within specifications Table 27 Recommended Equipment Equipment Vise or clamp for holding tip Metcal STTC 022 600 C or STTC 122 700 C tip soldering iron or equivalent The 600 C tip will help limit burning of the FR4 tip PC board 0 381 mm 0 015 in diameter RMA flux standard tin lead sold...

Page 75: ...repare the mini axial lead resistor for attachment to the head s pc board The lead to be attached to head s pc board will have a 90 bend to go into through hole in the tip pc board 6 Using tweezers place the resistor body inside the rectangle of the trim template CAUTION If using a vise grip the tip on the sides with light force When tightening the vise use light force to avoid damaging the solder...

Page 76: ...ed With Resistors 7 Using a knife trim the leads even with the trim lines 8 Place resistor body inside the rectangle of the bend template 9 Using another pair of tweezers bend the 1 90 mm or 8 89 mm lead 90 as shown in Figure 47 and Figure 48 Figure 47 91W and 0W Combination Resistor Trim Dimensions ...

Page 77: ...fall into the hole Remove soldering iron as soon as lead falls into the hole NOTE Do not use the wrong value of resistor at the wrong length CAUTION The thermal mass of the joint is very small so taking extra time with the soldering iron in an attempt to ensure a good joint is not needed NOTE Make sure the zero ohm resistor is used for ground leads on the E2679B single ended probe head NOTE For th...

Page 78: ...78 1130B Series Probes User s Guide 2 Using Probe Heads ...

Page 79: ... male to BNC female adapter BNC male to SMA male adapter 50Ω SMA Terminator De skew Fixture When the probe has been calibrated the dc gain offset zero and offset gain will be calibrated The degree of accuracy specified at the probe tip is dependent on the oscilloscope system specifications This chapter contains procedures showing vertical and skew calibration for solder in differential probe head ...

Page 80: ...wear and tear on the probe head the probe head should be placed on a support to relieve the strain on the probe head cables 6 Push down on the back side of the yellow pincher Insert the probe head resistor lead underneath the center of the yellow pincher and over the center conductor of the deskew fixture The negative probe head resistor lead or ground lead must be underneath the yellow pincher an...

Page 81: ...et the horizontal scale to 1 00 ns div 4 Set the horizontal position to approximately 3 ns You should see a waveform similar to that in Figure 50 on page 82 If you see a waveform similar to that of Figure 51 then you have a bad connection and should check all of your probe connections Figure 49 Connecting the Probe and Deskew Fixture BNC to SMA Connector Deskew Fixture 50W SMA Terminator InfiniiMa...

Page 82: ...in the Setup menu select the channel connected to the probe 2 In the Channel Setup dialog box select the Probes button 3 In the Probe Setup dialog box select the Calibrate Probe button 4 In the Probe Cal dialog box select the Calibrated Atten Offset radio button 5 Select the Start Atten Offset Calibration button and follow the on screen instructions for the vertical calibration procedure ...

Page 83: ...lowing procedure refer to Figure 49 on page 81 1 As shown in Figure 52 on page 85 connect BNC male to SMA male adapter to the deskew fixture on the connector closest to the yellow pincher 2 Connect the SMA male to BNC female to the connector farthest from the yellow pincher 3 Connect the BNC male to BNC male cable to the BNC connector on the deskew fixture to one of the unused oscilloscope channel...

Page 84: ...on button and follow the on screen instructions 18 Set the vertical scale for the displayed channels to 100 mV div 19 Set the horizontal range to 1 00 ns div 20 Set the horizontal position to approximately 3 ns 21 Change the vertical position knobs of both channels until the waveforms overlap each other 22 Select the Setup menu choose Acquisition from the pull down menu 23 In the Acquisition Setup...

Page 85: ...Calibrating Probes 3 1130B Series Probes User s Guide 85 Figure 52 Connecting the Probe InfiniiMax Probe BNC to SMA Connector Deskew Fixture SMA to BNC Connector Pincher BNC Cable ...

Page 86: ...86 1130B Series Probes User s Guide 3 Calibrating Probes Figure 53 Overlapping Waveforms ...

Page 87: ...f the deskew fixture between the green line and front end of the yellow pincher The negative resistor tip or ground pin of the browser must be on either of the two outside conductors ground of the deskew fixture 6 On the Infiniium oscilloscope in the Setup menu select the channel connected to the probe 7 In the Channel Setup dialog box select the Probes button 8 In the Probe Setup dialog box selec...

Page 88: ...88 1130B Series Probes User s Guide 3 Calibrating Probes Figure 54 Placing the Probe on the Fixture BNC to SMA Connector Deskew Fixture Pincher InfiniiMax Probe ...

Page 89: ...ter SMA connector of the SMA probe head 3 Connect the other end of the deskew fixture or SMA to SMA adapter if you are using it instead to one of the SMA connectors of the N5380A B SMA probe head 4 Connect the BNC connector of the SMA to BNC adapter to the Aux Out on the Infiniium oscilloscope 5 Connect the InfiniiMax probe amplifier to the GPO SMP connector of the N5380A B SMA probe head Be sure ...

Page 90: ...90 1130B Series Probes User s Guide 3 Calibrating Probes ...

Page 91: ...robes User s Guide 4 Characteristics and Specifications General 92 Environmental 94 Regulatory 95 Probe Dimensions 96 All warranted specifications are denoted by a footnote reference number All other characteristics are typical values ...

Page 92: ...o 90 1134B 1132B 1131B 1130B 60 ps 86 ps 100 ps 233 ps Oscilloscope and Probe System Bandwidth 3 dB 1134B with 54855 1132B with 54854 1131B with 54853 1131B with 54852 1130B with 54833 1130B with 54832 6 GHz 4 GHz 2 5 GHz 2 GHz 1 GHz Input Capacitance Cm 0 10 pF Model for input C is Cm is between tips and Cg is to ground for each tip Cg 0 34 pF Cdiff 0 27 pF Differential mode capacitance capacitan...

Page 93: ...on on oscilloscope Offset Range 12 0 V When probing single ended Offset Accuracy 3 of setting before calibration on oscilloscope 1 of setting after calibration on oscilloscope Noise referred to input 3 0 mVrms Propagation Delay 6 ns Maximum Input Voltage 30V Peak mains isolated Maximum non destructive voltage on each input ground ESD Tolerance 8 kV from 100 pF 300 Ω HBM Values shown are for the pr...

Page 94: ...umidity up to 95 relative humidity non condensing at 40 C up to 90 relative humidity at 65 C Altitude Up to 4 600 meters Up to 15 300 meters Power Requirements voltages supplied by AutoProbe Interface 12 Vdc 11 mA 12 Vdc 5 mA 5 Vdc 28 mA 5 Vdc 92 mA 0 84 W Weight approximately 0 69 kg Dimensions Refer to the outline in Figure 56 on page 96 Pollution degree 2 Normally only non conductive pollution ...

Page 95: ...ity ISM GRP 1 A denotes the instrument is an Industrial Scientific and Medical Group 1 Class A product ICES NMB 001 indicates product compliance with the Canadian Interference Causing Equipment Standard This product complies with the WEEE Directive 2002 96 EC marking requirements The affixed label indicates that you must not discard this electrical electronic product in domestic household waste Pr...

Page 96: ...96 1130B Series Probes User s Guide 4 Characteristics and Specifications Probe Dimensions Figure 56 Probe Dimensions ...

Page 97: ...Characteristics and Specifications 4 1130B Series Probes User s Guide 97 MX0100A Probe Head Dimensions All dimensions are in mm inches Figure 57 MX0100A Probe Head Dimensions ...

Page 98: ...98 1130B Series Probes User s Guide 4 Characteristics and Specifications ...

Page 99: ... 112 E2678A B Differential Socketed Probe Head with Damped Wire Accessory 115 E2679B Single Ended Solder in Probe Head Full BW 118 E2679B Single Ended Solder in Probe Head Medium BW 121 N2851A QuickTip Head with N2849A QuickTip 124 This chapter provides graphs of the performance characteristics of the 1130B probes using the different probe heads that come with the E2668b single ended and E2669B di...

Page 100: ... s Guide 5 1130B Performance Data Plots E2675B Differential Browser Figure 58 Graph of 25 ohm 405 4 ps step generator with and without probe connected Figure 59 Graph of Vin and Vout of probe with a 25 ohm 405 4 ps step generator ...

Page 101: ...5 1130B Series Probes User s Guide 101 Figure 60 Graph of Vin and Vout of probe with a 25 ohm source and Vout Vin frequency response Figure 61 Graph of Vout Vin frequency response when inputs driven in common common mode rejection ...

Page 102: ...102 1130B Series Probes User s Guide 5 1130B Performance Data Plots Figure 62 Magnitude plot of probe input impedance versus frequency ...

Page 103: ... 5 1130B Series Probes User s Guide 103 E2676B Single Ended Browser Figure 63 Graph of 25 ohm 405 4 ps step generator with and without probe connected Figure 64 Graph of Vin and Vout of probe with a 25 ohm 405 4 ps step generator ...

Page 104: ...s Guide 5 1130B Performance Data Plots Figure 65 Graph of Vin and Vout of probe with a 25 ohm source and Vout Vin frequency response Figure 66 Graph of Vout Vin frequency response when inputs driven in common common mode rejection ...

Page 105: ...1130B Performance Data Plots 5 1130B Series Probes User s Guide 105 Figure 67 Magnitude plot of probe input impedance versus frequency ...

Page 106: ...5 1130B Performance Data Plots E2677B Differential Solder in Probe Head Full BW Figure 68 Graph of 25 ohm 100 ps step generator with and without probe connected Figure 69 Graph of Vin and Vout of probe with a 25 ohm 405 4 ps step generator ...

Page 107: ...5 1130B Series Probes User s Guide 107 Figure 70 Graph of Vin and Vout of probe with a 25 ohm source and Vout Vin frequency response Figure 71 Graph of Vout Vin frequency response when inputs driven in common common mode rejection ...

Page 108: ...108 1130B Series Probes User s Guide 5 1130B Performance Data Plots Figure 72 Magnitude plot of probe input impedance versus frequency ...

Page 109: ...ries Probes User s Guide 109 E2677B Differential Solder in Probe Head Medium BW Figure 73 Graph of 25 ohm 405 4 ps step generator with and without probe connected Figure 74 Graph of Vin and Vout of probe with a 25 ohm 405 4 ps step generator ...

Page 110: ...s Guide 5 1130B Performance Data Plots Figure 75 Graph of Vin and Vout of probe with a 25 ohm source and Vout Vin frequency response Figure 76 Graph of Vout Vin frequency response when inputs driven in common common mode rejection ...

Page 111: ...1130B Performance Data Plots 5 1130B Series Probes User s Guide 111 Figure 77 Magnitude plot of probe input impedance versus frequency ...

Page 112: ...1130B Performance Data Plots E2678A B Differential Socketed Probe Head Full BW Figure 78 Graph of 25 ohm 405 4 ps step generator with and without probe connected Figure 79 Graph of Vin and Vout of probe with a 25 ohm 405 4 ps step generator ...

Page 113: ...5 1130B Series Probes User s Guide 113 Figure 80 Graph of Vin and Vout of probe with a 25 ohm source and Vout Vin frequency response Figure 81 Graph of Vout Vin frequency response when inputs driven in common common mode rejection ...

Page 114: ...114 1130B Series Probes User s Guide 5 1130B Performance Data Plots Figure 82 Magnitude plot of probe input impedance versus frequency ...

Page 115: ...83 Graph of 25 ohm 240 ps step generator with and without probe connected Figure 84 Graph of Vin and Vout of probe with a 25 ohm 240 ps step generator NOTE Due to reflections on the long wire accessories signals being probed should be limited to 240 ps rise time measured at the 10 and 90 amplitude levels This is equivalent to 4 5 GHz bandwidth ...

Page 116: ...s Guide 5 1130B Performance Data Plots Figure 85 Graph of Vin and Vout of probe with a 25 ohm source and Vout Vin frequency response Figure 86 Graph of Vout Vin frequency response when inputs driven in common common mode rejection ...

Page 117: ...1130B Performance Data Plots 5 1130B Series Probes User s Guide 117 Figure 87 Magnitude plot of probe input impedance versus frequency ...

Page 118: ... 1130B Performance Data Plots E2679B Single Ended Solder in Probe Head Full BW Figure 88 Graph of 25 ohm 405 4 ps step generator with and without probe connected Figure 89 Graph of Vin and Vout of probe with a 25 ohm 405 4 ps step generator ...

Page 119: ...5 1130B Series Probes User s Guide 119 Figure 90 Graph of Vin and Vout of probe with a 25 ohm source and Vout Vin frequency response Figure 91 Graph of Vout Vin frequency response when inputs driven in common common mode rejection ...

Page 120: ...120 1130B Series Probes User s Guide 5 1130B Performance Data Plots Figure 92 Magnitude plot of probe input impedance versus frequency ...

Page 121: ...ries Probes User s Guide 121 E2679B Single Ended Solder in Probe Head Medium BW Figure 93 Graph of 25 ohm 405 4 ps step generator with and without probe connected Figure 94 Graph of Vin and Vout of probe with a 25 ohm 405 4 ps step generator ...

Page 122: ...s Guide 5 1130B Performance Data Plots Figure 95 Graph of Vin and Vout of probe with a 25 ohm source and Vout Vin frequency response Figure 96 Graph of Vout Vin frequency response when inputs driven in common common mode rejection ...

Page 123: ...1130B Performance Data Plots 5 1130B Series Probes User s Guide 123 Figure 97 Magnitude plot of probe input impedance versus frequency ...

Page 124: ...124 1130B Series Probes User s Guide 5 1130B Performance Data Plots N2851A QuickTip Head with N2849A QuickTip Figure 98 Input Impedances Modeled and Measured ...

Page 125: ... 138 E2678A B Differential Socketed Probe Head with Damped Wire Accessory 141 E2679B Single Ended Solder in Probe Head Full BW 144 E2679B Single Ended Solder in Probe Head Medium BW 147 N2851A QuickTip Head with N2849A QuickTip 150 This chapter provides graphs of the performance characteristics of the 1131B probes using the different probe heads that come with the E2668B single ended and E2669B di...

Page 126: ...h and without probe connected Figure 100 Graph of Vin and Vout of probe with a 25Ω 200 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 208 ps Vin tr 224 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vout tr 224 ps Vin tr 219 ps ...

Page 127: ...ph of Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 102 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 60 50 40 30 20 10 0 Frequency H z dB ...

Page 128: ...mance Data Plots Figure 103 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 229 2 Ω Zmin 153 4 Ω 50 kΩ 25 kΩ 0 57 pF 0 32 pF ...

Page 129: ...th and without probe connected Figure 105 Graph of Vin and Vout of probe with a 25Ω 200 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 208 ps Vin tr 232 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 232 ps Vout tr 229 ps ...

Page 130: ...ph of Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 107 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 60 50 40 30 20 10 0 Frequency H z dB ...

Page 131: ...ance Data Plots 6 1130B Series Probes User s Guide 131 Figure 108 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Zmin 120 Ω 25 kΩ 0 65 pF ...

Page 132: ...erator with and without probe connected Figure 110 Graph of Vin and Vout of probe with a 25 ohm 200 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e S e conds V olts Vsource tr 207 ps Vin tr 220 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 220 ps Vout tr 236 ps ...

Page 133: ...h of Vin and Vout of probe with a 25 ohm source and Vout Vin frequency response Figure 112 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 60 50 40 30 20 10 0 Frequency H z dB ...

Page 134: ...mance Data Plots Figure 113 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 272 8 Ω Zmin 201 8 Ω 50 kΩ 25 kΩ 0 44 pF 0 27 pF ...

Page 135: ...generator with and without probe connected Figure 115 Graph of Vin and Vout of probe with a 25Ω 200 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 208 ps Vin tr 223 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 223 ps Vin tr 287 ps ...

Page 136: ...ph of Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 117 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 60 50 40 30 20 10 0 Frequency H z dB ...

Page 137: ...User s Guide 137 Figure 118 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 343 3 Ω Zmin 251 6 Ω 50 kΩ 25 kΩ 0 52 pF 0 33 pF ...

Page 138: ...enerator with and without probe connected Figure 120 Graph of Vin and Vout of probe with a 25Ω 200 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 207 ps Vin tr 225 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vout tr 247 ps Vin tr 225 ps ...

Page 139: ...ph of Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 122 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 60 50 40 30 20 10 0 Frequency H z dB ...

Page 140: ...mance Data Plots Figure 123 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 234 9 Ω Zmin 174 6 Ω 50 kΩ 25 kΩ 0 56 pF 0 34 pF ...

Page 141: ... a 25Ω 240 ps step generator NOTE Due to reflections on the long wire accessories signals being probed should be limited to 240 ps rise time measured at the 10 and 90 amplitude levels This is equivalent to 1 5 GHz bandwidth 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 240 ps Vin tr 259 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 0...

Page 142: ...ph of Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 127 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 60 50 40 30 20 10 0 Frequency H z dB ...

Page 143: ... User s Guide 143 Figure 128 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 344 0 Ω Zmin 248 9 Ω 50 kΩ 25 kΩ 0 95 0 63 pF ...

Page 144: ...nerator with and without probe connected Figure 130 Graph of Vin and Vout of probe with a 25Ω 200 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 208 ps Vin tr 225 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 225 ps Vout tr 225 ps ...

Page 145: ...ph of Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 132 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 60 50 40 30 20 10 0 Frequency H z dB ...

Page 146: ...es Probes User s Guide 6 1131B Performance Data Plots Figure 133 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Zmin 142 9 Ω 25 kΩ 0 50 pF ...

Page 147: ...enerator with and without probe connected Figure 135 Graph of Vin and Vout of probe with a 25Ω 200 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 208 ps Vin tr 229 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 229 ps Vout tr 257 ps ...

Page 148: ...ph of Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 137 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 60 50 40 30 20 10 0 Frequency H z dB ...

Page 149: ...mance Data Plots 6 1130B Series Probes User s Guide 149 Figure 138 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Zmin 197 6 Ω 25 kΩ 0 58 ...

Page 150: ...150 1130B Series Probes User s Guide 6 1131B Performance Data Plots N2851A QuickTip Head with N2849A QuickTip Figure 139 Input Impedances Modeled and Measured ...

Page 151: ... 164 E2678A B Differential Socketed Probe Head with Damped Wire Accessory 167 E2679B Single Ended Solder in Probe Head Full BW 170 E2679B Single Ended Solder in Probe Head Medium BW 173 N2851A QuickTip Head with N2849A QuickTip 176 This chapter provides graphs of the performance characteristics of the 1132B probes using the different probe heads that come with the E2668B single ended and E2669B di...

Page 152: ...th and without probe connected Figure 141 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 145 ps Vin tr 162 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vout tr 151 ps Vin tr 162 ps ...

Page 153: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 143 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 154: ...formance Data Plots Figure 144 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 229 2 Ω Zmin 153 4 Ω 50 kΩ 25 kΩ 0 57 0 32 ...

Page 155: ...th and without probe connected Figure 146 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 145 ps Vin tr 170 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 146 ps Vout tr 170 ps ...

Page 156: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 148 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 157: ...ance Data Plots 7 1130B Series Probes User s Guide 157 Figure 149 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Zmin 120 Ω 25 kΩ 0 65 pF ...

Page 158: ...nerator with and without probe connected Figure 151 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 145 ps Vin tr 158 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 158 ps Vout tr 172 ps ...

Page 159: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 153 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 160: ...mance Data Plots Figure 154 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 272 8 Ω Zmin 201 8 Ω 50 kΩ 25 kΩ 0 44 pF 0 27 pF ...

Page 161: ...generator with and without probe connected Figure 156 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 145 ps Vin tr 158 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 158 ps Vin tr 236 ps ...

Page 162: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 158 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 163: ...User s Guide 163 Figure 159 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 343 3 Ω Zmin 251 6 Ω 50 kΩ 25 kΩ 0 52 pF 0 33 pF ...

Page 164: ...enerator with and without probe connected Figure 161 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 145 ps Vin tr 162 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vout tr 185 ps Vin tr 162 ps ...

Page 165: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 163 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 166: ...mance Data Plots Figure 164 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 234 9 Ω Zmin 174 6 Ω 50 kΩ 25 kΩ 0 56 pF 0 34 pF ...

Page 167: ...step generator NOTE Due to reflections on the long wire accessories signals being probed should be limited to approximately 240 ps rise time measured at the 10 and 90 amplitude levels This is equivalent to approximately 1 5 GHz bandwidth 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 237 ps Vin tr 256 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x1...

Page 168: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 168 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 169: ...User s Guide 169 Figure 169 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 344 0 Ω Zmin 248 9 Ω 50 kΩ 25 kΩ 0 95 pF 0 63 pF ...

Page 170: ...generator with and without probe connected Figure 171 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 145 ps Vin tr 165 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 165 ps Vout tr 166 ...

Page 171: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 173 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 172: ...es Probes User s Guide 7 1132B Performance Data Plots Figure 174 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Zmin 142 9 Ω 25 kΩ 0 50 pF ...

Page 173: ...enerator with and without probe connected Figure 176 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 146 ps Vin tr 165 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 165 ps Vout tr 211 ps ...

Page 174: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 178 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 175: ...nce Data Plots 7 1130B Series Probes User s Guide 175 Figure 179 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Zmin 197 6 Ω 25 kΩ 0 58 pF ...

Page 176: ...176 1130B Series Probes User s Guide 7 1132B Performance Data Plots N2851A QuickTip Head with N2849A QuickTip Figure 180 Input Impedances Modeled and Measured ...

Page 177: ... Differential Socketed Probe Head with Damped Wire Accessory 193 E2679B Single Ended Solder in Probe Head Full BW 196 E2679B Single Ended Solder in Probe Head Medium BW 199 N5380B SMA Probe Head 202 N2851A QuickTip Head with N2849A QuickTip 204 This chapter provides graphs of the performance characteristics of the 1134B probes using the different probe heads that come with the E2668B single ended ...

Page 178: ...th and without probe connected Figure 182 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 98 ps Vin tr 124 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vout tr 109 ps Vin tr 124 ps ...

Page 179: ...and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 184 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout Vout Vin 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 180: ...mance Data Plots Figure 185 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 229 2 Ω Zmin 153 4 Ω 50 kΩ 25 kΩ 0 57 pF 0 32 pF ...

Page 181: ...th and without probe connected Figure 187 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 98 ps Vin tr 135 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 135 ps Vout tr 125 ps ...

Page 182: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 189 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 183: ...ance Data Plots 8 1130B Series Probes User s Guide 183 Figure 190 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Zmin 120 Ω 25 kΩ 0 65 pF ...

Page 184: ...p generator with and without probe connected Figure 192 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 98 ps Vin tr 116 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 116 Vout tr 121 ps ...

Page 185: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 194 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 186: ...mance Data Plots Figure 195 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 272 8 Ω Zmin 201 8 Ω 50 kΩ 25 kΩ 0 44 pF 0 27 pF ...

Page 187: ...generator with and without probe connected Figure 197 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 97 ps Vin tr 115 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 115 ps Vin tr 192 ps ...

Page 188: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 199 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 189: ...User s Guide 189 Figure 200 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 343 3 Ω Zmin 251 6 Ω 50 kΩ 25 kΩ 0 52 pF 0 33 pF ...

Page 190: ...enerator with and without probe connected Figure 202 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 99 ps Vin tr 127 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vout tr 107 ps Vin tr 127 ps ...

Page 191: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 204 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 192: ...mance Data Plots Figure 205 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 234 9 Ω Zmin 174 6 Ω 50 kΩ 25 kΩ 0 56 pF 0 34 pF ...

Page 193: ...step generator NOTE Due to reflections on the long wire accessories signals being probed should be limited to approximately 240 ps rise time measured at the 10 and 90 amplitude levels This is equivalent to approximately 1 5 GHz bandwidth 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 240 ps Vin tr 258 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x1...

Page 194: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 209 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 195: ... User s Guide 195 Figure 210 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Single ended Mode Input Differential Mode Input Zmin 344 0 Ω Zmin 248 9 Ω 50 kΩ 25 kΩ 0 95 0 63 pF ...

Page 196: ...with and without probe connected Figure 212 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 98 ps Vin tr 128 ps Vsource tr 98 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 128 ps Vout tr 118 ps ...

Page 197: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 214 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 198: ...es Probes User s Guide 8 1134B Performance Data Plots Figure 215 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Zmin 142 9 Ω 25 kΩ 0 50 pF ...

Page 199: ...generator with and without probe connected Figure 217 Graph of Vin and Vout of probe with a 25Ω 100 ps step generator 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vsource tr 98 ps Vin tr 120 ps 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x10 9 0 05 0 0 05 0 1 0 15 0 2 Tim e Seconds V olts Vin tr 120 ps Vout tr 180 ps ...

Page 200: ...Vin and Vout of probe with a 25Ω source and Vout Vin frequency response Figure 219 Graph of Vout Vin frequency response when inputs driven in common common mode rejection 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency H z dB Vout Vin Vin Vout 10 8 10 9 10 10 60 50 40 30 20 10 0 Frequency H z dB ...

Page 201: ...mance Data Plots 8 1130B Series Probes User s Guide 201 Figure 220 Magnitude plot of probe input impedance versus frequency 10 6 10 7 10 8 10 9 10 10 10 1 10 2 10 3 10 4 10 5 Frequency H z Ω Zmin 197 6 Ω 25 kΩ 0 58 ...

Page 202: ...fer to the Performance Plots chapter in the 1168 9B User s Guide Figure 221 Vincident and Vout of probe with a 90 ps step Figure 222 Magnitude plot of differential return loss 0 0 2 0 4 0 6 0 8 1 1 2 1 4 1 6 1 8 2 x 10 9 0 05 0 0 05 0 1 0 15 0 2 0 25 0 3 0 35 0 4 0 45 0 5 Time Seconds V olts Vout tr10 90 88 5 ps tr20 80 58 8 ps Vincident tr10 90 90 ps tr20 80 60 ps 10 8 10 9 10 10 60 50 40 30 20 1...

Page 203: ...1134B Performance Data Plots 8 1130B Series Probes User s Guide 203 Figure 223 Magnitude response of differential insertion loss 16 03 dB 10 8 10 9 10 10 12 9 6 3 0 3 6 Frequency Hz dB BW 3 dB 8 GHz ...

Page 204: ...204 1130B Series Probes User s Guide 8 1134B Performance Data Plots N2851A QuickTip Head with N2849A QuickTip Figure 224 Input Impedances Modeled and Measured ...

Page 205: ... describes how to verify the bandwidth performance of the probe CAUTION Electrostatic discharge ESD can quickly and imperceptibly damage or destroy high performance probes resulting in costly repairs Always wear a wrist strap when handling probe components and ensure that cables are discharged before being connected NOTE Allow the probe to warm up for at least 20 minutes ...

Page 206: ...oss thread or force any connectors This could be a very costly error to correct Table 30 Required Test Equipment Test Equipment Critical Specification Model Number Vector Network Analyzer VNA 7 GHz sweep range full 2 port cal Option 1D5 Keysight 8720ES Calibration Standards No Substitute Keysight 85052D External Power Supply No Substitute Keysight 1143A AutoProbe Interface Adapter No Substitute Ke...

Page 207: ...he probe under test to the Auto Probe Adapter and power the probe using the 1143A power supply Install the outside thread adapter to the Auto Probe Adapter Figure 225 Probe Connected to Power Supply Calibrating a Reference Plane To get a reliable measurement from the VNA you must calibrate a reference plane so that the VNA knows where the probe under test is located along the transmission line 7 O...

Page 208: ...short end of Calibration Standard to the non pincher side of the PV DS test board f Select short screen key under the Forward group g Wait until the VNA beeps indicating that it has completed the task h Connect load end of Calibration Standard to the non pincher side of the PV DS test board i Select the loads screen key under the Forward group j Press broadband screen key selection k Wait until th...

Page 209: ... it has completed the task e Connect short end of Calibration Standard to the available end of the PORT 2 SMA cable f Select short screen key the Reverse group g Wait until the VNA beeps indicating that it has completed the task h Connect load end of Calibration Standard to the available end of the PORT 2 SMA cable i Select the loads screen key the Reverse group j Press broadband screen key select...

Page 210: ...aging to off 24 Save the reference plane cal by pressing the save recall key then the save state key 25 You may change name if you wish 26 Press the scale reference key Then set the scale to 1 dB per division and the reference position for 7 divisions 27 Set reference value for 0 dB 28 Press the measure key 29 Press the s21 screen key 30 Ensure s21 response on screen is flat about 0 1 dB out to 10...

Page 211: ... as shown in the following figure Figure 229 Probe Locations on PV Fixture 34 Press the Sweep Setup key on the VNA Then press the trigger menu screen key Select the continuous screen key 35 The Vin waveform shown on screen should be similar to that shown in Figure 230 on page 211 Figure 230 Typical Vin Waveform for an 1134B Probe 36 Select display key then data memory screen key 37 You have now sa...

Page 212: ... reference value to 20 dB 42 Hold probe in place as described previously 43 The display on screen is Vout and it should be similar to that shown in Figure 231 on page 212 Figure 231 Typical Vout Waveform for an 1134B Probe Displaying the Vout Vin Response 44 Press the Display key 45 Then select the Data Memory screen key You may need to adjust the Reference Value located under the Scale Ref key sl...

Page 213: ...e 46 Press marker key and position the marker to the first point that the signal is 3 dB below center screen 47 Read marker frequency measurement and record it in the test record located later in this chapter 48 The bandwidth test passes if the frequency measurement is greater that the probe s bandwidth limit ...

Page 214: ...e 9 Performance Verification Performance Test Record Table 31 Performance Test Record Model Date Recommended next test date Serial Tested by Probe Amplifier Test Limits Result Pass Fail 1130B 1 5 GHz 1131B 3 5 GHz 1132B 5 GHz 1134B 7 GHz ...

Page 215: ...ng effects of the InfiniiMax active probes Important points about these SPICE models are SPICE models shown here are currently only for input impedance which allows modeling of the probe loading effects Probe transfer function is generally flat to the specified BW Transfer function SPICE models may be added later if demand is sufficient These input impedance is a function of the probe head type on...

Page 216: ...or in the probe head model There is one SPICE schematic for the differential probe heads and one SPICE schematic for the single ended probe heads The schematics have parameterized R L and C values that are given in the SPICE deck for the specific probe head Additionally an input impedance plot is given that shows the matching of the measured data to the modeled data Matching is generally very good...

Page 217: ... and no effect on differential input Z Cgpl and Cgml represent C from probe tips to DUT ground near probe tips If using diff probe to probe single ended signals vplus connected to DUT signal vminus connected to DUT ground with means that Rc 0 and Zsrcm 0 Input impedance is defined to be vplus i vsplus If using diff probe to probe differential signals Rc or Zc will depend on the DUT circuit vplus c...

Page 218: ...for Single Ended Probe Heads Rtn Zrtn is dependent on connection from DUT ground to Earth ground Most likely modeled by a parallel RL similar to Rom Lom Will have slight effect on input Z Probe tip C to DUT ground lumped into Csgl since there is no damping R in ground path Input impedance is defined as vplus i vsplus ...

Page 219: ...1 99 95 value cm 2 Cgp3 86 122 value cg2 2 Cm2 85 84 value cm 2 Cgm4 122 vdom value cg2 2 Cgm3 122 87 value cg2 2 Cgp4 vdop 122 value cg2 2 Ctp vdop 88 value ct Ctm 89 vdom value ct Lm3 84 87 value l1 4 Lp3 86 85 value l1 4 Lm4 89 87 value l2 Lp4 86 88 value l2 Lp1 118 vplus value l1 4 Lp2 85 99 value l1 2 Lm1 vminus 117 value l1 4 Lm2 95 84 value l1 2 Lom 122 0 value lom Rrtn DUT_Ground 0 0001 Rc...

Page 220: ...320f ct 200f vsminus 164 vminus ACMag sweep 1 0 vsplus vplus 164 ACMag sweep 1 1 Cgp1 DUT_Ground 99 value cg1 2 Cgp2 122 85 value cg1 2 Cgm2 84 122 value cg1 2 Cgm1 95 DUT_Ground value cg1 2 Cm1 99 95 value cm 2 Cgp3 86 122 value cg2 2 Cm2 85 84 value cm 2 Cgm4 122 vdom value cg2 2 Cgm3 122 87 value cg2 2 Cgp4 vdop 122 value cg2 2 Ctp vdop 88 value ct Ctm 89 vdom value ct ...

Page 221: ... vplus value l1 4 Lp2 85 99 value l1 2 Lm1 vminus 117 value l1 4 Lm2 95 84 value l1 2 Lom 122 0 value lom Rrtn DUT_Ground 0 0001 Rc 164 DUT_Ground 0001 Rlossp 99 159 value rloss Rlossm 160 95 value rloss Rdp 159 118 value rd Rdm 117 160 value rd Rtm vdom 89 value rt Rtp 88 vdop value rt Rcxp vdop 122 50 Rcxm 122 vdom 50 Rom 122 0 value rom ...

Page 222: ...99 95 value cm 2 Cgp3 86 122 value cg2 2 Cm2 85 84 value cm 2 Cgm4 122 vdom value cg2 2 Cgm3 122 87 value cg2 2 Cgp4 vdop 122 value cg2 2 Ctp vdop 88 value ct Ctm 89 vdom value ct Lm3 84 87 value l1 4 Lp3 86 85 value l1 4 Lm4 89 87 value l2 Lp4 86 88 value l2 Lp1 118 vplus value l1 4 Lp2 85 99 value l1 2 Lm1 vminus 117 value l1 4 Lm2 95 84 value l1 2 Lom 122 0 value lom Rrtn DUT_Ground 0 0001 Rc 1...

Page 223: ... cg1 270f cg2 370f ct 200f ac dec 77 200k 19 7g options map vsplus 130 165 ACMag 1 Csg4 vsop 134 value cg2 2 Cstp vsop 131 value ct Csg2 138 139 value cg1 2 Csg3 132 134 value cg2 2 Csg1 137 136 value cg1 2 Lsp1 141 130 value l1 3 8 Lsp2 138 137 value l1 3 4 Lsg1 165 164 value l1 8 Lsg2 136 139 value l1 4 Lsom 134 0 value lom Lsp4 132 131 value l2 ...

Page 224: ...User s Guide 10 SPICE Models Lsp3 132 138 value l1 3 8 Lsg3 139 134 value l1 8 Rtrn 165 0 0001 Rdummy 164 136 0001 Rslossp 137 161 value rloss Rdsp 161 141 value rd Rstp 131 vsop value rt Rscxp vsop 134 50 Rsom 134 0 value rom ...

Page 225: ...ag 1 Csg4 vsop 134 value cg2 2 Cstp vsop 131 value ct Csg2 138 139 value cg1 2 Csg3 132 134 value cg2 2 Csg1 137 136 value cg1 2 Lsp1 141 130 value l1 3 8 Lsp2 138 137 value l1 3 4 Lsg1 165 164 value l1 8 Lsg2 136 139 value l1 4 Lsom 134 0 value lom Lsp4 132 131 value l2 Lsp3 132 138 value l1 3 8 Lsg3 139 134 value l1 8 Rtrn 165 0 0001 Rdummy 164 136 0001 Rslossp 137 161 value rloss Rdsp 161 141 v...

Page 226: ...226 1130B Series Probes User s Guide 10 SPICE Models ...

Page 227: ...to DUT ground Models all modes of input impedance Diff Common and A or B subckt N2849A_N2851A 1 2 r1 1 3 1e8 r2 2 3 1e8 r9 3 0 5e8 r_srlc2 5 7 201 895 l_srlc2 7 8 4 24047n c_srlc2 8 6 101 955f r_srlc3 4 9 190 712 l_srlc3 9 10 8 8192n c_srlc3 10 6 7 86088f r_srlc1 4 11 325 561 l_srlc1 11 12 2 89997n c_srlc1 12 6 315 986f r3 4 13 260 c1 13 6 200f r5 13 6 50k r8 6 0 1e 6 r4 14 16 130 r_srlc4 14 18 17...

Page 228: ...228 1130B Series Probes User s Guide 10 SPICE Models ...

Page 229: ...bes User s Guide 11 Replacement Parts E2675B Differential Browser Probe Head 230 E2677B Differential Solder In Probe Head 230 E2678A B Differential Socketed Probe Head 231 E2679B Single Ended Solder in Probe Head 231 Other Accessories 232 ...

Page 230: ... Resistive tip blue 91Ω 20 Ergonomic handle 1 Table 33 E2670B Kit Description Qty Supplied 91Ω resistor for full bandwidth 20 150Ω resistor for medium bandwidth 10 91Ω resistor template 1 150Ω resistor template 1 Table 34 Resistors Description Qty Order From Vendor Orderable Part Number 91Ω resistor 1 BREL International RMB16 910 JB 150Ω resistor 1 BREL International RMB16A 151 JB ...

Page 231: ...l 25 1000 inch square pins female on both ends 4 25 mil female socket w 20 mil round male pin on other end 4 Heatshrink socket accessory 4 Header adapter 91Ω 2 82Ω resistor template 1 Table 36 Resistors Description Qty Order From Vendor Orderable Part Number 82Ω resistor 1 Vishay MBA0204AC8209GC100 Table 37 Resistors Description Qty Order From Vendor Orderable Part Number 0Ω resistor 1 BREL Intern...

Page 232: ... E5381 82103 1 Header adapter kit for socketed differential probe head 01130 63201 10 each Keysight 01131 68703 1 Coupling tag for N5450B extreme temperature cable extension Keysight N5450 21201 1 SMA coaxial dc block Inmet 8037 1 SMA 6 dB coaxial attenuator Inmet 18AH 6 1 SMA 12 dB coaxial attenuator Inmet 18AH 12 1 SMA adjustable delay ATM Microwave P1907 1 GPO F to GPO F adapter for N5380B Corn...

Page 233: ...cteristics 94 H header adapter 73 humidity 94 I Infiniium oscilloscope 10 InfiniiVision oscilloscope 10 inspecting 10 K Keysight Technologies contacting 34 M medium bandwidth 67 69 MX0100A dimensions 97 MX0100A lead wires 40 MX0100A strain relief 44 MX0102A 29 N N2849A QuickTip 61 N2851A QuickTip 60 N2880A attenuators 24 N2880A InfiniiMax In Line Attenuator 24 N2881A InfiniiMax DC Blocking Caps 28...

Page 234: ...B Series Probes User s Guide Index soldering toolkit 29 specifications 91 215 T temperature 94 temperature chamber 23 temperature ranges 23 trim gauge template 41 V velcro dots 15 W WEEE compliance 95 weight 94 ...

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