Agilent 4263B LCR Meter Operation Manual Manual Change Agilent Part No. N/A Jun 2009 Change 1 Add TAR in Test Signal Frequency Accuracy Test (Page 9-38) as follows. Test Signal Frequency Accuracy Frequency Limits [Hz] Result1 [Hz] [Hz] 100 120 1k 10 k 20 k 100 k ±0.01 ±1.2 ±0.00010 k ±0.0010 k ±0.0020 k ±0.010 k Uncertainty [Hz] k k k k TAR ± 0.00031 ± 0.00034 ± 0.0000029 k ± 0.000019 k ± 0.000020 k ± 0.00019 k 31.77 3550.50 35.38 53.80 100.32 53.
Change 4 Add TAR in 0 m Impedance Measurement Accuracy Test (Page 9-40 to 9-42) as follows.
1 μF 100 k D ±0.0176 ± 0.00032 55.73 Note 1: Result = Measurement – Calibrated Value of Standard Measurement: Cable length: Measurement time: Test signal level: Status Frequency [Hz] Standard 10 nF 10 nF 10 nF 10 nF 100 100 100 k 100 k Capacitance 0m Med 50 mV PASS Parameter Cp D Cp D Limits ± 0.063 nF ±0.0063 ± 0.271 nF ±0.0271 Uncertainty Result1 nF ± 0.00070 nF ± 0.000043 nF ± 0.0023 nF ± 0.00044 TAR 89.93 146.37 119.28 62.
Measurement time: Med Test signal level: 500 mV Status PASS Frequency [Hz] Standard Parameter Limits 100 100 mΩ R ±0.62 mΩ Note 1: Result = Measurement – Calibrated Value of Standard Measurement: Resistance Cable length: 0m Measurement time: Short Test signal level: 500 mV Status PASS Frequency [Hz] Standard Parameter Limits 100 100 mΩ R ±1.10 mΩ Note 1: Result = Measurement – Calibrated Value of Standard Measurement: Cable length: Measurement time: Test signal level: Status Result1 mΩ Uncertainty ± 0.
Change 5 Add TAR in 1 m Impedance Measurement Accuracy Test (Page 9-43) as follows. Measurement: Cable length: Measurement time: Test signal level: Status Frequency [Hz] Standard 100 pF 1k 100 pF 1k 100 pF 10 k 100 pF 10 k 100 pF 20 k 100 pF 20 k 100 pF 100 k 100 pF 100 k 1 nF 100 1 nF 100 1 μF 100 1 μF 100 1 μF 1k 1 μF 1k 1 μF 10 k 1 μF 10 k 1 μF 100 k 1 μF 100 k Capacitance 1m Long 1V PASS Parameter Cp D Cp D Cp D Cp D Cp D Cp D Cp D Cp D Cp D Limits ±0.19 pF ±0.0019 ±0.48 pF ±0.0048 ±1.10 pF ±0.
Change 6 Add TAR in 2 m Impedance Measurement Accuracy Test (Page 9-44) as follows. Measurement: Cable length: Measurement time: Test signal level: Status Frequency [Hz] Standard 100 pF 1k 100 pF 1k 100 pF 10 k 100 pF 10 k 100 pF 20 k 100 pF 20 k 1 nF 100 1 nF 100 1 μF 100 1 μF 100 1 μF 1k 1 μF 1k 1 μF 10 k 1 μF 10 k Capacitance 2m Long 1V PASS Parameter Cp D Cp D Cp D Cp D Cp D Cp D Cp D Limits ±0.19 pF ±0.0019 ±0.51 pF ±0.0051 ±1.10 pF ±0.0110 ±0.002 nF ±0.0020 ±0.0018 μF ±0.0018 ±0.0011 μF ±0.0011 ±0.
Change 7 Add TAR in 4 m Impedance Measurement Accuracy Test (Page 9-45) as follows. Measurement: Cable length: Measurement time: Test signal level: Status Frequency [Hz] Standard 100 pF 1k 100 pF 1k 1 nF 100 1 nF 100 1 μF 100 1 μF 100 1 μF 1k 1 μF 1k Capacitance 4m Long 1V PASS Parameter Cp D Cp D Cp D Cp D Limits ±0.19 pF ±0.0019 ±0.002 nF ±0.0020 ±0.0018 μF ±0.0018 ±0.0011 μF ±0.0011 Uncertainty Result1 pF ± 0.0078 pF ± 0.000065 nF ± 0.000089 nF ± 0.000062 ± 0.000077 μF μF ± 0.000047 ± 0.
Agilent 4263B LCR Meter Operation Manual Manual Change Agilent Part No. N/A July 2008 Change 1 Change the Measurement Uncertainty value of Test Signal Frequency Accuracy Test (Page 9-38) to the following information. Test Signal Frequency 100 Hz 120 Hz 1 kHz 10 kHz 20 kHz 100 kHz Test Result1 Test Limits ±0.010 Hz ±1.200 Hz ±0.00010 kHz ±0.0010 kHz ±0.0010 kHz ±0.010 kHz Measurement Uncertainty Hz Hz kHz kHz kHz kHz ± 0.00031 Hz ± 0.00034 Hz ± 0.0000029 kHz ± 0.000019 kHz ± 0.000020 kHz ± 0.
Change 3 Change the Measurement Uncertainty value of DC Bias Level Accuracy Test (Page 9-39) to the following information. DC Bias Level Test Limits 0V 1.5 V 2V ±0.002 V ±0.077 V ±0.102 V Measurement Uncertainty Test Result1 V V V ± 0.088 mV ± 0.44 mV ± 0.92 mV Change 4 Change the Measurement Uncertainty value of 0 m Impedance Measurement Accuracy Test for 0 m Capacitance Measurement Accuracy Test (Meas. Time Mode: LONG) (Page 9-40) to the following information.
Change the Measurement Uncertainty value of 0 m Impedance Measurement Accuracy Test for 0 m Capacitance Measurement Accuracy Test (Meas. Time Mode: LONG) (Page 9-41) to the following information. Standard Test Signal Frequency Parameter Measured Test Limits 1 μF 100 Hz 1 μF 120 Hz 1 μF 1 kHz 1 μF 10 kHz 1 μF 100 kHz Cp D Cp D Cp D Cp D Cp D ±0.0018 μF ±0.0018 ±0.0018 μF ±0.0018 ±0.0011 μF ±0.0011 ±0.0026 μF ±0.0026 ±0.0176 μF ±0.0176 Test Result1 pF pF pF pF pF Measurement Uncertainty ± 0.
Change 7 Change the Measurement Uncertainty value of 0 m Impedance Measurement Accuracy Test for 0 m Capacitance Measurement Accuracy Test (DC Bias: ON) (Page 9-41) to the following information. Standard 1 μF Test Signal Parameter Frequency Measured 1k Cp D Test Limits Test Result1 ±0.0011 μF ±0.0011 μF Measurement Uncertainty ± 0.000066 μF ± 0.000033 Change 8 Change the Measurement Uncertainty value of 0 m Impedance Measurement Accuracy Test for 0 m Resistance Measurement Accuracy Test (Meas.
Change 11 Change the Measurement Uncertainty value of 0 m Impedance Measurement Accuracy Test for 0 m DC Resistance Measurement Accuracy Test (Opt. 001 Only) (Page 9-42) to the following information. Standard Test Limits 100 mohm 100 kohm ±0.97 mohm ±0.87 kohm Measurement Uncertainty Test Result1 mohm kohm ± 0.039 mohm ± 0.
Change 14 Change the Measurement Uncertainty value of 1 m Impedance Measurement Accuracy Test for 1 m DC Resistance Measurement Accuracy Test (Opt. 001 Only) (Page 9-43) to the following information. Standard Test Limits 100 mohm 100 kohm ±1.05 mohm ±0.87 kohm Measurement Uncertainty Test Result1 mohm kohm ± 0.030 mohm ± 0.
Change 16 Change the Measurement Uncertainty value of 2 m Impedance Measurement Accuracy Test for 2 m DC Resistance Measurement Accuracy Test (Opt. 001 Only) (Page 9-44) to the following information. Standard Test Limits 100 mohm 100 kohm ±1.13 mohm ±0.87 kohm Measurement Uncertainty Test Result1 mohm kohm ± 0.030 mohm ± 0.
Change 19 Change the Measurement Uncertainty value of 4 m Impedance Measurement Accuracy Test for 4 m DC Resistance Measurement Accuracy Test (Opt. 001.Only) (Page 9-45) to the following information. Standard Test Limits 100 mohm 100 kohm ±1.29 mohm ±0.87 kohm C Copyright 2007 Agilent Technologies ○ Test Result1 mohm kohm Measurement Uncertainty ± 0.030 mohm ± 0.
Agilent 4263B LCR Meter Operation Manual Manual Change Agilent Part No. N/A July 2007 Change 1 Add the following steps to the step 2 of DC Bias Level Accuracy Test (page 9-9). 2-a. Set the test signal frequency to 100 kHz using Freq. 2-b. Set the test signal level to 50 mV using Level. Change 2 Change the figure 9-4 of DC Bias Level Accuracy Test Setup without the Interface Box (page 9-10) as follows.
マニュアル チェンジ 変更 1 DC バイアス・レベル確度試験の手順 2(ページ 9-9)に以下の手順を追加して下さい。 2-a. Freq を押して測定信号周波数を 100 kHz に設定します。 2-b.
Agilent 4263B LCR Meter Operation Manual Manual Change Agilent Part No. N/A June 2007 Change 1 Add the following note to the “3-c. Turning On the 4263B and Setting the Line Frequency” (page 1-13). Note In case the setting of the ac line frequency is not match, there’s any possibility the measurement error will rise. Make sure the ac line frequency has been set up correctly. Change 2 Add the following condition to the “Measurement Accuracy” (page 8-3). 5. The ac line frequency has been set up correctly.
マニュアル チェンジ 変更 1 電源投入と電源周波数の設定の手順 3-c(ページ 1-11)に以下の注記を追加して下さい。 注記 AC 電源周波数の設定値が一致していない場合、測定誤差が増大する可能性があります。必ず AC 電源周波数 を正しく設定して下さい。 変更 2 測定確度の条件(ページ 8-3)に以下の条件を追加して下さい。 5.
Safety Summary When you notice any of the unusual conditions listed below, immediately terminate operation and disconnect the power cable. Contact your local Agilent Technologies sales representative or authorized service company for repair of the instrument. If you continue to operate without repairing the instrument, there is a potential fire or shock hazard for the operator. n Instrument operates abnormally. n Instrument emits abnormal noise, smell, smoke or a spark-like light during the operation.
Caution Do not apply DC voltage or current to the UNKNOWN terminals. Do not apply External DC bias voltage more than +2.5V. Doing so will damage the 4263B. Before you measure a capacitor, be sure the capacitor is fully discharged.
Agilent 4263B LCR Meter Operation Manual SERIAL NUMBERS This manual applies directly to instruments which has the serial number pre x JP1KD, or rmware revision 1.0. For additional important information about serial numbers, read \Serial Number" in Appendix A. Agilent Part No.
Notice The information contained in this document is subject to change without notice. This document contains proprietary information that is protected by copyright. All rights are reserved. No part of this document may be photocopied, reproduced, or translated to another language without the prior written consent of the Agilent Technologies. Agilent Technologies Japan, Ltd.
4263B Manual Printing History February 1996 : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : First Edition (part number: June 1998 : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : Second Edition (part number: January 2000 : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : Third Edition (part number: December 2000 : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : Fourth Edition (part number: Se
4263B Safety Summary The following general safety precautions must be observed during all phases of operation, service, and repair of this instrument. Failure to comply with these precautions or with speci c WARNINGS elsewhere in this manual may impair the protection provided by the equipment. In addition it violates safety standards of design, manufacture, and intended use of the instrument. The Agilent Technologies assumes no liability for the customer's failure to comply with these requirements.
4263B Certi cation Agilent Technologies certi es that this product met its published speci cations at the time of shipment from the factory. Agilent Technologies further certi es that its calibration measurements are traceable to the United States National Institute of Standards and Technology, to the extent allowed by the Institution's calibration facility, or to the calibration facilities of other International Standards Organization members.
4263B Exclusive Remedies The remedies provided herein are buyer's sole and exclusive remedies. Agilent Technologies shall not be liable for any direct, indirect, special, incidental, or consequential damages, whether based on contract, tort, or any other legal theory. Assistance Product maintenance agreements and other customer assistance agreements are available for Agilent Technologies products. For any assistance, contact your nearest Agilent Technologies Sales and Service O ce.
4263B Safety Symbols General de nitions of safety symbols used on equipment or in manuals are listed below. Instruction manual symbol: the product is marked with this symbol when it is necessary for the user to refer to the instruction manual. Alternating current. Direct current. On (Supply). O (Supply). Frame or chassis terminal This Warning sign denotes a hazard.
4263B Herstellerbescheinigung GERX SCHEMISSION LpA < 70 dB am Arbeitsplatz normaler Betrieb nach DIN 45635 T.
4263B Contents of this Manual Chapter 1 Provides the product overview and basic measurement procedure. First time users of the 4263B should read this chapter rst. Chapter 2 Shows how to operate the 4263B from its front panel. Please refer to this chapter when you wish to learn about operations using the front panel keys. Chapter 3 Describes all functions of this instrument. Please refer to this chapter when you wish to learn about the functions of the front and rear panel keys and terminals.
4263B Appendix A Contains information on using the 4263Bs which were manufactured before this manual was printed. Appendix B Contains information which is required for using the handler interface. Before using the handler interface, please read this appendix and set the handler interface input/output signal. Appendix C Contains the summary of operations, when the 4263B detects OVLD (Overload), or N.C. (No-Contact).
Contents 1. Getting Started Overview . . . . . . . . . . . . . . . . . . . . . . Features . . . . . . . . . . . . . . . . . . . . . Accessories Available . . . . . . . . . . . . . . . . Options Available . . . . . . . . . . . . . . . . . Guided Tour of Panels . . . . . . . . . . . . . . . . Front Panel . . . . . . . . . . . . . . . . . Display . . . . . . . . . . . . . . . . . . . . . . Rear Panel . . . . . . . . . . . . . . . . . . Incoming Inspection . . . . . . . . . . . . . . . . .
2. Operating the 4263B Measurement Con guration . . . . . . . . . . . . Selecting Measurement Time Mode . . . . . . . . Setting the Averaging Rate . . . . . . . . . . . . Setting Trigger Delay Time . . . . . . . . . . . . Setting Contact Check . . . . . . . . . . . . . . Setting the Beeper Mode . . . . . . . . . . . . . Setting the Level Monitor Mode . . . . . . . . . . Triggering a Measurement . . . . . . . . . . . . . Applying the DC Bias . . . . . . . . . . . . . . . Using the Internal DC Bias Source . .
DC Bias Setup Key . . . . . . . . . Auto/Hold Range Key . . . . . . . . . . Range Setup Key . . . . . . . . . . Trigger Key . . . . . . . . . . . . . . . Trigger Mode Key . . . . . . . . . . . . Delay Key . . . . . . . . . . . . . Local Key . . . . . . . . . . . . . . . . Address Key . . . . . . . . . . . . Save Key . . . . . . . . . . . . . Recall Key . . . . . . . . . . . . . . . Comparator Limit Keys . . . . . . Left/Down Arrow Key and Up/Right Arrow Key, 0,1,..,9,1(Point),0(Minus) Keys, ... Enter Key .
Power Code . . . . . . . . . . . . . Handler Interface . . . . . . . . . . . Speci cation . . . . . . . . . . . . . GPIB Interface . . . . . . . . . . . . Technical Information . . . . . . . . . . Overall Impedance Measurement Theory Transformer Parameters Measurement . Test Current Level . . . . . . . . . . . Test Current Transient . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5. GPIB Reference GPIB Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Common Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . Subsystem Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . Concept of Subsystem Command Tree . . . . . . . . . . . . . . . . . . . . . Program Message Syntax . . . . . . . . . . . . . . . . . . . . . . . . . . . Case . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Program Message Terminator . . . . . . . . .
:INITiate[:IMMediate] . . . . . . . . . . . . . . . . . . . . . . . . . . :lNITiate:CONTinuous fONjOFFj1j0g . . . . . . . . . . . . . . . . . . . SENSe Subsystem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . [:SENSe]:AVERage:COUNt . . . . . . . . . . . . . . . [:SENSe]:AVERage[:STATe] f ON j OFF j 1 j 0 g . . . . . . . . . . . . . . . [:SENSe]:CORRection:CKIT:STANdard3 , [:SENSe]:CORRection:COLLect[:ACQuire] STANdardf1j2j3g . . . . . . . . .
3RST . . . . . . . . . 3SAV 3SRE 3SRE? . . . . . . . . . 3STB? . . . . . . . . . 3TRG . . . . . . . . . 3TST? . . . . . . . . . 3WAI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Status Reporting Structure . . . . . . Service Request (SRQ) . . . . . . . Status Byte Register . . . . . . . . Statndard Event Status Register . . Standard Operation Status Group . . Operation Status Register . . . . . Questionable Status Register .
8. Speci cations Speci cations . . . . . . . . . . . . . . Measurement Parameters . . . . . . . . Measurement Conditions . . . . . . . . Measurement Range . . . . . . . . . . Measurement Accuracy . . . . . . . . Measurement Support Functions . . . . General . . . . . . . . . . . . . . . . Supplemental Performance Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2 m Resistance Measurement Accuracy Test . . . . . . . . . . 2 m DC Resistance Measurement Accuracy Test (Opt. 001 Only) . 4 m Impedance Measurement Accuracy Test . . . . . . . . . . . . Speci cation . . . . . . . . . . . . . . . . . . . . . . . . . . Test Equipment . . . . . . . . . . . . . . . . . . . . . . . . Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 m Capacitance Measurement Accuracy Test . . . . . . . . . 4 m Resistance Measurement Accuracy Test . . . . . . . . . .
B. Handler Interface Installation Introduction . . . . . . . . . . Electrical Characteristics . . . . Output Signals . . . . . . . . Input Signals . . . . . . . . Handler Interface Board Setup . Tools and Fasteners . . . . . . Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Figures 1-1. 1-2. 1-3. 3-1. 3-2. 3-3. 3-4. 3-5. 3-6. 3-7. 3-8. 3-9. 3-10. 3-11. 3-12. 3-13. 4-1. 4-2. 4-3. 4-4. 4-5. 4-6. 4-7. 5-1. 5-2. 5-3. 5-4. 5-5. 5-6. 5-7. 5-8. 5-9. 5-10. 5-11. 6-1. 6-2. 6-3. 7-1. 7-2. 7-3. 7-4. 7-5. 7-6. 7-7. Power Cable Supplied . . . . . . . . . . . . . . . . . . . . . . . . . . . Voltage Selector and Fuse . . . . . . . . . . . . . . . . . . . . . . . . . Connecting a Test Fixture . . . . . . . . . . . . . . . . . . . . . . . . . Front Panel . . . . . . . . . . . . . . . . . . .
7-8. 7-9. 7-10. 7-11. 7-12. 8-1. 8-2. 9-1. 9-2. 9-3. 9-4. 9-5. 9-6. 9-7. 9-8. 9-9. 9-10. 9-11. 9-12. A-1. B-1. B-2. B-3. B-4. Contact Con guration . . . . . . . . . . . . . . . . . . . Measurement Contacts for Test Lead Extension . . . . . . . Example of DUT Guard Plate Connection . . . . . . . . . . Guard Shield . . . . . . . . . . . . . . . . . . . . . . . Stray Capacitance Causing Contact Check Error . . . . . . . Conversion Diagram . . . . . . . . . . . . . . . . . . . . Maximum Capacitor Voltage . . .
Tables 1-1. 3-1. 3-2. 3-3. 3-4. 3-5. 5-1. 5-2. 5-3. 5-4. 5-5. 5-6. 5-7. 5-8. 7-1. 7-2. 8-1. 8-2. 8-3. 8-4. 8-5. 8-6. 8-7. 9-1. 9-2. 9-3. 9-4. 9-5. 9-6. 9-7. 9-8. 9-9. 9-10. 9-11. 9-12. 9-13. 9-14. 9-15. 9-16. 9-17. 9-18. A-1. B-1. B-2. B-3. C-1. Line Voltage Selection . . . . . . . . . . . . . . . . Measurement Range Selection . . . . . . . . . . . . Displayable Range . . . . . . . . . . . . . . . . . . Line Voltage selection . . . . . . . . . . . . . . . . Pin Assignment of Handler Interface Connector . .
C-2. Simultaneous OVLD and N.C. Condition . . . . . . . . . . . . . . . . . . .
1 Getting Started This chapter provides information to get you started using your 4263B LCR Meter.
4263B Overview 4263B LCR Meter is a general purpose LCR meter designed for both component evaluation on the production line and fundamental impedance testing for bench-top applications. Features Basic accuracy: 0.
4263B Accessories Available (Note: This is an optional product.
4263B Guided Tour of Panels Front Panel This section gives a guided tour of the front panel. For a detailed description of each key's function, refer to Chapter 3. Each description starting with (Shift) is the secondary function of the key, which is available by pressing the blue shift key. (Refer to \Shift key.") 1. Display displays measurement result, instrument states, and messages. 2. LINE Switch turns the 4263B ON and OFF. 3. Chassis Terminal is tied to ground through the instrument's chassis. 4.
4263B 11. Measurement Parameter Key selects the measurement parameter to be displayed. (Shift) Deviation Measurement Mode (1Mode) Key - advances the display page when the measurement parameters are being set. 12. Frequency Key sets the test signal frequency. (Shift) Display Mode Key selects the display mode. 13. Level Key sets the test signal level. (Shift) Bias Setup Key selects the DC bias voltage. 14. Trigger Mode Key selects the trigger mode from Internal, Manual, or External.
4263B height 0 Key / (Shift) Key Lock Key locks out any key input except for this key. . Key / (Shift) Reset Key resets the 4263B to the default state. 0 Key / (Shift) Con guration Key sets the beeper setting and the power line frequency, and executes the internal test. 3 Key / (Shift) Cable Key sets the cable length. 2 Key / (Shift) Contact Check Key toggles the contact check function between ON and OFF. 1 Key / (Shift) Comparator Key toggles the comparator function between ON and OFF.
4263B Display This section introduces the display. For a more detailed description of each display eld, refer to Chapter 3. 1. Character Display Area displays the measurement result, instrument setting, and instrument messages. 2. Annunciator ( 9 ) points to the currently selected instrument setting. The Annunciator labels are as follows: a. Measurement Time indicates the current measurement time. b. Trigger indicates the current trigger mode. c.
4263B Rear Panel This section gives a tour of the rear panel. For a more detailed description of each item on the rear panel, refer to Chapter 3. Caution Do not apply External DC bias voltage more than +2.5 V. Doing so will damage the 4263B 1. GPIB Interface is used to control the 4263B from an external controller by using the General Purpose Interface Bus ( gpib ). 2. External DC Bias Terminal is used to input an external DC bias. 3. 4. 5. 6. 7. 8.
4263B Incoming Inspection Warning To avoid hazardous electrical shock, do not turn on the 4263B when there are signs of shipping damage to any portion of the outer enclosure (for example, covers, panel, or display) Inspect the shipping container for damage. If the shipping container or cushioning material is damaged, it should be kept until the contents of the shipment have been checked for completeness and the 4263B has been checked mechanically and electrically.
4263B Power Cable In accordance with international safety standards, this instrument is equipped with a three-wire power cable. When connected to an appropriate ac power outlet, this cable grounds the instrument frame. The type of power cable shipped with each instrument depends on the country of destination. Refer to Figure 1-1 for the part numbers of the power cables available. Warning For protection from electrical shock, the power cable ground must not be defeated.
4263B Figure 1-1.
4263B Preparation for Turning On Before you use the 4263B, you must set it to match the available power line voltage and frequency. Set power line voltage | refer to \Setting the Line Voltage". Set power line frequency { refer to \Turning On the 4263B and Setting the Line Frequency".
4263B Turning On the 4263B and Setting the Line Frequency 1. Connect the power cable to Power Cord Receptacle on the rear panel. 2. Push the LINE switch in and the 4263B will emit a beep when it turns on. (If any message is displayed after the power-on self-test, refer to Messages back of this manual.) The 4263B will be ready for operation after a message similar to the one shown in the following gure. 3. Con rm that the power line frequency is set correctly. a. press .The following is displayed. b.
4263B Using the Front-Panel Keys The 4263B has four types of key operations as follows: Direct Execution Type Keys Toggle Type Keys Selection Type Keys Value Setup Type Keys This section shows the operation procedures for the 4263B when the front panel keys are used. Note If you want to exit an operation and go back to the measurement mode, press several times until you are back to the measurement mode.
4263B Value Setup Type Keys Pressing a value setup type key will display the parameter entry display and prompt you to enter a value. For example, 1. Press . The display is shown below. The displayed value can be altered by using the following keys: Numeric Keys Maximum and Minimum Keys Back Space Key Down and Up Arrow Keys Numeric Keys Input the value which the 4263B will actually use. For example, to set the averaging rate to 10, 1. Press . 2. Press .
4263B 2. Press again. 100nF will be displayed. 3. Press . 100pF will be displayed again. 4. Press to exit. Note Before you press , the previous setting is still the current setting, even if the displayed value has changed. If you press a key other than one of the keys in the ENTRY block before pressing , the setting will not change and the displayed value will be discarded. Minimum and Maximum Keys These keys enter the maximum and minimum numeric value in place of having to use the numeric keys.
4263B Back Space Key Erases the last entered character, and cancels the input value. For example, 1. Press to select the comparator limit menu. . 2. Press 3. Press . The number 4 which was entered last is erased.
4263B Basic Operation The following procedure is commonly used to perform a measurement using the 4263B: 1. Con guration setup 2. Turning on the 4263B 3. Settting parameters 4. Error correction 5. Connecting the DUT to the test xture 6. Measurement This section provides the basic measurement procedure of the 4263B. Follow the instructions and become familiar with the 4263B's operation.
4263B Connecting a Test Fixture Use the test xture suitable for your DUT type. The available xtures are shown in \Accessories Available". Figure 1-3.
4263B Resetting the 4263B Resetting the 4263B changes its settings to their default states. The 4263B's settings are held in backup memory for about 72 hours after the 4263B is turned OFF. So resetting is recommended when you start new measurements, even if you have just turned ON the 4263B. 1. Press to select the reset menu. 2. Press until Yes is blinking, then press . For more information about the default state settings of the 4263B, refer to \Reset Key " in Chapter 3.
4263B Selecting the Measurement Parameter The 4263B can measure the following parameters: Primary Z Y R G Cp Cs Lp Ls L2 Secondary X B D, Q, G, Rp D, Q, Rs D, Q, G, Rp, Rdc D, Q, Rs, Rdc N, 1/N, M, R2 Note The primary parameter L2 and the secondary parameters Rdc, N, 1/N, M, and R2 can be selected only with Option 001 (Add N/M/DCR measurement function). These parameters are not displayed when the 4263B is not equipped with Option 001. 1. Press . Primary parameters are displayed. 2.
4263B Setting the Test Signal Frequency 1. Press . The test signal frequency setting menu appears. 2. Select the desired frequency using is displayed. 3. Press . , or press until the desired frequency Selecting the Measurement Range The 4263B has two measurement range modes: Auto and Hold. The Auto mode changes measurement range automatically to t the measured value. The Hold mode xes the measurement range. The Hold Range annunciator turns ON when in the Hold Range mode.
4263B Setting the Test Signal Level 1. Press 2. Enter the desired value using the numeric key and the engineering key . Or press , or until the desired test signal level is displayed. When using the numeric key, the value can be set in 5 mV step. When using or , the level varies by 50 mV step. 3. Press Matching the Cable Length You can select four test cable lengths: 0 m, 1 m, 2 m, and 4 m.
4263B Performing the OPEN Correction Before connecting the Device Under Test (DUT) to the test xture, it is necessary to remove residual errors of the xture by performing the error correction function. The OPEN correction is for canceling the stray admittance in parallel with the DUT. To perform the OPEN correction, 1. Con rm that nothing is connected to the test xture. 2. Press . The OPEN correction menu is displayed. 3. Select OpenMeas using or , and press .
4263B Performing the SHORT Correction The SHORT correction is for canceling the e ects of the residual impedance in series with the DUT. To perform the SHORT correction, 1. Con gure the test electrodes in a SHORT con guration by connecting the High and Low electrodes to each other, or by connecting a shorting bar to the test xture. 2. Press . The SHORT correction menu is displayed. 3. Select ShortMeas using or , and press . The SHORT correction is performed with the following message.
4263B Performing the LOAD Correction The LOAD correction is for removing the complicated residual error that cannot be removed by the OPEN/SHORT correction. (The LOAD correction is not necessary when using an Agilent direct-connecting test xture.) The LOAD correction requires a LOAD standard device whose impendace value (reference value) is accurately known.
4263B 6. Select Exit using or and press . The 4263B returns to the menu of step-2. 7. Select LoadMeas using or , and press . The LOAD measurement is performed with the following message. When the LOAD measurement is completed, the 4263B returns to the measurement display. To turn ON the LOAD correction data, 8. Press to display the LOAD correction main menu again. 9. Select On/Off using or , and press . The following menu is displayed. 10. Select On using or , and press .
4263B If you select MeasVal in the menu of step-3, the 4263B displays the LOAD measurement value (LOAD correction data). 1. Select MeasVal and press . The 4263B displays the primary parameter of the LOAD measurement data. 2. Press . The 4263B displays the secondary parameter of the LOAD measurement data. 3. Press to return to the previous menu. The following warning message is displayed when the di erence between the LOAD measurement value and the reference value is more than 20%.
2 Operating the 4263B This chapter provides step-by-step instructions for using the 4263B LCR Meter.
4263B 2. Enter the desired value. 3. Press to set the value and to exit. Setting Trigger Delay Time To set the trigger delay time: 1. Press . 2. Enter the desired value. 3. Press to set the value and to exit. Setting Contact Check The Cont Chk annunciator tells whether the contact check function is set or not. Note When the measurement parameter is L2-N, L2-1/N, L2-M, or L2-R2, the contact check function can not be set.
4263B Setting the Beeper Mode To change the beeper mode for comparator result reporting; 1. Press . 2. Select Beep using or , and press . 3. Select the desired Beep mode using or , and press selection is completed, the 4263B returns to the previous menu. 4. To exit, select Exit using or , and press . . When the Beep mode Setting the Level Monitor Mode To set the level monitor mode: Press . Select the desired mode using , and press .
4263B Triggering a Measurement The 4263B has four trigger source modes: Internal, Manual, External, or Bus. The Trigger annunciator shows which trigger source is selected. Note When the bus trigger mode is selected, none of the Trigger annunciators are ON. The bus trigger mode can be set by GPIB commands only. To Trigger Internally 1. Press until the Int trigger annunciator is ON. To Trigger Manually 1. Press until the Man trigger annunciator is ON. 2. Press to trigger a measurement.
4263B 5. Press again to turn OFF the DC bias. The DC Bias ON/OFF indicator is OFF. Using an External DC Bias Source 1. Connect an external DC bias source to the Ext DC Bias Terminal on the 4263B's rear panel. For details about the external DC bias voltage, refer to \ External DC Bias Terminal" in Chapter 3 2. Press . 3. Select Ext using or , and press . 4. Press to apply the DC bias. The DC Bias ON/OFF indicator will turn ON. 5. Press again to turn OFF the DC bias.
4263B Note If you do not want to set a limit value for either the upper or lower limit of the primary/secondary parameters, set a maximum or minimum value for that value. To start sorting Press shift; . To display the sorting results Pressing . The menu for selecting the display mode appears as follows. If Comprtr is selected in this menu, the comparison result is displayed as follows. To stop sorting: Press .
4263B 2. Select 1RefEnt using or , and press . The 4263B displays the menu for entering the primary parameter's reference value (1Ref Primary=). To set by measuring a reference DUT: a. Press regardless of the trigger mode. The primary parameter is measured and the measurement result is displayed. Press to enter the measurement value as the primary reference. b. Then the 4263B displays the menu for entering the secondary parameter's reference value (1Ref Secondary=).
4263B Changing the Measurement Settings Display Mode Each time is pressed, the current settings of the 4263B are displayed one after another on the right side of the LCD. The information displayed and the order of display is as follows: 1. Test signal frequency and Test signal level 2. DC bias and Averaging rate 3. Trigger delay and Cable length 4. Comparator limit of the primary parameter 5. Comparator limit of the secondary parameter 6.
4263B If you press again after the level monitor value is displayed, the 4263B will return to the test signal frequency and test signal level display. Setting the Display Digit and Display Mode If you press , the display mode selecting menu appears. Select the desired display or . (Data: displays the measurement data, Comprtr: displays the mode using result of the comparator, Off: turns the display OFF.). You can exit this menu by selecting Exit.
4263B Returning the Local Mode (Exiting the Remote Mode) To return the 4263B to local mode from GPIB remote mode: Press . Setting the GPIB Address 1. Press . 2. Enter the desired value, then press to set the value and to exit. Saving and Recalling Instrument Settings The 4263B can save and recall the instrument's settings. Saved items are same as ones stored in the back-up memory listed in \LINE Switch" in Chapter 3 description. To save the current settings: 1. Press . 2.
4263B Note Record the register number that you used for future reference. To recall a setting. 1. Press . 2. Enter the register number (0 to 9) that you want to recall the settings from. 3. Press to recall. Printing Measurement Data The 4263B can print measurement data to an GPIB compatible printer without using an external controller. To print measurement data, 1. Set the printer to listen-always mode. 2. Connect the printer to the 4263B's GPIB port. 3. Turn the printer ON. 4.
4263B Testing the 4263B Performing a Self-Test The 4263B has a self-test function to check its basic performance. 1. Press . 2. Select Test using or , then press to execute the self test. If any error message is displayed, refer to \Messages" back of this manual. 3. Select Exit and press to exit. Testing the Front Panel Keys' Functionality The 4263B has a service function to test the functionality of the front panel keys, the handler interface, the ROM, the RAM, and the EEPROM).
4263B 5. To exit the front panel key test, press 6. Select Exit and press twice. to exit.
4263B If You Have a Problem If the Display is Blank and the 4263B Appears Dead If the display is blank, and even the annunciators are not ON: Check the fuse. If an Error Message is Displayed Refer to \Messages." If the 4263B does not Accept Any Key Input Check whether the Rmt annunciator is ON. Check whether the external controller is disabling all the front-panel controls using the LOCAL LOCKOUT command. If so, send the LOCAL command from the external controller. Press .
3 Function Reference and Technical Information This chapter provides information on all of the 4263B's functions.
4263B Front Panel Note Figure 3-1. Front Panel In this manual, the blue shift key is expressed as the key is not labeled with the word \blue." Display , even though the top of The display serves two functions | character display and annunciator display. The character display shows the measurement result, instrument setting information, and instrument messages. The 4263B has four measurement display modes. For details about the display mode, refer to \Display Mode Key ".
4263B LINE Switch The LINE Switch turns the 4263B ON or OFF. In the 1(ON) position, power is applied and all operating voltages are applied to the instrument. In the 0(OFF) position, no power is applied and no operating voltages are applied to the instrument. The 4263B's settings are held in backup memory for about 72 hours after power is turned OFF.
4263B DC Bias Key The DC Bias key enables or disables DC Bias output. When DC Bias output is enabled by either the internal DC bias source or the external bias source, the DC Bias ON/OFF indicator turns ON. DC Bias voltage is set using the DC Bias Setup key (refer to \DC Bias Setup Key "). Note The DC bias function is inhibited automatically when the measurement parameter is LS-Rdc, LP-Rdc, or L2-R2 (Option 001 only). Measurement Parameter Key Sets the measurement parameters.
4263B Note The primary parameter L2 and the secondary parameters Rdc, N, 1/N, M, and R2 can be set only with Option 001 (N / M / DCR measurement function addition) is present. These parameters cannot be set if the 4263B is not equipped with Option 001. When performing a measurement with the primary parameter L2 and the corresponding secondary parameters N, 1/N, M, and R2, the transformer measurement setup is required. Refer to \N / M / DCR Parameter Measurement" later in this chapter.
4263B Frequency Key The Frequency key sets the test signal frequency value. Available frequency values are: 100 Hz 120 Hz 1 kHz (default) 10 kHz (Not available when the cable length setting is 4 m) 20 kHz (Not available when the cable length setting is 4 m; Option 002 only) 100 kHz (Not available when the cable length setting is 2 m or 4 m) Display Mode Key The Display Mode key selects the display mode. The available display modes are as follows: Data Displays the measurement data.
4263B Level Key Sets the test signal level in the range of 0.02 V to 1 V. If using or , the test signal level can be set in 0.05 V step. If using the numeric keys, the test signal level can be set in 0.005 V step. Note If the measurement range is set to 0.1 and the test signal level is changed to less than 0.315 V, the range will be changed to 1 automatically. DC Bias Setup Key The DC Bias Setup key sets the DC bias voltage level. The available DC Bias voltage levels are 0 V, 1.
4263B Range Setup Key The Range Setup key sets the measurement range, according to the following table. Table 3-1. Measurement Range Selection Range Setup Optimum Measurement Range Measurable Range1 jZj 900k 1M 2 1 M jZj < 10 M jZj 90 k 100 k jZj < 1 M 100 k 2 jZj 9 k 10 k 10 k jZj < 100 k jZj 900 1k 1 k jZj < 10 k 100 10 < jZj < 1 k All jZj 11 10 1 < jZj 10 jZj 1.1 1 100 m < jZj 1 jZj 110 m 0.1 3 jZj 100 m 1 Accuracy not speci ed across this full range.
4263B Trigger Mode Key The Trigger Mode key selects the trigger source which is the input that will generate the measurement. The available trigger sources are as follows: Int (Internal) The 4263B is triggered automatically and continuously. (Default) Man (Manual) The 4263B is triggered when the key is pressed. Ext (External) The 4263B is triggered by a pulse input through the External Trigger terminal or through the handler interface.
4263B Address Key The Address key sets the 4263B's GPIB address. The available GPIB addresses are the integer numbers 0 to 30, and address 31 is the Talk Only mode in which the 4263B only outputs data through the GPIB interface. Resetting or powering o doesn't a ect the 4263B's address setting.
4263B Comparator Limit Keys These keys sets the upper/lower limit for the comparator Pass/Fail test. If / is pressed, the menu for setting the primary parameter's lower / upper limit appears. If / is pressed, the menu for setting the secondary parameter's lower / upper limit appears. Left/Down Arrow Key and Up/Right Arrow Key, These keys have the following three functions: When you enter a setting value, these keys increase or decrease the setting value.
4263B Back Space key The Back Space Key deletes a single preceding character of an input value. Minimum Key The Minimum key enters the minimum value during a parameter setting operation. Maximum Key The Maximum key enters the maximum value during a setting operation.
4263B Open Key The Open key executes the OPEN correction measurement to obtain the OPEN correction data (OPEN admittance). The 4263B uses this data to cancel the measurement errors due to the stray admittance of the test xture. The data is stored in non-volatile memory (EEPROM). The OPEN measurement must be done with nothing connected to the test xture. The following OPEN correction menu is displayed when is pressed. OpenMeas | Performs the OPEN measurement to get the OPEN correction data.
4263B Short Key The Short key executes the SHORT correction measurement to obtain the SHORT correction data (SHORT impedance). The 4263B uses this data to cancel the measurement errors due to the residual impedance of the test xture. The data is stored in non-volatile memory (EEPROM). The SHORT measurement must be done with the high and low terminals shorted together. If you press , The following SHORT correction menu is displayed when is pressed.
4263B Load Key The Load Key executes the LOAD correction. The LOAD correction is performed by connecting a LOAD standard device which has been previously measured. By performing the LOAD correction in addition to the OPEN/SHORT correction, the 4263B can remove measurement error resulting from the complex residual impedance which cannot be completely removed by the OPEN/SHORT correction.
4263B If the di erence between the LOAD measurement value and reference value is more than 20 %, the 4263B displays \WARNING: Out Of Limit" This is only a WARNING message, so the LOAD correction data will still be used. The LOAD correction data is saved in non-volatile memory (EEPROM), and is cleared when the 4263B is reset. It is not cleared when the *RST command was executed from GPIB. Comparator Key The Comparator key toggles the comparator function ON and OFF.
4263B Contact Check Key The Contact Check key toggles the contact check function ON and OFF. This function monitors whether the DUT is properly connected to the test electrodes. When the contact check fails, N.C. (No-Contact) will be displayed on the LCD display. The measurement status of the GPIB output data is set to 2 (No-Contact). Refer to \Address Key " for the GPIB output data. The /NO CONTACT pin of the handler interface is asserted.
4263B Cable Key The Cable key allows you to accurately extend your measurement or reference plane. Parasitics and phase shift due to the cable are automatically removed with the Cable key.
4263B Reset Key The Reset key resets all instrument settings and Correction data to the default values.
4263B Con guration Key The Con guration key allows you to set the beeper mode, choose the power line frequency and to execute service functions and the self-test. Beep | Comparison results output to the beeper are classi ed into following modes: OFF Does not emit a beep (no output to beeper). PASS Emits a beep when the comparison result is IN. FAIL Emits a beep when the comparison result is HI, LO, or N.C..
4263B Rear Panel Figure 3-2. Rear Panel External Trigger Terminal The Ext (External) Trigger terminal is used to trigger 4263B by inputting a positive-going TTL pulse, when the 4263B is set to external trigger mode. Figure 3-3 shows the speci cations required for the TTL pulse. Figure 3-3.
4263B External DC Bias Terminal The Ext (External) DC Bias terminal is used to input a DC bias from an external source when DC bias setup is set to Ext. The external voltage range is 0 V to +2.5 V. Caution Do not apply External DC bias voltage more than +2.5 V. Doing so will damage the 4263B LINE Fuse Holder The 4263B's line fuse is selected depending on the LINE Voltage selection.
4263B Handler Interface The handler interface is used to synchronize timing with an external handler. Before using the handler interface, you must connect pull-up resisters to enable the output signals and set the dip switch to select the voltage level to match the input signals. Refer to Appendix B for these procedures.
4263B Table 3-4. Pin Assignment of Handler Interface Connector Description Signal Name1 Pin No. 1 2 EXT DCV1 EXT DCV1 External DC Voltage 1 : DC Voltage supply pins for DC isolated open collector outputs (/PHI, /SHI, /PIN, /SIN, /PLO, /SLO, /NO CONTACT). Maximum voltage is +24 V, minimum +5 V. 18 /KEY LOCK Key Lock : When this line is asserted, all of the 4263B's front panel key functions are disabled.
4263B Note Figure 3-5. Timing Diagram This timing diagram is also applied when the contact check fails. Because the measurement is performed and the measurement result is output, even if the contact check fails.
4263B GPIB Interface GPIB Interface is used for remote control of the 4263B using the General Purpose Interface Bus (GPIB). GPIB is a standard for interfacing instruments to computers, and supports for IEEE 488.1, IEEE 788.2, IEC-625, and JIS-C1901. GPIB allows instruments to be controlled by an external computer which sends commands or instructions to and receives data from the instrument.
4263B Technical Information This section discuss the 4263B's theory of operation and the technical information. Overall Impedance Measurement Theory The 4263B measures the impedance of the Device Under Test (dut ) in the following manner: Figure 3-6. Simpli ed Model of Impedance Measurement Figure 3-6 shows the simpli ed model of the 4263B impedance measurement. Vs is the test signal level (voltage) and Rs is the source resistance.
4263B In Figure 3-7, R: X: jZj : Resistance Reactance : Absolute value of impedance Phase of impedance The 4263B denotes the absolute value jZj of impedance with Z. Note Impedance, Z, can also be expressed as admittance, Y. Admittance is expressed in terms of impedance, Z, as follows: 1 Y = Z Figure 3-8. Relationship Between Impedance and Admittance For parallel connected circuits, it is better to use admittance, Y. Figure 3-9.
4263B The 4263B denotes the absolute value jYj of admittance with Y. Note The 4263B measures a DUT's impedance, Z, which is a vector value, and gives the result using the following equivalent circuits: Figure 3-10.
4263B Transformer Parameters Measurement Note This function only applies to the 4263B with option 001. DCR measurement | Ls-Rdc, Lp-Rdc Where, Ls : Lp : Equivalent series inductance Equivalent parallel inductance Rdc : DC resistance The 4263B has an internal DC voltage source for DCR measurement. The DC voltage level is 2 V. The 4263B switches test signal source to DC for DC Resistance measurement, and to AC for LS or LP measurement.
4263B Warning While H terminal of the 4263B is connected to a terminal of the transformer, high-voltage can be induced at the other terminals. For safe operation, when connecting or disconnecting a transformer, connect the transformer leads in the following order: Connect transformer, rst to L , L , and H terminals, and then connect the H terminal last. Disconnect the transformer from the H terminal rst, and then the H , L , and L terminals.
4263B Test Current Level Figure 3-6 shows the 4263B's simpli ed model. The actual current level applied to a DUT depends on the test signal level (Vs), the DUT's impedance value (Z), and the 4263B's source resistance (Rs) which is in series with the DUT. The actual current level (I) through the DUT is calculated using the following equations. There are two di erent equations according to which voltage source is used: AC or DC.
4263B When measuring DCR or R2, the actual test current level through the DUT can be obtained as follows: The source resistance, Rs, is selected by measured the DUT's resistance value, RDUT .
4263B Figure 3-13.
4 Remote Operation (To Control from a Computer) This chapter provides step-by-step instructions for controlling the 4263B using GPIB remote mode. The examples in this manual use the HP 9000 series 200 or 300 BASIC language. This chapter covers the following: Getting started Setting up the 4263B Triggering a measurement Retrieving measurement data Other features If you have a problem Refer to Chapter 5 for the description of each GPIB command.
4263B Getting Started This section will teach you the basics of operating the 4263B in GPIB remote mode (from now on referred to as remote). This includes reading the GPIB address, sending commands to the 4263B, and retrieving data from the 4263B. Input/Output Statements The statements used to operate the 4263B in remote depend on the computer and the programming language being used. In particular, you need to know the statements the language uses to input and output information.
4263B Returning to Local Mode When you press a key on the 4263B's keyboard while operating in remote, the 4263B does not respond. This is because in remote (as indicated by the display's Rmt annunciator) the 4263B ignores all front panel inputs except the key. To return the 4263B to the Local mode, press the . Query Commands There are several commands in the alphabetic command directory that end with a question mark.
4263B Remote Operation Most measurements can be modeled by the following simple three step sequence: 1. Set up the instrument. Typically, you begin the setup step by sending *RST to set the instrument to its default settings. Next, if you need values di erent from the default settings, change the settings one by one as required. 2. Trigger the measurement. The trigger may be generated automatically by steps taken in your setup commands, or you can send an explicit trigger command.
4263B To Set Up the 4263B To Reset the 4263B The following commands reset the 4263B: *RST :SYST:PRES Note *RST initiates the trigger system also.
4263B 1. To select the Z- mode, To select the R-X mode, 2. To select the Y- mode, To select the G-B mode, 3.
4263B 7. (Option 001 only) To select the Ls-Rdc mode, OUTPUT OUTPUT OUTPUT OUTPUT 717;":SENS:FUNC:CONC ON" 717;":SENS:FUNC 'FIMP','FRES'" 717;":CALC1:FORM LS" 717;":CALC2:FORM REAL" To select the Lp-Rdc mode, OUTPUT 717;":SENS:FUNC:CONC ON" OUTPUT 717;":SENS:FUNC 'FADM','FRES'" OUTPUT 717;":CALC1:FORM LP" OUTPUT 717;":CALC2:FORM REAL" 8.
To Apply a DC Bias 4263B The following commands are used to apply a dc bias voltage: :SOUR:VOLT:OFFS :SOUR:VOLT:OFFS:SOUR :SOUR:VOLT:OFFS:STAT For example, to apply 1.5 V DC bias using the internal bias source, OUTPUT OUTPUT OUTPUT : OUTPUT 717;":SOUR:VOLT:OFFS:SOUR INT" 717;":SOUR:VOLT:OFFS 1.
4263B To perform OPEN and SHORT correction : OUTPUT 717;":SENS:CORR:COLL:METH REFL2" DISP "Connect the test fixture without a DUT, then press `Continue'." PAUSE OUTPUT 717;":SENS:CORR:COLL STAN1" OUTPUT 717;"*OPC?" ENTER 717;A ! DISP "Connect the shorting bar to the test fixture, then press `Continue'." PAUSE OUTPUT 717;":SENS:CORR:COLL STAN2" OUTPUT 717;"*OPC?" ENTER 717;A : To perform OPEN, SHORT, and LOAD correction.
To Set the Averaging Rate The following commands set the averaging rate: :SENS:AVER :SENS:AVER:COUN For example, to set the averaging rate to 4, OUTPUT 717;":SENS:AVER:COUN 4" To Set Trigger Delay Time The following command sets trigger delay time: :TRIG:DEL For example, to set trigger delay time to 10 ms, OUTPUT 717;":TRIG:DEL 1E-2" To Set Beeper Mode The following commands set beeper mode: :SYST:BEEP :SYST:BEEP:STAT :CALC1:LIM:BEEP :CALC1:LIM:BEEP:COND For example, to set beeper mode to emit a bee
4263B f1j2g means that one of the two numbers must be attached to the root mnemonic, that is, the word \CALC"; 1 means the primary parameter and 2 means the secondary parameter.
4263B To Get the Current Instrument Settings The following command gets the current instrument settings: *LRN? For example, DIM A$[1000] : OUTPUT 717;"*LRN?" ENTER 717;A$ PRINT A$ To Save and Recall Instrument Settings The following commands save and recall instrument settings: *SAV *RCL To save the instrument settings to register no. 1, OUTPUT 717;"*SAV 1" To recall the instrument settings from register no.
4263B To Trigger a Measurement The following commands are used to trigger measurements and retrieve measurement data. Refer to \Trigger System" in Chapter 5 for information about the 4263B's trigger system. :TRIG :TRIG:SOUR :INIT :INIT:CONT :ABOR *TRG :FETC? Group Execution Trigger (GET) Follow the procedure below to perform successive measurements automatically (initial setup). 1. Set the trigger mode to the internal trigger with the :TRIG:SOUR command. 2.
4263B Waiting For Completion Of Measurement (detecting completion of measurement) You can detect the status of the 4263B by using the status register, as described in this section. For information on the entire status report system (for example, information on each bit of the status register), refer to Chapter 5, \GPIB Reference." The measurement state is indicated by the operation status register (refer to Table 5-6 and Table 5-7).
4263B Sample program Figure 4-3 shows a sample program to detect the completion of measurement using an SRQ. This program stops the trigger system, sets up SRQ, and then starts up the trigger system once. When an SRQ of the completion of the measurement occurs, it displays a \Measurement Complete" message and nishes. The program is detailed below. Line 20 Sets the GPIB address. Lines 40 to 60 Stops the trigger system and sets the trigger mode to the internal trigger.
4263B Reading Out Measured Result This section describes how to read out the measured result. You can read out the measured result in two ways: reading out data for each measurement or reading out data of several measurements in batch. The three commands shown in the table below can be used to read out the measured data for each measurement.
4263B Reading out measured result using *TRG command This command actually performs two tasks: it triggers the instrument and returns the results. It is useful, for example, when you want to retrieve measurement results immediately after triggering the instrument from an external controller. The readout procedure using the *TRG command is described below. 1. Use the :TRIG:SOUR command to set up the trigger mode to the GPIB trigger (Bus). 2. Execute the *TRG command. 3. Read out the measured result.
4263B Figure 4-4.
4263B The program of Figure 4-5 is detailed below. Lines 50 to 60 Sets the GPIB address. Line 70 Sets the data transfer format to the binary format. Lines 90 to 100 Turns ON the trigger system continuous startup and sets the trigger mode to the GPIB trigger. Lines 120 to 130 Reads out the ON/OFF state of the comparator function and assigns it to the Comp ag variable. Lines 170 to 210 After the trigger system state transitions to the trigger wait state, triggers the instrument.
4263B Figure 4-5.
4263B Reading out measured result using :FETC? command You can use this readout method when you want to trigger the instrument from any source other than an external controller or when you want to perform a process that is between triggering the instrument and reading out the measured result. The readout procedure using the :FETC? command is described below. 1. Set up the trigger mode as necessary. 2. Trigger the instrument by using the method for the trigger mode.
4263B Figure 4-6.
4263B The program of Figure 4-7 is detailed below. Lines 50 to 60 Sets the GPIB address. Line 70 Sets the data transfer format to the binary format. Lines 90 to 100 Turns ON the trigger system continuous startup and sets the trigger mode to the external trigger. Lines 120 to 130 Reads out the ON/OFF state of the comparator function and assigns it to the Comp ag variable.
4263B Figure 4-7.
4263B To Retrieve Data E ciently The basic procedure to retrieve measurement data is described in \To Trigger a Measurement". This section describes how to retrieve the measurement data e ciently. To Use a Data Bu er You can use the data bu er to temporarily store the results of several measurements and then later read out these results in batch.
4263B Other Features To Test the 4263B The following command runs the 4263B's internal self test: *TST? For example, : OUTPUT 717;"*TST?" ENTER 717;A IF A<>0 THEN PRINT "Self Test:Error" : To Report the Instrument's Status The following commands report the instrument's status: *CLS *ESE *ESR? *SRE *STB? :STAT:OPER? :STAT:OPER:COND? :STAT:OPER:ENAB :STAT:QUES? :STAT:QUES:COND? :STAT:QUES:ENAB :STAT:PRES HP BASIC SPOLL command For example, to always generate a service request when an error enters the e
4263B ! Clear the SRQ BIt : LOOP : END LOOP STOP ! Err_report;! Stat=SPOLL(717) OUTPUT 717;"*ESR?" Asks contents of the Standard Event Status Register ENTER 717;Estat Asks to output error number and message PRINT "Syntaz Error detected.
4263B If You Have a Problem Check all GPIB addresses and connections; most GPIB problems are caused by an incorrect address and bad or loose GPIB cables.
5 GPIB Reference This chapter provides a reference for the General Purpose Interface Bus (gpib ) commands used to control the 4263B in the GPIB remote mode. GPIB Command reference Status Reporting Structure Trigger System Data Transfer Format 4263B's GPIB commands are compatible with the Standard Commands for Programmable Instruments (SCPI). SCPI is the instrument command language for controlling instrument that goes beyond IEEE 488.
4263B Subsystem Commands Subsystem Commands include all measurement functions and some general purpose functions. Each subsystem is a set of commands that roughly corresponds to a functional block inside the instrument. For example, the commands comprising the SOURce (power) subsystem are for signal generation, and the commands comprising the STATus subsystem are for status register access.
4263B COMMAND Subsystem Command List (continued) [SENSe] :AVERage :COUNt [:STATe] :CORRection :CKIT :STNdard3 :COLLect [:ACQuire] :METHod :DATA? [:STATe] :FIMPedance :APERture :CONTact :VERify :RANGe :AUTO [:UPPer] :FUNCtion :CONCurrent :COUNt? [:ON] SOURce :FREQuency :CW :VOLTage [:LEVel] [:IMMediate] [:AMPLitude] :OFFSet :SOURce :STATe STATus :OPERation :CONDition? :ENABle [:EVENt]? :PRESet :QUEStionable :CONDition? :ENABle [:EVENt]? SYSTem :BEEPer [:IMMediate] :STATe :ERRor? :KLOCk :LFRequency :PRESet
4263B Concept of Subsystem Command Tree The top of the subsystem command tree is called the root command , or simply the root . To reach the low-level commands, you must specify a particular path (like DOS le directory path). After Power ON or after *RST, the current path is set to the root. The path settings are changed as follows: Message Terminator A message terminator, such as < new line> character, sets the current path to the root.
4263B Program Message Syntax This section provides the construction of SCPI program message. A program message is the message that you send from computer to an instrument. Program message consist of commands combined with appropriate punctuation and program message terminators. Case Letter cases (upper and lower) are ignored. Program Message Terminator A program message must end with one of the three program message terminators , line>, <^END>, or <^END>.
4263B Parameter Types SCPI de nes di erent data formats for use in program message and query responses. The 4263B accepts commands and parameters in various formats and responds to a particular query in a prede ned and xed format. Each command reference contains in formation about the parameter types available for the individual commands. is used in both common commands and subsystem commands. represents numeric parameters as follows: l00 no decimal point required l00.
4263B Table 5-1. Usable Units De nition Mnemonic Usable Unit 6 10 (Mega) MA Hz V 10 3 (kilo) K OHM S 10 -3 (Milli) M The su x is optional and can be omitted. Multiple Messages To send more than one command in the same message, you must separate them with a semicolon: *CLS;:INIT Query and Response Message Syntax All subsystem commands can be queried except for the commands described as \no query" in the command reference. To send a query message, and ? after the last command mnemonic.
4263B Command Reference In this section, all the commands which are available with the 4263B are listed in alphabetical order. Notations The following conventions and de nition are used in this chapter to describe GPIB operation. :CALClatef1j2g:LIMit:LOWer[:DATA] Sets or queries the lower limit of the speci ed parameter. :CALClatef1j2g:LIMit:LOWer:STATefONjOFFj1j0g Sets or queries if the lower limit of the speci ed parameter is enabled.
4263B ABORt Command :ABORt The ABORt command resets the trigger system and places all trigger sequences in the Idle state. Any actions related to the trigger system that are in progress, such as acquiring a measurement, are aborted immediately. The execution of an :ABORt command will set any pending operation ag to FALSE, for example ags that were set by the initiation of the trigger system. Refer to \Trigger System". Unlike *RST, :ABORt does not alter the settings programmed by other commands.
4263B CALCulate Subsystem The CALCulate subsystem controls the measurement-data processing as listed below: 1. To select measurement parameter (:CALCulate{1|2}:FORMat subsystem) with the [:SENSe]:FUNCtion[:ON] subsystem 2. To control the level monitor function (:CALCulate{3|4}:MATH subsystem) 3. To control deviation measurement mode (:CALCulate{1|2}:MATH subsystem) 4. To control comparator function (:CALCulate{1|2}:LIMit subsystem) The 4263B performs data processing in the order as listed.
4263B :CALCulate1:FORMat f REAL j MLINear j CP j CS j LP j LS g :CALCulate2:FORMat f IMAGinary j PHASe j D j Q j REAL j LP j RP j INV g Sets or queries the measurement parameter. This command works with the [:SENSe]:FUNCtion[:ON] subsystem. The 4263B makes a vector measurement of the DUT, using the method speci ed by the SENSe subsystem. After the measurement, the scalar measurement parameter speci ed by :CALCulate{1|2}:FORMat command is calculated from the measured vector value.
4263B Table 5-2.
4263B When you enable the beep function, :SYSTem:BEEPer:STATe command is automatically set to ON. Query response is 0 or 1. Note The comparator output states of each parameter link together. So the CALCulate{1|2}:LIMit:BEEPer command toggles the comparator function of both parameter ON or OFF. :CALCulatef1j2g:LIMit:CLEar Clears the data which is reported by :CALCulate{1|2}:LIMit:FAIL? command. (no query) :CALCulatef1j2g:LIMit:FAIL? Returns the comparison result of the selected parameter.
:CALCulatef1j2g:LIMit:UPPer:STATe f ON j OFF j 1 j 0 g 4263B Sets or queries if the upper limit of the selected parameter is enabled. OFF or 0 Disables the upper limit. ON or 1 Enables the upper limit. Query response is 0 or 1. :CALCulatef1j2g:MATH:EXPRession:CATalog? Returns available parameters which can be used with the :CALCulate{1|2}:MATH:EXPRession:NAME command. (query only) Query response is always DEV,PCNT.
4263B CALibration Subsystem COMMAND CALibration :CABLe PARAMETER value> Sets or queries the cable length which extends the reference plane to which the phase shift measurement error is corrected.
4263B DATA Subsystem The DATA subsystem commands are used for the following data processing: 1. Storing the data to the 4263B data bu er. 2. Reading the data from the 4263B data bu er. 3. Reading the level monitor value.
4263B :DATA[:DATA]? f BUF1 j BUF2 g Returns the data in a data bu er, BUF1 or BUF2, according to the format determined by the FORMat subsystem commands. (query only) BUF1 and BUF2 are used to store up to 200 measurement results in each. The size of the data bu er is speci ed by the :DATA:POINts command. This query needs parameter BUF1 or BUF2, which is the name of the data bu er to be read. So, the query form is :DATA[:DATA]? BUF1 or :DATA[:DATA]? BUF2.
4263B handle> Sets or queries which of the primary or secondary parameter's measurement data is fed into the data bu er. :DATA:FEED? query needs parameter, BUF1 or BUF2, which is the name of data bu er to be read. So, the query form is :DATA:FEED? BUF1 or :DATA:FEED? BUF2. is, 'CALCulate1 ' Sets to feed the primary parameter's measurement data speci ed the :CALCulate1:FORMat command. 'CALCulate2 ' Sets to feed the secondary parameter's measurement data speci ed :CALCulate2:FORMat command.
4263B DISPlay Subsystem The DISPlay subsystem controls the selection of displayed mode. COMMAND DISPlay [:WINDow] [:STATe] :TEXT1 :DIGit :PAGE :TEXT2 :PAGE PARAMETER f3j4j5g f1j2g f1j2j3j4j5j6g :DISPlay[:WINDow][:STATe] f ON j OFF j 1 j 0 g Sets the display ON or OFF, or queries whether the display is set to ON or OFF. OFF or 0 Sets the display OFF (blank). ON or 1 Set the display ON. Query response is 0 or 1. :DISPlay[:WINDow]:TEXT1:DIGit f3j4j5g Sets the number of display digits.
:DISPlay[:WINDow]:TEXT2:PAGE f1j2j3j4j5j6g Selects the mode of Measurement Settings display. 1 Displays the test signal frequency and level. 2 Displays the DC bias setting and averaging rate. 3 Displays the trigger delay and cable length. 4 Displays the comparator limit for the primary parameter. 5 Displays the comparator limit for the secondary parameter. 6 Displays the level monitor value. Query response is 0, 1, 2, 3, 4, or 5.
4263B FETCh? Query :FETCh? Retrieves the measurements taken by the INITiate subsystem commands and places them into the 4263B's output bu er.
4263B FORMat Subsystem COMMAND FORMat [:DATA] :FORMat[:DATA] fASCiijREAL[,64]g PARAMETER {ASCii|REAL[,64]} Sets the data format for transferring numeric and array information. ASCii Sets the data transfer format to ASCII. AL[,64] Sets the data transfer format to IEEE 754 oating point numbers of the speci ed length of 64-bit. For details on data transfer formats, see \Data Transfer Format". Query response is ASK or REAL,64.
4263B INITiate Subsystem The INITiate subsystem controls the initiation of the trigger system. All trigger sequences are indicated as a group. The detailed description of the trigger system is given in \Trigger System". COMMAND INITiate :CONTinuous [:IMMediate] PARAMETER :INITiate[:IMMediate] Causes all sequences to exit Idle state and enter Initiate state. This command causes the trigger system to initiate and complete one full trigger cycle, returning to Idle state on completion.
4263B SENSe Subsystem COMMAND [SENSe] :AVERage :COUNt [:STATe] :CORRection :CKIT :STANdard3 :COLLect [:ACQuire] :METHod :DATA? [:STATe] :FIMPedance :APERture :CONTact :VERify :RANGe :AUTO [:UPPer] :FUNCtion :CONCurrent :COUNt? [:ON] [:SENSe]:AVERage:COUNt [MOHM [:SENSe]:AVERage[:STATe] f ON j OFF j 1 j 0 g 5-24 GPIB Reference value
4263B [:SENSe]:CORRection:CKIT:STANdard3 , Enters or queries the reference value for the LOAD correction. The reference value must be in R-X (resistance-reactance) parameter form; the rst represents R, and the second represents X. To calculate the R-X parameter from other parameters, see Figure 3-10. Note The 4263B's test signal frequency at the 120 Hz setting is actually 119.048 Hz, and it is speci ed as 120 Hz 6 1%.
[:SENSe]:CORRection:COLLect:METHod f REFL2 j REFL3 g 4263B Sets or queries the measurement error correction method. REFL2 OPEN/SHORT correction REFL3 OPEN/SHORT/LOAD correction You must take the required correction data using the [:SENSe]:CORRection:COLLect[:ACQuire] command. For details, see \To Perform Correction" in Chapter 4 and \Correction Functions of the 4263B" in Chapter 7. * [:SENSe]:CORRection:COLLect:METHod is set to REFL2 by 3RST. Query response is REFL2 or REFL3.
4263B [:SENSe]:FIMPedance:RANGe[:UPPer] [MOHMjOHMjKOHMjMAOHM] Sets or queries the measurement range. is, numeric 0.1 (=100 m)(Allows above 315 mV), 1, 10, 100, 1000 (= 1 k), 10000 (= 10 k), 100000 (= 100 k)(Not allows at 100 kHz), 1000000 (= 1 M) ( )(Not allows at 100 kHz) MINimum 0.1 ( ) MAXimum 1000000 (=1 M) ( ) UP Moves to an upper range. DOWN Moves to a lower range. Query response is a numeric value in format.
4263B Table 5-3.
4263B SOURce Subsystem COMMAND SOURce :FREQuency [:CW] :VOLTage [:LEVel] [:IMMediate] [:AMPLitude] :OFFSet :SOURce :STATe :SOURce:FREQuency[:CW] [HZjKHZ] [MVjV] value> [MVjV] fINTernaljEXTernalg value>[HZjKHZ] Sets or queries the test signal frequency.
:SOURce:VOLTage[:LEVel][:IMMediate]:OFFSet:STATe f ON j OFF j 1 j 0 g Sets or queries whether or not DC bias output is enabled. OFF or 0 Disables DC bias output. ON or 1 Enables DC bias output. Query response is 0 or 1.
4263B STATus Subsystem The STATus Subsystem commands controls the Operation Status and Questionable Status registers in the status-reporting structures (See \Status Reporting Structure". COMMAND STATus :OPERation :CONDition? :ENABle [:EVENt]? :PRESet :QUEStionable :CONDition? :ENABle [:EVENt]? PARAMETER :STATus:OPERation[:EVENt]? Returns the contents of the event register of the Operation Status Register group. Reading the event register clears it.
:STATus:QUEStionable:ENABle 4263B Sets or queries the enable register of the Questionable Status Register group. is, numeric value Decimal expression of the contents of the register. The 4263B has no operation to report the event to the Questionable Status Event Register. Query response is a numeric value in format.
4263B SYSTem Subsystem The SYSTem subsystem reports the rmware version and error, sets the beeper, locks the front-panel keys, and de nes the power line frequency. COMMAND SYSTem :BEEPer [:IMMediate] :STATe :ERRor? :KLOCk :LFRequency :PRESet :VERSion? PARAMETER :SYSTem:BEEPer[:IMMediate] Produces a beep immediately. (no query) :SYSTem:BEEPer:STATe fONjOFFj1j0g Sets or queries if the beeper is enabled. ONor1 Enables the beeper.
4263B Item Reset key :SYST:PRES1 *RST1 1 kHz Test signal frequency 1V Test signal level Measurement parameter Cp-D Deviation measurement OFF Deviation reference values Cleared Measurement range Auto Medium Measurement time mode 1 Averaging rate Trigger mode Internal 0s Trigger delay time OFF Contact Check ON/OFF state OFF Comparator ON/OFF state Comparator limits Cleared Display mode Measure Display Internal DC bias source 0V DC bias setup OFF DC bias ON/OFF state Correction ON/OFF state ON OFF Correction m
4263B TRIGger subsystem The TRIGger subsystem controls the measurement trigger functions. COMMAND TRIGger :DELay [:IMMediated] :SOURce PARAMETER [MS|S] {BUS|EXTernal|INTernal|MANual} value> [MSjS] Sets or queries the trigger delay time. is, numeric 0 to 9.999 (s) MINimum 0 (s)[ MAXimum 9.999 (s) The following units can be used for . :TRIGger:DELay format.
4263B Common Commands 3CLS Clears the Status Byte Register, the Standard Event Status Enable Register. 3ESE Sets or queries the bits of the Standard Event Status Register. (Query only) Query response is a numeric value in format. 3ESE? *The ESE? (Event Status Enable) Query reads the bits of the Standard Event Status Enable Register. Query response is a decimal register value in format. 3ESR? Queries an identi cation string which consists of four elds separated by commas.
4263B value>is, numeric value 0 to 9 Saves the instrument state in the speci ed register number. The 4263B has 10 available storage registers. (No query) is, numeric value 0 to 9 3SRE Sets the bits of the Status Byte Enable Register.
3WAI Makes the 4263B wait until all previously sent commands are completed.
4263B Status Reporting Structure This section provides information about the status reporting structure for Service Request functions which correspond to SCPI. Figure 5-2. Status Reporting Structure Service Request (SRQ) The 4263B can send an SRQ (Service Request) control signal when it requires the controller to perform a task. When the 4263B generates an SRQ, it also sets Bits 6 of the Status Byte Register, RQS (Request Service) bit.
4263B Status Byte Register The Status Byte Register is composed of eight bits that summarize an overlaying status data structure. The Status Byte Register can be read using either *STB? or SPOLL, which return a decimal expression of the contents of the register (equal to the sum of the total bit weights of all the bits set to \1"). Figure 5-3. Status Byte Register Table 5-4. Status Byte Assignments Bit No.
4263B Statndard Event Status Register The Standard Event Status Register is frequently used and is one of the simplest. You can program it using GPIB common commands, *ESE and *ESR?. Refer to *ESE command and *ESR? command in \Command Reference". Figure 5-4.
4263B Table 5-5. Standard Event Status Register Assignments 7 Bit Weight 128 6 5 32 4 16 3 8 2 4 1 0 1 Bit No. Description Power-On Bit | This bit is set when the 4263B has been turned OFF and then ON since the last time this register was read. Always 0 (zero) Command Error Bit | This bit is set if the following command errors occur. An IEEE 488.2 syntax error occurred. The 4263Breceived a Group Execute Trigger (GET) inside a program message.
4263B Figure 5-5.
4263B Operation Status Register The Operational Status Register group provides information about the state of the 4263B measurement system. Bit No. 10-15 9 8 7 6 5 4 3 2 1 0 Bit No. 10 - 15 9 8 7 6 5 4 3 2 1 0 Table 5-6. Operation Status Condition Register Assignments Bit Description Weight Always 0 (zero) 512 BUF2 fullness | This bit is set when the BUF2 is full. 256 BUF1 fullness | This bit is set when the BUF1 is full.
4263B Table 5-8. Questionable Status Register Assignments Bit No.
4263B Trigger System This section provides information about trigger system of the 4263B. SCPI de nes a common trigger model for several types of instruments. Information on the trigger system requires more technical expertise than most other topics covered in this chapter. But you can avoid having to learn the information in this section by using the :INITiate commands to make your measurements.
4263B Initiate State If the trigger system is on a downward path, it travels directly through the Initiate state without restrictions. If the trigger system is on an upward path, and :INITiate:CONTinuous is ON, then it exits downward to an Trigger Event Detection state. If the trigger system is on an upward path and :INITiate:CONTinuous is OFF, then it exits upward to the idle state. Trigger Event Detection State If the trigger system is on a downward path, it branches as follows. Figure 5-7.
4263B Data Transfer Format ASCii Numeric data is transferred as ASCii bytes in (integer), ( xed point) or ( oating point) formats, as appropriate. The numbers are separated by commas as speci ed in IEEE 488.2. Figure 5-8. NR1 Format Figure 5-9. NR2 Format Figure 5-10. NR3 Format For example, expressions for \1000" are, 1000 format 1000.0 format 1.
4263B REAL Figure 5-11. REAL Data Format This data eld is initiated by a unique code, the number sign (3). The second byte,\" designates the number of the bytes for the \", \" designates \" length. \&END" is the response message terminator. \" contains the data in IEEE 754 oating point numbers of 64-bits. This is the same data format used by the HP Technical computers, such as the HP 9000 series 200/300 computers.
6 Application Measurement This chapter provides actual measurement examples as follows: Measuring Electrolytic Capacitors Measuring Transformers Measuring Electrolytic Capacitors (Sample Program) This example shows how to measure electrolytic capacitors using a handler. 1. Set up the measurement system. The following gure shows a typical system. Figure 6-1.
4263B 2. Run the following sample program.
4263B 530 OUTPUT @Hp4263;":STAT:OPER:ENAB ";DVAL("0000001000000000",2) 540 OUTPUT @Hp4263;"*SRE ";DVAL("10000000",2) 550 OUTPUT @Hp4263;":INIT:CONT ON" 560 ! 570 ! Triggering 580 ! 590 ON INTR Hp_ib GOTO Buffer_full 600 ENABLE INTR Hp_ib;2 610 LOOP 620 END LOOP 630 ! 640 Buffer_full:OFF INTR 650 DISP "Buffer full.
4263B resistance measurement, the 4263B may be broken down at the C and ESR measurements. To avoid the breakdown of the 4263B, add double (or triple) processes for discharging the capacitor in an automatic measurement system using a handler.
4263B Note When measuring capacitance of large valued capacitors, set the trigger delay time to prevent the transient caused by the DUT (capacitor) and the test signal source resistor. For example, when the test signal frequency is 100/120 Hz and the measurement time mode is Short, the following gure shows the relation between the trigger delay time and the additional error.
4263B Measuring Transformers This example shows how to measure transformers. 1. Connect the 16060A test xture to the UNKNOWN terminals. Connect the furnished BNC test leads to the 16060A. 2. Reset the 4263B. Press to display the reset menu. Select Yes using or , and press . 3. Select test signal frequency. Press to display the frequency setting menu. Select the desired frequency using or (for example, 1kHz), and press . 4. Select test signal level. Press to display the level setting menu.
4263B i. Short all the test leads connected to the 16060A's \A", \B", and \COMMON" terminals. ii. Press to display the deviation measurement menu. Select 1RefEnt using or , and press . iii. Press to measure the reference value of the primary parameter, and press to set the measurement result as the reference. iv. Press to measure the reference value of the secondary parameter, and press to set the measurement result as the reference. v. Select Prim, and select 1ABS.
4263B Note When \-------" is displayed as the measured value of N, change the A:B switch setting on the 16060A. 6. Measure L2-M. a. Press . Select L2 and press . Then select M and press . b. Set the deviation measurement function to cancel the residual impedance again, because changing the measurement parameter resets the deviation measurement function. i. Press . Select Prim, and select 1ABS. ii. Exit the deviation measurement menu by selecting Exit. c. The measurement results are shown below.
4263B 8. The measurement results are shown below. R2, like L2, corresponds to the side of the transformer connected to the \A" terminal. To obtain the resistance of the other side of the transformer, change the A:B switch setting to 1:N.
7 Impedance Measurement Basics This chapter contains more detailed information on measurements using the 4263B, that should help you to work more e ciently. The following sections are included.
4263B Characteristics Example Figure 7-1 shows typical characteristics of various components. As can be seen in the gure, a component can have di erent e ective parameter values dependent upon its operating conditions. The measured values most useful in actual applications are obtained from precise measurement under the actual operating conditions. Figure 7-1.
4263B Parallel/Series Circuit Mode There are two equivalent circuit models used to measure L, C, or R components. They are the parallel and series models as shown in Table 7-1. Circuit Model Cp Model Cs Model Lp Model Ls Model Table 7-1.
4263B Selecting Circuit Model for Capacitance Measurement The following description gives some practical guide lines for selecting the appropriate capacitance measurement circuit model. Small Capacitance Values Small capacitance yields a large reactance, which implies that the e ect of the large value parallel resistance (Rp) has relatively more signi cance than that of the low value series resistance (Rs). So the parallel circuit model (Cp-D, Cp-Q, or Cp-G) is the one to use. (Refer to Figure 7-2 (a).
4263B Selecting Circuit Model for Inductance Measurement The following description gives some practical guide lines for selecting the appropriate inductance measurement circuit model. Small Inductance Values For low values of inductance the reactance is typically small so Rs is more signi cant. Therefore , the series circuit model (Ls-D, Ls-Q, or Ls-Rs) is appropriate. (Refer to Figure 7-3 (a).
4263B Four-Terminal Pair Con guration The 4263B uses the four-terminal pair measurement con guration which permits easy, stable, and accurate measurements and avoids the measurement limitations due to factors such as mutual inductance, interference of the measurement signals, and unwanted residual in the test connections. Figure 7-4 shows the four-terminal pair measurement principle. The UNKNOWN terminals consists of four coaxial connectors.
4263B Measurement Contacts To realize accurate measurements using the four-terminal pair measurement technique, the following two conditions are required: (Refer to Figure 7-5 for each numbered point.) 1. The signal path between the LCR Meter and DUT should be as short as possible. 2. For a four-terminal pair measurement circuit con guration, the outer shields of HCUR and HPOT, LCUR , and LPOT terminals must all be connected together at a point as near as possible to the DUT. Figure 7-5.
4263B Capacitance to Ground To measure capacitors of 10 pF or less, the stray capacitance between the measurement contacts and the conductors near the capacitor will in uence the measurement, as shown in Figure 7-6. Figure 7-6. Model of Capacitance to Ground To minimize the stray capacitance of the test leads, the center conductor of the test leads should be kept as short as possible, as shown in Figure 7-7, (A).
4263B Contact Resistance Contact resistance between the contacting terminals and the DUT causes measurement error when measuring large values of capacitance, especially in D (dissipation factor) measurements. When measuring large capacitance values, the four-terminal measurement contacts have the advantage of less measurement error as compared to the two terminal method. Select a test xture which can hold the DUT tight to stabilize the connection and to give the lowest contact resistance. Figure 7-8.
4263B Using a Guard Plate for Low Capacitance Measurements Use a guard plate to minimize measurement errors caused by stray capacitance when measuring low capacitance values, such as chip capacitors. See Figure 7-10. Figure 7-10. Example of DUT Guard Plate Connection Shielding Shielding minimizes the e ects of electrical noise picked up by the test leads. So, provide a shield plate and connect it to the outer shield conductors of the four-terminal pair test leads as shown in Figure 7-11. Figure 7-11.
4263B Contact Check To realize accurate measurements and to make the contact check function work correctly, use the following guide lines. Using the four-terminal pair con guration, place your test leads as near as possible to the DUT. Minimize CHL and CPC by arranging your test leads as shown in Figure 7-12. If CHL is large, the valid range of the contact check is reduced. If CPC is larger than about 3 pF, the contact check function may perceive that the DUT is connected even if it is not. Figure 7-12.
4263B Correction Functions of the 4263B The 4263B has the following correction functions, Cable Length correction, OPEN, SHORT, and LOAD corrections. These correction functions are used to correct errors due to test xtures and test leads. Table 7-2 lists these correction functions with a brief description of each. Correction Selection Cable Length Correction OPEN/SHORT Correction OPEN/SHORT/LOAD Correction Table 7-2. Correction Functions Description Correct phase shift error due to the test leads.
4263B Measurements using Agilent test leads and a test xture. In this case, the Cable Length correction and the OPEN/SHORT correction are used. Measurement using a xture that has complicated residual errors. Perform the OPEN/SHORT/LOAD correction using a LOAD standard.
4263B Standard for the LOAD Correction You need a standard to do the LOAD correction. This can be any standard which has speci ed reference values. The type of standard does not have to be same as the device to be measured. That is, a capacitor standard can be used when you want to measure inductors. Using a Standard Supplied by a Component Manufacturer Use the manufacturer speci ed values of the standard as the reference values for the LOAD correction.
8 Speci cations This chapter describes general information regarding the 4263B. This chapter is made up of the following sections.
4263B Speci cations Measurement Parameters Z (jZj) : Absolute value of impedance Y (jYj) : Absolute value of admittance ( ) : Phase angle R : Resistance X : Reactance G : Conductance B : Susceptance L : Inductance (four-terminal pair con guration) C : Capacitance Q : Quality factor D : Dissipation factor Rs (ESR) : Equivalent series resistance Rp : Parallel resistance Option 001: Add the following parameters: L2 : Inductance (two-terminal con guration) N : Turns ratio 1/N : Reciprocal of N M : Mutual indu
4263B Test Cable Lengths 0 m, 1 m, 2 m, 4 m (@ 100 Hz, 120 Hz, 1 kHz) 0 m, 1 m, 2 m (@ 10 kHz, 20 kHz) 0 m, 1 m (@ 100 kHz) Measurement Time Mode Short, Medium, and Long Ranging Auto and Hold (manual) Averaging 1 to 256 Trigger Mode Internal, Manual, External, and Bus Trigger Delay Time 0 to 9.999 seconds in 0.001 seconds steps Measurement Range Parameter Z, R, X Y, G, B C L Measurement Range 1 m to 100 M 10 nS to 1000 S 1 pF to 1 F 10 nH to 100 kH Parameter D Q 6 ( ) Rdc Measurement Range 0.0001 to 9.
4263B jZj, jYj, L, C, R, X, G, B, and Rdc accuracy (Ae [%]) When jZxj > 100 Ae = A + B 2 C 2 jZxj / Zs + D / jZxj + jZxj / E When jZxj or DCR 100 Ae = A + B 2 C 2 Zs / jZxj + D / jZxj + jZxj / E where, jZxj is the measured jZj value. When measuring Y, L, C, R, X, G, B, or Rdc, convert the value to the impedance value using Figure 8-1. Zs is the setup range value and is given in Table 8-1. A, B, and C are given in Table 8-1. D is given in Table 8-2. E is given in Table 8-3.
4263B j Zx j 1M Table 8-1. Measurement Accuracy Parameter: A, B, and C jZx j 100 M Z s DC 1M 0.85 / 0.85 0.075 / 0.025 j Zx j < 1 M 100 k 0.85 / 0.85 0.055 / 0.02 10 k jZx j < 100 k 10 k 1k jZx j < 10 k 1k 100 < j Zx j 1 k 100 100 k 10 < jZxj 100 100 1 < jZxj 10 10 100 m 1m < j Zx j 1 jZx j 100 m 1 100 m 0.85 / 0.85 0.09 / 0.02 0.85 / 0.85 0.29 / 0.
4263B Table 8-1. Measurement Accuracy Parameter: A, B, and C (continued) C j Zx j Zs A [%] (Short / Medium, Long) B [%] (Short / Medium, Long) Test Signal Frequency 20 kHz 100 kHz jZx j 100 M 1M 1.9 / 1.9 0.121 / 0.061 Not Speci ed 100 k j Zx j < 1 M 100 k 1.4 / 1.4 0.051 / 0.031 1.152 / 1.152 0.112 / 0.12 10 k jZx j < 100 k 10 k 1k jZx j < 10 k 1k 100 < j Zx j < 1 k 100 0.8 / 0.8 0.05 / 0.03 0.7 / 0.7 0.05 / 0.03 0.7 / 0.7 0.05 / 0.03 0.5 / 0.5 0.05 / 0.03 0.6 / 0.6 0.05 / 0.
4263B D accuracy (De) De Ae = 6 100 Accuracy applies when Dx (measured D value) 0.1. When Dx > 0.1, multiply De by (1+Dx ). Q accuracy (Qe) Qe =6 Qx is the measured Q value. De is the D accuracy. Accuracy applies when Qx 2 De < 0.1 6 ( ) accuracy ( e ) 2 Q2x De Qx De 17 2 where, e = 180 2 Ae G accuracy (Ge) Ge Where, De is the D accuracy. Bx is given as Bx = Bx 2 De = 2 fCx = 1 2 fLx Where, Cx is the measured C value [F]. Lx is the measured L value [H]. De is the D accuracy.
4263B Rp Accuracy (RPe [ ]) RPe x 2 De = 6 RP D 7D x RPx is the measured Rp [ ], De is the D accuracy. Dx is the measured D. Accuracy applies when Dx (measured D value) 0.1.
4263B Measurement Support Functions Correction Function OPEN/SHORT correction: Eliminates measurement errors due to stray parasitic impedance in the test xtures. LOAD correction: Improves measurement accuracy by using a calibrated device as a reference. Display 40-digit22-lines LCD display. Capable of displaying: measurement values, comparator/contact check results, comparator limits, control settings, self test messages, and annunciators.
4263B General Power Requirements 100/120/220/240 V 610%, 47 to 66 Hz 45 VA max Operating Temperature, Humidity and Altitude 0 to 45 C, 95% RH @ 40 C, 0 to 2000 meters Storage Temperature, Humidity and Altitude 040 to 70 C, 90 % RH @ 65 C, 0 to 4572 meters EMC Complies with CISPR 11 (1990) / EN 55011 (1991) : Group 1, Class A. Complies with EN 61000-3-3 (1995) / IEC 1000-3-3 (1994) Complies with EN 50082-1 (1992) / IEC 801-2 (1991) : 4 kV CD, 8 kV AD.
4263B Supplemental Performance Characteristics The supplemental performance characteristics are listed below. These characteristics are not speci cations but are typical characteristics included as additional information for the operator. Test Signal Accuracy 6(10% + 10 mV), @ 20mV Vosc < 50 mV Test Signal Output Impedance 25 6 10% ( 1 Range) 100 6 10% ( 10 Range) Measurement Accuracy When Vosc 6= 50 mV, 100 mV, 250 mV, 500 mV, 1 V, multiply the Ae [%] value by the following K value.
4263B L2, M, R2 N Measurement Range Parameter Measurement Range L2, M 1 H to 100 H N 0.9 to 200 R2 1 m to 100 M L2, M, R2, N Measurement Accuracy L2 accuracy (L2e [%]) where, L2e = Ae + AEL2 AEL2 [%] is the additional error for L2. AEL2 = (D0 =L2x + L2x =E 0 ) 2 100 where, L2x is the measured L2 value [H].
4263B R2 measurement accuracy (R2e [%]) where, R2e = Ae + AER2 AER2 [%] is the additional error for R2: AER2 = (D"=R2x ) 2 100 where, R2x is the measured R2 value [ ]. D" is given in the following table. Cable Length 0m 1m 2m 4m D" 250 m 500 m 750 m 1250 m N measurement accuracy (Ne [%]) Ne = F + 100 2 G=L2x + (H + 100 2 I=L2x ) 2 J 2 Nx where, Nx is the measured N value. F, G, H, I and J are given in the following tables.
4263B I1 Measurement Test Signal Frequency Time Mode 100/120 Hz 1 kHz 10 kHz 20 kHz 100 kHz 7 H 0.7 H 0.5 H 0.2 H Short 90 H 3.5 H 0.5 H 0.3 H 0.
4263B Measurement Time The following shows typical measurement times when the level monitor is OFF. For all the measurement modes except Ls-Rdc, Lp-Rdc, L2-R2, L2-N, L2-1/N, and L2-M 1. When DC bias is OFF Total Measurement Time [ms] = Td + Tzm1 Where, Td is the trigger delay time [ms]. Tzm1 is given in Table 8-4, last column. Table 8-4. Measurement Time (DC Bias: OFF) Measurement Analog Digital Tzm11 1 1 Time Mode Measurement Computation (= Analog Meas. + Dig. Comput.
4263B Ls-Rdc, Lp-Rdc, L2-R2 modes Total Measurement Time [ms] = Td + 120 + Tzm1 + Tdcr (0 Td < 40 ms) Total Measurement Time [ms] = 4 2 Td + Tzm1 + Tdcr (Td 40 ms) Where, Td is the trigger delay time [ms]. Tzm1 is given in Table 8-4. Tdcr is given in Table 8-6. Table 8-6. Additional Measurement Time for Rdc Measurement Measurement Tdcr Time Mode Short 80 ms Medium 400 ms Long 1680 ms L2-N, L2-1/N, L2-M modes Total Measurement Time [ms] = Td + Tzm1 + Tnm Where, Td is the trigger delay time [ms].
4263B Front-end Protection Internal input circuit is protected, when a charged capacitor is connected to the Input terminals. The maximum capacitor voltage is: 1000 V (C < 2 F) 2=C V (2 F C < 32 F) 250 V (32 F C < 128 F) 8=C V (C 128 F) (where, C is the capacitance value of capacitor (F) ) p p Caution Figure 8-2. Maximum Capacitor Voltage Do not apply DC voltage or current to the UNKNOWN terminals. Doing so will damage the 4263B.
9 Maintenance This chapter provides information on how to maintain the 4263B. 4263B maintenance consists of performance tests and functional tests.
4263B Test Equipment Table 9-1 lists the recommended equipment for performing maintenance on the 4263B. Table 9-1. Recommended Test Equipment Equipment Critical Speci cations Recommended Qty. Use1 Model 5334B 1 P Frequency Counter Frequency: 100 Hz to 100 kHz Accuracy: < 25 ppm 3458A 1 P Frequency: 100 Hz to 100 kHz RMS Voltmeter Voltage Range: 50 mVrms to 1 Vrms Accuracy: < 1% 3458A 1 P DC Voltmeter Voltage Range: 1.5 V to 2 V Accuracy: < 0.
4263B Performance Tests Introduction This section provides the test procedures used to verify that the 4263B's speci cations listed in Chapter 8 are met. All tests can be performed without access to the interior of the instrument. The performance tests can also be used to perform incoming inspection, and to verify that the 4263B meets its performance speci cations after troubleshooting or adjustment.
4263B Performance Test Record Record the performance test results in the test record at the end of this section (Photocopy the test record and use the photocopy). The test record lists all test speci cations, their acceptable limits, and measurement uncertainties for the recommended test equipment. Test results recorded during incoming inspection can be used for comparison purposes during periodic maintenance, troubleshooting, and after repair or adjustment.
4263B Test Signal Frequency Accuracy Test The 4263B's test signal frequency is measured with a frequency counter. Speci cation Test Signal Frequency Accuracy: Note 6 0.01 % (61% at 120 Hz) The 4263B's test signal frequency at the 120 Hz setting is actually 119.048Hz, and it is speci ed as 120 Hz 6 1%. Test Equipment Description Universal Counter 61 cm BNC(m)-BNC(m) Cable Recommended Model 5334B p/n 8120-1839 Procedure 1. Reset the 4263B. 2. Set up the equipment as shown in Figure 9-1.
4263B 3. Set the test signal frequency to 100 Hz using . 4. Record the universal counter reading on the calculation sheet. 5. Calculate the test result according to the calculation sheet, and record the result into the performance test record. 6. Press to change the test signal frequency, and perform this test for all the frequency settings listed in Table 9-2. Table 9-2. Frequency Accuracy Test Settings Test Signal Frequency 100 Hz 120 Hz 1 kHz 10 kHz 20 kHz1 100 kHz 1 Option 002 only.
4263B Test Signal Level Accuracy Test The 4263B's test signal level is measured with an AC voltmeter. Speci cation Test Signal Level Accuracy: 6 (10 % + 10 mV) Test Equipment Description Multimeter 61 cm BNC(m)-BNC(m) Cable Dual Banana-BNC(f) Adapter Recommended Model 3458A p/n 8120-1839 p/n 1251-2277 Procedure 1. Reset the 4263B. 2. Set up the equipment as shown in Figure 9-2. Figure 9-2. Test Signal Level Accuracy Test Setup 3.
4263B 5. Set the test signal frequency to 100 Hz using . 6. Record the Multimeter reading on the calculation sheet. 7. Calculate the test result according to the calculation sheet, and record the result into the performance test record. 8. Change the test signal settings by using and to perform this test for all settings listed in Table 9-3. Table 9-3.
4263B DC Bias Level Accuracy Test The 4263B's DC bias level is measured with a DC voltmeter. Speci cation 6 (5 % + 2 mV) DC Bias Level Accuracy: Test Equipment Description DC Voltmeter Interface Box 61 cm BNC(m)-BNC(m) Cable Dual Banana-BNC(f) Adapter Recommended Model 3458A p/n 04284-65007 p/n 8120-1839 p/n 1251-2277 Procedure 1. Reset the 4263B. 2. Set up the equipment as shown in Figure 9-3.
4263B Figure 9-4. DC Bias Level Accuracy Test Setup Without The Interface Box 3. Press the 3458A Multimeter's 4DCV5 to set the measurement mode to DC voltage. 4. Press to turn the DC Bias ON. (DC Bias indicator ON.) 5. Record the multimeter reading on the calculation sheet. (Default DC Bias setting is 0 V) 6. Calculate the test result according to the calculation sheet, and record the result into the performance test record. 7.
4263B 0 m Impedance Measurement Accuracy Test The 4263B measures the calibrated standard capacitors and resistors at the 4263B's front panel, and the measured values are compared with the standards' listed calibration values. Speci cation Basic Measurement Accuracy: 6 0.1 % (See Chapter 8 General Information f or details.
4263B 4. Press to display the OPEN correction menu. 5. Select Open Meas and press . The OPEN correction is performed. 6. Connect the SHORT termination to the 4263B's UNKNOWN terminals. 7. Press to display the SHORT correction menu. 8. Select ShortMeas and press . The SHORT correction is performed. 9.
4263B Table 9-5. 0 m Capacitance Measurement Test (LONG) Settings Standard Test Signal Frequency 10 pF 100 kHz 100 pF 1 kHz 10 kHz 20 kHz1 100 kHz 1000 pF 100 Hz 1 kHz 100 kHz 0.01 F 100 Hz 120 Hz 1 kHz 10 kHz 100 kHz 1 kHz 0.1 F 100 kHz 100 Hz 1 F 120 Hz 1 kHz 10 kHz 100 kHz 1 Option 002 only. 0 m Capacitance Measurement Accuracy Test (Meas. Time Mode: MED). 15.
4263B Table 9-6. 0 m Capacitance Measurement Test (MED) Settings Standard Test Signal Frequency 100 Hz 0.01 F 100 kHz 0 m Capacitance Measurement Accuracy Test (Meas. Time Mode: SHORT). 21. Set the 4263B measurement conditions as follows: Measurement Parameter: Measurement Time Mode: Test Signal Level: Test Signal Frequency: Trigger Mode: Cp-D SHORT 500 mV 100 Hz Man 22. Connect the 0.01 F Standard Capacitor to the 4263B's UNKNOWN terminals. 23. Press to start the measurement. 24.
4263B 29. Set the DC bias voltage to 2 V according to the following procedure: a. Press to display the DC Bias Setting. b. Press until 2 V blinks, and press c. Press to turn the DC Bias ON. (DC Bias indicator ON.) 30. Press . to start the measurement. 31. Record the 4263B readings of Cp and D on the calculation sheet. 32. Calculate the test results according to the calculation sheet, and record the results into the performance test record. 33. Press to turn the DC Bias o . Table 9-8.
4263B Table 9-9. 0 m Resistance Measurement Test (LONG) Settings Standard Test Signal Frequency 100 m 100 Hz 1 kHz 0 m Resistance Measurement Accuracy Test (Meas. Time Mode: MED). 40. Set the 4263B measurement conditions as follows: Measurement Parameter: Measurement Time Mode: Test Signal Level: Test Signal Frequency: Trigger Mode: R-X MED 500 mV 100 Hz Man 41. Connect the 100 m Standard Resistor to the 4263B's UNKNOWN terminals. 42. Press to start the measurement. 43.
4263B Table 9-11. 0 m Resistance Measurement Test (SHORT) Settings Standard Test Signal Frequency 100 m 100 Hz 0 m DC Resistance Measurement Accuracy Test (Opt. 001 Only). 50. Set the 4263B measurement conditions as follows: Measurement Parameter: Measurement Time Mode: Test Signal Level: Trigger Mode: Ls-Rdc LONG 1V Man 51. Connect the 100 m Standard Resistor to the 4263B's UNKNOWN terminals. 52. Press to start the measurement. 53. Record the 4263B readings of Rdc on the calculation sheet. 54.
4263B 1 m Impedance Measurement Accuracy Test The 4263B measures the calibrated standard capacitors and resistors while using the 1 m test leads, and the measured values are compared with the standards' listed calibration values. Speci cation 6 0.1 % (See Chapter 8 General Information for Basic Measurement Accuracy: details.
4263B Figure 9-6. 1 m Impedance Measurement Accuracy Test Setup 5. Press to display the OPEN correction menu. 6. Select OpenMeas and press . The OPEN correction is performed. 7. Connect the SHORT termination instead of the OPEN termination. 8. Press to display the SHORT correction menu. 9. Selec ShortMeas and press . The SHORT correction is performed. 10.
4263B 14. Calculate the test results according to the calculation sheet, and record the results into the performance test record. 15. Perform this test for all standards and frequency settings listed in Table 9-12. Table 9-12. 1 m Capacitance Measurement Test Settings Standard Test Signal Frequency 100 pF 1 kHz 10 kHz 20 kHz1 100 kHz 1000 pF 100 Hz 100 Hz 1 F 1 kHz 10 kHz 100 kHz 1 Option 002 only. 1 m Resistance Measurement Accuracy Test. 16.
4263B 1 m DC Resistance Measurement Accuracy Test (Opt. 001 Only). 22. Set the 4263B measurement condition as follows. Measurement Parameter: Measurement Time Mode: Test Signal Level: Trigger Mode: Ls-Rdc LONG 1V Man 23. Connect the 100 m Standard Resistor to the 4263B's UNKNOWN terminals using the 1 m test leads and four BNC(f)-BNC(f) adapters. 24. Press to start the measurement. 25. Record the 4263B readings of Rdc on the calculation sheet. 26.
4263B 2 m Impedance Measurement Accuracy Test The 4263B measures the calibrated standard capacitors and resistors while using the 2 m test leads, and the measured values are compared with the standards' listed calibration values. Speci cation 6 0.1 % (See Chapter 8 General Information for Basic Measurement Accuracy: details.
4263B Figure 9-7. 2 m Impedance Measurement Accuracy Test Setup 5. Press to display the OPEN correction correction menu. 6. Select Open Meas and press . The OPEN correction is performed. 7. Connect the SHORT termination instead of the OPEN termination. 8. Press to display the SHORT correction menu. 9. Select ShortMeas and press . The SHORT correction is performed. 10.
4263B 14. Calculate the test results according to the calculation sheet, and record the results into the performance test record. 15. Perform this test for all standards and frequency settings listed in Table 9-14. Table 9-14. 2 m Capacitance Measurement Test Settings Standard Test Signal Frequency 100 pF 1 kHz 10 kHz 20 kHz1 1000 pF 100 Hz 100 Hz 1 F 1 kHz 10 kHz 1 Option 002 only. 2 m Resistance Measurement Accuracy Test. 16.
4263B 2 m DC Resistance Measurement Accuracy Test (Opt. 001 Only). 22. Set the 4263B measurement condition as follows. Measurement Parameter: Measurement Time Mode: Test Signal Level: Trigger Mode: Ls-Rdc LONG 1V Man 23. Connect the 100 m Standard Resistor to the 4263B's UNKNOWN terminals using the 2 m test leads and four BNC(f)-BNC(f) adapters. 24. Press to start the measurement. 25. Record the 4263B readings of DCR on the calculation sheet. 26.
4263B 4 m Impedance Measurement Accuracy Test The 4263B measures the calibrated standard capacitors and resistors while using the 4 m test leads, and the measured values are compared with the standards' listed calibration values. Speci cation 6 0.1 % (See Chapter 8 General Information for Basic Measurement Accuracy: details.
4263B Figure 9-8. 4 m Impedance Measurement Accuracy Test Setup 5. Press to display the OPEN correction menu. 6. Select OpenMeas and press . The OPEN correction is performed. 7. Connect the SHORT termination instead of the OPEN termination. 8. Press to display the SHORT correction menu. 9. Select ShortMeas and press . The SHORT correction is performed. 10.
4263B 14. Calculate the test results according to the calculation sheet, and record the results into the performance test record. 15. Perform this test for all standards and frequency settings listed in Table 9-16. Table 9-16. 4 m Capacitance Measurement Test Settings Standard Test Signal Frequency 100 pF 1 kHz 1000 pF 100 Hz 100 Hz 1 F 1 kHz 4 m Resistance Measurement Accuracy Test. 16.
4263B 4 m DC Resistance Measurement Accuracy Test (Opt. 001 Only). 22. Set the 4263B measurement condition as follows. Measurement Parameter: Measurement Time Mode: Test Signal Level: Trigger Mode: Ls-Rdc LONG 1V Man 23. Connect the 100 m Standard Resistor to the 4263B's UNKNOWN terminals using the 4 m test leads and four BNC(f)-BNC(f) adapters. 24. Press to start the measurement. 25. Record the 4263B readings of Rdc on the calculation sheet. 26.
4263B Calculation Sheet Test Signal Frequency Accuracy Test Counter Reading [a] Hz Hz kHz kHz kHz kHz Test Signal Frequency 100 Hz 120 Hz 1 kHz 10 kHz 20 kHz1 100 kHz Test Result Equation a 0 100.000 Hz a 0 120.000 Hz a 0 1.00000 kHz a 0 10.0000 kHz a 0 20.0000 kHz a 0 100.000 kHz 1 Option 002 only.
4263B Standards' Calibration Values This table is used in the 0 m, 1 m, 2 m, and 4 m Impedance Measurement Accuracy Tests. Standard Frequency Parameter 10 pF 1 kHz 100 pF 1 kHz 1000 pF 1 kHz 0.01 F 120 Hz 0.01 F 1 kHz 0.01 F 10 kHz 0.01 F 100 kHz 0.1 F 1 kHz 0.
0 m Impedance Measurement Accuracy Test 0 m Capacitance Measurement Accuracy Test (Meas.
4263B 0 m Capacitance Measurement Accuracy Test (Meas. Time Mode: LONG) Standard Test Signal Parameter 4263B Reading Test Result Frequency Measured [a] Equation F a 0 cv21 1 F 1 kHz Cp D a 0 cv22 1 F F a 0 cv23 10 kHz Cp D a 0 cv24 F a 0 cv25 1 F 100 kHz Cp D a 0 cv26 0 m Capacitance Measurement Accuracy Test (Meas. Time Mode: MED) 4263B Reading Test Result Standard Test Signal Parameter Equation Frequency Measured [a] nF a 0 cv7 0.01 F 100 Hz Cp D a 0 cv8 nF a 0 cv13 0.
4263B 0 m Resistance Measurement Accuracy Test (Meas. Time Mode: MED) Standard Test Signal Parameter 4263B Reading Test Result Frequency Measured [a] Equation m a 0 cv27 100 m 100 Hz R 0 m Resistance Measurement Accuracy Test (Meas.
4263B 1 m Impedance Measurement Accuracy Test Standard 100 pF 100 pF 100 pF 100 pF 1000 pF 1 F 1 F 1 F 1 F 1 m Capacitance Measurement Accuracy Test 4263B Reading Test Signal Parameter Frequency Measured [a] pF 1 kHz Cp D pF 10 kHz Cp D 1 Cp pF 20 kHz D pF 100 kHz Cp D pF 100 Hz Cp D F 100 Hz Cp D F 1 kHz Cp D F 10 kHz Cp D F 100 kHz Cp D Test Result Equation a 0 cv3 a 0 cv4 a 0 cv3 a 0 cv4 a 0 cv3 a 0 cv4 a 0 cv3 a 0 cv4 a 0 cv5 a 0 cv6 a 0 cv19 a 0 cv20 a 0 cv21 a 0 cv22 a 0 cv23 a 0 cv24 a 0 c
4263B 2 m Impedance Measurement Accuracy Test Standard 100 pF 100 pF 100 pF 1000 pF 1 F 1 F 1 F 2 m Capacitance Measurement Accuracy Test 4263B Reading Test Signal Parameter Frequency Measured [a] pF 1 kHz Cp D pF 10 kHz Cp D 1 Cp pF 20 kHz D pF 100 Hz Cp D F 100 Hz Cp D F 1 kHz Cp D F 10 kHz Cp D Test Result Equation a 0 cv3 a 0 cv4 a 0 cv3 a 0 cv4 a 0 cv3 a 0 cv4 a 0 cv5 a 0 cv6 a 0 cv19 a 0 cv20 a 0 cv21 a 0 cv22 a 0 cv23 a 0 cv24 1 Option 002 only.
4263B 4 m Impedance Measurement Accuracy Test Standard 100 pF 1000 pF 1 F 1 F 4 m Capacitance Measurement Accuracy Test 4263B Reading Test Signal Parameter Frequency Measured [a] pF 1 kHz Cp D pF 100 Hz Cp D F 100 Hz Cp D F 1 kHz Cp D Test Result Equation a 0 cv3 a 0 cv4 a 0 cv5 a 0 cv6 a 0 cv19 a 0 cv20 a 0 cv21 a 0 cv22 4 m Resistance Measurement Accuracy Test 4263B Reading Test Result Standard Test Signal Parameter Frequency Measured [a] Equation m a 0 cv27 100 m 100 Hz R m a 0 cv27 100 m 1 kHz R
4263B Performance Test Record Agilent 4263B LCR Meter Serial No.: Date: Temperature: Humidity: Tested by: Test Signal Frequency Accuracy Test Test Signal Test Limits Test Result1 Frequency 100 Hz 60.010 Hz 120 Hz 61.200 Hz 1 kHz 60.00010 kHz 10 kHz 60.0010 kHz 20 kHz2 60.0010 kHz 100 kHz 60.010 kHz 1 Test Result = Measured Value 0 Setting Value Hz Hz kHz kHz kHz kHz Measurement Uncertainty 6 0.0010 Hz 60.0012 Hz 60.0000088 kHz 60.000086 kHz 60.000086 kHz 60.00086 kHz 2 Option 002 only.
4263B DC Bias Level Accuracy Test DC Bias Test Limits Level 0 V 60.002 V 1.5 V 60.077 V 2 V 60.102 V Test Result1 V V V Measurement Uncertainty 60.000002 V 60.000027 V 60.
0 m Impedance Measurement Accuracy Test 4263B 0 m Capacitance Measurement Accuracy Test (Meas. Time Mode: LONG) 1 of 2 Measurement Standard Test Signal Parameter Test Limits Test Result1 Uncertainty Frequency Measured 10 pF pF 6 0.0029 pF 100 kHz Cp 6 0.331 pF 6 0.0002 D 6 0.0331 pF 6 0.018 pF 100 pF 1 kHz Cp 6 0.19 pF D 6 0.0019 6 0.0001 pF 6 0.029 pF 100 pF 10 kHz Cp 6 0.44 pF 6 0.0002 D 6 0.0044 2 pF 100 pF Cp 6 0.029 pF 6 1.10 pF 20 kHz 6 0.0002 D 6 0.0110 pF 6 0.029 pF 100 pF 100 kHz Cp 6 1.
4263B 0 m Capacitance Measurement Accuracy Test (Meas. Time Mode: LONG) 2 of 2 Standard Test Signal Parameter Test Limits Measurement Test Result1 Frequency Measured Uncertainty F 6 0.00044 F 1 F 100 Hz Cp 6 0.0018 F 6 0.00015 D 6 0.0018 F 6 0.00044 F 1 F 120 Hz Cp 6 0.0018 F D 6 0.0018 6 0.00015 F 6 0.00020 F 1 F 1 kHz Cp 6 0.0011 F 6 0.0001 D 6 0.0011 F 6 0.00044 F 1 F 10 kHz Cp 6 0.0026 F 6 0.0004 D 6 0.0026 F 1 F 6 0.0010 F 100 kHz Cp 6 0.0176 F 6 0.0025 D 6 0.
4263B 0 m Resistance Measurement Accuracy Test (Meas. Time Mode: LONG) Measurement Standard Test Signal Parameter Test Limits Test Result1 Uncertainty Frequency Measured m 6 0.10 m 100 m 100 Hz R 6 0.52 m m 100 m 6 0.10 m 1 kHz R 6 0.48 m 1 Test Result = Measured Value 0 Standard's Calibration Value 0 m Resistance Measurement Accuracy Test (Meas. Time Mode: MED) Standard Test Signal Parameter Test Limits Measurement Test Result1 Frequency Measured Uncertainty m 6 0.10 m 100 m 100 Hz R 6 0.
4263B 1 m Impedance Measurement Accuracy Test 1 m Capacitance Measurement Accuracy Test Standard Test Signal Parameter Test Limits Test Result1 Frequency Measured 100 pF 1 kHz Cp 6 0.19 pF D 6 0.0019 100 pF 10 kHz Cp 6 0.48 pF D 6 0.0048 2 Cp 100 pF 6 1.10 pF 20 kHz D 6 0.0110 100 pF 100 kHz Cp 6 1.37 pF D 6 0.0137 1000 pF 100 Hz Cp 6 2.0 pF D 6 0.0020 1 F 100 Hz Cp 6 0.0018 F D 6 0.0018 1 F 1 kHz Cp 6 0.0011 F D 6 0.0011 1 F 10 kHz Cp 6 0.0026 F D 6 0.0026 1 F 100 kHz Cp 6 0.0207 F D 6 0.
4263B 2 m Impedance Measurement Accuracy Test 2 m Capacitance Measurement Accuracy Test Standard Test Signal Parameter Test Limits Test Result1 Frequency Measured 100 pF 1 kHz Cp 6 0.19 pF D 6 0.0019 100 pF 10 kHz Cp 6 0.51 pF D 6 0.0051 2 Cp 100 pF 6 1.10 pF 20 kHz D 6 0.0110 1000 pF 100 Hz Cp 6 2.0 pF D 6 0.0020 1 F 100 Hz Cp 6 0.0018 F D 6 0.0018 1 F 1 kHz Cp 6 0.0011 F D 6 0.0011 1 F 10 kHz Cp 6 0.0026 F D 6 0.
4263B 4 m Impedance Measurement Accuracy Test 4 m Capacitance Measurement Accuracy Test Measurement Standard Test Signal Parameter Test Limits Test Result1 Uncertainty Frequency Measured pF 100 pF 6 0.018 pF 1 kHz Cp 6 0.19 pF 6 0.0001 D 6 0.0019 pF 6 0.18 pF 1000 pF 100 Hz Cp 6 2.0 pF D 6 0.0001 6 0.0020 F 6 0.00044 F 1 F 100 Hz Cp 6 0.0018 F 6 0.00015 D 6 0.0018 F 6 0.00020 F 1 F 1 kHz Cp 6 0.0011 F 6 0.0001 D 6 0.
4263B Functional Tests Introduction This section provides the test procedures used to verify that the 4263B performs its designed functions. The functional tests can be used for post repair function veri cation. The transformer measurement functional test is recommended to be performed during the 4263B performance testing. Record the transformer measurement functional test result in the test record at the end of this section.
4263B Transformer Measurement Functional Test (Opt. 001 Only) The 4263B's transformer measurement function is tested using a power splitter. The 4263B measures a transformer's turn ratio by stimulating a transformer and comparing the primary voltage to the secondary voltage. In this test, the 4263B stimulates the power splitter, instead of the transformer, and compares the two voltages across the power splitter.
4263B 5. Press to start the measurement. 6. Con rm that the N reading is within the limits listed in Table 9-18. 7. Perform this test for all settings listed in Table 9-18 Table 9-18. Transformer Measurement Test Limits Switch Frequency Minimum Maximum Setting Setting Limit Limit 1:N 1 kHz 1.980 2.020 1:N 100 kHz 1.970 2.030 N:1 1 kHz 0.985 1.015 N:N 100 kHz 0.980 1.
4263B Handler Interface Functional Test The 4263B's handler interface function is tested using the built-in self-test and the handler interface tester. Test Equipment Description Handler Interface Tester Recommended Model p/n 04339-65007 Procedure Initial Setup. 1. Turn the 4263B OFF. 2. Set the LED PW switch on the Handler Interface Tester to OFF, and set the IN1, IN2, IN3, and IN4 switches to 0. 3. Set up the equipment as shown in Figure 9-10 Figure 9-10. Handler Interface Functional Test Setup 4.
4263B Handler Interface Output Test. 11. Start the handler interface output test with the following procedure. a. Press to display the con guration setting menu. b. Select SVC using c. Select HNDL using or or , and press , and press . . 12. Set the LED PW switch on the Handler Interface Tester to ON. Caution Do not set the LED PW switch to ON, except when doing the handler interface output test. The LEDs may cause the 4263B to shut-down during normal operation. 13.
4263B Contact Check Functional Test The 4263B's contact check function is tested, by breaking contact at the Lpot terminal. When the 4263B measures impedance correctly, the contact check function for the other three terminals will operate correctly. Test Equipment Description 10 k Standard Resistor OPEN Termination Test Leads, 1 m Adapter BNC(f)-BNC(f) Recommended Model 42038A1 , 2 42090A2 16048A p/n 1250-0080, 4 ea.
4263B 5. Select OpenMeas and press . The OPEN correction is performed. 6. Set the measurement parameter to R-X. 7. Connect the 10 k standard resistor instead of the OPEN termination. 8. Press to hold the measurement range. 9. Press to activate the contact check function. 10. Con rm that the 4263B displays the measurement values. 11. Remove the test leads BNC connector from the Lpot terminal of the standard resistor. 12. Con rm that the 4263B displays N.C. (No Contact).
4263B Functional Test Record Agilent 4263B LCR Meter Serial No.: Date: Temperature: Humidity: Tested by: Transformer Measurement Functional Test (Opt.
A Manual Changes Introduction This appendix contains the information required to adapt this manual to earlier versions or con gurations of the 4263B than the current printing date of this manual. The information in this manual applies directly to an 4263B whose serial number pre x is listed on the title page of this manual. Manual Changes To adapt this manual to your 4263B, refer to Table A-1, and make all of the manual changes listed opposite your instrument's serial number.
4263B Serial Number Agilent Technologies uses a two-part, ten-character serial number that is stamped on the serial number plate (see Figure A-1). The rst ve characters are the serial pre x and the last ve digits are the su x. Figure A-1.
B Handler Interface Installation Introduction This appendix describes the electrical characteristics of each signal line of the handler interface. Electrical Characteristics Output Signals Each DC output is isolated using open collector output opto-isolators. The output voltage of each line is enabled by putting pull-up resistors on the main board, and by connecting the pull-up resistors to an externally applied DC voltage.
4263B Figure B-1.
4263B Figure B-2.
4263B Input Signals The DC isolated input signals are connected to the cathodes of the LEDs in the opto-isolators. The anodes of the LEDs are powered by an external voltage source (EXT DCV2). The OFF state voltage (high level) of the DC isolated input signals depends on the pull-up voltage powered by an external voltage source (EXT DCV2). (The input current is restricted by using a switch on the main board.) The electrical characteristics of the input signals are listed in Table B-2.
4263B Handler Interface Board Setup Before using the handler interface, connect the pull-up resisters to enable the output signals and set the dip switch to select the voltage level for the input signals. Caution SUSCEPTIBLE TO DAMAGE FROM ESD. Perform the following procedures only at a static-safe workstation and wear a grounding strap. Tools and Fasteners The 4263B mechanical components are secured using metric threaded fasteners.
4263B The following gure shows the location of the A1 main board and the A2 CPU board. 4. Remove the A2 CPU board assembly. a. Disconnect two atcable assemblies from the front side of the A2 assembly. b. Disconnect the atcable assembly, which is connected to the GPIB connector on the rear panel, from the rear right side of the A2 assembly. c. Remove the four screws that secure the A2 assembly to the stud. d.
4263B 5. Remove the A1 main board assembly. a. Disconnect the following cable assemblies and wire assemblies from the A1 assembly. i. The four cable assemblies marked \A", \B", \C", and \D" which are connected to the UNKNOWN connectors on the Front Panel ii. The wire assembly which is connected to the transformer iii. The two wire assemblies which are connected to the DC-DC Converter iv. The wire assembly which is connected to the Ext DC Bias terminal b.
4263B Table B-3. Pull-up Resistor Location Socket No. Signal Name Signal Type J5-1 /EOM Control Signal (5 V to 15 V) J5-2 /INDEX J5-3 /PIN Comparison Signal (5 V to 24 V) J5-4 /PHI J5-5 /PLO J5-6 /SIN J5-7 /SHI J5-8 /SLO J5-9 /NO CONTACT J5-10 /ALARM Control Signal (5 V to 15 V) J5-11 Not used 6. Mount the pull-up resistors for the comparison output signals. (Refer to Figure B-4 and Table B-3 for the location of the pull-up resistors for the comparison output signals.
4263B 8. Set SW1 according to the voltage value of EXT DCV2. EXT DCV2 EXT TRIG KEY LOCK SW1-1 SW1-2 SW1-3 Close 5 V to 6 V Close Close Close 6 V to 9 V Close Open Open 9 V to 15 V Open Close 9. Reinstall the A1 main board, the A2 CPU board, and the cover.
C Overload/No-Contact Operations Table C-1 shows the summary of operations, when the 4263B detects OVLD (Overload), or N.C. (No-Contact). Table C-1. OVLD/N.C. Condition Display Handler GPIB Output Output Data Mode Comprtr Mode OVLD OVLD High4 /PHI and /SHI 2 :1 :9.9E37 (Overload) 3 :2 Low4 /PLO and /SLO 2 :1 :9.9E37 3 :4 N.C. N.C. N.C. /NO CONTACT 2 :2 :9.9E37 (No-Contact) 3 :8 1 1. 2. 3. 4. Solutions Select an approptiate measurement range.
4263B When the OVLD and N.C. are detected at the same time, Display, Handler output and GPIB output of the 4263B depend on the impedance value of the DUT, the selected measurement range and the connection between DUT and the contact-pin. The 4263B performs one of following cases in the Table C-2. Table C-2. Simultaneous OVLD and N.C. Condition Condition Display Handler GPIB Output Output Data Mode Comprtr Mode N.C. N.C. /NO CONTACT 2 :2 OVLD & N.C. :9.
Messages This section lists the messages that are displayed on the 4263B's LCD display or transmitted by the instrument over GPIB in numerical order.
4263B Instrument Errors 11 ADC FAILURE The A/D conversion failed. The 4263B stops operation and the /ALARM signal on the handler interface . Contact your nearest Agilent Technologies o ce. 12 ROM TEST FAILED Contact your nearest Agilent Technologies o ce. 13 RAM TEST FAILED Contact your nearest Agilent Technologies o ce. 14 EEPROM R/W FAILEDx Contact your nearest Agilent Technologies o ce. 15 USER DATA LOST Correction data and instrument settings saved in EEPROM have been lost.
4263B 31 OPT NOT INSTALLED The :SENS:CONC command is received even though the 4263B is not equipped with Option 001 (Add N/M/DCR measurement function). 32 ILLEGAL MEAS FUNC Illegal parameters combination for :SENS:FUNC command is received while the :SENS:FUNC:CONC is set to ON; For example, FIMP and VOLT:AC are illegal. GPIB Errors -100 Command error This is a generic syntax error that the 4263B cannot detect more speci c errors. This code indicates only that a command error, as de ned in IEEE 488.
4263B -113 Undefined header The header is syntactically correct, but it is unde ned for the 4263B for example, *XYZ is not de ned for the 4263B. -121 Invalid character in number An invalid character for the data type being parsed was encountered; for example, an alpha character in a decimal number or a \9" in octal data. -123 numeric overflow The magnitude of exponent was larger than 32000 (se IEEE488.2,7.7.2.4.1).
4263B -151 Invalid string data A string data element was expected, but was invalid for some reason (see IEEE 488.2, 7.7.5.2); for example, an END message was received before the terminal quote character. -158 String data not allowed A string data element was encountered but was not allowed by the 4263B at this point in the syntax analysis process. -160 Block data error This error as well as errors -161 through -168, are generated when analyzing the syntax of a block data element.
4263B -221 Setting conflict A legal program data element was parsed but could not be executed due to the current device state (see IEEE 488.2, 6.4.5.3 and 11.5.1.1.5). -222 Data out of range A legal program data element was parsed but could not be executed because the interpreted value was outside the legal range as de ned by the 4263B (see IEEE 488.2, 11.5.1.1.5).
4263B -430 Query DEADLOCKED A condition causing an deadlocked query error occurred (see IEEE 488.2, 6.3.1.7); for example, both input bu er and output bu er are full and the 4263B cannot continue. -440 Query UNTERMINATED after indefinite response A query was received in the same program message after an query requesting an inde nite response was executed (see IEEE 488.2, 6.5.7.5.7).
Index Special characters :, 5-4 ;, 5-4 0 0 m impedance measurement accuracy test, 9-11 1 1 m impedance measurement accuracy test, 9-18 2 2 m impedance measurement accuracy test, 9-22 4 4 m impedance measurement accuracy test, 9-26 A :ABORt, 4-13, 5-9 ABORt Command , 5-9 accessory, 1-3 Address key, 3-10 Altitude Operating, 8-10 Storage, 8-10 6 ( ), 8-7 annunciator, 3-2 Arrow key , 3-11 ASCII , 5-22, 5-48 Auto/Hold key, 3-7 auto range, 3-7 Auto Range mode, 1-22 :AVERage:COUNt, 4-10, 5-24 Average ke
Calibration Cycle, 9-4 CALibration subsystem, 5-15 capacitance measurement accuracy test 0 m DC Bias:ON, 9-14 0 m DC Bias:ON calculation sheet, 9-33 0 m LONG, 9-11 0 m LONG calculation sheet, 9-32 0 m MED, 9-13 0 m MED calculation sheet, 9-33 0 m SHORT, 9-14 0 m SHORT calculation sheet, 9-33 1 m, 9-18 1 m calculation sheet, 9-35 2 m , 9-22 2 m calculation sheet, 9-36 4 m, 9-26 4 m calculation sheet, 9-37 capacitance to ground, 7-8 characteristics example, 7-2 Chassis Terminal, 3-3 circuit mode, 7-3 cleaning
:DISPlay[:WINDow]:TEXT1:PAGE, 5-19 :DISPlay[:WINDow]:TEXT2:PAGE, 5-20 Down/Left Arrow Keys, 1-16 DUT characteristics, 7-2 E electrolytic capacitor measurement, 6-1 EMC, 8-10 Engineering Units key, 3-11 Enter Key, 3-11 *ESE , 4-26, 5-36 *ESE? , 5-36 *ESR? , 4-26, 5-36 external DC bias speci cations, 8-2 External DC bias Terminal, 3-22 external trigger mode, 2-4, 3-9 External Trigger Terminal , 3-21 F :FETCh?, 4-13, 5-21 FETCh? query, 5-21 :FIMPedance:APERture, 4-9, 5-26 :FIMPedance:CONTact:VERify, 4-1
local mode, 2-10 Local Mode how to return, 4-3 *LRN?, 4-12, 5-36 M manual changes, A-1 manual trigger mode, 2-4, 3-9 Mathematical Functions, 8-9 Maximum DC Bias Current, 8-16 Maximum Key, 3-12 Maximum Keys, 1-16 measurement accuracy, 8-11 speci cations, 8-3 measurement accuracy parameter, 8-4 Measurement Con guration, 2-1 measurement contacts, 7-7 measurement parameter GPIB command, 5-11 how to select, 1-21, 4-5 Measurement Parameter key , 3-4 Measurement Parameters, 8-2 measurement range, 3-8 GPIB comman
how to, 1-20, 4-5 Reset key, 3-19 resistance measurement accuracy test 0 m LONG, 9-15 0 m LONG calculation sheet, 9-33 0 m MED, 9-16 0 m MED calculation sheet, 9-33 0 m SHORT, 9-16 0 m SHORT calculation sheet, 9-34 1 m, 9-20 1 m calculation sheet, 9-35 2 m, 9-24 2 m calculation sheet, 9-36 4 m, 9-28 4 m calculation sheet, 9-37 response message syntax, 5-7 Rp Accuracy, 8-8 Rs Accuracy, 8-7 *RST, 4-5, 5-37 S *SAV, 4-12, 5-37 save instrument settings, 2-10 Save Key , 3-10 Save/Recall, 8-9 Selection Type Key
T Talker , 3-26 talk only mode, 2-11, 3-10 Temperature Operating, 8-10 Storage, 8-10 test cable con guration, 7-6 test cable lengths speci cations, 8-3 test current transient, 3-33 test equipment, 9-2 test xture, 1-3 how to connect, 1-19 test leads, 1-3 con guration, 7-6 extension, 7-9 test signal speci cations, 8-2 test signal accuracy, 8-11 speci cations, 8-2 test signal frequency, 3-6 GPIB command, 5-29 how to select, 1-22, 4-7 speci cations, 8-2 test signal frequency accuracy speci cations, 8-2 test si
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